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WO2017012575A1 - Method and system for integrating vehicle data measurement and computation, monitoring, surveillance, and troubleshooting - Google Patents

Method and system for integrating vehicle data measurement and computation, monitoring, surveillance, and troubleshooting Download PDF

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Publication number
WO2017012575A1
WO2017012575A1 PCT/CN2016/090935 CN2016090935W WO2017012575A1 WO 2017012575 A1 WO2017012575 A1 WO 2017012575A1 CN 2016090935 W CN2016090935 W CN 2016090935W WO 2017012575 A1 WO2017012575 A1 WO 2017012575A1
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WO
WIPO (PCT)
Prior art keywords
vehicle
value
parameter
power
parameters
Prior art date
Application number
PCT/CN2016/090935
Other languages
French (fr)
Chinese (zh)
Inventor
冯春魁
Original Assignee
冯春魁
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Filing date
Publication date
Application filed by 冯春魁 filed Critical 冯春魁
Publication of WO2017012575A1 publication Critical patent/WO2017012575A1/en

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W40/00Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
    • B60W40/10Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models related to vehicle motion
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W40/00Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
    • B60W40/12Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models related to parameters of the vehicle itself, e.g. tyre models
    • B60W40/13Load or weight
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W50/00Details of control systems for road vehicle drive control not related to the control of a particular sub-unit, e.g. process diagnostic or vehicle driver interfaces
    • B60W50/02Ensuring safety in case of control system failures, e.g. by diagnosing, circumventing or fixing failures
    • B60W50/0205Diagnosing or detecting failures; Failure detection models
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W50/00Details of control systems for road vehicle drive control not related to the control of a particular sub-unit, e.g. process diagnostic or vehicle driver interfaces
    • B60W50/04Monitoring the functioning of the control system
    • B60W50/045Monitoring control system parameters
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W40/00Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60WCONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
    • B60W40/00Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
    • B60W40/02Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models related to ambient conditions
    • B60W40/06Road conditions
    • B60W40/076Slope angle of the road

Definitions

  • the present invention relates to the field of vehicle technology, and more particularly to a method and system for data measurement, monitoring, monitoring, and processing of an integrated vehicle.
  • Vehicles running on land are one of the most important and basic transportation vehicles in the world. Because the safety of vehicles is closely related to the safety of drivers and occupants, the safety monitoring performance of vehicles is always improved. The core focus of technology;
  • vehicles usually have a power system that generates power and a mechanical transmission system that transmits power.
  • the power system usually has an energy supply device, a power control device, and a power device; the power system of the vehicle and the mechanical transmission system that transmits power can work. Any one or more components in a rotated state may be referred to as a rotary working power or transmission component of the vehicle;
  • the vehicle has fuel power, electric power, hybrid system, etc.;
  • Existing hybrid vehicles include two or more power systems, such as fuel power systems and electric power systems;
  • Existing fuel-powered vehicles generally have a fuel power system and a mechanical transmission system;
  • the fuel power system generally includes a fuel supply system, an engine control system, and a fuel engine; wherein the fuel engine usually has a cylinder block, a piston, and a crankshaft that outputs power.
  • the mechanical transmission system generally includes a fuel engine output shaft, a drive wheel, and an intermediate mechanical transmission component (including a transmission shaft, a transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel; the fuel engine output shaft, the drive Both the wheel and the intermediate mechanical transmission component may operate at a high speed rotation state, and any one or more of the components of the series may be referred to as a rotary working power or transmission component of the vehicle;
  • Existing electric vehicles usually also have an electric power system, a mechanical transmission system; the electric power system generally includes a power supply device, a motor drive device, a motor; an electric motor rotor, a motor output shaft, a drive wheel, and a motor output shaft Any one or more of the intermediate mechanical transmission components between the drive wheel and the drive wheel may also be referred to as a rotary working power or transmission component of an electric power vehicle; some of the hub motor vehicles may also integrate the power system and the mechanical transmission system. ;
  • various stress sensors can be conveniently installed to facilitate the internal stress condition of each part; for example, the stress or torque sensor is fixed to the fixed part. It is not convenient to detect the true stress condition of the rotating component on the support component; if it is installed inside the rotating component, the signal is not convenient to transmit/or the sensor power supply device is inconvenient to set; thus, the existing rotary working power that can be used for the vehicle or Torque sensor for transmission components High cost; low-cost monitoring of the rotating working power of the vehicle or the operating conditions of the transmission components (especially early failures) is an industrial problem, a worldwide problem;
  • A, local device type monitoring program the existing tire pressure monitoring system can monitor the tire pressure, have a certain early warning effect on the puncture; but it can only monitor the tire pressure of the pneumatic tire, and usually only the tire leakage caused by tire leakage Or when the wheel speed changes significantly, the response is slow; and there is no monitoring capability for the deformation (out of roundness) of the tire, and no monitoring capability for other rigid rotating parts (even the wear of the pneumatic tire's own transmission bearing); Vehicles with wheels (including drive wheels) (such as high-speed rail vehicles, motor trains, ordinary trains, electric locomotives, and tracked vehicles) have no monitoring effect.
  • vehicle operating parameters such as longitudinal speed, Longitudinal acceleration, vehicle mass, vehicle driving force, torque, power, current, etc. may also vary greatly in normal operating conditions; therefore, existing Class B technical solutions can only simply exceed the safety limit of vehicle operating parameters.
  • the threshold (such as the maximum speed limit, the maximum acceleration limit value, the maximum safe load capacity, the maximum power, the maximum torque, the maximum current, etc.) responds; it is inconvenient to implement the vehicle before the vehicle operating parameters do not exceed the preset safety limit threshold.
  • the monitoring of the operation safety status is even more inconvenient to achieve high-sensitivity early monitoring; usually only passive, lag waiting for the vehicle's transmission spindle to break, the transmission gear burst, including the tire tire when there is no tire pressure monitoring system, may have caused In the event of a serious security incident, the police can be alerted and rehabilitated.
  • One of the technical problems to be solved by the present invention is to provide a technical solution for facilitating monitoring of vehicle power transmission anomalies (including caused by a rotating working power of a vehicle or a malfunction of a transmission component);
  • the invention provides
  • a monitoring method for controlling a running time of a vehicle by a power device the measuring object being any one or more parameters of a vehicle operating parameter of the vehicle
  • the joint operation value is calculated based on a vehicle motion balance calculation formula;
  • the vehicle motion balance calculation formula is a formula describing a balance between a vehicle dynamic direction and a related resistance in a running direction or a deformation thereof;
  • the correlation resistance includes a rolling resistance and a gradient resistance Any one or any of a variety of speed resistance and wind resistance.
  • determining whether the power transmission condition of the vehicle is abnormal includes any one or more of the following:
  • the reference data includes a first permission upper limit value and an actual value; determining whether a difference between the joint operation value and the actual value is greater than a first permission upper limit value;
  • the reference data includes a first permission lower limit value and an actual value; determining whether a difference between the joint operation value and the actual value is less than a first permission lower limit value;
  • the reference data includes an actual value; determining whether the actual value is greater than an upper limit value set according to the joint operation value;
  • the reference data includes an actual value; and it is judged whether the actual value is smaller than a lower limit value set according to the joint operation value.
  • the reference data includes a second permission upper limit value; and determining whether the joint operation value is greater than a second permission upper limit value;
  • the reference data includes a second permission lower limit value; and determining whether the joint operation value is less than a second permission lower limit value.
  • the abnormality of the power transmission condition includes any one of the following cases:
  • the reference data includes a first permission upper limit value and an actual value; the difference between the joint operation value and the actual value is greater than the first permission upper limit value;
  • the reference data includes a first permission lower limit value and an actual value; the difference between the joint operation value and the actual value is less than the first permission lower limit value;
  • the reference data includes an actual value; the actual value is greater than an upper limit value set according to the joint operation value;
  • the reference data includes an actual value; the actual value is less than a lower limit value set according to the joint operation value;
  • the reference data includes a second permission upper limit value; the joint operation value is greater than the second permission upper limit value;
  • the reference data includes a second permissible lower limit value; the joint operation value is less than the second permissible lower limit value.
  • the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality: actual value in reference data And any one or more of the data in the second permission range is set according to the measured value, and the time value of the reference data and the value of the joint operation value are within a preset time range;
  • the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality: actual value in reference data
  • any one or more of the second permission ranges are set according to the historical record value of the measurement object, and the difference between the vehicle running condition and the current vehicle running condition when the historical value is taken is lower than the preset a threshold value, where the historical record value includes any one of a history original value and a history actual value or Two kinds of data.
  • any one or more of the actual value and the second permission range in the reference data is calculated according to the vehicle motion balance calculated when the set condition is satisfied. Joint operation value setting;
  • any one or more of the actual value and the second permission range in the reference data are set according to the historical record value;
  • any one or more of the actual value and the second permission range in the reference data are set according to a preset value
  • the calibration value in the reference data, the second Any one or more of the permitted range and the first permitted range is a joint operation value set obtained based on a preset value or a vehicle motion balance calculation performed when the set condition is satisfied.
  • the second permission upper limit value is set according to an actual value
  • the second permission lower limit value is set according to an actual value
  • the monitoring method includes the following 5A1, 5A2, 5A3, 5A4, 5A5 Any one or more of the options:
  • the second license upper limit value is included in the reference data, the second license upper limit value is less than a maximum value of the safety limit threshold value;
  • the second permitted lower limit value is included in the reference data, the second permitted lower limit value is greater than a minimum value of the safety limit threshold value;
  • the sum of the first permitted upper limit value and the actual value is less than a maximum value of the safety limit threshold
  • the sum of the first permitted lower limit value and the actual value is greater than a minimum value of the safety limit threshold
  • the lower limit value set according to the joint operation value is greater than the minimum value of the safety limit threshold value, and / Or the actual value is greater than the minimum value of the safety limit threshold;
  • the upper limit value set according to the joint operation value is smaller than the maximum value of the safety limit threshold value, and / Or the actual value is less than the maximum value of the safety limit threshold.
  • the monitoring method further includes the steps of:
  • the monitoring method calculates the joint operation value according to the obtained value of the input parameter of the vehicle, and the input parameter is a parameter required for calculating the joint operation value. .
  • the monitoring method further includes the steps of: acquiring operating environment information of the vehicle; determining, according to the joint operation value, the reference data, and the operating environment information, whether a power transmission abnormality occurs. The power transmission failure situation.
  • the vehicle mass required to calculate the joint operation value is a time-based vehicle The exercise balance is calculated.
  • the monitoring method further includes the following scheme: acquiring a power device operating condition, and associating the power device operating condition with the calculation.
  • the mass variation type item quality is included.
  • the parameters participating in the calculation include any one or three of the efficiency coefficient, the rolling resistance coefficient, and the road surface gradient.
  • the value of the vehicle mass is output and/or saved.
  • the time of energy accumulation is controlled within one day or within one hour or within 30 minutes or 10 minutes. Within one minute or within 30 seconds or within 20 seconds or within 10 seconds or within 5 seconds or within 2 seconds or within 1 second or within 100 millimeters or within 10 milliseconds or 1 millisecond Inside or within 0.1 mm.
  • the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor drive parameter and an electrical power parameter of the back end.
  • the fuel power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter
  • the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
  • the vehicle operating parameters include a vehicle mass, a source power parameter, and a system operating parameter
  • the system operating parameter includes a mechanical operating parameter, a system inherent parameter, and a quality variable item quality.
  • the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, an ordinary private vehicle, a general train, a crawler vehicle, Any of electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles with powertrains, or tricycles.
  • the second technical problem to be solved by the present invention is to provide a technical solution for facilitating monitoring of data related to vehicle operation safety
  • the invention provides
  • a method of monitoring vehicle operation comprising the steps of:
  • the joint operation value is calculated based on a vehicle motion balance calculation formula
  • the vehicle motion balance calculation formula is a formula describing a balance between the dynamic direction and the related resistance of the vehicle in the running direction or a deformation thereof
  • the correlation resistance It includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
  • the joint operation value of the measurement object is output on a human machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
  • the monitoring method further includes the steps of: acquiring an actual value or a calibration value of the measurement object, and outputting the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product. Measure the actual or calibrated value of the object.
  • the measurement object is one or more parameters that have been output on the human machine interface of the in-vehicle electronic device and/or the portable personal consumer electronics product.
  • the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle instrument panel, a driving recorder, and an in-vehicle video monitoring. Any one or more devices in the system.
  • the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart wristband.
  • the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor drive parameter and an electrical power parameter of the back end.
  • the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
  • the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, a general private vehicle, a general train, a crawler vehicle, Any of electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles with powertrains, or tricycles.
  • the vehicle is an aircraft that is operating on land and whose air lift is below a predetermined threshold or the longitudinal speed is below a preset value.
  • the third technical problem to be solved by the present invention is to provide a technical solution for facilitating processing of data related to vehicle operation safety
  • the invention provides
  • the formula for calculating the balance of motion is a formula for describing the balance of the dynamics of the vehicle in the running direction and the associated resistance or a variant thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
  • the measurement object is an unmeasurable parameter and/or any one or more parameters of a preset parameter and/or a system inherent parameter, and the joint operation value is output and/or saved;
  • the processing method when the measurement object is any one of vehicle operation parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the processing method further needs to acquire the actual object of the measurement object. a value; outputting and/or saving the joint operation value and the actual value, and/or outputting and/or saving a difference between the joint operation value and the actual value.
  • the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more parameters of a motor drive parameter and an electrical power parameter of the back end.
  • the fourth technical problem to be solved by the present invention is to provide a monitoring method that does not require overloading of a vehicle weighed with a scale.
  • the invention also provides
  • a method of monitoring a vehicle overload comprising the steps of:
  • the joint operation value is calculated based on a vehicle motion balance calculation formula
  • the vehicle motion balance calculation formula is a formula describing a balance between a vehicle dynamic direction and a related resistance in a running direction or a variant thereof Formula
  • the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; determining whether the vehicle is overloaded according to the acquired joint operation value and the vehicle maximum load safety permission value of the vehicle .
  • the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more parameters of a motor driving parameter and a back end electrical power parameter.
  • the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
  • the fifth technical problem to be solved by the present invention is to provide a solution for improving the reliability of the joint operation value when the operating condition of the power plant changes;
  • the invention also provides (35.) a method for calculating a vehicle operating parameter of a vehicle, the measuring object being any one or more parameters of vehicle operating parameters of the vehicle, the calculating method comprising the steps of: acquiring the vehicle a value of the input parameter and a power plant operating condition; the input parameter is a parameter required to calculate a joint operation value of the measurement object of the vehicle; and a joint operation of the measurement object is calculated according to the value of the acquired input parameter Value and output and/or save the value; the calculation is based on vehicle motion
  • the calculation of the balance calculation formula correlates the power plant operating conditions with the calculations.
  • the invention also provides
  • the determining parameter obtaining module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle and reference data of the measurement object; and the joint operation value is calculated based on a vehicle motion balance calculation formula;
  • the power transmission status determination module (2) is configured to: determine whether the power transmission status of the vehicle is abnormal according to a joint operation value of the measurement object of the vehicle and reference data of the measurement object;
  • the power transmission abnormality processing module (3) is configured to: if the result of the determining is yes, initiate a set power transmission abnormality processing mechanism;
  • the output module (4) is configured to: output a determination result of the power transmission status determination module (2);
  • the saving module (5) is configured to: save the determination result of the power transmission status determination module (2).
  • the invention also provides
  • a monitoring system for vehicle operating parameters the measuring object being any one or more of vehicle operating parameters of the vehicle, wherein the monitoring system comprises a joint operation value acquiring module (1), an indicating module (2):
  • the calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle; the joint operation value is calculated based on a vehicle motion balance calculation formula;
  • the indication module (2) is configured to output a joint operation value of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
  • the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle instrument panel, a driving recorder, and an in-vehicle video monitoring. Any one or more devices in the system.
  • the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart bracelet.
  • the invention also provides
  • a processing system for vehicle data the measurement object being any one or more parameters of vehicle operating parameters, the processing system comprising a joint operation value acquisition module (1), the processing system further comprising an output module (2) ) and / or save module (3):
  • the calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle, and the joint operation value is calculated based on a vehicle motion balance calculation formula; when the measurement object is Measuring parameters and / or preset parameters When any of the vehicle operating parameters other than the number and/or the system inherent parameter is used, the actual value or the calibration value of the measuring object is also acquired;
  • the output module (2) is configured to: output the joint operation value; and/or the measurement object is an unmeasured parameter and/or any one or more of a preset parameter and/or a system inherent parameter; and/or
  • the joint operation value and the actual value are output, and / Or outputting a difference between the joint operation value and the actual value;
  • the saving module (2) is configured to: save the joint operation value as: the unmeasured parameter and/or any one or more parameters of the preset parameter and/or the system intrinsic parameter; and/or
  • the measured object is any one of vehicle operating parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, saving the joint operation value and the actual value, and/ Or saving the difference between the joint operation value and the actual value.
  • the invention also provides
  • a monitoring system for overloading a vehicle comprising a joint operation value acquisition module (1) and an overload determination module (2); the monitoring system further comprising an overload processing module (3) and an output module (4) ), saving any one or more of the modules (5);
  • the joint operation value obtaining module (1) is configured to: acquire a joint operation value of a vehicle mass of the vehicle, where the joint operation value is calculated based on a vehicle motion balance calculation formula;
  • the overload judgment module (2) is configured to: determine whether the vehicle is overloaded according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle;
  • the overload processing module (3) has the following functions: if the determination result includes yes, the set overload processing mechanism is activated;
  • the output module (4) is configured to: output a determination result of the overload determination module (2);
  • the saving module (5) is configured to: save the determination result of the overload determination module (2).
  • FIG. 1 is a schematic diagram of a monitoring method when a vehicle is controlled by a power unit according to the present invention
  • FIG. 2 is a schematic diagram of a monitoring system when a vehicle is controlled by a power unit according to the present invention
  • FIG. 3 is a schematic view of the operation of the vehicle of the present invention.
  • the data is a value, and the data is equivalent to the value; for example, the joint operation data is equivalent to the joint operation value, and the measured value is equivalent to The measured data and command value are equivalent to the command data
  • the preset data is the preset value
  • the system preset data is the system preset value
  • the manual preset data is the manual preset value
  • the system default data is the system default value
  • the fuzzy algorithm data is The fuzzy algorithm value, the historical record data, that is, the historical record value, that is, the historical data, that is, the historical value, etc.; obviously, in the present invention, the meaning of direct combination of a plurality of well-known names is equivalent to adding a "" to the plurality of publicly-known words.
  • the meaning of the connection of the words for example: the measured data is the measured data, the preset data is the preset data, etc.; the meaning of the direct combination of the non-public well-known words and the publicly-known words is equivalent to adding one to the non-public well-known words and the publicly-known words.
  • the meaning of the connection of the word "" for example, the joint operation data, that is, the data of the joint operation (that is, the data obtained through the joint operation), the state of the power transmission state, that is, the transmission of power, and the like; and so on, the understanding of all the nouns You can refer to this way to reason.
  • the joint operation value is the estimated value, that is, the estimated value;
  • the calculation rule that is, the rule, that is, the corresponding relationship, that is, the model, is a formula; in the present invention, it is equivalent to based on (that is, passing or passing); according to the data B setting data A or data A is set based on the data B, It can be any of the following cases: data B is directly set to data A, and data B is subjected to some additional processing (such as adding a certain offset value and multiplying a certain coefficient) into data A and the like;
  • the absolute value of the difference between A and B is smaller than the preset value.
  • the size of the preset value is different, and the size of the preset value can be reasonable through the system.
  • A is within the B range: the A is less than or equal to the upper limit of the B range , A is greater than or equal to the lower limit of the B range;
  • the data (ie, the value of a parameter) in the present invention usually has various attributes, such as a time attribute, an acquisition path, a value range, and the like;
  • the data (or the value of the parameter) can be divided into current data (ie, current value), historical data (ie, historical value), and predicted data (that is, predicted value, that is, data predicted based on a certain time point) That is, the future value);
  • the current value is the real-time value when there is no limit;
  • the historical data (or historical value) refers to the data generated in the past time point;
  • the time of the data (or the value of the parameter) the priority refers to the data (or The generation (or generation) time of the parameter's value, not the priority value time;
  • the data (or the value of the parameter) can be divided into actual measurement, setting, and joint operation; the measured value can be called measured data (or measured value), and the set data is called setting data (
  • the data obtained by the joint operation (that is, calculated based on the vehicle motion balance calculation formula) is called joint operation data (or joint operation value); the setting data (or set value) can be divided into system settings.
  • Data, manual setting data; system setting data is data that is not manually set.
  • the time of the integration time and the acquisition route, the data (or the value of the parameter) can be further divided into: the current measured data (or measured value), the current joint operation data (or joint operation value), the current setting data (or Fixed value), past measured data (or measured value), past preset data (or preset value), past joint operation data (or joint operation value), etc.; past joint operation data (or joint operation value) ) that is, the time-first joint operation data (or joint operation value);
  • setting data usually refers to the set data (such as data that has been set by the system, has been manually set)
  • the setting in the present invention means that the setting is preset, and the setting data is the set data. That is, the preset data (that is, the preset value); in the present invention, the past measured value, the past set value, and the past joint operation value belong to the set data for the current application, That is, preset data.
  • the preset data can be further divided into system preset data (ie, system preset value), manual preset data (ie, manual preset value), instruction data (or command value), and current running.
  • Learning value ie, system preset value
  • manual preset data ie, manual preset value
  • instruction data or command value
  • current running current running
  • Learning value ie, system preset value
  • manual preset value may also be referred to as manual input data (or manual input value)
  • the learning value of the current running referred to as the learning value;
  • the manual preset data (ie, the manual preset value, that is, the manual input value) refers to the value set by the vehicle controller according to the actual situation;
  • the command data (ie, the command value is the command) may also be referred to as command preset data (or command preset value), with the control function of the parameter; for the mechanical operating parameters of the vehicle (especially speed and / or acceleration) and / Or control command data (or command value) of data such as source dynamic parameters (especially for thrust or) therein, for controlling mechanical operating parameters of the vehicle (especially for speed and / or acceleration) and / or source dynamic parameters (especially for Target data (or target value) of parameters such as thrust or); if the current speed is 100KM/H, when the system issues command data (or command value) of 200KM/H speed, the vehicle needs an acceleration process to reach the target speed;
  • the learned value of the secondary operation generally refers to the value obtained by calculating the vehicle motion balance calculation according to the set condition in the current running flow, and the joint obtained by calculating the vehicle motion balance according to the set condition in the present invention.
  • the calculated value means that the joint operation value is calculated by pre-calculating the vehicle motion balance, and therefore can also be understood as being obtained according to the joint operation value obtained in advance;
  • the system preset data (that is, the system preset value) includes the history value, the fuzzy algorithm value, and the system default value.
  • Historical value usually refers to the value of the learned record that has been experienced by going through; the historical record value, including the original value of the historical record, the actual value of the historical record, the value of the historical record correlation factor, etc., the specific formation method is described later. Said
  • the fuzzy algorithm value refers to the value obtained by the set fuzzy algorithm rule (see the following for details);
  • the system default value is the simplest data setting method. Obviously, the system default (accurate) value; the system default value can include the factory default value, the corrected or adjusted default value; the factory default value is also the factory default. Value, raw value; in general, system defaults can be applied more widely than factory defaults;
  • the measured data is relatively easy to understand, and refers to the value measured based on the sensor (or hardware facility, instrument, etc.); in the present invention, the actual measurement is the measurement, that is, the detection; for example, the fuel mass value obtained by the oil meter measurement, such as the velocity measurement.
  • the measured vehicle speed such as the acceleration measured by the acceleration sensor, such as the angle of attack measured by the inclination meter, the slope of the road, etc.; the value of the position and velocity measured based on the information of the satellite navigation system (such as Beidou or GPS). Also belonging to the measured value, the satellite navigation system (such as Beidou or GPS) information can understand a kind of radio positioning and measurement information. Based on the measured data, the data is calculated by routine calculation.
  • the measured value it is also the measured value; for example, the torque T is measured first, and then divided by the radius to obtain the force, which is also called the measured value; special statement: based on part of the measured data (such as source dynamic parameters)
  • the result of vehicle motion balance calculation (this method is the core point of the invention), which is not a measured value, and belongs to a joint operation value;
  • the data (or the value of the parameter) can be divided into a maximum value (ie, an upper limit value), a minimum value (ie, a lower limit value), an intermediate value, or a center value;
  • the data can be divided into actual value, instruction data (or instruction value), reasonable range (including reasonable value), safety range (safety value), special meaning value, etc.; because the instruction data (or instruction value) is Security has a special meaning, and it is also allowed to be drawn from the preset data as an independent data type;
  • the actual value and the true value of the present invention are different concepts; the real value is usually a natural and true value of a certain attribute of a certain parameter.
  • the no-load mass m0 of a certain vehicle is 1500KG
  • the mass of the carried goods is 200KG (for example, 150KG for people and 50KG for goods).
  • the true value of the total mass of the vehicle is 1700KG; Set the actual value of the total mass of the vehicle at any time (for example, manual input, or perform a vehicle motion balance calculation).
  • the actual value of the total mass of the vehicle is likely to be set to 1680KG due to comprehensible error, accuracy, etc., then the 1680KG It can be regarded as the actual value of the total mass of the vehicle at the time of setting (but not the actual value); the actual value is a kind of practical data in the present invention, and the actual value is naturally set with the setting time and setting of the parameter.
  • the actual value of the parameter in this paper refers to the value that is close to or equal to the true value when the parameter is set; for example, when When the actual value is set according to the preset value, the actual value is also the actual value of the parameter when preset; for example, when the actual value of the parameter is set according to the system default value in the preset value, the actual value is also That is, the actual value (that is, the calibration value) of the parameter in the system default (usually, the standard state); for example, when the actual value is set based on the learning mode, the actual value is also learning.
  • the actual value means that the parameter is in a practical application (for example, in any measurement method, monitoring method, monitoring method or processing method in the present invention) Gets the actual value of the current state of the acquisition time of the value of the input parameter, ie the current value of the parameter.
  • the current or current time refers to the acquisition time of the value of the input parameter in a practical application (for example, in any of the measurement methods, monitoring methods, monitoring methods, or processing methods of the present invention);
  • the actual value of the parameter is the current actual value of the parameter without any limitation; when there is no limit, the current value of the parameter is also the current actual value of the parameter.
  • any scheme or data can be equivalently substituted into other technical solutions;
  • any formula in the present invention can be arbitrarily modified to move any parameter of the formula to the left of the equation equal sign as a target parameter (or Calculating the object), and putting other parameters equivalently to the right to calculate the target parameter (or measuring object);
  • the deformations in the present invention are equivalent deformations;
  • Vehicle operating parameters all parameters that have an impact on the operating state of the vehicle, and/or all parameters related to vehicle operation, and/or all vehicle related parameters may be referred to simply as vehicle operating parameters; source dynamic parameters, vehicles as described herein
  • the quality and system operating parameters are all vehicle operating parameters; the parameters in this paper do not refer to a single parameter, but may also be multiple parameters or parameter groups; In this paper, the system operation parameters are also the system operation parameter groups; Other parameters not described in the present invention may be classified according to the concept of the present invention with reference to the parameter value path and technical characteristics.
  • the definition of the source power parameter of the vehicle is the source power parameter, the source power parameter is generated based on the vehicle's power system; the source power is the power;
  • the electrical power parameters include motor drive parameters, electrical power parameters of the rear end, etc.; the present invention classifies electrical power parameters having electrical parameter properties into motor drive parameters (also referred to as electrical drive parameters or front end electrical power parameters);
  • the vehicle quality (that is, the vehicle quality parameter) of the present invention mainly includes the following parameters: the mass of the carried item m1, the data including the mass of the carrying item such as the total mass m2 of the vehicle; and the vehicle quality priority refers to the total mass of the vehicle, unless otherwise specified,
  • the total mass of the vehicle can be expressed by m2 (also denoted by m); the mass unit can be expressed in kilograms (KG or kg); the total mass m2 of the vehicle is usually composed of the mass of the carried item m1, the no-load mass m0, and the quality-variable item mass mf; Any one or more of the mass m2, the carrying item mass m1, the no-load mass m0, and the mass-changing item quality may be referred to as vehicle mass.
  • the mass of the carried item m1 refers specifically to the quality of the loaded personnel items other than the net weight of the vehicle, and may also be referred to as the quality of the carried item;
  • the no-load mass m0 is the quality or net mass of the vehicle when it is empty; it can be accurately known by preset (for example, reading factory parameters, etc.) or weighing on the scale, without counting;
  • the quality change item quality mf refers to the variable quality during operation; mf mainly includes the fuel quality, so the fuel quality can be used to calculate the mass of the quality change item in the calculation;
  • the system operating parameter (ie, the system operating parameter group) of the present invention refers to all parameters except vehicle quality and source power parameters in the vehicle operating parameters; the system operating parameter group of the present invention mainly includes the following three types of parameters: Mechanical operating parameters, system intrinsic parameters, quality of quality changes.
  • the system operating parameters of the vehicle are substantially parameters representative of the underlying conditions of power transmission and/or the inherent properties of the vehicle and/or the inherent properties of the environment and/or the results of the motion produced by the vehicle under the action of power.
  • the mechanical operating parameter of the present invention (in addition to the source dynamic parameter and the vehicle mass), the size (ie, the amplitude) of the parameter in the vehicle operating parameter can be controlled by the operator as a mechanical operating parameter; and/or: ( The parameter to be measured in the vehicle operating parameters other than the source dynamic parameters and the vehicle mass is the mechanical operating parameter;
  • System intrinsic parameters refers to parameters related to the inherent properties of the vehicle and/or the environment; and/or: (in addition to the source dynamic parameters and vehicle mass) the size (ie amplitude) of the parameter in the vehicle operating parameters is not controlled by the operator
  • the parameters of the control are inherent parameters of the system; and/or: (in addition to the source dynamic parameters and the mass of the vehicle) the predefinable parameters in the vehicle operating parameters are system intrinsic parameters; and/or: (except the source dynamic parameters and the vehicle)
  • the unmeasurable parameter in the vehicle operating parameter other than the mass is a system inherent parameter; the system inherent parameter of the present invention may also be referred to as a system setting parameter;
  • Derived parameters any parameters described in the present invention, derived, deformed, renamed, expanded, reduced, increased offset values, filtered, weighted, averaged, estimated interference, compensated interference, RLS algorithm processing, recursive minimum two
  • the parameters obtained by the power processing and the like are all referred to as derived parameters of the parameters, and all the derived parameters still belong to the original parameter type; OK;
  • the third range described in the present invention may also be referred to as a conventional range (that is, a compliance range, that is, a range conforming to a regulation or agreement).
  • the third range may refer to the normal range or calibration range or rated range of the parameter;
  • the calibration range refers to the range when the parameter is in a preset or reasonable calibration state, and the calibration state is also a nominal state or a standard state;
  • the calibration range may also be marked
  • the rated range refers to the range when the parameter is at a preset or reasonable rated state;
  • the conventional value (ie, the compliance value) of the parameter in the present invention may be the normal value or the calibration value or the rated value of the parameter; the normal value of the parameter refers to the value in the normal range of the parameter, and It is preferably a central value in the normal range; the calibration value of the parameter refers to the value in the calibration range of the parameter, and is preferably the central value in the calibration range; the calibration value may also be referred to as a nominal value or a standard value; the nominal value of the parameter refers to The value in the nominal range of the parameter, and preferably the center value in the nominal range; it is obvious that the conventional value of the parameter is typically the value in the third range.
  • the fourth range described in the present invention refers to the safety range of the parameter; the safety range of the vehicle operating parameter (also referred to as the safety limit threshold or safety permission value or safety threshold or safety limit threshold or safety threshold or safety value) a preset value for the vehicle operating parameter that is generally generated to prevent an abnormality in operating conditions or a safety accident, or a preset value for avoiding device damage according to a power plant or a power control device or an energy supply device design specification.
  • the safety range of the vehicle operating parameter also referred to as the safety limit threshold or safety permission value or safety threshold or safety limit threshold or safety threshold or safety value
  • a preset value for the vehicle operating parameter that is generally generated to prevent an abnormality in operating conditions or a safety accident, or a preset value for avoiding device damage according to a power plant or a power control device or an energy supply device design specification.
  • the safety value of the parameter may also include a value set according to the natural limit attribute of the vehicle operating parameter;
  • the upper limit of the safety range is naturally the maximum load safety value m_ena (also known as the legal load or the maximum safe load mass of the vehicle).
  • the lower limit of the safety range of the quality of the carried goods is naturally 0; the total mass of the vehicle is safe.
  • the value is the sum of the safe value of the no-load mass and the quality of the carried goods; for example, the upper limit of the safety range of the remaining fuel mass mf0 is naturally
  • the fuel tank can be loaded with the maximum mass of fuel of this type of fuel, and the lower limit of the safety range of the remaining fuel mass mf0 is naturally 0;
  • the upper limit of the safety range of the fuel consumption rate fm2 is naturally various limit states (such as maximum Load limit, maximum slope, maximum slope, maximum speed, maximum acceleration, parameters such as the maximum fuel supply per unit time that can be supplied by the fuel supply line, etc.)
  • the comprehensive limit value, the lower limit of the safety range of the fuel consumption rate fm2 Naturally, it is 0; in the present invention, the lower limit value of the safety range is also the minimum value of the safety value; the upper limit value of the safety range is also the maximum value of the safety value;
  • An acceptable range of parameters means that the parameter can achieve a useful value or a range of natural attributes of the parameter (including the input parameter); the acceptable range described in the present invention can be
  • the third range may also be the fourth range or the second range, depending on the application; for example, the power transmission condition identification, the vehicle power transmission abnormality monitoring, reflecting, and analyzing the vehicle's power transmission to be monitored Any of the operating conditions (wear and/or safety conditions) of the components, analysis of wheel deformation (out of roundness) and/or wheel wear, monitoring of data related to vehicle operating safety, and processing of data related to vehicle operation safety
  • One or more uses are for a practical use; in the absence of a limitation, the scope of the invention is an acceptable range (ie, a reasonable range).
  • the third range is within the fourth range; in the present invention, the second permission range may be simply referred to as the second range; the first permission range may be simply referred to as the first range; the second range is The invention proposes a range with special significance, which can be used for the identification of the power transmission condition; when a certain parameter is a parameter to be measured (that is, a variable parameter), the second range of the parameter can be the actual value of the parameter.
  • the third range the absolute value can be much smaller than the absolute value of the fourth range, and can be greater than the absolute value of the fourth range in some special occasions; when a certain parameter is a presettable parameter, the parameter The second range may coincide with the acceptable range or within the acceptable range;
  • any one or more of the first range, the second range, the third range, the fourth range, and the acceptable range of the vehicle operating parameters may be preset, and may be preset values (especially system presets)
  • the value can also be a manual input value); any parameter can preset its standard value, third range, and fourth range; for example, the standard value of gravitational acceleration g can be preset to 9.81; the third of gravitational acceleration g
  • the range can be preset to (9.5 ⁇ ⁇ 10.5), the fourth range of gravitational acceleration g can be preset to (8.5 ⁇ ⁇ 11.5), and so on; and the standard value, the third range, and the fourth range of any parameter A data can be preset and adjusted according to the site conditions and actual conditions.
  • all preset data can pass through the vehicle production service manufacturer, professional testing organization, manual trial and error method, limited trial, type test, existing Knowing in any one or more ways of the technology; the user can also test, verify, adjust, and set the vehicle by itself; such as the deviation of the preset data (that is, the preset value (especially the system preset value)) Even the error causes the monitoring effect of the monitoring method to decrease, and does not affect the effectiveness of the technical solution; in the present invention, the setting is preset;
  • the operation of the present invention mainly refers to the operation of the vehicle without mechanical connection with the ground facility.
  • the invention can measure the parameter, that is, the parameter that can be measured, generally refers to the value of the parameter in the running of the vehicle can be obtained by the measured way;
  • the unmeasurable parameter of the invention is the parameter that cannot be measured, generally refers to the value of the parameter in the running of the vehicle cannot be Measured or unmeasurable, determined by the hardware condition of the vehicle; if the sensor that can measure the parameter is not set, or the sensor is not working properly, it is untestable; the high-configuration, high-performance vehicle naturally measurable parameter More; low-profile, low-cost vehicles can be set with fewer sensors; the tire radius can only be measured at rest, and is usually unmeasurable during operation; the total mass of the vehicle can be weighed by the scale, which is usually not measurable during operation; Said, for example, speed, source dynamic parameters, longitudinal acceleration, wind resistance fw, mass change type of goods (especially the fuel quality therein) are all measurable parameters; most of the system inherent parameters, such as empty body mass m0, Efficiency coefficient, rolling resistance factor f,
  • the preset parameter of the present invention means that when the vehicle is working normally, the absolute value of the difference between the maximum value and the minimum value of the parameter is within a preset range, that is, the value of the parameter obtained based on the preset and the parameter.
  • the difference of the current value is within a predetermined reasonable (or prescribed) range, that is, the value of the parameter obtained based on the preset can be used to describe the true condition of the parameter; for example, the empty body mass m0, the efficiency coefficient, The rolling resistance coefficient, the integrated gear ratio im, the gravitational acceleration, the tire radius, etc.
  • the value of the preset parameter can be set based on a preset value, which is usually a calibration value;
  • the radius of the tire, the calibration value can be the preset value of the vehicle; the calibration value of gravity acceleration and tire radius is equal to the preset value when the vehicle leaves the factory; the calibration value of the rolling resistance coefficient is equal to The theoretical value of the type of tire on a preset type of road surface (cement road, asphalt road, etc.).
  • the calibration value can be a fixed value or a variable function value, such as the efficiency coefficient described above, which is a function that gradually decreases as time and/or total travel distance changes.
  • the parameter to be measured according to the present invention means that at a certain moment when the vehicle is in normal working, the difference between the value of the parameter obtained based on the preset and the current value of the parameter exceeds a preset reasonable (or prescribed) range, That is, the value of the parameter obtained based on the preset cannot be used to describe the true state of the parameter, and cannot be used normally, that is, the current value of the parameter cannot be obtained by a preset manner, and the parameter is an unpredeterminable parameter;
  • the source dynamic parameters, speed, longitudinal acceleration, wind resistance fw, mass change type of goods are all parameters to be measured; the parameters to be measured can also be understood as variable parameters, which work normally in the vehicle.
  • the absolute value of the difference between the maximum value and the minimum value of the parameter is outside the preset range; the preset range may be adjusted by the user or the manufacturer, that is, the number of parameters to be measured by the manufacturer or the user is freely selected.
  • the mechanical operating parameters are obtained by actual measurement, for example, the air density p0 in the system inherent parameters is obtained by default;
  • the newly added two technical solutions can set the road gradient to a preset parameter to reduce the cost in some models of vehicles, for example, reading preset values of the road gradient of the road by preset map data and position information;
  • the air density p0 can be used as a measurable parameter in another type of vehicle to improve the measurement accuracy of the wind resistance fw in your different altitude or temperature environment; therefore, the new scheme is advantageous for further calculation of the vehicle motion balance calculation principle. Achieve better monitoring performance or cost.
  • the present invention is primarily applicable to vehicles that can be operated along a road surface or track by a power plant; the road surface of the present invention includes (horizontal or sloped) road surface, and the track of the present invention includes (horizontal or railway track of a slope; the operation of the present invention refers to longitudinal operation without limitation or additional description;
  • the power device of the electric power system is a motor;
  • the motor according to the present invention refers to a motor capable of directly driving the vehicle to run longitudinally along the road surface or the track.
  • the main types of the motor include, but are not limited to, an AC asynchronous motor and an AC synchronous motor. , DC motor, switched reluctance motor, permanent magnet brushless motor, linear motor, hub motor, etc.;
  • a power plant of a fuel power system means a fuel engine capable of directly driving a vehicle to run longitudinally along a road surface or track;
  • a powerplant of a hybrid power system is a hybrid power unit that can directly drive a vehicle to run longitudinally along a road surface or track; a hybrid power plant means that the device is powered by two or more types of power (such as a motor and a fuel engine). Directly driving the vehicle in longitudinal operation;
  • the power control device of the electric power system is a motor drive device, and refers to a device capable of driving the motor of the present invention and Connecting cables, including but not limited to: inverters, servo drives, DC motor controllers, switched reluctance motor drives, permanent magnet brushless motor drives, linear motor drives, integrated controllers with motor drive capability, etc.; If the motor is directly powered/powered through a feed switch, the feed switch can also be regarded as a simple motor drive device;
  • the power control device of the fuel power system is a fuel engine control system
  • the power control device of the hybrid system is a hybrid control system
  • An energy supply device for an electric power system which may be referred to as a power supply device, refers to a device that can provide driving energy to a motor drive device, a motor, and a vehicle, and a connection cable thereof, including a power battery pack, a hydrogen fuel cell, and a nuclear power. Power supply, solar power, power supply for rail electric locomotives, etc.;
  • the energy supply device of a fuel power system which may be referred to as a fuel supply system, refers to a device capable of providing fuel to a fuel engine, including a fuel container (such as a fuel tank), a fuel delivery pipe (such as a fuel pipeline), and a fuel injection system (such as Fuel injection pump), etc.
  • a fuel container such as a fuel tank
  • a fuel delivery pipe such as a fuel pipeline
  • a fuel injection system such as Fuel injection pump
  • the energy supply device of a hybrid power system which may be referred to as a hybrid energy supply system, refers to a device capable of providing energy to a hybrid control system and a hybrid power device, and may include two or more energy supplies at the same time.
  • Devices such as fuel supply systems and power supply units;
  • the category of the components (ie, components) included depends on the collection point of the specific motor drive parameter group signal;
  • the electric power system includes three components of the power supply device, the motor drive device and the motor of the vehicle; for example, the collection point of the source power parameter signal is at the output end of the power supply device or the motor At the input end of the driving device, the electric power system includes two parts of the motor driving device and the motor; if the collecting point of the source power parameter signal is at the output end of the motor driving device or the input end of the motor, the electric power system only includes the motor;
  • the fuel power system of the present invention if the collection point of the source power parameter signal is at the fuel input end of the fuel injection system of the vehicle, the fuel power system includes the fuel injection system of the vehicle, the fuel engine and the like;
  • the collection point of the power parameter signal is at the fuel injection output end of the fuel injection system of the vehicle, and the fuel power system includes a fuel engine or the like;
  • the power device, the power control device, and the energy supply device according to the present invention are mainly functionally classified; from the device structure, any two or three of the three may be combined into the following. Any one of a comprehensive system: a two-in-one integrated system of power control devices and power plants, a two-in-one integrated system of energy supply devices and power control devices, a three-in-one integrated system of energy supply devices and power control devices and power plants; The specification and claims of the present invention also encompass any of the above two-in-one, three-in-one integrated systems.
  • the system preset value of the present invention is also a system setting value
  • the reading parameter value includes reading a local parameter value, reading a parameter value through a communication method (such as CAN, 485, 232, WIFI, Bluetooth, infrared, etc.), and transmitting the data through the network (for example, Various wired and wireless networks) remotely reading vehicle operating parameter values and other methods;
  • a communication method such as CAN, 485, 232, WIFI, Bluetooth, infrared, etc.
  • the definition of the source dynamic parameters of the vehicle; the parameter that can represent or calculate the force or torque or power that directly drives the longitudinal operation of the vehicle is the source dynamic parameter; the source dynamic parameter is generated based on the vehicle's power system; according to the type of the power system
  • the source dynamic parameters generated based on the electric power system may be referred to as electric power parameters; the source dynamic parameters generated based on the fuel power system are referred to as fuel dynamic parameters; if simultaneously generated based on two or more power systems
  • the source power parameter is called a hybrid power parameter; obviously, the force that is directly driven by the vehicle's power system to directly drive the vehicle is the force formed by the power system of the vehicle, which may be simply referred to as source power, that is, power, that is, driving force;
  • the invention operates in a longitudinal direction, so the power is also longitudinal power; the source power parameter is also the power parameter; the running direction refers to the moving direction.
  • the electric power parameter includes a motor driving parameter, an electric power parameter of the rear end, and the like; the present invention classifies an electric power parameter having an electrical parameter property obtained by a motor and a motor front end (including a power supply device, a motor driving device, etc.) into a motor drive.
  • Parameters also referred to as electrical drive parameters or electrical dynamic parameters of the front end
  • the mechanical components of the rear end of the motor (motor output shaft, drive wheel, and intermediate mechanical transmission components between the motor output shaft and the drive wheel, etc.)
  • the electrical power parameters obtained above are classified into the electrical dynamic parameters of the back end;
  • the fuel power parameter includes a fuel power parameter of the front end, a fuel power parameter of the rear end, and the like;
  • the fuel power parameter of the front end generally refers to a fuel dynamic parameter obtained by the fuel engine output crankshaft front end component (such as an engine cylinder, a fuel supply system, etc.)
  • the fuel dynamic parameters of the rear end mainly include the fuel measured by the engine rear end (fuel engine output shaft, drive wheel, and intermediate mechanical transmission components (including transmission shaft, transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel) Dynamic parameter
  • the hybrid parameters also include the hybrid parameters of the front end, the hybrid parameters of the back end, and the like;
  • a source dynamic parameter of a non-motor drive parameter type may be defined, and a source dynamic parameter of the non-motor drive parameter type includes any one or more of the source dynamic parameters of the back end electrical power parameter, fuel power parameter, and hybrid power parameter. ;
  • the source power parameters of the vehicle can be further divided into the source power parameters of the front end and the source power parameters of the back end; wherein the source power parameters of the front end include the electrical power parameters of the front end (also referred to as motor drive parameters or electrical drive parameters). ), the fuel dynamic parameters of the front end, the hybrid parameters of the front end, etc.; wherein the source dynamic parameters of the back end include the electrical power parameters of the back end and the fuel power of the back end Parameters, hybrid parameters of the back end, etc.;
  • Hybrid vehicle if the longitudinal operation of the vehicle is only directly driven by the motor during a certain period of time, then the power unit of the hybrid vehicle is a motor (not called a hybrid device) during the period, then the time period is called
  • the corresponding source power parameter is the electric power parameter; if the longitudinal operation of the vehicle is only directly driven by the fuel engine during a certain period of time, the power device of the hybrid vehicle is fueled during the time period.
  • the engine also not called hybrid device
  • the source power parameter corresponding to the time when the vehicle is controlled by the fuel engine is the fuel power parameter; only when the vehicle is running longitudinally, two or more When the direct drive of the power system is realized, the power device is a hybrid device, and the corresponding source power parameter is a hybrid power parameter;
  • the electrical parameters of the motor mainly include and are not limited to the following parameters: motor voltage Uo, motor current Io, power factor ⁇ 1 (also denoted by ⁇ ), electrical power Po (also denoted by Pm), electromagnetic torque Te, motor Rotation speed n1, rotating magnetic field speed n0;
  • the electrical parameters of the motor drive device mainly include and are not limited to the following parameters: output voltage U2o, output current I2o, output power factor ⁇ 2, output electrical power P2o, electromagnetic torque Te, input voltage U2i (also denoted by Ui) Input current I2i (also denoted by Ii), input electrical power P2i, driver DC bus voltage Udc, torque current component iq;
  • the torque current component iq refers to a vector-controlled motor drive device (such as a frequency converter or a servo drive). After vector transformation, the motor current is stripped of the torque component of the excitation component; the torque current component iq, and the motor torque have Comparing the direct correspondence; the conversion coefficient Ki, Ki*iq through the torque current and the electromagnetic torque can be used to directly calculate the torque;
  • the electrical parameters of the power supply unit mainly include but are not limited to the following parameters:
  • the usual power supply device may include the following output electrical parameters: output voltage U3o (also represented by Ub1), output current I3o (also denoted by Ib1), output electrical power P3o, power factor ⁇ 3;
  • the power supply device of the external power supply type may further include the following input electrical parameters: input voltage U3i, input current I3i, input electrical power P3i;
  • the voltage U4 (which can also be represented by Ub2) fed back into the power supply device from the motor power generation, and the current I4 fed back to the power supply device from the motor when the motor brakes (also indicated by Ib2).
  • P2o Po
  • the electromagnetic torque Te according to the present invention refers to a voltage or current or a magnetic field according to the motor.
  • the calculated motor torque including the electromagnetic torque Te calculated inside the motor drive device, also includes the electromagnetic torque Te calculated by measuring the motor voltage and the motor current outside the motor drive device;
  • the measurement of the electromagnetic torque Te is very simple, low in cost, and high in precision.
  • the electromagnetic torque Te does not include the mechanical torque machine obtained by installing the mechanical stress measurement principle (such as the dynamic torque tester) on the motor output shaft or other mechanical drive shaft or flywheel; the two are in the measurement principle, the measurement path, and the cost performance of the measurement. There are significant differences.
  • the electrical parameters of the present invention are further divided into motor drive parameters and electrical auxiliary parameters;
  • Common motor drive parameters include, but are not limited to, the following types: electrical power, electromagnetic torque, current, electromechanical combination parameters, etc.:
  • the first type electrical power; in the absence of additional instructions or qualifications, the electrical power of the present invention refers to active power; the way to obtain electrical power is as follows:
  • Electrical power value acquisition method 1 first obtain current and voltage, and then indirectly obtain power value by calculation; such as (Uo, Io, ⁇ 1), or (U2o, I2o, ⁇ 2), or (U2i, I2i), or (U3o, I3o, ⁇ 3), or (U3i, I3i); calculating electrical power by voltage and current, is a well-known technique;
  • Electrical power value acquisition method 3 directly read the internal parameters of the motor drive device to obtain electrical power values; such as Po, Pm, P2o, P2i, P3o, P3i;
  • Electrical power value acquisition method 4 Obtain electrical power value by measuring with active power meter; such as Po, Pm, P2o, P2i, P3o, P3i;
  • Electromagnetic torque Te value acquisition mode 1 directly read the internal parameters of the motor drive device to obtain the Te value; such as directly reading the electromagnetic torque Te value in the inverter or servo drive;
  • Electromagnetic torque Te value acquisition mode 3 By measuring the output voltage and output current of the motor drive device, and indirectly obtaining the Te value by calculation;
  • the current value acquisition mode 2 the current sensor is used to measure the current of the device, the power factor factor is used to measure the power factor, and then the current value is obtained by calculation;
  • a single torque or a single current or a single power can be independent motor drive parameters; the voltage can be used as a motor drive parameter in conjunction with the corresponding current parameter; the speed can be a motor drive parameter in conjunction with the corresponding torque parameter;
  • electromechanical combined type parameter refers to the parameter calculated according to the combination of the above-mentioned motor drive parameters, and the specific definition manner thereof is described later;
  • Electrical auxiliary parameters refer to parameters that can be used to identify the operating conditions of the motor and the state of the motor.
  • the main parameters include, but are not limited to, the following parameters: motor running status word, motor control command word, etc.; because existing motor drive devices such as frequency conversion
  • the device can output fault information such as accelerating overcurrent, deceleration and overcurrent, and constant speed overcurrent, so it is also possible to obtain acceleration, deceleration, constant speed and other operating states from the inside of the motor drive device through relevant electrical auxiliary parameters;
  • the method of obtaining the electrical auxiliary parameter value 1 reading the internal parameters of the motor drive device and obtaining;
  • the electrical power parameters of the back end mainly include the driving torque, driving power and driving force measured by the back end of the motor;
  • the fuel power parameters of the engine mainly include, but are not limited to, the following parameters: fuel consumption rate fm1 in the engine, cylinder pressure F1, driving power Pr1, driving torque Tr1, driving force Ff1, air flow C1 in the cylinder, and the like;
  • the fuel power parameters of the fuel supply system mainly include, but are not limited to, the following parameters: the fuel consumption rate on the input side of the fuel injection system, the fuel consumption rate on the injection output side of the fuel injection system, the throttle opening degree, the accelerator pedal position, and the fuel tank. Fuel consumption rate to the fuel supply pipe of the engine (or fuel injection pump);
  • the fuel dynamic parameters measured at the rear end of the engine (the fuel engine output shaft, the drive wheel, and the intermediate mechanical transmission components (including the drive shaft, transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel), Including drive torque, drive power, driving force, etc.
  • common fuel dynamic parameters include but are not limited to the following types: drive power, drive torque, driving force, fuel consumption rate, cylinder pressure, fuel-power combined parameters, etc.;
  • the description, calculations, and those skilled in the art understand the present invention.
  • the fuel power parameters of the present invention are generally converted into fuel power parameters of the fuel engine output (generally the output shaft) to participate in the calculation; of course, in practical applications, the user can also set Fuel power parameters for other parts;
  • Driving power value acquisition mode 1 Some engines can obtain the percentage of power through the engine load report data, and then multiply the maximum power of the engine to obtain the power value Pr1;
  • Driving torque value acquisition mode 1 obtaining a Tr1 value by measuring with a torque sensor
  • Drive torque value acquisition mode 3 Some engines can obtain the percentage of the maximum torque through the engine load report data, and then multiply the engine maximum torque to obtain the torque value;
  • the driving force value acquisition method obtaining the power value Pr1/ or the torque value Tr1 by the engine load report data, and dividing the torque value by the relevant radius to obtain the driving force Ff1 value of the fuel engine; dividing the power value by the linear running part
  • the speed can obtain the driving force; or directly measure the driving force with a force sensor;
  • Cylinder pressure value acquisition mode 1 The cylinder pressure sensor is used to obtain the value of the cylinder pressure F1; generally, F1 is converted into a fuel engine driving force Ff1 by averaging/filtering processing and the related efficiency coefficient, or F1 is converted into The driving torque Tr1 of the fuel engine; when the cylinder pressure F1 is an instantaneous value, attention must be paid to the combustion ignition phase; the fuel engine is usually a multi-cylinder engine, when the piston of a single cylinder is at the top dead center (or the engine combustion chamber space is the smallest) fuel ignition The instantaneous value of F1 generated during combustion is the largest, and the instantaneous value of F1 becomes smaller when the piston descends;
  • the fuel consumption rate is first obtained, it can be converted into the driving power Pr1 of the fuel engine by an energy conversion coefficient;
  • fuel power combined type parameter refers to the combination of fuel dynamic parameters according to the aforementioned parameters, the specific definition of which will be described later;
  • Hybrid parameters The hybrid parameters of the front end are usually the combination of the motor drive parameters and the fuel dynamic parameters of the front end; the hybrid power parameters of the back end are usually the combination of the back end electric power parameters and the back end fuel power parameters; the back end hybrid power
  • the parameters may also be the rear end of the vehicle (the power output shaft, the drive wheel, and the intermediate mechanical transmission component between the power output shaft and the drive wheel of the powertrain and the fuel power system (including the drive shaft, the transmission gear) Institutions, etc.)) an overall source power parameter measured on the component, which may include driving torque, driving power, driving force, etc., which may generally be measured by a torque sensor or other force sensor;
  • the source dynamic parameter described in the present invention includes at least one set of source dynamic parameters in the parameter content, and may also include multiple sets of source dynamic parameters;
  • the vehicle quality according to the present invention mainly includes the following parameters: the mass of the carried item m1, the data including the quality of the carried item, such as a vehicle.
  • the mass of the carried item m1 refers specifically to the mass of the loaded personnel other than the net weight of the vehicle, and may also be referred to as the mass of the vehicle. The obvious meanings of the two are the same, and the two are equivalent;
  • the empty vehicle mass m0 can be classified into the system inherent parameters in the system operation parameter group described later in the parameter type; the empty vehicle mass m0 can pass the manufacturer parameters. Or the weighing scale is accurately known, no need to measure; the mass change type item mf can be classified into the system operating parameters described later in the parameter type; in the calculation, the vehicle mass (m1 and / or m2) and the empty vehicle body The mass m0 and the mass change type item mass mf can be mixed and calculated;
  • the specific division of m1 and m0 can be determined by system or manual freedom; for example, the relatively fixed driving and in-vehicle service personnel of the electric bus can be classified into the empty vehicle mass m0, and can also be classified into the mass of the carried item m1. in;
  • m2, m1, m3, and m4 can be used as measurement objects;
  • m2 can be used as a direct measurement object
  • m1 or m2 can directly correspond to the mass of the person's load contained in the vehicle, it is easy for the driver and passenger to identify, such as m2 corresponding to the total mass of the vehicle.
  • the value of the total mass m2 of the vehicle is close to the empty body mass m0, and the value of m0 can be used instead of the value of m2 to calculate the vehicle motion balance.
  • the actual technical solution has not changed.
  • the system operation parameter group of the present invention refers to all parameters except vehicle quality and source power parameters in the vehicle operating parameters, and mainly includes the following three types of parameters: mechanical operation parameters, system inherent parameters, quality-changing item quality, It is essentially the underlying conditions and/or inherent properties of the power transmission of the vehicle and/or the parameters of the motion results (eg, speed, acceleration, etc.) produced by the vehicle under power; this inherent property refers to the inherent properties of the vehicle and/or the environment.
  • the quality of quality-changing items mainly includes the quality of fuel, so the calculation of fuel quality can be used to replace the quality of quality-changing items.
  • Fuels in fuel-powered vehicles mainly include gasoline, diesel, gas, etc.
  • fuels mainly include, but are not limited to: hydrogen, ethanol, hydrocarbon, methane, ethane, toluene, and butyl. Alkene, butane, proton exchange membrane, alkaline fuel, phosphoric acid, dissolved carbonate, solid oxide, direct methanol, other regenerative fuels, etc.;
  • the fuel refers to a type of energy supply; since the power device that directly drives the longitudinal operation of the vehicle is a motor, an electric vehicle powered by a fuel cell can be used. Still classified as an electric powered vehicle;
  • the fuel mass of the present invention includes any one or more of the remaining fuel mass mf0, the consumed fuel mass mf1, and the fuel mass mf2 of the historical record point;
  • Fuel cell power and fuel-powered hybrid vehicles include two fuel qualities, one for the fuel cell fuel (such as hydrogen), one for ordinary fuel (such as gasoline, diesel, etc.);
  • the mechanical operating parameter of the present invention is substantially a parameter of a variable parameter in a basic condition of power transmission of a vehicle and/or a motion result (such as speed, acceleration, etc.) generated by the vehicle under dynamic action, and is mainly included but not limited to the following Parameters: longitudinal velocity V x (also denoted by V1), longitudinal acceleration a (also denoted by V x ), road gradient ⁇ , wind resistance fw, front windward velocity V2, curve coefficient ⁇ , steering angle, comprehensive force factor coefficient Ka ⁇ , the angular acceleration ⁇ of the internal integrated rotating rigid body (which can also be represented by ⁇ 0), and the like.
  • Vx value acquisition method 1 directly obtain V x value by speed sensor measurement set on the vehicle body;
  • V x unit can be expressed in kilometers per hour (abbreviated as KM/H), and can also be expressed in meters per second (m/s) ;
  • All speed-related parameters can be used to obtain the V x value; such as the operating frequency FR of the power control device, the angular velocity of the power unit, the angular frequency of the power control device, the gear speed, the angular velocity of the intermediate rotating member, and the linear speed of the intermediate transmission;
  • the frequency FR has a certain correspondence with the engine speed n1, for example, the rated frequency of the frequency converter generally corresponds to the rated speed of the engine;
  • Vx value acquisition method 4 obtaining V x value through GPS and remote positioning information
  • a value acquisition method 1 directly measured by an acceleration sensor installed on the vehicle body; if the acceleration sensor output signal also contains the value of g*sin ⁇ , it can be combined: (g*sin ⁇ +a)
  • Pavement slope ⁇ the angle between the road surface or the track and the horizontal line of the vehicle; when the vehicle runs uphill: 90°> ⁇ >0°; sin ⁇ is a positive value, indicating that the kinetic energy is converted into potential energy, which is higher than the horizontal operation. Need to consume more power;
  • the slope ⁇ of the track for the electric locomotive can also be expressed by the road surface gradient ⁇ ;
  • ⁇ value acquisition mode 1 obtaining ⁇ value by direct measurement by a longitudinal inclination sensor or level set on the vehicle body;
  • ⁇ value acquisition method 2 ⁇ value of specific line and track at a specific position can be obtained through GPS information, or other pre-stored databases, network systems, etc.; especially for high-speed rail vehicles, motor vehicles and other rail locomotives, because the vehicle track trajectory is relatively fixed, The ⁇ value can be directly read according to the position information table by presetting a position information corresponding to the road surface slope ⁇ value (and/or the curve coefficient ⁇ and/or the rolling resistance coefficient f). (or together with ⁇ and / or f); for cars, this method can also be used if the path is a path that has been passed and has been learned;
  • Air resistance that is, the acquisition of wind resistance fw, can be as follows:
  • the actual V2 will be the sum of the vehicle longitudinal speeds V x and V0, at which time the vehicle running wind resistance fw increases; if the ambient wind speed air flow V0 and the vehicle running direction in the same direction, and the difference in longitudinal speed V x V2 V0 actual vehicle will, when the vehicle is operating to reduce drag fw; V2 so then obtain by obtaining the value of fw windage front face velocity, increases the cost, but the advantages of having a high measurement accuracy.
  • Fw value acquisition method 3 set an independent wind pressure or wind resistance sensor on the vehicle, directly measure the wind pressure or wind resistance per unit area of the vehicle during operation, and then calculate the wind resistance fw value through the correlation coefficient;
  • Fw value acquisition mode 4 pre-set a correlation table of vehicle longitudinal speed and wind resistance fw value, and when the vehicle is running, the corresponding wind resistance fw value is obtained by looking up the longitudinal speed value table;
  • the wind resistance fw When the vehicle is running at low speed, the wind resistance fw is small. When the vehicle speed is higher, the wind resistance is larger. Therefore, the measurement of the wind resistance fw plays a key role in monitoring the high-speed operation of the vehicle.
  • curve coefficient ⁇ refers to the vehicle's current running curve; when the vehicle turns, it will affect the driving force of the vehicle; in general, the greater the camber, the driving force also increases;
  • Different types of vehicles may have different ⁇ , ⁇ specific values, specific relationship between ⁇ angle and ⁇ value, which can be known by vehicle manufacturers, or professional testing institutions, or users to personally drive turning test; for simple calculation, in relatively straight or If the turning degree is less than the set angle (such as 30°), the curve coefficient ⁇ value can usually be set to 1, or directly ignore ⁇ and not participate in the calculation;
  • the acquisition method of the curve coefficient ⁇ 3 The ⁇ value of the specific line and the track at a specific position can be obtained through GPS information, or other pre-stored databases, network systems, and the like;
  • the angular acceleration of the internal integrated rotating rigid body ⁇ refers to the comprehensive conversion of all rigid mechanical rotating parts in the internal transmission system of the vehicle; the ⁇ parameter can be obtained by the speed sensor or by obtaining the speed of the power unit first. N1 or the longitudinal speed V x of the vehicle or the longitudinal acceleration a of the vehicle is calculated and obtained;
  • the system inherent parameter of the present invention refers to a parameter caused by a vehicle or an inherent property of the environment, and the inherent parameter of the system of the present invention may also be referred to as a system setting parameter;
  • Common system intrinsic parameters include, but are not limited to, the following: the empty body mass m0 of the vehicle (also referred to as the no-load inherent quality or the curvilinear mass or the empty vehicle mass), and the rolling resistance factor f (also available as ⁇ 1) Indicates), the integrated gear ratio im, the rear gear ratio im3, the drive wheel radius R1 (also denoted by R), the equivalent radius R0 of the engine output crank connected to the cylinder piston, the conversion coefficient of the torque current and the electromagnetic torque Ki , motor current active component and electromagnetic torque conversion coefficient Ko, mechanical transmission system efficiency coefficient Km, electric power system efficiency coefficient Kea, fuel power system efficiency coefficient or conversion coefficient Kfa, back end efficiency coefficient Km3, internal comprehensive rotation
  • the efficiency coefficient of the electric power system Kea includes and is not limited to the following parameters:
  • the efficiency coefficient of the motor Ke refers to the conversion efficiency of the electrical power of the motor to the mechanical power output of the motor shaft;
  • the efficiency coefficient k21 of the motor drive to the motor refers to the conversion efficiency of the input power of the motor driver to the electrical power of the motor when the motor operating condition is the electric state; also refers to the output power of the power source to the motor Conversion efficiency of electrical power;
  • the power factor to motor efficiency coefficient k31 refers to the conversion efficiency of the input power of the power source to the electrical power of the motor when the operating condition of the motor is the electric state;
  • the efficiency coefficient of the motor braking power to the power supply k14 the efficiency coefficient from the braking power of the motor to the power of the power supply device when the motor is in the braking state;
  • Km the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency:
  • Km the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency:
  • Km the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency:
  • Km the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency:
  • Km the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency:
  • Km the motor output shaft including the vehicle, the drive wheel, and the motor output shaft and the drive wheel.
  • Km the fuel engine output shaft of the vehicle, the drive wheel, and the intermediate transmission components between the fuel engine output shaft and the drive wheel.
  • Km Km (VX)
  • VX a one-dimensional function
  • Kfa efficiency coefficient or conversion coefficient of fuel power system Kfa: Because different fuel power parameters have different signal acquisition positions/acquisition methods; therefore, Kfa contains multiple subdivision parameters; for the convenience of description and understanding by those skilled in the art, The invention uses Kfa to summarize the efficiency coefficient or conversion coefficient of all fuel power systems; Kfa may specifically include Kf1, Kf2, Kf3...Kfn, etc.;
  • the fuel power parameter is the fuel consumption rate fm1 in the engine
  • the fuel power parameter is the fuel consumption rate fm2 of the fuel input end of the fuel injection system
  • the fuel power parameter is the air flow rate C1 of the fuel engine (and the C1 may be subjected to peak averaging or filtering, etc.)
  • the air flow rate C1 may be converted into a fuel engine by the energy conversion coefficient Kf4.
  • Drive power Pr1, then Pr1 C1 * Kf4; in general, the air flow C1 can only be used to calculate power in a gasoline engine because the air flow of the gasoline engine has a relatively fixed stoichiometric ratio with the fuel;
  • the gas manifold is not throttled and it is not convenient to calculate the power through C1;
  • the fuel power parameter is the load report data (torque value) Tr2 of the fuel engine (and the Tr2 may be subjected to peak averaging or filtering, etc.)
  • the series of filtering may be performed by the energy conversion coefficient Kf6.
  • the value of the dynamic parameter *Ka; the Ka value can be known by a combination of a type test, a finite number of manual trials, and other prior art; for example, obtaining a source dynamic parameter of a magnetic levitation vehicle and a corresponding coefficient Ka corresponding thereto
  • the preset value can be used to calculate the power of the magnetic levitation vehicle, and then the vehicle motion balance calculation formula can be established to calculate the vehicle motion balance.
  • the in-pipe train of the US Tesla Company can also be monitored by the technical solution provided by the present invention; it is obvious that the relevant corresponding coefficient Ka and/or the conversion coefficient Kfa can be either a single efficiency coefficient or a parameter including an efficiency coefficient. That is, a parameter composed of efficiency coefficients is a combined parameter including an efficiency coefficient; for example, by multiplying a certain source dynamic parameter of the motor (for example, motor current i1) by a corresponding coefficient or conversion coefficient (for example, Ka1). The driving force of the vehicle (for example, fq or Fx), then the Ka1 is a parameter including an efficiency coefficient;
  • the relevant efficiency coefficient k31, k21, k14, Ke, Km, Kfa value is basically constant within a certain speed and load interval;
  • the change of k31, k21, k14 value means that the internal rectifier bridge of the power supply or the motor driver, the IGBT may have a short circuit, or an open circuit, parameter variation and other abnormal conditions;
  • the change of the Ke value means that the internal rotating magnetic field parameter variation of the motor or the motor winding is short-circuited, or Variations that may cause serious consequences, such as a broken circuit;
  • the current, voltage and speed torque of the vehicle can be changed, but the basic values of k31, k21, k14, and Ke cannot be changed; therefore, the above k31, k21, k14, and Ke values are not only used as the efficiency coefficient of the electric power system, but also as the electric power. An important basis for the security status of the system;
  • the efficiency coefficient of the fuel power system or the value of the conversion coefficient Kfa is usually expressed as the efficiency of the fuel engine. If the engine pull cylinder or the piston sealing effect is deteriorated, the Kfa will decrease, so the Kfa value can also be used as the safety condition of the fuel power system.
  • the Kfa value can also be used as the safety condition of the fuel power system.
  • a change in the efficiency coefficient Km of the mechanical transmission system may represent severe wear in the mechanical transmission system of the vehicle including the power unit output shaft, the drive wheel, and the intermediate transmission member between the power unit output shaft and the drive wheel, or Variations that may cause serious consequences, such as deformation or gear embrittlement;
  • the mechanical torque speed of the vehicle can be changed, and even the frictional force can vary with the size of the load, but the basic Km value cannot be changed greatly, or it may be a serious fault; therefore, the Km value can be used not only as the efficiency of the mechanical transmission component.
  • the coefficient can also be used as an important basis for the safety condition of mechanical transmission components;
  • the vehicle can be effectively monitored.
  • Keem of the electric power system of a vehicle which includes both the efficiency coefficient Km of the mechanical transmission system and the efficiency coefficient Kea of the electric power system; the Keem value is the Km value of the vehicle and the efficiency coefficient value of the electric power system Kea Product of
  • a fuel efficiency system comprehensive efficiency coefficient Kfam of a vehicle which includes both the mechanical transmission system efficiency coefficient Km and the fuel power system efficiency coefficient Kfa; the Kfam value is the product of the vehicle Km value and the fuel power system efficiency coefficient value Kfa. ;
  • the efficiency coefficient represents the power component between the signal acquisition point of the source dynamic parameter for the vehicle motion balance calculation and the drive wheel and/or The efficiency of the transmission component; the power component and/or the transmission component is called the power transmission component to be monitored; the efficiency coefficient is also the energy transmission efficiency of the power transmission component to be monitored; because of the principle of energy conservation, if the efficiency coefficient is lowered, it means The energy transmission efficiency of the power transmission component to be monitored is reduced, that is, the internal loss is increased, the internal resistance or the resistance is increased, the heat is increased, the safety condition is deteriorated, and the like, and the risk of failure of the power transmission component to be monitored is increased.
  • the efficiency factor can be used to reflect and analyze the operating conditions of the power transmission components of the vehicle to be monitored, which in particular refer to wear and/or safety conditions.
  • the signal acquisition point of the source power parameter can be moved to the signal point in the front of the power system as much as possible, and the vehicle dynamic balance calculation can be used to monitor and protect a wider range of power components.
  • the sum of the rolling resistance, the slope resistance, the shifting resistance, and the power corresponding to the wind resistance, p2 is equal to the calculated power of the longitudinal dynamic equation (that is, the vehicle longitudinal motion balance calculation formula), that is, p2 can be calculated by the longitudinal motion balance of the vehicle; Comparing the calculated k with a preset value (usually a calibration value) of the energy conversion efficiency of the detection point to the driving wheel, thereby determining
  • k1 is the energy conversion rate of the energy supply device (eg, power source)
  • k1 energy supply device (eg Input power/output power of the power supply
  • k2 is the energy conversion rate of the power control device (eg frequency converter)
  • k2 output power of the energy supply device (eg power supply) / output power of the power control device (eg frequency converter)
  • the detection point is a power control device (such as a frequency converter) input point
  • k k2 * k3 * k4
  • k2 is the energy conversion rate of the power control device (such as the frequency converter)
  • k3 is the power device (such as the motor)
  • Energy conversion rate k4 is the energy conversion rate of the transmission system
  • the corresponding energy conversion rates of the corresponding subsystems are k41, k42, ..., k4N, and k4 is equal to the product of the respective energy conversion rates of the respective subsystems. ;
  • rolling resistance coefficient f refers to the rolling resistance coefficient of the rolling wheel (ie the wheel) and the road surface (or track) of the vehicle;
  • inflatable rubber tires can be used, which can be understood based on common knowledge, that is, the wheels of the vehicle are rubber wheels or rubber wheels; the rolling resistance coefficient f of the tire is also the rubber wheel.
  • the rolling resistance coefficient f, the rolling resistance coefficient f is mainly determined by the air pressure p1 of the tire, the wear condition kt of the tire, and the flatness condition kr of the road surface, and the value can be described by a mathematical function: f(k0, p1, kt, kr); K0 is the correction factor, p1 is the tire pressure, kt is the tire wear state, and kr is the road condition.
  • the reference value of the standard wear condition kt and the standard air pressure p1 and the standard road condition kr can be set by the vehicle manufacturer or a professional inspection agency.
  • the f-reference value of the vehicle may change slightly when the speed, load, and even the gradient change greatly.
  • the change of the f-reference may be corrected by setting different correction coefficients k0 in different speeds, loads, and road gradient intervals.
  • the change of the pavement leveling condition kr, or the change of the kt value of the wear condition, will result in a change in the f value; however, the kt change is a slow process that does not cause a sudden change in the f value; the change in the smoothness of the road surface kr causes a change in f, which can be passed The visual and simple identification and resolution of drivers and passengers.
  • the f value will be mainly determined by the tire pressure p1; under the same road condition, under the same load, when the tire pressure p1 is insufficient, the tire deformation is larger (the rounding degree is larger), then The larger the value of f, the greater the running resistance of the vehicle (the more likely it is to heat up and puncture at high speed); the principle is that circular objects are easy to roll, ellipticals are not easy, and polygonal diamonds, squares, and triangular objects roll more. difficult;
  • the f parameter is directly monitored as a measurement object, or the joint calculation value calculation of other measurement objects includes an f parameter for indirect monitoring, and the tire deformation (out of roundness) and/or the tire wear condition kt can be monitored during vehicle operation. So that the risk of a puncture can be warned in advance.
  • the gas leakage causes the tire deformation (roundness) to increase rapidly, and the tire air pressure p1 rapidly decreases, which may cause a large change in the joint calculation value of the measurement object, so the present invention is utilized.
  • the technical method is provided to quickly send out a precious warning signal at the moment of a puncture.
  • Orbital electric locomotives such as high-speed rail vehicles, motor trains, ordinary trains, subway trains, and tracked vehicles
  • the rolling resistance coefficient f is mainly caused by the rolling wheel itself. Or the friction coefficient and the wear condition between the track and the track; the rigid rolling wheel can not use the tire pressure monitoring technology of the inflatable tire at all, and usually only after the vehicle stops, the manual and sampling type ultrasonic detection is performed; therefore, the invention is more needed.
  • a technical solution is provided to monitor whether wheel deformation (out of roundness) and/or wheel wear condition kt is abnormal during vehicle operation; an increase in rolling resistance factor f generally means wheel deformation (roundness) and/or wheel The condition of wear increases weight.
  • the safety condition of the wheel refers especially to the deformation of the wheel (out of roundness) and/or the condition of wheel wear; any one or more of the rolling resistance coefficient f and the rolling resistance coefficient component fr related to the road condition.
  • the value of the parameter can also be measured by the sensor.
  • the current road surface condition for example, cement road, grass or the like
  • the rolling wheel is connected with a mechanical sensor to detect the softness and hardness of the current road surface to identify the rolling resistance coefficient f of the current road surface and/or the rolling resistance coefficient component fr related to the road condition;
  • the value of any one or more of the road gradient ⁇ , the rolling resistance coefficient f, and the rolling resistance coefficient component fr related to the road condition may be calculated based on the position information of the road.
  • Acquired or sensor measurement data acquisition; the location information may be acquired based on map information and/or satellite positioning and/or wireless network other than satellite positioning system; the solution may be applicable to any of the aspects of the present invention; vehicle related rolling resistance
  • the value of the coefficient component fc can be obtained according to a preset value; preset values of wheels of different specifications and different models can be different;
  • the overall transmission ratio im the overall transmission ratio im of most electric vehicles is a fixed value; the overall transmission ratio im of the fuel-powered vehicle usually varies according to the transmission gear position; if the integrated transmission ratio im is variable, then In the calculation, the current value needs to be given by the central controller; for the same reason, if the transmission ratio im3 of the back end is variable, the current value needs to be given by the central controller during the calculation; obviously, the system is inherently unspecified.
  • the parameter is usually given the current value by the system preset value; the current value is usually understood as a value close to or equal to the current true value.
  • the above integrated transmission ratio im refers to an integrated transmission ratio including an output shaft of the power unit, a driving wheel, and an intermediate transmission component between the output shaft of the power unit and the driving wheel;
  • the efficiency coefficient Km of the mechanical transmission system generally refers to the power device to the driving wheel.
  • the ratio of the parameter of the source power parameter of the back end to the drive wheel is called the efficiency coefficient Km3 of the back end.
  • the value of the inherent parameters of the system generally has a preset value (especially the preset value of the system), which can be given by the central controller of the vehicle. The correctness is also guaranteed by the central control of the vehicle; the system default value It can be known by vehicle production service providers and professional testing organizations; users can also test, verify, adjust and set up by themselves. If the deviation of the system preset value due to the parameter or even the error causes the monitoring effect of the monitoring method to decrease, the effectiveness of the technical solution is not affected;
  • the source power parameter has the highest priority; any parameter (including vehicle quality, system operation parameter) is combined with the source dynamic parameter to form a calculation expression.
  • the calculation expression becomes the source-power combination parameter, and the source-power combination parameter is also classified as the source dynamic parameter; depending on the type of the power system, the source-power combination parameter is also divided into the electric-power combination parameter and the fuel-power combination type.
  • Parameter, hybrid combination parameter among them
  • the aerodynamic combined parameters include electromechanical combined parameters and electric power combined parameters at the rear end;
  • An example of a typical electromechanical combination parameter is as follows: ((Ke*Km)*(k12*Po/V x ) represents a driving force calculated according to the motor power; eg (Te*im/R) represents an electromagnetic torque according to The driving force calculated by Te, such as (Te*n1/9.55/V x -fw), represents another driving force for removing the wind resistance calculated from the motor power, which is calculated by torque and speed;
  • (Km*Pr1/V x ) represents a driving force calculated according to the driving power Pr1 of the fuel engine; for example, (Tr1*im/R) represents a driving according to the driving of the fuel engine.
  • the source power combination type parameter has an infinite number of expressions, and the present invention is not exemplified;
  • the acquisition method of the source power combined type parameter value 1 obtain the value of the source dynamic power parameter in the source power combined type parameter by the foregoing manner, obtain the value of the other parameter in the source power combined type parameter by the foregoing manner, and further adopt the source power combined type Obtaining the value of the source power combination parameter by calculating the calculation formula of the parameter;
  • Mechanical combination type parameters When the parameters of the mechanical operation parameters, vehicle quality, and system inherent parameters are combined into a calculation expression containing mechanical operation parameters, the calculation formula becomes a mechanical combination type parameter, and the mechanical combination type Parameters are also classified as mechanical operating parameters;
  • (g*f*cos ⁇ +g*sin ⁇ +a) represents a comprehensive force factor associated with mass, and can also be called a coefficient X1 having a direct product relationship with mass, such as (m2*) g*f*cos ⁇ ) represents the rolling resistance of the vehicle.
  • (m2*g*sin ⁇ ) represents the slope resistance of the vehicle.
  • (m2*a) represents the shifting resistance of the vehicle, such as (m2*g*f*cos ⁇ +m2*) g*sin ⁇ +m2*a+fw) represents the comprehensive operational force of the vehicle; obviously, the mechanical comprehensive running force is the relevant resistance of the vehicle in the running direction; the related resistance includes rolling resistance, slope resistance, shifting resistance, and wind resistance. One of them, or includes the sum of any of rolling resistance, slope resistance, shift resistance, and wind resistance.
  • the method for obtaining the mechanical combination type parameter value 1 obtaining the value of the mechanical operation parameter in the mechanical combination type parameter by the foregoing method, obtaining the value of the other parameter in the mechanical combination type parameter by the foregoing manner, and further calculating the calculation formula of the mechanical operation parameter And obtaining the value of the source power combination parameter;
  • the calculation formula becomes a mass combination type parameter, and the mass combination type parameter is also classified into the vehicle quality; (m1+m0) ), (m2-m0), etc. belong to the vehicle quality; if the parameters such as m2*g, m1*g become the gravity of the object, but in the present invention, it is still classified as the vehicle mass, not the source power. parameter.
  • the power transmission condition correlation factor refers to a parameter directly or indirectly related to the determination of the power transmission condition of the vehicle.
  • the road condition information mainly refers to the road surface roughness and the road surface.
  • the index is high;
  • the load condition mainly refers to the condition of the vehicle loader or the item. If the person in the vehicle frequently beats or the item rolls freely in the vehicle, the good condition index is low; the position information according to the present invention can be GPS, digital map, etc.;
  • the vehicle is controlled by the power unit refers to a state in which the vehicle is controlled by the power unit alone, and the state usually does not include all “vehicle non-powered devices such as vehicle parking, flameout, neutral shifting, or mechanical braking”.
  • the state of control operation because it is not convenient to monitor the operation of the vehicle by collecting source power parameters and calculations during "vehicle non-powered device control operation”.
  • the "vehicle controlled by power plant” state or the “vehicle non-powered device control operation” state may be identified and given by the central controller of the vehicle; or may be obtained by acquiring the power plant operating state word or the power device control command word.
  • the "forward or reverse or stop” state of the driving state of the power device is recognized and judged, and the current state of the mechanical brake is used to identify the current state as "the vehicle is controlled by the power device” or "the vehicle is not controlled by the power device”.
  • a monitoring method for controlling a running time of a vehicle by a power device provided by the present invention, wherein the “vehicle controlled by the power device” may have a starting point and an ending point in time;
  • the length of each "the vehicle is controlled by the power unit” can be as long or as short as long as it is always in the "vehicle controlled by the power unit", which can be as long as several hours, as short as a few minutes or even seconds;
  • the period of time when the "vehicle is controlled by the power unit” is the same as the "operational flow” described in this article.
  • m1 Even in the same vehicle, during different time periods of "the vehicle is controlled by the power unit" (that is, in different operating procedures), certain parameters, especially the mass of the goods carried by the vehicle, m1 may change, such as the increase in passengers, m1 Naturally, if the passengers are reduced, the m1 will naturally become smaller. Assuming a 7-seat car with an empty body mass of 1500KG, the vehicle mass value may vary from 80KG to 560KG when the driver is alone and at full load;
  • the present invention provides a self-learning mechanism based on the vehicle motion balance according to the set conditions. Calculating the obtained joint operation value setting technical solution of the reference data, and can flexibly adjust the reference data by automatically following the normal change of the load, and is particularly suitable for the vehicle whose vehicle or item quality may vary greatly each time monitor.
  • the operating conditions of the power unit including the driving state of the power unit and the braking state of the power unit;
  • the driving state of the power device may be referred to as the electric state
  • the braking state of the power device is the motor braking state
  • the motor braking state includes the regenerative feedback generating braking and the energy braking
  • the power device of the vehicle is a fuel engine
  • the operating conditions of the power device are divided into a fuel engine driving state, a fuel engine braking state, and the like
  • the power device operating device The condition is divided into the driving state of the hybrid device, the braking state of the hybrid device, and the like;
  • the vehicles are all driven forward by the power unit under the control of the power unit.
  • Reversing is a very short process, and monitoring during reversing has little practical significance; of course, it is also possible to use the series of technical solutions provided by the present invention to perform related monitoring and protection during reversing.
  • the motor speed n1 and the longitudinal speed V X of the vehicle are all agreed to be positive values; (Electrical power, electromagnetic torque Te, torque current component iq, motor current Io) are positive values; the mechanical driving force calculated according to electrical energy is also a positive value, indicating that the motor is in a state of converting electrical energy into mechanical energy at this time;
  • each fuel power parameter is positive, indicating that the fuel engine is At a time when the fuel is converted into mechanical energy;
  • each hybrid power parameter is a positive value
  • each motor driving parameter (electric power, electromagnetic rotation)
  • the moment Te and the torque current component iq) are both negative values
  • the mechanical driving force calculated according to the electrical energy is also a negative value, indicating that the motor is in a state of converting mechanical energy into electrical energy at this time;
  • the power device of the vehicle is a fuel engine
  • the engine speed n1 and the longitudinal speed V X of the vehicle are still agreed to be positive values; if the fuel power parameter is passed through The moment sensor measurement must be agreed to a negative value;
  • the engine speed n1 and the vehicle longitudinal speed V X are all agreed to be positive values, if the hybrid parameter is the passing torque at this time.
  • the sensor measurement must be agreed to a negative value;
  • the method for identifying the operating conditions of the power unit provided by the present invention is as follows:
  • the current motor operating condition can be identified as: an electric state
  • the current motor operating condition can be identified as: motor braking state;
  • the operating condition of the motor can be naturally recognized according to the positive and negative of Te.
  • motor operating conditions identification method 4 Some models of motor drive devices, such as four-quadrant inverters, can also directly identify and determine the motor operating conditions by reading its internal status word.
  • the critical switching zone when the motor is in the critical switching zone of the electric state, it means that it is easy to enter the motor braking state;
  • the critical switching zone of the motor braking state when the motor is in the critical switching zone of the motor braking state, it means that it is easy to enter the electric state;
  • a critical state identification threshold Te_gate may be set, and when
  • the working condition is in the critical switching area;
  • the source dynamic parameter Positive and negative can identify the operating condition of the power plant of the vehicle; when the value of the source power parameter is positive, it can be judged that the operating condition of the power device is the driving state, and when the value of the source power parameter is negative, the operating condition of the power device can be judged It is a braking state; of course, if the fuel power parameter is a fuel consumption rate type parameter, it is inconvenient to measure the positive and negative, and the fuel engine braking state is also inconvenient to convert the vehicle body energy into fuel in reverse;
  • the operating condition of the power unit can also be identified; when the mechanical class is integrated When the value of the running force is positive, it can be judged that the running condition of the power device of the vehicle is the driving state, indicating that the vehicle needs to absorb the longitudinal driving of the power-driven vehicle indicated by the source power parameter; when the value of the comprehensive running force of the mechanical class is negative Determining that the operating condition of the power device of the vehicle is a braking state, indicating that the kinetic energy or potential energy of the vehicle can be fed back to the vehicle body or requires braking; when the absolute value of the comprehensive operating force of the mechanical class is lower than a preset threshold (such as rated When the value is 5-10%), it can be judged that the current power plant operating condition is in the critical switching zone, and the method can also be referred to as the critical switching zone identification method 6.
  • a preset threshold such as rated When the value is 5-100%
  • the information of the power plant control system (such as the OBD system of the fuel engine) can also be directly read to identify the operating conditions of the vehicle and the critical switching zone.
  • the pre-selected parameter is preferably For the source dynamic parameters and / or mechanical class comprehensive operating force.
  • the network system includes, but is not limited to, various wired or wireless mobile 3G, 4G networks, the Internet, the Internet of Things, the Internet of Vehicles, the traffic police network center, the operation management center, the vehicle fault diagnosis center, and the GPS.
  • Network in-vehicle network, local area network, etc.; network system can include corresponding human-computer interaction interface, storage system, data processing system, mobile APP system, etc.; personnel or institutions related to vehicle operation (such as driver and passenger, operation management party) , traffic police, fault diagnosis center) can monitor the vehicle health status in real time or afterwards through the network system.
  • the present invention is not a purely physical description document, but a technical solution that is prioritized as a collection of technical solutions and with vehicle motion balance calculation as the core; therefore, the basic technical solution and the technical approach of obtaining parameter values are used as the division data.
  • the priority of the type for example, the total mass of the vehicle m2, the mass of the carried item m1 is usually calculated by the vehicle's motion balance to obtain its true value (it is not convenient for frequent weighing measurement), so it is classified into the vehicle quality parameter; M0 because the value of this parameter can usually be conveniently determined by the system preset value, so it is classified into the system inherent parameter type; the fuel quality is constantly changing according to the measurement path, and usually needs to obtain its actual value according to the measurement path. So it is classified in the system operating parameters. Other parameters not described in the present invention may be classified according to the parameter value path and the technical characteristics.
  • the measurement object is any one of the parameters included in the vehicle operating parameter;
  • the vehicle operating parameter includes a vehicle mass, a source power parameter, and a system operating parameter, and the system operating parameter includes a mechanical operating parameter, a system inherent parameter, Quality change type of goods, etc.;
  • the joint operation value in the present invention is also the joint operation original value; the joint operation value of the present invention only represents a data type/or data acquisition path, and the value is calculated based on the vehicle motion balance calculation formula. There is no other meaning; there are infinitely many implementation formulas for calculating the joint operation value based on the vehicle motion balance calculation (such as Embodiment 1 to Embodiment 33, Equation 13.1 to Formula 13.6, Embodiment 41, etc. in the subsequent documents);
  • the joint operation values of the objects can be referred to the following embodiments:
  • the joint operation value or the non-joint operation value can be directly represented by the parameter name m1 or m2; when the measurement object is the source dynamic parameter Or when the system runs parameters, The expression of the joint operation value may be followed by a suffix after the parameter name: _cal; for example, the efficiency coefficient parameter name Km of the mechanical transmission system, and the joint operation value is represented by Km_cal; if the rolling resistance coefficient parameter name is ⁇ 1 or f, the joint operation The value is expressed in ⁇ 1_cal or f_cal;
  • the joint operation value of the present invention is equivalent to the theoretical value described in the Chinese patent application No. 201410312798.3; the quality of the vehicle described in the present invention is equivalent to the Chinese patent application with the application number 201410312798.3
  • the carrying quality in the present invention; the equivalent of the present invention includes the core properties of the two, the technical processing scheme equivalent, etc., and the two can be directly replaced;
  • the power device is a motor, and the vehicle is in a motor control operation state; the formulas in the following embodiments are all calculated based on the longitudinal dynamic equation of the vehicle; of course, other
  • the power device (such as a fuel engine, an air engine, etc.) may also be selected according to the corresponding power device to be applied to other types of vehicles;
  • M2 (fq2-fq1)/(a2-a1); (Formula A3-4-3);
  • M2 (KeKm(Te2-Te1)*im/R1)/(a2-a1); (Formula A3-4-4);
  • M2 Kem*(
  • M2 ((( ⁇
  • M2 (Kem*(
  • M2 (((-
  • Te_cal (m2*g* ⁇ 1*cos ⁇ +m2*g*sin ⁇ +m2*a+fw)/(im/R1), (Formula A10-1)
  • Kem_cal (m2*g* ⁇ 1*cos ⁇ +m2*g*sin ⁇ +m2*a+fw)/(Te*im/R1),
  • Kem_cal (Te*im/R1)/(m2*g* ⁇ 1*cos ⁇ +m2*g*sin ⁇ +m2*a+fw);
  • 11_cal ((-
  • k12 is a constant, and the value can be 1.732;
  • alternative calculation formula of k12*cos ⁇ *Uo*Io is as follows:
  • M2 ((Ke*Km)*(Te*im/R)–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 ((Ke*Km)*(P2o/V x )–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 ((Ke*Km)*(Te*im/R))/(g*f);
  • M2 ((Ke*Km)*(iq*Ki*im/R))/(g*f*cos ⁇ +g*sin ⁇ +a);
  • Embodiment 14 illustrates that (iq*Ki) in Embodiment 4 can be replaced by (Io*cos ⁇ 1*Ko) or (k21*I2o*cos ⁇ 2*Ko) or (k31*I3o*cos ⁇ 3*Ko),
  • M2 ((P2o_2/V x 2)-(P2o_1/V x 1))/(a2-a1);
  • P2o_1, V x 1, and a1 are the electric power, longitudinal speed, and longitudinal acceleration obtained when tim1 is respectively;
  • P2o_2, a2, and V x 2 are different from the vehicle operating parameters obtained when tim2 at the time point of tim1 (electrical Power, longitudinal velocity, longitudinal acceleration); and a2 ⁇ a1;
  • M2 (k31*(Ke*Km)*(P3i/V x )–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 ((Ke*Km)*(Te*im/R)–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 (-
  • M2 ((Ke*Km)*(Te1+Te2)*im/R–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • Embodiment 18 illustrates that, similarly, a vehicle in which N motors are driven in parallel can also be calculated by using the technique of this embodiment, such as replacing (Te1+Te2) of the present embodiment with (Te1+Te2+...+TeN). .
  • the operating condition is: ignore the fuel quality, and the default power plant operating condition is the power unit driving state; and the motor driving device is three parallel driving; P2i_1, P2i_2, P2i_3 are driven by the respective motors Input electrical power of the device;
  • M2 (k21*(Ke*Km)*(P2i_1+P2i_2+P2i_3)/V x –fw)/(g*f*cos ⁇ +g*sin ⁇ +a)
  • Embodiment 19 illustrates that, in the same way, a vehicle in which N plurality of motor drive devices are driven in parallel can also be calculated by using the technique of the embodiment, such as replacing (P2i_1+P2i_2+P2i_3) of the present embodiment with (P2i_1+...+ P2i_N).
  • Step 2.1 Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
  • Step 2.2 When the operating conditions of all the motors of the vehicle are in the electric state, perform the following vehicle motion balance calculation:
  • M2 (k31*(Ke*Km)*(P3i_1+P3i_2)/V x –fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • Step 2.3 When the operating conditions of all the motors of the vehicle are not all electric, the vehicle motion balance calculation can be aborted, and the output data of the previous period can be used instead of the output, or a status message of “multi-motor state inconsistency” can be output.
  • Embodiment 20 illustrates that, similarly, a vehicle in which N power supply devices are powered side by side can also be extended by the technology of this embodiment.
  • the calculation is as follows: (P3i_1+P3i_2) of the present embodiment is replaced with (P3i_1+...+P3i_N).
  • M2 (fq–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 (Pq/V x –fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • M2 ((Ke*Km)*(Te*im/R)–fw)/(g*f*cos ⁇ +g*sin ⁇ +a);
  • Km_cal (m2*(g*f*cos ⁇ +g*sin ⁇ +a)+fw)/(Ke*Te*im/R)
  • F_cal ((Ke*Km)*(P2o/V x )–fw-m2*(g*sin ⁇ +a))/(m2*g*cos ⁇ )
  • Fw_cal (Po_1+Po_2)*(Ke*Km)/V x -m2*(g*f*cos ⁇ +g*sin ⁇ +a);
  • Te_cal (m2*(g*f*cos ⁇ +g*sin ⁇ +a)+fw)/((Ke*Km)*im/R)
  • fr_cal the joint operation value fr_cal of the mechanical combination type parameter fr of the vehicle;
  • fr the vehicle driving force acting on the driving wheel including the wind resistance; (the operating condition is: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit);
  • Step 2.1 Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
  • Step 2.2 When the motor running condition is the motor braking state or the critical switching zone, the current calculation is aborted, and the calculation result output of the previous calculation cycle is taken;
  • Step 2.3 When the motor operating condition is electric,
  • Fr_cal ((Ke*Km)*(P2o/V x )–fw)
  • M2 ((Ke*Km)*(Te*im/R)/ ⁇ -(fw+fb+L0* ⁇ ))/(g*f*cos ⁇ +g*sin ⁇ +a)
  • Km_cal (m2*(g*f*cos ⁇ +g*sin ⁇ +a)+(fw+fb+L0* ⁇ ))/(Ke*Te*im/R/ ⁇ )
  • Step 2.1 Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
  • Step 2.2 When the motor operating condition is electric
  • M2 ((Ke*Km)*
  • Step 2.3 When the motor operating condition is the motor braking state
  • M2 (-
  • the calculation of the running parameters of the relevant vehicle can still be performed, and then the monitoring can be performed;
  • any measurement method, monitoring method, measurement system, and monitoring system provided by the present invention can also be measured or monitored when reversing.
  • Fx is the longitudinal driving force of the vehicle
  • the vehicle motion balance model that increases the braking force fb component is:
  • the vehicle motion balance calculation model or the vehicle motion balance model according to the present invention together with the mechanical vehicle balance model shown in the above-mentioned 13.1, 13.2, 13.3, and 13.4, plus the embodiment 1-33 provided by the present invention.
  • the vehicle motion balance and the longitudinal dynamic balance in the present invention refer to the balance between the power and the related resistance, including the constant speed operation state and the variable speed operation state.
  • X1 is a coefficient having a direct product relationship with the mass, and X1 includes the rolling resistance coefficient, the longitudinal acceleration, the longitudinal speed, and the road gradient of the vehicle. Any one or more of the efficiency coefficients of the mechanical transmission system;
  • Y1 is a component having no direct product relationship with mass, and Y1 includes the wind resistance of the vehicle. Both X1 and Y1 are system operating parameters of the vehicle; when the power unit that controls the vehicle is a motor, the source power parameter is the motor drive parameter.
  • the source dynamic parameter in the vehicle motion balance calculation of the present invention refers to the calculation formula, which may be on the left side of the calculation formula equal sign, or In the right side of the calculation formula equal sign; that is, it can be either the input parameter in the calculation or the output parameter in the calculation, that is, the measurement object itself; similarly, all the “calculations" in this paper can refer to the calculation.
  • the vehicle motion balance of the present invention refers to the longitudinal direction of the vehicle.
  • Dynamic balance the principle of vehicle motion balance is essentially a combination of energy conservation principle and/or Newton's law and/or vehicle operating characteristic factors; the energy conservation refers to the energy (or power) output by the vehicle's power system and the external power consumption of the vehicle's power system.
  • the energy (or power) is equal in magnitude, and/or the energy (or power) absorbed by the vehicle's powertrain is equal to the energy (or power) fed back outside the vehicle's powertrain;
  • the Newton's law refers to the vehicle's longitudinal dynamic balance;
  • the vehicle running characteristic means that the vehicle runs longitudinally along the road surface or the track under the control of the power system; for the wheeled vehicle, the wheel of the vehicle runs longitudinally along the road surface (or track), so the vehicle naturally has rolling resistance during operation (m2) *g*f*cos ⁇ ); if the vehicle is in direct contact with the road surface (or track) (eg magnetic suspension vehicle, etc.), the rolling system The number f is close to zero.
  • the vehicle motion balance refers to the longitudinal dynamic balance of the vehicle, that is, the balance between the dynamic direction and the related resistance of the vehicle in the running direction;
  • the related resistance includes rolling resistance, slope resistance, and shifting Any one or any of a variety of resistance and windage;
  • the formula for calculating the vehicle's motion balance is a formula describing the balance between the dynamic direction of the vehicle and the associated resistance in the running direction or a variant thereof; of course, the relevant resistance may also include other values below the preset value.
  • the running direction refers to the moving direction; it is obvious and unambiguous: the vehicle motion balance calculation formula at any place in the present invention is the vehicle longitudinal dynamics calculation formula, that is, the vehicle longitudinal dynamics equation, and the vehicle motion balance calculation at any place in the present invention is According to the longitudinal dynamics calculation formula of the vehicle, the calculation is based on the longitudinal dynamic equation of the vehicle.
  • the longitudinal dynamic equation of the vehicle in the present invention refers especially to the longitudinal driving dynamics equation of the vehicle;
  • the calculation parameter of *g*f*cos ⁇ ) includes the rolling resistance coefficient f, and the rolling resistance coefficient f is one of the core factors of the rolling resistance (m2*g*f*cos ⁇ ), and the calculation of the rolling resistance of the rolling resistance coefficient f is not considered.
  • the program has major flaws or is impossible to achieve. Only in vehicles with a non-mechanical contact between the vehicle and the road surface (or track) (such as a magnetic levitation vehicle) that differs significantly from the operational characteristics of the wheeled vehicle, the rolling resistance factor f is close to zero, which also results in rolling resistance (m2*g*). f*cos ⁇ ) is close to zero.
  • Tracked vehicles (such as tanks) are also a special type of wheeled vehicle that can be considered as a one-piece rigid wheel.
  • the vehicle is rolling longitudinally along the road (or track), as shown in Embodiment 2 and/or Embodiment 15 (ie, the two-speed differential vehicle motion balance calculation formula), based on two different time points.
  • the vehicle motion balance calculation formula of the difference of the obtained parameters is likely to eliminate the influence of rolling resistance (m2*g*f*cos ⁇ ), and the core principle of the differential vehicle motion balance calculation formula is still based on typical vehicle motion.
  • the calculation based on the vehicle motion balance generally refers to calculating another parameter according to any two parameters of the vehicle mass (usually the total mass of the vehicle), the source dynamic parameter, and the system operating parameter, and of course, the parameters participating in the calculation of the vehicle motion balance are also It may further include other data; that is, the principle of vehicle motion balance calculation, generally refers to calculating another parameter according to data including at least two of the vehicle mass (usually the total mass of the vehicle), the source dynamic parameter, and the system operating parameter.
  • the embodiment 10 and the embodiment 17 further include data such as the operating conditions of the power unit, when the operating condition of the power unit is the driving state of the power unit and when the operating condition of the power unit is the braking state of the power unit, the driving state is different.
  • the calculation method in the following formula 13.2, the parameters participating in the calculation of the vehicle's motion balance also include the braking force fb;
  • the joint operation value may be calculated according to the source dynamic parameter and the system operating parameter, and of course, the parameter required to participate in the calculation may further include other data; that is, when When the measured object is the vehicle mass, the joint operation value may be calculated according to data including at least the source power parameter and the system operating parameter.
  • the joint operation value may be calculated according to vehicle quality (usually the total mass of the vehicle) and system operating parameters, and of course, the parameters required to participate in the calculation may further include other data; that is, when When the measured object is a source dynamic parameter, the joint operational value may be calculated based on data including at least vehicle mass (typically total vehicle mass) and system operating parameters.
  • the joint operation value may be calculated according to vehicle quality (usually the total mass of the vehicle) and the source dynamic parameter, and of course, the parameters required to participate in the calculation may further include other data, such as Other system operating parameters than the object; that is, when the measured object is a system operating parameter, the combined operational value may be calculated based on data including at least vehicle mass (typically total vehicle mass) and source dynamic parameters.
  • the vehicle deformation calculation formula is used to obtain the corresponding table of the vehicle motion balance calculation formula. If the total vehicle mass m2 is fixed, the correspondence between the power and the system operating parameters (especially the mechanical operating parameters) is obtained by the vehicle motion balance calculation formula. Relationship, or when the power is a fixed value, according to the vehicle motion balance calculation formula lookup table, the corresponding relationship between the total vehicle mass and the mechanical operation parameter is obtained, or when the system operation parameter is a fixed value, the vehicle movement balance calculation formula is used to check the table.
  • One-to-one correspondence is derived from the correspondence between the total mass of the vehicle and the power, etc., based on the calculation formula of the vehicle motion balance, simplifying or ignoring certain parameters for calculation, and also a variant of the vehicle motion balance calculation formula, also within the scope of the inventive concept within.
  • the joint operation value is a result calculated based on the vehicle motion balance calculation formula, and the value of the measurement object is calculated based on the vehicle motion balance calculation formula, and the value is also a joint operation value.
  • One of the technical problems to be solved by the present invention is to provide a method for calculating vehicle operating parameters (#1), which can be used to reflect and analyze the wear and/or safety condition of a power transmission component to be monitored of a vehicle, and / or: wheel deformation (out of roundness) and / Or a condition in which the wheel is worn; and/or: a change in the overall gear ratio; and/or: a change in the radius of the drive wheel.
  • vehicle operating parameters (#1) can be used to reflect and analyze the wear and/or safety condition of a power transmission component to be monitored of a vehicle, and / or: wheel deformation (out of roundness) and / Or a condition in which the wheel is worn; and/or: a change in the overall gear ratio; and/or: a change in the radius of the drive wheel.
  • the invention provides a method for calculating vehicle operating parameters (#1):
  • the vehicle motion balance calculation formula is a formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or a variant thereof
  • the relevant resistance includes any one or any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; or: the related resistance includes one of rolling resistance, slope resistance, shift resistance, and wind resistance. Or include any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; and that is, resultant force;
  • the calculation method (#1) is a standard process for vehicle motion balance calculation, and may also be referred to as vehicle motion balance calculation for short;
  • the vehicle motion balance calculation formula and the calculation method and the parameter setting method can be referred to the content of any position in this document;
  • the formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or the deformation thereof includes: the power Fx, the rolling resistance f ⁇ , the gradient resistance f ⁇ , the shift resistance fa, Deformation of at least one of the wind resistances fw.
  • the deformation formula of F includes: (Kem*k12*cos ⁇ *Uo*Io)/Vx, (Km*Pr1)/Vx, (Km*fm1*Kf1)/Vx, ((Ke*Km)*(P2o/Vx) , ((Ke*Km)*(Te*im/R), Kem*k12*cos ⁇ *Uo*Io/Vx, (Kem*k13*Ui*Ii)/Vx, (Kem*k13*Ub1*Ib1)/ Vx, (Kem*Pm)/Vx;
  • Kem represents the comprehensive efficiency coefficient of electromechanical transmission
  • k12 is the preset constant
  • ⁇ power factor Uo motor voltage
  • Io is the motor current
  • Km is the efficiency coefficient of the mechanical transmission system
  • Pr1 is the driving power of the fuel engine
  • Vx is the vehicle.
  • the longitudinal velocity, fm1 represents the fuel consumption rate in the engine
  • Kf1 represents the energy conversion coefficient
  • Ke represents the efficiency coefficient of the motor
  • P2o represents the electrical output power of the motor
  • Te represents the electromagnetic torque
  • Pm represents the electrical power of the motor
  • im im represents the integrated transmission.
  • Ratio R represents the drive wheel radius
  • k13 represents the efficiency coefficient of the motor drive to the motor
  • Ui represents the input voltage of the motor drive
  • Ii represents the input current of the motor drive
  • Ub1 represents the output voltage of the power supply
  • Ib1 represents the power supply The output voltage
  • the deformation mode of the total mass m2 of the vehicle includes: m1+m0, m1+m0+mf2-mf1, and m1+m0+mf0, where m1 is the mass of the carried item, and m0 represents the mass of the empty body. Mf0 represents the remaining fuel mass, mf1 has consumed fuel mass, and mf2 represents the fuel quality at the historical point;
  • the formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or the deformation thereof further includes: the two sides of the equal sign are simultaneously integrated and deformed with respect to the same variable;
  • the integral deformation method includes: the integral of power for time is energy, the integral of force to displacement is energy, the integral of speed with respect to time is displacement, the integral of acceleration for time is speed, and the integral of force versus time is impulse.
  • the value of the input parameter in the obtained vehicle motion balance calculation formula is a reasonable value (also referred to as a qualified value or an acceptable value)
  • reasonable values of parameters (including input parameters) refer to the use of the parameter (including input parameters) to achieve a useful value or to represent the natural attributes of the parameter (including input parameters)
  • the power transmission condition identification, the vehicle power transmission abnormality, the monitoring, the reflection, the analysis of the operating condition (wear and/or safety condition) of the power transmission component to be monitored of the vehicle, and the analysis of the wheel deformation (loss) Roundness) and/or condition of wheel wear, monitoring of data related to vehicle operation safety, and processing of any data related to vehicle operation safety are all useful applications; parameters are current
  • the actual value, or the value in the third range, or the value in the fourth range is a value representing the natural attribute of the parameter (including the input parameter);
  • the value of the total mass of the vehicle included in the input parameter is set based on the current actual value of the total mass of the vehicle or a preset actual value, and the current actual value or the preset actual value is in the input parameter.
  • a reasonable value of the total mass of the vehicle included the meaning of the preset actual value of the parameter is: the value is a value close to the actual value of the parameter at a preset time point (not the current time point);
  • the meaning of the actual value preset in the present invention can also be understood as: the actual value of the parameter acquired at a preset time point (not the current time point); the meaning of the preset actual value in the present invention can also be It is understood as: the actual value of the parameter at the preset time point (not the current time point); the actual value of the vehicle total mass preset means: the value is at the preset time point (non-current) The actual value of the total mass of the vehicle at the time point is close to the value; it can also be understood as: obtained at a preset time point (not the current time point) The actual value of the total mass of the vehicle taken; it can also be understood as: the actual value indicating the total mass of the vehicle at a preset time point (not the current time point);
  • the value of the parameter in the first type parameter other than the total mass of the vehicle included in the input parameter is set based on the current actual value of the parameter, and the current actual value is the input parameter of the first type (
  • the first type of parameter refers to a parameter to be measured and/or a measurable parameter and/or a source dynamic parameter and/or a mechanical operating parameter and/or Any one or more of the types of quality-changing item quality; there is also a possibility that if the historical value of the parameter is different, the difference between the vehicle operating condition and the current vehicle operating condition is lower than a preset threshold And the historical record value is also a reasonable value of the first type of input parameter (eg, source dynamic parameter, speed, acceleration, etc.);
  • the value of the parameter in the second type parameter other than the total mass of the vehicle included in the input parameter is based on the current actual value of the parameter or the value in the safety range of the parameter or is set; generally speaking, The value in the security range of the parameter is set by the preset mode; the current actual value of the parameter or the value in the preset security range of the parameter is a reasonable value of the input parameter of the second type; in the present invention,
  • the second type parameter refers to any one or more of the unmeasurable parameters and/or the preset parameters and/or the system inherent parameters; for example, the efficiency coefficient, the rolling resistance coefficient, the integrated gear ratio, the driving wheel radius, and the gravitational acceleration are usually a parameter in the second type parameter; preferably, the value in the preset safety range is a preset calibration value;
  • the values of any one or more of the road gradient ⁇ , the rolling resistance coefficient f, and the rolling resistance coefficient component fr included in the input parameter may be calculated based on the position information of the road or Sensor measurement data acquisition;
  • parameters indicating the properties of the power system and/or the mechanical transmission system are referred to as closely related to safety in the power or transmission system.
  • Parameters for example, efficiency factor, rolling resistance coefficient, integrated gear ratio, drive wheel radius are all parameters related to safety in power or transmission system; abnormalities in integrated transmission ratio usually indicate severe failure of the mechanical transmission system of the vehicle, driving The abnormality of the wheel radius usually occurs when there are serious safety hazards such as tire puncture and radius reduction; in the present invention, the parameters closely related to safety in the power or transmission system belong to the second type parameter.
  • the calculation method (#1) also includes any one of the schemes A, B, and C:
  • the measurement object is a parameter closely related to safety in the power or transmission system or a parameter containing the parameter; the value of the input parameter is set according to a reasonable value of the input parameter; for example, the measurement object is an efficiency coefficient or includes efficiency
  • the parameter of the coefficient for example, in the embodiment 9, the efficiency coefficient Kem of the electromechanical transmission of the vehicle is measured; or (Kem(Te*im/R1)) is used as the measurement object, and the measurement object (Kem(Te*) Im/R1)) includes an efficiency coefficient Kem; for example, the measurement object is a rolling resistance coefficient or a parameter including a rolling resistance coefficient; for example, in the embodiment 10, the rolling resistance coefficient ⁇ 1 of the vehicle is used as a measurement target; 11*cos ⁇ ) is a measurement object, and the measurement object (g* ⁇ 1*cos ⁇ ) includes a rolling resistance coefficient ⁇ 1;
  • the value of the total mass of the vehicle included in the input parameters is set based on the preset actual value of the total mass of the vehicle, and is not set based on the current actual value of the total mass of the vehicle;
  • the values of other parameters other than those set are based on reasonable values of each parameter;
  • At least one of the power included in the input parameter or the safety-related parameter in the transmission system is set based on the preset value, and is not set based on the current actual value of the parameter, the preset value
  • the value in the preset safety range; the values of the parameters other than the safety-related parameters in the power or transmission system are set according to the reasonable values of the parameters.
  • the actual value of the total mass of the vehicle is inconvenient to measure during the operation of the vehicle; the actual value of the total mass of the vehicle may be preset by the operator according to the situation on the site, and the manual input method is adopted; Inconvenient, it is not conducive to improve calculation accuracy and safety monitoring; for example, if the input parameters include the total mass of the vehicle, assume that the vehicle's own weight is 1500KG and the load is limited to 500KG. If the vehicle's total mass value is set to 2000KG and 1600KG, in other input parameters. Under the premise of constant conditions, the results of vehicle motion balance calculation may differ by 25%, which will reduce the accuracy of vehicle motion balance calculation and the significance of safety monitoring;
  • the value of the total mass of the vehicle included in the input parameter is obtained based on a previously calculated vehicle motion balance calculation; that is, before the measurement method (#1) is performed, the vehicle is first used
  • the total mass is the calculated value of the vehicle motion balance calculation (this calculation is the previous calculation), and the value is usually the actual value of the previous calculation, and the actual value is used for the calculation method (#1) ) the vehicle motion balance calculation in step S2;
  • the safety range is The value is the calibration value; this is beneficial to improve the calculation accuracy and monitoring accuracy; because the safety range is the limit range, the upper and lower deviations are relatively large;
  • a preferred scheme 3 of setting scheme 2 in any of the A, B, and C schemes, at least one of the first type of parameters other than the total mass of the input parameters is set based on the measured value, such as source dynamic parameters, speed, and acceleration. And so on; preferably, the at least one is all.
  • the parameter closely related to safety in the power or transmission system is preferably an efficiency coefficient and/or a rolling resistance coefficient;
  • the efficiency coefficient can be used to reflect and analyze the running condition of the power transmission component of the vehicle to be monitored, This operating condition refers in particular to wear and/or safety conditions;
  • the rolling resistance factor f (especially the rolling factor component fc associated with the vehicle) can be used to reflect and analyze wheel deformation (out of roundness) and/or wheel wear conditions.
  • the efficiency factor and/or the rolling factor have a more important safety significance than the overall gear ratio and/or the drive wheel radius.
  • the measuring method (#1) may further include the following expansion scheme 1: outputting the calculated value of the measured object on the human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product; further, the expansion scheme 1 may further include: obtaining relevant data of the measurement object, and outputting relevant data of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product;
  • the measurement method (#1) may further include the following expansion scheme 2: outputting and/or saving the calculated value of the measurement object; further, the expansion scheme 2 may further include the following scheme: acquiring the measurement object Relevant data, the phase of the measured object Off data output and / or save;
  • the input parameter does not include the rolling resistance coefficient or the efficiency coefficient; the result of the calculation of the vehicle motion balance will be difficult to reflect the wear of the power transmission component to be monitored and / or safety conditions, wheel deformation (out of roundness) and / or wheel wear conditions;
  • KeKm the efficiency coefficient
  • S2 obtaining a reasonable value of each input parameter: for example, obtaining a value of the parameter to be measured (the measured value of the input parameter (Te2, a2) when time2 is acquired; and the measured value of the input parameter (Te1, a1) when time1 is acquired); Obtaining a preset standard value of the preset parameter (R1, im); obtaining an actual value of the total mass m2 of the vehicle; calculating the calculation according to the obtained value of the input parameter and the vehicle motion balance calculation formula (A3-5) The value of the object; the calculated value can be regarded as the actual value of the efficiency coefficient (KeKm) at time2;
  • the measurement object is a parameter closely related to safety in the power or transmission system or a parameter including the parameter, and the value is obtained based on the vehicle motion balance calculation formula, which is important for safety monitoring, monitoring, and data processing of the vehicle.
  • the measurement result can be used to reflect the condition of the rolling resistance coefficient (that is, the deformation of the wheel (out of roundness) and/or the condition of wheel wear); if the measuring object For the efficiency coefficient or the parameter including the efficiency coefficient, the calculation result can be used to reflect the wear and/or safety condition of the power transmission component to be monitored of the vehicle; if the measurement object is an integrated transmission ratio or a parameter including an integrated transmission ratio, the calculation The result can be used to reflect the condition of the integrated gear ratio.
  • the abnormality of the integrated gear ratio usually indicates a serious fault of the mechanical transmission system of the vehicle. If the measured object is the radius of the drive wheel or the parameter including the radius of the drive wheel, the calculation result can be used to reflect the radius of the drive wheel. Condition, the abnormality of the drive wheel radius usually occurs in the tire puncture, half Severe reduction in diameter When there is a safety hazard;
  • the value of the total mass of the vehicle included in the input parameter is set according to a preset actual value based on the total mass of the vehicle, and if the total mass of the vehicle is within the preset time point to the current time period Abnormal changes (such as abnormal jumps of the carrier and abnormal changes in the quality of the cargo) can be reflected by the vehicle motion balance calculation; if the total mass of the vehicle included in the input parameters is the current actual value based on the total mass of the vehicle The calculation result does not reflect the abnormal change of the total mass of the vehicle;
  • the vehicle motion balance calculation result of the measurement object can be used for a condition that reflects the efficiency factor (ie, the wear and/or safety of the power transmission components to be monitored);
  • the vehicle motion balance calculation result of the measurement object can be used to reflect the condition of the rolling resistance coefficient (that is, the wheel deformation (roundness) and/or the condition of the wheel wear);
  • the vehicle motion balance calculation of the measured object can be used to reflect the condition of the integrated gear ratio; even if the measured object non-driving wheel radius or the parameter containing the driving wheel radius, the value of the driving wheel radius included in the input parameter is a preset value (this value is preferably the calibration value) , the vehicle motion balance calculation result of the measurement object can be used to reflect the condition of the driving wheel radius;
  • the vehicle motion balance calculation The calculation results lose the ability to monitor the efficiency factor (ie, the wear and/or safety of the power transmission components to be monitored);
  • the The calculation result of the vehicle motion balance calculation loses the ability to monitor the rolling resistance coefficient (ie, the deformation of the wheel (out of roundness) and/or the condition of wheel wear);
  • the measured object is not the integrated gear ratio or the parameter including the integrated gear ratio, and the input gear does not include the integrated gear ratio or the integrated gear ratio included in the input parameter to obtain the current actual value as the value of the input parameter, proceed to the vehicle.
  • the calculation of the motion balance, the calculation result loses the monitoring ability for the integrated transmission ratio
  • the measured object is not a driving wheel radius or a parameter containing a driving wheel radius
  • the input parameter does not include the driving wheel radius or the driving wheel radius included in the input parameter to obtain the current actual value as the value of the input parameter for the vehicle
  • the calculation of the motion balance, the calculation result loses the ability to monitor the radius of the drive wheel
  • the wind resistance is used as the calculation object to calculate the wind resistance of the vehicle.
  • the vehicle motion balance calculation of the value of the calculation object not only need to understand the algorithm principle of vehicle motion balance calculation, but also need to study the characteristics of the input parameters, select the appropriate vehicle motion balance calculation formula, set the characteristics of the input parameters. In order to achieve unexpected security monitoring results.
  • optimization scheme of measurement method (#1) Preferably, referring to other contents in this paper, in the calculation method (#1), the following schemes for identifying the operating conditions to improve the calculation performance are also included. 1.
  • the fuel quality improvement calculation performance is obtained.
  • Scheme 1 the scheme of the two-speed differential-type vehicle motion balance calculation parameter, the preferred source power parameter is the motor drive parameter scheme 1, the preferred fuel-power parameter, the source power parameter scheme 1 or any one of the schemes To further improve the speed measurement accuracy and performance.
  • the measurement method is started after starting up or receiving a manual receiving operation instruction.
  • the measuring method can be started up automatically, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running can start immediately after power-on, or can be pre-processed. It can be run after setting the time.
  • the preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications.
  • the degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications.
  • the operation instruction is used to control the starting of the calculation method, and the operation button, the touch screen or other mobile electronic devices (such as mobile phones) in the vehicle are subjected to artificial Produced after the operation.
  • the measuring method can be used for discovering, monitoring the abnormality of the power transmission efficiency of the power transmission component to be monitored and/or the power transmission abnormality caused by the abnormal rolling resistance coefficient of the wheel; and can also be used for discovering and monitoring the power transmission component to be monitored.
  • the technical solution can be used for discovering, monitoring, and including the vehicle power transmission abnormality caused by the rotating working power of the vehicle or the running failure of the transmission component; even when the vehicle operating parameter does not exceed the safety limit threshold, the technical solution provided by the present invention can also It is convenient to avoid more serious and unpredictable safety accidents (including broken shafts, car crashes, etc.); like human cancer diagnosis, if it is found in the late stage, it usually means the end of life. If early warning and early detection usually mean Life is normal; therefore, this technical solution is heavy for the safe operation of the vehicle. Practical significance.
  • the calculation method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and each of the preferred schemes, the self-starting or the receiving manual operation Any one or more of the schemes after the instruction is initiated, and the uses and fields of the technical solution can be applied to the present invention to solve any of the problems raised in the present invention. solution.
  • the present invention also provides a measuring system for vehicle operating parameters, including the following modules,
  • the preset module of the motion balance calculation formula is configured to calculate the vehicle motion balance calculation formula of the measurement object by using any one of the vehicle operating parameters as a calculation object; the vehicle motion balance calculation formula is to describe the power of the vehicle in the running direction
  • the formula for the balance of the associated resistance or the formula of the deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; or: the related resistance includes rolling resistance, slope resistance, and shift resistance One of the wind resistances, or the sum of any one of rolling resistance, slope resistance, shift resistance, and wind resistance;
  • An input parameter acquisition and calculation module is configured to obtain a value of the input parameter, where the input parameter is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is calculated according to the vehicle motion balance calculation formula A parameter required for the value of the object; the value of the estimated object is calculated according to the value of the acquired input parameter and the vehicle motion balance calculation formula.
  • a second technical problem to be solved by the present invention is to provide a change (including a change in the rotational working power or transmission component operation failure of the vehicle and/or the overall transmission ratio even when the vehicle operating parameter does not exceed the safety limit threshold). / or the technical solution of monitoring the abnormality of vehicle power transmission caused by the change of the radius of the driving wheel;
  • the invention provides a monitoring method (#1) when a vehicle is controlled by a power device, and the monitoring method comprises the steps of:
  • the reference data determines whether the power transmission condition of the vehicle is abnormal; the joint operation value is a result calculated based on a vehicle motion balance calculation formula;
  • the vehicle motion balance calculation formula is a formula for describing a balance between the dynamic direction of the vehicle and the related resistance in the running direction or a deformation thereof;
  • the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; or
  • the related resistance includes one of rolling resistance, slope resistance, shift resistance, wind resistance, or includes any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; including, as well, at least; And can be understood as the combined force of multiple forces;
  • the input parameter of the vehicle motion balance calculation formula is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula;
  • the number of parameters in the input parameter to be measured is set, and the parameters are set based on the measured value; other parameters may be set by preset values; the more the measured parameters, the higher the accuracy will be, the better the monitoring performance is.
  • the measured parameters are less costly; the user and the manufacturer can customize according to their different situations.
  • the present invention provides the same monitoring method (#1) as the other, but describes another monitoring method (#2):
  • a method for monitoring the power transmission condition of a vehicle comprising the following steps A:
  • S200 Determine a vehicle motion balance calculation formula for calculating the measurement object;
  • the vehicle motion balance calculation formula is a formula for describing a balance between a power and a related resistance of a moving direction of the vehicle or a formula thereof;
  • the related resistance includes a rolling resistance, a gradient resistance, and a shifting speed Any one or any of a variety of resistance and wind resistance; or: the relevant resistance includes any one of rolling resistance, slope resistance, shift resistance, and wind resistance, or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
  • the inclusion is also understood to be at least; the sum can be understood as a resultant force; setting the number of parameters in the input parameter to be measured, obtaining the value of the input parameter, the input parameter being the vehicle motion balance calculation All the parameters except the measured object in the formula; and calculating the measuring object according to the value of the input parameter and the vehicle motion balance calculation formula; acquiring reference data of the measuring object in the current motion state of the vehicle;
  • S300 Compare and calculate the calculated value of the measurement object and the reference data of the measurement object, and determine whether the power transmission status of the vehicle is abnormal.
  • the vehicle motion balance calculation formula, the calculation method and the parameter setting method in the monitoring method (#1) or the monitoring method (#2) can be referred to the content of any position in this document;
  • the monitoring method (#1) or the monitoring method (#2) is started from the startup or started after receiving the manual instruction (referred to as manual startup).
  • the monitoring method can be started up automatically, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running may start immediately after power-on, or may be pre-evented. It can be run after setting the time.
  • the preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications.
  • the degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications.
  • the manual instruction is used to control the start of operation of the monitoring method, which is an operation button, a touch screen, a voice system, or other mobile electronic devices (such as a mobile phone) in the vehicle.
  • the monitoring method which is an operation button, a touch screen, a voice system, or other mobile electronic devices (such as a mobile phone) in the vehicle.
  • the option of starting from the start and starting manually is of great significance; because the monitoring method plays an important role in the operation safety of the vehicle, the self-starting is selected to avoid unfavorable factors such as forgetting to open and misuse, and it is beneficial to record the whole process.
  • Safety monitoring data in some cases, when the vehicle monitoring method is not adjusted, if you choose to start automatically, it may lead to adverse effects such as increased false alarm rate, so it is intentional to choose manual starting in some cases.
  • the values of the input parameters in the obtained vehicle motion balance calculation formula are all reasonable values (also referred to as qualified values); different input parameters have different reasonable values; for example, the value of the total mass of the vehicle included in the input parameters is Based on the current actual value of the total mass of the vehicle or the preset actual value, the current actual value or the preset actual value is a reasonable value of the total mass of the vehicle included in the input parameter; for example, in the input parameter
  • the value of the parameter included in the first type of parameter other than the total mass of the vehicle is set based on the current actual value of the parameter, and the current actual value is the input parameter of the first type (eg, the source dynamic parameter) a reasonable value of the speed, acceleration, etc.; for example, a parameter of the second type of parameter other than the total mass of the vehicle included in the input parameter (eg, efficiency coefficient, The value of the rolling resistance coefficient, the integrated gear ratio, the driving wheel radius, the gravitational acceleration, etc.) is based on the current actual value of the parameter or the value in the safety
  • the calculation method (#1) also includes any one of the schemes A, B, and C:
  • the measurement object is a parameter closely related to safety in the power or transmission system or a parameter including the parameter; the value of the input parameter is set according to a reasonable value of the input parameter;
  • the value of the total mass of the vehicle included in the input parameters is set based on the preset actual value of the total mass of the vehicle, and is not set based on the current actual value of the total mass of the vehicle;
  • the values of other parameters other than those set are based on reasonable values of each parameter;
  • At least one of the power included in the input parameter or the safety-related parameter in the transmission system is set based on the preset value, and is not set based on the current actual value of the parameter, the preset value
  • the value in the preset safety range; the values of the parameters other than the safety-related parameters in the power or transmission system are set according to the reasonable values of the parameters;
  • Preferred Embodiment 2 of Setting Scheme 2 Preferably, in the A, B, and C schemes, when the parameter in the second type parameter in the input parameter is set based on the value in the preset safety range, the safety range is The value is a calibration value; this is beneficial to improve calculation accuracy and monitoring accuracy;
  • a preferred scheme 3 of setting scheme 2 in any of the A, B, and C schemes, at least one of the first type of parameters other than the total mass of the input parameters is set based on the measured value, such as source dynamic parameters, speed, and acceleration. And so on; preferably, the at least one is all.
  • the safety-critical parameter closely related to safety in the transmission system is preferably an efficiency coefficient and/or a rolling resistance coefficient; compared to the overall transmission ratio and/or the driving wheel radius, the efficiency coefficient and/or The rolling resistance coefficient has a more important safety significance.
  • the measuring object is a parameter in the vehicle quality
  • the input parameter of the measuring object includes a system operating parameter and a source dynamic parameter
  • the measurement object is one of a source dynamic parameter, and the input parameter of the measurement object includes a system operation parameter and a vehicle quality; or
  • the measurement object is one of the system operation parameters, and the input parameters of the measurement object include a vehicle mass number and a source power parameter.
  • the measurement object is a vehicle quality, a source dynamic parameter, a mechanical operation parameter or a quality change type.
  • a parameter in the quality of the item, the reference value of the measured object is an actual value; or
  • the measurement object is any one of system inherent parameters, and the measurement object is a reference value of a system preset value.
  • the present invention provides the same monitoring method (#1) as the other, but describes another monitoring method (#3):
  • a method for monitoring the power transmission condition of a vehicle (#3) comprising the following steps:
  • the vehicle motion balance formula is a formula for describing a balance between a power fx and a related resistance of a moving direction of the vehicle or an equivalent deformation thereof;
  • the related resistance includes a rolling resistance f ⁇ , a gradient resistance Any one or more of f ⁇ , variable speed resistance fa, and wind resistance fw;
  • All the parameters except the measurement object in the vehicle motion balance formula are input parameters, obtain values of all input parameters, and calculate the measurement object according to the input parameter (value) and the vehicle motion balance formula; and obtain the calculation Reference data of the object; at least one of the reference data and the input parameter takes a preset value and determines a number of parameters of the input parameter that take a preset value;
  • the other parameters take the actual value.
  • the reference data of R1, im, and kekm are preset values, and all other parameters m2, a2, a1, Te2, and Te1 are actual values;
  • reference data of Ke, Km, R1, im, g, and f are preset values, and all other parameters Te3, fw, m2, ⁇ , and a are actual values;
  • Ke Km1, im1, R1_1, Km2, Kf3, R0, im2, and R1_2 are preset values, and the reference data of all other parameters Te, F1, fw, and m2 are actual values.
  • step S300 described in the monitoring method (#3) is a step S300 described in the monitoring method (#3).
  • the reference data takes a preset value, and the input parameters all take the actual value, and are used to monitor whether the power transmission condition of the vehicle is abnormal; wherein the preset value taken by the reference data is a historical record value in the same state as the current vehicle running state; the present invention
  • the history value in the same state as the current vehicle running state refers to the difference between the vehicle operating condition and the current vehicle operating condition when the value of the historical value is lower than a preset threshold;
  • the vehicle power transmission condition can be specifically a condition representing the part, for example, in the joint operation formula of kem in Embodiment 9, the reference data of the Kem The preset value is taken.
  • the reference data of m2 takes a preset value (such as self-learning), and the input is input.
  • the condition of the part described by m2 (such as whether the vehicle body is intact or the carrying item is dropped) can be monitored; as in the embodiment 11, the reference data of ⁇ 1 takes a preset value, and the input parameters are all taken practically. At the time of the value, it is possible to monitor the condition of the part represented by ⁇ 1 (such as whether the tire suddenly leaks).
  • the reference data takes the actual value, and one of the input parameters takes a preset value for monitoring whether the parameter of the input parameter takes the preset value is abnormal; the preset value of the parameter in the input parameter is the same state as the current vehicle running state.
  • the historical value under the vehicle is the calibration value when the vehicle is shipped.
  • the example 2 is taken as an example.
  • the reference data of m2 takes the actual value. If ⁇ 1 takes the preset value and the remaining parameters take the actual value, it can monitor whether ⁇ 1 is Abnormal; if the reference data of m2 takes the preset value, ki takes the preset value and the remaining parameters take the actual value, it can monitor whether ki is abnormal.
  • the delivery condition can be specifically representative of the condition of the component.
  • the reference data takes a preset value
  • N-1 of the input parameters take a preset value, which is used to monitor whether the parameter of the preset value is abnormal in the measurement object and the input parameter
  • the preset value of the reference data is The historical record value in the same state of the current vehicle running state, or the calibration value when the vehicle is shipped from the factory
  • the preset value taken by the two parameters in the input parameter is the historical record value in the same state as the current vehicle running state, or The calibration value of the vehicle when it leaves the factory; continue to use the example 2 as an example.
  • the reference data takes the actual value
  • N of the input parameters take a preset value, which is used to monitor whether the parameter of the input parameter takes the preset value is abnormal; wherein, the preset value of the N parameter in the input parameter is the current value
  • Embodiment 8 when the reference data of Te takes the actual value, and m2, ⁇ 1, im, and R1 of the input parameter take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2 ⁇ 1, im, and R1 are abnormal;
  • Te's reference data takes the actual value
  • m2, ⁇ 1, im, ⁇ , and R1 in the input parameters take the preset value and the remaining input parameters take the actual value
  • it is possible to monitor whether m2, ⁇ 1, im, ⁇ , and R1 are abnormal It should be understood that other situations regarding the relationship between the number of preset values and actual values in the reference data and the input parameters and the specific use may be performed by those skilled in the art based on the above description and specific embodiments, where I will not repeat them one by one.
  • the historical record value in the same state as the current vehicle running state refers to: the vehicle mass corresponding to the historical record value generation, the speed of the vehicle, the external environment information of the vehicle, and the source power.
  • the parameters are consistent with the current vehicle mass, the speed of the vehicle, the external environment information of the vehicle, and the source power parameters; the external environment information refers to environmental information other than the body of the vehicle that affects the running state of the vehicle, such as road gradient, wind speed, and road surface.
  • the coefficient of friction or the like; the agreement means that the sizes of the parameters are the same or close, and if the parameters have directions, the directions of the parameters are the same or close.
  • the step S300 includes any one of the following situations:
  • the value of the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory
  • the reference data of the measuring object is an actual value
  • the method can be used to reflect the abnormality of the rolling resistance coefficient (that is, caused by the wheel deformation);
  • the reference data of the measuring object is a calibration value when the vehicle is shipped from the factory;
  • the reference data of the measurement object is the actual value; the method can be used to reflect the efficiency coefficient (that is, the power system and/or mechanical transmission system abnormality Anomaly;
  • the reference data of the measurement object is a calibration value when the vehicle is shipped from the factory;
  • the measurement object is the vehicle running parameter except the rolling resistance coefficient, the parameter including the rolling resistance coefficient, the efficiency coefficient, and other parameters including the efficiency coefficient:
  • the value of the efficiency factor and/or the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory
  • the reference data of the measurement object is an actual value; correspondingly, the method can be used to reflect the efficiency coefficient and/or the rolling resistance. Anomalies in coefficients (ie, caused by abnormalities in the powertrain and/or mechanical transmission system and/or wheel deformation);
  • the reference data of the measurement object is a history value in the same state as the current vehicle running state.
  • the values of the other parameters except the rolling resistance coefficient in the input parameter are the calibration value or the actual value
  • the value of the other parameters except the efficiency coefficient in the input parameter is a calibration value or an actual value
  • the values of the other parameters except the rolling resistance coefficient and the efficiency coefficient in the input parameter are the calibration value or the actual value.
  • the step S300 further includes:
  • the determination result of the power transmission condition of the vehicle is correct, and further determining the power transmission status failure;
  • the input parameter includes a quality-changing item quality.
  • the step S200 further includes: acquiring a power device operating condition, and associating the power device operating condition with the calculation of the measurement object;
  • the energy/power transmission direction is transmitted from the power device to the vehicle body through the mechanical transmission system, and the value of the source power parameter is multiplied by an efficiency coefficient less than 1 when calculating the measurement object;
  • the energy/power transmission direction is transmitted from the vehicle body to the power unit via the mechanical transmission system, and the value of the source power parameter is divided by the efficiency coefficient less than 1 when calculating the measurement object. .
  • the step S400 further comprises: when the vehicle is in an unsteady driving state, the determining process of the power transmission condition of the vehicle is canceled; wherein, when the vehicle is powered The vehicle is in an unsteady driving state when at least one of the parameter, the mechanical comprehensive running force, and the speed is less than a preset threshold, or when the power running condition of the vehicle is the powering device braking state.
  • the preset range is set based on the reference data of the measurement object, and if the calculated value of the measurement object falls within the preset range, the determination center The vehicle power transmission condition of the vehicle is normal; if the calculated value of the measurement object does not fall within the preset range, it is determined that the vehicle power transmission condition of the vehicle is abnormal.
  • the step S400 further comprises the following steps:
  • the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) can also perform the following B step processing:
  • the joint operation value of the measurement object may include a direct joint operation value (that is, a directly obtained joint operation value), an indirect joint operation value (that is, an indirectly obtained joint operation value), and the like; for example, according to a source dynamic parameter of the vehicle and
  • the operating parameters of the system are calculated by vehicle motion balance to obtain the total mass m2 of the vehicle, then m2 is the direct joint calculation value; the carrier is calculated according to the total mass m2 of the vehicle.
  • the product quality m1 or the empty body mass m0, then m1 or m0 are indirect joint operation values; the joint operation value in the present invention may also be referred to as joint operation data, and the two are equivalent.
  • the joint operation value of the present invention is a value obtained by a joint operation for any one parameter (such as m2/ or m1/ or m0/ or mf); the actual value and the true value of the present invention are different concepts; the true value is usually The natural value of a certain attribute of an object; the actual value in the reference data in the monitoring method of the present invention generally refers to a value used as a reference for the determination of the power transmission condition, so it may also be referred to as a reference value. ;
  • the actual value (also referred to as the reference value) in the reference data in the monitoring method of the present invention must consider practical technical means or implementation scheme, and its value is naturally constrained to the specific value time and/or value.
  • Method according to the specific setting scheme of the reference data described later (such as the source of the data or the selection of the value path, the setting method, the value time, etc.), the general rules (reference data setting method 1, 2, 3, 4) 5, 6) and related embodiments (embodiments 34-43), it is obvious that the actual value in the reference data in the monitoring method of the present invention is different depending on the measurement object and/or the actual value setting mode.
  • the reference value has a variety of different time ranges, multiple different ranges, and can be implemented by a variety of different technical methods or schemes.
  • the following principle may be adopted: at least one of the reference data and the input parameter takes a preset value and determines a parameter number of the input parameter that takes a preset value; the preset value includes a calibration value or the same state as the current vehicle running state. History value under;
  • the reference data is preferentially an actual value or a preset value;
  • the preset value includes a calibration value or a history value in a state identical to the current vehicle running state;
  • the other parameters take the actual value.
  • the reference data of R1, im, and kekm are preset values, and all other parameters m2, a2, a1, Te2, and Te1 are actual values;
  • reference data of Ke, Km, R1, im, g, and f are preset values, and all other parameters Te3, fw, m2, ⁇ , and a are actual values;
  • Ke Km1, im1, R1_1, Km2, Kf3, R0, im2, and R1_2 are preset values, and the reference data of all other parameters Te, F1, fw, and m2 are actual values.
  • the reference data when only one of the reference data and the input parameter takes a preset value: the reference data takes a preset value, and all the input parameters take an actual value for monitoring whether the vehicle power transmission condition is abnormal;
  • the preset value obtained by the reference data is a historical record value in the same state as the current vehicle running state; in the present invention, the historical record value in the same state as the current vehicle running state refers to the value of the historical record value.
  • the difference between the vehicle operating condition and the current vehicle operating condition is lower than a preset threshold;
  • the vehicle power transmission condition can be specifically a condition representing the part, for example, in the joint operation formula of kem in Embodiment 9, the reference data of the Kem The preset value is taken.
  • the reference data of m2 takes a preset value (such as self-learning), and the input is input.
  • the condition of the part described by m2 (such as whether the vehicle body is intact or the carrying item is dropped) can be monitored; as in the embodiment 11, the reference data of ⁇ 1 takes a preset value, and the input parameter When all the actual values are taken, the condition of the part represented by ⁇ 1 (such as whether the tire suddenly leaks) can be monitored.
  • the reference data takes an actual value, and one of the input parameters takes a preset value for monitoring whether the parameter of the input parameter takes the preset value is abnormal; the preset value of the parameter in the input parameter is the current vehicle running state.
  • the delivery condition can be specifically representative of the condition of the component.
  • the reference data takes a preset value
  • N-1 of the input parameters take a preset value, which is used to monitor whether the parameter of the preset value is abnormal in the measurement object and the input parameter
  • the preset value of the reference data is The historical record value in the same state of the current vehicle running state, or the calibration value when the vehicle is shipped from the factory
  • the preset value taken by the two parameters in the input parameter is the historical record value in the same state as the current vehicle running state, or The calibration value of the vehicle when it leaves the factory; continue to use the example 2 as an example.
  • the reference data takes an actual value
  • N of the input parameters take a preset value, which is used to monitor whether the parameter of the input parameter takes the preset value is abnormal
  • the preset value of the N parameter in the input parameter is The historical value in the same state as the current vehicle running state, or the calibration value when the vehicle is shipped from the factory.
  • Embodiment 8 when the reference data of Te takes the actual value, and m2, ⁇ 1, im, and R1 of the input parameter take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2 ⁇ 1, im, and R1 are abnormal;
  • Te's reference data takes the actual value
  • m2, ⁇ 1, im, ⁇ , and R1 in the input parameters take the preset value and the remaining input parameters take the actual value
  • it is possible to monitor whether m2, ⁇ 1, im, ⁇ , and R1 are abnormal It should be understood that other situations regarding the relationship between the number of preset values and actual values in the reference data and the input parameters and the specific use may be performed by those skilled in the art based on the above description and specific embodiments, where I will not repeat them one by one.
  • the value of the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory
  • the reference data of the measuring object is an actual value
  • the method can be used to reflect the abnormality of the rolling resistance coefficient (that is, caused by the wheel deformation);
  • the reference data of the measuring object is a calibration value when the vehicle is shipped from the factory;
  • the value of the efficiency coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measurement object is actual. Value; this method can be used to reflect anomalies in the efficiency factor (ie, caused by abnormalities in the powertrain and/or mechanical transmission system);
  • the reference data of the measurement object is a calibration value when the vehicle is shipped from the factory;
  • the measurement object is the vehicle running parameter except the rolling resistance coefficient, the parameter including the rolling resistance coefficient, the efficiency coefficient, and other parameters including the efficiency coefficient:
  • the value of the efficiency factor and/or the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory
  • the reference data of the measurement object is an actual value; correspondingly, the method can be used to reflect the efficiency coefficient and/or the rolling resistance. Anomalies in coefficients (ie, caused by abnormalities in the powertrain and/or mechanical transmission system and/or wheel deformation);
  • the reference data of the measurement object is a history value in the same state as the current vehicle running state.
  • the values of the other parameters except the rolling resistance coefficient in the input parameter are the calibration value or the actual value
  • the value of the other parameters except the efficiency coefficient in the input parameter is a calibration value or an actual value
  • the values of the other parameters except the rolling resistance coefficient and the efficiency coefficient in the input parameter are the calibration value or the actual value.
  • the actual value (ie, the reference value) in the reference data in the monitoring method of the present invention is a value subordinate to the setting type of the measurement object and/or the actual value (ie, the reference value), which is an amplitude (size).
  • the concept is a middle layer data; the actual value (ie, the reference value) in the reference data in the monitoring method of the present invention is generally a value close to or equal to the true value of the measured object of the vehicle when the joint operation value is taken;
  • the range of amplitudes of the actual values (ie, reference values) in the reference data in the monitoring method can be applied to most types of measurement objects, such as source dynamic parameters.
  • the actual value (ie, the reference value) in the reference data in the method is set according to the actual value set in the same time range as the value of the joint operation value, that is, the reference value, that is, the The measured value is usually a value close to or equal to the true value of the measured object of the vehicle when the joint operation value is taken;
  • Embodiments 34, 35, 36, 37, 38, and 41 when the actual value (that is, the reference value) in the reference data in the monitoring method is set in accordance with the joint obtained according to (when the set condition is satisfied)
  • the actual value (that is, the reference value) is also naturally a value close to or equal to the joint operation value of "(a specific) meets the set condition"; because "(a specific "When the set condition is met” is the time specified by the user or the system (used to set the reference data).
  • the vehicle can work in the normal state at this time.
  • the actual value (that is, the reference value, that is, the joint operation)
  • the value is usually a value that is close to or equal to the true value of the measurement object when "(a specific) satisfies the set condition; the setting of the actual value (ie, the reference value) in the reference data in such a monitoring method)
  • the method is usually applied when the measurement object is the vehicle mass; when the measurement object is the vehicle mass, because it is in the same
  • the value of vehicle mass in the period of "the vehicle is controlled by the power unit” usually does not change much (the quality of high-speed rail, electric trains, plug-in electric vehicles usually does not change; even for fuel-powered vehicles or fuel cell vehicles, fuel quality) The change is also slow), so the value of the actual value (ie, the reference value) is usually still close to the true value of the joint calculation value of the vehicle's measurement object (obtained for the abnormality judgment of the power transmission condition). Or equal;
  • the actual value (ie, the reference value) in the reference data in the monitoring method is set according to the preset value (especially the system default value)
  • the actual value also That is, the reference value, that is, the system default value
  • the system default value is usually a value equal to or close to the true value of the measurement object in the system default (usually, the standard state), usually a calibration value; such reference data (calibration value)
  • the setting method is usually applied when the measured object is the inherent parameter of the system or the vehicle mass with fixed amplitude; when the measured object is the vehicle mass (usually applicable to the vehicle mass with fixed amplitude (such as unmanned vehicle, no one)
  • the value of the calibration value is usually still possible with the vehicle's measurement object (for The obtained value of the joint operation value obtained by abnormally determining the power transmission condition is close to or equal to the true value.
  • the joint operation value of the quality of the carried item can be represented by m1, and the actual value can be represented by m1_org or by m1_ref; for example, the joint operation value of the total mass of the vehicle can be represented by m2, and the actual value can be represented by m2_org;
  • the reference data of the measurement object refers to the data or value used for the comparison of the power transmission abnormality judgment with the joint operation value of the measurement object, because the single data cannot constitute a complete comparison/judgment operation; the joint operation value is calculated based on the vehicle motion balance calculation.
  • the formula calculates the result;
  • the reference data described herein may also be referred to as a reference value, which are equivalent;
  • the reference data described herein includes or is the power transmission condition identification data;
  • the power transmission condition identification data includes or is powered Passing any one or two of the difference between the status identification difference and the power transmission status identification value; for ease of description, the power transmission status identification value described herein may also be referred to as the second permission range;
  • the power transmission status identification described herein The difference value may also be referred to as a first permission range; obviously, the reference data of the measurement object or the data included in the reference data in the present invention are required to be set as a combination for the calculation object calculated based on the vehicle motion balance calculation formula.
  • the calculated value is combined with the data for the power transmission abnormality judgment; the reference data is real Reasonable data for the purpose; the reference data of the corresponding measurement object is set according to any one or more points in the setting method of the input parameter of the calculation object, the vehicle motion balance calculation formula, and the vehicle motion balance calculation formula.
  • the value of any one or more of the road surface gradient ⁇ , the rolling resistance coefficient f, and the road condition-related rolling resistance component fr included in the reference data or the input parameter may be based on the position information of the road. Calculated or sensor measurement data acquisition;
  • the vehicle's operation is essentially the energy transmission and power transmission process;
  • the short name of the power transmission process is the power transmission condition;
  • the energy supply device is first (fuel supply device or power supply device) transmits energy to a power device (fuel engine or motor), which converts energy into power, and then passes through the mechanical transmission system to drive the vehicle to move;
  • the energy supply device and power of the vehicle Device represents the supply of power
  • the mechanical transmission system represents the transmitter of the power
  • the driven vehicle (along with the loaded personnel and items) represents the power receptor;
  • the vehicle source dynamic parameter represents the supply information of the power
  • the vehicle mass represents the most basic attribute of the power receiver
  • the system operating parameters of the vehicle represent the basic conditions of the power transmission and the motion results generated by the vehicle under the action of the power (eg Longitudinal speed, longitudinal acceleration, etc.);
  • the abnormal loss of energy (or power) represented by the source dynamic parameters increases:
  • the monitoring system uses the source dynamic parameters as the measurement object, and may consume more energy or power when other relevant vehicle operating conditions (such as vehicle mass, road gradient, wind resistance, longitudinal speed, longitudinal acceleration, etc.) are constant.
  • vehicle operating conditions such as vehicle mass, road gradient, wind resistance, longitudinal speed, longitudinal acceleration, etc.
  • the deviation between the actual value of the source dynamic parameter and the joint operation value calculated by the vehicle motion balance is increased; if the monitoring system uses the longitudinal velocity in the mechanical operating parameter as the measurement object, such as the power output of the vehicle, that is, the actual value of the source dynamic parameter remains unchanged.
  • the efficiency coefficient and the rolling resistance coefficient are inconvenient to measure during vehicle operation, if the vehicle motion balance calculation formula includes the efficiency coefficient and/or the rolling resistance coefficient (especially for Fc), it can be used for the identification or monitoring of the power transmission status of the vehicle, that is, for power transmission abnormal monitoring; there are two ways:
  • Identification method 1 The efficiency coefficient or the parameter including the efficiency coefficient or the rolling resistance coefficient (especially fc) or the parameter including the rolling resistance coefficient is used as the measurement object, and the (usually preset) measurement object is used for power transmission.
  • a second range of condition recognition based on a vehicle motion balance calculation formula, obtaining a calculation result of the measurement object (that is, a joint operation value), and comparing whether the calculation result exceeds a second range; the calculation result exceeding the second range is a power transmission abnormality;
  • Identification method 2 or calculating a certain measurement object based on the vehicle motion balance calculation formula, and including the efficiency coefficient and/or the rolling resistance coefficient in the calculated input parameter, and calculating the calculation result based on the vehicle motion balance calculation formula Comparing the second range of power transmission condition identification, comparing whether the calculation result exceeds the second range; the calculation result exceeding the second range is a power transmission abnormality.
  • the two parameters are parameters that indicate the safety status of the vehicle.
  • the calculation formula of the vehicle motion balance for the purpose of monitoring the power transmission condition preferably includes rolling.
  • the power supply to be monitored includes an energy supply device (such as a power supply device, a fuel supply system) or a power control device (such as a motor drive device), it does not belong to a rotating state.
  • the power transmission conditions of the present invention include the operating conditions of the system in the vehicle related to the transmission of power and/or the conditions of the operating environment;
  • the system associated with the transmission of power in the vehicle includes power transmission components to be monitored and/or The two wheels; the drive wheels included in the second wheel and/or the transmission component may be referred to as wheels;
  • the operating conditions of the system associated with the transmission of power in the vehicle in particular The magnitude of the efficiency condition of the power transmission of the power transmission component to be monitored (ie the magnitude of the efficiency factor) and/or the rolling resistance coefficient of the wheel, in particular the rolling factor component fc associated with the vehicle therein.
  • the power transmission condition of the present invention is abnormal, including an abnormality of the operating condition of the system related to the transmission of power in the vehicle and/or an abnormality of the operating environment of the vehicle; an abnormality of the operating condition of the system related to the transmission of the power in the vehicle is Power transmission failure; anomalies in the operating conditions of the system related to the transmission of power in the vehicle include an abnormality in the efficiency of the power transmission of the power transmission component to be monitored, and/or an abnormality in the rolling resistance coefficient of the wheel (especially for the vehicle related thereto)
  • the rolling resistance coefficient component fc is abnormal);
  • a mechanical shaft or gear in the power transmission component to be monitored when a mechanical shaft or gear in the power transmission component to be monitored is broken or stuck, it means that the efficiency coefficient of power transmission is zero (complete failure); when the degree of wear exceeds the preset range, As the running resistance increases and the heat increases, the probability of failure of the mechanical shaft or gear will increase rapidly, and this feature can be measured and evaluated with an efficiency coefficient lower than a preset value used to measure early faults; for example, when the power to be monitored An electrical component (such as an IGBT module) in a transmission component, when it is short-circuited or broken or bombed, means that its power transmission efficiency coefficient is zero; when its internal resistance becomes larger than a preset range, its output power is reduced.
  • An electrical component such as an IGBT module
  • the abnormal rolling resistance coefficient of the wheel (especially the abnormality of the rolling resistance coefficient component fc related to the vehicle therein) generally means that the wheel deformation (out of roundness) exceeds a preset range and/or the wheel wear exceeds a preset range, and the rolling of the wheel can also be used.
  • the drag coefficient is higher than a certain preset value for measuring early faults to measure and evaluate; the rolling resistance coefficient of the wheel can also be used to reflect and analyze the operational safety of the vehicle, which are closely related;
  • the utility model provides a monitoring method (#1) or a monitoring method (#2) or a monitoring method (#3) and a system beneficial effect when a vehicle is controlled by a power device:
  • the technical solution provided by the present invention can be used to discover and monitor an abnormality of an efficiency coefficient of power transmission of a power transmission component to be monitored and/or an abnormality of power transmission caused by an abnormality of a rolling resistance coefficient of a wheel; Discovering, monitoring power transmission anomalies caused by failure of the power transmission components to be monitored and/or the second wheel, and/or for discovering and monitoring the power to be monitored
  • the technical solution provided by the present invention can be used for discovering, monitoring, and including the vehicle power transmission caused by the rotating working power of the vehicle or the operation failure of the transmission component Abnormal; that is, the technical solution provided by the present invention can be especially used for discovering and monitoring the rotating working type power of the vehicle or the running failure of the transmission component; the technical solution provided by the present invention can be facilitated even when the vehicle operating parameter does not exceed the safety limit threshold.
  • the technical solution provided by the invention not only facilitates abnormal monitoring of power transmission of the power system, the rotary working power or the transmission component; and the technical solution of the invention is compared with the prior art that the tire pressure monitoring is performed by the air pressure or the wheel speed change. It can include a monitoring scheme to detect changes in the operating force caused by tire deformation, provide a new safety monitoring technology for pneumatic tires, and fill the existing tire pressure monitoring scheme to make it difficult to monitor vehicles (such as high-speed rail vehicles, motor trains, and ordinary trains). , tracked vehicles, etc.) The monitoring blind zone of rigid wheels (including drive wheels).
  • the power transmission condition abnormality may be simply referred to as a power transmission abnormality
  • the power transmission abnormality of the present invention includes any one or more of the following 1A1, 1A2:
  • the difference between the joint operation value of the measurement object and the actual value exceeds the first permission range (that is, the power transmission condition recognition difference value); in any aspect of the present invention, in order to facilitate the present invention
  • the measurement object is any of the unmeasured parameters and/or the preset parameters and/or the system inherent parameters
  • the reference data of the measurement object is or includes the actual value (ie, the reference value)
  • This actual value also allows replacement with the calibration value
  • the joint operation value of the measurement object exceeds the second permission range (that is, the power transmission status identification value);
  • the setting principle and setting manner of the power transmission condition identification data used for the power transmission condition determination are the same; the second permission range (that is, the power transmission status identification value, that is, the identification range of the power transmission status) can be calculated according to the calculation.
  • the actual value of the object that is, the reference value
  • the second permission range can be set according to the actual value (that is, the reference value); the second permission range can be as close as possible
  • the actual value ie, the reference value
  • the value is the first permitted range (that is, the power transmission condition identification difference, that is, the identification difference of the power transmission condition, that is, the first deviation value);
  • the power transmission anomaly that is, the calculation result based on the vehicle motion balance calculation formula exceeds a preset range
  • the range is the second permission range, that is, the range for identification of the power transmission condition, that is, for analysis Identifying the range of operating conditions of the system related to the transmission of power in the vehicle;
  • the measurement object is any one of a parameter to be measured and/or a measurable parameter and/or a source dynamic parameter and/or a mechanical operation parameter and/or a quality change item quality: the measurement object Reference data includes actual values or actual values, or the reference The test data includes an actual value and a first license range, or the reference data is an actual value and a first license range, or the reference data includes a second license range or a second license range;
  • the measurement object is any one of unmeasured parameters and/or preset parameters and/or system inherent parameters:
  • the reference data of the measurement object includes a second permission range or a second permission range; and the second permission range is a joint operation value setting obtained according to the preset value or the vehicle motion balance calculation performed when the set condition is satisfied;
  • the reference data includes a calibration value or a calibration value
  • the calibration value is a joint operation value setting obtained according to a preset value or a vehicle motion balance calculation performed when the set condition is satisfied;
  • the reference data includes a calibration value and a first permission range, or the reference data is a calibration value and a first permission range; the first permission range is set according to a preset value; and the calibration value is according to a preset value or a satisfaction setting.
  • the joint operation value obtained by calculating the vehicle motion balance calculated when the condition is determined;
  • the reference data of the measurement object includes an actual value or an actual value, or the reference data includes a second permission range or a second permission range, or The reference data includes an actual value and a first permitted range, or the reference data is an actual value and a first permitted range;
  • the actual value of the vehicle quality can be set in various ways; for example, the actual value of the mass of the carrying item m1 or the total mass m2 of the vehicle that is manually operated by the manual input; the actual value can also be set according to the measured value; for example, setting on the vehicle
  • Any one or more of the actual value of the vehicle mass and the second permitted range is set according to the joint operation value obtained by calculating the vehicle motion balance calculated when the set condition is satisfied; or
  • the second permitted range of the measurement object may be calculated according to the actual value (ie, the reference value) of the measurement object and the first permission range (ie, the power transmission condition recognition difference value), or
  • the first permitted range ie, the power transmission condition identification difference value
  • the power transmission anomaly includes 1A1, which is equivalent to 1A2 in terms of actual technical solutions and effects, except that the parameter input values are different and the description manners are different;
  • One of the core ideas of the present invention is to compare (real-time) the joint operation value of a certain measurement object with the reference data set according to the actual value (that is, the reference value) of the measurement object, and process the determination result in real time;
  • the reference data 2 (which may also be referred to as second reference data), which may include the power transmission condition identification data, is set according to the joint operation value, and the reference data 2 (ie, the second reference data) is further calculated.
  • the power transmission condition identification difference value (that is, the first permission range) includes any one or more of a power transmission condition recognition upper limit difference and a power transmission condition recognition lower limit difference; and the power transmission status identification value ( That is, the second permission range includes any one or more of the power transmission condition recognition upper limit value and the power transmission condition recognition lower limit value; and the excess (ie, exceeding) of the present invention includes greater than a certain upper limit value and less than Any one or more of a certain lower limit value; for the sake of simplicity of description, the upper limit difference of the power transmission condition identification in this paper may also be referred to as the first permissible upper limit value, and the difference in the lower limit of the power transmission condition identification may also be referred to as the first The permissible lower limit value, the power transmission status identification upper limit value may also be referred to as a second permissible upper limit value, and the power transmission status identification lower limit value may also be referred to as a second permissible lower limit value;
  • the case of the 1A1 may specifically include any one or two of the following 1A11 and 1A12;
  • the difference between the joint operation value of the measurement object and the actual value is greater than the power transmission condition recognition upper limit difference (that is, the first permission upper limit value);
  • the difference between the joint operation value of the measurement object and the actual value is less than the difference between the lower limit of the power transmission condition recognition (that is, the first permission lower limit value);
  • the case of the 1A2 may specifically include any one or two of the following 1A21 and 1A22;
  • the joint operation value of the measurement object is greater than the upper limit value of the power transmission condition recognition (that is, the second permission upper limit value);
  • the joint operation value of the measurement object is smaller than the power transmission condition recognition lower limit value (that is, the second permission lower limit value);
  • determining whether the power transmission condition of the vehicle is abnormal may include any one or more of the following methods:
  • the reference data of the measurement object includes a first permission upper limit value and an actual value (ie, a reference value); and determining whether a difference between the joint operation value of the measurement object and the actual value (that is, the reference value) is greater than the first permission upper limit value;
  • the reference data of the measurement object includes a first permission lower limit value and an actual value (that is, a reference value); and determining whether a difference between the joint operation value of the measurement object and the actual value (that is, the reference value) is less than the first permission lower limit value;
  • the reference data of the measurement object includes the actual value (that is, the reference value); determining the actual value (or calibration value) of the measurement object is No greater than the upper limit set according to the joint operation value;
  • the reference data of the measurement object includes an actual value (ie, a reference value); and whether the actual value (or the calibration value) of the measurement object is less than a lower limit value set according to the joint operation value;
  • the reference data of the measurement object includes a second permission upper limit value; determining whether the joint operation value of the measurement object is greater than the second permission upper limit value;
  • the reference data of the measurement object includes a second permission lower limit value; and whether the joint operation value of the measurement object is smaller than the second permission lower limit value.
  • the measurement object is any of the unmeasured parameters and/or the preset parameters and/or the system inherent parameters
  • the measurement object is or includes the actual value ( This actual value also allows replacement with the calibration value when the reference value is also used.
  • the invention allows the power transmission condition identification value (that is, the second permission range) of the measurement object to be within the range of the safety limit threshold of the measurement object; it can be broken by the prior art that the vehicle operation parameter does not exceed the safety limit threshold.
  • Example 1 Example 2 below, which is the preferred rule set by the value range of the reference data;
  • Example 1 If the vehicle longitudinal velocity is the object of measurement, assume that its (upper limit) safety limit threshold is 200KM/H (obviously, this value is the maximum value of the safety limit threshold; the minimum value of the safety limit threshold of this parameter is usually 0) ;), assuming that the vehicle is running at a longitudinal speed of 60KM/H, the actual value is usually set to 60KM/H, and the power transmission condition identification difference is usually set to be between 10-20KM/H, and the power transmission condition recognition upper limit is The value (that is, the second permissible upper limit value) is usually set to be between 70-80KM/H, and the power transmission condition recognition lower limit value (that is, the second permissible lower limit value) is usually set to 40-50KM/H.
  • the power transmission condition judgment result will be abnormal, so that the monitoring protection can be realized; at this time, the measurement object is far from exceeding the safety limit threshold (obviously, that is, the power transmission condition identification upper limit value of the measurement object at this time (also On the second license Value) is much smaller than the maximum safety limit threshold value 200KM / H; at this time the power of the estimated state of transmission of object recognition lower limit value (i.e., a second permission lower limit value) is much higher than the safety limit minimum threshold 0);
  • the source dynamic parameters, the mechanical operating parameters, and the mass-changing item qualities have the same feature type (both of which are measurement objects whose amplitudes may vary greatly), and may be used as classes.
  • the same reference data setting method for example, the reference data can be set by the measured value
  • the measurement object is the source dynamic parameter and the mass variation type quality of the same feature type (the amplitude may vary greatly)
  • the maximum value is set such that the power transmission condition recognition lower limit value (that is, the second permission lower limit value) of the measurement object is higher than the minimum value of the safety limit threshold value.
  • Example 2 If the vehicle carrying mass (that is, the mass of the carried item) is the object of measurement, the safety limit threshold of the upper limit is assumed to be limited to 7 people/560KG (obviously, this value is the maximum value of the safety limit threshold; Minimum limit in safety limit threshold Often 0;), assuming the actual load of the vehicle is 4 people / 320KG, the actual value is usually set to 320KG, then the power transmission status identification difference (that is, the first permission range) is usually set between 80-160KG.
  • the power transmission condition recognition upper limit value (that is, the second permission upper limit value) is usually set to 480 KG, and the power transmission condition recognition lower limit value (that is, the second permission lower limit value) is usually set to 160 KG;
  • the joint operation value of the vehicle carrying mass is greater than the power transmission condition identification upper limit value (ie, the second permission upper limit value) or less than the power transmission condition recognition lower limit value (ie, the second permission lower limit value), and the power transmission condition The judgment result will be abnormal, so that the monitoring protection can be realized; at this time, the measurement object is far beyond the safety limit threshold (obviously, that is, the upper limit of the power transmission condition identification of the measurement object at this time (that is, the second permission upper limit) The value is far below the maximum value of 560KG in the safety limit threshold; at this time, the power transmission condition recognition lower limit value (that is, the second permission lower limit value) of the measurement object is much higher than the minimum value (0KG) of the safety limit threshold value;
  • the method of setting the value range of the same reference data can naturally be adopted;
  • the minimum value of the safety limit threshold of the total mass of the vehicle is usually the value of the empty body mass m0.
  • the maximum of the safety limit thresholds for the total mass of the vehicle is typically the sum of the maximum of the safety limit thresholds for the mass of the carried item and the m0 value of the empty body mass.
  • the sum of the power transmission condition identification upper limit difference (that is, the first permitted upper limit value) and the actual value (or the calibration value) is less than the maximum value of the safety limit threshold, that is, the power transmission condition recognition upper limit difference (also That is, the first allowable upper limit value is smaller than the difference between the maximum value and the actual value (or the calibration value) in the safety limit threshold; preferably, the absolute value of the upper limit difference of the power transmission condition recognition is as small as possible; the sensitivity of the monitoring can be improved , but the absolute value should not be too small to reduce the false trigger rate of monitoring; preferably, the sum of the lower limit of the power transmission condition identification (that is, the first lower limit value) and the actual value (or the calibration value) is greater than the safety value.
  • the minimum value of the limit threshold that is, the power transmission condition identification lower limit difference (that is, the first permission lower limit value) is greater than the difference between the minimum value and the actual value (or the calibration value) of the safety limit threshold; preferably, the power transmission condition
  • the power transmission condition recognition upper limit value (that is, the second permission upper limit value) is greater than the actual value; preferably, the power transmission condition identification upper limit value (that is, the second permission upper limit value) is smaller than the safety limit threshold value.
  • the maximum value generally, the power transmission condition recognition lower limit value (that is, the second permission lower limit value) is smaller than the actual value (or the calibration value); preferably, the power transmission condition identifies the lower limit value (that is, the second permission)
  • the limit value is greater than the minimum value of the safety limit threshold; that is, preferably, when the reference data includes or is the second permission range, the second permission range is within the safety range; further, the power transmission condition recognition upper limit The closer the value (ie, the second permissible upper limit) and/or the lower limit of the power transmission condition identification (ie, the second permissible lower limit) to the actual value (or the calibration value), the sensitivity of the monitoring can be improved, but A certain amount of difference must be maintained with the actual value to reduce the false trigger rate of the monitoring;
  • Step B in the monitoring method (#1) or the monitoring method (#2) is also one of the important steps of the power transmission abnormality monitoring scheme of the present invention; abnormal power transmission during vehicle operation may cause a serious safety accident, and needs timely response processing;
  • the power transmission abnormality processing mechanism of the present invention includes, but is not limited to, a voice prompt alarm, an acousto-optic alarm, a selective execution of a protection action according to a current operating condition of the vehicle, a startup power transmission failure monitoring mechanism, and an alarm information output to the vehicle owner.
  • the power transmission abnormality processing mechanism of the present invention may also be referred to simply as a security processing mechanism.
  • the alarm information of the present invention may include, but is not limited to, time, location, cause of the alarm, value of any one or more vehicle operating parameters during the alarm, and the like;
  • the selective execution of the protection action according to the current operating condition of the vehicle means that when the joint calculation value of the vehicle measurement object has exceeded the reference data of the measurement object, the system first checks the current operation measurement condition of the vehicle and then performs the related action; Not limited to subordinates:
  • Case 1 Check whether the reference data is set correctly; if the reference data is not set correctly or is not set, the related alarm information is masked and no protection action is performed;
  • Case 2 Check whether the value of each input parameter in the calculation of the joint operation value is within the preset time range; if the preset time range is exceeded, such as 1 millisecond, the related alarm information is masked and output is not executed. Protection action
  • the output of the present invention includes outputting data to an in-vehicle human-machine interaction interface, a network system, a connection port, an external control system, a mobile APP system, etc.; in particular, when the monitoring method/system provided by the present invention is independent of When the vehicle's control/drive system is used, it is more necessary to output the data to an external control/drive system to process the abnormal information in time; the human-computer interaction interface includes a display, a voice system, an indicator light, etc.; the connection port is available to an external person.
  • the machine interaction interface, the network system reads data directly or in a communication manner, so that personnel or institutions related to vehicle operation (such as drivers and passengers, operation management parties, traffic police, and fault diagnosis centers) can directly or indirectly view the listening and monitoring. data.
  • the saving of the present invention includes saving the data into a monitoring module, an in-vehicle storage system, a network system, an external control system, a mobile APP system, etc.; to enable the vehicle to operate related personnel or institutions (such as drivers and passengers,
  • the operation management party, the traffic police, and the fault diagnosis center can arbitrarily retrieve and monitor the data
  • the in-vehicle storage module includes a U disk, a hard disk, etc.; it can form a function similar to the aircraft black box, which is convenient for post-mortem analysis.
  • Obtaining the joint operation value of the measurement object may be implemented by using multiple acquisition methods; for example, reading the joint operation value output by other devices; for example, measuring the joint operation value of the vehicle by the monitoring system itself; or partially reading the current There are device output data, some of which are self-measured data.
  • the reference data of the present invention needs to consider two aspects; one is the data property of the reference data (including the data type/path of data acquisition); the other is the value of the reference data. Or set the time;
  • the following contents are the general rules of the specific setting scheme of the reference data (such as the source of the data or the selection of the value path, the setting method, the value time, etc.) (the demonstration method of reference data setting 1, 2 , 3, 4, 5, 6):
  • the measured object is the mass of the vehicle whose amplitude may vary greatly (such as a bus, a truck, a general private vehicle), (obviously, the magnitude may vary greatly, Different "times when the vehicle is controlled by the power unit" (ie, in different operating procedures), the loading or unloading of personnel or goods may cause the vehicle quality to vary greatly.) This parameter is in the running of the vehicle.
  • the preferred method is to set the reference data according to the joint operation value obtained by performing the vehicle motion balance calculation when the set condition is satisfied (and the key target is the actual value or the second permission range); that is, the actual value in the reference data. And any one or more kinds of data in the second permission range may be set according to a joint operation value obtained by calculating a vehicle motion balance calculated when the set condition is satisfied;
  • the technical solution is one of the core ideas of the present invention, because the vehicle quality of the vehicle may vary greatly in each different operation process.
  • a self-learning mechanism is basically established, and the load can be automatically followed.
  • Change and flexibly adjust the reference data (the key target is the actual value or the second license range); on this basis, the monitoring sensitivity can be improved and the adaptability to environmental changes can be improved.
  • the operation period of “not satisfying the set condition” that is, the majority of the running time of the vehicle operation, it is naturally unnecessary to repeatedly set the reference data;
  • the preferred method is to pass a preset value (for example, the system default) Value) setting reference data, the second permission range; that is, the second permission range in the reference data can be set according to the system default value; the reference data can be set at the time before the vehicle is run or on the system.
  • a preset value for example, the system default
  • the reference data can be set at the time before the vehicle is run or on the system.
  • the reference data may also be set based on the joint operation value obtained by performing the vehicle motion balance calculation when the set condition is satisfied.
  • the measured object is untestable parameter and / or preset parameters and / or system inherent parameters (such as rolling resistance coefficient, efficiency coefficient), such parameters are not easy to actually measure in the vehicle operation, but the parameters are in the vehicle
  • the amplitude is relatively stable during normal operation, even if the change has relatively stable rules (such as following speed, mileage, usage time, etc.); according to the preset value (especially the system default value (medium system default value))
  • the reference data (calibration value (that is, the reference value), the first permission range, the second permission range, or any one of the data) is the simplest or simpler method; the vehicle motion balance can also be performed according to the set conditions. Calculating the obtained joint operation value setting reference data; that is, the calibration value and/or the second permission range in the reference data may be set according to a preset value (especially a system preset value (medium system default value));
  • the set time of the reference data can be either before the current operation of the vehicle or at the beginning of the current operation; when the measurement object is a system inherent parameter, the subsequent embodiments 36, 37, 38 are reference examples; as for how to go specifically When setting or judging "when the setting condition is satisfied", the contents of Embodiment 35, Embodiment 41 and the like can be naturally referred to;
  • the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality whose amplitude may vary greatly: preferred
  • the method sets the reference data according to the measured value, and focuses on setting the actual value and/or the second permission range in the reference data; subsequent embodiment 40, embodiment 42, and embodiment 43 are reference examples; (obviously, the frame The value may vary greatly, meaning that even in the same period of time when the vehicle is controlled by the power unit (ie, in the same operational process), the amplitude may vary greatly; in general, the actual data in the reference data Any one of the value and the second permission range may be set according to the measured value, and the value of the reference data and the value of the joint operation value are within a preset time range (ie, synchronized);
  • the measured object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operating parameter and/or mass change item quality
  • the actual value or the reference data in the reference data The scope of the two licenses may change rapidly, so the measured value of the measured object can be obtained, and the actual value or the second permitted range in the reference data can be set according to it; and the time value of the reference data and the joint operation value must be limited to Within the time range; the smaller the time range, the better; when the vehicle speed is 120KM/H, it is 2KM per minute, about 33 meters per second, 1 second can be different by 33 meters, and 10 milliseconds is 0.33 meters; 1 The difference in milliseconds is 0.033 meters; the size of a typical obstacle (such as speed bump, stone) may be about 0.1 meters; the setting of this time range can use the maximum speed of the CPU power transmission abnormality processing CPU, such as within 1 millisecond of 100M main frequency Can perform 100,000 single-cycle instruction operations;
  • the reference data and the value of the joint operation value need to be within a preset time range (ie, synchronization)
  • the reference data needs to be newly set to satisfy the condition that the value of the reference data and the value of the joint operation value are within a preset time range (ie, synchronization).
  • the reference data is set according to the historical record value of the measurement object; when the historical record value includes the original value of the historical record, When any one or two kinds of data are recorded and the actual value or/and the second permitted range are set according to the data, the difference between the vehicle operating condition and the current vehicle operating condition when the data is valued Below a preset threshold; that is, any one or more of the actual value and the second permitted range may be set according to a historical record value of the measured object, and the vehicle operating condition at the time of the historical value is compared with the current The difference in vehicle operating conditions is lower than a preset threshold;
  • the difference between the vehicle operating condition and the current vehicle operating condition at the time of the historical value is lower than the preset threshold, and refers to the vehicle operating condition (vehicle quality, vehicle speed, longitudinal acceleration, corresponding to the historical value generation).
  • vehicle operating condition vehicle quality, vehicle speed, longitudinal acceleration, corresponding to the historical value generation.
  • vehicle's external environmental information and source power parameters are consistent with current vehicle operating conditions (vehicle quality, vehicle speed, longitudinal acceleration, vehicle external environmental information, and source dynamic parameters); obviously, the vehicle operating conditions refer to input parameters.
  • the type and magnitude of the parameters included in the vehicle refers to environmental information other than the body of the vehicle that affects the running state of the vehicle, such as road gradient, wind speed, rolling resistance coefficient component fr related to road conditions, etc.; It means that the parameters are the same or close, and if the parameters have directions, the directions of the parameters are the same or close.
  • the measured object is the source dynamic parameter
  • the values of the correlation factors of the multiple core power transmission conditions are similar; for example, the vehicle mass Values, road grade, longitudinal speed, longitudinal acceleration and other parameters are similar.
  • the source and power parameters of the two different time periods may be similar.
  • Specific vehicle operating conditions such as the core power transmission condition correlation factor
  • the number of the data, the weight of each data, and the threshold of the degree of difference in the correlation factors of each power transmission condition are set and adjusted by the user; the more relevant parameters, the more reasonable the weight setting, and the smaller the difference threshold is, the more the calculation/monitoring accuracy is. High; in general, the use of historical values to set the actual value of the rapidly changing measurement object provides a completely new technical choice, which makes up for the lack of ways that must be measured before.
  • Exemplary method 6 setting the reference data according to the historical record value of the measurement object
  • the preferred method is: when the measurement object is any one of the source dynamic parameter, the mechanical operation parameter, the quality change item quality, the vehicle quality, and the system inherent parameter (usually any vehicle operating parameter), according to the history record
  • the difference sets the first permission range, that is, the first permission range can be set according to the history difference value; for detailed operation, see "*** According to historical record value - technical solution for setting reference data" - implementation details
  • the present invention provides a technical solution for how to set reference data (second license range, first license range) using history values;
  • the power transmission condition identification value (that is, the second permission range) is usually set as follows: the actual value of the measurement object is as close as possible to improve the sensitivity of the monitoring, but it must be compared with the actual value. Keep the right difference to reduce The false trigger rate of the monitoring; if the power transmission status recognition upper limit is set to 1.2 to 1.5 times the actual value, or the power transmission status recognition lower limit is set to 0.7 to 0.9 times the actual value, or the power transmission status recognition upper limit The difference is set to 0.1 to 0.3 times the actual value, or the power transmission condition recognition lower limit difference is set to (-0.3) to (-0.1) times the actual value;
  • the precise setting of the power transmission condition identification data such as manual trial and error, or empirical method to slowly explore, to slowly verify, power transmission status identification data
  • the adjustment accuracy is low and the efficiency is low; and the road conditions, load conditions and vehicle conditions of different vehicles are changed, which makes it more difficult to accurately set the identification data of the power transmission condition.
  • the historical record value includes a historical record original value and a historical record actual value, and the power transmission status recognition difference value is set according to a difference between the historical record original value and the historical record actual value (ie, the first Scope of permission);
  • the historical record value includes a historical record original value, and the power transmission status identification value is set according to the historical record original value;
  • the fuzzy algorithm includes any one or more of the following fuzzy algorithm rules: statistically analyzing the reference data that has been used most frequently according to a certain number of running times; or automatically Select the most frequently selected reference data in the last few runs; or automatically select the last run reference data; or set different weight indices for each reference data (such as the user's most valuable and most protective reference data) Set reference data; or set the reference data by comprehensive statistical analysis and weight index;
  • Subsequent power transfer abnormality determination/execution is usually performed after the reference data has been set, which simplifies the system.
  • >m1_gate) in this embodiment can also be simply transformed into (m1>m1_ref(1+1/4)) and (m1 ⁇ m1_ref(1-1/4)) a calculation formula; that is, it is judged whether or not the joint operation value is greater than the set power transmission condition recognition upper limit value (that is, the second permission upper limit value) according to the actual value, and the power transmission condition recognition upper limit value is usually larger than the measurement target The actual value; and the determination of whether the joint operation value is smaller than the set power transmission condition recognition lower limit value (that is, the second permission lower limit value) according to the actual value, the power transmission condition recognition lower limit value is usually smaller than the actual measurement target value;
  • the essence of the embodiment is: when the measured object is the vehicle mass of the conventional vehicle, the actual value is set according to the joint operation value acquired when the set condition is satisfied, and the power transmission condition is set according to the actual value and the system preset value.
  • the difference value that is, the first permission range
  • the difference value is identified, and then it is judged whether or not the difference between the joint operation value and the actual value exceeds the first permitted range (that is, the power transmission condition recognition difference value).
  • the object of measurement according to the present invention may also be referred to as a direct monitoring object, and the actual meaning is equivalent to the direct monitoring object described in the Chinese Patent Application No. 201410312798.3; the actual value of the present invention is equivalent to the actual meaning.
  • the reference value described in the Chinese Patent Application No. 201410312798.3; the difference in the power transmission condition identification value in the present invention is substantially equivalent to that in all the embodiments described in the Chinese Patent Application No. 201410312798.3
  • the error threshold or threshold value
  • the joint operation value described in the present invention has the actual meaning equivalent to the Chinese application with the application number 201410354068.X.
  • the estimated value in the application; the quality of the carried item in the present invention is substantially equivalent to the carrying quality described in the Chinese Patent Application No. 201410354068.X; the power transmission condition of the vehicle mass is identified in the present invention.
  • the limit value, the actual meaning is equivalent to the reference value m1_ref1 in the Chinese patent application with the application number 201410354068.X; the lower limit value of the power transmission condition identification of the vehicle mass described in the present invention, the actual meaning is equivalent to the application number 201410354068.X
  • the relevant state information is automatically set for each time period when the first entering vehicle is controlled by the power unit: "the power transmission status identification upper limit value (reference value m1_ref1) is not set", “the power transmission status identification lower limit value is not set” (reference value m1_ref2)";
  • the power transmission status identification is set according to the joint operation value m1 of the vehicle mass obtained in the current step A.
  • m1_org special explanation: for convenience of description and understanding, the present invention describes all the values m1 of the vehicle mass as the basis for setting the power transmission condition identification value as m1_org;
  • the status information is "the power transmission status recognition upper limit value (m1_ref1, that is, the second permission lower limit value)" is determined, it is determined whether (m1>m1_ref1) is established, and if (m1>m1_ref1), the set security is started.
  • Processing mechanism such as sound and light alarms, outputting alarm information to network systems, etc.;
  • the status information is "set power transmission status recognition lower limit value (m1_ref2)"
  • (m1 ⁇ m1_ref2) it is judged whether (m1 ⁇ m1_ref2) is established, and if it is (m1 ⁇ m1_ref2), the set security processing mechanism is started; for example, sound and light alarm, The alarm information is output to the network system, etc.
  • the essence of the embodiment is: when the measured object is the vehicle mass of the conventional vehicle, the actual value is set according to the joint operation value obtained when the set condition is satisfied, and the second permission range is based on the actual value, that is, according to the satisfaction setting. Setting a joint operation value obtained when the condition is set, and determining whether the joint operation value exceeds the second permission range;
  • Embodiment 35 Alternative 2 m1_ref1 is cleared when the first time a new vehicle is controlled by the power unit; (m1>m1_ref1) when m1_ref1 is not zero;
  • Embodiment 35 Alternative 3:
  • the setting condition of the reference data in Embodiment 35 is: when the entering vehicle is controlled by the power unit to reach a set time (for example, 2.0 seconds); the following A, B, C, D Any one of the schemes to replace the setting conditions of the reference data:
  • a "confirmation" signal may be manually input;
  • the power transmission status identification data can be maintained unchanged; allowing as long as no door opening and closing action occurs, multiple independent The power device control operation period can share a certain power transmission status identification data;
  • the setting conditions of the reference data include two conditions of manual preset and a set parameter reaching the preset value; the artificial preset condition includes a manual input confirmation signal; and the set condition is also called the compliance setting. condition.
  • Embodiment 35 Alternative 4: The power transmission condition identification data described in Embodiment 35 allows the user to freely adjust manually or systematically; if in certain circumstances, if the vehicle is allowed to unload or get on and off during operation (or even jump) At this time, the power transmission status identification data can be freely adjusted by the user manually or the system, or the power transmission status identification data can be cleared and a status information is set: "the power transmission status identification data is not set", or the power transmission status identification is reset. Data, etc.
  • the monitoring system can take this situation. Incorporate monitoring scope and trigger corresponding security processing mechanisms;
  • (Reference data setting mode 1): Set the joint operation value Kem_cal of the efficiency coefficient of the electromechanical transmission integrated in step A to the actual value, that is, the calibration value (ie, the reference value Kem_ref); the power transmission condition can be set according to the system default value. Identify the difference (that is, the error threshold) Kem_gate, if the system automatically sets a fixed error threshold: Kem_gate 0.2;
  • the set security processing mechanism is activated: if a voice prompt alarm is issued in the network system;
  • the essence of the embodiment is: when the measurement object is the system inherent parameter (efficiency coefficient) of the vehicle, (the reference data setting mode 1) the first permission range can be set according to the system default value, and the actual value in the standard state is also The calibration value can be set according to the obtained joint operation value; (reference data setting mode 2) The first permission range can be set according to the system default value, and the calibration value can be set according to the preset value (system default value); Whether the difference between the joint operation value and the calibration value exceeds the first permitted range (that is, the power transmission condition recognition difference value) is established.
  • >Kem_gate) can also be simply transformed into (Kem_ref>Kem_cal(1+1/5)), which is The value is an upper limit value set according to the joint operation value, that is, whether the calibration value is greater than the upper limit value set according to the joint operation value; in this embodiment, the calculation formula of (
  • the set security processing mechanism is activated: if a voice prompt alarm is issued in the network system;
  • the essence of the embodiment is: when the measurement object is the system inherent parameter of the vehicle (the rolling resistance coefficient in the vehicle), (the reference data setting mode 1) the first permission range can be set according to the system default value, and the calibration value can be obtained according to the obtained The joint operation value is set; (reference data setting mode 2) the first permission range can be set according to the system default value, and the calibration value can be set according to the system default value; then the joint operation value and the actual value are determined. Whether the difference exceeds the first permitted range is true.
  • Step A acquiring a joint operation value f_cal of the rolling resistance coefficient of the vehicle; setting a power transmission status identification value according to a system default value; for example, setting a system setting value f (usually an actual value) of the measurement object with a setting
  • Step B If any one or two of (f_cal>S_ref1) and (f_cal ⁇ S_ref2) are met, the set security processing mechanism is started: if a voice prompt alarm is issued in the network system;
  • the power transmission condition recognition upper limit value (that is, the second permission upper limit value) can be based on the system default value (system setting)
  • the value, usually the actual value is set.
  • the upper limit of the power transmission condition identification is usually greater than the actual value of the measurement object; the second lower limit value can be set according to the system default value (system setting value, usually the actual value).
  • the power transmission condition recognition lower limit value is usually smaller than the actual value of the measurement object; it is determined whether the joint operation value is greater than the second permission upper limit value and whether the joint operation value is less than the second permission lower limit value is established.
  • the essence of the embodiment is: when the measured object is the unmanned vehicle mass (the total mass of the vehicle), the second permitted upper limit value may be set according to the system default value, and the second permitted upper limit value is usually greater than the calculation The true value of the object; the second permission lower limit value may be set according to the system default value, and the second permission lower limit value is usually smaller than the actual value of the measurement object; determining that the joint operation value exceeds the Whether the scope of the license is established.
  • Step B If any one or both of (fq_cal>S_ref1) and (fq_cal ⁇ S_ref2) are met, the set security processing mechanism is started: if a voice prompt alarm is issued in the network system;
  • the measurement object is the source dynamic parameter (the electromechanical combination parameter fq)
  • the actual value may be set according to the measured value of the measurement object
  • the second permitted range may be based on the measured value (also That is, the actual value) and the system preset value are set; and it is determined whether the joint operation value exceeds the second permission range.
  • the reference data may include a plurality of data types, such as the reference data, including the power transmission status identification value, in addition to having various setting manners.
  • the reference data may also be data including a power transmission condition identification difference (ie, a first permission range) and an actual value (or a calibration value); wherein the power transmission status identification value (That is, the second permission range) may further include a power transmission condition recognition upper limit value (that is, a second permission upper limit value) and/or a power transmission condition recognition lower limit value (that is, a second permission lower limit value);
  • the power transmission condition identification difference value (that is, the first permission range) may further include a power transmission condition identification upper limit value (that is, a first permission upper limit value) and a power transmission condition recognition lower limit difference (that is, a first permission lower limit) Any one or two of the values;
  • the joint operation value, the actual value or the calibration value, the reference data, and the like of the measurement object of the present invention refer to the amplitude/size of the parameter when there is no limitation description or additional description; of course, the calculation
  • the object itself can also be a time parameter, such as acceleration response time, deceleration response time, parameter change rate, etc.; for example, the measurement object can be either cylinder pressure or cylinder pressure change rate, that is, the difference of cylinder pressure per unit time. If the object is measured, it can be either speed, rate of change of speed / acceleration, or rate of change of acceleration / jerk;
  • Embodiments 1 through 40 When the powerplant of the vehicle includes a fuel engine, the alternate embodiments of Embodiments 1 through 40 described above are as follows when the vehicle is operating in fuel engine control:
  • Fuel Power Alternative 1 In the foregoing Examples 1, 3, 5, 6, 7, 8, 9, 11, 13, 17, 18, 21, 22, 24, 25, 28, 29, 31, 32, 33 If the calculation formula contains Kem, it is split into Ke*Km, and the Km of the efficiency coefficient of the mechanical transmission system can be kept unchanged, and the calculation of the electromagnetic torque Te and the motor efficiency coefficient Ke is replaced by the corresponding front-end fuel. Calculation of the power parameter and the efficiency coefficient of the fuel power system or the conversion coefficient Kfa, by which the fuel can be calculated from the fuel dynamic parameter and the Kfa The driving torque Tr1 of the engine (the acquisition of the specific fuel dynamic parameters, the calculation method of Tr1, refer to the content of 4.2.2.3 in the first part of the foregoing);
  • the expression ((Ke*Km)*(Te*im/R)) in the embodiment 11 is replaced by (Km*Tr2*Kf6*im/R1); the load report data (torque value) Tr2 of the engine is indicated.
  • Fuel Power Alternative 2 In Embodiment 4 or Embodiment 10, if Kem is included in the calculation formula, it is split into Ke*Km, and the operation of the Km of the efficiency coefficient of the mechanical transmission system can be kept unchanged, and the motor drive parameters are
  • the calculation of the electrical power Pm and the efficiency coefficient of the relevant electric power system (such as Ke, k13, k14, etc.) is replaced by the corresponding front-end fuel dynamic parameters and the corresponding fuel power system efficiency coefficient or conversion coefficient Kfa.
  • the fuel dynamic parameters of the front end and the Kfa can calculate the driving power Pr1 of the fuel engine (the acquisition/calculation method of the specific Pr1, refer to the section 4.2.2.3 in the first part of the foregoing)
  • fm1 is used as the source power parameter, the calculation can be stopped when the power unit is in the braking state;
  • Fuel Power Alternative 3 In Examples 12, 15, 16, 19, 20, 23, 26, 27, 30, motor drive parameters (such as Po, P2o, P2i, P3o, P3i, etc.) and associated electrical power
  • the calculation of the efficiency coefficient of the system (such as Ke, k31, k21, etc.) is replaced by the corresponding fuel dynamic parameters of the front end and the corresponding efficiency coefficient or conversion coefficient Kfa.
  • the fuel dynamic parameters of the front end and the Kfa can be calculated.
  • the driving power of the fuel engine Pr1 for the acquisition/calculation of the specific Pr1, refer to the contents of Section 4.2.2.3 in the first part of the above);
  • the expression ((Ke*Km)*(P2o/V x )) can be written as (Ke*Km*P2o/V x ), and (Ke*Km*P2o) is replaced by (Km*Pr1) And further replaced by (Km*fm2*Kf2); indicating that the fuel consumption rate fm2 of the fuel input end of the fuel injection system is used as a source power parameter, thereby calculating a joint operation value of the vehicle mass; according to the alternative, the formula can be Can be organized as:

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Abstract

A method and system for integrating vehicle data measurement and computation, monitoring, surveillance, and troubleshooting. In the monitoring method, a measured object is one or more of vehicle operation parameters of a vehicle. It is determined whether the power transmission status of the vehicle is abnormal according to a jointly calculated value of measured objects and reference data of the measured objects, the jointly calculated value being calculated according to a vehicle motion balance calculation formula. The method for integrating vehicle data measurement and computation, monitoring, surveillance, and troubleshooting can monitor abnormal power transmission in a vehicle caused by failure of a rotary working power or transmission component in the vehicle.

Description

综合车辆的数据测算、监控、监视、处理的方法及系统Method and system for data measurement, monitoring, monitoring and processing of integrated vehicles 技术领域Technical field
本发明涉及车辆技术领域,更具体的说,涉及一种综合车辆的数据测算、监控、监视、处理的方法及系统。The present invention relates to the field of vehicle technology, and more particularly to a method and system for data measurement, monitoring, monitoring, and processing of an integrated vehicle.
背景技术Background technique
在陆地上运行的车辆,是当前世界上最重要、最基础的交通运输工具之一;因为车辆的运行安全与驾驶者、乘员的生命安全紧密相关,提高车辆运行的安全监控性能,始终为车辆技术的核心重点;Vehicles running on land are one of the most important and basic transportation vehicles in the world. Because the safety of vehicles is closely related to the safety of drivers and occupants, the safety monitoring performance of vehicles is always improved. The core focus of technology;
从构造上划分,车辆通常具有产生动力的动力系统、传递动力的机械传动系统;动力系统通常具有能源供应装置、动力控制装置、动力装置;车辆的动力系统和传递动力的机械传动系统中可工作于旋转状态的任意一个或多个部件可称为车辆的旋转工作型动力或传动部件;Structurally, vehicles usually have a power system that generates power and a mechanical transmission system that transmits power. The power system usually has an energy supply device, a power control device, and a power device; the power system of the vehicle and the mechanical transmission system that transmits power can work. Any one or more components in a rotated state may be referred to as a rotary working power or transmission component of the vehicle;
从动力系统种类划分,车辆有燃料动力、电气动力、混合动力系统等;Divided from the type of power system, the vehicle has fuel power, electric power, hybrid system, etc.;
现有燃料动力车辆,包括汽油、柴油、天然气、沼气等动力车辆;Existing fuel-powered vehicles, including gasoline, diesel, natural gas, biogas and other power vehicles;
现有电气动力车辆,包括插电式电动车辆、燃料电池式电动车辆等;Existing electric powered vehicles, including plug-in electric vehicles, fuel cell electric vehicles, etc.;
现有混合动力车辆,则同时包括两种或两种以上的动力系统,如燃料动力系统和电气动力系统等;Existing hybrid vehicles include two or more power systems, such as fuel power systems and electric power systems;
现有燃料动力车辆,通常具有燃料动力系统和机械传动系统;所述的燃料动力系统通常包括燃料供应系统、发动机控制系统、燃料发动机;其中燃料发动机通常具有气缸缸体、活塞、输出动力的曲轴机构;所述机械传动系统通常包括燃料发动机输出轴、驱动轮、以及燃料发动机输出轴和驱动轮之间的中间机械传动部件(包括传动轴、传动齿轮机构等);该燃料发动机输出轴、驱动轮、以及中间机械传动部件均可能工作于高速旋转状态,该系列组件中任意一个或多个部件均可称为车辆的旋转工作型动力或传动部件;Existing fuel-powered vehicles generally have a fuel power system and a mechanical transmission system; the fuel power system generally includes a fuel supply system, an engine control system, and a fuel engine; wherein the fuel engine usually has a cylinder block, a piston, and a crankshaft that outputs power. The mechanical transmission system generally includes a fuel engine output shaft, a drive wheel, and an intermediate mechanical transmission component (including a transmission shaft, a transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel; the fuel engine output shaft, the drive Both the wheel and the intermediate mechanical transmission component may operate at a high speed rotation state, and any one or more of the components of the series may be referred to as a rotary working power or transmission component of the vehicle;
现有电动车辆,通常也具有电气动力系统、机械传动系统;所述的电气动力系统通常包括电源装置、电机驱动装置、电机;电动车辆的电机转子、电机输出轴、驱动轮、以及电机输出轴和驱动轮之间的中间机械传动部件中任意一个或多个部件也可称为电气动力车辆的旋转工作型动力或传动部件;某些轮毂电机车辆也可以将动力系统、机械传动系统合为一体;Existing electric vehicles, usually also have an electric power system, a mechanical transmission system; the electric power system generally includes a power supply device, a motor drive device, a motor; an electric motor rotor, a motor output shaft, a drive wheel, and a motor output shaft Any one or more of the intermediate mechanical transmission components between the drive wheel and the drive wheel may also be referred to as a rotary working power or transmission component of an electric power vehicle; some of the hub motor vehicles may also integrate the power system and the mechanical transmission system. ;
因为车辆的旋转工作型动力或传动部件,不像固定型工作部件或直线运行型工作部件可以方便的安装各种的应力传感器便于检测各部件内部应力状况;如将应力或转矩传感器安装于固定支撑组件上则不便于检测旋转部件的真实应力状况;如安装于旋转部件内部,则信号不便于传输/或传感器电源供应装置不便于设置;所以导致现有的可用于车辆的旋转工作型动力或传动部件的转矩传感器 成本高昂;对于车辆的旋转工作型动力或传动部件的运行状况(尤其是早期故障)的低成本监控,是行业性难题,世界性难题;Because of the rotating working power or transmission components of the vehicle, unlike the fixed working part or the linear running type working part, various stress sensors can be conveniently installed to facilitate the internal stress condition of each part; for example, the stress or torque sensor is fixed to the fixed part. It is not convenient to detect the true stress condition of the rotating component on the support component; if it is installed inside the rotating component, the signal is not convenient to transmit/or the sensor power supply device is inconvenient to set; thus, the existing rotary working power that can be used for the vehicle or Torque sensor for transmission components High cost; low-cost monitoring of the rotating working power of the vehicle or the operating conditions of the transmission components (especially early failures) is an industrial problem, a worldwide problem;
为了解决上述问题,现有技术分为两大类解决方案:In order to solve the above problems, the prior art is divided into two major types of solutions:
A、局部器件型监控方案:现有的胎压监控系统可监测胎压,对爆胎有一定预警作用;但其仅能监测充气轮胎的胎压,且通常只能在轮胎漏气导致胎压或轮速显著变化时才能监控,响应偏慢;且对于轮胎的形变(失圆)无监控能力,对于其他刚性旋转部件(甚至对充气轮胎自身传动轴承的磨损)运行无监控能力;对于采用刚性车轮(包括驱动轮)的车辆(如高铁车辆、动车、普通列车、电力机车、履带式车辆)更无监控效果。A, local device type monitoring program: the existing tire pressure monitoring system can monitor the tire pressure, have a certain early warning effect on the puncture; but it can only monitor the tire pressure of the pneumatic tire, and usually only the tire leakage caused by tire leakage Or when the wheel speed changes significantly, the response is slow; and there is no monitoring capability for the deformation (out of roundness) of the tire, and no monitoring capability for other rigid rotating parts (even the wear of the pneumatic tire's own transmission bearing); Vehicles with wheels (including drive wheels) (such as high-speed rail vehicles, motor trains, ordinary trains, electric locomotives, and tracked vehicles) have no monitoring effect.
B、通用型的车辆运行参数的安全极限阈值超限比较型技术方案:B. General-purpose safety limit threshold for vehicle operating parameters:
现有技术中,有多种获取车辆质量的联合运算值的技术;以进行各种变速控制、制动及稳定性控制、自适应巡航控制(ACC)系统或自动换道(LCX)系统、ABS控制等;In the prior art, there are a variety of techniques for obtaining joint operational values of vehicle mass; for various shift control, braking and stability control, adaptive cruise control (ACC) systems or automatic lane change (LCX) systems, ABS Control, etc.
现有技术中,有多种计算车辆燃料消耗量的方法和设备,以推断驾驶员的行为,用于监测和训练驾驶员,协助车队所有者、运输公司及类似公司以及保险公司管理;In the prior art, there are a variety of methods and apparatus for calculating vehicle fuel consumption to infer driver behavior for monitoring and training drivers, assisting fleet owners, transportation companies and similar companies, and insurance company management;
现有技术中,更有多种检测旋转部件转速、车辆纵向速度、纵向加速度的技术方案;通过传感器检测,通过GPS数据分析,或用其他参数来联合运算等,以实现超速限速等功能;In the prior art, there are a plurality of technical solutions for detecting the rotational speed of the rotating component, the longitudinal speed of the vehicle, and the longitudinal acceleration; by means of sensor detection, by GPS data analysis, or by using other parameters to jointly calculate, etc., to achieve functions such as overspeed limit speed;
因为车辆运行工况有成百上千种可能,车辆随时处于低速/高速、轻载/重载、加速/减速、上坡/下坡等状态的切换中,所以车辆运行参数(如纵向速度、纵向加速度、车辆质量、车辆驱动力、转矩、功率、电流等)在正常运行状况中也可能出现大幅度变化;所以现有B类技术方案,均只能简单的在车辆运行参数超过安全极限阈值(如最高限速、最大加速度限制值、最大安全载重量、最大功率、最大转矩、最大电流等)进行响应;在车辆运行参数未超过预设的安全极限阈值前,不便于实现对车辆运行安全状况的监控,更不便于实现高灵敏度的早期监控;通常只能被动的、滞后的等待车辆的传动主轴断裂、传动齿轮爆裂、包括在无胎压监控系统时爆胎,在可能已造成严重安全事故的事件发生后才能示警、善后。Because there are hundreds of possibilities for vehicle operating conditions, the vehicle is always in the state of low speed / high speed, light load / heavy load, acceleration / deceleration, uphill / downhill, etc., so vehicle operating parameters (such as longitudinal speed, Longitudinal acceleration, vehicle mass, vehicle driving force, torque, power, current, etc. may also vary greatly in normal operating conditions; therefore, existing Class B technical solutions can only simply exceed the safety limit of vehicle operating parameters. The threshold (such as the maximum speed limit, the maximum acceleration limit value, the maximum safe load capacity, the maximum power, the maximum torque, the maximum current, etc.) responds; it is inconvenient to implement the vehicle before the vehicle operating parameters do not exceed the preset safety limit threshold. The monitoring of the operation safety status is even more inconvenient to achieve high-sensitivity early monitoring; usually only passive, lag waiting for the vehicle's transmission spindle to break, the transmission gear burst, including the tire tire when there is no tire pressure monitoring system, may have caused In the event of a serious security incident, the police can be alerted and rehabilitated.
发明内容Summary of the invention
本发明要解决的技术问题之一是提供一种便于对(包括车辆的旋转工作型动力或传动部件运行故障所导致的)车辆动力传递异常进行监控的技术方案;One of the technical problems to be solved by the present invention is to provide a technical solution for facilitating monitoring of vehicle power transmission anomalies (including caused by a rotating working power of a vehicle or a malfunction of a transmission component);
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供The invention provides
1、一种车辆由动力装置控制运行时的监控方法,测算对象是车辆的车辆运行参数中任意一种或多种参数,1. A monitoring method for controlling a running time of a vehicle by a power device, the measuring object being any one or more parameters of a vehicle operating parameter of the vehicle,
根据测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;所 述所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种。Determining whether the power transmission condition of the vehicle is abnormal according to the joint operation value of the measurement object and the reference data of the measurement object; The joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance between a vehicle dynamic direction and a related resistance in a running direction or a deformation thereof; the correlation resistance includes a rolling resistance and a gradient resistance Any one or any of a variety of speed resistance and wind resistance.
2、进一步的,所述监控方法中,判断车辆的动力传递状况是否异常包括下述任意一种或多种方式:2. Further, in the monitoring method, determining whether the power transmission condition of the vehicle is abnormal includes any one or more of the following:
2A1.参考数据包括第一许可上限值和实际值;判断所述联合运算值与实际值的差值是否大于第一许可上限值;2A1. The reference data includes a first permission upper limit value and an actual value; determining whether a difference between the joint operation value and the actual value is greater than a first permission upper limit value;
2A2.参考数据包括第一许可下限值和实际值;判断所述联合运算值与实际值的差值是否小于第一许可下限值;2A2. The reference data includes a first permission lower limit value and an actual value; determining whether a difference between the joint operation value and the actual value is less than a first permission lower limit value;
2A3.参考数据包括实际值;判断所述实际值是否大于根据联合运算值设定的上限值;2A3. The reference data includes an actual value; determining whether the actual value is greater than an upper limit value set according to the joint operation value;
2A4.参考数据包括实际值;判断所述实际值是否小于根据联合运算值设定的下限值。2A4. The reference data includes an actual value; and it is judged whether the actual value is smaller than a lower limit value set according to the joint operation value.
2A5.参考数据包括第二许可上限值;判断所述联合运算值是否大于第二许可上限值;2A5. The reference data includes a second permission upper limit value; and determining whether the joint operation value is greater than a second permission upper limit value;
2A6.参考数据包括第二许可下限值;判断所述联合运算值是否小于第二许可下限值。2A6. The reference data includes a second permission lower limit value; and determining whether the joint operation value is less than a second permission lower limit value.
3、进一步的,所述动力传递状况异常包括下述任意一种情况:3. Further, the abnormality of the power transmission condition includes any one of the following cases:
3A1.参考数据包括第一许可上限值和实际值;所述联合运算值与实际值的差值大于第一许可上限值;3A1. The reference data includes a first permission upper limit value and an actual value; the difference between the joint operation value and the actual value is greater than the first permission upper limit value;
3A2.参考数据包括第一许可下限值和实际值;所述联合运算值与实际值的差值小于第一许可下限值;3A2. The reference data includes a first permission lower limit value and an actual value; the difference between the joint operation value and the actual value is less than the first permission lower limit value;
3A3.参考数据包括实际值;所述实际值大于根据联合运算值设定的上限值;3A3. The reference data includes an actual value; the actual value is greater than an upper limit value set according to the joint operation value;
3A4.参考数据包括实际值;所述实际值小于根据联合运算值设定的下限值;3A4. The reference data includes an actual value; the actual value is less than a lower limit value set according to the joint operation value;
3A5.参考数据包括第二许可上限值;所述联合运算值大于第二许可上限值;3A5. The reference data includes a second permission upper limit value; the joint operation value is greater than the second permission upper limit value;
3A6.参考数据包括第二许可下限值;所述联合运算值小于第二许可下限值。3A6. The reference data includes a second permissible lower limit value; the joint operation value is less than the second permissible lower limit value.
4.进一步的,所述监控方法中:4. Further, in the monitoring method:
4A1.当所述测算对象为需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时:参考数据中实际值、第二许可范围中任意一种或多种数据为根据实测值设定,且所述参考数据的取值时间与所述联合运算值的取值时间在预设的时间范围内;4A1. When the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality: actual value in reference data And any one or more of the data in the second permission range is set according to the measured value, and the time value of the reference data and the value of the joint operation value are within a preset time range;
或,or,
4A2.当所述测算对象为需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时:参考数据中实际值、第二许可范围中任意一种或多种数据为根据测算对象的历史记录值设定,所述历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值,所述历史记录值中包含历史记录原值、历史记录实际值中任意一种或 两种数据。4A2. When the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality: actual value in reference data And any one or more of the second permission ranges are set according to the historical record value of the measurement object, and the difference between the vehicle running condition and the current vehicle running condition when the historical value is taken is lower than the preset a threshold value, where the historical record value includes any one of a history original value and a history actual value or Two kinds of data.
5.进一步的,所述监控方法中:5. Further, in the monitoring method:
4A1.当所述测算对象为车辆质量中任一参数时:所述参考数据中实际值、第二许可范围中任意一种或多种数据为根据满足设定条件时所进行车辆运动平衡计算获取的联合运算值设定;4A1. When the measurement object is any one of the vehicle quality: any one or more of the actual value and the second permission range in the reference data is calculated according to the vehicle motion balance calculated when the set condition is satisfied. Joint operation value setting;
或,or,
4A2.当所述测算对象为车辆质量中任一参数时:所述参考数据中实际值、第二许可范围中任意一种或多种数据为根据历史记录值设定;4A2. When the measurement object is any one of the vehicle quality: any one or more of the actual value and the second permission range in the reference data are set according to the historical record value;
或,or,
4A3.当所述测算对象为车辆质量中任一参数时:所述参考数据中实际值、第二许可范围中任意一种或多种数据为根据预设值设定;4A3. When the measurement object is any one of the vehicle quality: any one or more of the actual value and the second permission range in the reference data are set according to a preset value;
6.进一步的,所述监控方法中,当所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时,所述参考数据中的标定值、第二许可范围、第一许可范围中任意一种或多种数据为根据预设值或满足设定条件时所进行车辆运动平衡计算所获取的联合运算值设定。6. Further, in the monitoring method, when the measurement object is any one of an unmeasured parameter and/or a preset parameter and/or a system inherent parameter, the calibration value in the reference data, the second Any one or more of the permitted range and the first permitted range is a joint operation value set obtained based on a preset value or a vehicle motion balance calculation performed when the set condition is satisfied.
7、进一步的,所述监控方法中,当所述测算对象为除系统固有参数之外的车辆运行参数中任一参数时,所述第二许可上限值为根据实际值设定,和/或所述第二许可下限值为根据实际值设定。7. Further, in the monitoring method, when the measurement object is any one of vehicle operating parameters other than a system inherent parameter, the second permission upper limit value is set according to an actual value, and/ Or the second permission lower limit value is set according to an actual value.
8、进一步的,当所述测算对象为系统固有参数和/或为除系统固有参数之外的车辆运行参数中任一参数时,所述监控方法包括下述5A1、5A2、5A3、5A4、5A5中任意一种或多种方案:8. Further, when the measurement object is any one of system inherent parameters and/or vehicle operating parameters other than system inherent parameters, the monitoring method includes the following 5A1, 5A2, 5A3, 5A4, 5A5 Any one or more of the options:
5A1.当参考数据中包括第二许可上限值时,该第二许可上限值小于安全极限阈值中最大值;5A1. When the second license upper limit value is included in the reference data, the second license upper limit value is less than a maximum value of the safety limit threshold value;
5A2.当参考数据中包括第二许可下限值时,该第二许可下限值大于安全极限阈值中最小值;5A2. When the second permitted lower limit value is included in the reference data, the second permitted lower limit value is greater than a minimum value of the safety limit threshold value;
5A3.当参考数据中包括第一许可上限值与实际值时,该第一许可上限值与该实际值的和值小于安全极限阈值中最大值;5A3. When the first permitted upper limit value and the actual value are included in the reference data, the sum of the first permitted upper limit value and the actual value is less than a maximum value of the safety limit threshold;
5A4.当参考数据中包括第一许可下限值与实际值时,该第一许可下限值与该实际值的和值大于安全极限阈值中最小值;5A4. When the first permitted lower limit value and the actual value are included in the reference data, the sum of the first permitted lower limit value and the actual value is greater than a minimum value of the safety limit threshold;
5A5.当根据实际值和根据联合运算值设定的下限值判断所述车辆的动力传递状况是否异常时,该根据联合运算值设定的下限值大于安全极限阈值中最小值,和/或该实际值大于安全极限阈值中最小值;5A5. When it is determined whether the power transmission condition of the vehicle is abnormal according to the actual value and the lower limit value set according to the joint operation value, the lower limit value set according to the joint operation value is greater than the minimum value of the safety limit threshold value, and / Or the actual value is greater than the minimum value of the safety limit threshold;
5A6.当根据实际值和根据联合运算值设定的上限值判断所述车辆的动力传递状况是否异常时,该根据联合运算值设定的上限值小于安全极限阈值中最大值,和/或该实际值小于安全极限阈值中最大值。5A6. When it is determined whether the power transmission condition of the vehicle is abnormal according to the actual value and the upper limit value set according to the joint operation value, the upper limit value set according to the joint operation value is smaller than the maximum value of the safety limit threshold value, and / Or the actual value is less than the maximum value of the safety limit threshold.
9.进一步的,所述监控方法,还包括步骤:9. Further, the monitoring method further includes the steps of:
6A1.如所述判断的结果为是,则启动设定的动力传递异常处理机制;6A1. If the result of the determination is yes, the set power transmission abnormality processing mechanism is activated;
和/或, and / or,
6A2.输出和/或保存所述判断的结果。6A2. Output and/or save the result of the determination.
10.进一步的,所述监控方法,获取的车辆的输入参数的值,根据获取的车辆的输入参数的值计算所述联合运算值,所述输入参数为计算所述联合运算值所需求的参数。10. The monitoring method, the acquired value of the input parameter of the vehicle, calculates the joint operation value according to the obtained value of the input parameter of the vehicle, and the input parameter is a parameter required for calculating the joint operation value. .
11.进一步的,所述监控方法中,还包括下述步骤:获取所述车辆的运行环境信息;根据所述联合运算值、所述参考数据和所述运行环境信息判断是否发生动力传递异常中的动力传递故障情况。11. The monitoring method further includes the steps of: acquiring operating environment information of the vehicle; determining, according to the joint operation value, the reference data, and the operating environment information, whether a power transmission abnormality occurs. The power transmission failure situation.
12.进一步的,所述监控方法中,当所述测算对象为除车辆质量之外的车辆运行参数中任一参数时,计算所述联合运算值所需求的车辆质量为基于时间在先的车辆运动平衡计算所得。12. Further, in the monitoring method, when the measurement object is any one of vehicle operating parameters other than vehicle mass, the vehicle mass required to calculate the joint operation value is a time-based vehicle The exercise balance is calculated.
13.进一步的,所述监控方法中还包括下述方案:获取动力装置运行工况,将动力装置运行工况与所述计算关联。13. Further, the monitoring method further includes the following scheme: acquiring a power device operating condition, and associating the power device operating condition with the calculation.
14.进一步的,所述监控方法中,参与所述计算的参数中包括质量变化型物品质量。14. Further, in the monitoring method, among the parameters participating in the calculation, the mass variation type item quality is included.
15.进一步的,所述监控方法中,参与所述计算的参数中包括效率系数、滚阻系数、路面坡度中任意一种或三种参数。15. Further, in the monitoring method, the parameters participating in the calculation include any one or three of the efficiency coefficient, the rolling resistance coefficient, and the road surface gradient.
16.进一步的,所述监控方法中,输出和/或保存车辆质量的值。16. Further, in the monitoring method, the value of the vehicle mass is output and/or saved.
17.进一步的,所述监控方法中,当源动力参数为能量类型的源动力组合型参数时,能量累计的时间控制在一天之内或以1小时之内或30分钟之内或10分钟之内或一分钟之内或30秒之内或20秒之内或10秒之内或5秒之内或2秒之内或1秒之内或100毫米之内或10毫秒之内或1毫秒之内或0.1毫米之内。17. Further, in the monitoring method, when the source dynamic parameter is a source-type combined parameter of the energy type, the time of energy accumulation is controlled within one day or within one hour or within 30 minutes or 10 minutes. Within one minute or within 30 seconds or within 20 seconds or within 10 seconds or within 5 seconds or within 2 seconds or within 1 second or within 100 millimeters or within 10 milliseconds or 1 millisecond Inside or within 0.1 mm.
18.进一步的,所述监控方法中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。18. Further, in the monitoring method, the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor drive parameter and an electrical power parameter of the back end.
19.进一步的,所述监控方法中,当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。19. Further, in the monitoring method, when the source power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter, the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
20.进一步的,所述监控方法中,所述车辆运行参数包括车辆质量、源动力参数、系统运行参数,所述系统运行参数包括机械运行参数、系统固有参数、质量变化型物品质量。20. Further, in the monitoring method, the vehicle operating parameters include a vehicle mass, a source power parameter, and a system operating parameter, and the system operating parameter includes a mechanical operating parameter, a system inherent parameter, and a quality variable item quality.
21.进一步的,所述监控方法中,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车中任意一种车辆。21. Further, in the monitoring method, the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, an ordinary private vehicle, a general train, a crawler vehicle, Any of electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles with powertrains, or tricycles.
本发明要解决的技术问题之二为提供一种便于对与车辆运行安全相关数据进行监视的技术方案;The second technical problem to be solved by the present invention is to provide a technical solution for facilitating monitoring of data related to vehicle operation safety;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供 The invention provides
22.一种车辆运行的监视方法,测算对象是车辆的车辆运行参数中任意一种或多种参数,所述监视方法包括步骤:22. A method of monitoring vehicle operation, the measurement object being any one or more of vehicle operating parameters of the vehicle, the monitoring method comprising the steps of:
获取测算对象的联合运算值,该联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种。Obtaining a joint operation value of the measurement object, wherein the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance between the dynamic direction and the related resistance of the vehicle in the running direction or a deformation thereof; the correlation resistance It includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述测算对象的联合运算值。The joint operation value of the measurement object is output on a human machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
23.进一步的,所述监视方法中,还包括步骤:获取所述测算对象的实际值或标定值,在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的实际值或标定值。23. Further, the monitoring method further includes the steps of: acquiring an actual value or a calibration value of the measurement object, and outputting the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product. Measure the actual or calibrated value of the object.
24.进一步的,所述监视方法中,24. Further, in the monitoring method,
测算对象为车内电子设备和/或便携式个人消费电子产品的人机界面上已输出的一种或多种参数。The measurement object is one or more parameters that have been output on the human machine interface of the in-vehicle electronic device and/or the portable personal consumer electronics product.
25.进一步的,所述监视方法中,所述车内电子设备包括车内导航系统、倒车雷达、车内中控台、驾驶屏显系统、车内仪表盘、行车记录仪、车内视频监控系统中任意一种或多种设备。25. Further, in the monitoring method, the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle instrument panel, a driving recorder, and an in-vehicle video monitoring. Any one or more devices in the system.
26.进一步的,所述监视方法中,所述便携式个人消费电子产品包括手机、智能手表、智能手环中任意一种或多种设备。26. Further, in the monitoring method, the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart wristband.
27.进一步的,所述监视方法中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。27. Further, in the monitoring method, the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor drive parameter and an electrical power parameter of the back end.
28.进一步的,所述监视方法中,当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。28. Further, in the monitoring method, when the source power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter, the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
29.进一步的,所述监视方法中,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车中任意一种车辆。29. Further, in the monitoring method, the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, a general private vehicle, a general train, a crawler vehicle, Any of electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles with powertrains, or tricycles.
42.进一步的,所述车辆为在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器。42. Further, the vehicle is an aircraft that is operating on land and whose air lift is below a predetermined threshold or the longitudinal speed is below a preset value.
本发明要解决的技术问题之三是提供一种便于对与车辆运行安全相关数据进行处理的技术方案;The third technical problem to be solved by the present invention is to provide a technical solution for facilitating processing of data related to vehicle operation safety;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供The invention provides
30.一种车辆数据的处理方法,测算对象为车辆运行参数中任意一个或多个参数,包括步骤:30. A method for processing vehicle data, the measuring object being any one or more parameters of a vehicle operating parameter, including the steps of:
获取测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆 运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种。Obtaining a joint operation value of the measurement object, wherein the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle The formula for calculating the balance of motion is a formula for describing the balance of the dynamics of the vehicle in the running direction and the associated resistance or a variant thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
还包括下列任意一个或多个步骤:Also includes any one or more of the following steps:
20A1.所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出和/或保存;20A1. The measurement object is an unmeasurable parameter and/or any one or more parameters of a preset parameter and/or a system inherent parameter, and the joint operation value is output and/or saved;
20A2、当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,所述处理方法还需获取所述测算对象的实际值;将所述联合运算值和所述实际值输出和/或保存,和/或将所述联合运算值和所述实际值的差值输出和/或保存。20A2, when the measurement object is any one of vehicle operation parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the processing method further needs to acquire the actual object of the measurement object. a value; outputting and/or saving the joint operation value and the actual value, and/or outputting and/or saving a difference between the joint operation value and the actual value.
31.进一步的,所述监视方法中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。31. Further, in the monitoring method, the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more parameters of a motor drive parameter and an electrical power parameter of the back end.
本发明要解决的技术问题之四是提供一种无须借助与磅秤称量的车辆超载的监控方法,The fourth technical problem to be solved by the present invention is to provide a monitoring method that does not require overloading of a vehicle weighed with a scale.
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明还提供The invention also provides
32.一种车辆超载的监控方法,所述监控方法包括步骤:32. A method of monitoring a vehicle overload, the monitoring method comprising the steps of:
获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载。Obtaining a joint operation value of the vehicle mass of the vehicle, wherein the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance between a vehicle dynamic direction and a related resistance in a running direction or a variant thereof Formula; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; determining whether the vehicle is overloaded according to the acquired joint operation value and the vehicle maximum load safety permission value of the vehicle .
33.进一步的,所述监控方法中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。33. Further, in the monitoring method, the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more parameters of a motor driving parameter and a back end electrical power parameter.
34.进一步的,所述监控方法中,当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。34. Further, in the monitoring method, when the source power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter, the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, Any one or more parameters in the engine load report data.
本发明要解决的技术问题之五是提供一种在动力装置运行工况变化时提高联合运算值的可信度的方案;The fifth technical problem to be solved by the present invention is to provide a solution for improving the reliability of the joint operation value when the operating condition of the power plant changes;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明还提供(35.)一种车辆的车辆运行参数的测算方法,测算对象是所述车辆的车辆运行参数中任意一种或多种参数,所述测算方法包括步骤:获取所述车辆的输入参数的值和动力装置运行工况;所述输入参数为计算所述车辆的测算对象的联合运算值所需求的参数;根据所述获取的输入参数的值计算出所述测算对象的联合运算值,并将该值输出和/或保存;所述计算为基于车辆运动 平衡计算公式的计算,将动力装置运行工况与所述计算关联。The invention also provides (35.) a method for calculating a vehicle operating parameter of a vehicle, the measuring object being any one or more parameters of vehicle operating parameters of the vehicle, the calculating method comprising the steps of: acquiring the vehicle a value of the input parameter and a power plant operating condition; the input parameter is a parameter required to calculate a joint operation value of the measurement object of the vehicle; and a joint operation of the measurement object is calculated according to the value of the acquired input parameter Value and output and/or save the value; the calculation is based on vehicle motion The calculation of the balance calculation formula correlates the power plant operating conditions with the calculations.
本发明还提供The invention also provides
(36.)一种车辆由动力装置控制运行时的监控系统,测算对象是车辆的车辆运行参数中任意一种参数,所述监控系统包括判断参数获取模块(1)、动力传递状况判断模块(2);所述监控系统还包括动力传递异常处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;(36.) A monitoring system in which a vehicle is controlled by a power unit, wherein the measurement target is any one of vehicle operating parameters of the vehicle, and the monitoring system includes a judgment parameter acquisition module (1) and a power transmission status determination module ( 2); the monitoring system further includes any one or more of a power transmission abnormality processing module (3), an output module (4), and a saving module (5);
所述判断参数获取模块(1)用于:获取所述车辆的测算对象的联合运算值和所述测算对象的参考数据;所述联合运算值为基于车辆运动平衡计算公式计算所得;The determining parameter obtaining module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle and reference data of the measurement object; and the joint operation value is calculated based on a vehicle motion balance calculation formula;
所述动力传递状况判断模块(2)用于:根据车辆的测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;The power transmission status determination module (2) is configured to: determine whether the power transmission status of the vehicle is abnormal according to a joint operation value of the measurement object of the vehicle and reference data of the measurement object;
所述动力传递异常处理模块(3)用于:如所述判断的结果为是,则启动设定的动力传递异常处理机制;The power transmission abnormality processing module (3) is configured to: if the result of the determining is yes, initiate a set power transmission abnormality processing mechanism;
所述输出模块(4)用于:输出所述动力传递状况判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the power transmission status determination module (2);
所述保存模块(5)用于:保存所述动力传递状况判断模块(2)的判断结果。The saving module (5) is configured to: save the determination result of the power transmission status determination module (2).
本发明还提供The invention also provides
(37.)一种车辆运行参数的监视系统,测算对象是车辆的车辆运行参数中任意一种或多种参数,其特征在于,所述监视系统包括联合运算值获取模块(1)、指示模块(2):(37.) A monitoring system for vehicle operating parameters, the measuring object being any one or more of vehicle operating parameters of the vehicle, wherein the monitoring system comprises a joint operation value acquiring module (1), an indicating module (2):
所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值;联合运算值为基于车辆运动平衡计算公式计算所得;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle; the joint operation value is calculated based on a vehicle motion balance calculation formula;
所述指示模块(2)用于在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的联合运算值。The indication module (2) is configured to output a joint operation value of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
38.进一步的,所述监控系统中,所述车内电子设备包括车内导航系统、倒车雷达、车内中控台、驾驶屏显系统、车内仪表盘、行车记录仪、车内视频监控系统中任意一种或多种设备。38. Further, in the monitoring system, the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle instrument panel, a driving recorder, and an in-vehicle video monitoring. Any one or more devices in the system.
39.进一步的,所述监控系统中,所述便携式个人消费电子产品包括手机、智能手表、智能手环中任意一种或多种设备。39. Further, in the monitoring system, the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart bracelet.
本发明还提供The invention also provides
(40.)一种车辆数据的处理系统,测算对象为车辆运行参数中任意一个或多个参数,所述处理系统包括联合运算值获取模块(1)、所述处理系统还包括输出模块(2)和/或保存模块(3):(40.) A processing system for vehicle data, the measurement object being any one or more parameters of vehicle operating parameters, the processing system comprising a joint operation value acquisition module (1), the processing system further comprising an output module (2) ) and / or save module (3):
所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;当所述测算对象为除不可测参数和/或可预设参 数和/或系统固有参数之外的车辆运行参数中任一参数时,还需获取所述测算对象的实际值或标定值;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle, and the joint operation value is calculated based on a vehicle motion balance calculation formula; when the measurement object is Measuring parameters and / or preset parameters When any of the vehicle operating parameters other than the number and/or the system inherent parameter is used, the actual value or the calibration value of the measuring object is also acquired;
所述输出模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出;和/或The output module (2) is configured to: output the joint operation value; and/or the measurement object is an unmeasured parameter and/or any one or more of a preset parameter and/or a system inherent parameter; and/or
当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,将所述联合运算值和所述实际值输出,和/或将所述联合运算值和所述实际值的差值输出;When the measured object is any one of vehicle operating parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the joint operation value and the actual value are output, and / Or outputting a difference between the joint operation value and the actual value;
所述保存模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值保存;和/或The saving module (2) is configured to: save the joint operation value as: the unmeasured parameter and/or any one or more parameters of the preset parameter and/or the system intrinsic parameter; and/or
当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,将所述联合运算值和所述实际值保存,和/或将所述联合运算值和所述实际值的差值保存。And when the measured object is any one of vehicle operating parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, saving the joint operation value and the actual value, and/ Or saving the difference between the joint operation value and the actual value.
本发明还提供The invention also provides
(41.)一种车辆超载的监控系统,所述监控系统包括联合运算值获取模块(1)、超载判断模块(2);所述监控系统还包括超载处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;(41.) A monitoring system for overloading a vehicle, the monitoring system comprising a joint operation value acquisition module (1) and an overload determination module (2); the monitoring system further comprising an overload processing module (3) and an output module (4) ), saving any one or more of the modules (5);
所述联合运算值获取模块(1)用于:获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;The joint operation value obtaining module (1) is configured to: acquire a joint operation value of a vehicle mass of the vehicle, where the joint operation value is calculated based on a vehicle motion balance calculation formula;
所述超载判断模块(2)用于:根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载;The overload judgment module (2) is configured to: determine whether the vehicle is overloaded according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle;
所述超载处理模块(3)具有下述功能:如所述判断结果包括是,则启动设定的超载处理机制;The overload processing module (3) has the following functions: if the determination result includes yes, the set overload processing mechanism is activated;
所述输出模块(4)用于:输出所述超载判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the overload determination module (2);
所述保存模块(5)用于:保存所述超载判断模块(2)的判断结果。The saving module (5) is configured to: save the determination result of the overload determination module (2).
附图说明DRAWINGS
图1是本发明一种车辆由动力装置控制运行时的监控方法的示意图;1 is a schematic diagram of a monitoring method when a vehicle is controlled by a power unit according to the present invention;
图2是本发明一种车辆由动力装置控制运行时的监控系统的示意图;2 is a schematic diagram of a monitoring system when a vehicle is controlled by a power unit according to the present invention;
图3是本发明车辆运行的示意图;Figure 3 is a schematic view of the operation of the vehicle of the present invention;
具体实施方式detailed description
第一部分内容:针对本发明技术方案所述的名词、参数,特做如下的解释说明:The first part of the content: For the nouns and parameters described in the technical solution of the present invention, the following explanations are given:
本发明中,数据即值,数据与值等同;例如:联合运算数据等同于联合运算值、实测值等同于 实测数据、指令值等同于指令数据、预设数据即预设值、系统预设数据即系统预设值、人工预设数据即人工预设值、系统默认数据即系统默认值、模糊算法数据即模糊算法值、历史记录数据即历史记录值即历史数据即历史值,等等;显而易见的,本发明中,多个公知名字直接组合的含义,等同于该多个公知名词中加一个“的”字的连接的含义,例如:实测数据即实测的数据、预设数据即预设的数据,等;非公知名词与公知名词直接组合的含义,等同与该非公知名词与该公知名词中加一个“的”字的连接的含义,例如:联合运算数据即联合运算的数据(也即经过联合运算所得的数据)、动力传递状况即动力的传递的状况,等;以此类推,所有名词的理解均可参照此方式推理所得。联合运算值即估算值即推算值;In the present invention, the data is a value, and the data is equivalent to the value; for example, the joint operation data is equivalent to the joint operation value, and the measured value is equivalent to The measured data and command value are equivalent to the command data, the preset data is the preset value, the system preset data is the system preset value, the manual preset data is the manual preset value, the system default data is the system default value, and the fuzzy algorithm data is The fuzzy algorithm value, the historical record data, that is, the historical record value, that is, the historical data, that is, the historical value, etc.; obviously, in the present invention, the meaning of direct combination of a plurality of well-known names is equivalent to adding a "" to the plurality of publicly-known words. The meaning of the connection of the words, for example: the measured data is the measured data, the preset data is the preset data, etc.; the meaning of the direct combination of the non-public well-known words and the publicly-known words is equivalent to adding one to the non-public well-known words and the publicly-known words. The meaning of the connection of the word "," for example, the joint operation data, that is, the data of the joint operation (that is, the data obtained through the joint operation), the state of the power transmission state, that is, the transmission of power, and the like; and so on, the understanding of all the nouns You can refer to this way to reason. The joint operation value is the estimated value, that is, the estimated value;
本发明中计算规则即规则也即对应关系即模型即公式;本发明中,根据等同于基于(也即通过或经过);根据数据B设定数据A或数据A为基于数据B所设定,可为下述任一情况:将数据B直接设为数据A、将数据B经过某些附加处理(如与某一偏差值相加、与某一系数相乘)设为数据A等;In the present invention, the calculation rule, that is, the rule, that is, the corresponding relationship, that is, the model, is a formula; in the present invention, it is equivalent to based on (that is, passing or passing); according to the data B setting data A or data A is set based on the data B, It can be any of the following cases: data B is directly set to data A, and data B is subjected to some additional processing (such as adding a certain offset value and multiplying a certain coefficient) into data A and the like;
本发明中A与B接近指A与B的差值的绝对值小于预设值,当A与B的参数类型不同时该预设值的大小也不同,该预设值的大小可通过系统合理的调整;A范围在B范围之内:指A范围的上限值小于或等于B范围的上限值,A范围的下限值或等于大于B范围的下限值;A范围超出范围:指A范围的上限值大于B范围的上限值,和/或:A范围的下限值小于B范围的下限值;A在B范围之内:指A小于或等于B范围的上限值,A大于或等于B范围的下限值;A范围超出范围:指A大于B范围的上限值,和/或:A小于B范围的下限值;本段文字中A与B均为一个代号,其具体可为任一参数、数据、值等;In the present invention, the absolute value of the difference between A and B is smaller than the preset value. When the parameter types of A and B are different, the size of the preset value is different, and the size of the preset value can be reasonable through the system. Adjustment; A range is within B range: the upper limit of the A range is less than or equal to the upper limit of the B range, the lower limit of the A range is equal to the lower limit of the B range; the A range is out of range: The upper limit of the A range is greater than the upper limit of the B range, and/or: the lower limit of the A range is less than the lower limit of the B range; A is within the B range: the A is less than or equal to the upper limit of the B range , A is greater than or equal to the lower limit of the B range; A range is out of range: A is greater than the upper limit of the B range, and / or: A is less than the lower limit of the B range; in this paragraph, both A and B are one Code, which can be any parameter, data, value, etc.;
数据的分析研究:本发明中所述数据(即参数的值),通常具有多种属性,例如时间属性、获取途径、值域等;Analytical research of data: The data (ie, the value of a parameter) in the present invention usually has various attributes, such as a time attribute, an acquisition path, a value range, and the like;
从时间属性上区分,数据(或参数的值)可分为当前数据(即当前值)、历史数据(即历史值)、预测数据(也即预测值也即基于某时间点往前预测的数据也即未来值);在没有限定说明时当前值也即实时值;历史数据(或历史值)指过去的时间点所生成数据;数据(或参数的值)的时间,优先指该数据(或参数的值)的生成(或产生)时间,而非优先指取值时间;Differentiating from the time attribute, the data (or the value of the parameter) can be divided into current data (ie, current value), historical data (ie, historical value), and predicted data (that is, predicted value, that is, data predicted based on a certain time point) That is, the future value); the current value is the real-time value when there is no limit; the historical data (or historical value) refers to the data generated in the past time point; the time of the data (or the value of the parameter), the priority refers to the data (or The generation (or generation) time of the parameter's value, not the priority value time;
从获取途径上区分,数据(或参数的值)可分为实测、设定、联合运算;实测所得的值可称为实测数据(或实测值)、设定所得的数据称为设定数据(或设定值)、联合运算所得(也即基于车辆运动平衡计算公式计算所得)的数据称为联合运算数据(或联合运算值);设定数据(或设定值)可分为系统设定数据、人工设定数据;系统设定数据也即非人工设定的数据。Differentiating from the access route, the data (or the value of the parameter) can be divided into actual measurement, setting, and joint operation; the measured value can be called measured data (or measured value), and the set data is called setting data ( The data obtained by the joint operation (that is, calculated based on the vehicle motion balance calculation formula) is called joint operation data (or joint operation value); the setting data (or set value) can be divided into system settings. Data, manual setting data; system setting data is data that is not manually set.
综合时间与获取途径的属性,数据(或参数的值)可进一步分为:当前的实测数据(或实测值)、当前的联合运算数据(或联合运算值)、当前的设定数据(或设定值)、过去的实测数据(或实测值)、过去的预设数据(或预设值)、过去的联合运算数据(或联合运算值)等;该过去的联合运算数据(或联合运算值)也即时间在先的联合运算数据(或联合运算值); The time of the integration time and the acquisition route, the data (or the value of the parameter) can be further divided into: the current measured data (or measured value), the current joint operation data (or joint operation value), the current setting data (or Fixed value), past measured data (or measured value), past preset data (or preset value), past joint operation data (or joint operation value), etc.; past joint operation data (or joint operation value) ) that is, the time-first joint operation data (or joint operation value);
基于本领域技术人员或公知常识课理解的:在实际应用(例如安全监控)中,当前的实测数据(或实测值)、当前的联合运算数据(或联合运算值)是常见的;而当前的设定数据(由机器或人工当前设定一个数据)用于当前的实际应用,是少见的;设定数据通常指已设定的数据(例如已由系统设定的数据、已由人工设定的数据);除明确限定之外(例如限定为“当前的”设定数据),在没有限定说明时,本发明中设定指已设定即预设,设定数据为已设定的数据也即预设数据(也即预设值);在本发明中,过去的实测值、过去的设定值、过去的联合运算值,对于当前的应用来说均属于已设定的数据,也即预设数据。Based on the knowledge of those skilled in the art or common sense courses: in actual applications (such as security monitoring), current measured data (or measured values), current joint operational data (or joint operational values) are common; and current Setting data (currently set by the machine or manually) for the current actual application is rare; setting data usually refers to the set data (such as data that has been set by the system, has been manually set) In addition to the explicit definition (for example, limited to "current" setting data), in the case of no limitation, the setting in the present invention means that the setting is preset, and the setting data is the set data. That is, the preset data (that is, the preset value); in the present invention, the past measured value, the past set value, and the past joint operation value belong to the set data for the current application, That is, preset data.
预设数据(或预设值)进一步的可分为系统预设数据(即系统预设值)、人工预设数据(即人工预设值)、指令数据(或指令值)、当次运行的学习值;该人工预设数据(或人工预设值)也可称为人工输入数据(或人工输入值);当次运行的学习值,简称学习值;The preset data (or preset value) can be further divided into system preset data (ie, system preset value), manual preset data (ie, manual preset value), instruction data (or command value), and current running. Learning value; the manual preset data (or manual preset value) may also be referred to as manual input data (or manual input value); the learning value of the current running, referred to as the learning value;
人工预设数据(即人工预设值即人工输入值),指车辆操控人员根据实际情况,现场设置的值;The manual preset data (ie, the manual preset value, that is, the manual input value) refers to the value set by the vehicle controller according to the actual situation;
指令数据(即指令值即指令),也可称为指令预设数据(或指令预设值),具有该参数的控制功能;为车辆的机械运行参数(尤其为速度和/或加速度)和/或源动力参数(尤其为其中推力或)等数据的控制指令数据(或指令值),用于控制车辆的机械运行参数(尤其为速度和/或加速度)和/或源动力参数(尤其为其中推力或)等参数的目标数据(或目标值);如当前速度为100KM/H,当系统发出200KM/H速度的指令数据(或指令值),车辆需要一个加速过程才能到达目标速度;The command data (ie, the command value is the command) may also be referred to as command preset data (or command preset value), with the control function of the parameter; for the mechanical operating parameters of the vehicle (especially speed and / or acceleration) and / Or control command data (or command value) of data such as source dynamic parameters (especially for thrust or) therein, for controlling mechanical operating parameters of the vehicle (especially for speed and / or acceleration) and / or source dynamic parameters (especially for Target data (or target value) of parameters such as thrust or); if the current speed is 100KM/H, when the system issues command data (or command value) of 200KM/H speed, the vehicle needs an acceleration process to reach the target speed;
当次运行的学习值,通常指在当次运行流程中,根据满足设定条件时进行车辆运动平衡计算所获取的数值,本发明中根据满足设定条件时进行车辆运动平衡计算所获取的联合运算值是指该联合运算值是通过预先进行的车辆运动平衡计算所得,因此也可以理解为根据预先获取的联合运算值所得;The learned value of the secondary operation generally refers to the value obtained by calculating the vehicle motion balance calculation according to the set condition in the current running flow, and the joint obtained by calculating the vehicle motion balance according to the set condition in the present invention. The calculated value means that the joint operation value is calculated by pre-calculating the vehicle motion balance, and therefore can also be understood as being obtained according to the joint operation value obtained in advance;
系统预设数据(即系统预设值)包括历史记录值、模糊算法值、系统默认值The system preset data (that is, the system preset value) includes the history value, the fuzzy algorithm value, and the system default value.
历史记录值,通用名词;通常指通过去已经历的、已学习记录的值;历史记录值,包括历史记录原值、历史记录实际值、历史记录关联因子值等,其具体形成方式见后文所述;Historical value, general noun; usually refers to the value of the learned record that has been experienced by going through; the historical record value, including the original value of the historical record, the actual value of the historical record, the value of the historical record correlation factor, etc., the specific formation method is described later. Said
模糊算法值,指通过设定的模糊算法规则获取的值(详见后续内容);The fuzzy algorithm value refers to the value obtained by the set fuzzy algorithm rule (see the following for details);
系统默认值,是最简单的数据设置方式,显而易见的,也即系统默认(准确)的数值;系统默认值可包括出厂默认值、修正或调整后的默认值;出厂默认值也即出厂时默认的数值,原始数值;通常情况下,系统默认值可比出厂默认值应用更广泛;The system default value is the simplest data setting method. Obviously, the system default (accurate) value; the system default value can include the factory default value, the corrected or adjusted default value; the factory default value is also the factory default. Value, raw value; in general, system defaults can be applied more widely than factory defaults;
实测数据(或实测值)相对易于理解,指基于传感器(或硬件设施、仪器等)测量所得的数值;本发明中,实测即测量即检测;如油表测量所得的燃料质量值,如速度测量仪器测量所得的车辆速度,如加速度传感器测量所得的加速度,如倾角测量仪测量所得的迎角、路面坡度,等;基于卫星导航系统(如北斗或GPS)信息测量所得的位置、速度的值,也属于实测值,该卫星导航系统(如北斗或GPS)信息可理解一种无线电定位、测量信息。基于实测所得的数据再经过常规计算所得数 据,称为实测推算值,也属于实测值;例如,先实测转矩T,再除以半径得到力,该力也称为实测值;特别声明:基于部分实测数据(例如源动力参数)再进行车辆运动平衡计算所得结果(该方式为本发明的核心点),不属于实测值,其属于联合运算值;The measured data (or measured value) is relatively easy to understand, and refers to the value measured based on the sensor (or hardware facility, instrument, etc.); in the present invention, the actual measurement is the measurement, that is, the detection; for example, the fuel mass value obtained by the oil meter measurement, such as the velocity measurement. The measured vehicle speed, such as the acceleration measured by the acceleration sensor, such as the angle of attack measured by the inclination meter, the slope of the road, etc.; the value of the position and velocity measured based on the information of the satellite navigation system (such as Beidou or GPS). Also belonging to the measured value, the satellite navigation system (such as Beidou or GPS) information can understand a kind of radio positioning and measurement information. Based on the measured data, the data is calculated by routine calculation. According to what is called the measured value, it is also the measured value; for example, the torque T is measured first, and then divided by the radius to obtain the force, which is also called the measured value; special statement: based on part of the measured data (such as source dynamic parameters) The result of vehicle motion balance calculation (this method is the core point of the invention), which is not a measured value, and belongs to a joint operation value;
从值域上区分,数据(或参数的值)可分为最大值(也即上限值)、最小值(也即下限值)、中间值或中心值;Distinguishing from the value range, the data (or the value of the parameter) can be divided into a maximum value (ie, an upper limit value), a minimum value (ie, a lower limit value), an intermediate value, or a center value;
从数据的性质上区分,数据可分实际值、指令数据(或指令值)、合理范围(包括合理值)、安全范围(安全值)、特殊意义值等;因为指令数据(或指令值)在安全上具有特殊的意义,也允许将其从预设数据中划出作为一种独立的数据类型;Distinguish from the nature of the data, the data can be divided into actual value, instruction data (or instruction value), reasonable range (including reasonable value), safety range (safety value), special meaning value, etc.; because the instruction data (or instruction value) is Security has a special meaning, and it is also allowed to be drawn from the preset data as an independent data type;
以本领域技术人员所知的常识,或基于本文主要内容可理解的:本发明所述实际值与真实值是有区别的概念;真实值通常为某参数某一属性的自然的、真实的数值;例如某一车辆的空载质量m0为1500KG,运载物品质量共200KG(例如人为150KG,货物为50KG),在假设其他质量为零时,该车辆总质量的真实值为1700KG;如果在某一时刻设定车辆总质量的实际值(例如人工输入、或进行一次车辆运动平衡计算),因可理解的误差、精度等因素,该车辆总质量的实际值很可能被设为1680KG,则该1680KG可视为车辆总质量的在设定时的实际值(但并非真实值);实际值作为本发明中一种可实际操作的数据,实际值的大小自然与该参数的设定时间、设定方式、设定精度等多种因素有关;在没有限定说明时,本文中参数的实际值指与该参数设定时的真实值接近或相等的数值;例如,当实际值为根据预设值设定时该实际值也即为预设时该参数的实际值;例如,当参数的实际值为根据其预设值中系统默认值设定时,该实际值也即为该参数在系统默认(通常也即标准状态下)的实际值(也即标定值);例如,当实际值的设定方式为基于学习方式设定时,该实际值也即为进行学习时的实际值(也即学习值);如果没有任何限定说明时,实际值指该参数在进行某一实际应用中(例如本发明中任一测算方法、监控方法、监视方法或处理方法中)获取输入参数的值的获取时间的当前状态的实际值,也即该参数的当前值。本发明中,在没有限定说明时,当前或当前时间,指某一实际应用中(例如本发明中任一测算方法、监控方法、监视方法或处理方法中)获取输入参数的值的获取时间;本发明中,在没有任何限定说明时,参数的实际值为该参数当前的实际值;在没有限定说明时,参数的当前值也为该参数当前的实际值。It is understood by common knowledge known to those skilled in the art, or based on the main content of the present invention: the actual value and the true value of the present invention are different concepts; the real value is usually a natural and true value of a certain attribute of a certain parameter. For example, the no-load mass m0 of a certain vehicle is 1500KG, and the mass of the carried goods is 200KG (for example, 150KG for people and 50KG for goods). When the other mass is zero, the true value of the total mass of the vehicle is 1700KG; Set the actual value of the total mass of the vehicle at any time (for example, manual input, or perform a vehicle motion balance calculation). The actual value of the total mass of the vehicle is likely to be set to 1680KG due to comprehensible error, accuracy, etc., then the 1680KG It can be regarded as the actual value of the total mass of the vehicle at the time of setting (but not the actual value); the actual value is a kind of practical data in the present invention, and the actual value is naturally set with the setting time and setting of the parameter. The method, setting accuracy, and other factors are related; when there is no limit, the actual value of the parameter in this paper refers to the value that is close to or equal to the true value when the parameter is set; for example, when When the actual value is set according to the preset value, the actual value is also the actual value of the parameter when preset; for example, when the actual value of the parameter is set according to the system default value in the preset value, the actual value is also That is, the actual value (that is, the calibration value) of the parameter in the system default (usually, the standard state); for example, when the actual value is set based on the learning mode, the actual value is also learning. Actual value (ie, learning value); if there is no limit, the actual value means that the parameter is in a practical application (for example, in any measurement method, monitoring method, monitoring method or processing method in the present invention) Gets the actual value of the current state of the acquisition time of the value of the input parameter, ie the current value of the parameter. In the present invention, the current or current time refers to the acquisition time of the value of the input parameter in a practical application (for example, in any of the measurement methods, monitoring methods, monitoring methods, or processing methods of the present invention); In the present invention, the actual value of the parameter is the current actual value of the parameter without any limitation; when there is no limit, the current value of the parameter is also the current actual value of the parameter.
本发明中,任一方案或数据均可等效替换入其他技术方案中;本发明中任一公式均可任意变形,以将该公式中任一参数移至公式等号左边作为目标参数(或测算对象),且将其他参数等效放至右边计算出该目标参数(或测算对象);本发明中所述变形均为等效的变形;In the present invention, any scheme or data can be equivalently substituted into other technical solutions; any formula in the present invention can be arbitrarily modified to move any parameter of the formula to the left of the equation equal sign as a target parameter (or Calculating the object), and putting other parameters equivalently to the right to calculate the target parameter (or measuring object); the deformations in the present invention are equivalent deformations;
车辆运行参数:所有对车辆运行状态有影响的参数,和/或所有与车辆运行相关的参数,和/或车辆相关所有参数均可简称为车辆运行参数;本发明所述的源动力参数、车辆质量、系统运行参数(包括其中的机械运行参数、系统固有参数、质量变化型物品质量),均属于车辆运行参数;;本文中参数并非指单一的参数,也可为多个参数或参数组;本文中系统运行参数也即系统运行参数组; 本发明中未一一例举说明的其他参数,均可按本发明的构思,参考参数取值途径、技术特性相应的归类。Vehicle operating parameters: all parameters that have an impact on the operating state of the vehicle, and/or all parameters related to vehicle operation, and/or all vehicle related parameters may be referred to simply as vehicle operating parameters; source dynamic parameters, vehicles as described herein The quality and system operating parameters (including the mechanical operating parameters, the inherent parameters of the system, and the mass of the quality-changing items) are all vehicle operating parameters; the parameters in this paper do not refer to a single parameter, but may also be multiple parameters or parameter groups; In this paper, the system operation parameters are also the system operation parameter groups; Other parameters not described in the present invention may be classified according to the concept of the present invention with reference to the parameter value path and technical characteristics.
车辆的源动力参数的定义;能代表或计算出直接驱动车辆纵向运行的力或转矩或功率的参数即为源动力参数,源动力参数为基于车辆的动力系统生成;源动力即动力;The definition of the source power parameter of the vehicle; the parameter that can represent or calculate the force or torque or power that directly drives the longitudinal operation of the vehicle is the source power parameter, the source power parameter is generated based on the vehicle's power system; the source power is the power;
其中,电气动力参数包括电机驱动参数、后端的电气动力参数等;本发明将具有电气参数属性的电气动力参数归类于电机驱动参数(也可称为电气驱动参数或前端的电气动力参数);Wherein, the electrical power parameters include motor drive parameters, electrical power parameters of the rear end, etc.; the present invention classifies electrical power parameters having electrical parameter properties into motor drive parameters (also referred to as electrical drive parameters or front end electrical power parameters);
本发明所述车辆质量(也即车辆质量参数)主要包括如下参数:运载物品质量m1、包含运载物品质量的数据如车辆总质量m2;在没有特殊说明时,车辆质量优先指车辆总质量,该车辆总质量可用m2表示(也可用m表示);质量单位可用公斤(KG或kg)表示;车辆总质量m2通常由运载物品质量m1、空载质量m0、质量变化型物品质量mf构成;车辆总质量m2、运载物品质量m1、空载质量m0、质量变化型物品质量中任一或多种参数均可称为车辆质量。The vehicle quality (that is, the vehicle quality parameter) of the present invention mainly includes the following parameters: the mass of the carried item m1, the data including the mass of the carrying item such as the total mass m2 of the vehicle; and the vehicle quality priority refers to the total mass of the vehicle, unless otherwise specified, The total mass of the vehicle can be expressed by m2 (also denoted by m); the mass unit can be expressed in kilograms (KG or kg); the total mass m2 of the vehicle is usually composed of the mass of the carried item m1, the no-load mass m0, and the quality-variable item mass mf; Any one or more of the mass m2, the carrying item mass m1, the no-load mass m0, and the mass-changing item quality may be referred to as vehicle mass.
运载物品质量m1特指车辆净重以外的所装载的人员物品的质量,也可称为运载物品质量;The mass of the carried item m1 refers specifically to the quality of the loaded personnel items other than the net weight of the vehicle, and may also be referred to as the quality of the carried item;
空载质量m0为车辆空载时质量或净质量;其可通过预设(例如读取厂家参数等)或磅秤称量准确得知,无须测算;The no-load mass m0 is the quality or net mass of the vehicle when it is empty; it can be accurately known by preset (for example, reading factory parameters, etc.) or weighing on the scale, without counting;
质量变化型物品质量mf指运行过程中可变的质量;mf主要包括燃料质量,所以在计算时可以用燃料质量替代质量变化型物品质量进行计算;The quality change item quality mf refers to the variable quality during operation; mf mainly includes the fuel quality, so the fuel quality can be used to calculate the mass of the quality change item in the calculation;
本发明所述系统运行参数(也即系统运行参数组),是指车辆运行参数中除车辆质量和源动力参数之外的所有参数;本发明所述系统运行参数组主要包括如下3类参数:机械运行参数、系统固有参数、质量变化型物品质量。车辆的系统运行参数实质为代表动力传递的基础条件和/或车辆的固有属性和/或环境固有属性和/或车辆在动力作用下产生的运动结果的参数。The system operating parameter (ie, the system operating parameter group) of the present invention refers to all parameters except vehicle quality and source power parameters in the vehicle operating parameters; the system operating parameter group of the present invention mainly includes the following three types of parameters: Mechanical operating parameters, system intrinsic parameters, quality of quality changes. The system operating parameters of the vehicle are substantially parameters representative of the underlying conditions of power transmission and/or the inherent properties of the vehicle and/or the inherent properties of the environment and/or the results of the motion produced by the vehicle under the action of power.
本发明所述机械运行参数:(除了源动力参数和车辆质量之外的)车辆运行参数中该参数的大小(也即幅值)可由操控人员控制的参数为机械运行参数;和/或:(除了源动力参数和车辆质量之外的)车辆运行参数中的需测量的参数为机械运行参数;The mechanical operating parameter of the present invention: (in addition to the source dynamic parameter and the vehicle mass), the size (ie, the amplitude) of the parameter in the vehicle operating parameter can be controlled by the operator as a mechanical operating parameter; and/or: ( The parameter to be measured in the vehicle operating parameters other than the source dynamic parameters and the vehicle mass is the mechanical operating parameter;
系统固有参数:指与车辆和/或环境固有属性相关的参数;和/或:(除了源动力参数和车辆质量之外的)车辆运行参数中该参数的大小(也即幅值)不由操控人员控制的参数为系统固有参数;和/或:(除了源动力参数和车辆质量之外的)车辆运行参数中的可预设的参数为系统固有参数;和/或:(除了源动力参数和车辆质量之外的)车辆运行参数中的不可测量的参数为系统固有参数;本发明所述系统固有参数也可称为系统设定参数;System intrinsic parameters: refers to parameters related to the inherent properties of the vehicle and/or the environment; and/or: (in addition to the source dynamic parameters and vehicle mass) the size (ie amplitude) of the parameter in the vehicle operating parameters is not controlled by the operator The parameters of the control are inherent parameters of the system; and/or: (in addition to the source dynamic parameters and the mass of the vehicle) the predefinable parameters in the vehicle operating parameters are system intrinsic parameters; and/or: (except the source dynamic parameters and the vehicle) The unmeasurable parameter in the vehicle operating parameter other than the mass is a system inherent parameter; the system inherent parameter of the present invention may also be referred to as a system setting parameter;
衍生参数:本发明所述任何参数,在其基础上衍生、变形、变名、扩大、缩小、增加偏移值、进行滤波、加权、平均、估计干扰、补偿干扰、RLS算法处理、递归最小二乘方处理等等处理所得参数,均称为参数的衍生参数,所有衍生参数仍然属于原参数类型;OK;Derived parameters: any parameters described in the present invention, derived, deformed, renamed, expanded, reduced, increased offset values, filtered, weighted, averaged, estimated interference, compensated interference, RLS algorithm processing, recursive minimum two The parameters obtained by the power processing and the like are all referred to as derived parameters of the parameters, and all the derived parameters still belong to the original parameter type; OK;
本发明中所述第三范围,也可称为常规范围(也即合规范围,也即符合规定或约定的范围), 第三范围可指该参数的正常范围或标定范围或额定范围;标定范围指该参数处于预设或合理的标定状态时的范围,标定状态也即标称状态或标准状态;标定范围也可标称范围或标准范围;额定范围指该参数处于预设或合理的额定状态时的范围;The third range described in the present invention may also be referred to as a conventional range (that is, a compliance range, that is, a range conforming to a regulation or agreement). The third range may refer to the normal range or calibration range or rated range of the parameter; the calibration range refers to the range when the parameter is in a preset or reasonable calibration state, and the calibration state is also a nominal state or a standard state; the calibration range may also be marked The range or standard range; the rated range refers to the range when the parameter is at a preset or reasonable rated state;
相应的,本发明中所述参数的常规值(也即合规值);常规值可为该参数的正常值或标定值或额定值;参数的正常值指参数的正常范围中的值,且优选为正常范围中的中心值;参数的标定值指参数的标定范围中的值,且优选为标定范围中的中心值;标定值也可称为标称值或标准值;参数的额定值指参数的额定范围中的值,且优选为额定范围中的中心值;显而易见的,参数的常规值通常为第三范围中的值。Correspondingly, the conventional value (ie, the compliance value) of the parameter in the present invention; the normal value may be the normal value or the calibration value or the rated value of the parameter; the normal value of the parameter refers to the value in the normal range of the parameter, and It is preferably a central value in the normal range; the calibration value of the parameter refers to the value in the calibration range of the parameter, and is preferably the central value in the calibration range; the calibration value may also be referred to as a nominal value or a standard value; the nominal value of the parameter refers to The value in the nominal range of the parameter, and preferably the center value in the nominal range; it is obvious that the conventional value of the parameter is typically the value in the third range.
本发明中所述第四范围,指该参数的安全范围;车辆运行参数的安全范围(也可称为安全极限阈值或安全许可值或安全阈值或安全极限阀值或安全阀值或安全值),通常为防止出现运行状况异常或导致运行安全事故产生的该车辆运行参数的预设值,或为根据动力装置或动力控制装置或能源供应装置设计规格而制定的避免器件损坏的预设值,如电流安全值I_ena,电压安全值U_ena,驱动转矩安全值T_ena,功率安全值P_ena等;参数的安全值,还可包括根据该车辆运行参数的自然极限属性设定的值;如运载物品质量的安全范围中上限值自然为车辆最大载重安全值m_ena(也可称为法定装载量或车辆最大安全载重质量),运载物品质量的安全范围中下限值自然为0;车辆总质量的安全值为空载质量与运载物品质量的安全值之和;如剩余燃料质量mf0的安全范围中上限值自然为燃料容器所能装载的该型号燃料最大体积的燃料质量,剩余燃料质量mf0的安全范围中下限值自然为0;燃料消耗率fm2的安全范围中上限值自然为各种极限状态(如最大载重、最大坡度、最大坡度、最大速度、最大加速度、燃料供应管路所能提供的单位时间内最大燃料供应量等参数等)综合决定的极限值,燃料消耗率fm2的安全范围中下限值自然为0;本发明中,安全范围中下限值也即安全值中最小值;安全范围中上限值也即安全值中最大值;The fourth range described in the present invention refers to the safety range of the parameter; the safety range of the vehicle operating parameter (also referred to as the safety limit threshold or safety permission value or safety threshold or safety limit threshold or safety threshold or safety value) a preset value for the vehicle operating parameter that is generally generated to prevent an abnormality in operating conditions or a safety accident, or a preset value for avoiding device damage according to a power plant or a power control device or an energy supply device design specification. Such as current safety value I_ena, voltage safety value U_ena, driving torque safety value T_ena, power safety value P_ena, etc.; the safety value of the parameter may also include a value set according to the natural limit attribute of the vehicle operating parameter; The upper limit of the safety range is naturally the maximum load safety value m_ena (also known as the legal load or the maximum safe load mass of the vehicle). The lower limit of the safety range of the quality of the carried goods is naturally 0; the total mass of the vehicle is safe. The value is the sum of the safe value of the no-load mass and the quality of the carried goods; for example, the upper limit of the safety range of the remaining fuel mass mf0 is naturally The fuel tank can be loaded with the maximum mass of fuel of this type of fuel, and the lower limit of the safety range of the remaining fuel mass mf0 is naturally 0; the upper limit of the safety range of the fuel consumption rate fm2 is naturally various limit states (such as maximum Load limit, maximum slope, maximum slope, maximum speed, maximum acceleration, parameters such as the maximum fuel supply per unit time that can be supplied by the fuel supply line, etc.) The comprehensive limit value, the lower limit of the safety range of the fuel consumption rate fm2 Naturally, it is 0; in the present invention, the lower limit value of the safety range is also the minimum value of the safety value; the upper limit value of the safety range is also the maximum value of the safety value;
参数的可接受范围(也即合理范围),指该参数的能实现某一具有实用价值的用途或表示该参数(包括输入参数)自然属性的范围;本发明中所述可接受范围,既可为第三范围也可为第四范围也可为第二范围,视用途而定;例如本发明所述的动力传递状况识别、车辆动力传递异常进行监控、反映、分析车辆的待监控的动力传动部件的运行状况(磨损和/或安全的状况)、分析车轮形变(失圆度)和/或车轮磨损的状况、与车辆运行安全相关数据进行监视、与车辆运行安全相关数据进行处理中任意一种或多种用途,均为某一具有实用价值的用途;在没有限定说明时,本发明中范围均为可接受范围(也即合理范围)An acceptable range of parameters (ie, a reasonable range) means that the parameter can achieve a useful value or a range of natural attributes of the parameter (including the input parameter); the acceptable range described in the present invention can be The third range may also be the fourth range or the second range, depending on the application; for example, the power transmission condition identification, the vehicle power transmission abnormality monitoring, reflecting, and analyzing the vehicle's power transmission to be monitored Any of the operating conditions (wear and/or safety conditions) of the components, analysis of wheel deformation (out of roundness) and/or wheel wear, monitoring of data related to vehicle operating safety, and processing of data related to vehicle operation safety One or more uses are for a practical use; in the absence of a limitation, the scope of the invention is an acceptable range (ie, a reasonable range).
从值域角度分析,通常来说,第三范围在第四范围之内;本发明中第二许可范围可简称为第二范围;第一许可范围可简称为第一范围;第二范围是本发明提出的一种具有特殊意义的范围,该范围可用于动力传递状况的识别;当某一参数为需测量参数(也即可变参数)时,该参数的第二范围可随参数的实际值的正常变化而浮动,甚至跟随实际值而曲线浮动;其既可在第三范围之内也可超 出第三范围;其绝对值既然可远小于第四范围的绝对值,在某些特殊场合时也可大于第四范围的绝对值;当某一参数为可预设参数时,该参数的第二范围可与可接受范围重合,也可在可接受范围之内;From the perspective of the value range, generally, the third range is within the fourth range; in the present invention, the second permission range may be simply referred to as the second range; the first permission range may be simply referred to as the first range; the second range is The invention proposes a range with special significance, which can be used for the identification of the power transmission condition; when a certain parameter is a parameter to be measured (that is, a variable parameter), the second range of the parameter can be the actual value of the parameter. The normal change and float, even with the actual value and the curve floats; it can be within the third range or super The third range; the absolute value can be much smaller than the absolute value of the fourth range, and can be greater than the absolute value of the fourth range in some special occasions; when a certain parameter is a presettable parameter, the parameter The second range may coincide with the acceptable range or within the acceptable range;
显而易见的,车辆运行参数的第一范围、第二范围、第三范围、第四范围、可接受范围中任意一种或多种均可预设,均可为预设值(尤其是系统预设值,其次也可为人工输入值);任一参数均可预设其标准值、第三范围、第四范围;例如:重力加速度g的标准值可预设为9.81;重力加速度g的第三范围可预设为(9.5~`10.5),重力加速度g的第四范围可预设为(8.5~`11.5),等等;且任一参数的标准值、第三范围、第四范围中任一数据均可根据现场情况、实际情况预设、调整。Obviously, any one or more of the first range, the second range, the third range, the fourth range, and the acceptable range of the vehicle operating parameters may be preset, and may be preset values (especially system presets) The value can also be a manual input value); any parameter can preset its standard value, third range, and fourth range; for example, the standard value of gravitational acceleration g can be preset to 9.81; the third of gravitational acceleration g The range can be preset to (9.5 ~ `10.5), the fourth range of gravitational acceleration g can be preset to (8.5 ~ `11.5), and so on; and the standard value, the third range, and the fourth range of any parameter A data can be preset and adjusted according to the site conditions and actual conditions.
本发明中,所有未详细解释的参数或数据或方案,均可通过本发明提供的技术方案或构思进行合理解释、描述、归纳;且可结合现有技术、公知常识进行。All of the parameters or data or solutions that are not explained in detail in the present invention can be reasonably explained, described, and summarized by the technical solutions or concepts provided by the present invention; and can be combined with the prior art and common knowledge.
本发明中,所有预设的数据(也即预设值(尤其是系统预设值))可通过车辆的生产服务厂商、专业检测机构、人工试凑法、有限次试验、型式试验、现有技术中任一或多种途径得知;用户也可驾驶车辆自行测试、验证、调整、设置;如因参数的预设的数据(也即预设值(尤其是系统预设值))的偏差甚至错误造成本监控方法的监控效果下降,不影响本技术方案的有效性;本发明中,设定即预设;In the present invention, all preset data (that is, preset values (especially system preset values)) can pass through the vehicle production service manufacturer, professional testing organization, manual trial and error method, limited trial, type test, existing Knowing in any one or more ways of the technology; the user can also test, verify, adjust, and set the vehicle by itself; such as the deviation of the preset data (that is, the preset value (especially the system preset value)) Even the error causes the monitoring effect of the monitoring method to decrease, and does not affect the effectiveness of the technical solution; in the present invention, the setting is preset;
显而易见的,本发明所述运行主要指车辆与地面设施无机械连接的运行。Obviously, the operation of the present invention mainly refers to the operation of the vehicle without mechanical connection with the ground facility.
本发明可测参数,也即可测量的参数,通常指在车辆运行中该参数的值可由实测途径获取;本发明不可测参数即不可测量的参数,通常指在车辆运行中该参数的值无法实测途径获取;可测或不可测,是由车辆的硬件条件决定;如未设置可测量该参数的传感器,或传感器工作不正常,均为不可测;高配置、高性能的车辆自然可测参数多;低配置、低成本的车辆则可设置更少的传感器;轮胎半径仅仅能在静止时,在运行中通常不可测;车辆总质量可通过磅秤称量,在运行中通常无法测量;通常来说,例如速度、源动力参数、纵向加速度、风阻fw、质量变化型物品质量(尤其为其中的燃料质量)均属于可测量的参数;大部分的系统固有参数,例如空载车体质量m0、效率系数、滚阻系数f、综合传动比im、驱动轮半径R1(也可用R表示)、重力加速度g,与气缸活塞相连的发动机输出曲柄的等效半径R0、机械传动系统的效率系数Km在运行中通常是不可测参数;不可测量的参数的取值通常只能预设或通过车辆运动平衡计算取值。The invention can measure the parameter, that is, the parameter that can be measured, generally refers to the value of the parameter in the running of the vehicle can be obtained by the measured way; the unmeasurable parameter of the invention is the parameter that cannot be measured, generally refers to the value of the parameter in the running of the vehicle cannot be Measured or unmeasurable, determined by the hardware condition of the vehicle; if the sensor that can measure the parameter is not set, or the sensor is not working properly, it is untestable; the high-configuration, high-performance vehicle naturally measurable parameter More; low-profile, low-cost vehicles can be set with fewer sensors; the tire radius can only be measured at rest, and is usually unmeasurable during operation; the total mass of the vehicle can be weighed by the scale, which is usually not measurable during operation; Said, for example, speed, source dynamic parameters, longitudinal acceleration, wind resistance fw, mass change type of goods (especially the fuel quality therein) are all measurable parameters; most of the system inherent parameters, such as empty body mass m0, Efficiency coefficient, rolling resistance factor f, integrated gear ratio im, drive wheel radius R1 (also denoted by R), gravitational acceleration g, and cylinder piston phase Equivalent radius crank engine output R0, the efficiency of mechanical transmission coefficient Km is generally undetectable in operation parameter; parameter value is typically not measurable or only by a predetermined movement of the vehicle is calculated equilibrium value.
本发明可预设参数是指在车辆正常工作时,该参数的最大值与最小值的差值的绝对值在预设范围之内,也即基于预设所获取的参数的值与该参数的当前值的差值在预设的合理的(或规定的)范围内,也即基于预设所获取的参数的值可用于描述该参数的真实状况;例如空载车体质量m0、效率系数、滚阻系数、综合传动比im、重力加速度、轮胎半径等均属于可预设参数;通常来说,可预设参数的值可基于预设值设定,该预设值通常为标定值;如轮胎的半径,其标定值可为车辆出厂预设的值;重力加速度以及轮胎半径等的标定值就等于车辆出厂时预设的值;滚阻系数的标定值等于该 类型轮胎在预设类型路面(水泥路、沥青路等)上的理论值。该标定值可以是一个固定的值,也可以是可变的函数值,如上述的效率系数,是一个随时间和/或行驶总路程变化而逐渐递减的函数。The preset parameter of the present invention means that when the vehicle is working normally, the absolute value of the difference between the maximum value and the minimum value of the parameter is within a preset range, that is, the value of the parameter obtained based on the preset and the parameter. The difference of the current value is within a predetermined reasonable (or prescribed) range, that is, the value of the parameter obtained based on the preset can be used to describe the true condition of the parameter; for example, the empty body mass m0, the efficiency coefficient, The rolling resistance coefficient, the integrated gear ratio im, the gravitational acceleration, the tire radius, etc. are all preset parameters; in general, the value of the preset parameter can be set based on a preset value, which is usually a calibration value; The radius of the tire, the calibration value can be the preset value of the vehicle; the calibration value of gravity acceleration and tire radius is equal to the preset value when the vehicle leaves the factory; the calibration value of the rolling resistance coefficient is equal to The theoretical value of the type of tire on a preset type of road surface (cement road, asphalt road, etc.). The calibration value can be a fixed value or a variable function value, such as the efficiency coefficient described above, which is a function that gradually decreases as time and/or total travel distance changes.
本发明需测量的参数,指在车辆正常工作时的某一时刻,基于预设所获取的参数的值与该参数的当前值的差值超过预设的合理的(或规定的)范围,也即基于预设所获取的参数的值不能用于描述该参数的真实状况,无法正常使用,也即该参数的当前值无法通过预设方式获得,该参数为不可预设的参数;通常来说,例如源动力参数、速度、纵向加速度、风阻fw、质量变化型物品质量(尤其为其中的燃料质量)均属于需测量的参数;需测量的参数也可理解为可变参数,在车辆正常工作时,该参数的最大值与最小值的差值的绝对值在预设范围之外;该预设范围可由用户或厂家调整,也即厂家或用户可自由选择需测量的参数的个数,需测量的参数越多则参数的获取精度提高;可预设参数越多则可降低成本;通常来说,需测量的参数和可测参数的值基于传感器的实测值获取。The parameter to be measured according to the present invention means that at a certain moment when the vehicle is in normal working, the difference between the value of the parameter obtained based on the preset and the current value of the parameter exceeds a preset reasonable (or prescribed) range, That is, the value of the parameter obtained based on the preset cannot be used to describe the true state of the parameter, and cannot be used normally, that is, the current value of the parameter cannot be obtained by a preset manner, and the parameter is an unpredeterminable parameter; For example, the source dynamic parameters, speed, longitudinal acceleration, wind resistance fw, mass change type of goods (especially the fuel quality therein) are all parameters to be measured; the parameters to be measured can also be understood as variable parameters, which work normally in the vehicle. The absolute value of the difference between the maximum value and the minimum value of the parameter is outside the preset range; the preset range may be adjusted by the user or the manufacturer, that is, the number of parameters to be measured by the manufacturer or the user is freely selected. The more parameters are measured, the better the accuracy of the parameters is acquired; the more parameters can be preset, the lower the cost; in general, the values of the parameters to be measured and the values of the measurable parameters are based on the actual sensor. Value acquisition.
本发明人在发明构思中之前版本的文件中,为常用的可实施的方案;例如机械运行参数(中的路面坡度)由实测获取,例如系统固有参数中空气密度p0为通过预设获取;该新增加的两技术方案,可在某些型号的车辆中将路面坡度设为可预设参数以降低成本,例如通过预设的地图数据、位置信息读取该道路的路面坡度的预设值;例如可在另一型号的车辆中将空气密度p0作为可测量的参数,以提高在你不同海拔或气温环境中风阻fw的测量精度;所以该新增方案利于进一步的利用车辆运动平衡的计算原理实现更好的监控性能或成本。The inventors in the previous version of the concept of the invention are commonly implemented embodiments; for example, the mechanical operating parameters (the road gradient in the road) are obtained by actual measurement, for example, the air density p0 in the system inherent parameters is obtained by default; The newly added two technical solutions can set the road gradient to a preset parameter to reduce the cost in some models of vehicles, for example, reading preset values of the road gradient of the road by preset map data and position information; For example, the air density p0 can be used as a measurable parameter in another type of vehicle to improve the measurement accuracy of the wind resistance fw in your different altitude or temperature environment; therefore, the new scheme is advantageous for further calculation of the vehicle motion balance calculation principle. Achieve better monitoring performance or cost.
1、基础性的说明:1. Basic explanation:
1.1、本发明主要适用于可以由动力装置控制沿路面或轨道运行的车辆;本发明所述路面包括(水平的或有坡度的)的公路路面,本发明所述的轨道包括(水平的或有坡度的)的铁路轨道;在没有限定说明或附加说明时,本发明所述的运行指纵向运行;1.1. The present invention is primarily applicable to vehicles that can be operated along a road surface or track by a power plant; the road surface of the present invention includes (horizontal or sloped) road surface, and the track of the present invention includes (horizontal or Railway track of a slope; the operation of the present invention refers to longitudinal operation without limitation or additional description;
1.2、动力装置的概述:指能直接驱动车辆沿路面或轨道纵向运行的装置;如普通燃料动力车辆的可提供照明能量的蓄电池,纯制动用的真空泵电机,均不能视为本发明所述的动力装置;1.2. Overview of power plant: refers to the device that can directly drive the vehicle to run longitudinally along the road or track; such as the battery that can provide illumination energy for ordinary fuel-powered vehicles, the vacuum pump motor for pure brake, can not be regarded as the present invention Powerplant
1.2.1、电气动力系统的动力装置为电机;本发明所述的电机,指能直接驱动车辆沿路面或轨道纵向运行的电机,电机主要类型包括而不局限于:交流异步电机、交流同步电机、直流电机、开关磁阻电机、永磁无刷电机、直线电机、轮毂电机等;1.2.1. The power device of the electric power system is a motor; the motor according to the present invention refers to a motor capable of directly driving the vehicle to run longitudinally along the road surface or the track. The main types of the motor include, but are not limited to, an AC asynchronous motor and an AC synchronous motor. , DC motor, switched reluctance motor, permanent magnet brushless motor, linear motor, hub motor, etc.;
1.2.2、燃料动力系统的动力装置指能直接驱动车辆沿路面或轨道纵向运行的燃料发动机;1.2.2. A power plant of a fuel power system means a fuel engine capable of directly driving a vehicle to run longitudinally along a road surface or track;
1.2.3、混合动力系统的动力装置指能直接驱动车辆沿路面或轨道纵向运行的混合动力装置;混合动力装置表示该装置由两种或两种以上的动力(如电机和燃料发动机等)同时直接驱动车辆纵向运行;1.2.3. A powerplant of a hybrid power system is a hybrid power unit that can directly drive a vehicle to run longitudinally along a road surface or track; a hybrid power plant means that the device is powered by two or more types of power (such as a motor and a fuel engine). Directly driving the vehicle in longitudinal operation;
1.3、动力控制装置的概述:1.3, overview of the power control device:
1.3.1、电气动力系统的动力控制装置为电机驱动装置,指能驱动本发明所述电机的装置及其 连接线缆,包括而不局限于:变频器、伺服驱动器、直流电机控制器、开关磁阻电机驱动装置、永磁无刷电机驱动器、直线电机驱动器、具备电机驱动能力的一体化控制器等;如电机通过一个馈电开关直接供电/断电,则该馈电开关,也可视为一种简单的电机驱动装置;1.3.1. The power control device of the electric power system is a motor drive device, and refers to a device capable of driving the motor of the present invention and Connecting cables, including but not limited to: inverters, servo drives, DC motor controllers, switched reluctance motor drives, permanent magnet brushless motor drives, linear motor drives, integrated controllers with motor drive capability, etc.; If the motor is directly powered/powered through a feed switch, the feed switch can also be regarded as a simple motor drive device;
1.3.2、燃料动力系统的动力控制装置为燃料发动机控制系统;1.3.2. The power control device of the fuel power system is a fuel engine control system;
1.3.3、混合动力系统的动力控制装置为混合动力控制系统;1.3.3, the power control device of the hybrid system is a hybrid control system;
1.4、能源供应装置的概述:1.4 Overview of the energy supply device:
1.4.1、电气动力系统的能源供应装置,可称为电源装置,是指能给电机驱动装置、电机、车辆提供驱动能量的装置及其连接线缆,包括动力电池组、氢燃料电池、核能电源、太阳能电源、有轨电力机车的电源等;1.4.1. An energy supply device for an electric power system, which may be referred to as a power supply device, refers to a device that can provide driving energy to a motor drive device, a motor, and a vehicle, and a connection cable thereof, including a power battery pack, a hydrogen fuel cell, and a nuclear power. Power supply, solar power, power supply for rail electric locomotives, etc.;
1.4.2、燃料动力系统的能源供应装置,可称为燃料供应系统,是指能给燃料发动机提供燃料的装置包括燃料容器(如油箱)、燃料输送管(如输油管)、燃料喷射系统(如喷油泵)等;1.4.2. The energy supply device of a fuel power system, which may be referred to as a fuel supply system, refers to a device capable of providing fuel to a fuel engine, including a fuel container (such as a fuel tank), a fuel delivery pipe (such as a fuel pipeline), and a fuel injection system (such as Fuel injection pump), etc.
1.4.3、混合动力系统的能源供应装置,可称为混合能源供应系统,是指能给混合动力控制系统和混合动力装置提供能源的装置,可同时包括包括两种或两种以上的能源供应装置,如燃料供应系统和电源装置等;1.4.3. The energy supply device of a hybrid power system, which may be referred to as a hybrid energy supply system, refers to a device capable of providing energy to a hybrid control system and a hybrid power device, and may include two or more energy supplies at the same time. Devices such as fuel supply systems and power supply units;
1.5、动力系统具体所包含器件的说明:1.5, the description of the specific components of the power system:
1.5.1、本发明所述电气动力系统,所包含器件(也即部件)的范畴视具体的电机驱动参数组信号的采集点而定;1.5.1. The electrical power system of the present invention, the category of the components (ie, components) included depends on the collection point of the specific motor drive parameter group signal;
如源动力参数信号的采集点在电源装置的输入端则电气动力系统同时包含车辆的电源装置、电机驱动装置以及电机三个器件;如源动力参数信号的采集点在电源装置的输出端或电机驱动装置的输入端,则电气动力系统同时包含电机驱动装置、电机两个器件;如源动力参数信号的采集点在电机驱动装置的输出端或电机的输入端,则电气动力系统只包含电机;If the collection point of the source power parameter signal is at the input end of the power supply device, the electric power system includes three components of the power supply device, the motor drive device and the motor of the vehicle; for example, the collection point of the source power parameter signal is at the output end of the power supply device or the motor At the input end of the driving device, the electric power system includes two parts of the motor driving device and the motor; if the collecting point of the source power parameter signal is at the output end of the motor driving device or the input end of the motor, the electric power system only includes the motor;
1.5.2、本发明所述燃料动力系统中,如源动力参数信号的采集点在车辆的燃料喷射系统的燃料输入端则燃料动力系统同时包含车辆的燃料喷射系统、燃料发动机等器件;如源动力参数信号的采集点在车辆的燃料喷射系统的燃料喷射输出端,则燃料动力系统包含燃料发动机等;1.5.2. In the fuel power system of the present invention, if the collection point of the source power parameter signal is at the fuel input end of the fuel injection system of the vehicle, the fuel power system includes the fuel injection system of the vehicle, the fuel engine and the like; The collection point of the power parameter signal is at the fuel injection output end of the fuel injection system of the vehicle, and the fuel power system includes a fuel engine or the like;
1.5.3、本发明所述的动力装置、动力控制装置、能源供应装置,三者主要是从功能上分类;从器件构造上说,可以把三者中任意两者或者三者组合成下述任一种综合系统:动力控制装置和动力装置的二合一综合系统,能源供应装置和动力控制装置的二合一综合系统,能源供应装置和动力控制装置和动力装置的三合一综合系统;本发明的说明书和权利要求范围也包含上述任何一种二合一、三合一综合系统。1.5.3. The power device, the power control device, and the energy supply device according to the present invention are mainly functionally classified; from the device structure, any two or three of the three may be combined into the following. Any one of a comprehensive system: a two-in-one integrated system of power control devices and power plants, a two-in-one integrated system of energy supply devices and power control devices, a three-in-one integrated system of energy supply devices and power control devices and power plants; The specification and claims of the present invention also encompass any of the above two-in-one, three-in-one integrated systems.
1.6、本发明所述的获取参数组或参数的值,获取途径解释如下:1.6. The value of the parameter group or parameter obtained by the present invention is obtained as follows:
1.6.1、参数值的获取,包括而不仅限于如下方式:1.6.1, the acquisition of parameter values, including but not limited to the following:
1.6.1.1、用硬件传感器直接测量参数值: 1.6.1.1. Directly measure parameter values with hardware sensors:
1.6.1.2、先用硬件传感器测量中间参数值,再计算得到参数值;1.6.1.2. First measure the intermediate parameter value with a hardware sensor, and then calculate the parameter value;
1.6.1.3、读取外部设备(如动力控制装置)计算、输出的参数值;1.6.1.3. Read parameter values calculated and output by external devices (such as power control devices);
1.6.1.4、读取系统预设值而获取参数;如滚阻系数等;本发明所述系统预设值也即系统设定值;1.6.1.4, reading a system preset value to obtain a parameter; such as a rolling resistance coefficient; etc.; the system preset value of the present invention is also a system setting value;
1.6.1.5、读取人工输入值而获取参数;1.6.1.5. Read the manual input value and obtain the parameter;
1.6.1.6、读取测算所得数据而获取参数;如读取本发明提供的车辆运行参数的测算方法测算所得的参数值。1.6.1.6, reading the measured data to obtain the parameter; and reading the parameter value obtained by calculating the calculation method of the vehicle operating parameter provided by the present invention.
1.6.2、本发明所述的读取参数值,包括读取本地参数值、通过通讯方式(如CAN、485、232、WIFI、蓝牙、红外等)读取参数值、通过网络传输方式(如各种有线无线网络)远程读取车辆运行参数值等多种方式;1.6.2. The reading parameter value according to the present invention includes reading a local parameter value, reading a parameter value through a communication method (such as CAN, 485, 232, WIFI, Bluetooth, infrared, etc.), and transmitting the data through the network (for example, Various wired and wireless networks) remotely reading vehicle operating parameter values and other methods;
2、车辆的源动力参数的定义;能代表或计算出直接驱动车辆纵向运行的力或转矩或功率的参数即为源动力参数;源动力参数为基于车辆的动力系统生成;根据动力系统种类的不同;可将基于电气动力系统生成的源动力参数称为电气动力参数;将基于燃料动力系统生成的源动力参数称为燃料动力参数;如果同时基于两种或两种以上动力系统而生成的源动力参数称为混合动力参数;显而易见的,该由车辆的动力系统形成的直接驱动车辆纵向运行的力为车辆的动力系统形成的力,可简称为源动力也即动力也即驱动力;因本发明运行为纵向运行,所以该动力也即纵向动力;源动力参数也即动力参数;运行方向指移动方向。2. The definition of the source dynamic parameters of the vehicle; the parameter that can represent or calculate the force or torque or power that directly drives the longitudinal operation of the vehicle is the source dynamic parameter; the source dynamic parameter is generated based on the vehicle's power system; according to the type of the power system The source dynamic parameters generated based on the electric power system may be referred to as electric power parameters; the source dynamic parameters generated based on the fuel power system are referred to as fuel dynamic parameters; if simultaneously generated based on two or more power systems The source power parameter is called a hybrid power parameter; obviously, the force that is directly driven by the vehicle's power system to directly drive the vehicle is the force formed by the power system of the vehicle, which may be simply referred to as source power, that is, power, that is, driving force; The invention operates in a longitudinal direction, so the power is also longitudinal power; the source power parameter is also the power parameter; the running direction refers to the moving direction.
其中,电气动力参数包括电机驱动参数、后端的电气动力参数等;本发明将电机及电机前端(包括电源装置、电机驱动装置等)所获取的具有电气参数属性的电气动力参数归类于电机驱动参数(也可称为电气驱动参数或前端的电气动力参数);本发明将电机后端(电机输出轴、驱动轮、以及电机输出轴和驱动轮之间的中间机械传动部件等)的机械部件上所获取的电气动力参数归类于后端的电气动力参数;The electric power parameter includes a motor driving parameter, an electric power parameter of the rear end, and the like; the present invention classifies an electric power parameter having an electrical parameter property obtained by a motor and a motor front end (including a power supply device, a motor driving device, etc.) into a motor drive. Parameters (also referred to as electrical drive parameters or electrical dynamic parameters of the front end); the mechanical components of the rear end of the motor (motor output shaft, drive wheel, and intermediate mechanical transmission components between the motor output shaft and the drive wheel, etc.) The electrical power parameters obtained above are classified into the electrical dynamic parameters of the back end;
其中,燃料动力参数包括前端的燃料动力参数、后端的燃料动力参数等;所述前端的燃料动力参数通常指燃料发动机输出曲轴前端部件(如发动机汽缸、燃料供应系统等)所获取的燃料动力参数;后端的燃料动力参数主要包括发动机后端(燃料发动机输出轴、驱动轮、以及燃料发动机输出轴和驱动轮之间的中间机械传动部件(包括传动轴、传动齿轮机构等))测量所得的燃料动力参数;Wherein, the fuel power parameter includes a fuel power parameter of the front end, a fuel power parameter of the rear end, and the like; the fuel power parameter of the front end generally refers to a fuel dynamic parameter obtained by the fuel engine output crankshaft front end component (such as an engine cylinder, a fuel supply system, etc.) The fuel dynamic parameters of the rear end mainly include the fuel measured by the engine rear end (fuel engine output shaft, drive wheel, and intermediate mechanical transmission components (including transmission shaft, transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel) Dynamic parameter
混合动力参数也包括前端的混合动力参数、后端的混合动力参数等;The hybrid parameters also include the hybrid parameters of the front end, the hybrid parameters of the back end, and the like;
为了描述便利,可定义一个非电机驱动参数类型的源动力参数,非电机驱动参数类型的源动力参数包括后端的电气动力参数、燃料动力参数、混合动力参数中任意一种或多种源动力参数;For convenience of description, a source dynamic parameter of a non-motor drive parameter type may be defined, and a source dynamic parameter of the non-motor drive parameter type includes any one or more of the source dynamic parameters of the back end electrical power parameter, fuel power parameter, and hybrid power parameter. ;
综合而言,车辆的源动力参数又可分为前端的源动力参数、后端的源动力参数等;其中前端的源动力参数包括前端的电气动力参数(也可称为电机驱动参数或电气驱动参数)、前端的燃料动力参数、前端的混合动力参数等;其中后端的源动力参数又包括后端的电气动力参数、后端的燃料动力 参数、后端的混合动力参数等;In summary, the source power parameters of the vehicle can be further divided into the source power parameters of the front end and the source power parameters of the back end; wherein the source power parameters of the front end include the electrical power parameters of the front end (also referred to as motor drive parameters or electrical drive parameters). ), the fuel dynamic parameters of the front end, the hybrid parameters of the front end, etc.; wherein the source dynamic parameters of the back end include the electrical power parameters of the back end and the fuel power of the back end Parameters, hybrid parameters of the back end, etc.;
特别声明:混合动力车辆,如果在某个时间段车辆的纵向运行仅仅由电机直接驱动则该时间段该混合动力车辆的动力装置为电机(而不称为混合动力装置),则该时间段称为“车辆由电机控制运行时”,所对应的源动力参数为电气动力参数;如果在某个时间段车辆的纵向运行仅仅由燃料发动机直接驱动则该时间段该混合动力车辆的动力装置为燃料发动机(也不能称为混合动力装置),则该时间段称为“车辆由燃料发动机控制运行时”所对应的源动力参数为燃料动力参数;只有在车辆的纵向运行同时由两种或以上的动力系统的直接驱动而实现时该动力装置才为混合动力装置,所对应的源动力参数为混合动力参数;Special statement: Hybrid vehicle, if the longitudinal operation of the vehicle is only directly driven by the motor during a certain period of time, then the power unit of the hybrid vehicle is a motor (not called a hybrid device) during the period, then the time period is called For the "vehicle controlled by the motor", the corresponding source power parameter is the electric power parameter; if the longitudinal operation of the vehicle is only directly driven by the fuel engine during a certain period of time, the power device of the hybrid vehicle is fueled during the time period. The engine (also not called hybrid device), the source power parameter corresponding to the time when the vehicle is controlled by the fuel engine is the fuel power parameter; only when the vehicle is running longitudinally, two or more When the direct drive of the power system is realized, the power device is a hybrid device, and the corresponding source power parameter is a hybrid power parameter;
2.1、车辆的电气动力参数的定义:2.1, the definition of the vehicle's electrical power parameters:
2.1.1、从物理性质上区分,常规的电气参数主要包括而不仅限于如下:电气功率、电磁转矩、电流、电压、电机转速;2.1.1. Distinguishing from physical properties, conventional electrical parameters mainly include, but are not limited to, the following: electrical power, electromagnetic torque, current, voltage, motor speed;
2.1.2、从器件上,可分为电机、电机驱动装置、电源装置的电气参数;2.1.2. From the device, it can be divided into electrical parameters of motor, motor drive device and power supply device;
2.1.3、电机的电气参数主要包括而不仅限于如下参数:电机电压Uo,电机电流Io,功率因素φ1(也可用φ表示),电气功率Po(也可用Pm表示),电磁转矩Te,电机转速n1,旋转磁场转速n0;2.1.3. The electrical parameters of the motor mainly include and are not limited to the following parameters: motor voltage Uo, motor current Io, power factor φ1 (also denoted by φ), electrical power Po (also denoted by Pm), electromagnetic torque Te, motor Rotation speed n1, rotating magnetic field speed n0;
2.1.4、电机驱动装置的电气参数主要包括而不仅限于如下参数:输出电压U2o,输出电流I2o,输出功率因素φ2,输出电气功率P2o,电磁转矩Te,输入电压U2i(也可用Ui表示),输入电流I2i(也可用Ii表示),输入电气功率P2i,驱动器直流母线电压Udc、转矩电流分量iq;2.1.4. The electrical parameters of the motor drive device mainly include and are not limited to the following parameters: output voltage U2o, output current I2o, output power factor φ2, output electrical power P2o, electromagnetic torque Te, input voltage U2i (also denoted by Ui) Input current I2i (also denoted by Ii), input electrical power P2i, driver DC bus voltage Udc, torque current component iq;
转矩电流分量iq,是指矢量控制型电机驱动装置(如变频器或伺服驱动器),经过矢量变换,将电机电流剥离了励磁分量的转矩电流;转矩电流分量iq,与电机转矩具有比较直接的对应关系;通过转矩电流与电磁转矩的转化系数Ki,Ki*iq可用于直接计算转矩;The torque current component iq refers to a vector-controlled motor drive device (such as a frequency converter or a servo drive). After vector transformation, the motor current is stripped of the torque component of the excitation component; the torque current component iq, and the motor torque have Comparing the direct correspondence; the conversion coefficient Ki, Ki*iq through the torque current and the electromagnetic torque can be used to directly calculate the torque;
2.1.5、电源装置的电气参数主要包括而不仅限于如下参数:2.1.5. The electrical parameters of the power supply unit mainly include but are not limited to the following parameters:
通常的电源装置可包含下述输出电气参数:输出电压U3o(也可用Ub1表示),输出电流I3o(也可用Ib1表示),输出电气功率P3o,功率因素φ3;The usual power supply device may include the following output electrical parameters: output voltage U3o (also represented by Ub1), output current I3o (also denoted by Ib1), output electrical power P3o, power factor φ3;
外部供电型(如有轨电力机车的)电源装置还可包含下述输入电气参数:输入电压U3i,输入电流I3i,输入电气功率P3i;The power supply device of the external power supply type (such as the rail electric locomotive) may further include the following input electrical parameters: input voltage U3i, input current I3i, input electrical power P3i;
电机制动时从电机发电回馈入电源装置的电压U4(也可用Ub2表示),电机制动时从电机发电回馈入电源装置的电流I4(也可用Ib2表示)。When the motor brakes, the voltage U4 (which can also be represented by Ub2) fed back into the power supply device from the motor power generation, and the current I4 fed back to the power supply device from the motor when the motor brakes (also indicated by Ib2).
2.1.6、功能连接上相邻的前级输出的电气参数与后级输入的电气参数,在计算时可相互替代;如Uo=U2o,如Io=I2o,如φ1=φ2,如P2o=Po,如电机和电机驱动装置的Te,如U2i=U3o,如I2i=I3o,如P2i=P3o,等。2.1.6. The electrical parameters of the adjacent preamp outputs on the functional connection and the electrical parameters of the subsequent inputs can be substituted for each other in the calculation; for example, Uo=U2o, such as Io=I2o, such as φ1=φ2, such as P2o=Po For example, Te of motor and motor drive device, such as U2i=U3o, such as I2i=I3o, such as P2i=P3o, etc.
2.1.7、电磁转矩Te的特别说明:本发明所述的电磁转矩Te指根据电机的电压或电流或磁场 参数计算所得的电机转矩,包括在电机驱动装置内部计算所得的电磁转矩Te,也包括在电机驱动装置外部通过测量电机电压和电机电流而计算所得的电磁转矩Te;本发明所述的电磁转矩Te的测量非常简便、成本很低、且精度高。电磁转矩Te不包括在电机输出轴或其他机械传动轴或飞轮上安装机械应力测量原理(如动态扭矩测试仪)所得的机械转矩机;两者在测量原理、测量途径、测量的性价比上具有重大区别。2.1.7 Special Description of Electromagnetic Torque Te: The electromagnetic torque Te according to the present invention refers to a voltage or current or a magnetic field according to the motor. The calculated motor torque, including the electromagnetic torque Te calculated inside the motor drive device, also includes the electromagnetic torque Te calculated by measuring the motor voltage and the motor current outside the motor drive device; The measurement of the electromagnetic torque Te is very simple, low in cost, and high in precision. The electromagnetic torque Te does not include the mechanical torque machine obtained by installing the mechanical stress measurement principle (such as the dynamic torque tester) on the motor output shaft or other mechanical drive shaft or flywheel; the two are in the measurement principle, the measurement path, and the cost performance of the measurement. There are significant differences.
2.1.8、本发明所述电气参数,又分为电机驱动参数、电气辅助参数;2.1.8. The electrical parameters of the present invention are further divided into motor drive parameters and electrical auxiliary parameters;
2.1.8.1、常见的电机驱动参数包括而不仅限于下述几种类型:电气功率、电磁转矩、电流、机电组合型参数等:2.1.8.1. Common motor drive parameters include, but are not limited to, the following types: electrical power, electromagnetic torque, current, electromechanical combination parameters, etc.:
2.1.8.1.1、第一种:电气功率;在没有附加说明或限定条件时,本发明所述电气功率均指有功功率;电气功率的获取方式如下:2.1.8.1.1, the first type: electrical power; in the absence of additional instructions or qualifications, the electrical power of the present invention refers to active power; the way to obtain electrical power is as follows:
电气功率值获取方式1:先获取电流和电压,进而通过计算间接获取功率值;如(Uo、Io、φ1),或(U2o、I2o、φ2),或(U2i、I2i),或(U3o、I3o,φ3),或(U3i、I3i);通过电压和电流计算电气功率,属于公知技术;Electrical power value acquisition method 1: first obtain current and voltage, and then indirectly obtain power value by calculation; such as (Uo, Io, φ1), or (U2o, I2o, φ2), or (U2i, I2i), or (U3o, I3o, φ3), or (U3i, I3i); calculating electrical power by voltage and current, is a well-known technique;
电气功率值获取方式2:先获取电磁转矩和电机转速,进而通过计算间接获取功率值;如Te和n1,两参数组合可用于计算功率;P(kw)*9550=Te*n1,则P(w)=Te*n1/9.55;P(kw)表示该功率以KW为单位,P(w)表示该功率以W为单位。Electric power value acquisition method 2: first obtain electromagnetic torque and motor speed, and then indirectly obtain power value through calculation; such as Te and n1, two parameter combination can be used to calculate power; P(kw)*9550=Te*n1, then P (w)=Te*n1/9.55; P(kw) indicates that the power is in KW, and P(w) indicates that the power is in W.
电气功率值获取方式3:直接读取电机驱动装置内部参数而获取电气功率值;如Po,Pm,P2o,P2i,P3o,P3i;Electrical power value acquisition method 3: directly read the internal parameters of the motor drive device to obtain electrical power values; such as Po, Pm, P2o, P2i, P3o, P3i;
电气功率值获取方式4:用有功功率表测量而获取电气功率值;如Po,Pm,P2o,P2i,P3o,P3i;Electrical power value acquisition method 4: Obtain electrical power value by measuring with active power meter; such as Po, Pm, P2o, P2i, P3o, P3i;
2.1.8.1.2、第二种:电磁转矩;如Te,电磁转矩Te的获取方式如下:2.1.8.1.2, second: electromagnetic torque; such as Te, the electromagnetic torque Te is obtained as follows:
电磁转矩Te值获取方式1:直接读取电机驱动装置内部参数而获取Te值;如直接读取变频器或伺服驱动器中的电磁转矩Te值;Electromagnetic torque Te value acquisition mode 1: directly read the internal parameters of the motor drive device to obtain the Te value; such as directly reading the electromagnetic torque Te value in the inverter or servo drive;
电磁转矩Te值获取方式2:先获取电气功率值和电机转速值,进而通过计算间接获取Te值;因为功率P(w)=Te*n1/9.55=U*I,所以在电气功率可测的器件中Te都可经过简易计算计算所得,公式为:Te=P(w)*9.55/n1;Electromagnetic torque Te value acquisition method 2: first obtain the electric power value and the motor speed value, and then indirectly obtain the Te value by calculation; because the power P(w)=Te*n1/9.55=U*I, the electrical power can be measured The Te in the device can be calculated by simple calculation, and the formula is: Te=P(w)*9.55/n1;
电磁转矩Te值获取方式3:通过测量电机驱动装置输出电压和输出电流,进而通过计算间接获取Te值;Electromagnetic torque Te value acquisition mode 3: By measuring the output voltage and output current of the motor drive device, and indirectly obtaining the Te value by calculation;
2.1.8.1.3、第三种:电流;该参数可用于计算转矩和力;iq,Io*cosφ1,I2o*cosφ2,I3o*cosφ3等;在没有附加说明或限定条件时,本发明所述电流,通常指转矩电流分量、或电流中有功分量;2.1.8.1.3, third: current; this parameter can be used to calculate torque and force; iq, Io*cosφ1, I2o*cosφ2, I3o*cosφ3, etc.; without additional explanation or qualification, the present invention Current, usually referred to as the torque current component, or the active component of the current;
电流值获取方式1:直接读取电机驱动装置内部参数而获取电流值; Current value acquisition mode 1: directly reading the internal parameters of the motor drive device to obtain the current value;
电流值获取方式2:用电流传感器测量器件的电流,用功率因素表测量功率因素,进而通过计算而获取电流值;The current value acquisition mode 2: the current sensor is used to measure the current of the device, the power factor factor is used to measure the power factor, and then the current value is obtained by calculation;
单一的转矩或单一电流或单一的功率,均可以成为独立的电机驱动参数;电压与相应的电流参数配合,可成为电机驱动参数;转速与相应的转矩参数配合,可成为电机驱动参数;A single torque or a single current or a single power can be independent motor drive parameters; the voltage can be used as a motor drive parameter in conjunction with the corresponding current parameter; the speed can be a motor drive parameter in conjunction with the corresponding torque parameter;
2.1.8.1.4、第四种:机电组合型参数,指根据前述的电机驱动参数组合计算而成的参数,其具体定义方式见后文描述;2.1.8.1.4, the fourth type: electromechanical combined type parameter refers to the parameter calculated according to the combination of the above-mentioned motor drive parameters, and the specific definition manner thereof is described later;
2.1.8.2、电气辅助参数,指能配合识别电机运行工况、电机状态的参数,主要包括而不仅限于如下参数:电机运行状态字、电机控制命令字等;因为现有的电机驱动装置如变频器可输出加速过流、减速过流、恒速过流等故障信息,所以也可以通过相关的电气辅助参数从电机驱动装置内部获取加速、减速、恒速等运行状态;2.1.8.2. Electrical auxiliary parameters refer to parameters that can be used to identify the operating conditions of the motor and the state of the motor. The main parameters include, but are not limited to, the following parameters: motor running status word, motor control command word, etc.; because existing motor drive devices such as frequency conversion The device can output fault information such as accelerating overcurrent, deceleration and overcurrent, and constant speed overcurrent, so it is also possible to obtain acceleration, deceleration, constant speed and other operating states from the inside of the motor drive device through relevant electrical auxiliary parameters;
电气辅助参数值的获取方式1:读取电机驱动装置内部参数而获取;The method of obtaining the electrical auxiliary parameter value 1: reading the internal parameters of the motor drive device and obtaining;
2.1.9、后端的电气动力参数主要包括电机后端测量所得的驱动转矩、驱动功率、驱动力等;2.1.9. The electrical power parameters of the back end mainly include the driving torque, driving power and driving force measured by the back end of the motor;
2.2、燃料动力参数的定义:2.2. Definition of fuel power parameters:
2.2.1、发动机的燃料动力参数主要包括而不仅限于如下参数:发动机内的燃料消耗率fm1、气缸压力F1,驱动功率Pr1,驱动转矩Tr1,驱动力Ff1,气缸内空气流量C1等;2.2.1. The fuel power parameters of the engine mainly include, but are not limited to, the following parameters: fuel consumption rate fm1 in the engine, cylinder pressure F1, driving power Pr1, driving torque Tr1, driving force Ff1, air flow C1 in the cylinder, and the like;
2.2.2、燃料供应系统的燃料动力参数主要包括而不仅限于如下参数:燃料喷射系统输入侧的燃料消耗率、燃料喷射系统喷射输出侧的燃料消耗率、节气门开度、油门踏板位置、油箱到发动机(或燃料喷射泵)的供油管内燃料消耗率;2.2.2. The fuel power parameters of the fuel supply system mainly include, but are not limited to, the following parameters: the fuel consumption rate on the input side of the fuel injection system, the fuel consumption rate on the injection output side of the fuel injection system, the throttle opening degree, the accelerator pedal position, and the fuel tank. Fuel consumption rate to the fuel supply pipe of the engine (or fuel injection pump);
2.2.3、在发动机后端(燃料发动机输出轴、驱动轮、以及燃料发动机输出轴和驱动轮之间的中间机械传动部件(包括传动轴、传动齿轮机构等))测量所得的燃料动力参数,包括驱动转矩、驱动功率、驱动力等;2.2.3. The fuel dynamic parameters measured at the rear end of the engine (the fuel engine output shaft, the drive wheel, and the intermediate mechanical transmission components (including the drive shaft, transmission gear mechanism, etc.) between the fuel engine output shaft and the drive wheel), Including drive torque, drive power, driving force, etc.
2.2.4、从参数性质分类,常见的燃料动力参数包括而不仅限于下述几种类型:驱动功率、驱动转矩、驱动力、燃料消耗率、气缸压力、燃料动力组合型参数等;为了便于描述、计算和业内人员理解本发明,本发明所述的燃料动力参数通常折算为燃料发动机输出端(一般为输出轴)的燃料动力参数参与计算;当然,在实际应用中,用户也可设定为其他部位的燃料动力参数;2.2.4. From the classification of parameter properties, common fuel dynamic parameters include but are not limited to the following types: drive power, drive torque, driving force, fuel consumption rate, cylinder pressure, fuel-power combined parameters, etc.; The description, calculations, and those skilled in the art understand the present invention. The fuel power parameters of the present invention are generally converted into fuel power parameters of the fuel engine output (generally the output shaft) to participate in the calculation; of course, in practical applications, the user can also set Fuel power parameters for other parts;
2.2.4.1、第一种:驱动功率;2.2.4.1, first: drive power;
驱动功率值获取方式1:某些发动机可通过发动机负荷报告数据获取功率的百分比,再与发动机最大功率相乘就可获取功率值Pr1;Driving power value acquisition mode 1: Some engines can obtain the percentage of power through the engine load report data, and then multiply the maximum power of the engine to obtain the power value Pr1;
驱动功率值获取方式2:先获取信号采集点的转矩和转速,进而通过计算间接获取功率值;如:Pr1(kw)*9550=Tr1*n1,则Pr1(w)=Tr1*n1/9.55;n1为燃料发动机转速;Pr1(kw)表示该功率以KW为单位,Pr1(w)表示该功率以W为单位。Driving power value acquisition mode 2: first obtain the torque and speed of the signal collection point, and then indirectly obtain the power value through calculation; for example: Pr1(kw)*9550=Tr1*n1, then Pr1(w)=Tr1*n1/9.55 N1 is the fuel engine speed; Pr1(kw) means the power is in KW, and Pr1(w) means the power is in W.
2.2.4.2、第二种:驱动转矩;如Tr1,获取方式如下: 2.2.4.2, second: drive torque; such as Tr1, the acquisition method is as follows:
驱动转矩值获取方式1:用转矩传感器测量而获取Tr1值;Driving torque value acquisition mode 1: obtaining a Tr1 value by measuring with a torque sensor;
驱动转矩值获取方式2:先获取信号采集点的驱动功率值和转速值,进而通过计算间接获取转矩值;如:Tr1=Pr1(w)*9.55/n1;Driving torque value acquisition mode 2: first obtain the driving power value and the rotational speed value of the signal collecting point, and then obtain the torque value indirectly through calculation; for example: Tr1=Pr1(w)*9.55/n1;
驱动转矩值获取方式3:某些发动机可通过发动机负荷报告数据获取最大转矩的百分比,再与发动机最大转矩相乘就可获取转矩值;Drive torque value acquisition mode 3: Some engines can obtain the percentage of the maximum torque through the engine load report data, and then multiply the engine maximum torque to obtain the torque value;
2.2.4.3、第三种:驱动力Ff;2.2.4.3, the third type: driving force Ff;
驱动力值获取方式:通过发动机负荷报告数据获取功率值Pr1/或转矩值Tr1,用转矩值再除以相关半径就可获取燃料发动机的驱动力Ff1值;用功率值除以直线运行部件的速度可获取驱动力;或直接用力传感器测量驱动力;The driving force value acquisition method: obtaining the power value Pr1/ or the torque value Tr1 by the engine load report data, and dividing the torque value by the relevant radius to obtain the driving force Ff1 value of the fuel engine; dividing the power value by the linear running part The speed can obtain the driving force; or directly measure the driving force with a force sensor;
2.2.4.4、第四种:气缸压力F1;2.2.4.4, the fourth type: cylinder pressure F1;
气缸压力值获取方式1:用气缸压力传感器获取气缸压力F1的值;通常来说,将F1经过平均/或滤波等处理和相关效率系数转化成燃料发动机的驱动力Ff1,或将该F1转化成燃料发动机的驱动转矩Tr1;气缸压力F1如为瞬间值时,须注意燃烧点火相位;燃料发动机通常为多缸发动机,当单个气缸的活塞处于上止点(或发动机燃烧室空间最小)燃料点火燃烧时所产生的F1瞬间值最大,当活塞下行时F1瞬间值变小;Cylinder pressure value acquisition mode 1: The cylinder pressure sensor is used to obtain the value of the cylinder pressure F1; generally, F1 is converted into a fuel engine driving force Ff1 by averaging/filtering processing and the related efficiency coefficient, or F1 is converted into The driving torque Tr1 of the fuel engine; when the cylinder pressure F1 is an instantaneous value, attention must be paid to the combustion ignition phase; the fuel engine is usually a multi-cylinder engine, when the piston of a single cylinder is at the top dead center (or the engine combustion chamber space is the smallest) fuel ignition The instantaneous value of F1 generated during combustion is the largest, and the instantaneous value of F1 becomes smaller when the piston descends;
2.2.4.5、第五种:燃料消耗率;2.2.4.5, fifth: fuel consumption rate;
燃料消耗率的获取方式:现有技术有上百种燃料消耗率的技术方案,典型如通过流量传感器直接测量流经传感器探头的燃料消耗率、通过燃料喷射系统的喷射频率和脉冲宽度、通过节气门开度、油门踏板位置、歧管压力、真空度等多种信息处理获取燃料消耗率;对于汽油发动机还可通过流经发动机的空气流量推算出燃料消耗率;进一步的所述空气流量还分新鲜空气流量、废气流量等;How to obtain fuel consumption rate: There are hundreds of technical solutions for fuel consumption rate in the prior art, such as directly measuring the fuel consumption rate flowing through the sensor probe through the flow sensor, the injection frequency and pulse width through the fuel injection system, and the passage section. Various information processing such as valve opening degree, accelerator pedal position, manifold pressure, and vacuum degree obtain fuel consumption rate; for gasoline engine, fuel consumption rate can also be calculated by air flow rate flowing through the engine; further, the air flow rate is further divided Fresh air flow, exhaust gas flow, etc.;
如先获取燃料消耗率,可再通过一能量转化系数转化成燃料发动机的驱动功率Pr1;If the fuel consumption rate is first obtained, it can be converted into the driving power Pr1 of the fuel engine by an energy conversion coefficient;
2.2.4.6、第六种:燃料动力组合型参数,指根据前述的燃料动力参数组合而成的参数,其具体定义方式见后文描述;2.2.4.6, sixth type: fuel power combined type parameter, refers to the combination of fuel dynamic parameters according to the aforementioned parameters, the specific definition of which will be described later;
2.3、混合动力参数:前端的混合动力参数通常为电机驱动参数和前端的燃料动力参数的组合;后端的混合动力参数通常为后端的电气动力参数和后端的燃料动力参数的组合;后端的混合动力参数也可以为在电气动力系统和燃料动力系统的共同作用的车辆后端(动力装置输出轴、驱动轮、以及动力装置输出轴和驱动轮之间的中间机械传动部件(包括传动轴、传动齿轮机构等))部件上测算所得的一个整体的源动力参数,该参数可包括驱动转矩、驱动功率、驱动力等,一般可通过转矩传感器或其他的力传感器测算所得;2.3. Hybrid parameters: The hybrid parameters of the front end are usually the combination of the motor drive parameters and the fuel dynamic parameters of the front end; the hybrid power parameters of the back end are usually the combination of the back end electric power parameters and the back end fuel power parameters; the back end hybrid power The parameters may also be the rear end of the vehicle (the power output shaft, the drive wheel, and the intermediate mechanical transmission component between the power output shaft and the drive wheel of the powertrain and the fuel power system (including the drive shaft, the transmission gear) Institutions, etc.)) an overall source power parameter measured on the component, which may include driving torque, driving power, driving force, etc., which may generally be measured by a torque sensor or other force sensor;
2.4、本发明中所述的源动力参数,在参数内容上至少包含一组源动力参数,也可以同时包含多组源动力参数;2.4. The source dynamic parameter described in the present invention includes at least one set of source dynamic parameters in the parameter content, and may also include multiple sets of source dynamic parameters;
3、本发明所述车辆质量主要包括如下参数:运载物品质量m1、包含运载物品质量的数据如车 辆总质量m2;质量单位可用公斤(KG或kg)表示;3. The vehicle quality according to the present invention mainly includes the following parameters: the mass of the carried item m1, the data including the quality of the carried item, such as a vehicle. The total mass m2; the mass unit can be expressed in kilograms (KG or kg);
3.1、运载物品质量m1特指车辆净重以外的所装载的人员物品的质量,也可称为车辆运载质量,显而易见的两者的实质意义相同,两者等同;3.1. The mass of the carried item m1 refers specifically to the mass of the loaded personnel other than the net weight of the vehicle, and may also be referred to as the mass of the vehicle. The obvious meanings of the two are the same, and the two are equivalent;
3.2、为了便于业内技术人员理解与描述简便,空载车体质量m0在参数类型上可以归类于后述的系统运行参数组中的系统固有参数;空载车体质量m0可通过厂家参数,或磅秤称量准确得知,无须测算;质量变化型物品质量mf在参数类型上可以归类于后述的系统运行参数;在计算时,车辆质量(m1和/或m2)与空载车体质量m0与质量变化型物品质量mf均可以混合计算;3.2, in order to facilitate the understanding and description of the technical personnel in the industry, the empty vehicle mass m0 can be classified into the system inherent parameters in the system operation parameter group described later in the parameter type; the empty vehicle mass m0 can pass the manufacturer parameters. Or the weighing scale is accurately known, no need to measure; the mass change type item mf can be classified into the system operating parameters described later in the parameter type; in the calculation, the vehicle mass (m1 and / or m2) and the empty vehicle body The mass m0 and the mass change type item mass mf can be mixed and calculated;
3.3、m1与m0的具体划分可由系统或人工自由选择决定;如电动大巴里相对固定的驾驶与车内服务人员自身质量可划入空载车体质量m0中,也可划入运载物品质量m1中;3.3, the specific division of m1 and m0 can be determined by system or manual freedom; for example, the relatively fixed driving and in-vehicle service personnel of the electric bus can be classified into the empty vehicle mass m0, and can also be classified into the mass of the carried item m1. in;
插电式纯电动车辆的车辆总质量m2可采用下述计算公式:m2=m0+m1;外部电源供电式电动车辆(如高铁车辆、动车、电力机车、有轨电车)也可采用此计算公式;The total mass m2 of the plug-in pure electric vehicle can be calculated by the following formula: m2=m0+m1; external power supply-type electric vehicles (such as high-speed rail vehicles, motor trains, electric locomotives, trams) can also use this formula. ;
3.4、在本发明中,m2、m1、m3、m4均可作为测算对象;3.4. In the present invention, m2, m1, m3, and m4 can be used as measurement objects;
在无人驾驶的自动车辆中,可用m2作为直接的测算对象;In an unmanned automatic vehicle, m2 can be used as a direct measurement object;
在普通的有人驾驶车辆中,用m1或m2作为测算对象,是较佳的方式;因为m1可更直接对应于车辆所载人载物的质量,易于驾乘人员识别,如m2对应车辆总质量。In ordinary manned vehicles, it is better to use m1 or m2 as the measurement object; because m1 can directly correspond to the mass of the person's load contained in the vehicle, it is easy for the driver and passenger to identify, such as m2 corresponding to the total mass of the vehicle. .
当运载物品质量m1与剩余燃料质量mf0的值均接近于0时,车辆总质量m2的值接近于空载车体质量m0,此时可以用m0的值替代m2的值进行车辆运动平衡计算,但实质技术方案未变。When the values of the carried item mass m1 and the remaining fuel mass mf0 are both close to 0, the value of the total mass m2 of the vehicle is close to the empty body mass m0, and the value of m0 can be used instead of the value of m2 to calculate the vehicle motion balance. However, the actual technical solution has not changed.
4、本发明所述系统运行参数组是指车辆运行参数中除车辆质量和源动力参数之外的所有参数,主要包括如下3类参数:机械运行参数、系统固有参数、质量变化型物品质量,其实质为车辆的动力传递的基础条件和/或固有属性和/或车辆在动力作用下产生的运动结果(如速度、加速度等)的参数;该固有属性指车辆和/或环境的固有属性。4. The system operation parameter group of the present invention refers to all parameters except vehicle quality and source power parameters in the vehicle operating parameters, and mainly includes the following three types of parameters: mechanical operation parameters, system inherent parameters, quality-changing item quality, It is essentially the underlying conditions and/or inherent properties of the power transmission of the vehicle and/or the parameters of the motion results (eg, speed, acceleration, etc.) produced by the vehicle under power; this inherent property refers to the inherent properties of the vehicle and/or the environment.
4.A、质量变化型物品质量主要包括燃料质量,所以在计算时可以用燃料质量替代质量变化型物品质量进行计算;4.A. The quality of quality-changing items mainly includes the quality of fuel, so the calculation of fuel quality can be used to replace the quality of quality-changing items.
4.B、燃料动力车辆中燃料主要包括汽油、柴油、燃气等;在采用燃料电池供电的电动车辆中,燃料主要包括而不仅限于:氢、乙醇、碳氢、甲烷、乙烷、甲苯、丁烯、丁烷、质子交换膜、碱性燃料、磷酸、溶化的碳酸盐、固态氧化物、直接甲醇、其他再生型燃料等;4.B. Fuels in fuel-powered vehicles mainly include gasoline, diesel, gas, etc. In electric vehicles powered by fuel cells, fuels mainly include, but are not limited to: hydrogen, ethanol, hydrocarbon, methane, ethane, toluene, and butyl. Alkene, butane, proton exchange membrane, alkaline fuel, phosphoric acid, dissolved carbonate, solid oxide, direct methanol, other regenerative fuels, etc.;
特别声明:在本发明中,在采用燃料电池供电的电动车辆中,该燃料是指能源供应的类型;因为其直接驱动车辆纵向运行的动力装置是电机,所以可将采用燃料电池供电的电动车辆中仍然归类于电气动力车辆;Special statement: In the present invention, in an electric vehicle powered by a fuel cell, the fuel refers to a type of energy supply; since the power device that directly drives the longitudinal operation of the vehicle is a motor, an electric vehicle powered by a fuel cell can be used. Still classified as an electric powered vehicle;
在车辆运行中,燃料处于不断消耗中,燃料质量不断变化;。In the operation of the vehicle, the fuel is continuously consumed, and the fuel quality is constantly changing;
本发明所述燃料质量包含剩余燃料质量mf0、已消耗燃料质量mf1、历史记录点的燃料质量mf2中任意一种或多种数据; The fuel mass of the present invention includes any one or more of the remaining fuel mass mf0, the consumed fuel mass mf1, and the fuel mass mf2 of the historical record point;
纯燃料动力车辆中(或包含燃料动力的插电式混合动力车辆)的车辆总质量m2计算公式如下:m2=m1+m0+mf0,或:m2=m1+m0+mf2-mf1;该公式中mf0、mf2、mf1可为汽油、或柴油、或天然气等燃料的质量;The total mass m2 of a vehicle in a pure fuel-powered vehicle (or a plug-in hybrid vehicle including a fuel power) is calculated as follows: m2 = m1 + m0 + mf0, or: m2 = m1 + m0 + mf2 - mf1; Mf0, mf2, mf1 may be the quality of gasoline, or diesel, or natural gas fuel;
燃料电池型电动车辆的车辆总质量m2计算公式如下:m2=m1+m0+mf0,或:m2=m1+m0+mf2-mf1;该公式中mf0、mf2、mf1为燃料电池的燃料(如氢)的质量;The total mass m2 of the fuel cell type electric vehicle is calculated as follows: m2=m1+m0+mf0, or: m2=m1+m0+mf2-mf1; in the formula, mf0, mf2, and mf1 are fuels of fuel cells (such as hydrogen) )the quality of;
燃料电池动力与燃油动力混合动力车辆,则包含两种燃料质量,一种为燃料电池的燃料(如氢)的质量,一种为普通燃料(如汽油、柴油等)的质量;Fuel cell power and fuel-powered hybrid vehicles include two fuel qualities, one for the fuel cell fuel (such as hydrogen), one for ordinary fuel (such as gasoline, diesel, etc.);
4.1、本发明所述机械运行参数实质为车辆的动力传递的基础条件中可变参数和/或车辆在动力作用下产生的运动结果(如速度、加速度等)的参数,主要包括而不仅限于如下参数:纵向速度Vx(也可用V1来表示)、纵向加速度a(也可用Vx来表示)、路面坡度θ、风阻fw、正面迎风速度V2、弯道系数δ、转向角度、综合力因子系数kaθ、内部综合旋转刚体的角加速度β(也可用ω0表示)等。4.1. The mechanical operating parameter of the present invention is substantially a parameter of a variable parameter in a basic condition of power transmission of a vehicle and/or a motion result (such as speed, acceleration, etc.) generated by the vehicle under dynamic action, and is mainly included but not limited to the following Parameters: longitudinal velocity V x (also denoted by V1), longitudinal acceleration a (also denoted by V x ), road gradient θ, wind resistance fw, front windward velocity V2, curve coefficient δ, steering angle, comprehensive force factor coefficient Kaθ, the angular acceleration β of the internal integrated rotating rigid body (which can also be represented by ω0), and the like.
4.1.1、纵向速度Vx的获取,有如下多种方式:4.1.1. The acquisition of the longitudinal velocity V x can be as follows:
Vx值获取方式1:通过设置于车体上的速度传感器测量而直接获取Vx值;Vx单位可用公里/小时(缩写为KM/H)表示,也可用米/秒(m/s)表示;Vx value acquisition method 1: directly obtain V x value by speed sensor measurement set on the vehicle body; V x unit can be expressed in kilometers per hour (abbreviated as KM/H), and can also be expressed in meters per second (m/s) ;
Vx值获取方式2:通过测量动力装置的转速n1间接获取Vx值:供参考的计算式如下:Vx=(2π*n1/im)*R1/60;当车辆打滑时此方法欠准;Vx value acquisition mode 2: Indirect acquisition of V x value by measuring the rotational speed n1 of the power device: The calculation formula for reference is as follows: V x = (2π * n1/im) * R1/60; this method is not accurate when the vehicle is slipping;
所有与速度相关联的参数,都可以用来获取Vx值;如动力控制装置的运行频率FR、动力装置角速度、动力控制装置角频率、齿轮转速、中间旋转件角速度、中间传动件线速度;频率FR与发动机的转速n1具有某种对应关系,例如变频器的额定频率通常对应于发动机的额定转速;All speed-related parameters can be used to obtain the V x value; such as the operating frequency FR of the power control device, the angular velocity of the power unit, the angular frequency of the power control device, the gear speed, the angular velocity of the intermediate rotating member, and the linear speed of the intermediate transmission; The frequency FR has a certain correspondence with the engine speed n1, for example, the rated frequency of the frequency converter generally corresponds to the rated speed of the engine;
Vx值获取方式3:通过纵向加速度a间接获取Vx值;供参考的计算式如下:Vx_1=Vx_0+a*t;t为单位时间,Vx_0为上一时间周期的Vx值,Vx_1为当前周期的纵向速度Vx值;Vx value acquisition method 3: Indirect acquisition of V x value by longitudinal acceleration a; calculation formula for reference is as follows: V x _1=V x _0+a*t; t is unit time, V x _0 is V of the previous time period The value of x , V x _1 is the longitudinal velocity V x value of the current cycle;
Vx值获取方式4:通过GPS、远程定位信息获取Vx值;Vx value acquisition method 4: obtaining V x value through GPS and remote positioning information;
4.1.2、纵向加速度a的获取,有如下多种方式:4.1.2. The acquisition of longitudinal acceleration a can be as follows:
a值获取方式1:通过设置于车体上的加速度传感器直接测量所得;如加速度传感器输出信号还包含g*sinθ的值,可以合并处理:(g*sinθ+a)A value acquisition method 1: directly measured by an acceleration sensor installed on the vehicle body; if the acceleration sensor output signal also contains the value of g*sin θ, it can be combined: (g*sinθ+a)
a值获取方式2:通过动力装置的转速n1,或纵向速度
Figure PCTCN2016090935-appb-000001
间接测量而获取;供参考的计算式如下:a=(Vx_1-Vx_0)/t;
a value acquisition mode 2: through the speed of the power unit n1, or longitudinal speed
Figure PCTCN2016090935-appb-000001
Obtained by indirect measurement; the calculation formula for reference is as follows: a=(V x _1-V x _0)/t;
4.1.3、路面坡度θ:车辆行驶路面或轨道与水平线的夹角;当车辆往上坡方向运行时:90°>θ>0°;sinθ为正值,表示动能转化成势能,比水平运行需要消耗更多功率;4.1.3. Pavement slope θ: the angle between the road surface or the track and the horizontal line of the vehicle; when the vehicle runs uphill: 90°>θ>0°; sinθ is a positive value, indicating that the kinetic energy is converted into potential energy, which is higher than the horizontal operation. Need to consume more power;
当车辆水平运行时:θ=0,cosθ=1,sinθ=0;When the vehicle is running horizontally: θ = 0, cos θ = 1, sin θ = 0;
当车辆往下坡方向运行时:360°>θ>270°;sinθ为负值,表示势能转化成动能,比水平运行消 耗功率更小,甚至可能进入制动状态;When the vehicle runs downhill: 360°>θ>270°; sinθ is negative, indicating that potential energy is converted into kinetic energy, which is lower than horizontal operation. It consumes less power and may even enter a braking state;
供电力机车行驶的轨道的坡度θ,也可以用路面坡度θ等同表示;The slope θ of the track for the electric locomotive can also be expressed by the road surface gradient θ;
θ值获取方式1:通过设置于车体上的纵向的倾角传感器或水平仪直接测量而获取θ值;θ value acquisition mode 1: obtaining θ value by direct measurement by a longitudinal inclination sensor or level set on the vehicle body;
θ值获取方式2:可通过GPS信息、或其他预存数据库、网络系统等获取具体线路、轨道在具体位置上的θ值;尤其对于高铁车辆、动车等有轨机车,因车辆轨道轨迹相对固定,可以通过预设一个位置信息与路面坡度θ值(和/或连同弯道系数δ和/或滚阻系数f)相对应的数据库,在车辆运行时,根据位置信息查表可直接读取θ值(或连同δ和/或f);对于汽车,如果该路径是已走过、已学习过的路径,也可采用此方式;θ value acquisition method 2: θ value of specific line and track at a specific position can be obtained through GPS information, or other pre-stored databases, network systems, etc.; especially for high-speed rail vehicles, motor vehicles and other rail locomotives, because the vehicle track trajectory is relatively fixed, The θ value can be directly read according to the position information table by presetting a position information corresponding to the road surface slope θ value (and/or the curve coefficient δ and/or the rolling resistance coefficient f). (or together with δ and / or f); for cars, this method can also be used if the path is a path that has been passed and has been learned;
4.1.4、空气阻力也即风阻fw的获取,有如下多种方式:4.1.4. Air resistance, that is, the acquisition of wind resistance fw, can be as follows:
fw值获取方式1:先获取车辆的纵向速度Vx再通过计算得到fw值;供参考的计算式如下:fw=(1/2)*Cd*(p0*A0*(Vx)2);其中Cd为车辆的风阻系数,p0为空气密度,A0为车辆的迎风面积;Cd,p0,A0都属于系统固有参数,均可通过读取系统预设值而获取;通过测量纵向速度Vx而获取风阻fw,具有成本低、简易的优点;测量精度不高;Fw value acquisition mode 1: first obtain the longitudinal velocity V x of the vehicle and then calculate the fw value; the calculation formula for reference is as follows: fw=(1/2)*C d *(p0*A 0 *(V x ) 2 Where C d is the drag coefficient of the vehicle, p0 is the air density, A 0 is the windward area of the vehicle; C d , p0, A 0 are all inherent parameters of the system, which can be obtained by reading the preset value of the system; Measuring the longitudinal velocity V x and obtaining the wind resistance fw has the advantages of low cost and simplicity; the measurement accuracy is not high;
fw值获取方式2:在车辆上设置独立的风速风向测试仪器,先测量车辆运行时正面迎风速度V2再通过计算得到fw值;供参考的计算式如下:fw=(1/2)*Cd*(p0*A0*(V2)2);Cd,p0,A0都属于系统固有参数,均可通过读取系统预设值而获取;Fw value acquisition method 2: Set an independent wind speed and direction test instrument on the vehicle, first measure the front windward speed V2 when the vehicle is running and then calculate the fw value; the calculation formula for reference is as follows: fw=(1/2)*C d *(p0*A 0 *(V2) 2 ); C d , p0, A 0 are all intrinsic parameters of the system and can be obtained by reading the system preset value;
因为车辆在运行中,如果环境风速气流V0方向与车辆运行方向相反,实际V2将为车辆纵向速度Vx与V0的和,此时车辆运行风阻fw增大;如果环境风速气流V0与车辆运行方向同向,实际V2将为车辆纵向速度Vx与V0的差值,此时车辆运行风阻fw减少;所以通过获取正面迎风速度V2进而获取风阻fw值,增加了成本但是具有测量精度高的优点。Because the vehicle is running, if the ambient wind speed V0 direction is opposite to the running direction of the vehicle, the actual V2 will be the sum of the vehicle longitudinal speeds V x and V0, at which time the vehicle running wind resistance fw increases; if the ambient wind speed air flow V0 and the vehicle running direction in the same direction, and the difference in longitudinal speed V x V2 V0 actual vehicle will, when the vehicle is operating to reduce drag fw; V2 so then obtain by obtaining the value of fw windage front face velocity, increases the cost, but the advantages of having a high measurement accuracy.
fw值获取方式3:在车辆上设置独立的风压或风阻传感器,直接测量车辆运行时单位面积风压或风阻,进而通过相关系数计算出风阻fw值;Fw value acquisition method 3: set an independent wind pressure or wind resistance sensor on the vehicle, directly measure the wind pressure or wind resistance per unit area of the vehicle during operation, and then calculate the wind resistance fw value through the correlation coefficient;
fw值获取方式4:预先设置一车辆纵向速度与风阻fw值的关联表格,在车辆运行时,通过纵向速度的值查表得出对应的风阻fw值;Fw value acquisition mode 4: pre-set a correlation table of vehicle longitudinal speed and wind resistance fw value, and when the vehicle is running, the corresponding wind resistance fw value is obtained by looking up the longitudinal speed value table;
车辆在低速运行时风阻fw较小,当车辆速度越高时风阻越大,所以风阻fw的测算在监测车辆高速运行时有关键作用。When the vehicle is running at low speed, the wind resistance fw is small. When the vehicle speed is higher, the wind resistance is larger. Therefore, the measurement of the wind resistance fw plays a key role in monitoring the high-speed operation of the vehicle.
4.1.5、弯道系数δ:指车辆当前运行中拐弯系数;当车辆转弯时,将影响车辆驱动力的大小;一般来说,弯度越大,驱动力也增大;4.1.5, curve coefficient δ: refers to the vehicle's current running curve; when the vehicle turns, it will affect the driving force of the vehicle; in general, the greater the camber, the driving force also increases;
弯道系数δ的获取方式1:可通过车辆的运行轨迹或加速度传感器,测量出拐弯角度α进而获取δ值,供参考的计算式如下:δ=K(α);The method of obtaining the curve coefficient δ is as follows: the turning angle α can be measured by the running track or the acceleration sensor of the vehicle to obtain the δ value, and the calculation formula for reference is as follows: δ=K(α);
弯道系数δ的获取方式2:可通过设置于方向盘的转角传感器,测量出拐弯角度α进而获取δ值,供参考的计算式如下:δ=K(α); The acquisition method of the curve coefficient δ can be obtained by measuring the corner angle α by the rotation angle sensor provided on the steering wheel to obtain the δ value, and the calculation formula for reference is as follows: δ=K(α);
不同型号的车辆δ可能不同,δ具体数值,α角度与δ值的具体函数关系,可由车辆厂家、或专业检测机构、或用户亲自开车转弯测试得知;为了计算简便,在相对平直的或拐弯度小于设定角度(如30°)的路面,弯道系数δ值通常可设为1,或直接忽略δ、不参与运算;Different types of vehicles may have different δ, δ specific values, specific relationship between α angle and δ value, which can be known by vehicle manufacturers, or professional testing institutions, or users to personally drive turning test; for simple calculation, in relatively straight or If the turning degree is less than the set angle (such as 30°), the curve coefficient δ value can usually be set to 1, or directly ignore δ and not participate in the calculation;
弯道系数δ的获取方式3:可通过GPS信息、或其他预存数据库、网络系统等获取具体线路、轨道在具体位置上的δ值;The acquisition method of the curve coefficient δ 3: The δ value of the specific line and the track at a specific position can be obtained through GPS information, or other pre-stored databases, network systems, and the like;
4.1.6、内部综合旋转刚体的角加速度β:内部综合旋转刚体,指车辆内部传动系统中所有刚性机械旋转部件综合折算刚体;β参数既可通过转速传感器获取,也可通过先获取动力装置转速n1或车辆的纵向速度Vx或车辆的纵向加速度a再计算而获取;4.1.6. The angular acceleration of the internal integrated rotating rigid body β: The internal comprehensive rotating rigid body refers to the comprehensive conversion of all rigid mechanical rotating parts in the internal transmission system of the vehicle; the β parameter can be obtained by the speed sensor or by obtaining the speed of the power unit first. N1 or the longitudinal speed V x of the vehicle or the longitudinal acceleration a of the vehicle is calculated and obtained;
4.2、本发明所述系统固有参数:指因车辆、或环境固有属性而带来的参数,本发明所述系统固有参数也可称为系统设定参数;4.2. The system inherent parameter of the present invention refers to a parameter caused by a vehicle or an inherent property of the environment, and the inherent parameter of the system of the present invention may also be referred to as a system setting parameter;
4.2.1、常见的系统固有参数包括而不仅限于如下:车辆的空载车体质量m0(也可称为空载固有质量或整备质量或空车质量等)、滚阻系数f(也可用μ1表示)、综合传动比im、后端的传动比im3、驱动轮半径R1(也可用R表示),与气缸活塞相连的发动机输出曲柄的等效半径R0、转矩电流与电磁转矩的转化系数Ki,电机电流有功分量与电磁转矩的转化系数Ko,机械传动系统的效率系数Km,电气动力系统的效率系数Kea、燃料动力系统的效率系数或转化系数Kfa、后端的效率系数Km3、内部综合旋转刚体的转动惯量L0,风阻系数Cd(也可用Cd表示),空气密度p0,迎风面积A0(也可用S表示)、重力加速度g(也可称为重力加速度因子,其含义、取值9.8均为现有公知技术,最基础的物理常识)、参数取值的预设的时间范围等。本发明所述系统固有参数还包括其他的除车辆总质量之外的所有可由系统预设其正常状况的幅值的所有参数。4.2.1. Common system intrinsic parameters include, but are not limited to, the following: the empty body mass m0 of the vehicle (also referred to as the no-load inherent quality or the curvilinear mass or the empty vehicle mass), and the rolling resistance factor f (also available as μ1) Indicates), the integrated gear ratio im, the rear gear ratio im3, the drive wheel radius R1 (also denoted by R), the equivalent radius R0 of the engine output crank connected to the cylinder piston, the conversion coefficient of the torque current and the electromagnetic torque Ki , motor current active component and electromagnetic torque conversion coefficient Ko, mechanical transmission system efficiency coefficient Km, electric power system efficiency coefficient Kea, fuel power system efficiency coefficient or conversion coefficient Kfa, back end efficiency coefficient Km3, internal comprehensive rotation The moment of inertia L0 of the rigid body, the drag coefficient C d (also denoted by Cd), the air density p0, the windward area A 0 (also denoted by S), the gravitational acceleration g (also known as the gravitational acceleration factor, its meaning, value 9.8 All of the well-known technologies, the most basic physical common sense), the preset time range of parameter values, and the like. The system intrinsic parameters of the present invention also include all other parameters other than the total mass of the vehicle that can be preset by the system for the magnitude of its normal condition.
系统固有参数的详细说明如下:A detailed description of the system's inherent parameters is as follows:
4.2.2、电气动力系统的效率系数Kea、机械传动系统的效率系数Km、燃料动力系统的效率系数或转化系数Kfa:4.2.2, the efficiency coefficient of the electric power system Kea, the efficiency coefficient Km of the mechanical transmission system, the efficiency coefficient of the fuel power system or the conversion coefficient Kfa:
4.2.2.1、电气动力系统的效率系数Kea包括而不局限于如下参数:4.2.2.1. The efficiency coefficient of the electric power system Kea includes and is not limited to the following parameters:
电机的效率系数Ke:指电机的电气功率到电机轴输出机械功率的转换效率;The efficiency coefficient of the motor Ke: refers to the conversion efficiency of the electrical power of the motor to the mechanical power output of the motor shaft;
电机驱动装置到电机的效率系数k21(也可用k13来表示):指电机运行工况为电动状态时该电机驱动器的输入功率到电机的电气功率的转换效率;也可指电源的输出功率到电机的电气功率的转换效率;The efficiency coefficient k21 of the motor drive to the motor (also denoted by k13): refers to the conversion efficiency of the input power of the motor driver to the electrical power of the motor when the motor operating condition is the electric state; also refers to the output power of the power source to the motor Conversion efficiency of electrical power;
电源到电机的效率系数k31:指电机运行工况为电动状态时该电源的输入功率到电机的电气功率的转换效率;The power factor to motor efficiency coefficient k31: refers to the conversion efficiency of the input power of the power source to the electrical power of the motor when the operating condition of the motor is the electric state;
电机制动功率到电源的效率系数k14:指电机制动状态时从电机制动功率到回馈到电源装置功率的效率系数;The efficiency coefficient of the motor braking power to the power supply k14: the efficiency coefficient from the braking power of the motor to the power of the power supply device when the motor is in the braking state;
4.2.2.2、机械传动系统的效率系数Km,也可简称为机械传动系统效率:对于电气动力系统而 言,Km指包括车辆的电机输出轴、驱动轮、以及电机输出轴和驱动轮之间的中间传动部件等部件的综合传动的效率系数;同理,对于燃料动力系统而言,Km指包括车辆的燃料发动机输出轴、驱动轮、以及燃料发动机输出轴和驱动轮之间的中间传动部件等部件的综合传动的效率系数;为应对Km值在不同速度区间可能的波动,可设置一个一维函数,Km(VX)一,也即根据不同的速度区间(如零速、低速、高速)取相应的Km值;当车辆处于不同运行状态(如动力装置驱动运行/或动力装置制动运行)时,Km值可能有变化,所以也可根据不同的动力装置运行工况将Km值分别设置为不同值;4.2.2.2, the efficiency coefficient Km of the mechanical transmission system, also referred to as mechanical transmission system efficiency: For the electric power system, Km refers to the motor output shaft including the vehicle, the drive wheel, and the motor output shaft and the drive wheel. For the fuel power system, Km refers to the fuel engine output shaft of the vehicle, the drive wheel, and the intermediate transmission components between the fuel engine output shaft and the drive wheel. The efficiency coefficient of the integrated transmission of the component; in order to cope with the possible fluctuation of the Km value in different speed ranges, a one-dimensional function, Km (VX) , may be set, that is, according to different speed intervals (such as zero speed, low speed, high speed) Corresponding Km value; when the vehicle is in different operating states (such as power plant drive operation / power plant brake operation), the Km value may change, so the Km value may also be set to be different according to different power plant operating conditions. Different value
机电传动综合的效率系数Kem,也可称为机电传动综合效率Kem;Kem包含电机的效率系数Ke,包含了机械传动系统的效率系数Km;Kem=Ke*Km。The comprehensive efficiency coefficient Kem of electromechanical transmission can also be called the electromechanical transmission integrated efficiency Kem; Kem contains the efficiency coefficient Ke of the motor, including the efficiency coefficient Km of the mechanical transmission system; Kem=Ke*Km.
4.2.2.3、燃料动力系统的效率系数或转化系数Kfa:因为不同的燃料动力参数有不同的信号获取位置/获取方式;所以Kfa包含多个细分参数;为了描述和业内技术人员理解的便利,本发明用Kfa概括所有燃料动力系统的效率系数或转化系数;Kfa具体可包括Kf1、Kf2、Kf3…Kfn等;4.2.2.3, efficiency coefficient or conversion coefficient of fuel power system Kfa: Because different fuel power parameters have different signal acquisition positions/acquisition methods; therefore, Kfa contains multiple subdivision parameters; for the convenience of description and understanding by those skilled in the art, The invention uses Kfa to summarize the efficiency coefficient or conversion coefficient of all fuel power systems; Kfa may specifically include Kf1, Kf2, Kf3...Kfn, etc.;
4.2.2.3.1、例如当燃料动力参数为发动机内的燃料消耗率fm1时,可用能量转化系数Kf1将该燃料消耗率fm1转化成燃料发动机的驱动功率Pr1,则Pr1=fm1*Kf1;4.2.2.3.1, for example, when the fuel power parameter is the fuel consumption rate fm1 in the engine, the fuel consumption rate fm1 can be converted into the driving power Pr1 of the fuel engine by the energy conversion coefficient Kf1, then Pr1=fm1*Kf1;
4.2.2.3.2、例如当燃料动力参数为燃料喷射系统的燃料输入端的燃料消耗率fm2时,可用能量转化系数Kf2将该燃料消耗率fm2转化成燃料发动机的驱动功率Pr1,则Pr1=fm2*Kf2;4.2.2.3.2. For example, when the fuel power parameter is the fuel consumption rate fm2 of the fuel input end of the fuel injection system, the fuel consumption rate fm2 can be converted into the driving power Pr1 of the fuel engine by the energy conversion coefficient Kf2, then Pr1=fm2* Kf2;
4.2.2.3.3、例如当燃料动力参数为燃料发动机的气缸压力F1时(且该F1可经过峰值变平均值或滤波等处理),则需要一个效率系数Kf3将该气缸压力F1转化成燃料发动机的驱动力Ff1,则Ff1=F1*Kf3;或将该F1转化成燃料发动机的驱动转矩Tr1,Tr1=F1*Kf3*R0;4.2.2.3.3 For example, when the fuel power parameter is the cylinder pressure F1 of the fuel engine (and the F1 can be subjected to peak averaging or filtering, etc.), an efficiency coefficient Kf3 is required to convert the cylinder pressure F1 into a fuel engine. Driving force Ff1, then Ff1=F1*Kf3; or converting the F1 into a driving torque Tr1 of the fuel engine, Tr1=F1*Kf3*R0;
4.2.2.3.4、例如当燃料动力参数为燃料发动机的空气流量C1时(且该C1可经过峰值变平均值或滤波等处理),可用能量转化系数Kf4将该空气流量C1转化成燃料发动机的驱动功率Pr1,则Pr1=C1*Kf4;通常来说,只有在汽油发动机中才能用空气流量C1去计算功率,因为汽油发动机的空气流量与燃料有一个相对固定的化学计量比;柴油发动机的进气歧管没有被节流,不便于通过C1计算功率;4.2.2.3.4. For example, when the fuel power parameter is the air flow rate C1 of the fuel engine (and the C1 may be subjected to peak averaging or filtering, etc.), the air flow rate C1 may be converted into a fuel engine by the energy conversion coefficient Kf4. Drive power Pr1, then Pr1 = C1 * Kf4; in general, the air flow C1 can only be used to calculate power in a gasoline engine because the air flow of the gasoline engine has a relatively fixed stoichiometric ratio with the fuel; The gas manifold is not throttled and it is not convenient to calculate the power through C1;
4.2.2.3.5、例如当燃料动力参数为燃料发动机的负荷报告数据(功率值)Pr2时(且该Pr2可经过峰值变平均值或滤波等处理),可用能量转化系数Kf5进行系列的滤波和百分比计算,将该负荷报告数据(功率值)Pr2转化成燃料发动机的驱动功率Pr1,则Pr1=Pr2*Kf5;4.2.2.3.5. For example, when the fuel power parameter is the load report data (power value) Pr2 of the fuel engine (and the Pr2 may be subjected to peak averaging or filtering, etc.), a series of filtering and energy conversion coefficients Kf5 may be used. Percentage calculation, the load report data (power value) Pr2 is converted into the fuel engine driving power Pr1, then Pr1 = Pr2 * Kf5;
4.2.2.3.6、例如当燃料动力参数为燃料发动机的负荷报告数据(转矩值)Tr2时(且该Tr2可经过峰值变平均值或滤波等处理),可用能量转化系数Kf6进行系列的滤波和百分比计算,将该负荷报告数据(转矩值)Tr2转化成燃料发动机的驱动转矩Tr1,则Tr1=Tr2*Kf6;4.2.2.3.6. For example, when the fuel power parameter is the load report data (torque value) Tr2 of the fuel engine (and the Tr2 may be subjected to peak averaging or filtering, etc.), the series of filtering may be performed by the energy conversion coefficient Kf6. And percentage calculation, the load report data (torque value) Tr2 is converted into the driving torque Tr1 of the fuel engine, then Tr1 = Tr2 * Kf6;
因燃料动力参数具有更多种获取方式,燃料动力系统的效率系数或转化系数有更多类型,本发明就不一一例举;按照燃料动力系统的效率系数或转化系数Kfa的原理,无论类型,所有车辆的任一源动力参数,均可设置一个该源动力参数与驱动车辆纵向运行的动力的对应系数Ka,动力=该源 动力参数的值*Ka;该Ka值可通过型式试验、有限次人工试凑法、及其他现有技术的组合得知;例如获取磁悬浮车辆的某一源动力参数和与其对应的对应系数Ka的预设值,即可计算出磁悬浮车辆的动力,进而可设立车辆运动平衡计算公式进行车辆运动平衡计算。例如美国特斯拉公司的管道内列车也可采用本发明提供技术方案进行监控;显而易见,相关的对应系数Ka和/或转化系数Kfa既可为单一的效率系数,也可为包含效率系数的参数也即一个由效率系数组合而成的参数也即一个包含效率系数的组合型参数;例如通过电机的某源动力参数(例如电机电流i1)乘以某个对应系数或转化系数(例如Ka1)得到车辆的驱动力(例如fq或Fx),则该Ka1为包含效率系数的参数;Since there are more ways to obtain fuel power parameters, there are more types of efficiency coefficients or conversion coefficients of fuel power systems, and the present invention is not limited to one example; according to the efficiency coefficient of fuel power system or the principle of conversion coefficient Kfa, regardless of type , any source power parameter of all vehicles, may set a corresponding coefficient Ka of the source dynamic parameter and the power driving the longitudinal operation of the vehicle, power = the source The value of the dynamic parameter *Ka; the Ka value can be known by a combination of a type test, a finite number of manual trials, and other prior art; for example, obtaining a source dynamic parameter of a magnetic levitation vehicle and a corresponding coefficient Ka corresponding thereto The preset value can be used to calculate the power of the magnetic levitation vehicle, and then the vehicle motion balance calculation formula can be established to calculate the vehicle motion balance. For example, the in-pipe train of the US Tesla Company can also be monitored by the technical solution provided by the present invention; it is obvious that the relevant corresponding coefficient Ka and/or the conversion coefficient Kfa can be either a single efficiency coefficient or a parameter including an efficiency coefficient. That is, a parameter composed of efficiency coefficients is a combined parameter including an efficiency coefficient; for example, by multiplying a certain source dynamic parameter of the motor (for example, motor current i1) by a corresponding coefficient or conversion coefficient (for example, Ka1). The driving force of the vehicle (for example, fq or Fx), then the Ka1 is a parameter including an efficiency coefficient;
4.2.2.4、相关效率系数k31、k21、k14、Ke,Km、Kfa值,在一定的速度、载荷区间内是基本不变的;4.2.2.4, the relevant efficiency coefficient k31, k21, k14, Ke, Km, Kfa value is basically constant within a certain speed and load interval;
k31、k21、k14值变化意味着电源或电机驱动器内部整流桥、IGBT可能存在短路、或断路、参数变异等异常情况;Ke值的变化意味着电机内部旋转磁场参数变异、或电机绕组短路、或断路等可能造成严重后果的变异;The change of k31, k21, k14 value means that the internal rectifier bridge of the power supply or the motor driver, the IGBT may have a short circuit, or an open circuit, parameter variation and other abnormal conditions; the change of the Ke value means that the internal rotating magnetic field parameter variation of the motor or the motor winding is short-circuited, or Variations that may cause serious consequences, such as a broken circuit;
车辆的电流电压转速转矩都可以变,但基本的k31、k21、k14、Ke值不能变;所以上述k31、k21、k14、Ke值不仅仅作为电气动力系统的效率系数,也可作为电气动力系统的安全状况的重要依据;The current, voltage and speed torque of the vehicle can be changed, but the basic values of k31, k21, k14, and Ke cannot be changed; therefore, the above k31, k21, k14, and Ke values are not only used as the efficiency coefficient of the electric power system, but also as the electric power. An important basis for the security status of the system;
燃料动力系统的效率系数或转化系数Kfa的值,通常体现为燃料发动机的效率,如发动机拉缸、或活塞密封效果变差时Kfa会降低,所以Kfa值也可作为燃料动力系统的安全状况的重要依据;The efficiency coefficient of the fuel power system or the value of the conversion coefficient Kfa is usually expressed as the efficiency of the fuel engine. If the engine pull cylinder or the piston sealing effect is deteriorated, the Kfa will decrease, so the Kfa value can also be used as the safety condition of the fuel power system. Important reference;
机械传动系统的效率系数Km值的变化可能代表车辆的包括动力装置输出轴、驱动轮、以及动力装置输出轴和驱动轮之间的中间传动部件在内的机械传动系统中,出现严重磨损、或变形、或齿轮脆裂等可能造成严重后果的变异;A change in the efficiency coefficient Km of the mechanical transmission system may represent severe wear in the mechanical transmission system of the vehicle including the power unit output shaft, the drive wheel, and the intermediate transmission member between the power unit output shaft and the drive wheel, or Variations that may cause serious consequences, such as deformation or gear embrittlement;
车辆的机械的转矩转速都可以变,甚至摩擦力也可以随着载荷的大小变化,但是基本的Km值不能大幅变化,或则就可能是严重故障;所以Km值不仅仅可作为机械传动部件效率系数,也可以作为机械传动部件的安全状况的重要依据;The mechanical torque speed of the vehicle can be changed, and even the frictional force can vary with the size of the load, but the basic Km value cannot be changed greatly, or it may be a serious fault; therefore, the Km value can be used not only as the efficiency of the mechanical transmission component. The coefficient can also be used as an important basis for the safety condition of mechanical transmission components;
通过对k31、k21、k14,Ke值进行作为测算对象进行直接监控,或通过计算其他测算对象(如车辆质量)的联合运算值间接的监控k31、k21、k14,Ke值,可以有效的监控车辆的电气动力系统的运行状况;通过对Kfa进行直接或间接的监控,可以有效的监控车辆的燃料动力系统的工作状况;By directly monitoring the k31, k21, k14, and Ke values as measurement targets, or by indirectly monitoring the k31, k21, k14, and Ke values by calculating the joint operation values of other measurement objects (such as vehicle mass), the vehicle can be effectively monitored. The operation of the electric power system; through direct or indirect monitoring of Kfa, the working condition of the vehicle's fuel power system can be effectively monitored;
也可设置一个车辆的电气动力系统综合效率系数Keem,该系数同时包含机械传动系统的效率系数Km和电气动力系统的效率系数Kea;Keem值为车辆的Km值和电气动力系统的效率系数值Kea的乘积;It is also possible to set a comprehensive efficiency coefficient Keem of the electric power system of a vehicle, which includes both the efficiency coefficient Km of the mechanical transmission system and the efficiency coefficient Kea of the electric power system; the Keem value is the Km value of the vehicle and the efficiency coefficient value of the electric power system Kea Product of
也可设置一个车辆的燃料动力系统综合效率系数Kfam,该系数同时包含机械传动系统的效率系数Km和燃料动力系统效率系数Kfa;Kfam值为车辆的Km值和燃料动力系统效率系数值Kfa的乘积;It is also possible to set a fuel efficiency system comprehensive efficiency coefficient Kfam of a vehicle, which includes both the mechanical transmission system efficiency coefficient Km and the fuel power system efficiency coefficient Kfa; the Kfam value is the product of the vehicle Km value and the fuel power system efficiency coefficient value Kfa. ;
因电动车辆的动力系统综合效率系数Keem值一般较高(可高于90%),在进行非精确计算时也 可将Keem设为1或直接忽略、不参与计算。Because the overall efficiency coefficient of the power system of the electric vehicle Keem is generally higher (can be higher than 90%), when performing inaccurate calculations You can set Keem to 1 or ignore it directly and not participate in the calculation.
显而易见的,本发明中,在没有前后的限定说明时,无论哪种车辆,效率系数:表示用于车辆运动平衡计算的源动力参数的信号采集点到驱动轮的之间的动力部件和/或传动部件的效率;该动力部件和/或传动部件称为待监控的动力传动部件;该效率系数也即待监控的动力传动部件的能量传递效率;因为能量守恒原理,如果该效率系数降低即意味着该待监控的动力传动部件的能量传递效率降低,即意味着其内部损耗增加、内阻或阻力变大、发热增加、安全状况变差等,该待监控的动力传动部件的失效风险增大;所以效率系数可用于反映、分析车辆的待监控的动力传动部件的运行状况,该运行状况尤其指磨损和/或安全的状况。通常,可尽量将源动力参数的信号采集点移至动力系统中靠前的信号点,可借助车辆运动平衡计算进行更大范围的动力部件的监控和保护。Obviously, in the present invention, without any limitation of the front and rear, regardless of the vehicle, the efficiency coefficient: represents the power component between the signal acquisition point of the source dynamic parameter for the vehicle motion balance calculation and the drive wheel and/or The efficiency of the transmission component; the power component and/or the transmission component is called the power transmission component to be monitored; the efficiency coefficient is also the energy transmission efficiency of the power transmission component to be monitored; because of the principle of energy conservation, if the efficiency coefficient is lowered, it means The energy transmission efficiency of the power transmission component to be monitored is reduced, that is, the internal loss is increased, the internal resistance or the resistance is increased, the heat is increased, the safety condition is deteriorated, and the like, and the risk of failure of the power transmission component to be monitored is increased. Therefore, the efficiency factor can be used to reflect and analyze the operating conditions of the power transmission components of the vehicle to be monitored, which in particular refer to wear and/or safety conditions. Generally, the signal acquisition point of the source power parameter can be moved to the signal point in the front of the power system as much as possible, and the vehicle dynamic balance calculation can be used to monitor and protect a wider range of power components.
关于效率系数的实施例:Examples of efficiency coefficients:
位于车辆的能量(和/或动力)的传递环节上的某一源动力参数的检测点至驱动轮的能量转换效率为k,检测该检测点的功率p1,根据公式k*p1=p2计算得到k,其中能量传递环节为能源供应装置(例如电源)→动力控制装置(例如变频器)→动力装置(例如电机)→传动系统→驱动轮,p2为驱动力所形成的驱动功率;p2也即滚动阻力、坡度阻力、变速阻力以及风阻所对应的功率之和,p2等于纵向动力学方程(也即车辆纵向运动平衡计算公式)计算所得功率,也即p2可通过车辆纵向运动平衡计算所得;然后将计算得到的k与该检测点至驱动轮的能量转换效率的预设值(通常为标定值)进行比较,进而判断该检测点至驱动轮之间的能量(和/或动力)传递是否异常,也即判断车辆中与动力传递相关的系统的运行状况是否异常;本发明中,传动系统也即机械传动系统;The energy conversion efficiency of the detection point of a certain source dynamic parameter on the transmission link of the energy (and/or power) of the vehicle to the driving wheel is k, and the power p1 of the detection point is detected, and is calculated according to the formula k*p1=p2 k, wherein the energy transfer link is an energy supply device (such as a power supply) → a power control device (such as a frequency converter) → a power device (such as a motor) → a transmission system → a drive wheel, and p2 is a driving power formed by a driving force; The sum of the rolling resistance, the slope resistance, the shifting resistance, and the power corresponding to the wind resistance, p2 is equal to the calculated power of the longitudinal dynamic equation (that is, the vehicle longitudinal motion balance calculation formula), that is, p2 can be calculated by the longitudinal motion balance of the vehicle; Comparing the calculated k with a preset value (usually a calibration value) of the energy conversion efficiency of the detection point to the driving wheel, thereby determining whether the energy (and/or power) transmission between the detection point and the driving wheel is abnormal. , that is, determining whether the operating condition of the system related to power transmission in the vehicle is abnormal; in the present invention, the transmission system is also a mechanical transmission system;
例如,该检测点为能源供应装置(例如电源)输入点时,k=k1*k2*k3*k4,其中,k1为能源供应装置(例如电源)的能量转化率,k1=能源供应装置(例如电源)的输入功率/输出功率;k2为动力控制装置(例如变频器)的能量转化率,k2=能源供应装置(例如电源)的输出功率/动力控制装置(例如变频器)的输出功率;k3为动力装置(例如电机)的能量转化率,k3=动力控制装置(例如变频器)的输出功率/动力装置(例如电机)的输出功率;k4为传动系统的能量转化率,k4=动力装置(例如电机)的输出功率/传动系统输出功率。For example, when the detection point is an energy supply device (eg, a power source) input point, k=k1*k2*k3*k4, where k1 is the energy conversion rate of the energy supply device (eg, power source), k1=energy supply device (eg Input power/output power of the power supply; k2 is the energy conversion rate of the power control device (eg frequency converter), k2 = output power of the energy supply device (eg power supply) / output power of the power control device (eg frequency converter); k3 For the energy conversion rate of a power plant (such as a motor), k3 = output power of a power control device (such as a frequency converter) / output power of a power device (such as a motor); k4 is the energy conversion rate of the transmission system, k4 = power device ( For example, the output power of the motor / transmission system output power.
如该检测点为动力控制装置(例如变频器)输入点时,k=k2*k3*k4,其中,k2为动力控制装置(例如变频器)的能量转化率,k3为动力装置(例如电机)的能量转化率,k4为传动系统的能量转化率;If the detection point is a power control device (such as a frequency converter) input point, k = k2 * k3 * k4, where k2 is the energy conversion rate of the power control device (such as the frequency converter), and k3 is the power device (such as the motor) Energy conversion rate, k4 is the energy conversion rate of the transmission system;
因传动系统可进一步分为N个子系统,则相应的的子系统各自对应的能量转化率为k41、k42、……、k4N,则k4等于各相应的的子系统各自对应的能量转化率的乘积;Since the transmission system can be further divided into N subsystems, the corresponding energy conversion rates of the corresponding subsystems are k41, k42, ..., k4N, and k4 is equal to the product of the respective energy conversion rates of the respective subsystems. ;
4.2.3、滚阻系数f:指车辆的滚动轮(即车轮)与路面(或轨道)滚动阻力系数; 4.2.3, rolling resistance coefficient f: refers to the rolling resistance coefficient of the rolling wheel (ie the wheel) and the road surface (or track) of the vehicle;
4.2.3.1、在普通公路上行驶的车辆,可使用充气式橡胶轮胎,基于公知常识可理解的,也即该车辆的车轮为橡胶轮也即橡胶车轮;轮胎的滚阻系数f也即橡胶轮的滚阻系数f,滚阻系数f主要由轮胎的气压p1、轮胎的磨损状况kt、路面的平整状况kr决定,可用数学函数式来描述其值:f(k0,p1,kt,kr);k0为修正系数,p1为轮胎气压,kt为轮胎磨损状态,kr为路面状况。标准磨损状况kt和标准气压p1和标准路况kr下的f基准值,可由车辆生产厂家或专业检测机构设定。车辆的f基准值,在速度、载荷、甚至坡度大幅度变化时可能发生小幅度变化,可以通过在不同的速度、载荷、路面坡度区间,设置不同的修正系数k0,来修正f基准的变化。4.2.3.1 For vehicles driving on ordinary roads, inflatable rubber tires can be used, which can be understood based on common knowledge, that is, the wheels of the vehicle are rubber wheels or rubber wheels; the rolling resistance coefficient f of the tire is also the rubber wheel. The rolling resistance coefficient f, the rolling resistance coefficient f is mainly determined by the air pressure p1 of the tire, the wear condition kt of the tire, and the flatness condition kr of the road surface, and the value can be described by a mathematical function: f(k0, p1, kt, kr); K0 is the correction factor, p1 is the tire pressure, kt is the tire wear state, and kr is the road condition. The reference value of the standard wear condition kt and the standard air pressure p1 and the standard road condition kr can be set by the vehicle manufacturer or a professional inspection agency. The f-reference value of the vehicle may change slightly when the speed, load, and even the gradient change greatly. The change of the f-reference may be corrected by setting different correction coefficients k0 in different speeds, loads, and road gradient intervals.
路面平整状况kr变化,或磨损状况kt值的变化,都会导致f值的变化;但是kt变化是个缓慢的过程不会造成f值的突变;路面平整状况kr的变化而导致f的变化,可以通过司机、乘客的目视简单的识别和分辨。The change of the pavement leveling condition kr, or the change of the kt value of the wear condition, will result in a change in the f value; however, the kt change is a slow process that does not cause a sudden change in the f value; the change in the smoothness of the road surface kr causes a change in f, which can be passed The visual and simple identification and resolution of drivers and passengers.
所以在忽略kt、kr值的变化时,f值将主要由轮胎气压p1决定;在同等路况下,同等载重量下,当轮胎气压p1不足,轮胎变形越大(失圆度越大),则f值会越大,车辆运行阻力会越大(高速运行时越容易发热而爆胎);其原理为:圆形物体滚动容易,椭圆型则不易,多边菱形体、正方形、三角型物体滚动更难;Therefore, when neglecting the change of kt and kr values, the f value will be mainly determined by the tire pressure p1; under the same road condition, under the same load, when the tire pressure p1 is insufficient, the tire deformation is larger (the rounding degree is larger), then The larger the value of f, the greater the running resistance of the vehicle (the more likely it is to heat up and puncture at high speed); the principle is that circular objects are easy to roll, ellipticals are not easy, and polygonal diamonds, squares, and triangular objects roll more. difficult;
将f参数作为测算对象进行直接监控,或其他测算对象的联合运算值计算中包含f参数而进行间接监控,可以在车辆运行中监测轮胎形变(失圆度)和/或轮胎磨损状况kt是否异常,从而可以提前预警爆胎的风险。在车辆高速运行期中,如果突然发生爆胎事故,气体泄漏导致轮胎形变(失圆度)迅速增大,轮胎气压p1迅速降低,会导致测算对象的联合运算值发生大幅度突变,所以利用本发明提供的技术方法,可以在发生爆胎的瞬间快速发出宝贵的预警信号。The f parameter is directly monitored as a measurement object, or the joint calculation value calculation of other measurement objects includes an f parameter for indirect monitoring, and the tire deformation (out of roundness) and/or the tire wear condition kt can be monitored during vehicle operation. So that the risk of a puncture can be warned in advance. In the high-speed running period of the vehicle, if a puncture accident occurs suddenly, the gas leakage causes the tire deformation (roundness) to increase rapidly, and the tire air pressure p1 rapidly decreases, which may cause a large change in the joint calculation value of the measurement object, so the present invention is utilized. The technical method is provided to quickly send out a precious warning signal at the moment of a puncture.
从充气式轮胎的工作原理分析,由于车辆的自重产生的压力,气体大幅度泄露之前内部压力变化也是缓慢的,轮速变化也是缓慢的;但只要轮胎小幅度漏气,因车辆的重压导致轮胎形变(失圆)将会即刻产生;所以通过监测(滚动轮(包括驱动轮)的形变导致的)运行阻力变化监控动力传递异常,相较于依靠气压或依靠轮速监控胎压的现有技术,更快捷、有效。From the working principle of the inflatable tire, due to the pressure generated by the vehicle's own weight, the internal pressure change is also slow before the gas leaks greatly, and the wheel speed change is also slow; but as long as the tire leaks slightly, the vehicle is stressed. Tire deformation (out of round) will be generated immediately; therefore, the power transmission anomaly is monitored by monitoring the change in running resistance caused by the deformation of the rolling wheel (including the driving wheel), compared to the existing monitoring of the tire pressure by air pressure or by wheel speed. Technology is faster and more effective.
4.2.3.2、在固定轨道上行驶的有轨电力机车(如高铁车辆、动车、普通列车、地铁、履带式车辆),通常使用刚性滚动轮,其滚阻系数f,主要由滚动轮自身形变、或与轨道之间的摩擦系数和磨损状况决定;刚性滚动轮完全无法采用充气式轮胎的胎压监控技术,通常只能在车辆停止后进行人工、抽检式的超声探测;所以更需要本发明所提供的技术方案,在车辆运行中监测车轮形变(失圆度)和/或车轮磨损的状况kt是否异常;滚阻系数f的增大,通常意味着车轮形变(失圆度)和/或车轮磨损的状况增重。4.2.3.2. Orbital electric locomotives (such as high-speed rail vehicles, motor trains, ordinary trains, subway trains, and tracked vehicles) that travel on fixed tracks usually use rigid rolling wheels. The rolling resistance coefficient f is mainly caused by the rolling wheel itself. Or the friction coefficient and the wear condition between the track and the track; the rigid rolling wheel can not use the tire pressure monitoring technology of the inflatable tire at all, and usually only after the vehicle stops, the manual and sampling type ultrasonic detection is performed; therefore, the invention is more needed. A technical solution is provided to monitor whether wheel deformation (out of roundness) and/or wheel wear condition kt is abnormal during vehicle operation; an increase in rolling resistance factor f generally means wheel deformation (roundness) and/or wheel The condition of wear increases weight.
分析滚阻系数f的形成原理,可设立滚阻系数f的变形公式:(f=fc*fr)或(f=fc+fr),其中fc为与车辆相关的滚阻系数分量,fc与车轮形变(失圆度)和/或车轮磨损状况直接相关;fr为与路况相关的滚阻系数分量,可经过预设的地图信息或位置信息查表得出当前路段fr的值;将(fc*fr) 或(fc+fr)代入任意任一车辆运动平衡计算公式种替代滚阻系数f,进而可得出fc的值;所以计算出滚阻系数f(尤其是与车辆相关的滚阻系数分量fc)可用于分析车轮的安全状况,该车轮的安全状况尤其指车轮形变(失圆度)和/或车轮磨损的状况;滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值也可由传感器测量所得,例如可通过车辆上的光学传感器或超声波或雷达传感器识别当前路面状况(例如是否水泥路、是否草地等);例如可通过车辆上设置的滚动轮,通过与该滚动轮相连接的力学传感器来探测当前路面的软硬程度从而识别当前路面的滚阻系数f和/或与路况相关的滚阻系数分量fr;Analyze the formation principle of the rolling resistance coefficient f, and set the deformation formula of the rolling resistance coefficient f: (f=fc*fr) or (f=fc+fr), where fc is the rolling resistance coefficient component related to the vehicle, fc and the wheel Deformation (out of roundness) and / or wheel wear condition is directly related; fr is the rolling resistance coefficient component related to the road condition, and the value of the current road segment fr can be obtained through the preset map information or position information table; (fc* Fr) Or (fc+fr) is substituted for any vehicle motion balance calculation formula to replace the rolling resistance coefficient f, and then the value of fc can be obtained; therefore, the rolling resistance coefficient f (especially the rolling resistance coefficient component fc related to the vehicle) is calculated. It can be used to analyze the safety condition of the wheel. The safety condition of the wheel refers especially to the deformation of the wheel (out of roundness) and/or the condition of wheel wear; any one or more of the rolling resistance coefficient f and the rolling resistance coefficient component fr related to the road condition. The value of the parameter can also be measured by the sensor. For example, the current road surface condition (for example, cement road, grass or the like) can be identified by an optical sensor or an ultrasonic or radar sensor on the vehicle; for example, by using a scroll wheel provided on the vehicle, The rolling wheel is connected with a mechanical sensor to detect the softness and hardness of the current road surface to identify the rolling resistance coefficient f of the current road surface and/or the rolling resistance coefficient component fr related to the road condition;
综合而言,车辆运行时,任一道路位置的路面坡度θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信息计算所得或传感器测量数据获取;该位置信息可基于地图信息和/或卫星定位和/除卫星定位系统之外的无线网络获取;该方案可适用于本发明任一方案中;与车辆相关的滚阻系数分量fc的值可根据预设值获取;不同规格不同型号的车轮的预设值可以不同;In general, when the vehicle is running, the value of any one or more of the road gradient θ, the rolling resistance coefficient f, and the rolling resistance coefficient component fr related to the road condition may be calculated based on the position information of the road. Acquired or sensor measurement data acquisition; the location information may be acquired based on map information and/or satellite positioning and/or wireless network other than satellite positioning system; the solution may be applicable to any of the aspects of the present invention; vehicle related rolling resistance The value of the coefficient component fc can be obtained according to a preset value; preset values of wheels of different specifications and different models can be different;
4.2.4、综合传动比im:大部分电动车辆的综合传动比im为一固定值;燃料动力车辆的综合传动比im通常根据变速器档位不同而变化;如果综合传动比im可变,则在测算时需要由中央控制器给定出当前值;同理,如后端的传动比im3可变,则在测算时需要由中央控制器给定出当前值;显而易见,在没有特殊说明时,系统固有参数通常由系统预设值给定当前值;当前值,通常理解为与当前真实值接近或相等的数值。4.2.4, the overall transmission ratio im: the overall transmission ratio im of most electric vehicles is a fixed value; the overall transmission ratio im of the fuel-powered vehicle usually varies according to the transmission gear position; if the integrated transmission ratio im is variable, then In the calculation, the current value needs to be given by the central controller; for the same reason, if the transmission ratio im3 of the back end is variable, the current value needs to be given by the central controller during the calculation; obviously, the system is inherently unspecified. The parameter is usually given the current value by the system preset value; the current value is usually understood as a value close to or equal to the current true value.
4.2.5、其他参数的说明:4.2.5, description of other parameters:
上述综合传动比im,指包括动力装置输出轴、驱动轮以及动力装置输出轴和驱动轮之间的中间传动部件的综合传动比;机械传动系统的效率系数Km通常指动力装置到驱动轮之间传动系统的效率系数;因为本发明所述源动力参数包括后端的源动力参数,则需要设置相应的传动比、效率系数;将后端的源动力参数的参数取值点到驱动轮之间的传动比称为后端的传动比im3,将后端的源动力参数的参数取值点到驱动轮之间的效率系数称为后端的效率系数Km3;The above integrated transmission ratio im refers to an integrated transmission ratio including an output shaft of the power unit, a driving wheel, and an intermediate transmission component between the output shaft of the power unit and the driving wheel; the efficiency coefficient Km of the mechanical transmission system generally refers to the power device to the driving wheel. The efficiency coefficient of the transmission system; because the source power parameter of the present invention includes the source power parameter of the back end, the corresponding gear ratio and efficiency coefficient need to be set; and the parameter of the source power parameter of the back end is taken to the transmission between the driving wheels The ratio of the parameter of the source power parameter of the back end to the drive wheel is called the efficiency coefficient Km3 of the back end.
4.2.6、系统固有参数的值,一般都有预设值(尤其为系统预设值),可由车辆的中央控制器给定,其正确性,也由车辆的中央控制保证;系统预设值可通过车辆生产服务厂商、专业检测机构得知;用户也可驾车自行测试、验证、调整、设置。如因参数的系统预设值的偏差甚至错误造成本监控方法的监控效果下降,不影响本技术方案的有效性;4.2.6. The value of the inherent parameters of the system generally has a preset value (especially the preset value of the system), which can be given by the central controller of the vehicle. The correctness is also guaranteed by the central control of the vehicle; the system default value It can be known by vehicle production service providers and professional testing organizations; users can also test, verify, adjust and set up by themselves. If the deviation of the system preset value due to the parameter or even the error causes the monitoring effect of the monitoring method to decrease, the effectiveness of the technical solution is not affected;
5、数据优先权的界定和源动力组合型参数的解释:5. Definition of data priority and interpretation of source and power combination parameters:
本发明所述源动力参数、车辆质量、系统运行参数三种参数中,源动力参数具有最高优先权;任何参数(包括车辆质量、系统运行参数)只要和源动力参数组合成一个计算表达式,则该计算表达式成为源动力组合型参数,源动力组合型参数也归类于源动力参数;根据动力系统种类不同,源动力组合型参数也分为电气动力组合型参数、燃料动力组合型参数、混合动力组合型参数;其中电 气动力组合型参数包括机电组合型参数、后端的电气动力组合型参数;Among the three parameters of source power parameter, vehicle quality and system operation parameter, the source power parameter has the highest priority; any parameter (including vehicle quality, system operation parameter) is combined with the source dynamic parameter to form a calculation expression. The calculation expression becomes the source-power combination parameter, and the source-power combination parameter is also classified as the source dynamic parameter; depending on the type of the power system, the source-power combination parameter is also divided into the electric-power combination parameter and the fuel-power combination type. Parameter, hybrid combination parameter; among them The aerodynamic combined parameters include electromechanical combined parameters and electric power combined parameters at the rear end;
典型的机电组合型参数示例如下:如((Ke*Km)*(k12*Po/Vx)表示一个根据电机功率进而计算的驱动力;如(Te*im/R)表示一个根据电磁转矩Te计算的驱动力,如(Te*n1/9.55/Vx-fw)表示另一个根据电机功率计算的剔除了风阻的驱动力,该电气功率的计算途径为转矩与转速;An example of a typical electromechanical combination parameter is as follows: ((Ke*Km)*(k12*Po/V x ) represents a driving force calculated according to the motor power; eg (Te*im/R) represents an electromagnetic torque according to The driving force calculated by Te, such as (Te*n1/9.55/V x -fw), represents another driving force for removing the wind resistance calculated from the motor power, which is calculated by torque and speed;
典型的燃料动力组合型参数示例如下:如(Km*Pr1/Vx)表示一个根据燃料发动机的驱动功率Pr1进而计算的驱动力;如(Tr1*im/R)表示一个根据燃料发动机的驱动转矩Tr1计算的驱动力;An example of a typical fuel-power combination type parameter is as follows: (Km*Pr1/V x ) represents a driving force calculated according to the driving power Pr1 of the fuel engine; for example, (Tr1*im/R) represents a driving according to the driving of the fuel engine. The driving force calculated by the moment Tr1;
典型的混合动力组合型参数示例如下:如(Tr3*im3/R)表示一个根据混合动力系统的驱动转矩Tr3计算的驱动力;An example of a typical hybrid combination type parameter is as follows: (Tr3*im3/R) indicates a driving force calculated based on the driving torque Tr3 of the hybrid system;
源动力组合型参数具有无穷多的表达式,本发明不一一例举;The source power combination type parameter has an infinite number of expressions, and the present invention is not exemplified;
源动力组合型参数值的获取方式1:通过前述方式获取源动力组合型参数中的源动力参数的值,通过前述方式获取源动力组合型参数中的其他参数的值,进而通过源动力组合型参数的计算式计算而获取源动力组合型参数的值;The acquisition method of the source power combined type parameter value 1: obtain the value of the source dynamic power parameter in the source power combined type parameter by the foregoing manner, obtain the value of the other parameter in the source power combined type parameter by the foregoing manner, and further adopt the source power combined type Obtaining the value of the source power combination parameter by calculating the calculation formula of the parameter;
6、不包含源动力参数的组合型参数:6. Combined parameters that do not contain source dynamic parameters:
6.1、机械组合型参数:当机械运行参数、车辆质量、系统固有参数三者之中的参数组合成一个包含机械运行参数的计算表达式,则该计算式成为机械组合型参数,机械组合型参数也归类于机械运行参数;6.1. Mechanical combination type parameters: When the parameters of the mechanical operation parameters, vehicle quality, and system inherent parameters are combined into a calculation expression containing mechanical operation parameters, the calculation formula becomes a mechanical combination type parameter, and the mechanical combination type Parameters are also classified as mechanical operating parameters;
典型的机械组合型参数示例如下:如(g*f*cosθ+g*sinθ+a)表示与质量关联的综合力因子,也可称为与质量具有直接乘积关系的系数X1,如(m2*g*f*cosθ)表示车辆的滚动阻力,如(m2*g*sinθ)表示车辆的坡度阻力,如(m2*a)表示车辆的变速阻力,如(m2*g*f*cosθ+m2*g*sinθ+m2*a+fw)表示车辆的机械类综合运行力;显而易见的,机械类综合运行力为车辆在运行方向上相关阻力;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和。An example of a typical mechanical combination parameter is as follows: For example, (g*f*cosθ+g*sinθ+a) represents a comprehensive force factor associated with mass, and can also be called a coefficient X1 having a direct product relationship with mass, such as (m2*) g*f*cosθ) represents the rolling resistance of the vehicle. For example, (m2*g*sinθ) represents the slope resistance of the vehicle. For example, (m2*a) represents the shifting resistance of the vehicle, such as (m2*g*f*cosθ+m2*) g*sinθ+m2*a+fw) represents the comprehensive operational force of the vehicle; obviously, the mechanical comprehensive running force is the relevant resistance of the vehicle in the running direction; the related resistance includes rolling resistance, slope resistance, shifting resistance, and wind resistance. One of them, or includes the sum of any of rolling resistance, slope resistance, shift resistance, and wind resistance.
机械组合型参数值的获取方式1:通过前述方式获取机械组合型参数中的机械运行参数的值,通过前述方式获取机械组合型参数中的其他参数的值,进而通过机械运行参数的计算式计算而获取源动力组合型参数的值;The method for obtaining the mechanical combination type parameter value 1: obtaining the value of the mechanical operation parameter in the mechanical combination type parameter by the foregoing method, obtaining the value of the other parameter in the mechanical combination type parameter by the foregoing manner, and further calculating the calculation formula of the mechanical operation parameter And obtaining the value of the source power combination parameter;
6.2、当车辆质量、系统固有参数两者之中的参数组合成一个包含车辆质量的计算式,则该计算式成为质量组合型参数,质量组合型参数也归类于车辆质量;(m1+m0),(m2-m0)等都属于车辆质量;如m2*g、m1*g等参数虽然变成了物体承受的重力,但在本发明中仍将其归类于车辆质量,不属于源动力参数。6.2. When the parameters of the vehicle quality and the system inherent parameters are combined into a calculation formula containing the vehicle mass, the calculation formula becomes a mass combination type parameter, and the mass combination type parameter is also classified into the vehicle quality; (m1+m0) ), (m2-m0), etc. belong to the vehicle quality; if the parameters such as m2*g, m1*g become the gravity of the object, but in the present invention, it is still classified as the vehicle mass, not the source power. parameter.
6.3、当两个或以上的系统固有参数组合成一个计算式(如((Ke*Km)*(im/R))、或(im/R)等),则该计算式仍然归类于系统固有参数。6.3. When two or more system intrinsic parameters are combined into one calculation formula (such as ((Ke*Km)*(im/R)), or (im/R), etc.), the calculation formula is still classified in the system. Inherent parameters.
7、本发明所述动力传递状况关联因子,指与车辆的动力传递状况判断有直接或间接关联的参数, 其包括所述车辆的车况信息、路况信息、载况信息、位置信息、车辆的车辆质量、源动力参数、系统运行参数、动力装置运行工况中任意一个或多个参数;本发明所述车况主要指车辆动力系统和传动系统的状况,如车辆的机件良好、润滑良好、磨损小则车况良好指数高;如车辆磨损严重则车况良好指数低;路况信息,主要指路面的平整度,路面越平整则路况良好指数高;载况,主要指车辆装载人员或物品的状况,如车内人员频繁跳动或物品在车内任意滚动,则载况良好指数低;本发明所述位置信息可根据GPS、数字地图等方式获取;7. The power transmission condition correlation factor according to the present invention refers to a parameter directly or indirectly related to the determination of the power transmission condition of the vehicle. The vehicle condition information, the road condition information, the load condition information, the position information, the vehicle quality of the vehicle, the source power parameter, the system operating parameter, the power device operating condition, and any one or more parameters of the vehicle; Mainly refers to the condition of the vehicle's power system and transmission system. If the vehicle's parts are good, the lubrication is good, and the wear is small, the vehicle condition is good. If the vehicle is seriously worn, the vehicle condition is good. The road condition information mainly refers to the road surface roughness and the road surface. The flatter the road condition is good, the index is high; the load condition mainly refers to the condition of the vehicle loader or the item. If the person in the vehicle frequently beats or the item rolls freely in the vehicle, the good condition index is low; the position information according to the present invention can be GPS, digital map, etc.;
本发明中后续实施例中参数值的具体获取方式,都可采用前述的所有的车辆运行参数的获取方式,为了描述简便,后续实施例中参数值的具体获取方式可省略不写。For the specific acquisition manner of the parameter values in the subsequent embodiments of the present invention, all the foregoing vehicle operating parameter acquisition manners may be used. For the convenience of description, the specific acquisition manner of the parameter values in the subsequent embodiments may be omitted.
8、本发明所述的“车辆由动力装置控制运行”的说明:8. Description of "the vehicle is controlled by the power unit" according to the present invention:
8.1、本发明约定:“车辆由动力装置控制运行”指车辆单独由动力装置控制运行的状态,该状态通常不包括车辆停车、熄火、空挡溜车、或机械制动等所有“车辆非动力装置控制运行”的状态;因为在“车辆非动力装置控制运行”时不便于通过采集源动力参数及计算来监控车辆的运行。8.1. The invention stipulates that “the vehicle is controlled by the power unit” refers to a state in which the vehicle is controlled by the power unit alone, and the state usually does not include all “vehicle non-powered devices such as vehicle parking, flameout, neutral shifting, or mechanical braking”. The state of control operation; because it is not convenient to monitor the operation of the vehicle by collecting source power parameters and calculations during "vehicle non-powered device control operation".
8.2、“车辆由动力装置控制运行”状态或“车辆非动力装置控制运行”状态,可由车辆的中央控制器来识别与给定;也可以通过获取动力装置运行状态字或动力装置控制命令字来识别、判断动力装置驱动状态的“正转或反转或停机”状态,再配合机械制动器的动作状态信息来识别当前状态为“车辆由动力装置控制运行”或“车辆非动力装置控制运行”。8.2. The "vehicle controlled by power plant" state or the "vehicle non-powered device control operation" state may be identified and given by the central controller of the vehicle; or may be obtained by acquiring the power plant operating state word or the power device control command word. The "forward or reverse or stop" state of the driving state of the power device is recognized and judged, and the current state of the mechanical brake is used to identify the current state as "the vehicle is controlled by the power device" or "the vehicle is not controlled by the power device".
8.3、本发明提供的一种车辆由动力装置控制运行时的监控方法,所述的“车辆由动力装置控制运行时”可有时间上的起点、结束点;8.3. A monitoring method for controlling a running time of a vehicle by a power device provided by the present invention, wherein the “vehicle controlled by the power device” may have a starting point and an ending point in time;
可设定从“车辆非动力装置控制运行”的状态进入“车辆由动力装置控制运行”状态时,作为本“车辆由动力装置控制运行”的时间段的起点,意味着一个新的“车辆由动力装置控制运行”的时间段的开始;It can be set from the state of "vehicle non-powered device control operation" to the "vehicle controlled by power plant operation" state, as the starting point of the time period of the "vehicle controlled by the power plant operation", meaning a new "vehicle by The beginning of the time period in which the power unit controls operation;
可设定从“车辆由动力装置控制运行”进入“车辆非动力装置控制运行”状态如停车、机械刹车、空挡溜车等时,作为本“车辆由动力装置控制运行”的时间段的结束点;It can be set from the "the vehicle is controlled by the power unit" to the "vehicle non-power unit control operation" state such as parking, mechanical brake, neutral block, etc., as the end point of the time period in which the "vehicle is controlled by the power unit" ;
每一个“车辆由动力装置控制运行”的时间段的长度,可长可短,只要一直处于“车辆由动力装置控制运行”中,长可达数小时,短则几分钟甚至几秒;显而易见的,“车辆由动力装置控制运行”的时间段,与本文中所述“运行流程”,两者实质意义一样,完全等同;The length of each "the vehicle is controlled by the power unit" can be as long or as short as long as it is always in the "vehicle controlled by the power unit", which can be as long as several hours, as short as a few minutes or even seconds; The period of time when the "vehicle is controlled by the power unit" is the same as the "operational flow" described in this article.
即使同一辆车辆,在不同的“车辆由动力装置控制运行”的时间段中(也即不同的运行流程中),某些参数尤其是车辆的运载物品质量m1可能发生变化,如乘客增加则m1自然变大,如乘客减少则m1自然变小,假设空载车体质量为1500KG的7座汽车,在司机单人乘坐时和满载时车辆质量值可能在80KG到560KG中变化;Even in the same vehicle, during different time periods of "the vehicle is controlled by the power unit" (that is, in different operating procedures), certain parameters, especially the mass of the goods carried by the vehicle, m1 may change, such as the increase in passengers, m1 Naturally, if the passengers are reduced, the m1 will naturally become smaller. Assuming a 7-seat car with an empty body mass of 1500KG, the vehicle mass value may vary from 80KG to 560KG when the driver is alone and at full load;
为了避免车辆质量正常波动导致导致车辆的动力系统和机械传动系统的运行状况无法进行高精度高灵敏度的监控,所以本发明提供一个基于自学习机制的根据满足设定条件时进行车辆运动平衡 计算所获取的联合运算值设定所述参考数据的技术方案、可以自动跟随载荷的正常变化而柔性化调整参考数据,特别适用于每次运载的人员或物品质量都可能大幅度变化的车辆的监控。In order to avoid the normal fluctuation of the vehicle quality, the operation state of the power system and the mechanical transmission system of the vehicle cannot be monitored with high precision and high sensitivity, the present invention provides a self-learning mechanism based on the vehicle motion balance according to the set conditions. Calculating the obtained joint operation value setting technical solution of the reference data, and can flexibly adjust the reference data by automatically following the normal change of the load, and is particularly suitable for the vehicle whose vehicle or item quality may vary greatly each time monitor.
9、动力装置运行工况,包括动力装置驱动状态、动力装置制动状态等多种工况;9. The operating conditions of the power unit, including the driving state of the power unit and the braking state of the power unit;
9.1、当车辆的动力装置为电机时,动力装置驱动状态可简称为电动状态、动力装置制动状态即为电机制动状态;其中电机制动状态又包含再生回馈发电制动、能耗制动等多种状态;当车辆的动力装置为燃料发动机时,动力装置运行工况则分为燃料发动机驱动状态、燃料发动机制动状态等;当车辆的动力装置为混合动力装置时,动力装置运行工况则分为混合动力装置驱动状态、混合动力装置制动状态等;9.1. When the power device of the vehicle is a motor, the driving state of the power device may be referred to as the electric state, and the braking state of the power device is the motor braking state; wherein the motor braking state includes the regenerative feedback generating braking and the energy braking When the power device of the vehicle is a fuel engine, the operating conditions of the power device are divided into a fuel engine driving state, a fuel engine braking state, and the like; when the power device of the vehicle is a hybrid device, the power device operating device The condition is divided into the driving state of the hybrid device, the braking state of the hybrid device, and the like;
为了便于描述和业内技术人员理解本发明,本发明提供的后述的实施例1到实施例32中,车辆均默认为在动力装置控制下往车头方向前进运行。倒车属于非常短暂的过程,倒车过程中监控几乎没有实际意义;当然也可以用本发明提供的系列技术方案,在倒车时进行相关的监控保护。For ease of description and understanding of the present invention by those skilled in the art, in the first to third embodiments of the present invention provided by the present invention, the vehicles are all driven forward by the power unit under the control of the power unit. Reversing is a very short process, and monitoring during reversing has little practical significance; of course, it is also possible to use the series of technical solutions provided by the present invention to perform related monitoring and protection during reversing.
为了便于描述和业内技术人员理解本发明,本发明约定如下9.2和9.3的参数设置方法:For ease of description and to understand the present invention by those skilled in the art, the present invention stipulates the following parameter setting methods of 9.2 and 9.3:
9.2、在本发明的后述实施例中,当车辆的动力装置为电机且当电机运行工况处于电动状态时,电机转速n1、车辆的纵向速度VX均约定为正值;各电机驱动参数(电气功率、电磁转矩Te、转矩电流分量iq、电机电流Io)均为正值;依据电气能量所计算的机械驱动力也为正值,表示电机此时处于将电能转化成机械能的状态;9.2. In the later-described embodiment of the present invention, when the power device of the vehicle is a motor and when the operating condition of the motor is in an electric state, the motor speed n1 and the longitudinal speed V X of the vehicle are all agreed to be positive values; (Electrical power, electromagnetic torque Te, torque current component iq, motor current Io) are positive values; the mechanical driving force calculated according to electrical energy is also a positive value, indicating that the motor is in a state of converting electrical energy into mechanical energy at this time;
同理,当车辆的动力装置为燃料发动机且运行工况处于燃料发动机驱动状态时,发动机转速n1、车辆纵向速度VX均约定为正值:各燃料动力参数均为正值,表示燃料发动机此时处于将燃料转化成机械能的状态;Similarly, when the power device of the vehicle is a fuel engine and the operating condition is in the fuel engine driving state, the engine speed n1 and the vehicle longitudinal speed V X are all agreed to be positive values: each fuel power parameter is positive, indicating that the fuel engine is At a time when the fuel is converted into mechanical energy;
同理,当车辆的动力装置为混合动力装置且运行工况为混合动力装置驱动状态时,发动机转速n1、车辆纵向速度VX均约定为正值:各混合动力参数均为正值;Similarly, when the power device of the vehicle is a hybrid device and the operating condition is the driving state of the hybrid device, the engine speed n1 and the vehicle longitudinal speed V X are all agreed to be positive values: each hybrid power parameter is a positive value;
9.3、在本发明的后述实施例中,当电机运行工况处于电机制动状态时,电机转速n1、车辆的纵向速度VX仍约定为正值:各电机驱动参数(电气功率、电磁转矩Te、转矩电流分量iq)均为负值;依据电气能量所计算的机械驱动力也为负值,表示电机此时处于将机械能转化成电能的状态;9.3. In the later embodiment of the present invention, when the motor operating condition is in the motor braking state, the motor speed n1 and the longitudinal speed V X of the vehicle are still agreed to be positive values: each motor driving parameter (electric power, electromagnetic rotation) The moment Te and the torque current component iq) are both negative values; the mechanical driving force calculated according to the electrical energy is also a negative value, indicating that the motor is in a state of converting mechanical energy into electrical energy at this time;
同理,当车辆的动力装置为燃料发动机时,当运行工况处于燃料发动机制动状态时,发动机转速n1、车辆的纵向速度VX仍约定为正值;如果此时燃料动力参数为通过转矩传感器测量所得则须约定为负值;Similarly, when the power device of the vehicle is a fuel engine, when the operating condition is in the fuel engine braking state, the engine speed n1 and the longitudinal speed V X of the vehicle are still agreed to be positive values; if the fuel power parameter is passed through The moment sensor measurement must be agreed to a negative value;
同理,当车辆的动力装置为混合动力装置且运行工况为混合动力装置制动状态时,发动机转速n1、车辆纵向速度VX均约定为正值,如果此时混合动力参数为通过转矩传感器测量所得则须约定为负值;Similarly, when the power device of the vehicle is a hybrid device and the operating condition is the braking state of the hybrid device, the engine speed n1 and the vehicle longitudinal speed V X are all agreed to be positive values, if the hybrid parameter is the passing torque at this time. The sensor measurement must be agreed to a negative value;
9.4、本发明提供的供参考的动力装置运行工况的识别方法如下:9.4. The method for identifying the operating conditions of the power unit provided by the present invention is as follows:
9.4.1、电机运行工况的识别方法如下: 9.4.1. The identification method of the motor operating conditions is as follows:
供参考的电机运行工况的识别方法1:Method for identifying the operating conditions of the motor for reference 1:
先获取电机的电磁转矩Te与电机转速n1,进而进行如下识别:First, the electromagnetic torque Te of the motor and the motor speed n1 are obtained, and then the following identification is performed:
当Te与n1方向相同时,可识别当前电机运行工况为:电动状态;When Te and n1 are in the same direction, the current motor operating condition can be identified as: an electric state;
当Te与n1方向相反时,可识别当前电机运行工况为:电机制动状态;When Te and n1 are opposite in direction, the current motor operating condition can be identified as: motor braking state;
根据前述约定,则根据Te的正负可自然的识别出电机运行工况。According to the foregoing convention, the operating condition of the motor can be naturally recognized according to the positive and negative of Te.
供参考的交流电机的运行工况识别方法2:For the reference of the AC motor operating conditions identification method 2:
当Udc小于U2i的峰值时,当前电机运行工况趋向于电动状态;When Udc is less than the peak value of U2i, the current motor operating conditions tend to be motorized;
当Udc大于U2i的峰值时,当前电机运行工况趋向于电机制动状态;When Udc is greater than the peak value of U2i, the current motor operating condition tends to the motor braking state;
供参考的交流异步电机的电机运行工况识别方法3:Motor operating condition identification method for AC asynchronous motor for reference 3:
当n1<n0时,当前电机运行工况趋向于电动状态;When n1 < n0, the current motor operating conditions tend to be electric;
当n1>n0时,当前电机运行工况趋向于电机制动状态;When n1>n0, the current motor operating condition tends to the motor braking state;
供参考的电机运行工况的识别方法4:部分型号的电机驱动装置如四象限变频器,也可通过读取其的内部状态字,直接识别判断电机运行工况。For the reference of the motor operating conditions identification method 4: Some models of motor drive devices, such as four-quadrant inverters, can also directly identify and determine the motor operating conditions by reading its internal status word.
供参考的临界切换区识别方法5:Critical switching area identification method 5 for reference:
电机运行工况中,无论是在电动状态,还是电机制动状态,均包含一个较特殊的阶段:临界切换区;当电机处于电动状态的临界切换区,意味着很容易进入电机制动状态;当电机处于电机制动状态的临界切换区,意味着很容易进入电动状态;In the motor operating condition, whether in the electric state or the motor braking state, a special stage is included: the critical switching zone; when the motor is in the critical switching zone of the electric state, it means that it is easy to enter the motor braking state; When the motor is in the critical switching zone of the motor braking state, it means that it is easy to enter the electric state;
当电机运行工况处于临界切换区时,可能影响计算的准确性,可以中止参数的计算或监控;可设置一临界状态识别门限值Te_gate,当|Te|<Te_gate时,可判断当前电机运行工况处于临界切换区;When the motor operating condition is in the critical switching zone, it may affect the accuracy of the calculation, and the calculation or monitoring of the parameter may be suspended; a critical state identification threshold Te_gate may be set, and when |Te|<Te_gate, the current motor operation may be judged. The working condition is in the critical switching area;
9.4.2、其他的动力装置运行工况、临界切换区的识别方法:9.4.2. Identification methods for other power plant operating conditions and critical switching zones:
当非电机驱动参数类型的源动力参数(如后端的电气动力参数、燃料动力参数、混合动力参数等)的正负可测量时(如采用转矩传感器测量信号),则根据该源动力参数的正负可识别车辆的动力装置运行工况;当该源动力参数的值为正时可判断动力装置运行工况为驱动状态,当该源动力参数的值为负时可判断动力装置运行工况为制动状态;当然,如果燃料动力参数为燃料消耗率类型的参数,则不便于测量其正负,燃料发动机制动状态时也不便于将车体能量逆向转化成燃料;When the source and power parameters of the non-motor drive parameter type (such as the back end electrical power parameter, fuel power parameter, hybrid power parameter, etc.) are measurable (such as using a torque sensor to measure the signal), then according to the source dynamic parameter Positive and negative can identify the operating condition of the power plant of the vehicle; when the value of the source power parameter is positive, it can be judged that the operating condition of the power device is the driving state, and when the value of the source power parameter is negative, the operating condition of the power device can be judged It is a braking state; of course, if the fuel power parameter is a fuel consumption rate type parameter, it is inconvenient to measure the positive and negative, and the fuel engine braking state is also inconvenient to convert the vehicle body energy into fuel in reverse;
根据机械组合型参数中的车辆的机械类综合运行力(m2*g*f*cosθ+m2*g*sinθ+m2*a+fw),也可识别动力装置运行工况;当该机械类综合运行力的值为正时可判断车辆的动力装置运行工况为驱动状态,表示此时车辆需吸取源动力参数表示的动力驱动车辆纵向运行;当该机械类综合运行力的值为负时可判断车辆的动力装置运行工况为制动状态,表示此时车辆的动能或势能可回馈给车体或需要制动;当该机械类综合运行力的绝对值低于预设的阈值(如额定值的5-10%)时,则可判断当前动力装置运行工况处于临界切换区,该方法也可称为临界切换区识别方法6。 According to the mechanical comprehensive running force of the vehicle in the mechanical combination parameter (m2*g*f*cosθ+m2*g*sinθ+m2*a+fw), the operating condition of the power unit can also be identified; when the mechanical class is integrated When the value of the running force is positive, it can be judged that the running condition of the power device of the vehicle is the driving state, indicating that the vehicle needs to absorb the longitudinal driving of the power-driven vehicle indicated by the source power parameter; when the value of the comprehensive running force of the mechanical class is negative Determining that the operating condition of the power device of the vehicle is a braking state, indicating that the kinetic energy or potential energy of the vehicle can be fed back to the vehicle body or requires braking; when the absolute value of the comprehensive operating force of the mechanical class is lower than a preset threshold (such as rated When the value is 5-10%), it can be judged that the current power plant operating condition is in the critical switching zone, and the method can also be referred to as the critical switching zone identification method 6.
某些车辆,还可直接读取动力装置控制系统(如燃料发动机的OBD系统)的信息识别车辆的运行工况、临界切换区。综合前述临界切换区识别方法5、6及现有技术得出:比较某预先选择的参数是否超过预设的范围,可判断车辆的运行工况是否处于临界切换区;该预先选择的参数,优选为源动力参数和/或机械类综合运行力。In some vehicles, the information of the power plant control system (such as the OBD system of the fuel engine) can also be directly read to identify the operating conditions of the vehicle and the critical switching zone. Combining the foregoing critical switching area identification methods 5 and 6 and the prior art, it is determined whether a pre-selected parameter exceeds a preset range, and whether the operating condition of the vehicle is in a critical switching area is determined; the pre-selected parameter is preferably For the source dynamic parameters and / or mechanical class comprehensive operating force.
10、本发明所述的网络系统,包括而不局限于:各种有线或无线的移动3G、4G网、互联网、物联网、车联网、交警网络中心、运营管理中心、车辆故障诊断中心、GPS网、车内网、局域网等等;网络系统可包含相应的人机交互界面、存储系统、数据处理系统以及手机APP系统等;与车辆运行相关的人员或机构(如驾乘人员、运营管理方、交警、故障诊断中心)可通过网络系统实时或事后监控车辆运行状况。10. The network system according to the present invention includes, but is not limited to, various wired or wireless mobile 3G, 4G networks, the Internet, the Internet of Things, the Internet of Vehicles, the traffic police network center, the operation management center, the vehicle fault diagnosis center, and the GPS. Network, in-vehicle network, local area network, etc.; network system can include corresponding human-computer interaction interface, storage system, data processing system, mobile APP system, etc.; personnel or institutions related to vehicle operation (such as driver and passenger, operation management party) , traffic police, fault diagnosis center) can monitor the vehicle health status in real time or afterwards through the network system.
本发明并非作为一种纯物理描述的文献,而是优先作为一种技术方案的集合,且以车辆运动平衡计算为核心的技术方案;所以以基础技术方案、获取参数值的技术途径作为划分数据类型的优先选择;如车辆总质量m2、运载物品质量m1因其通常需要车辆运动平衡计算获取其真实值(不便于频繁进行磅秤量测),所以归类于车辆质量参数;空载车体质量m0因该参数的值通常可便利的由系统预设值得知,所以归类于系统固有参数类型;燃料质量因在车辆运行中其值处于持续变化中,通常需要根据测量途径获取其实际值,所以归类于系统运行参数中。本发明中未一一例举说明的其他参数,均可按参数取值途径、技术特性相应的归类。The present invention is not a purely physical description document, but a technical solution that is prioritized as a collection of technical solutions and with vehicle motion balance calculation as the core; therefore, the basic technical solution and the technical approach of obtaining parameter values are used as the division data. The priority of the type; for example, the total mass of the vehicle m2, the mass of the carried item m1 is usually calculated by the vehicle's motion balance to obtain its true value (it is not convenient for frequent weighing measurement), so it is classified into the vehicle quality parameter; M0 because the value of this parameter can usually be conveniently determined by the system preset value, so it is classified into the system inherent parameter type; the fuel quality is constantly changing according to the measurement path, and usually needs to obtain its actual value according to the measurement path. So it is classified in the system operating parameters. Other parameters not described in the present invention may be classified according to the parameter value path and the technical characteristics.
特别声明1:本发明后述所提供的所有实施例中任一车辆运行参数的值的获取方法和动力装置运行工况的识别方法,均可采用前述的方法进行;当然也可以参考其他的现有公知技术进行。Special statement 1: The method for acquiring the value of any vehicle operating parameter and the method for identifying the operating condition of the power device in all the embodiments provided by the present invention described later may be performed by the foregoing method; It is carried out by well-known techniques.
第二部分内容:本发明的具体发明内容及具体实施例如下,其中,应用于电气动力车辆以及应用于燃料动力车辆的各系统及方法均可以进行相互应用,并可根据本申请文件中内容做相应的等效替换;本发明中任一处技术方案均可用于本发明中其他类型的车辆、其他类型的技术方案中。Part II: Specific Invention and Specific Embodiments of the Invention For example, the systems and methods applied to an electric powered vehicle and to a fuel powered vehicle can be mutually applied and can be made according to the contents of the present application. Corresponding equivalent replacement; any technical solution in the present invention can be used in other types of vehicles, other types of technical solutions in the present invention.
本发明中,测算对象是车辆运行参数中所包含的任意一种参数;所述车辆运行参数包括车辆质量、源动力参数、系统运行参数,所述系统运行参数包括机械运行参数、系统固有参数、质量变化型物品质量等;In the present invention, the measurement object is any one of the parameters included in the vehicle operating parameter; the vehicle operating parameter includes a vehicle mass, a source power parameter, and a system operating parameter, and the system operating parameter includes a mechanical operating parameter, a system inherent parameter, Quality change type of goods, etc.;
本发明中所述联合运算值也即联合运算原值;本发明所述联合运算值,仅仅表示一种数据类型/或数据获取的途径,表示该数值为基于车辆运动平衡计算公式计算所得的结果,无其他含义;基于车辆运动平衡计算的计算联合运算值有无穷多种实现公式(如后续文件中实施例1到实施例33、公式13.1到公式13.6、实施例41等);获取车辆的测算对象的联合运算值,可参考下述诸多实施例进行:The joint operation value in the present invention is also the joint operation original value; the joint operation value of the present invention only represents a data type/or data acquisition path, and the value is calculated based on the vehicle motion balance calculation formula. There is no other meaning; there are infinitely many implementation formulas for calculating the joint operation value based on the vehicle motion balance calculation (such as Embodiment 1 to Embodiment 33, Equation 13.1 to Formula 13.6, Embodiment 41, etc. in the subsequent documents); The joint operation values of the objects can be referred to the following embodiments:
特别注明1:为了便于描述和业内技术人员理解本发明:当测算对象为车辆质量时,联合运算值或非联合运算值均可直接用参数名m1或m2表示;当测算对象为源动力参数或系统运行参数时, 联合运算值的表达式可能会在参数名后加一后缀:_cal;如机械传动系统的效率系数参数名Km,联合运算值用Km_cal表示;如滚阻系数参数名为μ1或f,该联合运算值用μ1_cal或f_cal表示;Special Note 1: For ease of description and technical personnel in the industry understand the present invention: when the measurement object is the vehicle mass, the joint operation value or the non-joint operation value can be directly represented by the parameter name m1 or m2; when the measurement object is the source dynamic parameter Or when the system runs parameters, The expression of the joint operation value may be followed by a suffix after the parameter name: _cal; for example, the efficiency coefficient parameter name Km of the mechanical transmission system, and the joint operation value is represented by Km_cal; if the rolling resistance coefficient parameter name is μ1 or f, the joint operation The value is expressed in μ1_cal or f_cal;
特别注明2:本发明所述联合运算值,实际意义等同于申请号为201410312798.3的中国专利申请中所述理论值;本发明所述车辆质量,实际意义等同于申请号为201410312798.3的中国专利申请中所述运载质量;本发明所述等同包括两者的核心性质、技术处理方案等同等,两者可直接替换;In particular, the joint operation value of the present invention is equivalent to the theoretical value described in the Chinese patent application No. 201410312798.3; the quality of the vehicle described in the present invention is equivalent to the Chinese patent application with the application number 201410312798.3 The carrying quality in the present invention; the equivalent of the present invention includes the core properties of the two, the technical processing scheme equivalent, etc., and the two can be directly replaced;
本发明后述的实施例1到实施例40中动力装置为电机,车辆处于电机控制运行状态;下述各实施例中公式均为基于据车辆纵向动力学方程计算所得;当然,也可用其他的动力装置(例如燃油发动机、空气发动机等),也可根据相应的动力装置选择相应的源动力参数,应用于其他类型的车辆;In the first to fourth embodiments of the present invention, the power device is a motor, and the vehicle is in a motor control operation state; the formulas in the following embodiments are all calculated based on the longitudinal dynamic equation of the vehicle; of course, other The power device (such as a fuel engine, an air engine, etc.) may also be selected according to the corresponding power device to be applied to other types of vehicles;
实施例1:Example 1:
获取车辆的车辆质量的联合运算值(运行条件为:忽略路面坡度(如假设路面平直)、纵向加速度(如假设车辆匀速运行)、风阻(如假设车辆低速运行)、燃料质量(如假设车辆为插电式或储电式电动车辆)等因素;默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation value of the vehicle mass of the vehicle (operating conditions are: ignore the road gradient (if the road is assumed to be straight), longitudinal acceleration (such as assuming the vehicle runs at a constant speed), wind resistance (such as assuming low-speed operation of the vehicle), fuel quality (such as a hypothetical vehicle) Factors such as plug-in or storage electric vehicles; default power unit operating conditions are power unit drive status:
m2=Kem*(Te*im/R1)/(g*μ1)(公式A1-1)M2=Kem*(Te*im/R1)/(g*μ1) (Formula A1-1)
m1=m2-m0;M1=m2-m0;
实施例2:Example 2:
获取车辆的车辆质量的联合运算值;(运行条件为:忽略路面坡度、风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation value of the vehicle mass of the vehicle; (the operating conditions are: ignore the road gradient, wind resistance, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=(Ki*iq*im/R1)/(g*μ1+a)(公式A2-1)M2=(Ki*iq*im/R1)/(g*μ1+a) (Formula A2-1)
m1=m2-m0;M1=m2-m0;
实施例3:Example 3:
获取车辆的车辆质量的联合运算值(运行条件:两次变速运行,忽略路面坡度、风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation value of the vehicle mass of the vehicle (operating conditions: two shifting operations, ignoring the road gradient, wind resistance, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=(fq2-fq1)/(a2-a1);(公式A3-4-3);M2=(fq2-fq1)/(a2-a1); (Formula A3-4-3);
m1=m2-m0;M1=m2-m0;
fq2与a2为time2时获取的驱动力和纵向加速度,Te2为time2时获取的电磁转矩;fq2=KeKm(Te2*im/R1)The driving force and longitudinal acceleration obtained when fq2 and a2 are time2, and the electromagnetic torque obtained when Te2 is time2; fq2=KeKm(Te2*im/R1)
fq1与a1为time1时获取的驱动力和纵向加速度,Te1为time1时获取的电磁转矩;fq1=KeKm(Te1*im/R1)The driving force and longitudinal acceleration obtained when fq1 and a1 are time1, and the electromagnetic torque obtained when Te1 is time1; fq1=KeKm(Te1*im/R1)
m2=(KeKm(Te2-Te1)*im/R1)/(a2-a1);(公式A3-4-4);M2=(KeKm(Te2-Te1)*im/R1)/(a2-a1); (Formula A3-4-4);
实施例4: Example 4:
获取车辆的车辆质量的联合运算值(运行条件为:忽略纵向加速度、风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation value of the vehicle mass of the vehicle (operating conditions are: ignore longitudinal acceleration, wind resistance, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=(Pm/V1)/(g*μ1*cosθ+g*sinθ);(公式A4-1)M2=(Pm/V1)/(g*μ1*cosθ+g*sinθ); (Formula A4-1)
实施例5:Example 5:
获取所述车辆的车辆质量的联合运算值(运行条件为:忽略风阻、燃料质量;Obtaining a joint operation value of the vehicle mass of the vehicle (operating conditions are: ignoring wind resistance, fuel quality;
当动力装置运行工况为动力装置驱动状态:When the operating condition of the power unit is the driving state of the power unit:
m2=Kem*(|Te|*im/R1)/(g*μ1*cosθ+g*sinθ+a);(公式A5-2-2)M2=Kem*(|Te|*im/R1)/(g*μ1*cosθ+g*sinθ+a); (Formula A5-2-2)
当动力装置运行工况处于动力装置制动状态时:When the power unit operating condition is in the power unit braking state:
m2=(((-|Te|)*im/R1)/Kem)/(g*μ1*cosθ+g*sinθ+a);(公式A5-2-3)M2=(((−|Te|)*im/R1)/Kem)/(g*μ1*cosθ+g*sinθ+a); (Formula A5-2-3)
m1=m2-m0;M1=m2-m0;
实施例6:Example 6
获取车辆的车辆质量的联合运算值(运行条件:忽略路面坡度、纵向加速度、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation value of the vehicle mass of the vehicle (operating conditions: ignore the road gradient, longitudinal acceleration, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=((Te*n1/9.55)/V1-fw)/(g*μ1);(公式A6-1)M2=((Te*n1/9.55)/V1-fw)/(g*μ1); (Formula A6-1)
实施例7:Example 7
获取车辆的车辆质量的联合运算值(运行条件:忽略燃料质量)Obtain the joint operation value of the vehicle mass of the vehicle (operating conditions: ignore fuel quality)
当动力装置运行工况为动力装置驱动状态:When the operating condition of the power unit is the driving state of the power unit:
m2=(Kem*(|Te|*im/R1)/δ–fw–L0*ω0)/(g*μ1*cosθ+g*sinθ+a);当动力装置运行工况处于动力装置制动状态时:M2=(Kem*(|Te|*im/R1)/δ–fw–L0*ω0)/(g*μ1*cosθ+g*sinθ+a); when the power unit operating condition is in the power unit braking state Time:
m2=((((-|Te|)*im/R1)/Kem)/δ–fw–L0*ω0)/(g*μ1*cosθ+g*sinθ+a);M2=(((-|Te|)*im/R1)/Kem)/δ–fw–L0*ω0)/(g*μ1*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
为了计算简化,δ可直接取值为1,也可以忽略L0,直接设定L0*ω0=0;For calculation simplification, δ can be directly taken as 1, or L0 can be ignored, and L0*ω0=0 can be directly set;
实施例8:Example 8
获取车辆的电磁转矩的联合运算值Te_cal;(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtaining the joint operation value Te_cal of the electromagnetic torque of the vehicle; (the operating condition is: ignoring the fuel quality, and the default power plant operating condition is the power unit driving state:
Te_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)/(im/R1),(公式A10-1)Te_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)/(im/R1), (Formula A10-1)
实施例9: Example 9
获取车辆的机电传动综合的效率系数的联合运算值Kem_cal;(运行条件为:忽略燃料质量):Obtain the joint operation value Kem_cal of the integrated efficiency coefficient of the electromechanical transmission of the vehicle; (operating condition: ignore fuel quality):
当动力装置运行工况为动力装置驱动状态:When the operating condition of the power unit is the driving state of the power unit:
Kem_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)/(Te*im/R1),Kem_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)/(Te*im/R1),
当动力装置运行工况为动力装置制动状态:When the power unit operating condition is the power unit braking state:
Kem_cal=(Te*im/R1)/(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw);Kem_cal=(Te*im/R1)/(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw);
实施例10:Example 10:
获取车辆的滚阻系数的联合运算值μ1_cal(运行条件:忽略燃料质量):Obtain the joint operation value μ1_cal of the rolling resistance coefficient of the vehicle (operating condition: ignore fuel quality):
当动力装置运行工况为动力装置驱动状态:When the operating condition of the power unit is the driving state of the power unit:
μ1_cal=(Kem*(|k12*cosφ*Uo*Io|/V1)–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ),(公式A13-1-2)11_cal=(Kem*(|k12*cosφ*Uo*Io|/V1)–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ), (Formula A13-1-2)
当动力装置运行工况为动力装置制动状态:When the power unit operating condition is the power unit braking state:
μ1_cal=((-|(k12*cosφ*Uo*Io)|/V1)/Kem–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ),(公式A13-1-3)11_cal=((-|(k12*cosφ*Uo*Io)|/V1)/Kem–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ), (Formula A13-1-3 )
上述k12是常数,可取值1.732;k12*cosφ*Uo*Io的替代计算式如下:The above k12 is a constant, and the value can be 1.732; the alternative calculation formula of k12*cosφ*Uo*Io is as follows:
(k12*cosφ*Uo*Io)=(k13*Ui*Ii)=(k13*Ub1*Ib1)=Pm,(k12*cosφ*Uo*Io)=(k13*Ui*Ii)=(k13*Ub1*Ib1)=Pm,
(k12*cosφ*Uo*Io)=(U4*I4/k14)=(Ub2*Ib2/k14)=Pm;(k12*cosφ*Uo*Io)=(U4*I4/k14)=(Ub2*Ib2/k14)=Pm;
转矩转速综合测力计算式1:(Te*im/R1)=(Te*n1/9.55/V1);Torque and speed integrated force calculation formula 1: (Te*im/R1)=(Te*n1/9.55/V1);
fw=(1/2)*Cd*(p0*S*(V2)2);也可将纵向速度V1直接替代V2;Fw=(1/2)*Cd*(p0*S*(V2) 2 ); the longitudinal velocity V1 can also be directly substituted for V2;
实施例11:Example 11
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtaining the combined operational values m1 and m2 of the vehicle mass of the vehicle; (the operating conditions are: ignoring the fuel mass, and the default power plant operating condition is the powerplant driving state:
m2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例12:Example 12
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtaining the combined operational values m1 and m2 of the vehicle mass of the vehicle; (the operating conditions are: ignoring the fuel mass, and the default power plant operating condition is the powerplant driving state:
m2=((Ke*Km)*(P2o/Vx)–fw)/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*(P2o/V x )–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0; M1=m2-m0;
实施例13:Example 13
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略路面坡度、纵向加速度、风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the joint operation values m1 and m2 of the vehicle mass of the vehicle; (the operating conditions are: ignoring the road gradient, longitudinal acceleration, wind resistance, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=((Ke*Km)*(Te*im/R))/(g*f);M2=((Ke*Km)*(Te*im/R))/(g*f);
m1=m2-m0;M1=m2-m0;
实施例14:Example 14
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtain the combined operational values m1 and m2 of the vehicle mass of the vehicle; (operating conditions are: ignoring wind resistance, fuel quality, and default power plant operating conditions are power plant driving states:
m2=((Ke*Km)*(iq*Ki*im/R))/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*(iq*Ki*im/R))/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例14的延伸方案说明:可用(Io*cosφ1*Ko)或(k21*I2o*cosφ2*Ko)或(k31*I3o*cosφ3*Ko)替代实施例四中的(iq*Ki),The extension scheme of Embodiment 14 illustrates that (iq*Ki) in Embodiment 4 can be replaced by (Io*cosφ1*Ko) or (k21*I2o*cosφ2*Ko) or (k31*I3o*cosφ3*Ko),
实施例15:Example 15
获取车辆的车辆质量的联合运算值m2;(运行条件为:忽略路面坡度、风阻、燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtaining the joint operation value m2 of the vehicle mass of the vehicle; (the operating conditions are: ignoring the road gradient, wind resistance, fuel quality, and the default power plant operating condition is the power unit driving state:
m2=((P2o_2/Vx2)-(P2o_1/Vx1))/(a2-a1);M2=((P2o_2/V x 2)-(P2o_1/V x 1))/(a2-a1);
上述参数中,P2o_1、Vx1、a1各自为tim1时获取的电气功率、纵向速度、纵向加速度;P2o_2、a2、Vx2均为不同于tim1时间点的tim2时获取的车辆运行参数(电气功率、纵向速度、纵向加速度);且a2≠a1;Among the above parameters, P2o_1, V x 1, and a1 are the electric power, longitudinal speed, and longitudinal acceleration obtained when tim1 is respectively; P2o_2, a2, and V x 2 are different from the vehicle operating parameters obtained when tim2 at the time point of tim1 (electrical Power, longitudinal velocity, longitudinal acceleration); and a2≠a1;
实施例16:Example 16:
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态:Obtaining the combined operational values m1 and m2 of the vehicle mass of the vehicle; (the operating conditions are: ignoring the fuel mass, and the default power plant operating condition is the powerplant driving state:
m2=(k31*(Ke*Km)*(P3i/Vx)–fw)/(g*f*cosθ+g*sinθ+a);M2=(k31*(Ke*Km)*(P3i/V x )–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例17:Example 17
获取车辆的车辆质量的联合运算值(运行条件为:忽略燃料质量):Obtain the joint calculated value of the vehicle's vehicle mass (operating condition: ignore fuel quality):
当动力装置运行工况为动力装置驱动状态:When the operating condition of the power unit is the driving state of the power unit:
m2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a); M2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a);
当动力装置运行工况处于动力装置制动状态时:When the power unit operating condition is in the power unit braking state:
m2=(-|(Te*im/R)|/(Ke*Km)–fw)/(g*f*cosθ+g*sinθ+a);M2=(-|(Te*im/R)|/(Ke*Km)–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例18:Example 18
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态;且电机为2个并列驱动时的情况,且假设该两电机型号、结构一致,各电机的Ke,Km,im,R值均相同;Te1、Te2为两个电机各自的电磁转矩;Obtaining the joint operation values m1 and m2 of the vehicle mass of the vehicle; (the operating condition is: ignoring the fuel mass, and the default power plant operating condition is the power unit driving state; and the motor is in the case of two parallel driving, and the two are assumed The motor model and structure are the same, and the values of Ke, Km, im and R of each motor are the same; Te1 and Te2 are the electromagnetic torques of the two motors;
m2=((Ke*Km)*(Te1+Te2)*im/R–fw)/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*(Te1+Te2)*im/R–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例18的延伸方案说明:同理,N多个电机并列驱动的车辆也可用本实施例的技术延伸计算,如将本实施例的(Te1+Te2)替换成(Te1+Te2+…+TeN)。The extension scheme of Embodiment 18 illustrates that, similarly, a vehicle in which N motors are driven in parallel can also be calculated by using the technique of this embodiment, such as replacing (Te1+Te2) of the present embodiment with (Te1+Te2+...+TeN). .
实施例19:Example 19
获取车辆的车辆质量的联合运算值(运行条件为:忽略燃料质量、且默认动力装置运行工况为动力装置驱动状态;且电机驱动装置为3个并列驱动;P2i_1、P2i_2、P2i_3为各电机驱动装置的输入电气功率;Obtain the joint operation value of the vehicle mass of the vehicle (the operating condition is: ignore the fuel quality, and the default power plant operating condition is the power unit driving state; and the motor driving device is three parallel driving; P2i_1, P2i_2, P2i_3 are driven by the respective motors Input electrical power of the device;
m2=(k21*(Ke*Km)*(P2i_1+P2i_2+P2i_3)/Vx–fw)/(g*f*cosθ+g*sinθ+a)M2=(k21*(Ke*Km)*(P2i_1+P2i_2+P2i_3)/V x –fw)/(g*f*cosθ+g*sinθ+a)
m1=m2-m0;M1=m2-m0;
实施例19的延伸方案说明:同理,N多个电机驱动装置并列驱动的车辆也可用本实施例的技术延伸计算,如将本实施例的(P2i_1+P2i_2+P2i_3)替换成(P2i_1+…+P2i_N)。The extension scheme of Embodiment 19 illustrates that, in the same way, a vehicle in which N plurality of motor drive devices are driven in parallel can also be calculated by using the technique of the embodiment, such as replacing (P2i_1+P2i_2+P2i_3) of the present embodiment with (P2i_1+...+ P2i_N).
实施例20:Example 20
获取车辆的车辆质量的联合运算值;(运行条件为:忽略燃料质量;电源装置为2个并列供电;P3i_1、P3i_2为各电源装置的输入功率)Obtain the joint operation value of the vehicle mass of the vehicle; (the operating condition is: ignore the fuel quality; the power supply device is two parallel power supplies; P3i_1, P3i_2 are the input power of each power supply device)
步骤2.1:识别电机运行工况(参考前述9.4节内容的识别方法);Step 2.1: Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
步骤2.2:当车辆所有的电机的运行工况均为电动状态时,进行下述车辆运动平衡计算:Step 2.2: When the operating conditions of all the motors of the vehicle are in the electric state, perform the following vehicle motion balance calculation:
m2=(k31*(Ke*Km)*(P3i_1+P3i_2)/Vx–fw)/(g*f*cosθ+g*sinθ+a);M2=(k31*(Ke*Km)*(P3i_1+P3i_2)/V x –fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
步骤2.3:当车辆所有的电机的运行工况不全为电动状态时,可中止车辆运动平衡计算,可用前一周期测算数据替代输出,或输出一个“多电机状态不一致”的状态信息。Step 2.3: When the operating conditions of all the motors of the vehicle are not all electric, the vehicle motion balance calculation can be aborted, and the output data of the previous period can be used instead of the output, or a status message of “multi-motor state inconsistency” can be output.
实施例20的延伸方案说明:同理,N多个电源装置并列供电的车辆也可用本实施例的技术延伸 计算,如将本实施例的(P3i_1+P3i_2)替换成(P3i_1+…+P3i_N)。The extension scheme of Embodiment 20 illustrates that, similarly, a vehicle in which N power supply devices are powered side by side can also be extended by the technology of this embodiment. The calculation is as follows: (P3i_1+P3i_2) of the present embodiment is replaced with (P3i_1+...+P3i_N).
实施例21:Example 21:
获取车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining the joint operation values m1 and m2 of the vehicle mass of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
机电组合型参数fq实质为基于电气参数计算所得的作用于驱动轮的机械驱动力;fq=(Ke*Km)*(Te*im/R);The electromechanical combined parameter fq is essentially a mechanical driving force acting on the driving wheel calculated based on the electrical parameter; fq=(Ke*Km)*(Te*im/R);
m2=(fq–fw)/(g*f*cosθ+g*sinθ+a);M2=(fq–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例22:Example 22
获取车辆的车辆质量的联合运算值;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value of the vehicle mass of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
机电组合型参数Tq实质为基于电气参数测算的作用于驱动轮的机械转矩;Tq=(Ke*Km)*Te*im;The electromechanical combined parameter Tq is essentially the mechanical torque acting on the drive wheel based on the electrical parameter measurement; Tq=(Ke*Km)*Te*im;
m2=(Tq/R–fw)/(g*f*cosθ+g*sinθ+a);M2=(Tq/R–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例23:Example 23
获取所述车辆的车辆质量的联合运算值;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value of the vehicle mass of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
机电组合型参数Pq实质为基于电气参数计算所得的驱动车辆纵向运行的机械功率;Pq=(Ke*Km)*P2o;The electromechanical combined parameter Pq is essentially the mechanical power of the longitudinal running of the vehicle based on the electrical parameter calculation; Pq=(Ke*Km)*P2o;
m2=(Pq/Vx–fw)/(g*f*cosθ+g*sinθ+a);M2=(Pq/V x –fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例24:Example 24:
获取所述车辆的车辆质量的联合运算值;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value of the vehicle mass of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
m2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*(Te*im/R)–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
实施例25: Example 25
获取车辆的机械传动系统的效率系数的联合运算值Km_cal;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value Km_cal of the efficiency coefficient of the mechanical transmission system of the vehicle; (the operating condition is: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit);
Km_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/(Ke*Te*im/R)Km_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/(Ke*Te*im/R)
实施例26:Example 26:
获取车辆的滚阻系数的联合运算值f_cal;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value f_cal of the rolling resistance coefficient of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
f_cal=((Ke*Km)*(P2o/Vx)–fw-m2*(g*sinθ+a))/(m2*g*cosθ)F_cal=((Ke*Km)*(P2o/V x )–fw-m2*(g*sinθ+a))/(m2*g*cosθ)
实施例27:Example 27:
获取车辆的风阻的联合运算值fw_cal;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态;双电机并列驱动,Po_1、Po_2为各电机的输出功率);Obtaining the combined operation value fw_cal of the wind resistance of the vehicle; (the operating condition is: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit; the parallel operation of the dual motors, Po_1 and Po_2 are the output power of each motor);
fw_cal=(Po_1+Po_2)*(Ke*Km)/Vx-m2*(g*f*cosθ+g*sinθ+a);Fw_cal=(Po_1+Po_2)*(Ke*Km)/V x -m2*(g*f*cosθ+g*sinθ+a);
实施例28:Example 28
获取车辆的电磁转矩的联合运算值Te_cal;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value Te_cal of the electromagnetic torque of the vehicle; (the operating condition is: ignoring the fuel quality; and the power plant operating condition is the power unit driving state);
Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)*im/R)Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)*im/R)
实施例29:Example 29
获取车辆的机电组合型参数fq的联合运算值fq_cal;机电组合型参数fq属于源动力参数;fq=(Ke*Km)*(Te*im/R),fq实质为基于电气参数测算的作用于驱动轮的机械驱动力;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtain the joint operation value fq_cal of the electromechanical combination parameter fq of the vehicle; the electromechanical combination parameter fq belongs to the source dynamic parameter; fq=(Ke*Km)*(Te*im/R), and fq is substantially based on the measurement of the electrical parameter The mechanical driving force of the driving wheel; (the operating condition is: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit);
fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fwFq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw
实施例30:Example 30:
获取车辆的机械组合型参数fr的联合运算值fr_cal;机械组合型参数fr属于系统运行参数中机械运行参数;fr=m2*(g*f*cosθ+g*sinθ+a),fr实质为不包含风阻的作用于驱动轮的车辆驱动力;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtain the joint operation value fr_cal of the mechanical combination type parameter fr of the vehicle; the mechanical combination type parameter fr belongs to the mechanical operation parameter in the system operation parameter; fr=m2*(g*f*cosθ+g*sinθ+a), fr is substantially no The vehicle driving force acting on the driving wheel including the wind resistance; (the operating condition is: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit);
步骤2.1:识别电机运行工况(参考前述9.4节内容的识别方法);Step 2.1: Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
步骤2.2:当电机运行工况为电机制动状态或临界切换区时,中止本次计算,并取前一计算周期的计算结果输出; Step 2.2: When the motor running condition is the motor braking state or the critical switching zone, the current calculation is aborted, and the calculation result output of the previous calculation cycle is taken;
步骤2.3:当电机运行工况为电动状态时,Step 2.3: When the motor operating condition is electric,
fr_cal=((Ke*Km)*(P2o/Vx)–fw)Fr_cal=((Ke*Km)*(P2o/V x )–fw)
实施例31:Example 31:
获取所述车辆的车辆质量的联合运算值m1和m2;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining joint operation values m1 and m2 of vehicle mass of the vehicle; (operating condition is: ignoring fuel quality; and power plant operating condition is power plant driving state);
m2=((Ke*Km)*(Te*im/R)/δ-(fw+fb+L0*β))/(g*f*cosθ+g*sinθ+a)M2=((Ke*Km)*(Te*im/R)/δ-(fw+fb+L0*β))/(g*f*cosθ+g*sinθ+a)
m1=m2-m0;M1=m2-m0;
实施例32:Example 32:
获取所述车辆的机械传动系统的效率系数的联合运算值Km_cal;机械传动系统的效率系数属于系统运行参数中系统固有参数;(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);Obtaining a joint operation value Km_cal of the efficiency coefficient of the mechanical transmission system of the vehicle; the efficiency coefficient of the mechanical transmission system belongs to the system inherent parameter in the system operation parameter; (the operating condition is: ignoring the fuel quality; and the power device operating condition is the power device) Drive state);
Km_cal=(m2*(g*f*cosθ+g*sinθ+a)+(fw+fb+L0*β))/(Ke*Te*im/R/δ)Km_cal=(m2*(g*f*cosθ+g*sinθ+a)+(fw+fb+L0*β))/(Ke*Te*im/R/δ)
实施例33:Example 33:
获取车辆的车辆质量的联合运算值(运行条件为:忽略燃料质量;在车辆倒车运行时,车辆前进或倒车状态,由车辆的中央控制器给定;)Obtaining the joint calculated value of the vehicle mass of the vehicle (operating conditions are: ignoring the fuel quality; when the vehicle is running backwards, the vehicle is moving forward or reversed, given by the central controller of the vehicle;)
步骤2.1:识别电机运行工况(参考前述9.4节内容的识别方法);Step 2.1: Identify the operating conditions of the motor (refer to the identification method in Section 9.4 above);
步骤2.2:当电机运行工况为电动状态时Step 2.2: When the motor operating condition is electric
m2=((Ke*Km)*|(Te*im/R)|–fw)/(g*f*cosθ+g*sinθ+a);M2=((Ke*Km)*|(Te*im/R)|–fw)/(g*f*cosθ+g*sinθ+a);
步骤2.3:当电机运行工况为电机制动状态时Step 2.3: When the motor operating condition is the motor braking state
m2=(-|(Te*im/R)|/(Ke*Km)–fw)/(g*f*cosθ+g*sinθ+a);M2=(-|(Te*im/R)|/(Ke*Km)–fw)/(g*f*cosθ+g*sinθ+a);
m1=m2-m0;M1=m2-m0;
通过本实施例技术方案,在车辆倒车时,仍然可进行相关车辆运行参数的测算,进而可以进行监控;Through the technical solution of the embodiment, when the vehicle is reversing, the calculation of the running parameters of the relevant vehicle can still be performed, and then the monitoring can be performed;
通过参考本实施例的技术方案,可将本发明所提供的任一测算方法、监控方法、测算系统、监控系统在倒车时也进行测算或监控。By referring to the technical solution of the embodiment, any measurement method, monitoring method, measurement system, and monitoring system provided by the present invention can also be measured or monitored when reversing.
为基于基于车辆运动平衡计算还有下述诸多典型计算公式:Fx为车辆的纵向驱动力;There are many typical calculation formulas based on vehicle motion balance calculation: Fx is the longitudinal driving force of the vehicle;
13.1、常规的车辆运动平衡模型为:Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw;(公式13.1)13.1. The conventional vehicle motion balance model is: Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw; (Equation 13.1)
13.2、在常规模型基础上,增加制动力fb分量的车辆运动平衡模型为: 13.2. On the basis of the conventional model, the vehicle motion balance model that increases the braking force fb component is:
Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw+fb;(公式13.2)Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw+fb; (Equation 13.2)
13.3、在常规模型基础上,增加了车辆的内部综合旋转刚体转动惯量L0*β分量的车辆运动平衡模型为:13.3. On the basis of the conventional model, the vehicle motion balance model of the vehicle's internal integrated rotating rigid body moment of inertia L0*β component is added as follows:
Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw+L0*β;(公式13.3)Fx=m2*g*f*cosθ+m2*g*sinθ+m2*a+fw+L0*β; (Equation 13.3)
13.4、在常规模型基础上,增加弯道系数δ的车辆运动平衡模型为:13.4. On the basis of the conventional model, the vehicle motion balance model with increasing the curve coefficient δ is:
Fx=(m2*g*f*cosθ+m2*g*sinθ+m2*a+fw)*δ;(公式13.4)Fx=(m2*g*f*cosθ+m2*g*sinθ+m2*a+fw)*δ; (Equation 13.4)
连同上述的13.1、13.2、13.3、13.4所示机械方式的车辆运动平衡模型,加上本发明所提供的实施例1-33所示,本发明所述的车辆运动平衡计算方案或车辆运动平衡模型,有无穷多个可以具体实现的数学计算式;显而易见的,本发明中车辆运动平衡、纵向动力平衡,指动力与相关阻力的平衡,包括匀速运行状态和变速运行状态。The vehicle motion balance calculation model or the vehicle motion balance model according to the present invention, together with the mechanical vehicle balance model shown in the above-mentioned 13.1, 13.2, 13.3, and 13.4, plus the embodiment 1-33 provided by the present invention. There are an infinite number of mathematical calculations that can be specifically realized; obviously, the vehicle motion balance and the longitudinal dynamic balance in the present invention refer to the balance between the power and the related resistance, including the constant speed operation state and the variable speed operation state.
综合上述计算公式以及其他实施例的计算公式,可概括一个综合的车辆运动平衡模型或计算公式:Combining the above calculation formula with the calculation formulas of other embodiments, a comprehensive vehicle motion balance model or calculation formula can be summarized:
E=m*X1-Y1;(公式13.5)E=m*X1-Y1; (Equation 13.5)
当忽略Y1时,该模型为:E=m*X1;(公式13.6)When Y1 is ignored, the model is: E=m*X1; (Equation 13.6)
其中:m为所述车辆的车辆质量;E为所述车辆的源动力参数;X1是与质量具有直接乘积关系的系数,X1包括所述车辆的滚阻系数、纵向加速度、纵向速度、路面坡度、机械传动系统的效率系数中任意一个或多个参数;Y1是与质量无直接乘积关系的分量,Y1包括所述车辆的风阻。X1和Y1均为车辆的系统运行参数;当控制车辆运行的动力装置为电机时,源动力参数为电机驱动参数。Where: m is the vehicle mass of the vehicle; E is the source power parameter of the vehicle; X1 is a coefficient having a direct product relationship with the mass, and X1 includes the rolling resistance coefficient, the longitudinal acceleration, the longitudinal speed, and the road gradient of the vehicle. Any one or more of the efficiency coefficients of the mechanical transmission system; Y1 is a component having no direct product relationship with mass, and Y1 includes the wind resistance of the vehicle. Both X1 and Y1 are system operating parameters of the vehicle; when the power unit that controls the vehicle is a motor, the source power parameter is the motor drive parameter.
如实施例28、实施例1所示,显而易见的,本发明所述车辆运动平衡计算中的源动力参数,所述计算中指该计算公式中,既可在计算公式等号中的左边,也可以在计算公式等号中的右边;也即既可为计算中的输入参数,也可以是计算中的输出参数,也即测算对象本身;同理,本文所有“计算中”,均可指计算的输入参数或计算的输出参数;显而易见的,本发明所述“计算中”,均指“车辆运动平衡计算公式中”;本发明所述参与计算,也指“参与车辆运动平衡计算公式中”也即“包含入车辆运动平衡计算公式中”也即“车辆运动平衡计算公式中包含某参数”;As shown in the embodiment 28 and the embodiment 1, it is obvious that the source dynamic parameter in the vehicle motion balance calculation of the present invention refers to the calculation formula, which may be on the left side of the calculation formula equal sign, or In the right side of the calculation formula equal sign; that is, it can be either the input parameter in the calculation or the output parameter in the calculation, that is, the measurement object itself; similarly, all the "calculations" in this paper can refer to the calculation. Input parameters or calculated output parameters; obviously, the "calculation" in the present invention refers to "the vehicle motion balance calculation formula"; the participation calculation according to the present invention also refers to "involved in the vehicle motion balance calculation formula" That is, "included into the vehicle motion balance calculation formula", that is, "the vehicle motion balance calculation formula contains a certain parameter";
通过本申请文件所记载的多种实现公式(如文件中实施例1到实施例33、公式13.1到公式13.6、实施例41等),显而易见可得知,本发明所述车辆运动平衡指车辆纵向动力平衡;车辆运动平衡原理实质为能量守恒原理和/或牛顿定律和/或车辆运行特征因素的结合;该能量守恒指车辆的动力系统输出的能量(或动力)与车辆的动力系统外部所消耗的能量(或动力)大小相等,和/或指车辆的动力系统吸收的能量(或动力)与车辆的动力系统外部所回馈的能量(或动力)大小相等;该牛顿定律指车辆纵向动力平衡;该车辆运行特征是指:车辆在动力系统控制下沿路面或轨道纵向运行;对于轮式车辆为车辆的车轮在沿路面(或轨道)滚动纵向运行,所以车辆在运行中自然存在滚动阻力(m2*g*f*cosθ);如果车辆与路面(或轨道)为非直接接触式运行(例如磁悬浮车辆等),滚阻系 数f接近零,此时可设(m2*g*f*cosθ)=0;路面(或轨道)自然存在坡度θ,所以车辆自然存在坡度阻力(m2*g*sinθ),当车辆水平运行时:θ=0,cosθ=1,sinθ=0,坡度阻力(m2*g*sinθ)=0;坡度θ自然影响滚动阻力(m2*g*f*cosθ)的大小;因为车辆通常为非真空运行,与空气摩擦所以产生风阻(也即空气阻力)fw,当接近零速运行时或速度低于预设值时,fw=0;车辆的纵向速度变化时自然存在变速阻力(m2*a),匀速时(m2*a)=0;此为车辆运行主要特征;本文中车辆运动平衡指车辆纵向动力平衡,即车辆在运行方向动力与相关阻力平衡;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;当然,相关阻力还可包括低于预设值的其他不重要的阻力(例如fb、L0*β等)。运行方向指移动方向;显而易见且毫无疑义的:本发明中任一处车辆运动平衡计算公式即车辆纵向动力学计算公式也即车辆纵向动力学方程,本发明中任一处车辆运动平衡计算即根据车辆纵向动力学计算公式进行计算也即根据车辆纵向动力学方程进行计算,本发明中车辆纵向动力学方程尤其指车辆纵向驱动动力学方程;Through various implementation formulas (such as Embodiment 1 to Embodiment 33, Equation 13.1 to Formula 13.6, Embodiment 41, etc. in the document), it is apparent that the vehicle motion balance of the present invention refers to the longitudinal direction of the vehicle. Dynamic balance; the principle of vehicle motion balance is essentially a combination of energy conservation principle and/or Newton's law and/or vehicle operating characteristic factors; the energy conservation refers to the energy (or power) output by the vehicle's power system and the external power consumption of the vehicle's power system. The energy (or power) is equal in magnitude, and/or the energy (or power) absorbed by the vehicle's powertrain is equal to the energy (or power) fed back outside the vehicle's powertrain; the Newton's law refers to the vehicle's longitudinal dynamic balance; The vehicle running characteristic means that the vehicle runs longitudinally along the road surface or the track under the control of the power system; for the wheeled vehicle, the wheel of the vehicle runs longitudinally along the road surface (or track), so the vehicle naturally has rolling resistance during operation (m2) *g*f*cosθ); if the vehicle is in direct contact with the road surface (or track) (eg magnetic suspension vehicle, etc.), the rolling system The number f is close to zero. At this time, it can be set (m2*g*f*cosθ)=0; the road surface (or track) naturally has a slope θ, so the vehicle naturally has slope resistance (m2*g*sinθ) when the vehicle is running horizontally. : θ = 0, cos θ = 1, sin θ = 0, slope resistance (m2 * g * sin θ) = 0; slope θ naturally affects the rolling resistance (m2 * g * f * cos θ); because the vehicle is usually non-vacuum operation Friction with air (such as air resistance) fw, when approaching zero speed or when the speed is lower than the preset value, fw = 0; there is naturally a shift resistance (m2*a) when the longitudinal speed of the vehicle changes. At constant speed (m2*a)=0; this is the main feature of vehicle operation; the vehicle motion balance refers to the longitudinal dynamic balance of the vehicle, that is, the balance between the dynamic direction and the related resistance of the vehicle in the running direction; the related resistance includes rolling resistance, slope resistance, and shifting Any one or any of a variety of resistance and windage; the formula for calculating the vehicle's motion balance is a formula describing the balance between the dynamic direction of the vehicle and the associated resistance in the running direction or a variant thereof; of course, the relevant resistance may also include other values below the preset value. Unimportant resistance (eg fb, L0*β, etc.)The running direction refers to the moving direction; it is obvious and unambiguous: the vehicle motion balance calculation formula at any place in the present invention is the vehicle longitudinal dynamics calculation formula, that is, the vehicle longitudinal dynamics equation, and the vehicle motion balance calculation at any place in the present invention is According to the longitudinal dynamics calculation formula of the vehicle, the calculation is based on the longitudinal dynamic equation of the vehicle. The longitudinal dynamic equation of the vehicle in the present invention refers especially to the longitudinal driving dynamics equation of the vehicle;
通过实施例1至实施例33中除实施例2和实施例15之外的所有实施例,显而易见的可得知:车轮沿路面(或轨道)滚动纵向运行的车辆(也即轮式车辆),典型的车辆运动平衡计算公式(例如:fq=fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw)中包含滚动阻力(m2*g*f*cosθ),滚动阻力(m2*g*f*cosθ)的计算参数中包含滚阻系数f,滚阻系数f为滚动阻力(m2*g*f*cosθ)的核心因素之一,不考虑滚阻系数f的滚动阻力的计算方案是有重大缺陷、或无法实现的。只有在与轮式车辆的运行特征有重大区别的、车辆与路面(或轨道)非机械接触式运行的车辆(例如磁悬浮车辆),滚阻系数f接近零,也导致滚动阻力(m2*g*f*cosθ)接近零。履带式车辆(例如坦克等)也属于轮式车辆中一种特殊车辆,可将履带视为一个整体式的刚性的车轮。By all the embodiments except the embodiment 2 and the embodiment 15 in the embodiment 1 to the embodiment 33, it is obvious that the wheel is rolling along the road surface (or track) in a longitudinally running vehicle (that is, a wheeled vehicle), A typical vehicle motion balance calculation formula (for example: fq=fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw) contains rolling resistance (m2*g*f*cosθ), rolling resistance (m2) The calculation parameter of *g*f*cosθ) includes the rolling resistance coefficient f, and the rolling resistance coefficient f is one of the core factors of the rolling resistance (m2*g*f*cosθ), and the calculation of the rolling resistance of the rolling resistance coefficient f is not considered. The program has major flaws or is impossible to achieve. Only in vehicles with a non-mechanical contact between the vehicle and the road surface (or track) (such as a magnetic levitation vehicle) that differs significantly from the operational characteristics of the wheeled vehicle, the rolling resistance factor f is close to zero, which also results in rolling resistance (m2*g*). f*cos θ) is close to zero. Tracked vehicles (such as tanks) are also a special type of wheeled vehicle that can be considered as a one-piece rigid wheel.
车轮沿路面(或轨道)滚动纵向运行的车辆,如实施例2和/或实施例15所示(也即两次变速差值式车辆运动平衡计算公式)所示,在基于两个不同时间点所获取的参数的差值的车辆运动平衡计算公式才有可能消除滚动阻力(m2*g*f*cosθ)的影响,且该差值式车辆运动平衡计算公式的核心原理仍然基于典型的车辆运动平衡计算公式(例如:fq=m2*(g*f*cosθ+g*sinθ+a)+fw),且该差值式车辆运动平衡计算公式的运行受限于诸多前提条件;假设time1时所获取的滚阻系数、加速度、路面坡度、风阻分别为f1、a1、、θ1、fw1;不同于time1时间点的time2时所获取滚阻系数、加速度、路面坡度、风阻分别为f2、a2、θ2、fw2:则两个不同时间点的差值式车辆运动平衡计算公式为:((fq2-fq1)=(m2*(g*f2*cosθ2+g*sinθ2+a2)+fw2)-(m2*(g*f1*cosθ1+g*sinθ1+a1)+fw1));当两个不同时间点的滚阻系数f、路面坡度θ值、风阻fw、车辆总质量m2均接近,且两个不同时间点所获取的加速度a2和a1不等时,才可能得到差值式车辆运动平衡计算公式(m2=ΔF/Δa);当两个不同时间点的滚阻系数f、路面坡度θ值、加速度a、车辆总质量m2均接近,才可能得到差值式车辆运动平衡计算公式((fq2-fq1)=(fw2-fw1));本发明 中,基于两个不同时间点所获取的参数的差值的车辆运动平衡计算公式,为基础的典型的车辆运动平衡计算公式(例如:fq=m2*(g*f*cosθ+g*sinθ+a)+fw)的一种特殊变形。The vehicle is rolling longitudinally along the road (or track), as shown in Embodiment 2 and/or Embodiment 15 (ie, the two-speed differential vehicle motion balance calculation formula), based on two different time points. The vehicle motion balance calculation formula of the difference of the obtained parameters is likely to eliminate the influence of rolling resistance (m2*g*f*cosθ), and the core principle of the differential vehicle motion balance calculation formula is still based on typical vehicle motion. Balance calculation formula (for example: fq=m2*(g*f*cosθ+g*sinθ+a)+fw), and the operation of the differential vehicle motion balance calculation formula is limited by many preconditions; The obtained rolling resistance coefficient, acceleration, road gradient and wind resistance are f1, a1, θ1, and fw1, respectively; the time resistance coefficient, acceleration, road gradient, and wind resistance obtained at time2 different from time1 are f2, a2, and θ2, respectively. , fw2: The difference formula of the differential vehicle motion balance at two different time points is: ((fq2-fq1)=(m2*(g*f2*cosθ2+g*sinθ2+a2)+fw2)-(m2* (g*f1*cosθ1+g*sinθ1+a1)+fw1)); when two different time points are the rolling resistance factor f, the road surface slope θ value, When the resistance fw and the total mass m2 of the vehicle are close, and the accelerations a2 and a1 obtained at two different time points are not equal, it is possible to obtain a differential vehicle motion balance calculation formula (m2=ΔF/Δa); when two different The rolling resistance coefficient f at the time point, the road surface gradient θ value, the acceleration a, and the total mass m2 of the vehicle are all close to each other, and it is possible to obtain a differential vehicle motion balance calculation formula ((fq2-fq1)=(fw2-fw1)); The vehicle motion balance calculation formula based on the difference of the parameters obtained at two different time points is based on a typical vehicle motion balance calculation formula (for example: fq=m2*(g*f*cosθ+g*sinθ+ a special variant of a) +fw).
所述基于车辆运动平衡计算,通常指根据车辆质量(通常为车辆总质量)、源动力参数、系统运行参数中任意两种参数去计算另一种参数,当然参与该车辆运动平衡计算的参数还可能进一步包括其他数据;也即车辆运动平衡计算原理,通常指根据至少包括车辆质量(通常为车辆总质量)、源动力参数、系统运行参数中的任意两种参数的数据去计算另一种参数;如实施例9、实施例10、实施例17中还包括动力装置运行工况等数据,当动力装置运行工况为动力装置驱动状态和当动力装置运行工况为动力装置制动状态采用不同的计算方式;如后述公式13.2中,参与该车辆运动平衡计算的参数还包括制动力fb;The calculation based on the vehicle motion balance generally refers to calculating another parameter according to any two parameters of the vehicle mass (usually the total mass of the vehicle), the source dynamic parameter, and the system operating parameter, and of course, the parameters participating in the calculation of the vehicle motion balance are also It may further include other data; that is, the principle of vehicle motion balance calculation, generally refers to calculating another parameter according to data including at least two of the vehicle mass (usually the total mass of the vehicle), the source dynamic parameter, and the system operating parameter. As in the embodiment 9, the embodiment 10 and the embodiment 17 further include data such as the operating conditions of the power unit, when the operating condition of the power unit is the driving state of the power unit and when the operating condition of the power unit is the braking state of the power unit, the driving state is different. The calculation method; in the following formula 13.2, the parameters participating in the calculation of the vehicle's motion balance also include the braking force fb;
当测算对象为车辆质量(通常为车辆总质量)时,所述联合运算值可根据源动力参数和系统运行参数计算所得,当然参与该计算所需求的参数还可能进一步包括其他数据;也即当测算对象为车辆质量时,所述联合运算值可根据至少包括源动力参数和系统运行参数在内的数据计算所得。When the measured object is the vehicle mass (usually the total mass of the vehicle), the joint operation value may be calculated according to the source dynamic parameter and the system operating parameter, and of course, the parameter required to participate in the calculation may further include other data; that is, when When the measured object is the vehicle mass, the joint operation value may be calculated according to data including at least the source power parameter and the system operating parameter.
当测算对象为源动力参数时,所述联合运算值可根据车辆质量(通常为车辆总质量)和系统运行参数计算所得,当然参与该计算所需求的参数还可能进一步包括其他数据;也即当测算对象为源动力参数时,所述联合运算值可根据至少包括车辆质量(通常为车辆总质量)和系统运行参数在内的数据计算所得。When the measured object is a source dynamic parameter, the joint operation value may be calculated according to vehicle quality (usually the total mass of the vehicle) and system operating parameters, and of course, the parameters required to participate in the calculation may further include other data; that is, when When the measured object is a source dynamic parameter, the joint operational value may be calculated based on data including at least vehicle mass (typically total vehicle mass) and system operating parameters.
当测算对象为系统运行参数时,所述联合运算值可根据车辆质量(通常为车辆总质量)和源动力参数计算所得,当然参与该计算所需求的参数还可能进一步包括其他数据,如除测算对象之外的其他的系统运行参数;也即当测算对象为系统运行参数时,所述联合运算值可根据至少包括车辆质量(通常为车辆总质量)和源动力参数在内的数据计算所得。When the measured object is a system operating parameter, the joint operation value may be calculated according to vehicle quality (usually the total mass of the vehicle) and the source dynamic parameter, and of course, the parameters required to participate in the calculation may further include other data, such as Other system operating parameters than the object; that is, when the measured object is a system operating parameter, the combined operational value may be calculated based on data including at least vehicle mass (typically total vehicle mass) and source dynamic parameters.
当然,采用车辆运动平衡计算公式变形所得表格,如果在车辆总质量m2固定情况下通过车辆运动平衡计算公式查表一一对应得出动力与系统运行参数(尤其为其中的机械运行参数)的对应关系,或在动力为固定值时根据车辆运动平衡计算公式查表一一对应得出车辆总质量与机械运行参数的对应关系,或在系统运行参数为固定值时根据车辆运动平衡计算公式查表一一对应得出车辆总质量与动力的对应关系,等等,基于车辆运动平衡计算公式简化或忽略某些参数进行计算,也为车辆运动平衡计算公式的一种变形,也在本发明构思范围之内。Of course, the vehicle deformation calculation formula is used to obtain the corresponding table of the vehicle motion balance calculation formula. If the total vehicle mass m2 is fixed, the correspondence between the power and the system operating parameters (especially the mechanical operating parameters) is obtained by the vehicle motion balance calculation formula. Relationship, or when the power is a fixed value, according to the vehicle motion balance calculation formula lookup table, the corresponding relationship between the total vehicle mass and the mechanical operation parameter is obtained, or when the system operation parameter is a fixed value, the vehicle movement balance calculation formula is used to check the table. One-to-one correspondence is derived from the correspondence between the total mass of the vehicle and the power, etc., based on the calculation formula of the vehicle motion balance, simplifying or ignoring certain parameters for calculation, and also a variant of the vehicle motion balance calculation formula, also within the scope of the inventive concept within.
联合运算值为基于车辆运动平衡计算公式计算所得的结果,基于车辆运动平衡计算公式计算得到测算对象的值,该值也即联合运算值。The joint operation value is a result calculated based on the vehicle motion balance calculation formula, and the value of the measurement object is calculated based on the vehicle motion balance calculation formula, and the value is also a joint operation value.
本发明要解决的技术问题之一是提供一种车辆运行参数的测算方法(#1),其测算结果可用于反映、分析车辆的待监控的动力传动部件的磨损和/或安全的状况、和/或:车轮形变(失圆度)和/ 或车轮磨损的状况;和/或:综合传动比的变化;和/或:驱动轮半径的变化。One of the technical problems to be solved by the present invention is to provide a method for calculating vehicle operating parameters (#1), which can be used to reflect and analyze the wear and/or safety condition of a power transmission component to be monitored of a vehicle, and / or: wheel deformation (out of roundness) and / Or a condition in which the wheel is worn; and/or: a change in the overall gear ratio; and/or: a change in the radius of the drive wheel.
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供一种车辆运行参数的测算方法(#1):The invention provides a method for calculating vehicle operating parameters (#1):
S1、以车辆运行参数中的任意一种为测算对象,预设计算该测算对象的车辆运动平衡计算公式;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种(之合力);或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;和也即合力;S1: Calculating a vehicle motion balance calculation formula of the measurement object by using any one of the vehicle operating parameters as a calculation object; the vehicle motion balance calculation formula is a formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or a variant thereof The relevant resistance includes any one or any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; or: the related resistance includes one of rolling resistance, slope resistance, shift resistance, and wind resistance. Or include any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; and that is, resultant force;
S2、获取输入参数的值,该输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;根据该所获取的输入参数的值和该车辆运动平衡计算公式计算该测算对象的值。S2. Obtain a value of an input parameter, where the input parameter is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula. And calculating a value of the estimated object according to the obtained value of the input parameter and the vehicle motion balance calculation formula.
测算方法(#1)为车辆运动平衡计算的标准过程,也可简称为车辆运动平衡计算;The calculation method (#1) is a standard process for vehicle motion balance calculation, and may also be referred to as vehicle motion balance calculation for short;
该车辆运动平衡计算公式及计算方法及参数的设置方法可参考本文中任一位置的内容进行;The vehicle motion balance calculation formula and the calculation method and the parameter setting method can be referred to the content of any position in this document;
本测算方法(#1)中,车辆运动平衡计算公式既可为描述车辆在运行方向动力与相关阻力平衡的典型公式(例如:fq=Fx=m2*(g*f*cosθ+g*sinθ+a)+fw),也可为变形的基于两个不同时间点所获取的参数的差值的车辆运动平衡计算公式,也可为典型公式的其他的变形公式;In this calculation method (#1), the vehicle motion balance calculation formula can be a typical formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction (for example: fq=Fx=m2*(g*f*cosθ+g*sinθ+ a) +fw), which can also be a vehicle motion balance calculation formula based on the difference of the parameters obtained at two different time points, or other deformation formula of the typical formula;
本测算方法(#1)中,所述步骤S1中,描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式包括:动力Fx、滚动阻力fμ、坡度阻力fθ、变速阻力fa、风阻fw中至少一种的变形。In the calculation method (#1), in the step S1, the formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or the deformation thereof includes: the power Fx, the rolling resistance fμ, the gradient resistance f θ , the shift resistance fa, Deformation of at least one of the wind resistances fw.
本测算方法(#1)中,动力Fx的变形方式包括:F-fb-L0*β,Fx=F-F0,F表示电机或者发动机作用于车辆的力;In the calculation method (#1), the deformation mode of the power Fx includes: F-fb-L0*β, Fx=F-F0, and F represents the force of the motor or the engine acting on the vehicle;
F的变形式包括:(Kem*k12*cosφ*Uo*Io)/Vx、(Km*Pr1)/Vx、(Km*fm1*Kf1)/Vx、((Ke*Km)*(P2o/Vx)、((Ke*Km)*(Te*im/R)、Kem*k12*cosφ*Uo*Io/Vx、(Kem*k13*Ui*Ii)/Vx、(Kem*k13*Ub1*Ib1)/Vx、(Kem*Pm)/Vx;The deformation formula of F includes: (Kem*k12*cosφ*Uo*Io)/Vx, (Km*Pr1)/Vx, (Km*fm1*Kf1)/Vx, ((Ke*Km)*(P2o/Vx) , ((Ke*Km)*(Te*im/R), Kem*k12*cosφ*Uo*Io/Vx, (Kem*k13*Ui*Ii)/Vx, (Kem*k13*Ub1*Ib1)/ Vx, (Kem*Pm)/Vx;
F0的变形式包括:fb+L0*β,其中,F0表示电机或者发动机内总阻力,fb表示制动力分量,L0表示内部综合旋转刚体转动惯量,β表示内部综合旋转刚体的角加速度,当β=0时,表示内部综合旋转刚体的角加速度为零或者内部综合旋转刚体的角加速度;The deformation of F0 includes: fb+L0*β, where F0 represents the total resistance in the motor or engine, fb represents the braking force component, L0 represents the internal integrated rotating body moment of inertia, and β represents the angular acceleration of the internal integrated rotating rigid body, when β =0, indicating that the angular acceleration of the internal integrated rotating rigid body is zero or the angular acceleration of the internal integrated rotating rigid body;
其中,Kem表示机电传动综合的效率系数,k12为预设常数,φ功率因素,Uo电机电压,Io为电机电流,Km表示机械传动系统的效率系数,Pr1表示燃料发动机的驱动功率,Vx表示车辆的纵向速度,fm1表示发动机内的燃料消耗率,Kf1表示能量转化系数,Ke表示电机的效率系数,P2o表示电机输出电气功率,Te表示电磁转矩,Pm表示电机的电气功率,im表示综合传动比,R表示驱动轮半径,k13表示电机驱动装置到电机的效率系数,Ui表示电机驱动装置的输入电压,Ii表示电机驱动装置的输入电流,Ub1表示电源装置的输出电压,Ib1表示电源装置的输出电压; Among them, Kem represents the comprehensive efficiency coefficient of electromechanical transmission, k12 is the preset constant, φ power factor, Uo motor voltage, Io is the motor current, Km is the efficiency coefficient of the mechanical transmission system, Pr1 is the driving power of the fuel engine, and Vx is the vehicle. The longitudinal velocity, fm1 represents the fuel consumption rate in the engine, Kf1 represents the energy conversion coefficient, Ke represents the efficiency coefficient of the motor, P2o represents the electrical output power of the motor, Te represents the electromagnetic torque, Pm represents the electrical power of the motor, and im represents the integrated transmission. Ratio, R represents the drive wheel radius, k13 represents the efficiency coefficient of the motor drive to the motor, Ui represents the input voltage of the motor drive, Ii represents the input current of the motor drive, Ub1 represents the output voltage of the power supply, and Ib1 represents the power supply The output voltage;
本测算方法(#1)中,滚动阻力fμ的变形方式包括:fμ=m2*g*f*cosθ,m2表示车辆总质量,g表示重力加速度,f表示滚阻系数,θ表示路面坡度;当fμ=0时,表示滚阻系数f为零或者忽略滚阻系数f。In the calculation method (#1), the deformation mode of the rolling resistance fμ includes: fμ=m2*g*f*cosθ, m2 represents the total mass of the vehicle, g represents the acceleration of gravity, f represents the rolling resistance coefficient, and θ represents the gradient of the road surface; When fμ=0, it means that the rolling resistance coefficient f is zero or the rolling resistance coefficient f is ignored.
本测算方法(#1)中,车辆总质量m2的变形方式包括:m1+m0、m1+m0+mf2-mf1以及m1+m0+mf0,m1为运载物品质量,m0表示空载车体质量,mf0表示剩余燃料质量,mf1已消耗燃料质量,mf2表示历史记录点的燃料质量;In the calculation method (#1), the deformation mode of the total mass m2 of the vehicle includes: m1+m0, m1+m0+mf2-mf1, and m1+m0+mf0, where m1 is the mass of the carried item, and m0 represents the mass of the empty body. Mf0 represents the remaining fuel mass, mf1 has consumed fuel mass, and mf2 represents the fuel quality at the historical point;
本测算方法(#1)中,坡度阻力fθ的变形方式包括:fθ=m2*g*sinθ,当fθ=0时,表示路面坡度θ为零或者忽略路面坡度θ。In the calculation method (#1), the deformation mode of the gradient resistance f θ includes: f θ = m2 * g * sin θ, and when f θ =0, it indicates that the road surface gradient θ is zero or the road surface gradient θ is ignored.
本测算方法(#1)中,变速阻力fa的变形方式包括:fa=m2*a,当fa=0时,表示加速度a为零或者忽略加速度a。In the present measurement method (#1), the deformation mode of the shift resistance fa includes: fa=m2*a, and when fa=0, it indicates that the acceleration a is zero or the acceleration a is ignored.
本测算方法(#1)中,风阻fw的变形方式包括:fw=(1/2)*Cd*(p0*A0*(Vx)2),其中,Cd表示车辆的风阻系数,p0表示空气密度,A0表示车辆的迎风面积,Vx表示纵向速度;当fw=0时,表示fw为零或者忽略fw。In the calculation method (#1), the deformation mode of the wind resistance fw includes: fw=(1/2)*Cd*(p0*A0*(Vx) 2 ), where Cd represents the drag coefficient of the vehicle, and p0 represents the air density. A0 represents the windward area of the vehicle, Vx represents the longitudinal speed; when fw=0, it indicates that fw is zero or fw is ignored.
本测算方法(#1)中,所述步骤S1中,描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式还包括:等号的两边同时相对于同一变量进行积分变形;In the calculation method (#1), in the step S1, the formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or the deformation thereof further includes: the two sides of the equal sign are simultaneously integrated and deformed with respect to the same variable;
积分变形的方式包括:功率对于时间的积分为能量、力对位移的积分为能量、速度对于时间的积分为位移、加速度对于时间的积分为速度、力对时间的积分为冲量。The integral deformation method includes: the integral of power for time is energy, the integral of force to displacement is energy, the integral of speed with respect to time is displacement, the integral of acceleration for time is speed, and the integral of force versus time is impulse.
输入参数的值的基础设置方案:显而易见的,本发明的任一方案中,所获取的车辆运动平衡计算公式中输入参数的值均为合理值(也可称为合格值或可接受的值);不同的输入参数有不同的合理值;参数(包括输入参数)的合理值,指该参数(包括输入参数)的能实现某一具有实用价值的用途或表示该参数(包括输入参数)自然属性的值;例如本发明所述的动力传递状况识别、车辆动力传递异常进行监控、反映、分析车辆的待监控的动力传动部件的运行状况(磨损和/或安全的状况)、分析车轮形变(失圆度)和/或车轮磨损的状况、与车辆运行安全相关数据进行监视、与车辆运行安全相关数据进行处理中任意一种或多种用途,均为某一具有实用价值的用途;参数当前的实际值、或第三范围中的值、或第四范围中的值为表示该参数(包括输入参数)自然属性的值;Basic setting scheme of the value of the input parameter: Obviously, in any of the solutions of the present invention, the value of the input parameter in the obtained vehicle motion balance calculation formula is a reasonable value (also referred to as a qualified value or an acceptable value) Different input parameters have different reasonable values; reasonable values of parameters (including input parameters) refer to the use of the parameter (including input parameters) to achieve a useful value or to represent the natural attributes of the parameter (including input parameters) For example, the power transmission condition identification, the vehicle power transmission abnormality, the monitoring, the reflection, the analysis of the operating condition (wear and/or safety condition) of the power transmission component to be monitored of the vehicle, and the analysis of the wheel deformation (loss) Roundness) and/or condition of wheel wear, monitoring of data related to vehicle operation safety, and processing of any data related to vehicle operation safety are all useful applications; parameters are current The actual value, or the value in the third range, or the value in the fourth range is a value representing the natural attribute of the parameter (including the input parameter);
例如,输入参数中所包括的车辆总质量的值为基于车辆总质量的当前的实际值或预设的实际值所设定,该当前的实际值或预设的实际值均为输入参数中所包括的车辆总质量的合理值;参数的预设的实际值的含义为:该值为与在预设的时间点(非当前的时间点)上的该参数的实际值接近的值;For example, the value of the total mass of the vehicle included in the input parameter is set based on the current actual value of the total mass of the vehicle or a preset actual value, and the current actual value or the preset actual value is in the input parameter. a reasonable value of the total mass of the vehicle included; the meaning of the preset actual value of the parameter is: the value is a value close to the actual value of the parameter at a preset time point (not the current time point);
本发明中预设的实际值的含义也可理解为:在预设的时间点(非当前的时间点)上所获取的该参数的实际值;本发明中预设的实际值的含义也可理解为:表示该参数在预设的时间点(非当前的时间点)的实际值;车辆总质量预设的实际值的含义为:该值为与在预设的时间点上(非当前的时间点)的车辆总质量的实际值接近的值;也可理解为:在预设的时间点上(非当前的时间点)所获 取的车辆总质量的实际值;也可理解为:表示车辆总质量在预设的时间点(非当前的时间点)的实际值;The meaning of the actual value preset in the present invention can also be understood as: the actual value of the parameter acquired at a preset time point (not the current time point); the meaning of the preset actual value in the present invention can also be It is understood as: the actual value of the parameter at the preset time point (not the current time point); the actual value of the vehicle total mass preset means: the value is at the preset time point (non-current) The actual value of the total mass of the vehicle at the time point is close to the value; it can also be understood as: obtained at a preset time point (not the current time point) The actual value of the total mass of the vehicle taken; it can also be understood as: the actual value indicating the total mass of the vehicle at a preset time point (not the current time point);
例如,输入参数中所包括的除车辆总质量之外的第一类型参数中的参数的值为基于该参数的当前的实际值所设定,当前的实际值为该第一类型的输入参数(例如,源动力参数、速度、加速度等)的合理值;本发明中,第一类型参数指需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一种或多种类型参数;还有一种可能性,如果该参数的历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值,则该历史记录值也为该第一类型的输入参数(例如,源动力参数、速度、加速度等)的合理值;For example, the value of the parameter in the first type parameter other than the total mass of the vehicle included in the input parameter is set based on the current actual value of the parameter, and the current actual value is the input parameter of the first type ( For example, a reasonable value of source dynamic parameters, speed, acceleration, etc.; in the present invention, the first type of parameter refers to a parameter to be measured and/or a measurable parameter and/or a source dynamic parameter and/or a mechanical operating parameter and/or Any one or more of the types of quality-changing item quality; there is also a possibility that if the historical value of the parameter is different, the difference between the vehicle operating condition and the current vehicle operating condition is lower than a preset threshold And the historical record value is also a reasonable value of the first type of input parameter (eg, source dynamic parameter, speed, acceleration, etc.);
例如,输入参数中所包括的除车辆总质量之外的第二类型参数中的参数的值为基于该参数当前的实际值或该参数的安全范围中的值或所设定;通常来说该参数的安全范围中的值为预设方式所设定;该参数当前的实际值或该参数的预设的安全范围中的值为该第二类型的输入参数的合理值;本发明中,第二类型参数指不可测参数和/或可预设参数和/或系统固有参数中任一种或多种参数;例如,效率系数、滚阻系数、综合传动比、驱动轮半径、重力加速度通常为第二类型参数中的参数;优选的,该预设的安全范围中的值为预设的标定值;For example, the value of the parameter in the second type parameter other than the total mass of the vehicle included in the input parameter is based on the current actual value of the parameter or the value in the safety range of the parameter or is set; generally speaking, The value in the security range of the parameter is set by the preset mode; the current actual value of the parameter or the value in the preset security range of the parameter is a reasonable value of the input parameter of the second type; in the present invention, The second type parameter refers to any one or more of the unmeasurable parameters and/or the preset parameters and/or the system inherent parameters; for example, the efficiency coefficient, the rolling resistance coefficient, the integrated gear ratio, the driving wheel radius, and the gravitational acceleration are usually a parameter in the second type parameter; preferably, the value in the preset safety range is a preset calibration value;
综合而言,输入参数中所包括的的路面坡度θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信息计算所得或传感器测量数据获取;In general, the values of any one or more of the road gradient θ, the rolling resistance coefficient f, and the rolling resistance coefficient component fr included in the input parameter may be calculated based on the position information of the road or Sensor measurement data acquisition;
本发明中,将不可测参数和/或可预设参数和/或系统固有参数中,表示动力系统和/或机械传动系统的属性的参数,称为动力或传动系统中的与安全紧密相关的参数;例如,效率系数、滚阻系数、综合传动比、驱动轮半径均为动力或传动系统中的与安全紧密相关的参数;综合传动比的异常通常表示车辆的机械传动系统的严重故障,驱动轮半径的异常通常发生在车轮爆胎、半径缩小等严重安全隐患时;本发明中,动力或传动系统中的与安全紧密相关的参数属于第二类型参数。In the present invention, among the unmeasured parameters and/or predefinable parameters and/or system inherent parameters, parameters indicating the properties of the power system and/or the mechanical transmission system are referred to as closely related to safety in the power or transmission system. Parameters; for example, efficiency factor, rolling resistance coefficient, integrated gear ratio, drive wheel radius are all parameters related to safety in power or transmission system; abnormalities in integrated transmission ratio usually indicate severe failure of the mechanical transmission system of the vehicle, driving The abnormality of the wheel radius usually occurs when there are serious safety hazards such as tire puncture and radius reduction; in the present invention, the parameters closely related to safety in the power or transmission system belong to the second type parameter.
测算对象类型或输入参数的值的设置方案2:本测算方法(#1)还包括方案A、B、C中任一方案:Setting of the measurement object type or the value of the input parameter Scheme 2: The calculation method (#1) also includes any one of the schemes A, B, and C:
A、测算对象为动力或传动系统中的与安全紧密相关的参数或包含该参数的参数;输入参数的值均为根据输入参数的合理值所设定;例如:测算对象为效率系数或者包含效率系数的参数;例如,实施例9中,以车辆的机电传动综合的效率系数Kem为测算对象;也可以以(Kem(Te*im/R1))为测算对象,该测算对象(Kem(Te*im/R1))包含效率系数Kem;例如:测算对象为滚阻系数或者包含滚阻系数的参数;例如,实施例10中,以车辆的滚阻系数μ1为测算对象;也可以以(g*μ1*cosθ)为测算对象,该测算对象(g*μ1*cosθ)包含滚阻系数μ1;A. The measurement object is a parameter closely related to safety in the power or transmission system or a parameter containing the parameter; the value of the input parameter is set according to a reasonable value of the input parameter; for example, the measurement object is an efficiency coefficient or includes efficiency The parameter of the coefficient; for example, in the embodiment 9, the efficiency coefficient Kem of the electromechanical transmission of the vehicle is measured; or (Kem(Te*im/R1)) is used as the measurement object, and the measurement object (Kem(Te*) Im/R1)) includes an efficiency coefficient Kem; for example, the measurement object is a rolling resistance coefficient or a parameter including a rolling resistance coefficient; for example, in the embodiment 10, the rolling resistance coefficient μ1 of the vehicle is used as a measurement target; 11*cosθ) is a measurement object, and the measurement object (g*μ1*cosθ) includes a rolling resistance coefficient μ1;
B、输入参数中所包括的车辆总质量的值为基于车辆总质量的预设的实际值所设定,而非基于车辆总质量的当前的实际值所设定;输入参数中除车辆总质量之外的其他参数的值为根据各参数的合理值所设定; B. The value of the total mass of the vehicle included in the input parameters is set based on the preset actual value of the total mass of the vehicle, and is not set based on the current actual value of the total mass of the vehicle; The values of other parameters other than those set are based on reasonable values of each parameter;
C、输入参数中所包括的动力或传动系统中的与安全紧密相关的参数中至少一种为基于预设值所设定,而非基于该参数当前的实际值所设定,该预设值为预设的安全范围中的值;输入参数中除该动力或传动系统中的与安全紧密相关的参数之外的其他参数的值为根据各参数的合理值所设定。C. At least one of the power included in the input parameter or the safety-related parameter in the transmission system is set based on the preset value, and is not set based on the current actual value of the parameter, the preset value The value in the preset safety range; the values of the parameters other than the safety-related parameters in the power or transmission system are set according to the reasonable values of the parameters.
测算方法(#1)中,车辆总质量的实际值在车辆运行中不便测量;可以由操控人员根据现场情况,人工输入方式预设该车辆总质量的实际值;当然,此举需人工进行,不便利,也不利于提高计算精度、安全监控;例如,输入参数中如包括车辆总质量,假设车辆自重1500KG限载500KG,如果车辆的车辆总质量的值设为2000KG和1600KG,在其他输入参数条件不变的前提下,车辆运动平衡计算所得结果可能相差25%,将降低车辆运动平衡计算精度、和对于安全监控意义;In the calculation method (#1), the actual value of the total mass of the vehicle is inconvenient to measure during the operation of the vehicle; the actual value of the total mass of the vehicle may be preset by the operator according to the situation on the site, and the manual input method is adopted; Inconvenient, it is not conducive to improve calculation accuracy and safety monitoring; for example, if the input parameters include the total mass of the vehicle, assume that the vehicle's own weight is 1500KG and the load is limited to 500KG. If the vehicle's total mass value is set to 2000KG and 1600KG, in other input parameters. Under the premise of constant conditions, the results of vehicle motion balance calculation may differ by 25%, which will reduce the accuracy of vehicle motion balance calculation and the significance of safety monitoring;
设置方案2的优选方案1:优选的,输入参数中所包括的车辆总质量的值为基于在先进行的车辆运动平衡计算获取;也即在进行该测算方法(#1)之前,先以车辆总质量为测算对象进行车辆运动平衡计算(该计算为在先计算)出车辆总质量的值,该值通常为该在先计算时的实际值,再将该实际值用于测算方法(#1)中S2步骤的车辆运动平衡计算; Preferred Embodiment 1 of Setting Scheme 2: Preferably, the value of the total mass of the vehicle included in the input parameter is obtained based on a previously calculated vehicle motion balance calculation; that is, before the measurement method (#1) is performed, the vehicle is first used The total mass is the calculated value of the vehicle motion balance calculation (this calculation is the previous calculation), and the value is usually the actual value of the previous calculation, and the actual value is used for the calculation method (#1) ) the vehicle motion balance calculation in step S2;
设置方案2的优选方案2:进一步的,无论A、B、C方案中,当输入参数中的第二类型参数中参数为基于预设的安全范围中的值设定时,该安全范围中的值为标定值;这样利于提高计算精度、监控精度;因为安全范围为极限范围,上下偏差比较大;Setting 2 of the preferred scheme 2: Further, in the A, B, and C schemes, when the parameter in the second type parameter in the input parameter is set based on the value in the preset safety range, the safety range is The value is the calibration value; this is beneficial to improve the calculation accuracy and monitoring accuracy; because the safety range is the limit range, the upper and lower deviations are relatively large;
设置方案2的优选方案3:无论A、B、C方案中,输入参数中除车辆总质量之外的第一类型参数中至少一个参数为基于实测值设定,例如源动力参数、速度、加速度等;优选的,该至少一个为全部。A preferred scheme 3 of setting scheme 2: in any of the A, B, and C schemes, at least one of the first type of parameters other than the total mass of the input parameters is set based on the measured value, such as source dynamic parameters, speed, and acceleration. And so on; preferably, the at least one is all.
设置方案2的优选方案4:动力或传动系统中的与安全紧密相关的参数优选为效率系数和/或滚阻系数;效率系数可用于反映、分析车辆的待监控的动力传动部件的运行状况,该运行状况尤其指磨损和/或安全的状况;滚阻系数f(尤其是与车辆相关的滚阻系数分量fc),可用于反映、分析车轮形变(失圆度)和/或车轮磨损的状况;相比较于综合传动比和/或驱动轮半径,该效率系数和/或滚阻系数具有更为重要的安全意义。The preferred solution 4 of setting scheme 2: the parameter closely related to safety in the power or transmission system is preferably an efficiency coefficient and/or a rolling resistance coefficient; the efficiency coefficient can be used to reflect and analyze the running condition of the power transmission component of the vehicle to be monitored, This operating condition refers in particular to wear and/or safety conditions; the rolling resistance factor f (especially the rolling factor component fc associated with the vehicle) can be used to reflect and analyze wheel deformation (out of roundness) and/or wheel wear conditions. The efficiency factor and/or the rolling factor have a more important safety significance than the overall gear ratio and/or the drive wheel radius.
设定输入参数中以实测取值的参数(或及其个数),这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Set the parameters (or their number) of the measured parameters in the input parameters. These parameters are set based on the measured values; other parameters can be set by the preset values; the more the measured parameters, the higher the accuracy will naturally be, the monitoring The performance is good; the measured parameters are less and the cost is lower; the user and the manufacturer can be customized according to their different situations.
进一步的,测算方法(#1)还可包括下述扩展方案1:在车内电子设备和/或便携式个人消费电子产品的人机界面上输出计算所得的测算对象的值;进一步的,扩展方案1还可包括下述方案:获取所述测算对象的相关数据,在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的相关数据;Further, the measuring method (#1) may further include the following expansion scheme 1: outputting the calculated value of the measured object on the human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product; further, the expansion scheme 1 may further include: obtaining relevant data of the measurement object, and outputting relevant data of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product;
进一步的,测算方法(#1)还可包括下述扩展方案2:将计算所得的测算对象的值输出和/或保存;进一步的,扩展方案2还可包括下述方案:获取所述测算对象的相关数据,将该测算对象的相 关数据输出和/或保存;Further, the measurement method (#1) may further include the following expansion scheme 2: outputting and/or saving the calculated value of the measurement object; further, the expansion scheme 2 may further include the following scheme: acquiring the measurement object Relevant data, the phase of the measured object Off data output and / or save;
测算方法(#1)中,特别的,如果输入参数中所既不包括滚阻系数也不包括效率系数;则该次车辆运动平衡计算的结果将很难反映待监控的动力传动部件的磨损和/或安全的状况、车轮形变(失圆度)和/或车轮磨损的状况;In the calculation method (#1), in particular, if the input parameter does not include the rolling resistance coefficient or the efficiency coefficient; the result of the calculation of the vehicle motion balance will be difficult to reflect the wear of the power transmission component to be monitored and / or safety conditions, wheel deformation (out of roundness) and / or wheel wear conditions;
测算方法(#1)的实施示例1:Example 1 of the calculation method (#1):
S1、确立效率系数KeKm为测算对象;基于本文中公式A3-4-4(m2=(KeKm(Te2-Te1)*im/R1)/(a2-a1))的变形,得到新的车辆运动平衡计算公式:(KeKm=m2(a2-a1)R1/((Te2-Te1)*im));该公式为A3-5;S1, the establishment of the efficiency coefficient KeKm is the object of measurement; based on the deformation of the formula A3-4-4 (m2=(KeKm(Te2-Te1)*im/R1)/(a2-a1)), a new vehicle motion balance is obtained. Calculated by: (KeKm = m2(a2-a1)R1/((Te2-Te1)*im)); the formula is A3-5;
S2、获取各输入参数的合理值:例如获取其中需测量参数的值(获取time2时的输入参数(Te2、a2)的实测值;获取time1时的输入参数(Te1、a1)的实测值);获取可预设参数(R1、im)的预设的标准值;获取车辆总质量m2的实际值;根据该所获取的输入参数的值和该车辆运动平衡计算公式(A3-5)计算该测算对象的值;该计算所得的值可视为time2时的效率系数(KeKm)的实际值;S2: obtaining a reasonable value of each input parameter: for example, obtaining a value of the parameter to be measured (the measured value of the input parameter (Te2, a2) when time2 is acquired; and the measured value of the input parameter (Te1, a1) when time1 is acquired); Obtaining a preset standard value of the preset parameter (R1, im); obtaining an actual value of the total mass m2 of the vehicle; calculating the calculation according to the obtained value of the input parameter and the vehicle motion balance calculation formula (A3-5) The value of the object; the calculated value can be regarded as the actual value of the efficiency coefficient (KeKm) at time2;
测算方法(#1)的实施示例2:Example 2 of the calculation method (#1):
S1、确立车辆的滚阻系数f为测算对象;将实施例26中公式变形,确立车辆运动平衡计算公式为:f_cal=((Ke*Km)*Te3*im/R1)–fw-m2*(g*sinθ+a))/(m2*g*cosθ),(公式A3-6)S1. Establish a rolling resistance coefficient f of the vehicle as a measurement target; deform the formula in Embodiment 26 to establish a vehicle motion balance calculation formula: f_cal=((Ke*Km)*Te3*im/R1)–fw-m2*( g*sinθ+a))/(m2*g*cosθ), (Formula A3-6)
S2、获取各输入参数的合理值:假设time3为与上述time2时间点接近的时间点;获取其中需测量参数的值(获取time3时的输入参数(Te3、a、fw、θ)的实测值);获取可预设参数(Ke、Km、R1、im、g)的预设的标准值;获取time3时的车辆总质量m2的实际值;根据该所获取的输入参数的值和该车辆运动平衡计算公式(A3-6)计算该测算对象的值;因time3为与上述time2时间点接近,time2时的所获取的效率系数(KeKm)的也可视为time3时的实际值;该公式(A3-6)计算所得的值可视为time3时的滚阻系数f的实际值;可经过预设的地图信息或位置信息查表得出当前路段fr的值,进而可得出time3时与车辆相关的滚阻系数分量fc的实际值;S2: Obtain a reasonable value of each input parameter: suppose time3 is a time point close to the time point of the above time; obtain a value of the parameter to be measured (the measured value of the input parameter (Te3, a, fw, θ) when time3 is acquired) Obtaining a preset standard value of a preset parameter (Ke, Km, R1, im, g); obtaining an actual value of the total mass m2 of the vehicle at time 3; obtaining a balance of the vehicle according to the value of the acquired input parameter The calculation formula (A3-6) calculates the value of the measurement object; since time3 is close to the time 2 time point described above, the acquired efficiency coefficient (KeKm) at time 2 can also be regarded as the actual value at time 3; the formula (A3) -6) The calculated value can be regarded as the actual value of the rolling resistance coefficient f at time3; the value of the current road segment fr can be obtained through the preset map information or position information table, and then the vehicle can be obtained at time3. The actual value of the rolling resistance coefficient component fc;
测算方法(#1)的效果:The effect of the calculation method (#1):
A方案中,测算对象为动力或传动系统中的与安全紧密相关的参数或包含该参数的参数,并基于车辆运动平衡计算公式获取其值,对于车辆的安全监控、监视、数据处理均具有重要意义;如果测算对象为滚阻系数或者包含滚阻系数的参数,该计算结果可用于反映滚阻系数的状况(也即车轮形变(失圆度)和/或车轮磨损的状况);如果测算对象为效率系数或者包含效率系数的参数,该计算结果可用于反映车辆的待监控的动力传动部件的磨损和/或安全的状况;如果测算对象为综合传动比或者包含综合传动比的参数,该计算结果可用于反映综合传动比的状况,综合传动比的异常通常表示车辆的机械传动系统的严重故障;如果测算对象为驱动轮半径或者包含驱动轮半径的参数,该计算结果可用于反映驱动轮半径的状况,驱动轮半径的异常通常发生在车轮爆胎、半径缩小等严重 安全隐患时;In the A scheme, the measurement object is a parameter closely related to safety in the power or transmission system or a parameter including the parameter, and the value is obtained based on the vehicle motion balance calculation formula, which is important for safety monitoring, monitoring, and data processing of the vehicle. Meaning; if the measured object is a rolling resistance coefficient or a parameter containing a rolling resistance coefficient, the calculation result can be used to reflect the condition of the rolling resistance coefficient (that is, the deformation of the wheel (out of roundness) and/or the condition of wheel wear); if the measuring object For the efficiency coefficient or the parameter including the efficiency coefficient, the calculation result can be used to reflect the wear and/or safety condition of the power transmission component to be monitored of the vehicle; if the measurement object is an integrated transmission ratio or a parameter including an integrated transmission ratio, the calculation The result can be used to reflect the condition of the integrated gear ratio. The abnormality of the integrated gear ratio usually indicates a serious fault of the mechanical transmission system of the vehicle. If the measured object is the radius of the drive wheel or the parameter including the radius of the drive wheel, the calculation result can be used to reflect the radius of the drive wheel. Condition, the abnormality of the drive wheel radius usually occurs in the tire puncture, half Severe reduction in diameter When there is a safety hazard;
B方案中:输入参数中所包括的车辆总质量的值为基于车辆总质量的预设的实际值所设定,则在该预设的时间点到当前时间的时间段内,如果车辆总质量的异常变化(例如运载人员的异常跳车、货物质量的异常变动)可以被车辆运动平衡计算结果体现出来;如果输入参数中所包括的车辆总质量的值为基于车辆总质量的当前的实际值所设定;则计算结果反而无法体现车辆总质量的异常变化;In the B scheme: the value of the total mass of the vehicle included in the input parameter is set according to a preset actual value based on the total mass of the vehicle, and if the total mass of the vehicle is within the preset time point to the current time period Abnormal changes (such as abnormal jumps of the carrier and abnormal changes in the quality of the cargo) can be reflected by the vehicle motion balance calculation; if the total mass of the vehicle included in the input parameters is the current actual value based on the total mass of the vehicle The calculation result does not reflect the abnormal change of the total mass of the vehicle;
C方案中:因为车辆运动平衡计算是一种特殊的、基于能量守恒原理和/或牛顿定律和/或车辆运行特征因素的结合的技术方案;In the C scenario: because the vehicle motion balance calculation is a special technical solution based on the principle of energy conservation and/or Newton's law and/or vehicle operating characteristics;
即使测算对象非效率系数或包含效率系数的参数,如果输入参数中所包括的效率系数的值为预设的值(该值优选为标定值),则该测算对象的车辆运动平衡计算结果可用于反映效率系数的状况(也即待监控的动力传动部件的磨损和/或安全的状况);Even if the measurement object non-efficiency coefficient or the parameter including the efficiency coefficient, if the value of the efficiency coefficient included in the input parameter is a preset value (the value is preferably a calibration value), the vehicle motion balance calculation result of the measurement object can be used for a condition that reflects the efficiency factor (ie, the wear and/or safety of the power transmission components to be monitored);
即使测算对象非滚阻系数或包含滚阻系数的参数,如果输入参数中所包括的滚阻系数(尤其是与车辆相关的滚阻系数分量fc)的值为预设的值(该值优选为标定值),则该测算对象的车辆运动平衡计算结果可用于反映滚阻系数的状况(也即车轮形变(失圆度)和/或车轮磨损的状况);Even if the measurement object is not a rolling resistance coefficient or a parameter including a rolling resistance coefficient, if the value of the rolling resistance coefficient (especially the rolling resistance coefficient component fc related to the vehicle) included in the input parameter is a preset value (this value is preferably The calibration value), the vehicle motion balance calculation result of the measurement object can be used to reflect the condition of the rolling resistance coefficient (that is, the wheel deformation (roundness) and/or the condition of the wheel wear);
即使测算对象非综合传动比或包含综合传动比的参数,如果输入参数中所包括的综合传动比的值为预设的值(该值优选为标定值),则该测算对象的车辆运动平衡计算结果可用于反映综合传动比的状况;即使测算对象非驱动轮半径或包含驱动轮半径的参数,如果输入参数中所包括的驱动轮半径的值为预设的值(该值优选为标定值),则该测算对象的车辆运动平衡计算结果可用于反映驱动轮半径的状况;Even if the measured object has a non-integrated gear ratio or a parameter including an integrated gear ratio, if the value of the integrated gear ratio included in the input parameter is a preset value (the value is preferably a calibration value), the vehicle motion balance calculation of the measured object The result can be used to reflect the condition of the integrated gear ratio; even if the measured object non-driving wheel radius or the parameter containing the driving wheel radius, the value of the driving wheel radius included in the input parameter is a preset value (this value is preferably the calibration value) , the vehicle motion balance calculation result of the measurement object can be used to reflect the condition of the driving wheel radius;
经过深入研究分析:After in-depth research and analysis:
如果测算对象不为效率系数或包含效率系数的参数,且输入参数中未包括效率系数或输入参数中所包括效率系数以获取的当前的实际值作为该输入参数的值,则该车辆运动平衡计算的计算结果失去了对于效率系数(也即待监控的动力传动部件的磨损和/或安全的状况)的监控能力;If the measured object is not an efficiency coefficient or a parameter including an efficiency coefficient, and the input parameter does not include the efficiency coefficient or the efficiency coefficient included in the input parameter to obtain the current actual value as the value of the input parameter, the vehicle motion balance calculation The calculation results lose the ability to monitor the efficiency factor (ie, the wear and/or safety of the power transmission components to be monitored);
如果测算对象不为滚阻系数或包含滚阻系数的参数,且输入参数中未包括滚阻系数或输入参数中所包括滚阻系数以获取的当前的实际值作为该输入参数的值,则该车辆运动平衡计算的计算结果失去了对于滚阻系数(也即车轮形变(失圆度)和/或车轮磨损的状况)的监控能力;If the measured object is not a rolling resistance coefficient or a parameter including a rolling resistance coefficient, and the rolling resistance coefficient included in the input parameter or the current actual value obtained in the input parameter is obtained as the value of the input parameter, the The calculation result of the vehicle motion balance calculation loses the ability to monitor the rolling resistance coefficient (ie, the deformation of the wheel (out of roundness) and/or the condition of wheel wear);
如果测算对象不为综合传动比或包含综合传动比的参数,且输入参数中未包括综合传动比或输入参数中所包括综合传动比以获取的当前的实际值作为该输入参数的值,进行车辆运动平衡计算,则该计算结果失去了对于综合传动比的监控能力;If the measured object is not the integrated gear ratio or the parameter including the integrated gear ratio, and the input gear does not include the integrated gear ratio or the integrated gear ratio included in the input parameter to obtain the current actual value as the value of the input parameter, proceed to the vehicle. The calculation of the motion balance, the calculation result loses the monitoring ability for the integrated transmission ratio;
如果测算对象不为驱动轮半径或包含驱动轮半径的参数,且输入参数中未包括驱动轮半径或输入参数中所包括驱动轮半径以获取的为当前的实际值作为该输入参数的值进行车辆运动平衡计算,则该计算结果失去了对于驱动轮半径的监控能力;If the measured object is not a driving wheel radius or a parameter containing a driving wheel radius, and the input parameter does not include the driving wheel radius or the driving wheel radius included in the input parameter to obtain the current actual value as the value of the input parameter for the vehicle The calculation of the motion balance, the calculation result loses the ability to monitor the radius of the drive wheel;
例如,如果以车辆的迎风面积s为测算对象;如果输入参数中所包括效率系数以获取的为当前 的实际值作为该输入参数的值和输入参数中所包括滚阻系数以获取的为当前的实际值作为该输入参数的值,先以风阻为测算对象进行一次车辆运动平衡计算得出风阻的值1,同时获取此时速度V的实际值2;再基于该风阻的值1和速度V值2(和风阻的计算公式的变形公式)得到迎风面积S;因为即使此时车辆的监控的动力部件和/或传动部件的磨损和/或安全的状况、车轮形变(失圆度)和/或车轮磨损的状况异常时,因为此时车辆运动平衡计算的结果1将接近该测算对象的实际值,此时反而导致无法根据结果1和实际值监控异常;此参数只能用于其他用途。For example, if the windward area s of the vehicle is the object of measurement; if the efficiency coefficient included in the input parameter is obtained as the current The actual value is used as the value of the input parameter and the rolling resistance coefficient included in the input parameter to obtain the current actual value as the value of the input parameter. First, the wind resistance is used as the calculation object to calculate the wind resistance of the vehicle. 1, at the same time obtain the actual value 2 of the speed V at this time; and then obtain the windward area S based on the value 1 of the wind resistance and the value of the velocity V (and the deformation formula of the calculation formula of the wind resistance); because even if the monitored power component of the vehicle at this time And/or the wear and/or safety condition of the transmission component, the deformation of the wheel (out of roundness) and/or the condition of wheel wear is abnormal, because the result 1 of the vehicle motion balance calculation at this time will approach the actual value of the measurement object, At this point, it is impossible to monitor the exception according to the result 1 and the actual value; this parameter can only be used for other purposes.
综上分析,车辆运动平衡计算测算对象的值,不仅仅需要深入了解车辆运动平衡计算的算法原理,还需要对输入参数的特性深入研究,选择合适的车辆运动平衡计算公式、设置输入参数的特性,才能达到意想不到的安全监控效果。In summary, the vehicle motion balance calculation of the value of the calculation object, not only need to understand the algorithm principle of vehicle motion balance calculation, but also need to study the characteristics of the input parameters, select the appropriate vehicle motion balance calculation formula, set the characteristics of the input parameters. In order to achieve unexpected security monitoring results.
测算方法(#1)的优化方案:优选的,参考本文中其他处内容,在测算方法(#1)中,还包括下述识别运行工况提高计算性能的方案1、获取燃料质量提高计算性能的方案1、两次变速差值式车辆运动平衡计算参数的方案1、优选源动力参数为电机驱动参数的方案1、优选燃料动力参数中源动力参数的方案1中任意一种或多种方案;以进一步提高测速精度、性能。Optimization scheme of measurement method (#1): Preferably, referring to other contents in this paper, in the calculation method (#1), the following schemes for identifying the operating conditions to improve the calculation performance are also included. 1. The fuel quality improvement calculation performance is obtained. Scheme 1, the scheme of the two-speed differential-type vehicle motion balance calculation parameter, the preferred source power parameter is the motor drive parameter scheme 1, the preferred fuel-power parameter, the source power parameter scheme 1 or any one of the schemes To further improve the speed measurement accuracy and performance.
该测算方法开机自启动或者接收人工收操作指令后启动。在本发明中,该测算方法可以开机自启动,无需人为操作,在集成该监控方法的电子设备上电后自行运行,该自行运行可以是在上电后立刻开始运行,也可以是在经过预设时间后可以运行。其中,上述预设时间内可以仅作为一个待机时间,在该时间段内不执行其他应用程序,同时也可以在上述预设时间内执行其他应用程序,并可以进一步的以其他应用程序执行到一定程度(如执行一半或者执行完毕等)作为时间点来开始启动本监控方法或者直接以该些其他应用程序发送的启动指令来启动本监控方法。在接收人工操作指令后启动的工作模式中,该操作指令是用于控制本测算方法开始运行,其是在车内的操作按钮、触控屏或者其他移动电子设备(如手机)等在经过人为操作后产生。The measurement method is started after starting up or receiving a manual receiving operation instruction. In the present invention, the measuring method can be started up automatically, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running can start immediately after power-on, or can be pre-processed. It can be run after setting the time. The preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications. The degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications. In the working mode initiated after receiving the manual operation instruction, the operation instruction is used to control the starting of the calculation method, and the operation button, the touch screen or other mobile electronic devices (such as mobile phones) in the vehicle are subjected to artificial Produced after the operation.
该测算方法可用于发现、监控待监控的动力传动部件的动力传递的效率系数异常和/或车轮的滚动阻力系数异常所导致的动力传递异常;也即可用于发现、监控待监控的动力传动部件和/或第二车轮的彻底失效所导致的动力传递异常,和/或用于发现、监控待监控的动力传动部件和/或第二车轮的早期故障所导致的动力传递异常;本发明提供的技术方案,可用于发现、监控(包括车辆的旋转工作型动力或传动部件运行故障所导致的)车辆动力传递异常;即使当车辆运行参数未超过安全极限阈值时,本发明提供的技术方案也可便于尽量避免发生更严重的、不可预测的安全事故(包括断轴、车毁人亡等);如同人体医学的癌症诊断,如果晚期才发现通常意味生命终结,如果能早期预警、早期发现通常意味生命正常存活;所以本技术方案对于车辆的安全运行具有重要的实际意义。The measuring method can be used for discovering, monitoring the abnormality of the power transmission efficiency of the power transmission component to be monitored and/or the power transmission abnormality caused by the abnormal rolling resistance coefficient of the wheel; and can also be used for discovering and monitoring the power transmission component to be monitored. Abnormal power transmission caused by complete failure of the second wheel and/or power transmission abnormality caused by early failure of the power transmission component and/or the second wheel to be monitored, and/or monitored by the present invention; The technical solution can be used for discovering, monitoring, and including the vehicle power transmission abnormality caused by the rotating working power of the vehicle or the running failure of the transmission component; even when the vehicle operating parameter does not exceed the safety limit threshold, the technical solution provided by the present invention can also It is convenient to avoid more serious and unpredictable safety accidents (including broken shafts, car crashes, etc.); like human cancer diagnosis, if it is found in the late stage, it usually means the end of life. If early warning and early detection usually mean Life is normal; therefore, this technical solution is heavy for the safe operation of the vehicle. Practical significance.
本测算方法(#1)、及其动力Fx的变形、输入参数的值的基础设置方案、测算对象类型或输入参数的值的设置方案2及其各优选方案、开机自启动或者接收人工收操作指令后启动中任意一个或多个方案,以及该技术方案的用途与领域,均可应用于本发明中解决本发明中所提出的任一问题的 解决方案。The calculation method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and each of the preferred schemes, the self-starting or the receiving manual operation Any one or more of the schemes after the instruction is initiated, and the uses and fields of the technical solution can be applied to the present invention to solve any of the problems raised in the present invention. solution.
与上述的车辆运行参数的测算方法(#1)相对应,本发明还提供了一种车辆运行参数的测算系统,包括下述模块,Corresponding to the above-mentioned method for calculating vehicle operating parameters (#1), the present invention also provides a measuring system for vehicle operating parameters, including the following modules,
辆运动平衡计算公式预设模块,用于以车辆运行参数中的任意一种为测算对象,预设计算该测算对象的车辆运动平衡计算公式;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;The preset module of the motion balance calculation formula is configured to calculate the vehicle motion balance calculation formula of the measurement object by using any one of the vehicle operating parameters as a calculation object; the vehicle motion balance calculation formula is to describe the power of the vehicle in the running direction The formula for the balance of the associated resistance or the formula of the deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; or: the related resistance includes rolling resistance, slope resistance, and shift resistance One of the wind resistances, or the sum of any one of rolling resistance, slope resistance, shift resistance, and wind resistance;
输入参数获取及计算模块,用于获取输入参数的值,该输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;根据该所获取的输入参数的值和该车辆运动平衡计算公式计算该测算对象的值。An input parameter acquisition and calculation module is configured to obtain a value of the input parameter, where the input parameter is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is calculated according to the vehicle motion balance calculation formula A parameter required for the value of the object; the value of the estimated object is calculated according to the value of the acquired input parameter and the vehicle motion balance calculation formula.
本发明要解决的技术问题之二是提供一种即使在车辆运行参数未超过安全极限阈值时,也便于对(包括车辆的旋转工作型动力或传动部件运行故障和/或综合传动比的变化和/或驱动轮半径的变化所导致的)车辆动力传递异常进行监控的技术方案;A second technical problem to be solved by the present invention is to provide a change (including a change in the rotational working power or transmission component operation failure of the vehicle and/or the overall transmission ratio even when the vehicle operating parameter does not exceed the safety limit threshold). / or the technical solution of monitoring the abnormality of vehicle power transmission caused by the change of the radius of the driving wheel;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供一种车辆由动力装置控制运行时的监控方法(#1),,所述监控方法包括步骤:The invention provides a monitoring method (#1) when a vehicle is controlled by a power device, and the monitoring method comprises the steps of:
A、以车辆运行参数中的任意一种为测算对象,获取所述车辆的测算对象的联合运算值,获取所述测算对象的参考数据,根据车辆的测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;所述联合运算值为基于车辆运动平衡计算公式计算所得的结果;A. Taking any one of the vehicle operating parameters as a measurement object, acquiring a joint operation value of the measurement object of the vehicle, acquiring reference data of the measurement object, and jointly calculating the value according to the measurement object of the vehicle and the measurement object The reference data determines whether the power transmission condition of the vehicle is abnormal; the joint operation value is a result calculated based on a vehicle motion balance calculation formula;
该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;包括也可理解为至少为;多种力之和可理解为多种力的合力;The vehicle motion balance calculation formula is a formula for describing a balance between the dynamic direction of the vehicle and the related resistance in the running direction or a deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; or The related resistance includes one of rolling resistance, slope resistance, shift resistance, wind resistance, or includes any combination of rolling resistance, slope resistance, shift resistance, and wind resistance; including, as well, at least; And can be understood as the combined force of multiple forces;
该车辆运动平衡计算公式的输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;The input parameter of the vehicle motion balance calculation formula is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula;
优选的,设定输入参数中以实测取值的参数个数,这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Preferably, the number of parameters in the input parameter to be measured is set, and the parameters are set based on the measured value; other parameters may be set by preset values; the more the measured parameters, the higher the accuracy will be, the better the monitoring performance is. The measured parameters are less costly; the user and the manufacturer can customize according to their different situations.
本发明提供与监控方法(#1)原理相同,但描述不同的另一监控方法(#2):The present invention provides the same monitoring method (#1) as the other, but describes another monitoring method (#2):
1、一种车辆动力传递状况的监控方法(#2),包括如下步骤A:1. A method for monitoring the power transmission condition of a vehicle (#2), comprising the following steps A:
S100、以车辆运行参数中的任意一种为测算对象; S100, taking any one of vehicle operating parameters as a measurement object;
S200、确定计算该测算对象的车辆运动平衡计算公式;该车辆运动平衡计算公式为描述车辆移动方向的动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;该包括也可理解为至少为;该和可理解为合力;设定输入参数中以实测取值的参数个数,获取输入参数的值,所述输入参数为所述车辆运动平衡计算公式中除所述测算对象外的所有参数;并根据该输入参数的值、车辆运动平衡计算公式计算该测算对象;获取车辆当前运动状态下该测算对象的参考数据;S200: Determine a vehicle motion balance calculation formula for calculating the measurement object; the vehicle motion balance calculation formula is a formula for describing a balance between a power and a related resistance of a moving direction of the vehicle or a formula thereof; the related resistance includes a rolling resistance, a gradient resistance, and a shifting speed Any one or any of a variety of resistance and wind resistance; or: the relevant resistance includes any one of rolling resistance, slope resistance, shift resistance, and wind resistance, or any of rolling resistance, slope resistance, shift resistance, and wind resistance. And the inclusion is also understood to be at least; the sum can be understood as a resultant force; setting the number of parameters in the input parameter to be measured, obtaining the value of the input parameter, the input parameter being the vehicle motion balance calculation All the parameters except the measured object in the formula; and calculating the measuring object according to the value of the input parameter and the vehicle motion balance calculation formula; acquiring reference data of the measuring object in the current motion state of the vehicle;
S300、比较计算所得该测算对象的值和该测算对象的参考数据,判断所述车辆的动力传递状况是否异常。S300: Compare and calculate the calculated value of the measurement object and the reference data of the measurement object, and determine whether the power transmission status of the vehicle is abnormal.
该监控方法(#1)或监控方法(#2)中车辆运动平衡计算公式及计算方法及参数的设置方法可参考本文中任一位置的内容进行;The vehicle motion balance calculation formula, the calculation method and the parameter setting method in the monitoring method (#1) or the monitoring method (#2) can be referred to the content of any position in this document;
该监控方法(#1)或监控方法(#2)为开机自启动,或者接收人工指令后启动(简称人工启动)。在本发明中,该监控方法可以开机自启动,无需人为操作,在集成该监控方法的电子设备上电后自行运行,该自行运行可以是在上电后立刻开始运行,也可以是在经过预设时间后可以运行。其中,上述预设时间内可以仅作为一个待机时间,在该时间段内不执行其他应用程序,同时也可以在上述预设时间内执行其他应用程序,并可以进一步的以其他应用程序执行到一定程度(如执行一半或者执行完毕等)作为时间点来开始启动本监控方法或者直接以该些其他应用程序发送的启动指令来启动本监控方法。在接收人工操作指令后启动的工作模式中,该人工指令用于控制本监控方法开始运行,其是在车内的操作按钮、触控屏、语音系统、或者其他移动电子设备(如手机)等在经过人为操作后产生。开机自启动、人工启动的可选,具有重要意义;因该监控方法对于车辆的运行安全具有重要作用,选择开机自启动,可避免人员忘记开启、误操作等不利因素,且有利于记录全程的安全监控数据;在某些情况下,当车辆的监控方法未调校好如果选择自动启动,则可能导致误报率升高等不利影响,所以在某些情况下选择人工启动是有意的。The monitoring method (#1) or the monitoring method (#2) is started from the startup or started after receiving the manual instruction (referred to as manual startup). In the present invention, the monitoring method can be started up automatically, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running may start immediately after power-on, or may be pre-evented. It can be run after setting the time. The preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications. The degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications. In the working mode initiated after receiving the manual operation instruction, the manual instruction is used to control the start of operation of the monitoring method, which is an operation button, a touch screen, a voice system, or other mobile electronic devices (such as a mobile phone) in the vehicle. Produced after human manipulation. The option of starting from the start and starting manually is of great significance; because the monitoring method plays an important role in the operation safety of the vehicle, the self-starting is selected to avoid unfavorable factors such as forgetting to open and misuse, and it is beneficial to record the whole process. Safety monitoring data; in some cases, when the vehicle monitoring method is not adjusted, if you choose to start automatically, it may lead to adverse effects such as increased false alarm rate, so it is intentional to choose manual starting in some cases.
优选的,可参考前述测算方法(#1)、及其动力Fx的变形、输入参数的值的基础设置方案、测算对象类型或输入参数的值的设置方案2及其各优选方案、开机自启动或者接收人工收操作指令后启动中任意一个或多个方案,用于监控方法(#1)或监控方法(#2)中。Preferably, reference may be made to the foregoing measurement method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and various preferred schemes thereof, and the booting from the startup Or any one or more schemes initiated after receiving the manual operation instruction, used in the monitoring method (#1) or the monitoring method (#2).
所获取的车辆运动平衡计算公式中输入参数的值均为合理值(也可称为合格值);不同的输入参数有不同的合理值;例如,输入参数中所包括的车辆总质量的值为基于车辆总质量的当前的实际值或预设的实际值所设定,该当前的实际值或预设的实际值均为输入参数中所包括的车辆总质量的合理值;例如,输入参数中所包括的除车辆总质量之外的第一类型参数中的参数的值为基于该参数的当前的实际值所设定,当前的实际值为该第一类型的输入参数(例如,源动力参数、速度、加速度等)的合理值;例如,输入参数中所包括的除车辆总质量之外的第二类型参数中的参数(例如效率系数、 滚阻系数、综合传动比、驱动轮半径、重力加速度等)的值为基于该参数当前的实际值或该参数的安全范围中的值或所设定;通常来说该参数的安全范围中的值为预设方式所设定;该参数当前的实际值或该参数的预设的安全范围中的值为该第二类型的输入参数的合理值;The values of the input parameters in the obtained vehicle motion balance calculation formula are all reasonable values (also referred to as qualified values); different input parameters have different reasonable values; for example, the value of the total mass of the vehicle included in the input parameters is Based on the current actual value of the total mass of the vehicle or the preset actual value, the current actual value or the preset actual value is a reasonable value of the total mass of the vehicle included in the input parameter; for example, in the input parameter The value of the parameter included in the first type of parameter other than the total mass of the vehicle is set based on the current actual value of the parameter, and the current actual value is the input parameter of the first type (eg, the source dynamic parameter) a reasonable value of the speed, acceleration, etc.; for example, a parameter of the second type of parameter other than the total mass of the vehicle included in the input parameter (eg, efficiency coefficient, The value of the rolling resistance coefficient, the integrated gear ratio, the driving wheel radius, the gravitational acceleration, etc.) is based on the current actual value of the parameter or the value in the safety range of the parameter or is set; generally, the safety range of the parameter The value is set by the preset mode; the current actual value of the parameter or the value in the preset safety range of the parameter is a reasonable value of the input parameter of the second type;
测算对象类型或输入参数的值的设置方案2:本测算方法(#1)还包括方案A、B、C中任一方案:Setting of the measurement object type or the value of the input parameter Scheme 2: The calculation method (#1) also includes any one of the schemes A, B, and C:
A、测算对象为动力或传动系统中的与安全紧密相关的参数或包含该参数的参数;输入参数的值均为根据该输入参数的合理值所设定;;A. The measurement object is a parameter closely related to safety in the power or transmission system or a parameter including the parameter; the value of the input parameter is set according to a reasonable value of the input parameter;
B、输入参数中所包括的车辆总质量的值为基于车辆总质量的预设的实际值所设定,而非基于车辆总质量的当前的实际值所设定;输入参数中除车辆总质量之外的其他参数的值为根据各参数的合理值所设定;B. The value of the total mass of the vehicle included in the input parameters is set based on the preset actual value of the total mass of the vehicle, and is not set based on the current actual value of the total mass of the vehicle; The values of other parameters other than those set are based on reasonable values of each parameter;
C、输入参数中所包括的动力或传动系统中的与安全紧密相关的参数中至少一种为基于预设值所设定,而非基于该参数当前的实际值所设定,该预设值为预设的安全范围中的值;输入参数中除该动力或传动系统中的与安全紧密相关的参数之外的其他参数的值为根据各参数的合理值所设定;C. At least one of the power included in the input parameter or the safety-related parameter in the transmission system is set based on the preset value, and is not set based on the current actual value of the parameter, the preset value The value in the preset safety range; the values of the parameters other than the safety-related parameters in the power or transmission system are set according to the reasonable values of the parameters;
设置方案2的优选方案2:优选的,无论A、B、C方案中,当输入参数中的第二类型参数中参数为基于预设的安全范围中的值设定时,该安全范围中的值为标定值;这样利于提高计算精度、监控精度;; Preferred Embodiment 2 of Setting Scheme 2: Preferably, in the A, B, and C schemes, when the parameter in the second type parameter in the input parameter is set based on the value in the preset safety range, the safety range is The value is a calibration value; this is beneficial to improve calculation accuracy and monitoring accuracy;
设置方案2的优选方案3:无论A、B、C方案中,输入参数中除车辆总质量之外的第一类型参数中至少一个参数为基于实测值设定,例如源动力参数、速度、加速度等;优选的,该至少一个为全部。A preferred scheme 3 of setting scheme 2: in any of the A, B, and C schemes, at least one of the first type of parameters other than the total mass of the input parameters is set based on the measured value, such as source dynamic parameters, speed, and acceleration. And so on; preferably, the at least one is all.
设置方案2的优选方案4:动力或传动系统中的与安全紧密相关的参数优选为效率系数和/或滚阻系数;相比较于综合传动比和/或驱动轮半径,该效率系数和/或滚阻系数具有更为重要的安全意义。 Preferred solution 4 of setting scheme 2: the safety-critical parameter closely related to safety in the transmission system is preferably an efficiency coefficient and/or a rolling resistance coefficient; compared to the overall transmission ratio and/or the driving wheel radius, the efficiency coefficient and/or The rolling resistance coefficient has a more important safety significance.
设定输入参数中以实测取值的参数(或及其个数),这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Set the parameters (or their number) of the measured parameters in the input parameters. These parameters are set based on the measured values; other parameters can be set by the preset values; the more the measured parameters, the higher the accuracy will naturally be, the monitoring The performance is good; the measured parameters are less and the cost is lower; the user and the manufacturer can be customized according to their different situations.
优选的,在监控方法(#1)或监控方法(#2),所述测算对象为车辆质量中的一种参数,所述测算对象的输入参数包括系统运行参数以及源动力参数;或,Preferably, in the monitoring method (#1) or the monitoring method (#2), the measuring object is a parameter in the vehicle quality, and the input parameter of the measuring object includes a system operating parameter and a source dynamic parameter; or
所述测算对象为源动力参数中的一种参数,所述测算对象的输入参数包括系统运行参数以及车辆质量;或,The measurement object is one of a source dynamic parameter, and the input parameter of the measurement object includes a system operation parameter and a vehicle quality; or
所述测算对象为系统运行参数中的一种参数,所述测算对象的输入参数包括车辆质量数以及源动力参数。The measurement object is one of the system operation parameters, and the input parameters of the measurement object include a vehicle mass number and a source power parameter.
优选的,在该监控方法,所述测算对象为车辆质量、源动力参数、机械运行参数或质量变化型 物品质量中的一种参数,所述测算对象的参考值为实际值;或,Preferably, in the monitoring method, the measurement object is a vehicle quality, a source dynamic parameter, a mechanical operation parameter or a quality change type. a parameter in the quality of the item, the reference value of the measured object is an actual value; or
所述测算对象为系统固有参数中的任意一种,所述测算对象为参考值为系统预设值。The measurement object is any one of system inherent parameters, and the measurement object is a reference value of a system preset value.
本发明提供与监控方法(#1)原理相同,但描述不同的另一监控方法(#3):The present invention provides the same monitoring method (#1) as the other, but describes another monitoring method (#3):
1、一种车辆动力传递状况的监控方法(#3),包括如下步骤:1. A method for monitoring the power transmission condition of a vehicle (#3), comprising the following steps:
S100、确定车辆运行参数中的任意一种为测算对象;S100. Determine any one of vehicle operating parameters as a measurement object;
S200、确定计算该测算对象的车辆运动平衡公式;该车辆运动平衡公式为描述车辆移动方向的动力fx与相关阻力平衡的公式或其等效变形的公式;该相关阻力包括滚动阻力fμ、坡度阻力fθ、变速阻力fa、风阻fw中任意一种或多种;S200. Determine a vehicle motion balance formula for calculating the measurement object; the vehicle motion balance formula is a formula for describing a balance between a power fx and a related resistance of a moving direction of the vehicle or an equivalent deformation thereof; the related resistance includes a rolling resistance fμ, a gradient resistance Any one or more of fθ, variable speed resistance fa, and wind resistance fw;
S300、所述车辆运动平衡公式中除所述测算对象外的所有参数为输入参数,获取全部输入参数的值,并根据输入参数(的值)、车辆运动平衡公式计算该测算对象;获取该测算对象的参考数据;所述参考数据和输入参数中,至少一种取预设值并确定输入参数中取预设值的参数个数;S300. All the parameters except the measurement object in the vehicle motion balance formula are input parameters, obtain values of all input parameters, and calculate the measurement object according to the input parameter (value) and the vehicle motion balance formula; and obtain the calculation Reference data of the object; at least one of the reference data and the input parameter takes a preset value and determines a number of parameters of the input parameter that take a preset value;
S400、比较计算所得该测算对象的值和该测算对象的参考数据,判断所述车辆的动力传递状况是否异常。S400. Compare and calculate the calculated value of the measurement object and the reference data of the measurement object, and determine whether the power transmission status of the vehicle is abnormal.
2、优选的,监控方法(#3)中所述步骤S300中,所述参考数据和输入参数中除取预设值的参数外,其他的参数取实际值。例如:测算方法(#1)的实施示例1中,R1、im以及kekm的参考数据为预设值,其他的所有参数m2、a2、a1、Te2、Te1均为实际值;测算方法(#1)的实施示例2中,Ke、Km、R1、im、g以及f的参考数据为预设值,其他的所有参数Te3、fw、m2、θ及a均为实际值;实施例41中,Ke、Km1、im1、R1_1、Km2、Kf3、R0、im2以及R1_2为预设值,其他所有参数Te、F1、fw以及m2的参考数据为实际值。2. Preferably, in step S300 described in the monitoring method (#3), in addition to the parameter of the preset value in the reference data and the input parameter, the other parameters take the actual value. For example, in the implementation example 1 of the measurement method (#1), the reference data of R1, im, and kekm are preset values, and all other parameters m2, a2, a1, Te2, and Te1 are actual values; the calculation method (#1) In the implementation example 2, reference data of Ke, Km, R1, im, g, and f are preset values, and all other parameters Te3, fw, m2, θ, and a are actual values; in Embodiment 41, Ke Km1, im1, R1_1, Km2, Kf3, R0, im2, and R1_2 are preset values, and the reference data of all other parameters Te, F1, fw, and m2 are actual values.
3、优选的,监控方法(#3)中所述步骤S300中,3. Preferably, in step S300 described in the monitoring method (#3),
当所述参考数据和输入参数中只有一个取预设值时:When only one of the reference data and the input parameter takes a preset value:
参考数据取预设值,输入参数全部取实际值,用于监控车辆动力传递状况是否异常;其中,参考数据所取预设值,为与当前车辆运行状态相同状态下的历史记录值;本发明中,与当前车辆运行状态相同状态下的历史记录值,指该历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值;The reference data takes a preset value, and the input parameters all take the actual value, and are used to monitor whether the power transmission condition of the vehicle is abnormal; wherein the preset value taken by the reference data is a historical record value in the same state as the current vehicle running state; the present invention The history value in the same state as the current vehicle running state refers to the difference between the vehicle operating condition and the current vehicle operating condition when the value of the historical value is lower than a preset threshold;
优选的,当测算对象为能够描述车辆的其中一部分的属性的参数时,车辆动力传递状况能够具体为代表该部件的状况,例如:在实施例9中kem的联合运算公式中,Kem的参考数据取预设值,输入参数全部取实际值时,可监控kem所描述的部分(如传动部件)是否异常;在实施例1中,m2的参考数据取预设值(如自学习得到),输入参数全部取实际值时,可监控m2所描述的部分(如车体是否完整或者运载物品是否掉落)的状况;如实施例11中,μ1的参考数据取预设值,输入参数全部取实际值时,可监控μ1所代表的部分的状况(如轮胎是否突然漏气)。 Preferably, when the measurement object is a parameter capable of describing an attribute of a part of the vehicle, the vehicle power transmission condition can be specifically a condition representing the part, for example, in the joint operation formula of kem in Embodiment 9, the reference data of the Kem The preset value is taken. When all the input parameters take the actual value, it is possible to monitor whether the part (such as the transmission component) described by kem is abnormal. In the embodiment 1, the reference data of m2 takes a preset value (such as self-learning), and the input is input. When all the parameters take the actual value, the condition of the part described by m2 (such as whether the vehicle body is intact or the carrying item is dropped) can be monitored; as in the embodiment 11, the reference data of μ1 takes a preset value, and the input parameters are all taken practically. At the time of the value, it is possible to monitor the condition of the part represented by μ1 (such as whether the tire suddenly leaks).
参考数据取实际值,输入参数中有一个取预设值,用于监控输入参数中取预设值的参数是否异常;输入参数中该参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;以实施例2为例进行说明,m2的参考数据取实际值,μ1取预设值而其余的参数取实际值,则能够监控μ1是否异常;若m2的参考数据取预设值,ki取预设值而其余的参数取实际值,则能够监控ki是否异常。应当理解的是,对于取预设值的输入参数或者监控对象的异常,当该取预设值的输入参数或者监控对象为当测算对象为能够描述车辆的其中一部分的属性的参数时,车辆动力传递状况能够具体为代表该部件的状况。The reference data takes the actual value, and one of the input parameters takes a preset value for monitoring whether the parameter of the input parameter takes the preset value is abnormal; the preset value of the parameter in the input parameter is the same state as the current vehicle running state. The historical value under the vehicle is the calibration value when the vehicle is shipped. The example 2 is taken as an example. The reference data of m2 takes the actual value. If μ1 takes the preset value and the remaining parameters take the actual value, it can monitor whether μ1 is Abnormal; if the reference data of m2 takes the preset value, ki takes the preset value and the remaining parameters take the actual value, it can monitor whether ki is abnormal. It should be understood that, for an input parameter taking a preset value or an abnormality of a monitoring object, when the input parameter or the monitoring object of the preset value is a parameter when the measurement object is an attribute capable of describing a part of the vehicle, the vehicle power The delivery condition can be specifically representative of the condition of the component.
当所述参考数据和输入参数中有N个取预设值,N≥2:When N of the reference data and the input parameters take a preset value, N≥2:
参考数据取预设值,输入参数中有N-1个取预设值,用于监控测算对象和输入参数中取预设值的参数是否异常;其中,参考数据所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;输入参数中该两个参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;继续以实施例2为例进行说明,当m2的参考数据取预设值,输入参数中μ1取预设值而其他的参数取实际值时,能够监控m2以及μ1是否异常;当m2的参考数据取预设值,输入参数中μ1以及ki取预设值而其他的参数取实际值时,则能监控m2、μ1以及ki是否异常。The reference data takes a preset value, and N-1 of the input parameters take a preset value, which is used to monitor whether the parameter of the preset value is abnormal in the measurement object and the input parameter; wherein, the preset value of the reference data is The historical record value in the same state of the current vehicle running state, or the calibration value when the vehicle is shipped from the factory; the preset value taken by the two parameters in the input parameter is the historical record value in the same state as the current vehicle running state, or The calibration value of the vehicle when it leaves the factory; continue to use the example 2 as an example. When the reference data of m2 takes the preset value, if the input parameter takes μ1 to take the preset value and the other parameters take the actual value, can it monitor whether m2 and μ1 are Abnormal; when the reference data of m2 takes the preset value, if the input parameter μ1 and ki take the preset value and the other parameters take the actual value, it can monitor whether m2, μ1 and ki are abnormal.
参考数据取实际值,输入参数中有N个取预设值,用于监控输入参数中取预设值的参数是否异常;其中,输入参数中该N个参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值。例如在实施例8中,当Te的参考数据取实际值,输入参数中m2、μ1、im及R1取预设值而其余的输入参数取实际值时,可以监控m2μ1、im及R1是否异常;当Te的参考数据取实际值,输入参数中m2、μ1、im、θ及R1取预设值而其余的输入参数取实际值时,可以监控m2、μ1、im、θ及R1是否异常。应当理解的是,关于参考数据与输入参数中预设值与实际值的个数与对应具体用途的关系的其他情况,本领域人员可在上述的说明及具体实施例的基础上进行,此处不再一一赘述。The reference data takes the actual value, and N of the input parameters take a preset value, which is used to monitor whether the parameter of the input parameter takes the preset value is abnormal; wherein, the preset value of the N parameter in the input parameter is the current value The historical value of the vehicle in the same state of operation, or the calibration value when the vehicle is shipped from the factory. For example, in Embodiment 8, when the reference data of Te takes the actual value, and m2, μ1, im, and R1 of the input parameter take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2μ1, im, and R1 are abnormal; When Te's reference data takes the actual value, m2, μ1, im, θ, and R1 in the input parameters take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2, μ1, im, θ, and R1 are abnormal. It should be understood that other situations regarding the relationship between the number of preset values and actual values in the reference data and the input parameters and the specific use may be performed by those skilled in the art based on the above description and specific embodiments, where I will not repeat them one by one.
4、优选的,监控方法(#3)中,与当前车辆运行状态相同状态下的历史记录值指:历史记录值生成时所对应的车辆质量、车辆的速度、车辆的外部环境信息以及源动力参数与当前的车辆质量、车辆的速度、车辆的外部环境信息以及源动力参数分别一致;所述外部环境信息是指车子本体以外的影响车辆运行状态的环境信息,如路面坡度、风速、路面的摩擦系数等;所述一致是指参数的大小相同或者接近,且若该参数存在方向,则参数的方向相同或接近。4. Preferably, in the monitoring method (#3), the historical record value in the same state as the current vehicle running state refers to: the vehicle mass corresponding to the historical record value generation, the speed of the vehicle, the external environment information of the vehicle, and the source power. The parameters are consistent with the current vehicle mass, the speed of the vehicle, the external environment information of the vehicle, and the source power parameters; the external environment information refers to environmental information other than the body of the vehicle that affects the running state of the vehicle, such as road gradient, wind speed, and road surface. The coefficient of friction or the like; the agreement means that the sizes of the parameters are the same or close, and if the parameters have directions, the directions of the parameters are the same or close.
5、优选的,监控方法(#3)中,所述步骤S300中,包括如下情形中的任意一种:5. Preferably, in the monitoring method (#3), the step S300 includes any one of the following situations:
A、当该测算对象为效率系数或者包含效率系数的参数时:A. When the measured object is an efficiency coefficient or a parameter including an efficiency coefficient:
如果输入参数中所包括的滚阻系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际值;该方法可用于反映滚阻系数(也即车轮形变所导致)的异常; If the value of the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measuring object is an actual value; the method can be used to reflect the abnormality of the rolling resistance coefficient (that is, caused by the wheel deformation);
如果输入参数中所包括的滚阻系数的值为实际值,该测算对象的参考数据为车辆出厂时的标定值;If the value of the rolling resistance coefficient included in the input parameter is an actual value, the reference data of the measuring object is a calibration value when the vehicle is shipped from the factory;
B、当该测算对象为滚阻系数或者包含滚阻系数的参数时:B. When the measurement object is a rolling resistance coefficient or a parameter including a rolling resistance coefficient:
如果输入参数中所包括的效率系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际值;该方法可用于反映效率系数(也即动力系统和/或机械传动系统异常所导致)的异常;If the value of the efficiency factor included in the input parameter is the factory calibration value, the reference data of the measurement object is the actual value; the method can be used to reflect the efficiency coefficient (that is, the power system and/or mechanical transmission system abnormality Anomaly;
如果输入参数中所包括的效率系数的值为实际值,该测算对象的参考数据为车辆出厂时的标定值;If the value of the efficiency coefficient included in the input parameter is an actual value, the reference data of the measurement object is a calibration value when the vehicle is shipped from the factory;
C、当该测算对象为车辆运行参数中除滚阻系数、包含滚阻系数的参数、效率系数、包含效率系数的参数外的其他参数时:C. When the measurement object is the vehicle running parameter except the rolling resistance coefficient, the parameter including the rolling resistance coefficient, the efficiency coefficient, and other parameters including the efficiency coefficient:
如果输入参数中所包括的效率系数和/或滚阻系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际值;对应的,该方法可用于反映效率系数和/或滚阻系数(也即动力系统和/或机械传动系统异常和/或车轮形变所导致)的异常;If the value of the efficiency factor and/or the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measurement object is an actual value; correspondingly, the method can be used to reflect the efficiency coefficient and/or the rolling resistance. Anomalies in coefficients (ie, caused by abnormalities in the powertrain and/or mechanical transmission system and/or wheel deformation);
如果输入参数中所包括的效率系数和滚阻系数的值为实际值,该测算对象的参考数据为与当前车辆运行状态相同状态下的历史记录值。If the values of the efficiency coefficient and the rolling resistance coefficient included in the input parameters are actual values, the reference data of the measurement object is a history value in the same state as the current vehicle running state.
6、优选的,监控方法(#3)中,所述步骤S300中6. Preferably, in the monitoring method (#3), in the step S300
所述方案A中,输入参数中除滚阻系数外的其他参数的值为标定值或实际值;In the scheme A, the values of the other parameters except the rolling resistance coefficient in the input parameter are the calibration value or the actual value;
所述方案B中,输入参数中除效率系数外的其他参数的值为标定值或实际值;In the scheme B, the value of the other parameters except the efficiency coefficient in the input parameter is a calibration value or an actual value;
所述方案C中,输入参数中除滚阻系数、效率系数外的其他参数的值为标定值或实际值。In the scheme C, the values of the other parameters except the rolling resistance coefficient and the efficiency coefficient in the input parameter are the calibration value or the actual value.
7、优选的,监控方法(#3)中,所述步骤S300之后还包括如下步骤;7. Preferably, in the monitoring method (#3), after the step S300, the following steps are further included;
S301、输出和/或保存计算所得测算对象的值。S301. Output and/or save the calculated value of the measured object.
8、优选的,监控方法(#3)中,所述步骤S300还包括:8. Preferably, in the monitoring method (#3), the step S300 further includes:
A、先判断所述车辆的动力传递状况,后获取所述车辆的运行环境信息,判断所述运行环境信息是否落入预设的正常范围;A. First, determine the power transmission status of the vehicle, and then obtain the operating environment information of the vehicle, and determine whether the operating environment information falls within a preset normal range;
当判断所述车辆的动力传递状况为异常时:When it is judged that the power transmission condition of the vehicle is abnormal:
如果所述运行环境信息全部落入预设的正常范围,所述车辆的动力传递状况的判断结果正确,并进一步判断动力传递状况故障;If the operating environment information all falls within a preset normal range, the determination result of the power transmission condition of the vehicle is correct, and further determining the power transmission status failure;
如果所述运行环境信息中任意一种超过预设的正常范围,所述车辆的动力传递状况的判断结果错误,判断结果更改为车辆的动力传递状况正常;If any one of the operating environment information exceeds a preset normal range, the determination result of the power transmission condition of the vehicle is incorrect, and the determination result is changed to that the power transmission condition of the vehicle is normal;
当判断所述车辆的动力传递状况为正常时:When it is judged that the power transmission condition of the vehicle is normal:
如果所述运行环境信息全部落入预设的正常范围,所述车辆的动力传递状况的判断结果正确;If the operating environment information all falls within a preset normal range, the judgment result of the power transmission condition of the vehicle is correct;
如果所述运行环境信息中任意一种超过预设的正常范围,所述车辆的动力传递状况的判断结果错误,判断结果更改为车辆的动力传递状况异常; If any one of the operating environment information exceeds a preset normal range, the determination result of the power transmission condition of the vehicle is incorrect, and the determination result is changed to an abnormal power transmission condition of the vehicle;
B、先获取所述车辆的运行环境信息,判断所述运行环境信息是否落入预设的正常范围,后判断所述车辆的动力传递状况;如果所述运行环境信息全部落入预设的正常范围,进一步进行所述车辆的动力传递状况的判断。B. First, obtain the operating environment information of the vehicle, determine whether the operating environment information falls within a preset normal range, and then determine the power transmission status of the vehicle; if the operating environment information falls into a preset normal state The range further determines the power transmission condition of the vehicle.
9、优选的,监控方法(#3)中,所述步骤S300中,所述输入参数中包括质量变化型物品质量。9. Preferably, in the monitoring method (#3), in the step S300, the input parameter includes a quality-changing item quality.
10、优选的,监控方法(#3)中,所述步骤S200还包括:获取动力装置运行工况,并将所述动力装置运行工况与测算对象的计算关联;10. Preferably, in the monitoring method (#3), the step S200 further includes: acquiring a power device operating condition, and associating the power device operating condition with the calculation of the measurement object;
所述动力装置驱动状态、动力装置制动状态,The power unit driving state, the power unit braking state,
当动力装置运行工况为动力装置驱动状态时,能量/动力传递方向为从动力装置经机械传动系统再传递到车体,计算测算对象时将源动力参数的值乘以小于1的效率系数;When the operating condition of the power device is the driving state of the power device, the energy/power transmission direction is transmitted from the power device to the vehicle body through the mechanical transmission system, and the value of the source power parameter is multiplied by an efficiency coefficient less than 1 when calculating the measurement object;
当动力装置运行工况为动力装置制动状态时,能量/动力传递方向为从车体经机械传动系统再传递到动力装置,计算测算对象时将源动力参数的值除以小于1的效率系数。When the operating condition of the power unit is the braking state of the power unit, the energy/power transmission direction is transmitted from the vehicle body to the power unit via the mechanical transmission system, and the value of the source power parameter is divided by the efficiency coefficient less than 1 when calculating the measurement object. .
11、优选的,监控方法(#3)中,所述步骤S400还包括:当所述车辆处于非稳定驱动状态时,所述车辆的动力传递状况的判断过程取消;其中,当车辆的源动力参数、机械类综合运行力、速度中的至少一种小于预设阀值时,或者车辆的动力装置运行工况为动力装置制动状态时,所述车辆处于非稳定驱动状态。11. Preferably, in the monitoring method (#3), the step S400 further comprises: when the vehicle is in an unsteady driving state, the determining process of the power transmission condition of the vehicle is canceled; wherein, when the vehicle is powered The vehicle is in an unsteady driving state when at least one of the parameter, the mechanical comprehensive running force, and the speed is less than a preset threshold, or when the power running condition of the vehicle is the powering device braking state.
12、优选的,监控方法(#3)中,所述步骤S400中,基于该测算对象的参考数据而设定预设范围,若计算所得该测算对象的值落入该预设范围,判断所述车辆的车辆动力传递状况正常;若计算所得该测算对象的值没有落入该预设范围,判断所述车辆的车辆动力传递状况异常。12. Preferably, in the monitoring method (#3), in the step S400, the preset range is set based on the reference data of the measurement object, and if the calculated value of the measurement object falls within the preset range, the determination center The vehicle power transmission condition of the vehicle is normal; if the calculated value of the measurement object does not fall within the preset range, it is determined that the vehicle power transmission condition of the vehicle is abnormal.
13、优选的,监控方法(#3)中,所述步骤S400之后还包括步骤:13. Preferably, in the monitoring method (#3), the step S400 further comprises the following steps:
S401、输出和/或保存所述判断的结果。S401. Output and/or save the result of the determination.
进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)还可进行下述B步骤处理:Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) can also perform the following B step processing:
B.进行下述B1、B2、B3中任意一种或多种方案处理:B. Perform any one or more of the following B1, B2, and B3 treatments:
B1.如所述判断结果包括是,则启动设定的动力传递异常处理机制;B1. If the determination result includes yes, the set power transmission abnormality processing mechanism is started;
B2.输出所述判断结果;B2. outputting the judgment result;
B3.保存所述判断结果。B3. Save the judgment result.
所述测算对象的联合运算值可包括直接联合运算值(也即直接得到的联合运算值)、间接联合运算值(也即间接得到的联合运算值)等;例如,根据车辆的源动力参数和系统运行参数,进行车辆运动平衡计算得到车辆总质量m2,则m2为直接联合运算值;根据车辆总质量m2再计算出运载物 品质量m1或空载车体质量m0,则m1或m0均为间接联合运算值;本发明中所述联合运算值也可称为联合运算数据,两者等同。The joint operation value of the measurement object may include a direct joint operation value (that is, a directly obtained joint operation value), an indirect joint operation value (that is, an indirectly obtained joint operation value), and the like; for example, according to a source dynamic parameter of the vehicle and The operating parameters of the system are calculated by vehicle motion balance to obtain the total mass m2 of the vehicle, then m2 is the direct joint calculation value; the carrier is calculated according to the total mass m2 of the vehicle. The product quality m1 or the empty body mass m0, then m1 or m0 are indirect joint operation values; the joint operation value in the present invention may also be referred to as joint operation data, and the two are equivalent.
本发明所述联合运算值,为任意一个参数(如m2/或m1/或m0/或mf)根据联合运算所得的数值;本发明所述实际值与真实值是有区别的概念;真实值通常为某对象某一属性的自然的、真实的数值;本发明所述监控方法中的参考数据中实际值,通常指用于作为动力传递状况判断的识别基准的数值,所以也可称为基准值;The joint operation value of the present invention is a value obtained by a joint operation for any one parameter (such as m2/ or m1/ or m0/ or mf); the actual value and the true value of the present invention are different concepts; the true value is usually The natural value of a certain attribute of an object; the actual value in the reference data in the monitoring method of the present invention generally refers to a value used as a reference for the determination of the power transmission condition, so it may also be referred to as a reference value. ;
本发明所述监控方法中的参考数据中实际值(也称为基准值),其必须考虑切实可行的技术手段或实现方案,其值自然的受约束于具体的取值时间和/或取值方式;根据后述的参考数据的具体设置方案(如数据的来源或取值途径的选取、设定方式、取值时间等)的通常规则(参考数据设置的示范方法1、2、3、4、5、6)以及相关实施例(实施例34-43),显而易见的可得知:根据测算对象不同和/或实际值设置方式的不同,本发明所述监控方法中的参考数据中实际值(也即基准值)有多种不同的取值时间范围、多种不同的值域、可由多种不同的技术方法或方案来实现。可采用如下原则:所述参考数据和输入参数中,至少一种取预设值并确定输入参数中取预设值的参数个数;该预设值包括标定值或与当前车辆运行状态相同状态下的历史记录值;The actual value (also referred to as the reference value) in the reference data in the monitoring method of the present invention must consider practical technical means or implementation scheme, and its value is naturally constrained to the specific value time and/or value. Method; according to the specific setting scheme of the reference data described later (such as the source of the data or the selection of the value path, the setting method, the value time, etc.), the general rules (reference data setting method 1, 2, 3, 4) 5, 6) and related embodiments (embodiments 34-43), it is obvious that the actual value in the reference data in the monitoring method of the present invention is different depending on the measurement object and/or the actual value setting mode. (ie, the reference value) has a variety of different time ranges, multiple different ranges, and can be implemented by a variety of different technical methods or schemes. The following principle may be adopted: at least one of the reference data and the input parameter takes a preset value and determines a parameter number of the input parameter that takes a preset value; the preset value includes a calibration value or the same state as the current vehicle running state. History value under;
参考数据优先为实际值或预设值;该预设值包括标定值或与当前车辆运行状态相同状态下的历史记录值;The reference data is preferentially an actual value or a preset value; the preset value includes a calibration value or a history value in a state identical to the current vehicle running state;
例如,优选的,监控方法中参考数据和输入参数中除取预设值的参数外,其他的参数取实际值。例如:测算方法(#1)的实施示例1中,R1、im以及kekm的参考数据为预设值,其他的所有参数m2、a2、a1、Te2、Te1均为实际值;测算方法(#1)的实施示例2中,Ke、Km、R1、im、g以及f的参考数据为预设值,其他的所有参数Te3、fw、m2、θ及a均为实际值;实施例41中,Ke、Km1、im1、R1_1、Km2、Kf3、R0、im2以及R1_2为预设值,其他所有参数Te、F1、fw以及m2的参考数据为实际值。For example, in the monitoring method, in addition to the parameter of the preset value in the reference data and the input parameter, the other parameters take the actual value. For example, in the implementation example 1 of the measurement method (#1), the reference data of R1, im, and kekm are preset values, and all other parameters m2, a2, a1, Te2, and Te1 are actual values; the calculation method (#1) In the implementation example 2, reference data of Ke, Km, R1, im, g, and f are preset values, and all other parameters Te3, fw, m2, θ, and a are actual values; in Embodiment 41, Ke Km1, im1, R1_1, Km2, Kf3, R0, im2, and R1_2 are preset values, and the reference data of all other parameters Te, F1, fw, and m2 are actual values.
例如,优选的,监控方法中,当所述参考数据和输入参数中只有一个取预设值时:参考数据取预设值,输入参数全部取实际值,用于监控车辆动力传递状况是否异常;其中,参考数据所取预设值,为与当前车辆运行状态相同状态下的历史记录值;本发明中,与当前车辆运行状态相同状态下的历史记录值,指该历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值;For example, in the monitoring method, when only one of the reference data and the input parameter takes a preset value: the reference data takes a preset value, and all the input parameters take an actual value for monitoring whether the vehicle power transmission condition is abnormal; The preset value obtained by the reference data is a historical record value in the same state as the current vehicle running state; in the present invention, the historical record value in the same state as the current vehicle running state refers to the value of the historical record value. The difference between the vehicle operating condition and the current vehicle operating condition is lower than a preset threshold;
优选的,当测算对象为能够描述车辆的其中一部分的属性的参数时,车辆动力传递状况能够具体为代表该部件的状况,例如:在实施例9中kem的联合运算公式中,Kem的参考数据取预设值,输入参数全部取实际值时,可监控kem所描述的部分(如传动部件)是否异常;在实施例1中,m2的参考数据取预设值(如自学习得到),输入参数全部取实际值时,可监控m2所描述的部分(如车体是否完整或者运载物品是否掉落)的状况;如实施例11中,μ1的参考数据取预设值,输入参数 全部取实际值时,可监控μ1所代表的部分的状况(如轮胎是否突然漏气)。Preferably, when the measurement object is a parameter capable of describing an attribute of a part of the vehicle, the vehicle power transmission condition can be specifically a condition representing the part, for example, in the joint operation formula of kem in Embodiment 9, the reference data of the Kem The preset value is taken. When all the input parameters take the actual value, it is possible to monitor whether the part (such as the transmission component) described by kem is abnormal. In the embodiment 1, the reference data of m2 takes a preset value (such as self-learning), and the input is input. When all the parameters take the actual value, the condition of the part described by m2 (such as whether the vehicle body is intact or the carrying item is dropped) can be monitored; as in the embodiment 11, the reference data of μ1 takes a preset value, and the input parameter When all the actual values are taken, the condition of the part represented by μ1 (such as whether the tire suddenly leaks) can be monitored.
例如,参考数据取实际值,输入参数中有一个取预设值,用于监控输入参数中取预设值的参数是否异常;输入参数中该参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;以实施例2为例进行说明,m2的参考数据取实际值,μ1取预设值而其余的参数取实际值,则能够监控μ1是否异常;若m2的参考数据取预设值,ki取预设值而其余的参数取实际值,则能够监控ki是否异常。应当理解的是,对于取预设值的输入参数或者监控对象的异常,当该取预设值的输入参数或者监控对象为当测算对象为能够描述车辆的其中一部分的属性的参数时,车辆动力传递状况能够具体为代表该部件的状况。For example, the reference data takes an actual value, and one of the input parameters takes a preset value for monitoring whether the parameter of the input parameter takes the preset value is abnormal; the preset value of the parameter in the input parameter is the current vehicle running state. The historical value in the same state, or the calibration value when the vehicle is shipped from the factory; taking Example 2 as an example for description, the reference data of m2 takes the actual value, and μ1 takes the preset value and the remaining parameters take the actual value, which can be monitored. Whether μ1 is abnormal; if the reference data of m2 takes the preset value, ki takes the preset value and the remaining parameters take the actual value, it can monitor whether ki is abnormal. It should be understood that, for an input parameter taking a preset value or an abnormality of a monitoring object, when the input parameter or the monitoring object of the preset value is a parameter when the measurement object is an attribute capable of describing a part of the vehicle, the vehicle power The delivery condition can be specifically representative of the condition of the component.
当所述参考数据和输入参数中有N个取预设值,N≥2:When N of the reference data and the input parameters take a preset value, N≥2:
参考数据取预设值,输入参数中有N-1个取预设值,用于监控测算对象和输入参数中取预设值的参数是否异常;其中,参考数据所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;输入参数中该两个参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值;继续以实施例2为例进行说明,当m2的参考数据取预设值,输入参数中μ1取预设值而其他的参数取实际值时,能够监控m2以及μ1是否异常;当m2的参考数据取预设值,输入参数中μ1以及ki取预设值而其他的参数取实际值时,则能监控m2、μ1以及ki是否异常。The reference data takes a preset value, and N-1 of the input parameters take a preset value, which is used to monitor whether the parameter of the preset value is abnormal in the measurement object and the input parameter; wherein, the preset value of the reference data is The historical record value in the same state of the current vehicle running state, or the calibration value when the vehicle is shipped from the factory; the preset value taken by the two parameters in the input parameter is the historical record value in the same state as the current vehicle running state, or The calibration value of the vehicle when it leaves the factory; continue to use the example 2 as an example. When the reference data of m2 takes the preset value, if the input parameter takes μ1 to take the preset value and the other parameters take the actual value, can it monitor whether m2 and μ1 are Abnormal; when the reference data of m2 takes the preset value, if the input parameter μ1 and ki take the preset value and the other parameters take the actual value, it can monitor whether m2, μ1 and ki are abnormal.
例如,参考数据取实际值,输入参数中有N个取预设值,用于监控输入参数中取预设值的参数是否异常;其中,输入参数中该N个参数所取预设值,为与当前车辆运行状态相同状态下的历史记录值,或者为车辆出厂时的标定值。例如在实施例8中,当Te的参考数据取实际值,输入参数中m2、μ1、im及R1取预设值而其余的输入参数取实际值时,可以监控m2μ1、im及R1是否异常;当Te的参考数据取实际值,输入参数中m2、μ1、im、θ及R1取预设值而其余的输入参数取实际值时,可以监控m2、μ1、im、θ及R1是否异常。应当理解的是,关于参考数据与输入参数中预设值与实际值的个数与对应具体用途的关系的其他情况,本领域人员可在上述的说明及具体实施例的基础上进行,此处不再一一赘述。For example, the reference data takes an actual value, and N of the input parameters take a preset value, which is used to monitor whether the parameter of the input parameter takes the preset value is abnormal; wherein, the preset value of the N parameter in the input parameter is The historical value in the same state as the current vehicle running state, or the calibration value when the vehicle is shipped from the factory. For example, in Embodiment 8, when the reference data of Te takes the actual value, and m2, μ1, im, and R1 of the input parameter take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2μ1, im, and R1 are abnormal; When Te's reference data takes the actual value, m2, μ1, im, θ, and R1 in the input parameters take the preset value and the remaining input parameters take the actual value, it is possible to monitor whether m2, μ1, im, θ, and R1 are abnormal. It should be understood that other situations regarding the relationship between the number of preset values and actual values in the reference data and the input parameters and the specific use may be performed by those skilled in the art based on the above description and specific embodiments, where I will not repeat them one by one.
例如:E.g:
A、当该测算对象为效率系数或者包含效率系数的参数时:A. When the measured object is an efficiency coefficient or a parameter including an efficiency coefficient:
如果输入参数中所包括的滚阻系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际值;该方法可用于反映滚阻系数(也即车轮形变所导致)的异常;If the value of the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measuring object is an actual value; the method can be used to reflect the abnormality of the rolling resistance coefficient (that is, caused by the wheel deformation);
如果输入参数中所包括的滚阻系数的值为实际值,该测算对象的参考数据为车辆出厂时的标定值;If the value of the rolling resistance coefficient included in the input parameter is an actual value, the reference data of the measuring object is a calibration value when the vehicle is shipped from the factory;
B、当该测算对象为滚阻系数或者包含滚阻系数的参数时:B. When the measurement object is a rolling resistance coefficient or a parameter including a rolling resistance coefficient:
如果输入参数中所包括的效率系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际 值;该方法可用于反映效率系数(也即动力系统和/或机械传动系统异常所导致)的异常;If the value of the efficiency coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measurement object is actual. Value; this method can be used to reflect anomalies in the efficiency factor (ie, caused by abnormalities in the powertrain and/or mechanical transmission system);
如果输入参数中所包括的效率系数的值为实际值,该测算对象的参考数据为车辆出厂时的标定值;If the value of the efficiency coefficient included in the input parameter is an actual value, the reference data of the measurement object is a calibration value when the vehicle is shipped from the factory;
C、当该测算对象为车辆运行参数中除滚阻系数、包含滚阻系数的参数、效率系数、包含效率系数的参数外的其他参数时:C. When the measurement object is the vehicle running parameter except the rolling resistance coefficient, the parameter including the rolling resistance coefficient, the efficiency coefficient, and other parameters including the efficiency coefficient:
如果输入参数中所包括的效率系数和/或滚阻系数的值为车辆出厂时的标定值,该测算对象的参考数据为实际值;对应的,该方法可用于反映效率系数和/或滚阻系数(也即动力系统和/或机械传动系统异常和/或车轮形变所导致)的异常;If the value of the efficiency factor and/or the rolling resistance coefficient included in the input parameter is the calibration value when the vehicle is shipped from the factory, the reference data of the measurement object is an actual value; correspondingly, the method can be used to reflect the efficiency coefficient and/or the rolling resistance. Anomalies in coefficients (ie, caused by abnormalities in the powertrain and/or mechanical transmission system and/or wheel deformation);
如果输入参数中所包括的效率系数和滚阻系数的值为实际值,该测算对象的参考数据为与当前车辆运行状态相同状态下的历史记录值。If the values of the efficiency coefficient and the rolling resistance coefficient included in the input parameters are actual values, the reference data of the measurement object is a history value in the same state as the current vehicle running state.
例如:E.g:
所述方案A中,输入参数中除滚阻系数外的其他参数的值为标定值或实际值;In the scheme A, the values of the other parameters except the rolling resistance coefficient in the input parameter are the calibration value or the actual value;
所述方案B中,输入参数中除效率系数外的其他参数的值为标定值或实际值;In the scheme B, the value of the other parameters except the efficiency coefficient in the input parameter is a calibration value or an actual value;
所述方案C中,输入参数中除滚阻系数、效率系数外的其他参数的值为标定值或实际值。In the scheme C, the values of the other parameters except the rolling resistance coefficient and the efficiency coefficient in the input parameter are the calibration value or the actual value.
本发明所述监控方法中的参考数据中实际值(也即基准值)是从属于测算对象类型和/或实际值(也即基准值)设置方式的一个数值,是一个幅值(大小)的概念,是一个中间层数据;本发明所述监控方法中的参考数据中实际值(也即基准值)通常为与车辆的测算对象在联合运算值取值时的真实值接近或相等的数值;此处所述的通常,指大多数情况,大多数时候,该监控方法中的参考数据中实际值(也即基准值)的幅值范围可以适用于大多数类型的测算对象,如源动力参数、机械运行参数、质量变化型物品质量、在同一个“车辆由动力装置控制运行”的时间段(也即同一运行流程)中幅值变化的车辆总质量(如氢燃料电池的电动车辆或燃料动力车辆的车辆总质量)、高铁或电气列车或插电式电动汽车的车辆质量、幅值固定的车辆质量等;如实施例40、42、43所示,当监控方法中的参考数据中实际值(也即基准值)的设定方式为根据与联合运算值取值时同一时间范围内的实测值设定时,该实际值(也即基准值,也即该实测值)通常为与车辆的测算对象在联合运算值取值时的真实值接近或相等的数值;The actual value (ie, the reference value) in the reference data in the monitoring method of the present invention is a value subordinate to the setting type of the measurement object and/or the actual value (ie, the reference value), which is an amplitude (size). The concept is a middle layer data; the actual value (ie, the reference value) in the reference data in the monitoring method of the present invention is generally a value close to or equal to the true value of the measured object of the vehicle when the joint operation value is taken; Generally speaking, in most cases, most of the time, the range of amplitudes of the actual values (ie, reference values) in the reference data in the monitoring method can be applied to most types of measurement objects, such as source dynamic parameters. , mechanical operating parameters, mass-changing item quality, total mass of the vehicle in the same period of time (ie, the same operating process) in which the vehicle is controlled by the power unit (eg, electric vehicle or fuel for hydrogen fuel cells) Vehicle mass of power vehicles), vehicle quality of high-speed rail or electric trains or plug-in electric vehicles, vehicle quality of fixed amplitude, etc.; as shown in Examples 40, 42, 43 The actual value (ie, the reference value) in the reference data in the method is set according to the actual value set in the same time range as the value of the joint operation value, that is, the reference value, that is, the The measured value is usually a value close to or equal to the true value of the measured object of the vehicle when the joint operation value is taken;
如实施例34、35、36、37、38、41所示:当监控方法中的参考数据中实际值(也即基准值)的设定方式为根据(满足设定条件时)所获取的联合运算值设定时,该实际值(也即基准值)也自然为与该“(某一特定的)满足设定条件时”的联合运算值接近或相等的数值;因“(某一特定的)满足设定条件时”是用户或系统特意指定的(用于设置参考数据)的时间,通常可以默认为此时车辆工作于正常状态,该实际值(也即基准值,也即该联合运算值)通常为与在“(某一特定的)满足设定条件时”测算对象的真实值接近或相等的数值;此种监控方法中的参考数据中实际值(也即基准值)的设定方式通常适用于当测算对象为车辆质量时;当测算对象为车辆质量时,因为在同一个 的“车辆由动力装置控制运行”的时间段中车辆质量的值通常变化不大(高铁、电气列车、插电式电动汽车的质量通常不变;即使为燃料动力车辆或燃料电池车辆,燃料质量变化也是缓慢的),所以该实际值(也即基准值)的数值通常仍然可能与车辆的测算对象在(用于动力传递状况异常判断的所获取的)联合运算值取值时的真实值接近或相等;As shown in Embodiments 34, 35, 36, 37, 38, and 41: when the actual value (that is, the reference value) in the reference data in the monitoring method is set in accordance with the joint obtained according to (when the set condition is satisfied) When the calculated value is set, the actual value (that is, the reference value) is also naturally a value close to or equal to the joint operation value of "(a specific) meets the set condition"; because "(a specific "When the set condition is met" is the time specified by the user or the system (used to set the reference data). Usually, the vehicle can work in the normal state at this time. The actual value (that is, the reference value, that is, the joint operation) The value is usually a value that is close to or equal to the true value of the measurement object when "(a specific) satisfies the set condition; the setting of the actual value (ie, the reference value) in the reference data in such a monitoring method) The method is usually applied when the measurement object is the vehicle mass; when the measurement object is the vehicle mass, because it is in the same The value of vehicle mass in the period of "the vehicle is controlled by the power unit" usually does not change much (the quality of high-speed rail, electric trains, plug-in electric vehicles usually does not change; even for fuel-powered vehicles or fuel cell vehicles, fuel quality) The change is also slow), so the value of the actual value (ie, the reference value) is usually still close to the true value of the joint calculation value of the vehicle's measurement object (obtained for the abnormality judgment of the power transmission condition). Or equal;
如实施例36、37所示:当监控方法中的参考数据中实际值(也即基准值)的设定方式为根据预设值(尤其为系统默认值)设定时,该实际值(也即基准值,也即该系统默认值)通常为与该测算对象在系统默认(通常也即标准状态下)的真实值相等或接近的数值,通常为标定值;此种参考数据(标定值)的设定方式通常适用于当测算对象为系统固有参数或幅值固定的车辆质量时;当测算对象为车辆质量时(通常适用于为幅值固定的车辆质量(如无人驾驶车辆、无人驾乘车辆、运载物品质量和/或车辆总质量相对固定的车辆)时),因为该类型的车辆质量的幅值固定,所以该标定值的数值通常仍然可能与车辆的测算对象在(用于动力传递状况异常判断的所获取的)联合运算值取值时的真实值接近或相等。As shown in Embodiments 36 and 37: when the actual value (ie, the reference value) in the reference data in the monitoring method is set according to the preset value (especially the system default value), the actual value (also That is, the reference value, that is, the system default value) is usually a value equal to or close to the true value of the measurement object in the system default (usually, the standard state), usually a calibration value; such reference data (calibration value) The setting method is usually applied when the measured object is the inherent parameter of the system or the vehicle mass with fixed amplitude; when the measured object is the vehicle mass (usually applicable to the vehicle mass with fixed amplitude (such as unmanned vehicle, no one) When driving a vehicle, carrying the quality of the item and/or the vehicle with a relatively constant total mass of the vehicle), since the magnitude of the vehicle mass of this type is fixed, the value of the calibration value is usually still possible with the vehicle's measurement object (for The obtained value of the joint operation value obtained by abnormally determining the power transmission condition is close to or equal to the true value.
例如:运载物品质量的联合运算值可用m1表示,实际值可用m1_org表示或者用m1_ref表示;例如:车辆总质量的联合运算值可用m2表示,实际值可用m2_org表示;For example, the joint operation value of the quality of the carried item can be represented by m1, and the actual value can be represented by m1_org or by m1_ref; for example, the joint operation value of the total mass of the vehicle can be represented by m2, and the actual value can be represented by m2_org;
测算对象的参考数据,是指用于与测算对象的联合运算值配合进行动力传递异常判断比较的数据或数值,因为单个数据无法构成完整的比较/判断运算;联合运算值为基于车辆运动平衡计算公式计算所得的结果;本文中所述参考数据,也可称为参考值,两者等同;本文中所述参考数据包括或为动力传递状况识别数据;所述动力传递状况识别数据包括或为动力传递状况识别差值、动力传递状况识别值中任意一种或两种数据;为了描述简便,本文中所述动力传递状况识别值也可称为第二许可范围;本文中所述动力传递状况识别差值也可称为第一许可范围;显而易见的,本发明中测算对象的参考数据或参考数据所包括的数据均需设置为用于为与基于车辆运动平衡计算公式计算所得的测算对象的联合运算值配合进行动力传递异常判断的数据;参考数据为能实现该用途的合理的数据;根据测算对象、车辆运动平衡计算公式、车辆运动平衡计算公式的输入参数的设置方法中任意一点或多点的不同,设置相对应的测算对象的参考数据。The reference data of the measurement object refers to the data or value used for the comparison of the power transmission abnormality judgment with the joint operation value of the measurement object, because the single data cannot constitute a complete comparison/judgment operation; the joint operation value is calculated based on the vehicle motion balance calculation. The formula calculates the result; the reference data described herein may also be referred to as a reference value, which are equivalent; the reference data described herein includes or is the power transmission condition identification data; the power transmission condition identification data includes or is powered Passing any one or two of the difference between the status identification difference and the power transmission status identification value; for ease of description, the power transmission status identification value described herein may also be referred to as the second permission range; the power transmission status identification described herein The difference value may also be referred to as a first permission range; obviously, the reference data of the measurement object or the data included in the reference data in the present invention are required to be set as a combination for the calculation object calculated based on the vehicle motion balance calculation formula. The calculated value is combined with the data for the power transmission abnormality judgment; the reference data is real Reasonable data for the purpose; the reference data of the corresponding measurement object is set according to any one or more points in the setting method of the input parameter of the calculation object, the vehicle motion balance calculation formula, and the vehicle motion balance calculation formula.
综合而言,参考数据或输入参数中所包括的的路面坡度θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信息计算所得或传感器测量数据获取;In general, the value of any one or more of the road surface gradient θ, the rolling resistance coefficient f, and the road condition-related rolling resistance component fr included in the reference data or the input parameter may be based on the position information of the road. Calculated or sensor measurement data acquisition;
通过对车辆的动力传递状况进行深入研究分析:车辆的运行实质就是能量传递和动力传递过程;动力传递过程的状况的简称即为动力传递状况;车辆由动力装置驱动运行时,先从能源供应装置(燃料供应装置或电源装置)将能源传送到动力装置(燃料发动机或电机),动力装置将能源转化为动力,再经机械传动系统逐级传递,进而驱动车辆移动;车辆的能源供应装置和动力装置代表动力的供应 者,机械传动系统代表动力的传递者,被驱动的车辆(连同装载的人员和物品)代表动力的受体;Through in-depth study and analysis of the vehicle's power transmission status: the vehicle's operation is essentially the energy transmission and power transmission process; the short name of the power transmission process is the power transmission condition; when the vehicle is driven by the power unit, the energy supply device is first (fuel supply device or power supply device) transmits energy to a power device (fuel engine or motor), which converts energy into power, and then passes through the mechanical transmission system to drive the vehicle to move; the energy supply device and power of the vehicle Device represents the supply of power The mechanical transmission system represents the transmitter of the power, and the driven vehicle (along with the loaded personnel and items) represents the power receptor;
在车辆运动平衡计算中,车辆源动力参数代表动力的供应信息,车辆质量代表动力受体最基本属性,车辆的系统运行参数代表动力传递的基础条件和车辆在动力作用下产生的运动结果(如纵向速度、纵向加速度等);In the calculation of vehicle motion balance, the vehicle source dynamic parameter represents the supply information of the power, the vehicle mass represents the most basic attribute of the power receiver, and the system operating parameters of the vehicle represent the basic conditions of the power transmission and the motion results generated by the vehicle under the action of the power (eg Longitudinal speed, longitudinal acceleration, etc.);
如果车辆的旋转工作型动力或传动部件在高速运行中发生异常磨损或变形/运行阻力增大/效率变低时,因为源动力参数所代表的能量(或动力)的能量的异常损耗增多:假如监控系统以源动力参数作为测算对象,则在其他相关的车辆运行条件(如车辆质量、路面坡度、风阻、纵向速度、纵向加速度等)不变时,可能要耗费更多的能量或动力而造成源动力参数的实际值与车辆运动平衡计算所得联合运算值的偏差值增大;假如监控系统以机械运行参数中纵向速度作为测算对象,如车辆输出的动力也即源动力参数的实际值不变以及其他相关的车辆运行条件(如车辆质量、路面坡度、风阻、纵向加速度等)不变时,则可能导致车辆的纵向速度的实际值与车辆运动平衡计算所得联合运算值的偏差值增大;假如以车辆质量作为测算对象以及其他相关的车辆运行条件(如路面坡度、风阻、纵向加速度等)不变时,则当动力也即源动力参数的实际值增大时/或者车辆的纵向速度的实际值降低时,则将导致车辆运动平衡计算所得车辆质量联合运算值变化;所以通过将测算对象的联合运算值与参考数据进行比较,就可判断出所述车辆运行中的动力传递状况是否异常,并且通过后续的动力传递状况判断后的处理步骤可及时实现动力传递异常监控和预警;If the rotational working power or transmission components of the vehicle are abnormally worn or the deformation/running resistance increases/efficiency becomes high during high-speed operation, the abnormal loss of energy (or power) represented by the source dynamic parameters increases: The monitoring system uses the source dynamic parameters as the measurement object, and may consume more energy or power when other relevant vehicle operating conditions (such as vehicle mass, road gradient, wind resistance, longitudinal speed, longitudinal acceleration, etc.) are constant. The deviation between the actual value of the source dynamic parameter and the joint operation value calculated by the vehicle motion balance is increased; if the monitoring system uses the longitudinal velocity in the mechanical operating parameter as the measurement object, such as the power output of the vehicle, that is, the actual value of the source dynamic parameter remains unchanged. And other related vehicle operating conditions (such as vehicle mass, road grade, wind resistance, longitudinal acceleration, etc.) may be the same, which may result in an increase in the deviation between the actual value of the longitudinal speed of the vehicle and the joint calculated value of the vehicle motion balance calculation; If the vehicle mass is used as the calculation target and other related vehicle operating conditions (such as road surface) When the slope, wind resistance, longitudinal acceleration, etc. are constant, when the actual value of the power, that is, the source dynamic parameter increases, or the actual value of the longitudinal speed of the vehicle decreases, the vehicle mass joint calculation of the vehicle motion balance calculation will be caused. The value changes; therefore, by comparing the joint operation value of the measurement object with the reference data, it can be determined whether the power transmission condition in the vehicle operation is abnormal, and the processing step after the subsequent power transmission condition determination can realize the power in time. Deliver abnormal monitoring and warning;
虽然效率系数、滚阻系数(尤其为其中的与车辆相关的滚阻系数分量fc)在车辆运行过程中不便实测,但如果车辆运动平衡计算公式包含效率系数和/或滚阻系数(尤其为其中的fc),则可将其用于车辆的动力传递状况的识别或监控,也即用于动力传递异常监控;有如下两种方式:Although the efficiency coefficient and the rolling resistance coefficient (especially the rolling factor component fc associated with the vehicle therein) are inconvenient to measure during vehicle operation, if the vehicle motion balance calculation formula includes the efficiency coefficient and/or the rolling resistance coefficient (especially for Fc), it can be used for the identification or monitoring of the power transmission status of the vehicle, that is, for power transmission abnormal monitoring; there are two ways:
识别方式1:以效率系数或包含效率系数的参数或滚阻系数(尤其为其中的fc)或包含滚阻系数的参数为测算对象,建立(通常为预设)该测算对象的用于动力传递状况识别的第二范围,基于车辆运动平衡计算公式得出测算对象的计算结果(也即联合运算值),比较该计算结果是否超出第二范围;该计算结果超出第二范围为动力传递异常;Identification method 1: The efficiency coefficient or the parameter including the efficiency coefficient or the rolling resistance coefficient (especially fc) or the parameter including the rolling resistance coefficient is used as the measurement object, and the (usually preset) measurement object is used for power transmission. a second range of condition recognition, based on a vehicle motion balance calculation formula, obtaining a calculation result of the measurement object (that is, a joint operation value), and comparing whether the calculation result exceeds a second range; the calculation result exceeding the second range is a power transmission abnormality;
识别方式2:或基于车辆运动平衡计算公式计算某测算对象,且在该计算的输入参数中包括效率系数和/或滚阻系数,将该测算对象基于车辆运动平衡计算公式所得的计算结果与用于动力传递状况识别的第二范围比较,比较该计算结果是否超出该第二范围;该计算结果超出该第二范围为动力传递异常。Identification method 2: or calculating a certain measurement object based on the vehicle motion balance calculation formula, and including the efficiency coefficient and/or the rolling resistance coefficient in the calculated input parameter, and calculating the calculation result based on the vehicle motion balance calculation formula Comparing the second range of power transmission condition identification, comparing whether the calculation result exceeds the second range; the calculation result exceeding the second range is a power transmission abnormality.
根据前文研究分析所得的效率系数、滚阻系数的实质含义,该两参数是指示车辆安全状况非常关键的参数;无论如何,在以动力传递状况监控为目的车辆运动平衡计算公式最好同时包括滚阻系数和效率系数(无论是作为测算对象或输入参数),方能较好实现目的;如果采用(m2=ΔF/Δa)的仅仅包含效率系数的车辆运动平衡计算公式则将无法监控车轮形变(失圆度)和/或车轮磨损的状况;如果车辆运动平衡计算公式不包括效率系数则无法监控待监控的动力传动部件的磨损和/或安全的 状况;待监控的动力传动部件、车轮中,大部分器件均工作于旋转状态,均可属于旋转工作型动力或传动部件。当然,如果该待监控的动力部件中包括能源供应装置(例如电源装置、燃料供应系统)或动力控制装置(例如电机驱动装置、)不属于工作于旋转状态。According to the actual meaning of the efficiency coefficient and the rolling resistance coefficient obtained from the previous study, the two parameters are parameters that indicate the safety status of the vehicle. In any case, the calculation formula of the vehicle motion balance for the purpose of monitoring the power transmission condition preferably includes rolling. The resistance coefficient and the efficiency coefficient (whether as the object of measurement or input parameters) can better achieve the purpose; if the vehicle motion balance calculation formula containing only the efficiency coefficient (m2=ΔF/Δa) will not be able to monitor the wheel deformation ( Out-of-roundness) and/or condition of wheel wear; if the vehicle motion balance calculation formula does not include the efficiency factor, the wear and/or safety of the power transmission components to be monitored cannot be monitored. Condition; most of the components of the power transmission components and wheels to be monitored are in a rotating state, and all of them belong to the rotary working power or transmission components. Of course, if the power supply to be monitored includes an energy supply device (such as a power supply device, a fuel supply system) or a power control device (such as a motor drive device), it does not belong to a rotating state.
显而易见的,本发明动力传递状况,包括车辆中与动力的传递相关的系统的运行状况和/或运行环境的状况;车辆中与动力的传递相关的系统包括待监控的动力传动部件和/或第二车轮;第二车轮和/或传动部件中所包括的驱动轮均可称为车轮;该系统,尤其指旋转工作型动力或传动部件;车辆中与动力的传递相关的系统的运行状况,尤其指待监控的动力传动部件的动力传递的效率状况(也即效率系数的大小)和/或车轮的滚动阻力系数(尤其为其中的与车辆相关的滚阻系数分量fc)的大小。It will be apparent that the power transmission conditions of the present invention include the operating conditions of the system in the vehicle related to the transmission of power and/or the conditions of the operating environment; the system associated with the transmission of power in the vehicle includes power transmission components to be monitored and/or The two wheels; the drive wheels included in the second wheel and/or the transmission component may be referred to as wheels; the system, in particular, the rotary working power or transmission components; the operating conditions of the system associated with the transmission of power in the vehicle, in particular The magnitude of the efficiency condition of the power transmission of the power transmission component to be monitored (ie the magnitude of the efficiency factor) and/or the rolling resistance coefficient of the wheel, in particular the rolling factor component fc associated with the vehicle therein.
显而易见的,本发明动力传递状况异常,包括车辆中与动力的传递相关的系统的运行状况的异常和/或车辆运行环境异常;该车辆中与动力的传递相关的系统的运行状况的异常也即动力传递故障;车辆中与动力的传递相关的系统的运行状况的异常包括待监控的动力传动部件的动力传递的效率系数异常,和/或车轮的滚动阻力系数异常(尤其为其中的与车辆相关的滚阻系数分量fc异常);Obviously, the power transmission condition of the present invention is abnormal, including an abnormality of the operating condition of the system related to the transmission of power in the vehicle and/or an abnormality of the operating environment of the vehicle; an abnormality of the operating condition of the system related to the transmission of the power in the vehicle is Power transmission failure; anomalies in the operating conditions of the system related to the transmission of power in the vehicle include an abnormality in the efficiency of the power transmission of the power transmission component to be monitored, and/or an abnormality in the rolling resistance coefficient of the wheel (especially for the vehicle related thereto) The rolling resistance coefficient component fc is abnormal);
例如:当待监控的动力传动部件中某一机械轴或齿轮,当其断裂或卡死则意味着其动力传递的效率系数为零(彻底失效);当其磨损程度超过预设范围时则其运行阻力加大、发热增大,该机械轴或齿轮失效概率将迅速增高,而此特征可用效率系数低于某一用于衡量早期故障的预设值来衡量与评估;例如当待监控的动力传动部件中某一电气元件(例如IGBT模块),当其短路或断路或炸机时则意味着其动力传递的效率系数为零;当其内阻变大超过预设范围时,其输出功率降低、发热增大、IGBT失效概率将迅速增高,而此特征可用效率系数低于某一用于衡量早期故障的预设值来衡量与评估;等;所以动力传递的效率状况,可用于反映、分析车辆的动力系统安全状况,两者密切相关;可用于发现、监控待监控的动力传动部件的彻底失效,尤其可用于发现、监控待监控的动力传动部件的早期故障;For example, when a mechanical shaft or gear in the power transmission component to be monitored is broken or stuck, it means that the efficiency coefficient of power transmission is zero (complete failure); when the degree of wear exceeds the preset range, As the running resistance increases and the heat increases, the probability of failure of the mechanical shaft or gear will increase rapidly, and this feature can be measured and evaluated with an efficiency coefficient lower than a preset value used to measure early faults; for example, when the power to be monitored An electrical component (such as an IGBT module) in a transmission component, when it is short-circuited or broken or bombed, means that its power transmission efficiency coefficient is zero; when its internal resistance becomes larger than a preset range, its output power is reduced. Increased heat generation, IGBT failure probability will increase rapidly, and this feature can be used to measure and evaluate the efficiency coefficient lower than a preset value used to measure early faults; etc.; therefore, the efficiency of power transmission can be used to reflect and analyze The safety status of the vehicle's power system is closely related; it can be used to discover and monitor the complete failure of the power transmission components to be monitored, especially for the discovery and monitoring of the fire. Early failure of a power transmission member;
车轮的滚动阻力系数异常(尤其为其中的与车辆相关的滚阻系数分量fc异常)通常指车轮形变(失圆度)超过预设范围和/或车轮磨损超过预设范围,也可用车轮的滚动阻力系数高于某一用于衡量早期故障的预设值来衡量与评估;车轮的滚动阻力系数的大小,也可用于反映、分析车辆的运行安全状况,两者密切相关;The abnormal rolling resistance coefficient of the wheel (especially the abnormality of the rolling resistance coefficient component fc related to the vehicle therein) generally means that the wheel deformation (out of roundness) exceeds a preset range and/or the wheel wear exceeds a preset range, and the rolling of the wheel can also be used. The drag coefficient is higher than a certain preset value for measuring early faults to measure and evaluate; the rolling resistance coefficient of the wheel can also be used to reflect and analyze the operational safety of the vehicle, which are closely related;
本发明所提供的一种车辆由动力装置控制运行时的监控方法(#1)或监控方法(#2)或监控方法(#3)及系统的有益效果:The utility model provides a monitoring method (#1) or a monitoring method (#2) or a monitoring method (#3) and a system beneficial effect when a vehicle is controlled by a power device:
综合而言,本发明所提供的技术方案,可用于发现、监控待监控的动力传动部件的动力传递的效率系数异常和/或车轮的滚动阻力系数异常所导致的动力传递异常;也即可用于发现、监控待监控的动力传动部件和/或第二车轮的失效所导致的动力传递异常,和/或用于发现、监控待监控的动力 传动部件和/或第二车轮的早期故障所导致的动力传递异常;本发明提供的技术方案,可用于发现、监控(包括车辆的旋转工作型动力或传动部件运行故障所导致的)车辆动力传递异常;也即本发明提供的技术方案,尤其可用于发现、监控车辆的旋转工作型动力或传动部件运行故障;即使当车辆运行参数未超过安全极限阈值时,本发明提供的技术方案也可便于尽量避免发生更严重的、不可预测的安全事故(包括断轴、车毁人亡等);如同人体医学的癌症诊断,如果晚期才发现通常意味生命终结,如果能早期预警、早期发现通常意味生命正常存活;所以本技术方案对于车辆的安全运行具有重要的实际意义。In summary, the technical solution provided by the present invention can be used to discover and monitor an abnormality of an efficiency coefficient of power transmission of a power transmission component to be monitored and/or an abnormality of power transmission caused by an abnormality of a rolling resistance coefficient of a wheel; Discovering, monitoring power transmission anomalies caused by failure of the power transmission components to be monitored and/or the second wheel, and/or for discovering and monitoring the power to be monitored The power transmission abnormality caused by the early failure of the transmission component and/or the second wheel; the technical solution provided by the present invention can be used for discovering, monitoring, and including the vehicle power transmission caused by the rotating working power of the vehicle or the operation failure of the transmission component Abnormal; that is, the technical solution provided by the present invention can be especially used for discovering and monitoring the rotating working type power of the vehicle or the running failure of the transmission component; the technical solution provided by the present invention can be facilitated even when the vehicle operating parameter does not exceed the safety limit threshold. Try to avoid more serious and unpredictable safety accidents (including broken shafts, car crashes, etc.); like human medical cancer diagnosis, if it is found in the late stage, it usually means the end of life. If early warning, early detection usually means life. Normal survival; therefore, the technical solution has important practical significance for the safe operation of the vehicle.
本发明所提供的技术方案,不仅仅便于进行动力系统、旋转工作型动力或传动部件的动力传递异常监控;相较于依靠气压或轮速变化进行胎压监控的现有技术,本发明技术方案可以包含检测轮胎形变导致的运行力变化的监控方案,提供了一种新的充气轮胎的安全监控技术,还填补了现有的胎压监控方案不便于监控车辆(如高铁车辆、动车、普通列车、履带式车辆等)的刚性车轮(包括驱动轮)的监控盲区。The technical solution provided by the invention not only facilitates abnormal monitoring of power transmission of the power system, the rotary working power or the transmission component; and the technical solution of the invention is compared with the prior art that the tire pressure monitoring is performed by the air pressure or the wheel speed change. It can include a monitoring scheme to detect changes in the operating force caused by tire deformation, provide a new safety monitoring technology for pneumatic tires, and fill the existing tire pressure monitoring scheme to make it difficult to monitor vehicles (such as high-speed rail vehicles, motor trains, and ordinary trains). , tracked vehicles, etc.) The monitoring blind zone of rigid wheels (including drive wheels).
根据所述获取的联合运算值和所述测算对象的参考数据判断所述车辆的动力传递状况是否异常,是本发明方案的核心步骤之一;动力传递状况异常可简称为动力传递异常;Determining whether the power transmission condition of the vehicle is abnormal according to the acquired joint operation value and the reference data of the measurement object is one of the core steps of the solution of the present invention; the power transmission condition abnormality may be simply referred to as a power transmission abnormality;
本发明所述动力传递异常包括下述1A1、1A2中任意一种或多种情况:The power transmission abnormality of the present invention includes any one or more of the following 1A1, 1A2:
1A1.所述测算对象的联合运算值与所述实际值(也即基准值)的差值超出第一许可范围(也即动力传递状况识别差值);本发明中任意方案中,为了便于本领域技术人员理解,当测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时,当测算对象的参考数据为或包括实际值(也即基准值)时,该实际值还允许使用标定值替换;1A1. The difference between the joint operation value of the measurement object and the actual value (that is, the reference value) exceeds the first permission range (that is, the power transmission condition recognition difference value); in any aspect of the present invention, in order to facilitate the present invention Those skilled in the art understand that when the measurement object is any of the unmeasured parameters and/or the preset parameters and/or the system inherent parameters, when the reference data of the measurement object is or includes the actual value (ie, the reference value), This actual value also allows replacement with the calibration value;
1A2.所述测算对象的联合运算值超出第二许可范围(也即动力传递状况识别值);1A2. The joint operation value of the measurement object exceeds the second permission range (that is, the power transmission status identification value);
通常来说,用作动力传递状况判断的动力传递状况识别数据的设置原理、设置方式是相同的;第二许可范围(也即动力传递状况识别值也即动力传递状况的识别范围)可根据测算对象的实际值(也即基准值)设定;此处所述通常,指大多数测算对象类型,第二许可范围可根据实际值(也即基准值)设定;第二许可范围可尽量接近该实际值(也即基准值)以提高监控的灵敏度,但又须与该实际值(也即基准值)保持某个数量的差值以降低监控的误触发率;所述某个数量的差值即为第一许可范围(也即动力传递状况识别差值也即动力传递状况的识别差值也即第一偏差值);Generally, the setting principle and setting manner of the power transmission condition identification data used for the power transmission condition determination are the same; the second permission range (that is, the power transmission status identification value, that is, the identification range of the power transmission status) can be calculated according to the calculation. The actual value of the object (that is, the reference value) is set; generally speaking, it refers to most types of measurement objects, and the second permission range can be set according to the actual value (that is, the reference value); the second permission range can be as close as possible The actual value (ie, the reference value) to increase the sensitivity of the monitoring, but must maintain a certain amount of difference with the actual value (ie, the reference value) to reduce the false trigger rate of the monitoring; The value is the first permitted range (that is, the power transmission condition identification difference, that is, the identification difference of the power transmission condition, that is, the first deviation value);
综合而言,动力传递异常也即基于车辆运动平衡计算公式计算所得的结果超出预设的范围;该范围即第二许可范围,也即用于动力传递状况的识别的范围,也即用于分析、识别车辆中与动力的传递相关的系统的运行状况的范围;In general, the power transmission anomaly, that is, the calculation result based on the vehicle motion balance calculation formula exceeds a preset range; the range is the second permission range, that is, the range for identification of the power transmission condition, that is, for analysis Identifying the range of operating conditions of the system related to the transmission of power in the vehicle;
参考数据的典型设置方案如下:The typical setting scheme for the reference data is as follows:
1、当所述测算对象为需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时:所述测算对象的参考数据包括实际值或为实际值,或所述参 考数据包括实际值和第一许可范围,或所述参考数据为实际值和第一许可范围,或所述参考数据包括第二许可范围或为第二许可范围;1. When the measurement object is any one of a parameter to be measured and/or a measurable parameter and/or a source dynamic parameter and/or a mechanical operation parameter and/or a quality change item quality: the measurement object Reference data includes actual values or actual values, or the reference The test data includes an actual value and a first license range, or the reference data is an actual value and a first license range, or the reference data includes a second license range or a second license range;
第一许可范围为根据预设值设定;第二许可范围可由实际值与第一许可范围组成;第二许可范围=实际值+第一许可范围;该实际值、第二许可范围中任意一种或多种数据为根据实测值设定,且所述参考数据(实际值和/或第二许可范围)的取值时间与所述联合运算值的取值时间在预设的时间范围内;或:该实际值、第二许可范围中任意一种或多种数据为根据测算对象的历史记录值设定,所述历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值。The first permission range is set according to a preset value; the second permission range may be composed of the actual value and the first permission range; the second permission range=actual value+first permission range; any one of the actual value and the second permission range And the data is set according to the measured value, and the time value of the reference data (actual value and/or the second permission range) and the value of the joint operation value are within a preset time range; Or: any one or more of the actual value and the second permitted range are set according to a historical record value of the measured object, and the difference between the running condition of the historical recorded value and the current running condition of the vehicle The degree is below the preset threshold.
2、当所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时:2. When the measurement object is any one of unmeasured parameters and/or preset parameters and/or system inherent parameters:
所述测算对象的参考数据包括第二许可范围或为第二许可范围;第二许可范围为根据预设值或满足设定条件时所进行车辆运动平衡计算所获取的联合运算值设定;The reference data of the measurement object includes a second permission range or a second permission range; and the second permission range is a joint operation value setting obtained according to the preset value or the vehicle motion balance calculation performed when the set condition is satisfied;
或所述参考数据包括标定值或为标定值;标定值为根据预设值或满足设定条件时所进行车辆运动平衡计算所获取的联合运算值设定;Or the reference data includes a calibration value or a calibration value; the calibration value is a joint operation value setting obtained according to a preset value or a vehicle motion balance calculation performed when the set condition is satisfied;
或所述参考数据包括标定值和第一许可范围,或所述参考数据为标定值和第一许可范围;第一许可范围为根据预设值设定;标定值为根据预设值或满足设定条件时所进行车辆运动平衡计算所获取的联合运算值设定;Or the reference data includes a calibration value and a first permission range, or the reference data is a calibration value and a first permission range; the first permission range is set according to a preset value; and the calibration value is according to a preset value or a satisfaction setting. The joint operation value obtained by calculating the vehicle motion balance calculated when the condition is determined;
第二许可范围可由标定值与第一许可范围组成;第二许可范围=标定值+第一许可范围;The second license range may be composed of the calibration value and the first license range; the second license range=calibration value + first license range;
3、当所述测算对象为车辆质量中任一参数时:所述测算对象的参考数据包括实际值或为实际值,或所述参考数据包括第二许可范围或为第二许可范围,或所述参考数据包括实际值和第一许可范围,或所述参考数据为实际值和第一许可范围;3. When the measurement object is any one of the vehicle quality: the reference data of the measurement object includes an actual value or an actual value, or the reference data includes a second permission range or a second permission range, or The reference data includes an actual value and a first permitted range, or the reference data is an actual value and a first permitted range;
车辆质量的实际值可由多种方式设定;例如由人工输入车辆当次运行的运载物品质量m1或车辆总质量m2的实际值;实际值也可根据实测值设定;例如在车辆上设置称重传感器测量运载物品质量;也可由人工输入车辆质量的第二许可范围;第一许可范围为根据预设值设定;第二许可范围由实际值与第一许可范围组成;第二许可范围=实际值+第一许可范围;The actual value of the vehicle quality can be set in various ways; for example, the actual value of the mass of the carrying item m1 or the total mass m2 of the vehicle that is manually operated by the manual input; the actual value can also be set according to the measured value; for example, setting on the vehicle The weight sensor measures the quality of the carried item; the second permitted range of the vehicle quality may also be manually input; the first permitted range is set according to the preset value; the second permitted range is composed of the actual value and the first permitted range; the second permitted range = Actual value + first license range;
优选的,Preferably,
4A1.车辆质量的实际值、第二许可范围中任意一种或多种数据为根据满足设定条件时所进行车辆运动平衡计算获取的联合运算值设定;或,4A1. Any one or more of the actual value of the vehicle mass and the second permitted range is set according to the joint operation value obtained by calculating the vehicle motion balance calculated when the set condition is satisfied; or
4A2.车辆质量的中实际值、第二许可范围中任意一种或多种数据为根据历史记录值设定;或,4A2. Any one or more of the actual value of the vehicle quality and the second permitted range are set according to the historical value; or
4A3.车辆质量的中实际值、第二许可范围中任意一种或多种数据为根据预设值设定。4A3. Any one or more of the actual value of the vehicle quality and the second permitted range are set according to the preset value.
测算对象的第二许可范围(也即动力传递状况识别值)可以根据测算对象的实际值(也即基准值)与第一许可范围(也即动力传递状况识别差值)计算而得,或者说第一许可范围(也即动力传递状况识别差值)可以根据第二许可范围(也即动力传递状况识别值)和实际值(也即基准值)计 算而得;动力传递异常包括的1A1、1A2中两种情况,从实际技术方案与效果来说,1A1等同于1A2,只是参数输入值不同,描述方式不同而已;The second permitted range of the measurement object (that is, the power transmission condition identification value) may be calculated according to the actual value (ie, the reference value) of the measurement object and the first permission range (ie, the power transmission condition recognition difference value), or The first permitted range (ie, the power transmission condition identification difference value) may be based on the second permitted range (ie, the power transmission condition identification value) and the actual value (ie, the reference value). In the case of 1A1 and 1A2, the power transmission anomaly includes 1A1, which is equivalent to 1A2 in terms of actual technical solutions and effects, except that the parameter input values are different and the description manners are different;
本发明的核心思想之一就是将某一测算对象的联合运算值与根据该测算对象的实际值(也即基准值)而设定的参考数据进行(实时)比较、(实时)处理判断结果;换一种实现方式:根据联合运算值设定可包含动力传递状况识别数据的参考数据2(也可称为第二参考数据),再将该参考数据2(也即第二参考数据)与测算对象的实际值(也即基准值)进行实时比较、实时处理判断结果,也是可行的;也即判断所述实际值(也即基准值)是否大于根据联合运算值设定的上限值,和/或判断所述实际值(也即基准值)是否小于根据联合运算值设定的下限值;该两种方式仅为外在表现形式不一样,实际上技术方案、效果等同;该根据联合运算值设定的上限值和/或根据联合运算值设定的下限值也即第二范围;优选的,该第二许可范围在安全范围之内;One of the core ideas of the present invention is to compare (real-time) the joint operation value of a certain measurement object with the reference data set according to the actual value (that is, the reference value) of the measurement object, and process the determination result in real time; Alternatively, the reference data 2 (which may also be referred to as second reference data), which may include the power transmission condition identification data, is set according to the joint operation value, and the reference data 2 (ie, the second reference data) is further calculated. It is also feasible to perform real-time comparison and real-time processing of the judgment result of the actual value of the object (that is, the reference value); that is, whether the actual value (that is, the reference value) is greater than the upper limit value set according to the joint operation value, and And/or determining whether the actual value (that is, the reference value) is less than a lower limit value set according to the joint operation value; the two modes are only different from the external representation, and the technical solution and the effect are equivalent; The upper limit value of the calculated value setting and/or the lower limit value set according to the joint operation value, that is, the second range; preferably, the second permission range is within the safe range;
其中,所述动力传递状况识别差值(也即第一许可范围)包括动力传递状况识别上限差值、动力传递状况识别下限差值中任意一个或多个数据;所述动力传递状况识别值(也即第二许可范围)包括动力传递状况识别上限值、动力传递状况识别下限值中任意一个或多个数据;本发明所述超出(也即超过)包括大于某个上限值、小于某个下限值等任意一种或多种情况;为了描述简便,本文中动力传递状况识别上限差值也可称为第一许可上限值,动力传递状况识别下限差值也可称为第一许可下限值,动力传递状况识别上限值也可称为第二许可上限值,动力传递状况识别下限值也可称为第二许可下限值;The power transmission condition identification difference value (that is, the first permission range) includes any one or more of a power transmission condition recognition upper limit difference and a power transmission condition recognition lower limit difference; and the power transmission status identification value ( That is, the second permission range includes any one or more of the power transmission condition recognition upper limit value and the power transmission condition recognition lower limit value; and the excess (ie, exceeding) of the present invention includes greater than a certain upper limit value and less than Any one or more of a certain lower limit value; for the sake of simplicity of description, the upper limit difference of the power transmission condition identification in this paper may also be referred to as the first permissible upper limit value, and the difference in the lower limit of the power transmission condition identification may also be referred to as the first The permissible lower limit value, the power transmission status identification upper limit value may also be referred to as a second permissible upper limit value, and the power transmission status identification lower limit value may also be referred to as a second permissible lower limit value;
所述1A1情况,具体可包括下述1A11、1A12中任意一种或两种情况;The case of the 1A1 may specifically include any one or two of the following 1A11 and 1A12;
1A11.测算对象的联合运算值与实际值(也即基准值)的差值大于动力传递状况识别上限差值(也即第一许可上限值);1A11. The difference between the joint operation value of the measurement object and the actual value (ie, the reference value) is greater than the power transmission condition recognition upper limit difference (that is, the first permission upper limit value);
1A12.测算对象的联合运算值与实际值(也即基准值)的差值小于动力传递状况识别下限差值(也即第一许可下限值);1A12. The difference between the joint operation value of the measurement object and the actual value (ie, the reference value) is less than the difference between the lower limit of the power transmission condition recognition (that is, the first permission lower limit value);
所述1A2情况,具体可包括下述1A21、1A22中任意一种或两种情况;The case of the 1A2 may specifically include any one or two of the following 1A21 and 1A22;
1A21.测算对象的联合运算值大于动力传递状况识别上限值(也即第二许可上限值);1A21. The joint operation value of the measurement object is greater than the upper limit value of the power transmission condition recognition (that is, the second permission upper limit value);
1A22.测算对象的联合运算值小于动力传递状况识别下限值(也即第二许可下限值);1A22. The joint operation value of the measurement object is smaller than the power transmission condition recognition lower limit value (that is, the second permission lower limit value);
综合上述内容,显而易见的,判断车辆的动力传递状况是否异常可包括下述任意一种或多种方式:In summary, it is obvious that determining whether the power transmission condition of the vehicle is abnormal may include any one or more of the following methods:
2A1.测算对象的参考数据包括第一许可上限值和实际值(也即基准值);判断测算对象的联合运算值与实际值(也即基准值)的差值是否大于第一许可上限值;2A1. The reference data of the measurement object includes a first permission upper limit value and an actual value (ie, a reference value); and determining whether a difference between the joint operation value of the measurement object and the actual value (that is, the reference value) is greater than the first permission upper limit value;
2A2.测算对象的参考数据包括第一许可下限值和实际值(也即基准值);判断测算对象的联合运算值与实际值(也即基准值)的差值是否小于第一许可下限值;2A2. The reference data of the measurement object includes a first permission lower limit value and an actual value (that is, a reference value); and determining whether a difference between the joint operation value of the measurement object and the actual value (that is, the reference value) is less than the first permission lower limit value;
2A3.测算对象的参考数据包括实际值(也即基准值);判断测算对象的实际值(或标定值)是 否大于根据联合运算值设定的上限值;2A3. The reference data of the measurement object includes the actual value (that is, the reference value); determining the actual value (or calibration value) of the measurement object is No greater than the upper limit set according to the joint operation value;
2A4.测算对象的参考数据包括实际值(也即基准值);判断测算对象的实际值(或标定值)是否小于根据联合运算值设定的下限值;2A4. The reference data of the measurement object includes an actual value (ie, a reference value); and whether the actual value (or the calibration value) of the measurement object is less than a lower limit value set according to the joint operation value;
2A5.测算对象的参考数据包括第二许可上限值;判断测算对象的联合运算值是否大于第二许可上限值;2A5. The reference data of the measurement object includes a second permission upper limit value; determining whether the joint operation value of the measurement object is greater than the second permission upper limit value;
2A6.测算对象的参考数据包括第二许可下限值;判断测算对象的联合运算值是否小于第二许可下限值。2A6. The reference data of the measurement object includes a second permission lower limit value; and whether the joint operation value of the measurement object is smaller than the second permission lower limit value.
本发明中任意方案中,为了便于本领域技术人员理解,当测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时,当测算对象为或包括实际值(也即基准值)时,该实际值还允许使用标定值替换。In any aspect of the present invention, in order to facilitate the understanding by those skilled in the art, when the measurement object is any of the unmeasured parameters and/or the preset parameters and/or the system inherent parameters, when the measurement object is or includes the actual value ( This actual value also allows replacement with the calibration value when the reference value is also used.
本发明允许测算对象的动力传递状况识别值(也即第二许可范围)在测算对象的安全极限阈值的范围之内;可以突破现有公知技术在车辆运行参数未超出安全极限阈值时不便于进行安全监控的局限,详情见下述示例1、示例2,该部分内容为参考数据的值域设定的较优规则;The invention allows the power transmission condition identification value (that is, the second permission range) of the measurement object to be within the range of the safety limit threshold of the measurement object; it can be broken by the prior art that the vehicle operation parameter does not exceed the safety limit threshold. For the limitations of security monitoring, see Example 1, Example 2 below, which is the preferred rule set by the value range of the reference data;
示例1:如以车辆纵向速度为测算对象,假设其(上限)安全极限阈值为200KM/H(显而易见的,该值为安全极限阈值中最大值;该参数的安全极限阈值中最小值通常为0;),假设车辆以纵向速度60KM/H运行时,则实际值通常设为60KM/H,则动力传递状况识别差值通常会设置为10-20KM/H之间,则动力传递状况识别上限值(也即第二许可上限值)通常会设置为70-80KM/H之间,则动力传递状况识别下限值(也即第二许可下限值)通常会设置为40-50KM/H之间;则只要车辆纵向运行速度的联合运算值大于动力传递状况识别上限值(也即第二许可上限值)或小于动力传递状况识别下限值(也即第二许可下限值),所述动力传递状况判断结果将为异常,从而可以实现监控保护;而此时测算对象远未超过安全极限阈值(显而易见的,也即此时该测算对象的动力传递状况识别上限值(也即第二许可上限值)远小于安全极限阈值中最大值200KM/H;此时该测算对象的动力传递状况识别下限值(也即第二许可下限值)远高于安全极限阈值中最小值0);Example 1: If the vehicle longitudinal velocity is the object of measurement, assume that its (upper limit) safety limit threshold is 200KM/H (obviously, this value is the maximum value of the safety limit threshold; the minimum value of the safety limit threshold of this parameter is usually 0) ;), assuming that the vehicle is running at a longitudinal speed of 60KM/H, the actual value is usually set to 60KM/H, and the power transmission condition identification difference is usually set to be between 10-20KM/H, and the power transmission condition recognition upper limit is The value (that is, the second permissible upper limit value) is usually set to be between 70-80KM/H, and the power transmission condition recognition lower limit value (that is, the second permissible lower limit value) is usually set to 40-50KM/H. Between; as long as the combined operation value of the longitudinal running speed of the vehicle is greater than the upper limit of the power transmission condition identification (ie, the second permitted upper limit value) or less than the lower limit of the power transmission condition identification (ie, the second permitted lower limit value) The power transmission condition judgment result will be abnormal, so that the monitoring protection can be realized; at this time, the measurement object is far from exceeding the safety limit threshold (obviously, that is, the power transmission condition identification upper limit value of the measurement object at this time (also On the second license Value) is much smaller than the maximum safety limit threshold value 200KM / H; at this time the power of the estimated state of transmission of object recognition lower limit value (i.e., a second permission lower limit value) is much higher than the safety limit minimum threshold 0);
如本文中所述参考数据设置的示范方法4和5所述,源动力参数、机械运行参数、质量变化型物品质量具有同一特征类型(均属于幅值可能大幅变化的测算对象),可以采用类同的参考数据设置方法(如均可通过实测值设置参考数据),显而易见的,当测算对象为具有(幅值可能大幅变化的)同一特征类型的源动力参数、质量变化型物品质量中任一参数时,也可参考前述示例1的参考数据的值域设定方法,也即设定该测算对象的动力传递状况识别上限值(也即第二许可上限值)低于安全极限阈值中最大值,设定该测算对象的动力传递状况识别下限值(也即第二许可下限值)高于安全极限阈值中最小值。As described in the exemplary methods 4 and 5 of the reference data setting described herein, the source dynamic parameters, the mechanical operating parameters, and the mass-changing item qualities have the same feature type (both of which are measurement objects whose amplitudes may vary greatly), and may be used as classes. The same reference data setting method (for example, the reference data can be set by the measured value), it is obvious that when the measurement object is the source dynamic parameter and the mass variation type quality of the same feature type (the amplitude may vary greatly) For the parameter, reference may also be made to the value range setting method of the reference data of the foregoing example 1, that is, the upper limit value of the power transmission condition identification (that is, the second permission upper limit value) of the measurement object is set to be lower than the safety limit threshold. The maximum value is set such that the power transmission condition recognition lower limit value (that is, the second permission lower limit value) of the measurement object is higher than the minimum value of the safety limit threshold value.
示例2:如以车辆运载质量(也即运载物品质量)为测算对象,假设其上限的安全极限阈值为限载7人/560KG(显而易见的,该值为安全极限阈值中最大值;该参数的安全极限阈值中最小值通 常为0;),假设车辆实际装载4人/320KG运行时,则实际值通常设为320KG,则动力传递状况识别差值(也即第一许可范围)通常会设置为80-160KG之间,则动力传递状况识别上限值(也即第二许可上限值)通常会设置为480KG,则动力传递状况识别下限值(也即第二许可下限值)通常会设置为160KG;则只要车辆运载质量的联合运算值大于动力传递状况识别上限值(也即第二许可上限值)或小于动力传递状况识别下限值(也即第二许可下限值),所述动力传递状况判断结果将为异常,从而可以实现监控保护;而此时测算对象远未超过安全极限阈值(显而易见的,也即此时该测算对象的动力传递状况识别上限值(也即第二许可上限值)远低于安全极限阈值中最大值560KG;此时该测算对象的动力传递状况识别下限值(也即第二许可下限值)远高于安全极限阈值中最小值(0KG));Example 2: If the vehicle carrying mass (that is, the mass of the carried item) is the object of measurement, the safety limit threshold of the upper limit is assumed to be limited to 7 people/560KG (obviously, this value is the maximum value of the safety limit threshold; Minimum limit in safety limit threshold Often 0;), assuming the actual load of the vehicle is 4 people / 320KG, the actual value is usually set to 320KG, then the power transmission status identification difference (that is, the first permission range) is usually set between 80-160KG. Then, the power transmission condition recognition upper limit value (that is, the second permission upper limit value) is usually set to 480 KG, and the power transmission condition recognition lower limit value (that is, the second permission lower limit value) is usually set to 160 KG; The joint operation value of the vehicle carrying mass is greater than the power transmission condition identification upper limit value (ie, the second permission upper limit value) or less than the power transmission condition recognition lower limit value (ie, the second permission lower limit value), and the power transmission condition The judgment result will be abnormal, so that the monitoring protection can be realized; at this time, the measurement object is far beyond the safety limit threshold (obviously, that is, the upper limit of the power transmission condition identification of the measurement object at this time (that is, the second permission upper limit) The value is far below the maximum value of 560KG in the safety limit threshold; at this time, the power transmission condition recognition lower limit value (that is, the second permission lower limit value) of the measurement object is much higher than the minimum value (0KG) of the safety limit threshold value;
显而易见的,当测算对象为车辆总质量时,自然也可采用类同的参考数据的值域设定的方法;车辆总质量的安全极限阈值中最小值通常为空载车体质量m0的值,车辆总质量的安全极限阈值中最大值通常为运载物品质量的安全极限阈值中最大值与空载车体质量m0值的和。Obviously, when the measured object is the total mass of the vehicle, the method of setting the value range of the same reference data can naturally be adopted; the minimum value of the safety limit threshold of the total mass of the vehicle is usually the value of the empty body mass m0. The maximum of the safety limit thresholds for the total mass of the vehicle is typically the sum of the maximum of the safety limit thresholds for the mass of the carried item and the m0 value of the empty body mass.
上述示例1、示例2显而易见的表明;The above example 1, the example 2 clearly shows;
优选的,动力传递状况识别上限差值(也即第一许可上限值)与实际值(或标定值)的和值小于安全极限阈值中最大值,也即动力传递状况识别上限差值(也即第一许可上限值)小于安全极限阈值中最大值与实际值(或标定值)的差值;优选的,动力传递状况识别上限差值的绝对值越小越好;可提高监控的灵敏度,但该绝对值也不能过小以降低监控的误触发率;优选的,动力传递状况识别下限差值(也即第一许可下限值)与实际值(或标定值)的和值大于安全极限阈值中最小值,也即动力传递状况识别下限差值(也即第一许可下限值)大于安全极限阈值中最小值与实际值(或标定值)的差值;优选的,动力传递状况识别下限差值的绝对值越小越好;可提高监控的灵敏度,但该绝对值也不能过小以降低监控的误触发率;也即,优选的,当参考数据中包括或为第一许可范围与实际值时,第一许可范围与实际值的和值在安全范围之内;当参考数据中包括或为第一许可范围与标定值时,第一许可范围与标定值的和值在安全范围之内;;Preferably, the sum of the power transmission condition identification upper limit difference (that is, the first permitted upper limit value) and the actual value (or the calibration value) is less than the maximum value of the safety limit threshold, that is, the power transmission condition recognition upper limit difference (also That is, the first allowable upper limit value is smaller than the difference between the maximum value and the actual value (or the calibration value) in the safety limit threshold; preferably, the absolute value of the upper limit difference of the power transmission condition recognition is as small as possible; the sensitivity of the monitoring can be improved , but the absolute value should not be too small to reduce the false trigger rate of monitoring; preferably, the sum of the lower limit of the power transmission condition identification (that is, the first lower limit value) and the actual value (or the calibration value) is greater than the safety value. The minimum value of the limit threshold, that is, the power transmission condition identification lower limit difference (that is, the first permission lower limit value) is greater than the difference between the minimum value and the actual value (or the calibration value) of the safety limit threshold; preferably, the power transmission condition The smaller the absolute value of the lower limit difference is, the better it is; the sensitivity of the monitoring can be improved, but the absolute value should not be too small to reduce the false trigger rate of the monitoring; that is, preferably, when the reference data includes or is the first license Scope and In the actual value, the sum of the first permitted range and the actual value is within the safe range; when the reference data includes or is the first permitted range and the calibration value, the sum of the first permitted range and the calibration value is in the safe range Inside;;
通常来说,动力传递状况识别上限值(也即第二许可上限值)大于实际值;优选的,动力传递状况识别上限值(也即第二许可上限值)小于安全极限阈值中最大值;通常来说,动力传递状况识别下限值(也即第二许可下限值)小于实际值(或标定值);优选的,动力传递状况识别下限值(也即第二许可下限值)大于安全极限阈值中最小值;也即,优选的,当参考数据中包括或为第二许可范围时,第二许可范围在安全范围之内;更进一步的,动力传递状况识别上限值(也即第二许可上限值)和/或动力传递状况识别下限值(也即第二许可下限值)越接近于实际值(或标定值),可提高监控的灵敏度,但又须与该实际值保持某个数量的差值以降低监控的误触发率;Generally, the power transmission condition recognition upper limit value (that is, the second permission upper limit value) is greater than the actual value; preferably, the power transmission condition identification upper limit value (that is, the second permission upper limit value) is smaller than the safety limit threshold value. The maximum value; generally, the power transmission condition recognition lower limit value (that is, the second permission lower limit value) is smaller than the actual value (or the calibration value); preferably, the power transmission condition identifies the lower limit value (that is, the second permission) The limit value is greater than the minimum value of the safety limit threshold; that is, preferably, when the reference data includes or is the second permission range, the second permission range is within the safety range; further, the power transmission condition recognition upper limit The closer the value (ie, the second permissible upper limit) and/or the lower limit of the power transmission condition identification (ie, the second permissible lower limit) to the actual value (or the calibration value), the sensitivity of the monitoring can be improved, but A certain amount of difference must be maintained with the actual value to reduce the false trigger rate of the monitoring;
现有公知技术方案中,只有在车辆运载质量(也即运载物品质量)的联合运算值高于安全极限阈值中最大值(560KG)、或小于安全极限阈值中最小值(0)才可能作出响应;只要车辆质量在安全极限阈值(最大值、最小值)之中,(即使汽车4人中3人坠车、或高铁的尾节车厢脱落)均会作出 安全状况正常的错误判断。In the prior art solution, only when the joint operation value of the vehicle carrying quality (that is, the mass of the carried item) is higher than the maximum value (560 KG) of the safety limit threshold or less than the minimum value (0) of the safety limit threshold is possible. As long as the vehicle mass is within the safety limit threshold (maximum, minimum), even if 3 of the 4 people in the car crash, or the tailgate of the high-speed rail falls off, The wrong judgment of the normal security situation.
本监控方法(#1)或监控方法(#2)中步骤B也是本发明动力传递异常监控方案的重要步骤之一;车辆运行中的动力传递异常有可能导致严重安全事故,需要及时响应处理;Step B in the monitoring method (#1) or the monitoring method (#2) is also one of the important steps of the power transmission abnormality monitoring scheme of the present invention; abnormal power transmission during vehicle operation may cause a serious safety accident, and needs timely response processing;
B1方案:如所述判断结果包括是,则启动设定的动力传递异常处理机制;B1 scheme: if the judgment result includes yes, the set power transmission abnormality processing mechanism is started;
本发明所述的动力传递异常处理机制包括但不局限于:语音提示告警、声光告警、根据车辆当前运行条件选择性执行保护动作、启动动力传递故障监控机制、将告警信息输出到车内人机交互界面、网络系统、连接端口、手机APP系统等;当车辆的监控系统已经过安全测试、得到法律许可时所述的安全处理机制还可包括减速停车、紧急停车等;机器系统和人工可任意组合设定各种安全处理机制。本发明所述的动力传递异常处理机制也可简称为安全处理机制。The power transmission abnormality processing mechanism of the present invention includes, but is not limited to, a voice prompt alarm, an acousto-optic alarm, a selective execution of a protection action according to a current operating condition of the vehicle, a startup power transmission failure monitoring mechanism, and an alarm information output to the vehicle owner. Machine interaction interface, network system, connection port, mobile APP system, etc.; when the vehicle monitoring system has passed the safety test and obtained legal permission, the safety processing mechanism may also include deceleration parking, emergency parking, etc.; machine system and labor can be Set various security processing mechanisms in any combination. The power transmission abnormality processing mechanism of the present invention may also be referred to simply as a security processing mechanism.
本发明所述的告警信息可包含但不局限于:时间、位置、告警原因、告警时任一或多个车辆运行参数的值等;The alarm information of the present invention may include, but is not limited to, time, location, cause of the alarm, value of any one or more vehicle operating parameters during the alarm, and the like;
本发明所述根据车辆当前运行条件选择性执行保护动作,是指当车辆测算对象的联合运算值已超出测算对象的参考数据时,系统先检查车辆当前的运行测量条件再执行相关动作;可包括而不局限于下属情况:According to the present invention, the selective execution of the protection action according to the current operating condition of the vehicle means that when the joint calculation value of the vehicle measurement object has exceeded the reference data of the measurement object, the system first checks the current operation measurement condition of the vehicle and then performs the related action; Not limited to subordinates:
情况1:检查参考数据是否设置正确;如参考数据未正确设置或未设置完毕,则屏蔽相关的告警信息输出、不执行任何保护动作;Case 1: Check whether the reference data is set correctly; if the reference data is not set correctly or is not set, the related alarm information is masked and no protection action is performed;
情况2:检查联合运算值计算中各输入参数的取值时间是否在预设的时间范围之内;如超出了预设的时间范围如1毫秒时,则屏蔽相关的告警信息输出、不执行任何保护动作;Case 2: Check whether the value of each input parameter in the calculation of the joint operation value is within the preset time range; if the preset time range is exceeded, such as 1 millisecond, the related alarm information is masked and output is not executed. Protection action
情况3:当车辆处于调试、参数测试过程中,可不执行任何保护动作。Case 3: When the vehicle is in the process of debugging and parameter testing, no protection action can be performed.
B2方案:输出所述判断结果;B2 scheme: outputting the judgment result;
B3方案:保存所述判断结果;B3 scheme: saving the judgment result;
当本发明所述输出,包括将数据输出到车内人机交互界面、网络系统、连接端口、外部的控制系统、手机APP系统等;特别是当本发明所提供的监控方法/系统,独立于车辆的控制/驱动系统时,则更加需要将数据输出到外部的控制/驱动系统,以便及时处理异常信息;该人机交互界面包括显示器、语音系统、指示灯等;该连接端口可供外部人机交互界面、网络系统直接或以通讯方式读取数据,以让与车辆运行相关的人员或机构(如驾乘人员、运营管理方、交警、故障诊断中心)可直接或间接的查看收听、监控数据。The output of the present invention includes outputting data to an in-vehicle human-machine interaction interface, a network system, a connection port, an external control system, a mobile APP system, etc.; in particular, when the monitoring method/system provided by the present invention is independent of When the vehicle's control/drive system is used, it is more necessary to output the data to an external control/drive system to process the abnormal information in time; the human-computer interaction interface includes a display, a voice system, an indicator light, etc.; the connection port is available to an external person. The machine interaction interface, the network system reads data directly or in a communication manner, so that personnel or institutions related to vehicle operation (such as drivers and passengers, operation management parties, traffic police, and fault diagnosis centers) can directly or indirectly view the listening and monitoring. data.
本发明所述保存,包括将数据保存入监控系统内保存模块、车内存储系统、网络系统、外部的控制系统、手机APP系统等;以让与车辆运行相关人员或机构(如驾乘人员、运营管理方、交警、故障诊断中心)可任意调取、监控数据;车内存储模块包括U盘、硬盘等;可形成类似于飞机黑匣子功能,便于事后分析。 The saving of the present invention includes saving the data into a monitoring module, an in-vehicle storage system, a network system, an external control system, a mobile APP system, etc.; to enable the vehicle to operate related personnel or institutions (such as drivers and passengers, The operation management party, the traffic police, and the fault diagnosis center can arbitrarily retrieve and monitor the data; the in-vehicle storage module includes a U disk, a hard disk, etc.; it can form a function similar to the aircraft black box, which is convenient for post-mortem analysis.
获取所述测算对象的联合运算值,可以通过多种获取方式来实现;如读取其他设备输出的联合运算值;如通过监控系统自身测量部件测量车辆的联合运算值;或部分为读取现有设备输出数据,部分为自身测量数据等。Obtaining the joint operation value of the measurement object may be implemented by using multiple acquisition methods; for example, reading the joint operation value output by other devices; for example, measuring the joint operation value of the vehicle by the monitoring system itself; or partially reading the current There are device output data, some of which are self-measured data.
本发明所述参考数据,除了上述值域的设置规则外,还需考虑两方面的问题;一为参考数据的数据性质(包括数据类型/或数据获取的途径);二为参考数据的取值或设定时间;In addition to the setting rules of the above-mentioned range, the reference data of the present invention needs to consider two aspects; one is the data property of the reference data (including the data type/path of data acquisition); the other is the value of the reference data. Or set the time;
根据测算对象的不同,下述内容为参考数据的具体设置方案(如数据的来源或取值途径的选取、设定方式、取值时间等)的通常规则(参考数据设置的示范方法1、2、3、4、5、6):According to the difference of the measurement objects, the following contents are the general rules of the specific setting scheme of the reference data (such as the source of the data or the selection of the value path, the setting method, the value time, etc.) (the demonstration method of reference data setting 1, 2 , 3, 4, 5, 6):
示范方法1:Model Method 1:
如后续实施例34、35、41所示:当测算对象为幅值可能大幅变化的车辆质量时(如公交车辆、货车、普通私家车辆),(显而易见的,该幅值可能大幅变化,指在不同的“车辆由动力装置控制运行”的时间段中(也即不同的运行流程中)),人员或货物的上车或下车,可能导致车辆质量可能大幅变动),该参数在车辆运行中不便于(如每次通过磅秤称量)获取实测值,但其在车辆运行过程中数值通常不变(显而易见的,也即在当次的运行流程中,车辆质量值变化较小或不变);较优方式为根据满足设定条件时进行车辆运动平衡计算所获取的联合运算值设定所述参考数据(且重点目标为实际值或第二许可范围);也即参考数据中的实际值、第二许可范围中任意一种或多种数据可根据满足设定条件时所进行车辆运动平衡计算获取的联合运算值设定;As shown in the subsequent embodiments 34, 35, 41: when the measured object is the mass of the vehicle whose amplitude may vary greatly (such as a bus, a truck, a general private vehicle), (obviously, the magnitude may vary greatly, Different "times when the vehicle is controlled by the power unit" (ie, in different operating procedures), the loading or unloading of personnel or goods may cause the vehicle quality to vary greatly.) This parameter is in the running of the vehicle. It is inconvenient (such as weighing each time through the scale) to obtain the measured value, but the value is usually unchanged during the running of the vehicle (obviously, that is, in the current running process, the vehicle mass value changes little or unchanged) The preferred method is to set the reference data according to the joint operation value obtained by performing the vehicle motion balance calculation when the set condition is satisfied (and the key target is the actual value or the second permission range); that is, the actual value in the reference data. And any one or more kinds of data in the second permission range may be set according to a joint operation value obtained by calculating a vehicle motion balance calculated when the set condition is satisfied;
该技术方案是本发明核心思路之一,因为车辆的车辆质量在每个不同运行流程中均可能发生大幅度变化,通过该采用该技术方案,实质建立一个自学习机制,可以自动跟随载荷的正常变化而柔性调整参考数据(重点目标为其中的实际值或第二许可范围);在此基础上可提高监控灵敏度、提高对环境变化的适应能力。显而易见的,在非“满足设定条件时”的运行期间(也即车辆运行的绝大多数运行时间),自然的无需多次、重复设置参考数据;The technical solution is one of the core ideas of the present invention, because the vehicle quality of the vehicle may vary greatly in each different operation process. By adopting the technical solution, a self-learning mechanism is basically established, and the load can be automatically followed. Change and flexibly adjust the reference data (the key target is the actual value or the second license range); on this basis, the monitoring sensitivity can be improved and the adaptability to environmental changes can be improved. Obviously, during the operation period of “not satisfying the set condition” (that is, the majority of the running time of the vehicle operation), it is naturally unnecessary to repeatedly set the reference data;
示范方法2:当测算对象为幅值固定的车辆质量时(如无人驾驶车辆、运载物品质量和/或车辆总质量相对固定的车辆),较优的方式为通过预设值(例如系统默认值)设定参考数据,第二许可范围;也即参考数据中的第二许可范围可根据系统默认值设定;参考数据的设定时间既可在车辆当次运行之前,也可在系统上电运行之初;如后续实施例39所示;显而易见的,在“车辆当次运行之前”或非“当次运行之初”的运行期间(也即车辆运行的绝大多数运行时间);当然也可根据满足设定条件时进行车辆运动平衡计算所获取的联合运算值设定参考数据。Demonstration Method 2: When the measured object is a fixed-size vehicle mass (such as an unmanned vehicle, the quality of the carried item, and/or the vehicle with a relatively constant total mass), the preferred method is to pass a preset value (for example, the system default) Value) setting reference data, the second permission range; that is, the second permission range in the reference data can be set according to the system default value; the reference data can be set at the time before the vehicle is run or on the system. At the beginning of the electrical operation; as shown in the subsequent embodiment 39; obviously, during the operation of "before the vehicle is running" or not at the beginning of the current operation (that is, the majority of the running time of the vehicle); The reference data may also be set based on the joint operation value obtained by performing the vehicle motion balance calculation when the set condition is satisfied.
示范方法3: Model Method 3:
当测算对象为不可测参数和/或可预设参数和/或系统固有参数时(如滚阻系数、效率系数),该类参数也不便于在车辆运行中实际测量,但该类参数在车辆正常运行中幅值相对稳定,即使变化也有相对稳定的规则(如跟随速度、行驶里程、使用时间等因素而变化);根据预设值(尤其为系统预设值(中系统默认值))设定参考数据(标定值(也即基准值)、第一许可范围、第二许可范围任意一种或多种数据)为最简单或简便的方式;也可根据满足设定条件时进行车辆运动平衡计算所获取的联合运算值设定参考数据;也即参考数据中的标定值和/或第二许可范围可根据预设值(尤其为系统预设值(中系统默认值))所设定;When the measured object is untestable parameter and / or preset parameters and / or system inherent parameters (such as rolling resistance coefficient, efficiency coefficient), such parameters are not easy to actually measure in the vehicle operation, but the parameters are in the vehicle The amplitude is relatively stable during normal operation, even if the change has relatively stable rules (such as following speed, mileage, usage time, etc.); according to the preset value (especially the system default value (medium system default value)) The reference data (calibration value (that is, the reference value), the first permission range, the second permission range, or any one of the data) is the simplest or simpler method; the vehicle motion balance can also be performed according to the set conditions. Calculating the obtained joint operation value setting reference data; that is, the calibration value and/or the second permission range in the reference data may be set according to a preset value (especially a system preset value (medium system default value));
参考数据的设定时间既可在车辆当次运行之前,也可在当次运行之初;当测算对象为系统固有参数时,后续实施例36、37、38为参考示例;至于如何具体的去设置或判断“满足设定条件时”,可自然的参考实施例35、实施例41等内容;The set time of the reference data can be either before the current operation of the vehicle or at the beginning of the current operation; when the measurement object is a system inherent parameter, the subsequent embodiments 36, 37, 38 are reference examples; as for how to go specifically When setting or judging "when the setting condition is satisfied", the contents of Embodiment 35, Embodiment 41 and the like can be naturally referred to;
示范方法4:Model Method 4:
当测算对象为幅值可能大幅变化的需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时:较优的方式根据实测值设定所述参考数据,重点为设定参考数据中实际值和/或第二许可范围;后续实施例40、实施例42、实施例43为参考例;(显而易见的,该幅值可能大幅变化,指即使在同一的“车辆由动力装置控制运行”的时间段中(也即同一的运行流程中)),该幅值均可能大幅变动);综合而言,参考数据中实际值、第二许可范围中任意一种数据可根据实测值设定,且所述参考数据的取值时间与所述联合运算值的取值时间在预设的时间范围内(也即同步);When the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality whose amplitude may vary greatly: preferred The method sets the reference data according to the measured value, and focuses on setting the actual value and/or the second permission range in the reference data; subsequent embodiment 40, embodiment 42, and embodiment 43 are reference examples; (obviously, the frame The value may vary greatly, meaning that even in the same period of time when the vehicle is controlled by the power unit (ie, in the same operational process), the amplitude may vary greatly; in general, the actual data in the reference data Any one of the value and the second permission range may be set according to the measured value, and the value of the reference data and the value of the joint operation value are within a preset time range (ie, synchronized);
当测算对象为需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时,因为参考数据中的实际值或第二许可范围均可能快速变化,所以可获取测算对象的实测值,并根据其设定参考数据中的实际值或第二许可范围;且需将参考数据与联合运算值的取值时间限定在预设的时间范围内;该时间范围越小越好;当车速为标定值120KM/H时,每分钟为2KM,每秒约为33米,1秒可相差33米,10毫秒相差0.33米;1毫秒相差0.033米;一个典型障碍(如减速带、石头)的尺寸可能在0.1米左右;该时间范围的设置可尽量采用车辆动力传递异常处理CPU的最快速度,如100M主频时1毫秒内可进行10万次单周期的指令运算;When the measured object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operating parameter and/or mass change item quality, because the actual value or the reference data in the reference data The scope of the two licenses may change rapidly, so the measured value of the measured object can be obtained, and the actual value or the second permitted range in the reference data can be set according to it; and the time value of the reference data and the joint operation value must be limited to Within the time range; the smaller the time range, the better; when the vehicle speed is 120KM/H, it is 2KM per minute, about 33 meters per second, 1 second can be different by 33 meters, and 10 milliseconds is 0.33 meters; 1 The difference in milliseconds is 0.033 meters; the size of a typical obstacle (such as speed bump, stone) may be about 0.1 meters; the setting of this time range can use the maximum speed of the CPU power transmission abnormality processing CPU, such as within 1 millisecond of 100M main frequency Can perform 100,000 single-cycle instruction operations;
因参考数据的取值时间与所述联合运算值的取值时间需在预设的时间范围内(也即同步),显而易见的,当参考数据的取值时间脱离了预设的时间范围时,则需要新设定参考数据,以满足参考数据的取值时间与联合运算值的取值时间在预设的时间范围内(也即同步)的条件。Since the time value of the reference data and the value of the joint operation value need to be within a preset time range (ie, synchronization), it is obvious that when the time value of the reference data is out of the preset time range, Then, the reference data needs to be newly set to satisfy the condition that the value of the reference data and the value of the joint operation value are within a preset time range (ie, synchronization).
示范方法5:Model Method 5:
当测算对象为幅值可能大幅变化的需测量的参数和/或可测量的参数和/或源动力参数和/或机 械运行参数和/或质量变化型物品质量中任一参数时,还有一种可行性,根据所述测算对象的历史记录值设定参考数据;当所述历史记录值中包含历史记录原值、历史记录实际值中任意一种或两种数据且根据所述数据设定实际值或/和第二许可范围时,所述数据的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值;也即实际值、第二许可范围中任意一种或多种数据可根据测算对象的历史记录值设定,所述历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值;When the measurement object is a parameter to be measured whose amplitude may vary greatly and/or measurable parameters and/or source dynamic parameters and/or machine There is also a feasibility when any one of the mechanical operation parameter and/or the quality change item quality, the reference data is set according to the historical record value of the measurement object; when the historical record value includes the original value of the historical record, When any one or two kinds of data are recorded and the actual value or/and the second permitted range are set according to the data, the difference between the vehicle operating condition and the current vehicle operating condition when the data is valued Below a preset threshold; that is, any one or more of the actual value and the second permitted range may be set according to a historical record value of the measured object, and the vehicle operating condition at the time of the historical value is compared with the current The difference in vehicle operating conditions is lower than a preset threshold;
历史记录值的取值时的车辆运行条件与当前的车辆运行条件的差异度低于预设阈值,指:历史记录值生成时所对应的车辆运行条件(车辆质量、车辆的速度、纵向加速度、车辆的外部环境信息以及源动力参数)与当前的车辆运行条件(车辆质量、车辆的速度、纵向加速度、车辆的外部环境信息以及源动力参数)分别一致;显而易见的,该车辆运行条件指输入参数中所包括的参数的类型与幅值;所述外部环境信息是指车子本体以外的影响车辆运行状态的环境信息,如路面坡度、风速、与路况相关的滚阻系数分量fr等;所述一致是指参数的大小相同或者接近,且若该参数存在方向,则参数的方向相同或接近。The difference between the vehicle operating condition and the current vehicle operating condition at the time of the historical value is lower than the preset threshold, and refers to the vehicle operating condition (vehicle quality, vehicle speed, longitudinal acceleration, corresponding to the historical value generation). The vehicle's external environmental information and source power parameters are consistent with current vehicle operating conditions (vehicle quality, vehicle speed, longitudinal acceleration, vehicle external environmental information, and source dynamic parameters); obviously, the vehicle operating conditions refer to input parameters. The type and magnitude of the parameters included in the vehicle; the external environment information refers to environmental information other than the body of the vehicle that affects the running state of the vehicle, such as road gradient, wind speed, rolling resistance coefficient component fr related to road conditions, etc.; It means that the parameters are the same or close, and if the parameters have directions, the directions of the parameters are the same or close.
例如当测算对象为源动力参数,当联合运算值的取值时与某个历史记录值的取值时的车辆运行条件相近时(多个核心的动力传递状况关联因子的值相近;如车辆质量值、路面坡度、纵向速度、纵向加速度等参数的值均相近),则此时两个不同取值时间的源动力参数值可能也相近;具体的车辆运行条件(如核心的动力传递状况关联因子的个数、各数据的权重、各动力传递状况关联因子的差异度的阈值)由用户自行设定、调节;相关参数越多、权重设置越合理、差异度阈值越小则计算/监控精度越高;综合来说,用历史记录值设置于幅值快速变化的测算对象的实际值,提供了一种全新的技术选择,弥补了以前必须实测的途径不足。For example, when the measured object is the source dynamic parameter, when the value of the joint operation value is similar to the vehicle operating condition when the value of a certain historical value is used (the values of the correlation factors of the multiple core power transmission conditions are similar; for example, the vehicle mass Values, road grade, longitudinal speed, longitudinal acceleration and other parameters are similar. The source and power parameters of the two different time periods may be similar. Specific vehicle operating conditions (such as the core power transmission condition correlation factor) The number of the data, the weight of each data, and the threshold of the degree of difference in the correlation factors of each power transmission condition are set and adjusted by the user; the more relevant parameters, the more reasonable the weight setting, and the smaller the difference threshold is, the more the calculation/monitoring accuracy is. High; in general, the use of historical values to set the actual value of the rapidly changing measurement object provides a completely new technical choice, which makes up for the lack of ways that must be measured before.
示范方法6:根据所述测算对象的历史记录值设定所述参考数据;Exemplary method 6: setting the reference data according to the historical record value of the measurement object;
可优选方法为:无论测算对象为源动力参数、机械运行参数、质量变化型物品质量、车辆质量、系统固有参数中任一参数时(通常也即任意一种车辆运行参数)均可根据历史记录差值设定第一许可范围,也即第一许可范围可根据历史记录差值设定;详细操作见《***根据历史记录值-设置参考数据的技术方案)-实施细节》The preferred method is: when the measurement object is any one of the source dynamic parameter, the mechanical operation parameter, the quality change item quality, the vehicle quality, and the system inherent parameter (usually any vehicle operating parameter), according to the history record The difference sets the first permission range, that is, the first permission range can be set according to the history difference value; for detailed operation, see "*** According to historical record value - technical solution for setting reference data" - implementation details
《***根据历史记录值-设置参考数据的技术方案)-实施细节》:"*** According to historical value - technical solution for setting reference data" - Implementation details:
本发明提供一种如何运用历史记录值设定参考数据(第二许可范围、第一许可范围)的技术方案;The present invention provides a technical solution for how to set reference data (second license range, first license range) using history values;
*_1.原则:*_1. Principle:
无论哪种类型的测算对象,通常情况下动力传递状况识别值(也即第二许可范围)的设定原则是:就是尽量接近测算对象的实际值以提高监控的灵敏度,但又须与实际值保持合适的差值以降低 监控的误触发率;如将动力传递状况识别上限值设为实际值的1.2~1.5倍,或将动力传递状况识别下限值设为实际值的0.7~0.9倍,或动力传递状况识别上限差值设为实际值的0.1~0.3倍,或将动力传递状况识别下限差值设为实际值的(-0.3)~(-0.1)倍;Regardless of the type of measurement object, the power transmission condition identification value (that is, the second permission range) is usually set as follows: the actual value of the measurement object is as close as possible to improve the sensitivity of the monitoring, but it must be compared with the actual value. Keep the right difference to reduce The false trigger rate of the monitoring; if the power transmission status recognition upper limit is set to 1.2 to 1.5 times the actual value, or the power transmission status recognition lower limit is set to 0.7 to 0.9 times the actual value, or the power transmission status recognition upper limit The difference is set to 0.1 to 0.3 times the actual value, or the power transmission condition recognition lower limit difference is set to (-0.3) to (-0.1) times the actual value;
*_2.常规的设定方式:*_2. General setting method:
但该动力传递状况识别数据(第二许可范围和/或第一许可范围)的精确设定,如靠人工试凑法,或经验法去慢慢摸索,去慢慢验证,动力传递状况识别数据调整准确度低、效率低;且不同车辆运行时的路况、载况、车况变化万千,更为增大动力传递状况识别数据的精确设定的难度。However, the precise setting of the power transmission condition identification data (the second permission range and/or the first permission range), such as manual trial and error, or empirical method to slowly explore, to slowly verify, power transmission status identification data The adjustment accuracy is low and the efficiency is low; and the road conditions, load conditions and vehicle conditions of different vehicles are changed, which makes it more difficult to accurately set the identification data of the power transmission condition.
*_3.根据历史记录值的设定方式:*_3. According to the setting method of historical value:
根据所述测算对象的历史记录值设定所述参考数据(重点目标为其中的动力传递状况识别差值或动力传递状况识别值),是优选方法之一;Setting the reference data according to the historical record value of the measurement object (the key target is the power transmission condition recognition difference or the power transmission status identification value) is one of the preferred methods;
*_4.在动力传递状况判断之前,可参考本发明提供的(一种车辆数据的处理方法),该技术方案已演示如何设定历史记录值;当所述历史记录值已生成时,可根据历史记录值设定所述参考数据(如进行下述5B1、5B2中任意一种或多种步骤);*_4. Before the judgment of the power transmission condition, reference may be made to the present invention (a processing method of vehicle data), which has demonstrated how to set a history value; when the history value has been generated, The history value sets the reference data (such as performing any one or more of the following 5B1, 5B2);
5B1.所述历史记录值包括历史记录原值和历史记录实际值,根据所述历史记录原值与所述历史记录实际值的差值设定所述动力传递状况识别差值(也即第一许可范围);5B1. The historical record value includes a historical record original value and a historical record actual value, and the power transmission status recognition difference value is set according to a difference between the historical record original value and the historical record actual value (ie, the first Scope of permission);
5B2.所述历史记录值包括历史记录原值,根据所述历史记录原值设定所述动力传递状况识别值;5B2. The historical record value includes a historical record original value, and the power transmission status identification value is set according to the historical record original value;
*_5.参考数据设定的较优方式为下:*_5. The preferred way to set the reference data is as follows:
*_51.根据满足设定条件时进行车辆运动平衡计算所获取的联合运算值设定所述参考数据中的实际值(此方式最优适用于幅值可能大幅变化的车辆质量;其次适用于幅值固定的车辆质量车辆质量时(如无人驾驶车辆、无人驾乘车辆)、系统固有参数的实际值的设定);*_51. Set the actual value in the reference data according to the joint operation value obtained by calculating the vehicle motion balance when the set condition is satisfied (this method is optimally applied to the vehicle quality whose amplitude may vary greatly; secondly applies to the amplitude When the value of the vehicle quality is fixed (such as unmanned vehicles, unmanned vehicles), the actual value of the system's inherent parameters is set);
*_52.根据预设的历史记录值设定参考数据中的动力传递状况识别差值(此方式基本上适用于大多数类型的测算对象,且可变模糊控制为精准控制);*_52. Set the power transmission status recognition difference in the reference data according to the preset history value (this method is basically applicable to most types of measurement objects, and the variable fuzzy control is precise control);
*_53.两者相结合可得到理想的参考数据,可最大限度的提高动力传递异常监控的灵敏度、降低监控的误报率;*_53. The combination of the two can obtain ideal reference data, which can maximize the sensitivity of power transmission abnormal monitoring and reduce the false positive rate of monitoring;
*根据历史记录值-设置参考数据的有益意义:该技术方案是本发明核心思路之一,当测算对象为车辆质量、系统固有参数(如滚阻系数、效率系数)时,根据所述测算对象的历史记录值设定所述参考数据(第二许可范围和/或第一许可范围),可以将参数设置准确性、监控灵敏度得到层次性提高,从常规的模糊控制变为精确控制。*Based on the historical record value - the beneficial significance of setting the reference data: This technical solution is one of the core ideas of the present invention. When the measurement object is the vehicle quality, the system inherent parameters (such as the rolling resistance coefficient, the efficiency coefficient), according to the measurement object The history value sets the reference data (the second permission range and/or the first permission range), and the parameter setting accuracy and the monitoring sensitivity can be hierarchically improved from the conventional fuzzy control to the precise control.
《5A5-(模糊算法值的技术方案)-实施细节》:"5A5-(Technical Solution of Fuzzy Algorithm Value) - Implementation Details":
根据系统默认值设定参考数据,缺少灵活性;根据人工设定值而设定所述参考数据,欠智能; 经过模糊算法预设所述参考数据是较优方式;所述模糊算法包括下述任意一种或多种模糊算法规则:可根据在一定运行次数内统计分析曾使用次数最多的参考数据;或自动选择最近数次运行中选择次数最多的参考数据;或自动选择最近一次运行时参考数据;或设置各参考数据的不同的权重指数(如用户预设最有价值、最有保护意义的参考数据)设定参考数据;或综合次数统计分析和权重指数而设定参考数据等;Setting reference data according to system default value, lack of flexibility; setting the reference data according to manual setting values, under-intelligence; Presetting the reference data by a fuzzy algorithm is a preferred method; the fuzzy algorithm includes any one or more of the following fuzzy algorithm rules: statistically analyzing the reference data that has been used most frequently according to a certain number of running times; or automatically Select the most frequently selected reference data in the last few runs; or automatically select the last run reference data; or set different weight indices for each reference data (such as the user's most valuable and most protective reference data) Set reference data; or set the reference data by comprehensive statistical analysis and weight index;
《5A5-(模糊算法值的技术方案)-有益意义》::经过模糊算法预设参数,可提高系统的智能度。"5A5-(Technical scheme of fuzzy algorithm value) - beneficial meaning": After the parameters are preset by the fuzzy algorithm, the intelligence of the system can be improved.
通常在参考数据已设定后,才执行后续的动力传递异常判断/执行,这样可以简化系统。Subsequent power transfer abnormality determination/execution is usually performed after the reference data has been set, which simplifies the system.
实施例34:Example 34:
当满足参考数据的设定条件时(如车辆进入动力装置控制运行流程中设定时间(如1.0秒或5秒)时),根据步骤A计算所得车辆质量的联合运算值m1自动设置实际值(基准值m1_ref);如设m1_ref=m1,或者将m1加上一设定的数值再设为m1_ref;根据已设定的实际值(基准值m1_ref)设定动力传递状况识别差值(也可称为误差门限值m1_gate);如设:m1_gate=m1_ref/4;如果|m1-m1_ref|>m1_gate,则启动设定的安全处理机制;如语音提示告警。When the setting condition of the reference data is satisfied (for example, when the vehicle enters the set time (for example, 1.0 second or 5 seconds) in the power plant control operation flow), the joint operation value m1 calculated according to the step A is automatically set to the actual value ( Reference value m1_ref); if m1_ref=m1, or m1 plus a set value is set to m1_ref; set the power transmission status identification difference according to the set actual value (reference value m1_ref) (also called For the error threshold m1_gate); if: m1_gate=m1_ref/4; if |m1-m1_ref|>m1_gate, start the set security processing mechanism; such as voice prompt alarm.
本实施例中(|m1-m1_ref|>m1_gate)的计算式,也可简单的变形为(m1>m1_ref(1+1/4))和(m1<m1_ref(1-1/4))两个计算式;也即判断联合运算值大于根据实际值的设定的动力传递状况识别上限值(也即第二许可上限值)是否成立,该动力传递状况识别上限值通常大于测算对象的实际值;和判断联合运算值小于根据实际值的设定的动力传递状况识别下限值(也即第二许可下限值)是否成立,该动力传递状况识别下限值通常小于测算对象的实际值;The calculation formula of (|m1-m1_ref|>m1_gate) in this embodiment can also be simply transformed into (m1>m1_ref(1+1/4)) and (m1<m1_ref(1-1/4)) a calculation formula; that is, it is judged whether or not the joint operation value is greater than the set power transmission condition recognition upper limit value (that is, the second permission upper limit value) according to the actual value, and the power transmission condition recognition upper limit value is usually larger than the measurement target The actual value; and the determination of whether the joint operation value is smaller than the set power transmission condition recognition lower limit value (that is, the second permission lower limit value) according to the actual value, the power transmission condition recognition lower limit value is usually smaller than the actual measurement target value;
本实施方式实质为:当测算对象为常规车辆的车辆质量时,实际值为根据满足设定条件时所获取的联合运算值所设定,根据该实际值和系统预设值设定动力传递状况识别差值(也即第一许可范围),然后判断所述联合运算值与所述实际值的差值超出第一许可范围(也即动力传递状况识别差值)是否成立。The essence of the embodiment is: when the measured object is the vehicle mass of the conventional vehicle, the actual value is set according to the joint operation value acquired when the set condition is satisfied, and the power transmission condition is set according to the actual value and the system preset value. The difference value (that is, the first permission range) is identified, and then it is judged whether or not the difference between the joint operation value and the actual value exceeds the first permitted range (that is, the power transmission condition recognition difference value).
特别注明3:Special note 3:
特别注明3.1:本发明所述测算对象,也可称为直接监控对象,实际意义等同于申请号为201410312798.3的中国专利申请中所述直接监控对象;本发明所述实际值,实际意义等同于申请号为201410312798.3的中国专利申请中所述基准值;本发明文件中所述动力传递状况识别差值,实际意义等同于申请号为申请号为201410312798.3的中国专利申请中所述所有实施例中所述误差门限值或门限值;In particular, 3.1: The object of measurement according to the present invention may also be referred to as a direct monitoring object, and the actual meaning is equivalent to the direct monitoring object described in the Chinese Patent Application No. 201410312798.3; the actual value of the present invention is equivalent to the actual meaning. The reference value described in the Chinese Patent Application No. 201410312798.3; the difference in the power transmission condition identification value in the present invention is substantially equivalent to that in all the embodiments described in the Chinese Patent Application No. 201410312798.3 The error threshold or threshold value;
特别注明3.2:本发明中所述联合运算值,实际意义等同于申请号为201410354068.X的中国专 利申请中所述估算值;本发明中所述运载物品质量,实际意义等同于申请号为201410354068.X的中国专利申请中所述运载质量;本发明中所述车辆质量的动力传递状况识别上限值,实际意义等同于申请号为201410354068.X的中国专利申请中所述基准值m1_ref1;本发明中所述车辆质量的动力传递状况识别下限值,实际意义等同于申请号为201410354068.X的中国专利申请中所述基准值m1_ref2;本发明中所述车辆质量的实际值,实际意义等同于申请号为201410354068.X的中国专利申请中所述基准值设定依据的值m1_org;Special Note 3.2: The joint operation value described in the present invention has the actual meaning equivalent to the Chinese application with the application number 201410354068.X. The estimated value in the application; the quality of the carried item in the present invention is substantially equivalent to the carrying quality described in the Chinese Patent Application No. 201410354068.X; the power transmission condition of the vehicle mass is identified in the present invention. The limit value, the actual meaning is equivalent to the reference value m1_ref1 in the Chinese patent application with the application number 201410354068.X; the lower limit value of the power transmission condition identification of the vehicle mass described in the present invention, the actual meaning is equivalent to the application number 201410354068.X The reference value m1_ref2 in the Chinese patent application; the actual value of the vehicle mass in the present invention, the actual meaning is equivalent to the value m1_org based on the reference value set in the Chinese patent application with the application number 201410354068.X;
特别注明3.3:当中文“基准值”后面加“英文标号”再加上后缀“_ref”时,则该语句表达的含义为该测算对象的基准值;例如“基准值m1_ref”与“m1_ref”两者等同,均表示测算对象(m1)的基准值;Special Note 3.3: When the Chinese “reference value” is followed by “English label” followed by the suffix “_ref”, the meaning expressed by the statement is the reference value of the measurement object; for example, “reference value m1_ref” and “m1_ref” Equivalent to both, indicating the reference value of the measurement object (m1);
特别注明3.4:当中文“基准值”后面加“英文标号”再加上后缀“_ref1”时,则该语句表达的含义为该测算对象的动力传递状况识别上限值(也即也即第二许可上限值);例如“基准值m1_ref1”与“m1_ref1”两者等同,均表示测算对象(m1)的动力传递状况识别上限值(也即也即第二许可上限值);例如“基准值m2_ref1”与“m2_ref1”两者等同,均表示测算对象(m2)的动力传递状况识别上限值(也即也即第二许可上限值);例如“基准值S_ref1”与“S_ref1”两者等同,均表示测算对象(f)的动力传递状况识别上限值(也即也即第二许可上限值);Special Note 3.4: When the Chinese "reference value" is followed by "English label" followed by the suffix "_ref1", the meaning expressed by the statement is the upper limit of the power transmission status of the measurement object (that is, the first Second permission upper limit value; for example, "reference value m1_ref1" is equivalent to "m1_ref1", and both represent the upper limit value of the power transmission condition identification of the measurement object (m1) (that is, the second permission upper limit value); for example The "reference value m2_ref1" is equivalent to both "m2_ref1", and both represent the upper limit value of the power transmission condition identification of the measurement object (m2) (that is, the second permission upper limit value); for example, "reference value S_ref1" and "S_ref1" "The two are equivalent, both indicate the upper limit of the power transmission status of the measurement object (f) (that is, the second permissible upper limit value);
特别注明3.5:当中文“基准值”后面加“英文标号”再加上后缀“_ref2”时,则该语句表达的含义为该测算对象的动力传递状况识别下限值(也即第二许可下限值);例如“基准值m1_ref2”与“m1_ref2”两者等同,均表示测算对象(m1)的动力传递状况识别下限值(也即第二许可下限值);例如“基准值m2_ref2”与“m2_ref2”两者等同,均表示测算对象(m2)的动力传递状况识别下限值(也即第二许可下限值);例如“基准值S_ref2”与“S_ref2”两者等同,均表示测算对象(f)的动力传递状况识别下限值(也即第二许可下限值);Special Note 3.5: When the Chinese "reference value" is followed by "English label" followed by the suffix "_ref2", the meaning expressed by the statement is the lower limit of the power transmission status of the measurement object (ie, the second license) Lower limit value); for example, "reference value m1_ref2" is equivalent to "m1_ref2", and both represent the power transmission condition recognition lower limit value (that is, the second permission lower limit value) of the measurement target (m1); for example, "reference value m2_ref2" "Equivalent to both "m2_ref2", both represent the lower limit of the power transmission condition identification of the measurement object (m2) (that is, the second permission lower limit value); for example, "the reference value S_ref2" is equivalent to "S_ref2", both of which are Indicates the lower limit of the power transmission condition identification of the measurement object (f) (ie, the second permitted lower limit value);
实施例35:Example 35:
每首次进入车辆由动力装置控制运行状态下的时间段则自动设置相关状态信息:“未设定动力传递状况识别上限值(基准值m1_ref1)”、“未设定动力传递状况识别下限值(基准值m1_ref2)”;The relevant state information is automatically set for each time period when the first entering vehicle is controlled by the power unit: "the power transmission status identification upper limit value (reference value m1_ref1) is not set", "the power transmission status identification lower limit value is not set" (reference value m1_ref2)";
当满足参考数据的设定条件时,如进入车辆由动力装置控制运行状态的到达设定时间(如2.0秒)时,根据当前步骤A所得的车辆质量的联合运算值m1设定动力传递状况识别值;特别解释说明:本发明为了便于描述和理解,将所有作为动力传递状况识别值设定依据的车辆质量的值m1描述为m1_org;When the setting condition of the reference data is satisfied, for example, when the vehicle reaches the set time (for example, 2.0 seconds) when the power unit controls the operating state, the power transmission status identification is set according to the joint operation value m1 of the vehicle mass obtained in the current step A. Value; special explanation: for convenience of description and understanding, the present invention describes all the values m1 of the vehicle mass as the basis for setting the power transmission condition identification value as m1_org;
如将当前m1值乘以一个大于1的系数(如1.2或1.3)设定为动力传递状况识别上限值(m1_ref1,也即第二许可上限值),且自动设置一个状态信息:“已设定动力传递状况识别上限值(m1_ref1)”;动力传递状况识别上限值(m1_ref1,也即第二许可上限值)的值:m1_ref1=m1_org*1.2; If the current m1 value is multiplied by a coefficient greater than 1 (such as 1.2 or 1.3), the power transmission status identification upper limit value (m1_ref1, that is, the second permissible upper limit value) is set, and a status information is automatically set: Setting the power transmission condition recognition upper limit value (m1_ref1)"; the power transmission status recognition upper limit value (m1_ref1, that is, the second permission upper limit value): m1_ref1=m1_org*1.2;
如将m1与一设定的数值Δ2之差设定为动力传递状况识别下限值(m1_ref2,也即第二许可下限值),且自动设置一个状态信息:“已设定动力传递状况识别下限值(m1_ref2,也即第二许可下限值)”;m1_ref2=m1_org-Δ2,Δ2=30KG;For example, the difference between m1 and a set value Δ2 is set as the power transmission condition recognition lower limit value (m1_ref2, that is, the second permission lower limit value), and a state information is automatically set: "The power transmission condition recognition has been set. Lower limit value (m1_ref2, ie second permitted lower limit value)"; m1_ref2=m1_org-Δ2, Δ2=30KG;
当状态信息为“已设定动力传递状况识别上限值(m1_ref1,也即第二许可下限值)”时判断(m1>m1_ref1)是否成立,若是(m1>m1_ref1)则启动设定的安全处理机制;如声光告警、将告警信息输出到网络系统等;When the status information is "the power transmission status recognition upper limit value (m1_ref1, that is, the second permission lower limit value)" is determined, it is determined whether (m1>m1_ref1) is established, and if (m1>m1_ref1), the set security is started. Processing mechanism; such as sound and light alarms, outputting alarm information to network systems, etc.;
当状态信息为“已设定动力传递状况识别下限值(m1_ref2)”时判断(m1<m1_ref2)是否成立,若是(m1<m1_ref2)则启动设定的安全处理机制;如声光告警、将告警信息输出到网络系统等;When the status information is "set power transmission status recognition lower limit value (m1_ref2)", it is judged whether (m1 < m1_ref2) is established, and if it is (m1 < m1_ref2), the set security processing mechanism is started; for example, sound and light alarm, The alarm information is output to the network system, etc.
本实施方式实质为:当测算对象为常规车辆的车辆质量时,实际值为根据满足设定条件时所获取的联合运算值所设定,第二许可范围为根据实际值也即为根据满足设定条件时所获取的联合运算值所设定,判断所述联合运算值超出第二许可范围是否成立;The essence of the embodiment is: when the measured object is the vehicle mass of the conventional vehicle, the actual value is set according to the joint operation value obtained when the set condition is satisfied, and the second permission range is based on the actual value, that is, according to the satisfaction setting. Setting a joint operation value obtained when the condition is set, and determining whether the joint operation value exceeds the second permission range;
实施例35替代方案1:可将当前所得实际值m1_org除以一个大于1的系数(如1.5)设定为动力传递状况识别下限值(m1_ref2,也即第二许可下限值);m1_ref2=m1_org/1.5;Embodiment 35 Alternative 1: The currently obtained actual value m1_org divided by a coefficient greater than 1 (such as 1.5) can be set as the power transmission condition recognition lower limit value (m1_ref2, that is, the second permission lower limit value); m1_ref2= M1_org/1.5;
实施例35替代方案2:每首次进入一个新的车辆由动力装置控制运行状态时则将m1_ref1清零;当m1_ref1不为零时才判断(m1>m1_ref1);Embodiment 35 Alternative 2: m1_ref1 is cleared when the first time a new vehicle is controlled by the power unit; (m1>m1_ref1) when m1_ref1 is not zero;
实施例35替代方案3:实施例35中所述参考数据的设定条件为:进入车辆由动力装置控制运行状态到达设定时间(如2.0秒)时;也可用下述A、B、C、D任意一种方案来替换参考数据的设定条件:Embodiment 35 Alternative 3: The setting condition of the reference data in Embodiment 35 is: when the entering vehicle is controlled by the power unit to reach a set time (for example, 2.0 seconds); the following A, B, C, D Any one of the schemes to replace the setting conditions of the reference data:
A、如驾乘人员主观认定当前的车辆质量的联合运算值适合设定参考数据(也可称为作基准)时,可人工输入一个“确认”信号;A. If the driver and the passenger subjectively determine that the current calculated value of the vehicle quality is suitable for setting reference data (also referred to as a reference), a "confirmation" signal may be manually input;
B、如车辆运行到设定的纵向速度时(如5KM/小时)、B. If the vehicle is running to the set longitudinal speed (eg 5KM/hour),
C、如电机驱动装置运行到设定的频率时(如5HZ));C. If the motor drive is running to the set frequency (such as 5HZ);
D、如在上述条件基础上,再加上车辆开关门的触发信号,只要车辆未发生开关门动作,动力传递状况识别数据就可维持不变;允许只要未发生开关门动作,多个独立的动力装置控制运行时间段可共用某动力传递状况识别数据;D. On the basis of the above conditions, plus the trigger signal of the vehicle opening and closing door, as long as the vehicle does not open and close the door, the power transmission status identification data can be maintained unchanged; allowing as long as no door opening and closing action occurs, multiple independent The power device control operation period can share a certain power transmission status identification data;
参考数据的设定条件包括人工预设的条件、某一设定的参数到达预设值两种情况;该人工预设的条件包括人工输入确认信号;满足设定条件也可称为符合设定条件。The setting conditions of the reference data include two conditions of manual preset and a set parameter reaching the preset value; the artificial preset condition includes a manual input confirmation signal; and the set condition is also called the compliance setting. condition.
实施例35替代方案4:在实施例35的所述的动力传递状况识别数据,允许用户人工或系统自由调整;如在特定情况下,如果允许车辆在运行过程中卸货或上下客(甚至跳车),此时可由用户人工或系统自由调整动力传递状况识别数据、或将动力传递状况识别数据清0且设置一个状态信息:“未设定动力传递状况识别数据”、或重新设置动力传递状况识别数据等;Embodiment 35 Alternative 4: The power transmission condition identification data described in Embodiment 35 allows the user to freely adjust manually or systematically; if in certain circumstances, if the vehicle is allowed to unload or get on and off during operation (or even jump) At this time, the power transmission status identification data can be freely adjusted by the user manually or the system, or the power transmission status identification data can be cleared and a status information is set: "the power transmission status identification data is not set", or the power transmission status identification is reset. Data, etc.
当然,在常规情况下不允许车辆在运行中卸货或上下客(甚至跳车),监控系统可把此种情况 纳入监控范围,并可触发相应的安全处理机制;Of course, under normal circumstances, the vehicle is not allowed to unload or get on and off (or even jump) during operation. The monitoring system can take this situation. Incorporate monitoring scope and trigger corresponding security processing mechanisms;
实施例36:Example 36:
当测算对象为机电传动综合的效率系数时,When the measured object is the integrated efficiency coefficient of electromechanical transmission,
(参考数据设置方式1):将步骤A所获取机电传动综合的效率系数的联合运算值Kem_cal设置为实际值也即标定值(也即基准值Kem_ref);可根据系统默认值设定动力传递状况识别差值(也即误差门限值)Kem_gate,如系统自动设定一固定误差门限值:Kem_gate=0.2;(Reference data setting mode 1): Set the joint operation value Kem_cal of the efficiency coefficient of the electromechanical transmission integrated in step A to the actual value, that is, the calibration value (ie, the reference value Kem_ref); the power transmission condition can be set according to the system default value. Identify the difference (that is, the error threshold) Kem_gate, if the system automatically sets a fixed error threshold: Kem_gate = 0.2;
(参考数据设置方式2):当然也允许根据系统默认值设定标定值(基准值Kem_ref),或根据步骤A所获取机电传动综合的效率系数的联合运算值Kem_cal设定动力传递状况识别差值,如Kem_gate=Kem_cal/5;(Refer to data setting mode 2): Of course, it is also allowed to set the calibration value (reference value Kem_ref) according to the system default value, or set the power transmission status identification difference value according to the joint operation value Kem_cal of the electromechanical transmission integrated efficiency coefficient obtained in step A. , such as Kem_gate=Kem_cal/5;
如果|Kem_cal-Kem_ref|>Kem_gate,则启动设定的安全处理机制:如在网络系统中发出语音提示告警;If |Kem_cal-Kem_ref|>Kem_gate, the set security processing mechanism is activated: if a voice prompt alarm is issued in the network system;
本实施方式实质为:当测算对象为车辆的系统固有参数(中的效率系数)时,(参考数据设置方式1)第一许可范围可根据系统默认值设定,标准状态时的实际值也即标定值可根据所获取的联合运算值所设定;(参考数据设置方式2)第一许可范围可根据系统默认值设定,标定值可根据预设值(系统默认值)设定;然后判断所述联合运算值与所述标定值的差值超出第一许可范围(也即动力传递状况识别差值)是否成立。The essence of the embodiment is: when the measurement object is the system inherent parameter (efficiency coefficient) of the vehicle, (the reference data setting mode 1) the first permission range can be set according to the system default value, and the actual value in the standard state is also The calibration value can be set according to the obtained joint operation value; (reference data setting mode 2) The first permission range can be set according to the system default value, and the calibration value can be set according to the preset value (system default value); Whether the difference between the joint operation value and the calibration value exceeds the first permitted range (that is, the power transmission condition recognition difference value) is established.
在实施例36包含参考数据设置方式2的分支方案中,(|Kem_cal-Kem_ref|>Kem_gate)的计算式,也可简单的变形为(Kem_ref>Kem_cal(1+1/5)),该计算式的值为根据联合运算值设定的上限值,也即判断标定值大于根据联合运算值设定的上限值是否成立;本实施例中(|Kem_cal-Kem_ref|>Kem_gate)的计算式,也可简单的变形为(Kem_ref<Kem_cal(1-1/5)),该计算式的值也即根据联合运算值设定的下限值;判断实际值(也即标定值)小于根据联合运算值设定的下限值是否成立;根据联合运算值设定的上限值、根据联合运算值设定的下限值均可属于第二参考数据中数据。In the branching scheme in which the reference data includes the reference data setting mode 2, the calculation formula of (|Kem_cal-Kem_ref|>Kem_gate) can also be simply transformed into (Kem_ref>Kem_cal(1+1/5)), which is The value is an upper limit value set according to the joint operation value, that is, whether the calibration value is greater than the upper limit value set according to the joint operation value; in this embodiment, the calculation formula of (|Kem_cal-Kem_ref|>Kem_gate) It can also be simply transformed into (Kem_ref<Kem_cal(1-1/5)), the value of the calculation formula is the lower limit value set according to the joint operation value; determining the actual value (that is, the calibration value) is smaller than the joint operation Whether the lower limit value of the value setting is satisfied or not; the upper limit value set according to the joint operation value and the lower limit value set according to the joint operation value may belong to the data in the second reference data.
实施例37:Example 37:
当测算对象为车辆的滚阻系数时,When the measured object is the rolling resistance coefficient of the vehicle,
(参考数据设置方式1):将步骤A所获取滚阻系数的联合运算值μ1_cal设置为实际值也即标定值(也即基准值μ1_ref);可根据系统默认值设定动力传递状况识别差值(也即误差门限值)μ1_gate,如系统自动设定一固定误差门限值:μ1_gate=0.2;(Refer to data setting mode 1): Set the joint operation value μ1_cal of the rolling resistance coefficient acquired in step A to the actual value, that is, the calibration value (ie, the reference value μ1_ref); the power transmission status identification difference can be set according to the system default value. (that is, the error threshold) μ1_gate, if the system automatically sets a fixed error threshold: μ1_gate = 0.2;
(参考数据设置方式2):当然也允许根据系统默认值设定标定值(基准值μ1_ref),或根据 步骤A所获取机电传动综合的效率系数的联合运算值μ1_cal设定动力传递状况识别差值,如μ1_gate=μ1_cal/4;(Refer to data setting mode 2): Of course, it is also allowed to set the calibration value (reference value μ1_ref) according to the system default value, or according to The joint operation value μ1_cal of the integrated efficiency coefficient of the electromechanical transmission obtained in step A sets the power transmission condition identification difference, such as μ1_gate=μ1_cal/4;
如果|μ1_cal-μ1_ref|>μ1_gate,则启动设定的安全处理机制:如在网络系统中发出语音提示告警;If |μ1_cal-μ1_ref|>μ1_gate, the set security processing mechanism is activated: if a voice prompt alarm is issued in the network system;
本实施方式实质为:当测算对象为车辆的系统固有参数(中的滚阻系数)时,(参考数据设置方式1)第一许可范围可根据系统默认值设定,标定值可根据所获取的联合运算值所设定;(参考数据设置方式2)第一许可范围可根据系统默认值设定,标定值可根据根据系统默认值设定;然后判断所述联合运算值与所述实际值的差值超出第一许可范围是否成立。The essence of the embodiment is: when the measurement object is the system inherent parameter of the vehicle (the rolling resistance coefficient in the vehicle), (the reference data setting mode 1) the first permission range can be set according to the system default value, and the calibration value can be obtained according to the obtained The joint operation value is set; (reference data setting mode 2) the first permission range can be set according to the system default value, and the calibration value can be set according to the system default value; then the joint operation value and the actual value are determined. Whether the difference exceeds the first permitted range is true.
实施例38:Example 38:
将车辆的滚阻系数作为测算对象;Taking the rolling resistance coefficient of the vehicle as the object of measurement;
步骤A:获取所述车辆的滚阻系数的联合运算值f_cal;可根据系统默认值设定动力传递状况识别值;如将测算对象的系统设定值f(通常为实际值)与一设定的数值Δ1之和设定为动力传递状况识别上限值(S_ref1),S_ref1=f+Δ1;如将测算对象的系统设定值f与0.8的乘积设定为动力传递状况识别下限值(S_ref2),S_ref2=f*0.8;该f、偏差值Δ1、乘积系数0.8均为系统默认值;Step A: acquiring a joint operation value f_cal of the rolling resistance coefficient of the vehicle; setting a power transmission status identification value according to a system default value; for example, setting a system setting value f (usually an actual value) of the measurement object with a setting The sum of the values Δ1 is set as the power transmission condition recognition upper limit value (S_ref1), S_ref1=f+Δ1; if the product of the system setting value f of the measurement object and 0.8 is set as the power transmission condition recognition lower limit value ( S_ref2), S_ref2=f*0.8; the f, the deviation value Δ1, and the product coefficient 0.8 are all system default values;
步骤B:如果(f_cal>S_ref1)、(f_cal<S_ref2)中任一或两个条件成立时,则启动设定的安全处理机制:如在网络系统中发出语音提示告警;Step B: If any one or two of (f_cal>S_ref1) and (f_cal<S_ref2) are met, the set security processing mechanism is started: if a voice prompt alarm is issued in the network system;
本实施方式实质为:当测算对象为车辆的系统固有参数(中的滚阻系数)时,动力传递状况识别上限值(也即第二许可上限值)可根据系统默认值(系统设定值,通常为实际值)设定,该动力传递状况识别上限值通常大于测算对象的实际值;第二许可下限值可根据系统默认值(系统设定值,通常为实际值)设定,该动力传递状况识别下限值通常小于测算对象的实际值;判断所述联合运算值大于第二许可上限值是否成立和或判断所述联合运算值小于第二许可下限值是否成立。The essence of the embodiment is: when the measurement object is the system inherent parameter of the vehicle (the rolling resistance coefficient in the vehicle), the power transmission condition recognition upper limit value (that is, the second permission upper limit value) can be based on the system default value (system setting) The value, usually the actual value, is set. The upper limit of the power transmission condition identification is usually greater than the actual value of the measurement object; the second lower limit value can be set according to the system default value (system setting value, usually the actual value). The power transmission condition recognition lower limit value is usually smaller than the actual value of the measurement object; it is determined whether the joint operation value is greater than the second permission upper limit value and whether the joint operation value is less than the second permission lower limit value is established.
实施例39:Example 39:
步骤A包括:获取车辆质量的联合运算值m2;如无人驾驶的自动车辆自身质量为1200KG,可根据系统默认值由系统预设动力传递状况识别值;如由系统预设动力传递状况识别上限值(也即m2_ref1):m2_ref1=1500KG;如由系统预设动力传递状况识别下限值(也即m2_ref2):m2_ref2=800KG;Step A includes: obtaining a joint operation value m2 of the vehicle mass; if the unmanned automatic vehicle has a mass of 1200 KG, the system can preset the power transmission status identification value according to the system default value; if the system presets the power transmission status to identify The limit value (ie m2_ref1): m2_ref1=1500KG; if the lower limit value (ie m2_ref2) is recognized by the system preset power transmission condition: m2_ref2=800KG;
判断(m2>m2_ref1)、(m2<m2_ref2)中任意一个或两个条件是否成立;若是则启动设定的安全处理机制,如将告警信息输出到网络系统;Determining whether any one or two conditions (m2>m2_ref1) and (m2<m2_ref2) are true; if yes, initiating a set security processing mechanism, such as outputting alarm information to the network system;
本实施方式实质为:当测算对象为无人驾驶的车辆质量(中的车辆总质量)时,第二许可上限值可根据系统默认值设定,且该第二许可上限值通常大于测算对象的真实值;第二许可下限值可根据系统默认值设定,且该第二许可下限值通常小于测算对象的真实值;判断所述联合运算值超出第 二许可范围是否成立。The essence of the embodiment is: when the measured object is the unmanned vehicle mass (the total mass of the vehicle), the second permitted upper limit value may be set according to the system default value, and the second permitted upper limit value is usually greater than the calculation The true value of the object; the second permission lower limit value may be set according to the system default value, and the second permission lower limit value is usually smaller than the actual value of the measurement object; determining that the joint operation value exceeds the Whether the scope of the license is established.
实施例40:Example 40:
将机电组合型参数fq作为测算对象,机电组合型参数fq的计算公式为:fq=(Ke*Km)*(Te*im/R);Taking the electromechanical combination parameter fq as the calculation object, the calculation formula of the electromechanical combination parameter fq is: fq=(Ke*Km)*(Te*im/R);
步骤A:获取所述车辆的机电组合型参数的联合运算值fq_cal;可根据测算对象的实测值fq设定参考数据中的实际值,并根据该实测值/也即实际值设定动力传递状况识别值;如设定动力传递状况识别上限值S_ref1:S_ref1=fq*1.2;如设定动力传递状况识别下限值S_ref2:S_ref2=fq*0.7;Step A: acquiring a joint operation value fq_cal of the electromechanical combination type parameter of the vehicle; setting an actual value in the reference data according to the measured value fq of the measurement object, and setting a power transmission condition according to the measured value or the actual value Identification value; if the power transmission status identification upper limit value S_ref1 is set: S_ref1=fq*1.2; if the power transmission status recognition lower limit value S_ref2 is set: S_ref2=fq*0.7;
步骤B:如果(fq_cal>S_ref1)、(fq_cal<S_ref2)中任一或两个条件成立时,则启动设定的安全处理机制:如在网络系统中发出语音提示告警;Step B: If any one or both of (fq_cal>S_ref1) and (fq_cal<S_ref2) are met, the set security processing mechanism is started: if a voice prompt alarm is issued in the network system;
本实施方式实质为:当测算对象为源动力参数(中的机电组合型参数fq)时,实际值可根据所述测算对象的实测值设定,超出第二许可范围可根据该实测值(也即实际值)和系统预设值设定,;判断所述联合运算值超出第二许可范围是否成立。The essence of the embodiment is: when the measurement object is the source dynamic parameter (the electromechanical combination parameter fq), the actual value may be set according to the measured value of the measurement object, and the second permitted range may be based on the measured value (also That is, the actual value) and the system preset value are set; and it is determined whether the joint operation value exceeds the second permission range.
本文前述诸多实施例以及后文内容表明,参考数据除具有多种设定方式外,显而易见,本发明所述的参考数据可包含多种数据类型,如参考数据既可为包括动力传递状况识别值(也即第二许可范围)的数据,参考数据也可为包括动力传递状况识别差值(也即第一许可范围)和实际值(或标定值)的数据;其中,动力传递状况识别值(也即第二许可范围)又可包括动力传递状况识别上限值(也即第二许可上限值)和/或动力传递状况识别下限值(也即第二许可下限值);其中,动力传递状况识别差值(也即第一许可范围)又可包括动力传递状况识别上限差值(也即第一许可上限值)、动力传递状况识别下限差值(也即第一许可下限值)中任意一种或两种的数据;The foregoing various embodiments and the following texts indicate that the reference data may include a plurality of data types, such as the reference data, including the power transmission status identification value, in addition to having various setting manners. (that is, the second permission range), the reference data may also be data including a power transmission condition identification difference (ie, a first permission range) and an actual value (or a calibration value); wherein the power transmission status identification value ( That is, the second permission range) may further include a power transmission condition recognition upper limit value (that is, a second permission upper limit value) and/or a power transmission condition recognition lower limit value (that is, a second permission lower limit value); The power transmission condition identification difference value (that is, the first permission range) may further include a power transmission condition identification upper limit value (that is, a first permission upper limit value) and a power transmission condition recognition lower limit difference (that is, a first permission lower limit) Any one or two of the values;
在通常情况下,在没有限定说明/或附加说明时,本发明所述测算对象的联合运算值、实际值或标定值、参考数据等,均指参数的幅值/也即大小;当然,测算对象本身也可以是时间参数,如加速响应时间、减速响应时间、参数变化率等;如测算对象既可是气缸压力,也可是气缸压力的变化率,也即是单位时间内的气缸压力的差值;如测算对象既可是速度,也可是速度的变化率/也即加速度,也可是加速度的变化率/也即加加速度;In the normal case, the joint operation value, the actual value or the calibration value, the reference data, and the like of the measurement object of the present invention refer to the amplitude/size of the parameter when there is no limitation description or additional description; of course, the calculation The object itself can also be a time parameter, such as acceleration response time, deceleration response time, parameter change rate, etc.; for example, the measurement object can be either cylinder pressure or cylinder pressure change rate, that is, the difference of cylinder pressure per unit time. If the object is measured, it can be either speed, rate of change of speed / acceleration, or rate of change of acceleration / jerk;
当车辆的动力装置包括燃料发动机,当车辆在燃料发动机控制运行时,前述实施例1到实施例40的替代实施方案如下:When the powerplant of the vehicle includes a fuel engine, the alternate embodiments of Embodiments 1 through 40 described above are as follows when the vehicle is operating in fuel engine control:
燃料动力替代方案1:在前述实施例1、3、5、6、7、8、9、11、13、17、18、21、22、24、25、28、29、31、32、33中,如计算公式中包含Kem则拆分成Ke*Km,机械传动系统的效率系数的Km的运算可保持不变,将电磁转矩Te和电机效率系数Ke的运算,替换成相应的前端的燃料动力参数和燃料动力系统的效率系数或转化系数Kfa的运算,通过该燃料动力参数和该Kfa可计算出燃料 发动机的驱动转矩Tr1(具体燃料动力参数的获取、Tr1的计算方式,参考前述第一部分内容中4.2.2.3内容);Fuel Power Alternative 1: In the foregoing Examples 1, 3, 5, 6, 7, 8, 9, 11, 13, 17, 18, 21, 22, 24, 25, 28, 29, 31, 32, 33 If the calculation formula contains Kem, it is split into Ke*Km, and the Km of the efficiency coefficient of the mechanical transmission system can be kept unchanged, and the calculation of the electromagnetic torque Te and the motor efficiency coefficient Ke is replaced by the corresponding front-end fuel. Calculation of the power parameter and the efficiency coefficient of the fuel power system or the conversion coefficient Kfa, by which the fuel can be calculated from the fuel dynamic parameter and the Kfa The driving torque Tr1 of the engine (the acquisition of the specific fuel dynamic parameters, the calculation method of Tr1, refer to the content of 4.2.2.3 in the first part of the foregoing);
例如实施例1中表达式(Kem*(Te*im/R1))替换为(Ke*Km*(Te*im/R1)),进而替换为(Km*F1*Kf3*R0*im/R1);则表示将发动机内的气缸压力F1作为源动力参数,进而计算出车辆质量的联合运算值;按照该替换方案,可将公式可整理为:m2=(Km*F1*Kf3*R0*im/R1)/(g*μ1)(公式R-A1-1)For example, the expression (Kem*(Te*im/R1)) in Embodiment 1 is replaced by (Ke*Km*(Te*im/R1)), and is replaced by (Km*F1*Kf3*R0*im/R1). Then, the cylinder pressure F1 in the engine is taken as the source power parameter, and then the joint operation value of the vehicle mass is calculated; according to the alternative, the formula can be arranged as: m2=(Km*F1*Kf3*R0*im/ R1)/(g*μ1) (Formula R-A1-1)
例如实施例11中表达式((Ke*Km)*(Te*im/R))替换为(Km*Tr2*Kf6*im/R1);则表示将发动机的负荷报告数据(转矩值)Tr2作为源动力参数,进而计算出车辆质量的联合运算值;按照该替换方案,可将公式可整理为:m2=((Km*Tr2*Kf6*im/R1)–fw)/(g*f*cosθ+g*sinθ+a);For example, the expression ((Ke*Km)*(Te*im/R)) in the embodiment 11 is replaced by (Km*Tr2*Kf6*im/R1); the load report data (torque value) Tr2 of the engine is indicated. As the source dynamic parameter, the joint operation value of the vehicle mass is calculated; according to the alternative, the formula can be organized as: m2=((Km*Tr2*Kf6*im/R1)–fw)/(g*f* Cos θ + g * sin θ + a);
燃料动力替代方案2:在实施例4或实施例10中,如计算公式中包含Kem则拆分成Ke*Km,机械传动系统的效率系数的Km的运算可保持不变,将电机驱动参数中电气功率Pm和相关的电气动力系统的效率系数(如Ke、k13、k14等)的运算,替换成相应的前端的燃料动力参数和相应的燃料动力系统的效率系数或转化系数Kfa的运算,通过该前端的燃料动力参数和该Kfa可计算出燃料发动机的驱动功率Pr1(具体Pr1的获取/计算方式,参考前述第一部分内容中4.2.2.3章节内容)Fuel Power Alternative 2: In Embodiment 4 or Embodiment 10, if Kem is included in the calculation formula, it is split into Ke*Km, and the operation of the Km of the efficiency coefficient of the mechanical transmission system can be kept unchanged, and the motor drive parameters are The calculation of the electrical power Pm and the efficiency coefficient of the relevant electric power system (such as Ke, k13, k14, etc.) is replaced by the corresponding front-end fuel dynamic parameters and the corresponding fuel power system efficiency coefficient or conversion coefficient Kfa. The fuel dynamic parameters of the front end and the Kfa can calculate the driving power Pr1 of the fuel engine (the acquisition/calculation method of the specific Pr1, refer to the section 4.2.2.3 in the first part of the foregoing)
例如实施例10中,当动力装置运行工况为动力装置驱动状态时,表达式((Kem*(|k12*cosφ*Uo*Io|))=(Kem*k12*cosφ*Uo*Io),将(Kem*k12*cosφ*Uo*Io)替换为(Km*Pr1),替换为(Km*fm1*Kf1);则表示将发动机内燃料消耗率fm1作为源动力参数而计算出车辆质量的联合运算值;按照该替换方案,可将公式可整理为:For example, in Embodiment 10, when the operating condition of the power unit is the driving state of the power unit, the expression ((Kem*(|k12*cosφ*Uo*Io|))=(Kem*k12*cosφ*Uo*Io), Replace (Kem*k12*cosφ*Uo*Io) with (Km*Pr1) and replace with (Km*fm1*Kf1); it means that the engine fuel consumption rate fm1 is used as the source power parameter to calculate the joint of vehicle mass. The calculated value; according to the alternative, the formula can be organized as:
μ1_cal=((Km*fm1*Kf1)/V1)–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ),(公式A13-1-2)11_cal=((Km*fm1*Kf1)/V1)–m2*g*sinθ-m2*a-fw)/(m2*g*cosθ), (Formula A13-1-2)
如用fm1作为源动力参数则在动力装置制动状态时可停止计算;If fm1 is used as the source power parameter, the calculation can be stopped when the power unit is in the braking state;
燃料动力替代方案3:在实施例12、15、16、19、20、23、26、27、30中,将电机驱动参数(如Po,P2o,P2i,P3o,P3i等)和相关的电气动力系统的效率系数(如Ke、k31、k21等)的运算,替换成相应的前端的燃料动力参数和相应的效率系数或转化系数Kfa的运算,通过该前端的燃料动力参数和该Kfa可计算出燃料发动机的驱动功率Pr1(具体Pr1的获取/计算方式,参考前述第一部分内容中4.2.2.3章节内容);Fuel Power Alternative 3: In Examples 12, 15, 16, 19, 20, 23, 26, 27, 30, motor drive parameters (such as Po, P2o, P2i, P3o, P3i, etc.) and associated electrical power The calculation of the efficiency coefficient of the system (such as Ke, k31, k21, etc.) is replaced by the corresponding fuel dynamic parameters of the front end and the corresponding efficiency coefficient or conversion coefficient Kfa. The fuel dynamic parameters of the front end and the Kfa can be calculated. The driving power of the fuel engine Pr1 (for the acquisition/calculation of the specific Pr1, refer to the contents of Section 4.2.2.3 in the first part of the above);
例如实施例12中,表达式((Ke*Km)*(P2o/Vx))可写为(Ke*Km*P2o/Vx),将(Ke*Km*P2o)替换为(Km*Pr1),进而替换为(Km*fm2*Kf2);则表示将燃料喷射系统的燃料输入端的燃料消耗率fm2作为源动力参数,进而计算出车辆质量的联合运算值;按照该替换方案,可将公式可整理为:For example, in Embodiment 12, the expression ((Ke*Km)*(P2o/V x )) can be written as (Ke*Km*P2o/V x ), and (Ke*Km*P2o) is replaced by (Km*Pr1) And further replaced by (Km*fm2*Kf2); indicating that the fuel consumption rate fm2 of the fuel input end of the fuel injection system is used as a source power parameter, thereby calculating a joint operation value of the vehicle mass; according to the alternative, the formula can be Can be organized as:
m2=((Km*fm2*Kf2)/Vx)–fw)/(g*f*cosθ+g*sinθ+a); M2=((Km*fm2*Kf2)/V x )–fw)/(g*f*cosθ+g*sinθ+a);
如将上述(Km*fm2*Kf2)替换为(Km*C1*Kf4),则表示将燃料发动机的空气流量C1作为源动力参数,进而计算出车辆质量的联合运算值,可用于汽油动力车辆;If the above (Km*fm2*Kf2) is replaced by (Km*C1*Kf4), it means that the air flow C1 of the fuel engine is used as the source power parameter, and then the joint calculation value of the vehicle mass is calculated, which can be used for the gasoline-powered vehicle;
如将上述(Km*fm2*Kf2)替换为(Km*Pr2*Kf5),则表示将发动机的负荷报告数据(功率值)Pr2作为源动力参数而计算出车辆质量的联合运算值;If the above (Km*fm2*Kf2) is replaced by (Km*Pr2*Kf5), it means that the load calculation data (power value) Pr2 of the engine is used as the source power parameter to calculate the joint operation value of the vehicle mass;
通过上述燃料动力替代方案1、2、3,可在车辆由燃料发动机控制运行时获取测算对象的联合运算值;进而可参考前述实施例34到实施例40的参考数据设定方案和动力传递状况判断方案,根据所述获取的联合运算值和所述测算对象的参考数据判断所述车辆的动力传递状况是否异常,实现完整的动力传递异常监控。Through the fuel power alternatives 1, 2, and 3, the joint operation value of the measurement object can be obtained when the vehicle is controlled by the fuel engine; and the reference data setting scheme and power transmission status of the foregoing embodiment 34 to the embodiment 40 can be referred to. The determining solution determines whether the power transmission status of the vehicle is abnormal according to the acquired joint operation value and the reference data of the measurement object, and implements complete power transmission abnormality monitoring.
后端的源动力参数替代方案:在前述实施例1到实施例33中,所有的源动力参数均默认为前端的源动力参数;如将上述所有实施例中的将电机驱动参数(如Te、Pm、Po,P2o,P2i,P3o,P3i等)和相关的电气动力系统的效率系数(如Ke、k13、k14、k31、k21等)和相关的机械传动系统的效率系数的Km和相关的综合传动比im的运算,替换成后端的源动力参数和相关的后端的效率系数Km3和相关的后端的传动比im3的运算,则可实现用后端的源动力参数计算测算对象的联合运算值;The source power parameter alternative of the back end: in the foregoing Embodiment 1 to Embodiment 33, all the source power parameters are defaulted to the source power parameters of the front end; as in all the above embodiments, the motor drive parameters (such as Te, Pm) , Po, P2o, P2i, P3o, P3i, etc.) and related electrical power system efficiency factors (such as Ke, k13, k14, k31, k21, etc.) and related mechanical transmission system efficiency coefficient Km and related integrated transmission Compared with the operation of im, replacing the source dynamic parameters of the back end and the related back end efficiency coefficient Km3 and the related back end transmission ratio im3, the joint operation value of the measurement object can be calculated by using the source dynamic parameters of the back end;
实施例41:(本实施例为本发明所提供监控方法的优选实施例)Embodiment 41: (This embodiment is a preferred embodiment of the monitoring method provided by the present invention)
本监控方法包括步骤A、B、C;The monitoring method includes steps A, B, and C;
车辆运行条件为:默认动力装置运行工况为动力装置驱动运行;且车辆为混合动力车辆,所述动力装置包括燃料发动机和电机,燃料发动机和电机同时工作,一起驱动车辆运行;电气动力系统驱动前轮运行,Te为电机的电磁转矩,im1为电气动力系统传动比,R1_1为前轮半径,Km1为电气动力系统的机械传动系统的效率系数;燃料动力系统驱动后轮运行,F1为发动机内的气缸压力,im2为燃料动力系统传动比,R1_2为后轮半径,Km2为燃料动力系统的机械传动系统的效率系数;The running condition of the vehicle is: the default power device operating condition is the power device driving operation; and the vehicle is a hybrid vehicle, the power device includes a fuel engine and a motor, the fuel engine and the motor work simultaneously to drive the vehicle to run; the electric power system drives Front wheel operation, Te is the electromagnetic torque of the motor, im1 is the electric power system transmission ratio, R1_1 is the front wheel radius, Km1 is the efficiency coefficient of the mechanical transmission system of the electric power system; the fuel power system drives the rear wheel operation, F1 is the engine The cylinder pressure inside, im2 is the fuel power system transmission ratio, R1_2 is the rear wheel radius, and Km2 is the efficiency coefficient of the mechanical transmission system of the fuel power system;
该监控方法为开机自启动;The monitoring method is booting from startup;
步骤A:本步骤包括步骤A1、步骤A2、步骤A3;Step A: This step includes step A1, step A2, and step A3;
步骤A1:车辆总质量m2(直接联合运算值)计算公式为:Step A1: The calculation formula of the total mass m2 (direct joint operation value) of the vehicle is:
m2=(Ke*Km1*Te*im1/R1_1+Km2*F1*Kf3*R0*im2/R1_2–fw)/(g*f*cosθ+g*sinθ+a);(公式41-1)M2=(Ke*Km1*Te*im1/R1_1+Km2*F1*Kf3*R0*im2/R1_2–fw)/(g*f*cosθ+g*sinθ+a); (Equation 41-1)
运载物品质量m1(间接联合运算值)的计算:Calculation of the mass of the carried item m1 (indirect joint operation value):
m1=m2-m0-mf0;(公式41-2)M1=m2-m0-mf0; (Equation 41-2)
获取预设的时间范围内源动力参数(Te、F1)和系统运行参数(Ke、Km1、im1、R1_1、Km2、Kf3、R0、im2、R1_2、fw、g、f、θ、a、m0、mf0)的值;根据获取的参数值和车辆运动平衡计算公式(公式41-1)计算出m2的联合运算值;进而(通过公式41-2)计算出m1的联合运算值;Obtain the source dynamic parameters (Te, F1) and system operating parameters (Ke, Km1, im1, R1_1, Km2, Kf3, R0, im2, R1_2, fw, g, f, θ, a, m0, in the preset time range) The value of mf0); the joint operation value of m2 is calculated according to the obtained parameter value and the vehicle motion balance calculation formula (formula 41-1); and further, the joint operation value of m1 is calculated (by formula 41-2);
步骤A2:当参考数据已设定后可直接执行步骤A3;当参考数据未设定时,可首先执行下述步 骤设定参考数据:当车辆运行速度首次达到5KM/H时,获取该时候的m1的联合运算值并设定为实际值m1_org;根据为基于基于车辆运动平衡计算计算所得的历史记录值设定动力传递状况识别上限差值m1_def1、动力传递状况识别下限差值m1_def2;也可进而设定动力传递状况识别上限值m1_ref1、动力传递状况识别下限值m1_ref2;m1_def1与m1_def2均为正值,m1_def1与m1_def2相等或不等均允许;并设置一个“参考数据已设定”的状态信息;根据实际值和动力传递状况识别差值设定动力传递状况识别值的公式如下:m1_ref1=m1_org+m1_def1,m1_ref2=m1_org-m1_def2;Step A2: Step A3 can be directly executed after the reference data has been set; when the reference data is not set, the following steps can be performed first. Set reference data: When the running speed of the vehicle reaches 5KM/H for the first time, the joint operation value of m1 at that time is obtained and set to the actual value m1_org; according to the historical value calculated based on the calculation based on the vehicle motion balance calculation The power transmission condition recognition upper limit difference m1_def1, the power transmission condition identification lower limit difference m1_def2; the power transmission status recognition upper limit value m1_ref1 and the power transmission status recognition lower limit value m1_ref2 may be further set; m1_def1 and m1_def2 are both positive values, m1_def1 It is equal to or equal to m1_def2; and a state information of "reference data has been set" is set; the formula for identifying the power transmission status identification value according to the actual value and the power transmission condition identification difference is as follows: m1_ref1=m1_org+m1_def1, M1_ref2=m1_org-m1_def2;
步骤A3:当参考数据已设定后,进行下述4个动力传递状况判断条件中任意一个或多个:判断条件1:((m1-m1_org)>m1_def1);判断条件2:((m1-m1_org)<(-m1_def2));判断条件3:(m1>m1_ref1);判断条件4:(m1<m1_ref2);Step A3: When the reference data has been set, perform one or more of the following four power transmission condition determination conditions: judgment condition 1: ((m1-m1_org)>m1_def1); judgment condition 2: ((m1- M1_org)<(-m1_def2)); judgment condition 3: (m1>m1_ref1); judgment condition 4: (m1<m1_ref2);
步骤B:Step B:
当参考数据未设定时或当车辆处于非稳定驱动状态(当Te小于预设阈值1(如额定值5%)或F1小于预设阈值1(如额定值10%),可判定车辆处于非稳定驱动状态)时,直接执行步骤C;本实施例中可将动力装置制动状态、临界切换区均作为非稳定驱动状态;When the reference data is not set or when the vehicle is in an unsteady driving state (when Te is less than the preset threshold 1 (such as 5% of the rated value) or F1 is less than the preset threshold 1 (such as the rated value of 10%), it can be determined that the vehicle is not When the driving state is stable, step C is directly executed; in this embodiment, the braking state of the power device and the critical switching region are both regarded as unstable driving states;
当参考数据已设定且动力装置运行工况没有处于非稳定驱动状态时,并列执行下述B1、B2、B3、B4步骤,再执行步骤C;When the reference data has been set and the power plant operating condition is not in the unstable driving state, the following steps B1, B2, B3, and B4 are performed in parallel, and then step C is performed;
B1.如步骤A中4个动力传递状况判断条件中任一判断结果为是,则启动动力传递异常处理机制(如语音报警、灯光报警、启动动力传递故障监控机制等);B1. If any of the four power transmission condition determination conditions in step A is YES, the power transmission abnormality processing mechanism (such as voice alarm, light alarm, start power transmission failure monitoring mechanism, etc.) is started;
B2.输出所述判断结果到网络系统、车内人机界面中;B2. outputting the judgment result to the network system and the man-machine interface in the vehicle;
B3.保存所述判断结果到车内硬盘中;B3. Save the judgment result to the in-vehicle hard disk;
B4.输出所述m1的联合运算值到网络系统、车内人机界面中B4. Outputting the joint operation value of the m1 to the network system and the man-machine interface in the vehicle
步骤C:以0.1毫秒为周期循环实时执行步骤A和步骤B1;步骤B2、B3、B4以1秒为周期循环执行;当然,本步骤中各周期的具体时间,可根据各车辆的实际情况或用户需求任意调整;且本步骤为非必需步骤,也即完全允许直接省略本步骤,单独进行A、B循环,或单独执行一次A、B步骤;Step C: Perform step A and step B1 in real time in a cycle of 0.1 milliseconds; steps B2, B3, and B4 are executed in a cycle of 1 second; of course, the specific time of each cycle in this step may be based on the actual situation of each vehicle or User requirements are arbitrarily adjusted; and this step is a non-essential step, that is, it is completely allowed to directly omit this step, separately performing A, B cycles, or performing A and B steps separately;
实施例41的替代实施例1:当车辆工作于纯燃料发动机驱动状态/或电机未启动/或无电气动力系统时,设Te=0,实质上也为取消计算式(Ke*Km1*Te*im1/R1_1);当车辆工作于纯电机驱动状态/或燃料发动机未启动/或无燃料动力系统时,设F1=0,实质上也为取消计算式(Km2*F1*Kf3*R0*im2/R1_2); Alternate Embodiment 1 of Embodiment 41: When the vehicle is operating in a pure fuel engine driving state / or the motor is not activated / or has no electric power system, let Te = 0, and substantially cancel the calculation formula (Ke * Km1 * Te * Im1/R1_1); When the vehicle is operating in a pure motor drive state / or the fuel engine is not activated / or no fuel power system, set F1 = 0, which is also essentially cancel the calculation formula (Km2 * F1 * Kf3 * R0 * im2 / R1_2);
实施例41的替代实施例2:当步骤A中车辆质量的联合运算值的计算过程不在本监控系统内部,可以直接读取外部装置(如车辆中央控制器等)输入的联合运算值m1的结果以替代步骤A1; Alternate Embodiment 2 of Embodiment 41: When the calculation process of the joint operation value of the vehicle mass in the step A is not inside the monitoring system, the result of the joint operation value m1 input by the external device (such as the vehicle central controller, etc.) can be directly read. In place of step A1;
实施例41的替代实施例3:当步骤A中车辆质量的联合运算值的计算过程不在本监控系统内部,可以直接读取外部装置(如车辆中央控制器等)输入的联合运算值m1与实际值的差值m1_def0的结 果以替代步骤A1,m1_def0=(m1-m1_org);在步骤A2中无须设定实际值m1_org,只需设定动力传递状况识别上限差值m1_def1、动力传递状况识别下限差值m1_def2;在步骤A3中可用m1_def0直接替代(m1-m1_org)的值进行判断条件1、或判断条件2的动力传递状况判断; Alternate Embodiment 3 of Embodiment 41: When the calculation process of the joint operation value of the vehicle mass in the step A is not inside the monitoring system, the joint operation value m1 and the actual input of the external device (such as the vehicle central controller, etc.) can be directly read. The difference of the value m1_def0 In the alternative step A1, m1_def0=(m1-m1_org); in step A2, it is not necessary to set the actual value m1_org, and only the power transmission condition identification upper limit difference m1_def1 and the power transmission condition identification lower limit difference m1_def2 are set; in step A3 The m1_def0 can be used to directly replace the value of (m1-m1_org) to judge the condition 1, or determine the power transmission condition of the condition 2;
实施例41的替代实施例4:在步骤A3中当4个动力传递状况判断条件中任意一个或多个的结果为是时,获取与联合运算值m2的取值时同一预设的时间范围内车辆的运行环境信息,当根据获取的运行环境信息判断车辆运行环境正常时,则生成动力传递故障标志有效的信息,触发动力传递故障处理机制进行相关监控保护;当判断车辆运行环境异常时,则仍然只触发动力传递异常处理机制; Alternate Embodiment 4 of Embodiment 41: When the result of any one or more of the four power transmission condition determination conditions is YES in step A3, the time period corresponding to the value of the joint operation value m2 is acquired within the same preset time range The operating environment information of the vehicle, when it is judged that the vehicle operating environment is normal according to the obtained operating environment information, generates information that the power transmission failure flag is valid, triggers the power transmission failure processing mechanism to perform relevant monitoring and protection; when determining that the vehicle operating environment is abnormal, then Still only triggering the power transfer exception handling mechanism;
实施例41的替代实施例5:在步骤A2中根据模糊算法(如自动选择最近一次运行时参考数据)预设动力传递状况识别上限差值m1_def1和动力传递状况识别下限差值m1_def2。 Alternate Embodiment 5 of Embodiment 41: In step A2, the power transmission condition identification upper limit difference m1_def1 and the power transmission condition recognition lower limit difference m1_def2 are preset according to a blurring algorithm (such as automatically selecting the latest runtime reference data).
实施例41的替代实施例6:公式41-2中表达式(Ke*Km1*Te*im1)为前端的电气动力参数相关运算,该表达式也可用(Km3_1*Tr 3_1*im3_1)替代,Tr 3_1为后端的电气动力参数中驱动转矩(可用转矩传感器采集信号),im3_1为电气动力系统的后端的传动比,Km3_1为电气动力系统的后端的效率系数;Alternate Embodiment 6 of Embodiment 41: The expression (Ke*Km1*Te*im1) in Equation 41-2 is an electric dynamic parameter correlation operation of the front end, and the expression can also be replaced by (Km3_1*Tr 3_1*im3_1), Tr 3_1 is the driving torque in the back end electric power parameter (the signal can be collected by the torque sensor), im3_1 is the transmission ratio of the rear end of the electric power system, and Km3_1 is the efficiency coefficient of the rear end of the electric power system;
实施例41的替代实施例7:公式41-1中表达式(Km2*F1*Kf3*R0*im2)为前端的燃料动力参数相关运算,该表达式也可用(Km3_2*Tr 3_2*im3_2)替代,Tr 3_2为后端的燃料动力参数中驱动转矩(可用转矩传感器采集信号),im3_2为燃料动力系统的后端的传动比,Km3_2为燃料动力系统后端的效率系数。Alternate Embodiment 7 of Embodiment 41: The expression (Km2*F1*Kf3*R0*im2) in Equation 41-1 is a fuel-power parameter correlation operation of the front end, and the expression can also be replaced by (Km3_2*Tr 3_2*im3_2) Tr 3_2 is the driving torque in the fuel dynamic parameters of the rear end (the signal can be collected by the torque sensor), im3_2 is the transmission ratio of the rear end of the fuel power system, and Km3_2 is the efficiency coefficient of the rear end of the fuel power system.
实施例41的替代实施例8:实施例41中电气动力系统独立驱动前轮,燃料动力系统独自驱动后轮,公式41-2中表达式(Ke*Km1*Te*im1/R1_1+Km2*F1*Kf3*R0*im2/R1_2)为前端的混合动力参数的计算式;在某些车辆中可以允许电气动力系统和燃料动力系统同时单独驱动前轮或同时单独驱动后轮;如混合动力装置同时驱动同一个驱动轮(如假设为后轮)时,也可以在电气动力系统和燃料动力系统的共同作用的车辆后端的某个位置采集同时包含了电气动力和燃料动力信息的后端的混合动力参数(如转矩Tr 3_3);该表达式也可用(Km3_3*Tr 3_3*im3_3)替代,Tr 3_3为后端的混合动力参数中驱动转矩(可用转矩传感器采集信号),im3_3为混合动力系统的后端的传动比,Km3_3为混合动力系统后端的效率系数。则公式41-1可用下述公式41-8替代:Alternate Embodiment 8 of Embodiment 41: The electric power system of Embodiment 41 independently drives the front wheel, and the fuel power system drives the rear wheel alone, and the expression in Equation 41-2 (Ke*Km1*Te*im1/R1_1+Km2*F1 *Kf3*R0*im2/R1_2) is the calculation formula of the hybrid parameters of the front end; in some vehicles, the electric power system and the fuel power system may be allowed to simultaneously drive the front wheels separately or simultaneously to drive the rear wheels separately; for example, the hybrid device simultaneously When driving the same drive wheel (if assumed as the rear wheel), it is also possible to collect the hybrid parameters of the rear end containing both electric power and fuel power information at a certain position of the vehicle rear end of the electric power system and the fuel power system. (eg torque Tr 3_3); this expression can also be replaced by (Km3_3*Tr 3_3*im3_3), Tr 3_3 is the driving torque in the hybrid parameters of the back end (the available torque sensor collects the signal), and im3_3 is the hybrid system. The transmission ratio of the rear end, Km3_3 is the efficiency coefficient of the rear end of the hybrid system. Then Equation 41-1 can be replaced by the following formula 41-8:
m2=(Km3_3*Tr 3_3*im3_3/R1_2–fw)/(g*f*cosθ+g*sinθ+a)M2=(Km3_3*Tr 3_3*im3_3/R1_2–fw)/(g*f*cosθ+g*sinθ+a)
实施例41的替代实施例9:上述公式41-1、公式41-8均为动力装置驱动状态时计算公式;也可根据混合动力参数(驱动转矩Tr 3_3)的值识别动力装置运行工况;如当(Tr 3_3>0)时则可判定为动力装置驱动状态,如当(Tr 3_3<0)时则可判定为动力装置制动状态;当车辆处于动力装置制动状态时,在实施例8基础上计算公式41-9如下:Alternate Embodiment 9 of Embodiment 41: The above formula 41-1 and formula 41-8 are calculation formulas when the power unit is driven; the power unit operating conditions can also be identified according to the value of the hybrid power parameter (driving torque Tr 3_3) If it is (Tr 3_3>0), it can be determined as the power unit driving state. For example, when (Tr 3_3<0), it can be determined as the power unit braking state; when the vehicle is in the power unit braking state, it is implemented. Example 8 is based on the calculation of Equation 41-9 as follows:
m2=((Tr 3_3*im3_3/R1_2)/Km3_3–fw)/(g*f*cosθ+g*sinθ+a),公式41-9根据本计算公式41-9可在车辆处于动力装置制动状态时进行更准确计算; M2=((Tr 3_3*im3_3/R1_2)/Km3_3–fw)/(g*f*cosθ+g*sinθ+a), Equation 41-9 can be used in the vehicle braking according to the calculation formula 41-9 More accurate calculations in the state;
实施例41的替代实施例10:步骤A中参考数据的设置由外部系统进行也是可行的;本步骤中只需读取外部已设定好的参考数据,然后将联合运算值与参考数据直接进行判断;Alternate Embodiment 10 of Embodiment 41: It is also feasible to perform the setting of the reference data in the step A by the external system; in this step, it is only necessary to read the externally set reference data, and then directly perform the joint operation value and the reference data. Judge
实施例41的延伸实施例1:在实施例41中,还包括保存所述联合运算值中联合运算值m1与实际值m1_org的差值,以生成历史记录差值; Embodiment 1 of Embodiment 41: In Embodiment 41, further comprising saving a difference between the joint operation value m1 and the actual value m1_org in the joint operation value to generate a history difference value;
实施例41的延伸实施例2:在实施例41中,获取车辆的动力传递状况关联因子中源动力参数(Te和F1)的实际值,当Te小于预设阈值1(如额定值20%)或F1小于预设阈值1(如额定值30%)时将动力传递状况识别上限差值m1_def1和动力传递状况识别下限差值m1_def2各增大一倍,以降低误报率; Extended Embodiment 2 of Embodiment 41: In Embodiment 41, the actual value of the source dynamic parameters (Te and F1) in the power transmission condition correlation factor of the vehicle is obtained, when Te is less than the preset threshold 1 (eg, 20% of the rated value) Or when F1 is less than the preset threshold 1 (such as the rated value of 30%), the power transmission condition recognition upper limit difference m1_def1 and the power transmission condition recognition lower limit difference m1_def2 are each doubled to reduce the false alarm rate;
本发明所提供的监控方法中,优选方案为所有参数的值为实时获取,步骤A、B均为实时执行,且以设定的时间周期循环执行,且该设定的循环周期为越短越好,越短就越能提高监控的灵敏度和时效性。In the monitoring method provided by the present invention, the preferred solution is that the values of all the parameters are acquired in real time, and the steps A and B are performed in real time, and are executed cyclically in a set time period, and the set cycle period is shorter. Well, the shorter the shorter the sensitivity and timeliness of monitoring.
根据前述源动力组合型参数的描述,电气功率可组合出电气能量,燃料消耗率可组合出燃料消耗量,驱动功率可组合出燃料驱动能量;本发明也允许使用能量类型的源动力组合型参数(如某一时间段的电能消耗、或某一时间段的燃烧能量、或某一时间段的油耗、或某一时间段做功的总和)作为测算对象,从动力传递异常监控变为能量传递异常监控;动力与能量从物理概念容易混淆,但是对于车辆运行来说,两者的意义完全不同;动力是能量对时间的微分,具有瞬间-快速的概念,能量是动力在时间上的累计,具有时间延滞-慢速的概念;即使以秒为单位,以每秒消耗的能量作为测算对象/直接监控对象,正如前文分析内容,车辆以120KM的时速运行时可能1秒即33米,33米的距离足以越过公路护栏、足以坠入公路边的悬崖或江河湖海中,1秒足以产生严重的安全事故;从车辆运行参数的取值、计算精度来说,33米也足以越过坡峰从上坡变成下坡,θ值由正变负,因为车辆运动平衡原理的典型计算公式中坡阻分量(m2*g*sinθ)的存在,车辆上坡时与下坡时源动力参数将发生大幅变化,上坡时的源动力参数用于下坡时动力传递异常监控毫无意义,甚至得出相反的、错误的判断;同理,因为变速分量(m2*a)的存在,纵向加速度a值变化前的源动力参数用于a值变化后时动力传递异常监控毫无意义;所以用本发明提供的方案进行动力传递异常监控,最好使用瞬间值源动力参数(如瞬间功率、瞬间转矩、瞬间驱动力、瞬间电流等)进行实时动力传递异常监控;如果使用能量类型的源动力组合型参数进行动力传递异常监控效果,则需将能量累计的时间控制得越小越好(如100毫米、10毫秒、1毫秒、0.1毫米),如果使用100KM的总油耗、100KM的电能、100KM的平均功率等参数,对于车辆安全运行至关重要的瞬时动力传递异常监控,将毫无预警意义,最多只能起到事后检查、善后分析的功能。According to the foregoing description of the source power combination type parameter, the electric power can combine the electric energy, the fuel consumption rate can combine the fuel consumption amount, and the driving power can combine the fuel driving energy; the invention also allows the energy type source power combination parameter to be used. (such as the power consumption of a certain period of time, or the combustion energy of a certain period of time, or the fuel consumption of a certain period of time, or the sum of work of a certain period of time) as a measurement object, from abnormal power transmission monitoring to abnormal energy transmission. Monitoring; power and energy are easily confused from physical concepts, but for vehicle operation, the meaning of the two is completely different; power is the differentiation of energy versus time, with a moment-fast concept, energy is the accumulation of power in time, with Time delay - the concept of slow speed; even in seconds, the energy consumed per second as the object of measurement / direct monitoring object, as the previous analysis, the vehicle may run at 120KM or 1 second, 33 meters, 33 meters A distance sufficient to cross the highway barriers, enough to fall into the cliffs of the road or the rivers and rivers, 1 second is enough to cause serious security Accident; from the value of vehicle operating parameters, calculation accuracy, 33 meters is also enough to cross the slope from the uphill to the downhill, the value of θ changes from positive to negative, because the slope resistance component in the typical calculation formula of the principle of vehicle motion balance (m2*g*sinθ), the source dynamic parameters will change greatly when the vehicle is going uphill and downhill, and the source dynamic parameters when going uphill are used to monitor the abnormality of power transmission when going downhill. The same, wrong judgment; because of the existence of the shifting component (m2*a), the source dynamic parameter before the change of the longitudinal acceleration a value is used for the monitoring of the abnormality of the power transmission after the change of the a value is meaningless; The scheme is to monitor the abnormality of power transmission. It is best to use the instantaneous source power parameters (such as instantaneous power, instantaneous torque, instantaneous driving force, instantaneous current, etc.) for real-time power transmission anomaly monitoring; if using energy type source power combined parameters For the power transmission abnormal monitoring effect, it is necessary to control the energy accumulation time as small as possible (such as 100 mm, 10 msec, 1 msec, 0.1 mm), if 100 KM total fuel consumption, 100 K is used. M power, 100KM average power and other parameters, for the instantaneous power transmission abnormal monitoring that is vital to the safe operation of the vehicle, will have no warning significance, and can only function as post-examination and after-care analysis.
如果用能量类型的源动力组合型参数作为测算对象进行动力传递异常,也需具备核心括号内步骤(为基于基于车辆运动平衡计算计算联合运算值、设定包含动力传递状况识别数据的参考数据、 根据联合运算值和参考数据判断动力传递状况是否异常、对动力传递状况的判断结果有明确的处理方案)可参照下述实施例42:If the power-type combination parameter of the energy type is used as the measurement object for the power transmission abnormality, the core parenthesis step is also required (for calculating the joint operation value based on the vehicle motion balance calculation, setting the reference data including the power transmission condition identification data, According to the joint calculation value and the reference data, it is determined whether the power transmission condition is abnormal or not, and the determination result of the power transmission condition has a clear treatment plan. For the following example 42:
实施例42:本监控方法包括步骤A、B、C;Embodiment 42: The monitoring method includes steps A, B, and C;
该监控方法为接收人工指令后启动(简称人工启动);The monitoring method is started after receiving a manual instruction (referred to as manual startup);
步骤A:本步骤包括步骤A1、步骤A2、步骤A3;Step A: This step includes step A1, step A2, and step A3;
步骤A1:先获取(读取或测量)同一时间范围内的各参数(m1,m0,mf0,g,μ1,θ,a,fw,V1,Km,Ke)的值(如车辆为插电式纯电动车辆,可将mf0设零或直接取消该项),并根据所获取的各参数值,计算电机的电气功率的联合运算值Pm_cal,计算公式如下:Step A1: First (read or measure) the values of each parameter (m1, m0, mf0, g, μ1, θ, a, fw, V1, Km, Ke) in the same time range (if the vehicle is plug-in type) For pure electric vehicles, mf0 can be set to zero or cancel the item directly, and the joint operation value Pm_cal of the electrical power of the motor is calculated according to the obtained parameter values. The calculation formula is as follows:
m2=m1+m0+mf0,M2=m1+m0+mf0,
Pm_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)*V1/(Km*Ke)Pm_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)*V1/(Km*Ke)
进而将联合运算值Pm_cal(进行积分运算)获取在2秒之内的电气能量值EM1_cal,EM1_cal为间接联合运算值;Further, the joint operation value Pm_cal (integral operation) is used to obtain the electrical energy value EM1_cal within 2 seconds, and EM1_cal is an indirect joint operation value;
步骤A2:在上述获取Pm_cal和EM1_cal值同时;获取(读取动力控制装置测算所得数据或用功率表测量)电气功率实际值Pm_r,进而通过Pm_r积分运算获取与EM1_cal同时期的2秒内的电气能量的实测值EM2,或者用有功电表直接测量而获取EM2值;EM2作为参考数据中实际值;设定动力传递状况识别差值EM_def3:EM_def3=EM2/10;设定动力传递状况识别上限值EM_ref1:EM_ref1=EM2+EM_def3;设定动力传递状况识别下限值EM_ref2:EM_ref2=EM2-EM_def3;Step A2: Acquire the Pm_cal and EM1_cal values at the same time; acquire (read the data measured by the power control device or measure with the power meter) the electrical power actual value Pm_r, and then obtain the electrical within 2 seconds of the EM1_cal period by the Pm_r integral operation. The measured value of energy EM2, or directly measured by the active electricity meter to obtain the EM2 value; EM2 as the actual value in the reference data; set the power transmission status identification difference EM_def3: EM_def3 = EM2/10; set the upper limit of the power transmission status identification EM_ref1: EM_ref1=EM2+EM_def3; set the power transmission status recognition lower limit value EM_ref2: EM_ref2=EM2-EM_def3;
步骤A3:进行下述4个动力传递状况判断条件中任意一个或多个:判断条件1:((EM1_cal-EM2)>EM_def3)、判断条件2:((EM1_cal-EM2)<(-EM_def3))、判断条件3:(EM1_cal>EM_ref1)、判断条件4:(EM1_cal<EM_ref2)Step A3: Perform one or more of the following four power transmission condition determination conditions: judgment condition 1: ((EM1_cal-EM2)>EM_def3), judgment condition 2: ((EM1_cal-EM2)<(-EM_def3)) , judgment condition 3: (EM1_cal> EM_ref1), judgment condition 4: (EM1_cal < EM_ref2)
步骤B:如步骤A4中4个动力传递状况判断条件中任一判断结果为是,则启动动力传递异常处理机制(如语音报警等);Step B: If any of the four power transmission condition determination conditions in step A4 is YES, the power transmission abnormality processing mechanism (such as voice alarm, etc.) is started;
实施例42的替代方案1:如车辆为燃料动力车辆时,可用发动机内燃料消耗率fm1替代电机的电气功率,用燃料能量替代电气能量,用Kf1替代Ke;可将实施例42中联合运算公式改写成如下: Alternative 1 of Embodiment 42: When the vehicle is a fuel-powered vehicle, the electric power of the motor can be replaced by the fuel consumption rate fm1 in the engine, the electric energy is replaced by the fuel energy, and Ke is replaced by Kf1; the joint operation formula in Embodiment 42 can be used. Rewritten as follows:
fm1_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)*V1/(Km*Kf1),Fm1_cal=(m2*g*μ1*cosθ+m2*g*sinθ+m2*a+fw)*V1/(Km*Kf1),
进而将联合运算值fm1_cal(进行积分运算)获取在2秒之内的燃料能量值EM1_cal从而实现用燃料能量来进行动力传递异常监控;Further, the joint operation value fm1_cal (integral operation) is used to obtain the fuel energy value EM1_cal within 2 seconds to realize the power transmission abnormality monitoring using the fuel energy;
实施例42的替代方案2:因为对源动力参数进行时间累积或积分处理可得到能量消耗的数据,可将能量计算的时间周期从2秒设为1秒、0.1秒、0.01秒等;;时间越长,时间越长,如超过5秒10秒或20秒或30秒或一分钟之内或10分钟之内或30分钟之内或以1小时之内或一天之内等,则动力传递异常监控的意义越弱;也即当源动力参数为能量类型的源动力组合型参数时,能量累计 的时间可控制在十天之内或五天之内或一天之内或五小时之内或以1小时之内或30分钟之内或10分钟之内或一分钟之内或30秒之内或20秒之内或10秒之内或5秒之内或2秒之内或1秒之内或100毫米之内或10毫秒之内或1毫秒之内或0.1毫米之内;时间越短,动力传递异常监控响应越快,但是联合运算值、实测值、参考数据的(四个诱因所致)测量误差将越大/效果越差/成本也升高;由此可见,将源动力参数或将源动力组合型参数(如能量)作为测算对象的动力传递异常监控效果,远不如将车辆质量或系统固有参数作为测算对象。 Alternative 2 of Embodiment 42: The data of energy consumption can be obtained by performing time accumulation or integration processing on the source dynamic parameters, and the time period of energy calculation can be set from 2 seconds to 1 second, 0.1 second, 0.01 second, etc.; The longer, the longer the time, such as more than 5 seconds 10 seconds or 20 seconds or 30 seconds or within one minute or within 10 minutes or within 30 minutes or within 1 hour or within one day, the power transmission is abnormal. The weaker the meaning of monitoring; that is, when the source dynamic parameter is the source-power combination type parameter of the energy type, the energy accumulation The time can be controlled within ten days or within five days or within one day or within five hours or within one hour or within 30 minutes or within 10 minutes or within one minute or within 30 seconds or Within 20 seconds or within 10 seconds or within 5 seconds or within 2 seconds or within 1 second or within 100 millimeters or within 10 milliseconds or within 1 millisecond or within 0.1 millimeters; the shorter the time, the power The faster the response monitoring response is transmitted, but the combined calculation value, measured value, and reference data (caused by four incentives) will be larger/the effect will be worse/cost will also increase; thus, the source dynamic parameter will be The source-power combination parameter (such as energy) is used as the measurement object for the power transmission anomaly monitoring effect, which is far less than the vehicle quality or system inherent parameters.
在上述动力传递监控方法和系统中,允许系统根据需要切换测算对象,甚至同时启用多个测算对象,进行多个不同测算对象的多个动力传递状况判断;如既允许以车辆质量作为测算对象进行动力传递状况判断和监控,同时也允许以滚阻系数作为另一个测算对象进行另一个动力传递状况判断和监控,只要任意一个或多个动力传递状况判断结果为动力传递异常,则启动动力传递异常处理机制;In the above power transmission monitoring method and system, the system is allowed to switch the measurement object as needed, and even multiple measurement objects are simultaneously enabled to perform multiple power transmission status determinations of a plurality of different measurement objects; if the vehicle quality is allowed as the measurement object The power transmission condition is judged and monitored, and the rolling resistance coefficient is also allowed to be used as another measurement object to perform another power transmission condition judgment and monitoring. As long as any one or more power transmission condition determination results are abnormal power transmission, the power transmission abnormality is started. Processing mechanism
在监控过程中,也允许系统切换源动力参数,如车辆低速高转矩运行时,可以用转矩类型的参数作为源动力参数;如车辆以高速低转矩运行时,可以用功率类型的参数作为源动力参数,以提高测算对象的联合运算值计算精度,提高动力传递异常监控的灵敏度;In the monitoring process, the system is also allowed to switch the source power parameters. For example, when the vehicle is running at low speed and high torque, the torque type parameter can be used as the source power parameter; if the vehicle is running at high speed and low torque, the power type parameter can be used. As the source dynamic parameter, the calculation accuracy of the joint operation value of the measurement object is improved, and the sensitivity of the power transmission abnormality monitoring is improved;
也允许以同一个测算对象,采用多个源动力参数同时进行同一个测算对象的多个联合运算值的测算,进行多个动力传递状况判断和监控;如在外部电网供电的高铁中,以车辆质量为测算对象,以电机的电磁转矩Te作为源动力参数构建一个动力传递状况判断和监控#100系统,则该系统可以监控电机及后端机械传动系统;同时以电源输入电气功率P3i作为为源动力参数构建另一个动力传递状况判断和监控#101系统,则该系统可以同时监控高铁的电源装置、电机驱动装置、电机及后端机械传动系统;如果仅仅启用#100系统(未启用#101系统)监控电机及后端机械传动系统,则可直接用P3i和电机的电气功率Pm和效率系数k31验证高铁的电源装置、电机驱动装置的动力传递状况是否正常,验证方法为判断((P3i*k31)-Pm)的计算结果是否超过预设阈值(如P3i/20),如超过则电源装置或电机驱动装置运行异常;It is also allowed to use the same measurement object to simultaneously measure multiple joint operation values of the same measurement object by using multiple source dynamic parameters, and perform multiple power transmission status judgments and monitoring; for example, in a high-speed rail powered by an external power grid, a vehicle is used. The mass is the measurement object, and the motor electromagnetic torque Te is used as the source power parameter to construct a power transmission condition judgment and monitoring #100 system, then the system can monitor the motor and the rear mechanical transmission system; at the same time, the power input electric power P3i is used as the The source power parameter constructs another power transmission condition judgment and monitoring #101 system, then the system can simultaneously monitor the high-speed rail power supply unit, motor drive unit, motor and rear-end mechanical transmission system; if only the #100 system is enabled (#101 is not enabled) System) monitoring motor and rear mechanical transmission system, can directly verify the power transmission status of high-speed rail power supply unit and motor drive unit with P3i and motor electric power Pm and efficiency coefficient k31. The verification method is judged ((P3i* Whether the calculation result of k31)-Pm) exceeds a preset threshold (such as P3i/20), and if it exceeds, the power supply device Motor driving means operating abnormally;
如燃料动力车辆中,以气缸压力F1为燃料动力参数构建一个动力传递状况判断和监控#102系统,监控燃料发动机活塞及后端机械传动系统;同时根据燃料喷射系统的燃料输入端的燃料消耗率fm2和能量转化系数Kf2判断燃料喷射系统和发动机气缸内燃烧系统的动力传递状况是否正常,判断((fm2*Kf2)-(F1*Kf3*R0*n1/9.55))是否超过预设阈值(如(F1*Kf3*R0*n1/9.55)/20),如超过则燃料喷射系统或发动机气缸内燃烧系统异常。For example, in a fuel-powered vehicle, a power transmission condition determination and monitoring #102 system is constructed with the cylinder pressure F1 as a fuel power parameter, and the fuel engine piston and the rear mechanical transmission system are monitored; and the fuel consumption rate fm2 according to the fuel input end of the fuel injection system is also used. And the energy conversion coefficient Kf2 determines whether the power transmission condition of the fuel injection system and the combustion system of the engine cylinder is normal, and judges whether ((fm2*Kf2)-(F1*Kf3*R0*n1/9.55)) exceeds a preset threshold (eg ( F1*Kf3*R0*n1/9.55)/20), if exceeded, the combustion system of the fuel injection system or engine is abnormal.
总体而言,在本发明提供的一种车辆由动力装置控制运行时的监控方法及系统的基础上,根据车辆的动力传递原理,进行逐层或多层的动力传递异常监控,可在车辆运行参数未超过安全极限阈值时,便于对车辆的整体动力系统、机械传动系统进行全方位的灵敏而准确的保护。In general, based on the monitoring method and system for controlling the operation of the vehicle by the power device, the power transmission abnormality monitoring of the layer-by-layer or multi-layer is performed according to the power transmission principle of the vehicle, and can be operated in the vehicle. When the parameter does not exceed the safety limit threshold, it is convenient for all-round sensitive and accurate protection of the vehicle's overall power system and mechanical transmission system.
特别声明:在本发明中,在采用燃料电池供电的电动车辆中,属于一种相对特殊的情况;该燃 料是指能源供应的类型;因为其直接驱动车辆纵向运行的动力装置是电机,所以通常可视为电气动力车辆。如果车辆运动平衡计算中的源动力参数为电机驱动参数,则自然可采用电气动力车辆的动力传递状况监控方案;Special statement: In the present invention, in an electric vehicle powered by a fuel cell, it is a relatively special case; The material refers to the type of energy supply; since the power unit that directly drives the longitudinal operation of the vehicle is a motor, it is generally regarded as an electric power vehicle. If the source power parameter in the vehicle motion balance calculation is a motor drive parameter, the power transmission condition monitoring scheme of the electric power vehicle can be naturally adopted;
但也可将燃料电池与和其相连的电机作为一个整体视为燃料动力装置;如果参与车辆运动平衡计算的源动力参数为直接与燃料相关的参数(如燃料消耗率、燃料消耗量等)作为,此时也自然可采用燃料动力车辆的动力传递状况监控方案;However, the fuel cell and the motor connected to it may be regarded as a fuel power device as a whole; if the source power parameter participating in the vehicle motion balance calculation is a direct fuel-related parameter (such as fuel consumption rate, fuel consumption, etc.) as At this time, the power transmission condition monitoring scheme of the fuel-powered vehicle can also be naturally adopted;
本文中实施例1至实施例33以及公式13.1至13.6,重点为提供在多种条件下的为基于基于车辆运动平衡计算计算测算对象的联合运算值的实施方式;本文中实施例34至42,重点为提供多种参考数据的设置方式以及判断动力传递状况的实施方式; Embodiments 1 through 33 and Equations 13.1 to 13.6 herein focus on providing an embodiment for calculating joint operation values of measured objects based on vehicle motion balance calculation under various conditions; embodiments 34 to 42 herein, The focus is on providing a variety of reference data settings and methods for determining the power transfer status;
本发明允许将任意一种车辆运行参数作为测算对象,允许参考本申请文件中任一计算公式变形作为新的测算对象的联合运算值的计算方式,允许参考本申请文件中任意一种获取测算对象的联合运算值的获取联合运算值,允许参考本申请文件中任意一种参考数据的设置方式获取参考数据,允许参考本申请文件中任一种动力传递状况判断方式进行判断,允许参考本申请文件中任一种后续处理方式进行处理,可以任意构建新的监控方法。The invention allows any vehicle operating parameter to be used as a measurement object, and allows the calculation of the joint calculation value of the new measurement object with reference to any calculation formula in the present application, and allows the measurement object to be obtained by referring to any one of the application documents. The joint operation value of the joint operation value is allowed to obtain the reference data by referring to the setting manner of any reference data in the application file, and is allowed to be judged by referring to any power transmission status judgment manner in the application file, and the reference is allowed to refer to the application file. Any of the subsequent processing methods can be used to construct a new monitoring method.
例如前述的参考数据的值域设定的较优规则示例1,演示了以机械运行参数(如纵向速度)为测算对象的参考数据的值域设定的一个例子;如本文中所述参考数据设置的示范方法4和5所述,源动力参数、机械运行参数、质量变化型物品质量具有同一特征类型(均属于幅值可能大幅变化的测算对象),可以采用类同的参考数据设置方法(如均可通过实测值设置参考数据),显而易见的,当测算对象为源动力参数、质量变化型物品质量中任一参数时,也可参考前述示例1的参考数据的值域设定方法。For example, the preferred rule example 1 of the range setting of the aforementioned reference data demonstrates an example of the value range setting of the reference data with the mechanical operating parameters (such as the longitudinal velocity) as the measurement object; the reference data as described herein. According to the set demonstration methods 4 and 5, the source dynamic parameters, mechanical operating parameters, and quality-changing item qualities have the same feature type (both of which are measurement objects whose amplitude may vary greatly), and the same reference data setting method can be used ( If the reference data can be set by the measured value, it is obvious that when the measurement object is any one of the source dynamic parameter and the quality change type item quality, the value range setting method of the reference data of the foregoing example 1 can also be referred to.
例如当测算对象为车辆总质量时,因其值自然的包括的运载物品质量的值,自然也可采用前述示例2的参考数据的值域设定方法;For example, when the measured object is the total mass of the vehicle, the value range setting method of the reference data of the foregoing example 2 may naturally be adopted because of the value of the quality of the carried item naturally included in the value;
例如当测算对象为系统固有参数时,因其具有与车辆总质量、运载物品质量具有另一共同特征(显而易见的,也即在当次的运行流程中,其值变化较小或不变),自然也可采用前述示例2的参考数据的值域设定方法;当然也允许采用其他的值域设定方法;For example, when the measured object is a system-independent parameter, it has another common characteristic with the total mass of the vehicle and the quality of the carried item (obviously, that is, the value changes little or unchanged in the current running process), Naturally, the value range setting method of the reference data of the foregoing example 2 can also be employed; of course, other value range setting methods are also allowed;
例如参考实施例36包含参考数据设置方式2的分支方案,显而易见的,可设置其他类型的测算对象(如源动力参数、机械运行参数、质量变化型物品质量等参数)的第二参考数据,判断其实际值大于根据联合运算值设定的上限值是否成立,和/或判断其实际值小于根据联合运算值设定的下限值是否成立;显而易见的,也可参考前述参考数据的值域设定方法,可限定该根据联合运算值设定的下限值大于安全极限阈值中最小值,和/或该实际值大于安全极限阈值中最小值,和/或:限定该根据联合运算值设定的上限值小于安全极限阈值中最大值,和/或该实际值小于安全极限阈值中最 大值;For example, reference embodiment 36 includes a branching scheme of reference data setting mode 2. Obviously, second reference data of other types of measurement objects (such as source dynamic parameters, mechanical operating parameters, quality-changing item quality, etc.) may be set and judged. Whether the actual value is greater than the upper limit value set according to the joint operation value, and/or whether the actual value is smaller than the lower limit value set according to the joint operation value; obviously, the value range of the aforementioned reference data may also be referred to. The setting method may be configured to limit the lower limit value set according to the joint operation value to be greater than a minimum value of the safety limit threshold value, and/or the actual value is greater than a minimum value of the safety limit threshold value, and/or: limiting the setting according to the joint operation value The upper limit value is less than the maximum value of the safety limit threshold, and/or the actual value is less than the safety limit threshold Large value
例如可将纵向速度Vx作为测算对象,参考实施例12中计算公式(m2=((Ke*Km)*(P2o/Vx)–fw)/(g*f*cosθ+g*sinθ+a)),进而变形、设立新的计算方式:Vx=(Ke*Km)*P2o/(m2*(g*f*cosθ+g*sinθ+a)+fw),进而参考本申请文件中其他部分内容,将纵向速度的实测值作为实际值以及进一步设定参考数据,进而进行动力传递状况判断,进而进行B步骤的判断后处理;For example, the longitudinal velocity V x can be used as a measurement object, and the calculation formula in the embodiment 12 is referred to (m2=((Ke*Km)*(P2o/V x )−fw)/(g*f*cosθ+g*sinθ+a) )), and then deformed, set up a new calculation method: V x = (Ke * Km) * P2o / (m2 * (g * f * cos θ + g * sin θ + a) + fw), and then refer to other For some contents, the measured value of the longitudinal velocity is taken as the actual value and the reference data is further set, and then the power transmission condition is judged, and then the post-determination processing of the B step is performed;
例如可将车辆的电机的电磁转矩作为测算对象,参考实施例28中计算公式(Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)*im/R)),参考实施例41或其替换实施例或其延伸实施例获取测算对象的联合运算值;进而参考实施例40或本申请文件中其他处内容,根据电磁转矩的实测值Te作为实际值和设定参考数据,进而进行动力传递状况判断,进而进行B步骤的判断后处理,如所述判断结果包括是则启动设定的动力传递异常处理机制和/或保存判断结果和/或输出判断结果;For example, the electromagnetic torque of the motor of the vehicle can be used as a measurement target, and the calculation formula in the embodiment 28 is referred to (Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)) *im/R)), refer to Embodiment 41 or its alternative embodiment or its extended embodiment to obtain a joint operation value of the measurement object; and further refer to Embodiment 40 or other contents in the present application, based on the measured value of the electromagnetic torque Te is used as the actual value and the setting reference data, and further determines the power transmission condition, and further performs the post-decision processing of the B step. If the determination result includes the start, the set power transmission abnormality processing mechanism and/or the save determination result and / or output the judgment result;
例如前述的实施例28,其中提供公式为;For example, the aforementioned embodiment 28, wherein the formula is provided;
Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)*im/R)),Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)/((Ke*Km)*im/R)),
该公式可变形为:The formula can be transformed into:
((Ke*Km)*im/R)*Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)((Ke*Km)*im/R)*Te_cal=(m2*(g*f*cosθ+g*sinθ+a)+fw)
该公式的左边(((Ke*Km)*im/R)*Te_cal)的计算式为动力装置生成车辆驱动力(如称为F1),右边(m2*g*f*cosθ+m2*g*sinθ+m2*a+fw)的计算式表示车辆的机械类综合运行力(如称为Y1);如将高铁车辆的全部车厢视为一个整体车辆,则可直接采用该计算公式;The formula on the left side of the formula ((Ke*Km)*im/R)*Te_cal) is the vehicle driving force generated by the power unit (called F1), and the right side (m2*g*f*cosθ+m2*g*) The calculation formula of sin θ+m2*a+fw) represents the comprehensive operational force of the vehicle (referred to as Y1); if all the cars of the high-speed rail vehicle are regarded as one integral vehicle, the calculation formula can be directly adopted;
假设该高铁车辆可分为3节(或3段),每节(或每段)均有单独的动力装置,则可生成多个车辆驱动力(如F1,F2,F3),每节(或每段)车辆的各自的对应机械类综合运行力(如Y1,Y2,Y3);当每节(或每段)车辆的运行参数(f、θ、a、fw)不同时(尤其为路面坡度θ不同时),可单独测算该节(或该段)车辆的机械类综合运行力(如Y1或Y2或Y3),然后再用公式:F1+F2+F3=Y1+Y2+Y3;该方式可适用于具有多节(或多段)车辆的运行。Assuming that the high-speed rail vehicle can be divided into three sections (or three sections), each section (or each section) has a separate power unit, which can generate multiple vehicle driving forces (such as F1, F2, F3), each section (or Each segment) the corresponding mechanical class of the vehicle (such as Y1, Y2, Y3); when the operating parameters (f, θ, a, fw) of each segment (or each segment) are different (especially the road gradient) When θ is different, the mechanical comprehensive running force of the vehicle (such as Y1 or Y2 or Y3) of the section (or the section) can be separately measured, and then the formula: F1+F2+F3=Y1+Y2+Y3; Can be applied to the operation of vehicles with multiple sections (or multiple sections).
参数的值(如联合运算值、参考数据、计算联合运算值所需求的输入参数的值)的取值时间与获取时间的说明;本发明所述取值时间,指参数生成时时间,指计算该参数所需求的输入参数的值所对应的时间;因为获取有多种方式(读取、测量等);如读取在time1时间前100毫秒所生成的参数值,则该参数的获取时间为time1,但该参数的取值时间为time1时前100毫秒的时间;The value of the parameter (such as the joint operation value, the reference data, the value of the input parameter required to calculate the joint operation value) and the acquisition time; the time value of the present invention refers to the time when the parameter is generated, and refers to the calculation The time corresponding to the value of the input parameter required by the parameter; because there are multiple ways to acquire (read, measure, etc.); if the parameter value generated by 100 milliseconds before the time1 time is read, the acquisition time of the parameter is Time1, but the value of this parameter is the first 100 milliseconds of time1;
本发明中,当所述测算对象为需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时,较优方案是所有参数(如联合运算值、参考数据、计算联合运算值所需求的输入参数的值)都在预设的时间范围内取值(尽量同步)、实时计算、实时获取(读取或测量)联合运算值和参考数据、实时判断、实时处置判断结果,在此时,参数的取值时间可等同于获取时间; In the present invention, when the measurement object is any parameter to be measured and/or measurable parameter and/or source dynamic parameter and/or mechanical operation parameter and/or mass change item quality, the optimal solution All parameters (such as joint operation values, reference data, and values of input parameters required to calculate joint operation values) are taken within a preset time range (as much as possible), real-time calculation, real-time acquisition (read or measurement) The joint operation value and the reference data, the real-time judgment, and the judgment result in real time are processed. At this time, the value of the parameter may be equal to the acquisition time;
当所述测算对象为车辆质量、系统固有参数中任意一种参数,联合运算值(连同计算联合运算值所需求的参数的值)的取值时间较优方式为都在预设的时间范围内取值(尽量同步)、实时计算、实时获取(读取或测量)、实时进行动力传递异常判断/监控;但参考数据的取值时间(设定时间)不需要与联合运算值的取值时间在同一时间;则进行动力传递异常判断前的参考数据的获取时间(只需读取)与参考数据的取值时间允许不同;When the measured object is any one of the vehicle quality and the system inherent parameter, the value of the joint operation value (along with the value of the parameter required for calculating the joint operation value) is preferably within a preset time range. Value (as much as possible), real-time calculation, real-time acquisition (read or measurement), real-time power transmission abnormality judgment/monitoring; but the reference data value (set time) does not need to be associated with the joint operation value At the same time; the acquisition time (only read) of the reference data before the power transmission abnormality judgment is different from the reference time of the reference data;
参数值的取值时间的控制方式1:严格意义上来说在同一时间获取多个参数的值,可能不方便实现;在实际操作过程中,各参数组的值的取值时间可能有前有后,在此时只需要将各参数的值的取值时间控制在一个预设的时间范围内,该预设的时间范围可根据实际的软件处理速度、硬件响应速度而定;如可取100毫秒,或10毫秒,或1毫米,或0.1毫秒;该预设的时间范围时间越短,则测算/监控精度越高,但系统成本也增高;The control method of the value of the parameter value 1: In the strict sense, it is inconvenient to obtain the values of multiple parameters at the same time; in the actual operation process, the value of each parameter group may have the value before and after. At this time, it is only necessary to control the value of each parameter to a preset time range, which may be determined according to the actual software processing speed and hardware response speed; if it is 100 milliseconds, Or 10 milliseconds, or 1 millimeter, or 0.1 millisecond; the shorter the preset time range, the higher the measurement/monitoring accuracy, but the system cost is also increased;
参数值的取值时间的控制方式2:如果车辆运行条件基本不变,例如车辆的纵向速度在1小时之内均维持60KM匀速运行,则取纵向速度的当前值,与取纵向速度1小时前的值,效果是一样的;所以各参数值的取值时间的预设的时间范围可根据车辆运行条件来调整,也即当车辆运行条件不变时,可获取该参数在运行条件不变时任意时间点上的值。显而易见,在没有限定说明时,参数的取值,通常为取当前值,通常为取真实值接近或相等的数值;Control of the value of the parameter value 2: If the vehicle operating conditions are basically unchanged, for example, if the longitudinal speed of the vehicle is maintained at 60KM for 1 hour, the current value of the longitudinal speed is taken, and the longitudinal speed is taken 1 hour before. The value is the same; therefore, the preset time range of the value of each parameter value can be adjusted according to the running condition of the vehicle, that is, when the running condition of the vehicle is unchanged, the parameter can be obtained when the operating condition is unchanged. The value at any point in time. Obviously, when there is no limit description, the value of the parameter is usually the current value, which is usually a value that is close to or equal to the true value;
上述参数值的取值时间、获取时间的说明适用于本发明任一实施例。The description of the value time and acquisition time of the above parameter values is applicable to any embodiment of the present invention.
10.进一步的,所述监控方法(#1)中包括下述步骤:获取的车辆的输入参数的值,根据获取的车辆的输入参数的值计算所述联合运算值,所述输入参数为计算所述联合运算值所需求的参数。10. Further, the monitoring method (#1) includes the following steps: acquiring a value of an input parameter of the vehicle, and calculating the joint operation value according to the obtained value of the input parameter of the vehicle, wherein the input parameter is a calculation The parameters required by the joint operation value.
本方案的实施细节:Implementation details of this program:
获取测算对象的联合运算值有多种方式,一种是读取其他设备输出的测算对象的联合运算值,如通过车辆的OBD系统,或电机驱动装置读取已计算好的联合运算值,只需该联合运算值的为基于车辆运动平衡计算公式计算所得;There are many ways to obtain the joint operation value of the measurement object. One is to read the joint operation value of the measurement object output by other devices, such as reading the calculated joint operation value through the OBD system of the vehicle or the motor drive device. The joint operation value is calculated based on the vehicle motion balance calculation formula;
还有一种方式,通过与本监控系统一体化设计系统,在本发明所提供监控系统内,根据预设的车辆运动平衡计算公式也即车辆运动平衡的计算规则(包括表格处理模型,或数学计算公式),获取所述车辆的输入参数的值;所述输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数(也即该输入参数为所述车辆运动平衡计算公式中除所述测算对象外的所有参数);根据所述获取的输入参数的值计算出所述联合运算值;所述输入参数的值的取值时间都在预设的时间范围内;该输入参数的设置规则可见前述的输入参数的设置规则1;In another way, through the integrated design system with the monitoring system, in the monitoring system provided by the present invention, according to a preset vehicle motion balance calculation formula, that is, a vehicle motion balance calculation rule (including a table processing model, or a mathematical calculation) Formulating a value of an input parameter of the vehicle; the input parameter is a parameter required to calculate a value of the measurement object according to the vehicle motion balance calculation formula (that is, the input parameter is in the vehicle motion balance calculation formula) Calculating the joint operation value according to the value of the obtained input parameter; the value of the input parameter is within a preset time range; the input parameter The setting rules can be seen in the setting rules 1 of the aforementioned input parameters;
如在前述实施例9中,获取源动力参数(电磁转矩Te)的值,且获取预设的时间范围内车辆质量(m2)的值和系统运行参数(g、μ1、θ、a、fw、im、R1)的值,再通过实施例9所提供的车辆运动平衡模型计算出机电传动综合的效率系数的联合运算值Kem_cal的值; As in the foregoing embodiment 9, the value of the source power parameter (electromagnetic torque Te) is acquired, and the value of the vehicle mass (m2) and the system operating parameter (g, μ1, θ, a, fw in the preset time range are acquired). , im, R1), and then calculate the value of the joint operation value Kem_cal of the electromechanical transmission integrated efficiency coefficient by the vehicle motion balance model provided in the embodiment 9;
如在前述实施例12中,获取源动力参数(电机输出电气功率P2o)的值,且获取预设的时间范围内系统运行参数(Ke、Km、Vx、fw、g、f、θ、a)的值,再通过实施例12所提供的车辆运动平衡模型(m2=((Ke*Km)*(P2o/Vx)–fw)/(g*f*cosθ+g*sinθ+a))计算出m2的值;As in the foregoing embodiment 12, the power parameter acquisition source (electric motor output power P2o) value, and obtain operating parameter within a preset time system (Ke, Km, V x, fw, g, f, θ, a The value of the vehicle motion balance model provided by the embodiment 12 (m2=((Ke*Km)*(P2o/V x )–fw)/(g*f*cosθ+g*sinθ+a)) Calculate the value of m2;
本方案的有益意义:允许测算对象的联合运算与本监控系统一体化设计,可大为降低监控系统的信号连接、传输成本,降低传输误差。The beneficial significance of this scheme: Allows the joint operation of the measurement object to be integrated with the monitoring system, which can greatly reduce the signal connection and transmission cost of the monitoring system and reduce the transmission error.
11.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括下述步骤:获取所述车辆的运行环境信息;根据所述联合运算值、所述参考数据和所述运行环境信息判断是否发生动力传递异常中的动力传递故障情况。11. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes the steps of: acquiring operating environment information of the vehicle; and according to the joint operation value, The reference data and the operating environment information determine whether a power transmission failure condition in a power transmission abnormality occurs.
该方案的实施细节说明:Details of the implementation of the program:
动力传递异常包括车辆运行环境异常和/或动力传递故障(包括监控系统自身故障);显而易见的,监控系统自身故障自然包括参数获取模块的故障,该参数获取模块尤其指参数的测量模块;车辆运行环境异常包括路况异常、载况异常、车辆打滑、侧倾等;所以可以通过获取所述车辆的运行环境信息排除路况异常、载况等异常情况;特注:本发明所述载况异常指车辆质量在运行过程中的异常变动(例如人员跳车、运载物品质量异常、尾端车厢脱落等),其与超载有重大区别。The abnormality of power transmission includes abnormal operating environment of the vehicle and/or fault of power transmission (including the fault of the monitoring system itself); obviously, the fault of the monitoring system itself naturally includes the fault of the parameter acquisition module, and the parameter acquisition module refers especially to the measurement module of the parameter; Environmental anomalies include abnormal road conditions, abnormal load conditions, vehicle slippage, roll, etc.; therefore, abnormal conditions such as abnormal road conditions and load conditions can be excluded by acquiring the operating environment information of the vehicle; Abnormal changes during operation (such as personnel jumping, abnormal quality of the carried items, falling off of the tail compartment, etc.) are significantly different from overloading.
典型路况异常:平坦路面上的道路减速带、超过一定体积的石头、砖块、树木等;典型载况异常:车辆运载人员/物品异常的跳动等;Typical road conditions are abnormal: road speed bumps on flat roads, stones exceeding a certain volume, bricks, trees, etc.; typical load conditions are abnormal: the vehicle carrier/articles are abnormally beating;
运行环境信息的有多种获取方式:可通过相关的振动传感器、加速度传感器测量出车辆在运行中的相对于路面的颠簸度、人员的跳动,可主动的识别路况异常、载况异常情况;可通过光学、超声波、红外传感器、雷达等设施测量识别路况异常(如同倒车雷达可准确识别异物的高度、距离);可通过雨感传感器识别路面的滑湿度;可通过横向设置的倾角传感器或加速度传感器识别车辆的侧倾;车辆的打滑可通过车辆旋转部件的转速数据和实测的纵向速度的比对而获知;所述联合运算值的取值时间和所述运行环境信息的取值时间都在预设的时间范围内。运行环境信息也即外部环境信息。运行环境信息异常指该信息的值超过预设的正常范围。There are several ways to obtain the operating environment information: the vibration sensor and the acceleration sensor can measure the bumpiness of the vehicle during operation and the beating of the person, and can actively identify the abnormal road condition and the abnormal condition of the load; It can detect abnormal road conditions through optical, ultrasonic, infrared sensors, radar and other facilities (like the reversing radar can accurately identify the height and distance of foreign objects); the rain sensor can be used to identify the slippery humidity of the road surface; the tilt sensor or acceleration sensor can be set horizontally. Recognizing the roll of the vehicle; the slip of the vehicle can be known by the comparison of the rotational speed data of the rotating component of the vehicle and the measured longitudinal velocity; the time value of the joint operation value and the time value of the operating environment information are both pre-predicted Set within the time range. The operating environment information is also the external environment information. The abnormality of the running environment information means that the value of the information exceeds the preset normal range.
如所测量的运行环境信息均正常而发生了动力传递异常,则可直接判定车辆处于动力传递故障状况;动力传递故障主要包括:车辆旋转件的异常磨损,老化,爆裂,断裂、电机转子抱轴、发动机拉缸、驱动轮锁死、爆胎等;当车辆的动力传递故障监控机制确认发生动力传递故障,通常需要即刻启动减速、停车、故障告警等紧急处理方案;If the measured operating environment information is normal and the power transmission abnormality occurs, the vehicle can be directly determined that the vehicle is in a power transmission failure condition; the power transmission failure mainly includes: abnormal wear, aging, bursting, breaking, and motor rotor holding shaft of the rotating part of the vehicle , engine pull cylinder, drive wheel lock, puncture, etc.; when the vehicle's power transmission fault monitoring mechanism confirms the occurrence of power transmission failure, usually need to immediately start deceleration, parking, fault alarm and other emergency treatment programs;
如所测量的运行环境信息有异常情况而发生了动力传递异常,则可判定车辆当前的动力传递异常可能是因外部环境而引起;车辆可继续发出动力传递异常警示信息而非动力传递故障信息;同时车辆可继续进行监控运行判断动力传递异常是否随运行环境异常的消除而消除,如果不能同步消除或动力传递异常持续超过设定时间,则仍然可判定动力传递故障;If the measured operating environment information has an abnormal situation and a power transmission abnormality occurs, it may be determined that the current power transmission abnormality of the vehicle may be caused by the external environment; the vehicle may continue to issue the power transmission abnormal warning information instead of the power transmission failure information; At the same time, the vehicle can continue to perform the monitoring operation to determine whether the power transmission abnormality is eliminated with the elimination of the abnormality of the operating environment. If the synchronous cancellation or the power transmission abnormality continues to exceed the set time, the power transmission failure can still be determined;
本方案的有益意义:根据所述获取的联合运算值、所述参考数据和所述运行环境信息,直接判 断是否发生动力传递故障,相较于后续的先判断动力传递异常再判断动力传递故障,可提高车辆在动力传递故障的安全响应速度。The beneficial significance of the solution: directly judged according to the acquired joint operation value, the reference data and the operating environment information Whether the power transmission failure occurs, and the power transmission failure is judged compared with the subsequent judgment of the power transmission abnormality, which can improve the safety response speed of the vehicle in the power transmission failure.
12.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括下述方案:12. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes the following solutions:
当所述测算对象为除车辆质量之外的车辆运行参数中任一参数时,计算所述联合运算值所需求的车辆质量为基于时间在先的车辆运动平衡计算所得;也即:当输入参数中包括车辆质量(通常为车辆总质量)时,该车辆质量(通常为车辆总质量)的值为基于时间在先的车辆运动平衡计算所得When the measurement object is any one of vehicle operating parameters other than the vehicle mass, the vehicle mass required to calculate the joint operation value is calculated based on the time-first vehicle motion balance; that is, when the input parameter When the vehicle mass (usually the total mass of the vehicle) is included, the value of the vehicle mass (usually the total mass of the vehicle) is calculated based on the time-first vehicle motion balance.
本方案的实施说明:The implementation of this program:
如果测算对象为除车辆质量之外的车辆运行参数中任一参数时,则该测算对象的联合运算值计算所需的输入参数中,其必然需要车辆质量的值;该车辆质量的值有多种获取方式,包括人工输入、系统预设等;但用车辆运动平衡计算获取车辆质量的值是较优选择,因为此方案可自动跟随运载物品质量的大幅度变化,提高动力传递异常监控准确度;也即该作为输入参数的车辆质量值,是通过在当次车辆运动平衡计算联合运算值(以进行动力传递状况判断比较)的之前的车辆运动平衡计算所得,是通过在先的车辆运动平衡计算所得;也即可以在车辆运行之初即进行一次甚至多次车辆运动平衡计算以学习、建立车辆质量的基准值;才能自动适应幅值可能大幅变化的车辆质量时(如公交车辆、货车、普通私家车辆),才能自动跟随运载物品质量的大幅度变化。If the measurement object is any one of the vehicle operating parameters other than the vehicle mass, then the input parameter required for the calculation of the joint operation value of the measurement object necessarily requires the value of the vehicle mass; the value of the vehicle mass is large The acquisition method includes manual input, system preset, etc.; however, it is better to use vehicle motion balance calculation to obtain the vehicle quality value, because this scheme can automatically follow the large change of the quality of the carried goods and improve the accuracy of power transmission abnormal monitoring. That is, the vehicle mass value as the input parameter is calculated by calculating the vehicle motion balance before the calculation of the joint operation value (to perform the power transmission condition judgment comparison) in the current vehicle motion balance, and is based on the prior vehicle motion balance. Calculated; that is, one or more vehicle motion balance calculations can be performed at the beginning of the vehicle to learn and establish the vehicle quality reference value; in order to automatically adapt to the vehicle mass whose amplitude may vary greatly (such as buses, trucks, Ordinary private vehicles) can automatically follow the large changes in the quality of the goods carried.
当然,本发明界定的是技术方案,是该车辆质量值的生成途径;该以建立车辆质量基准值的车辆运动平衡计算的具体时间、具体器件并不重要,甚至可以读取其他设备输入的车辆运动平衡计算的输出结果;甚至可以是上一运行流程时车辆运动平衡计算的结果,此时该值也可称为历史记录值。Of course, the present invention defines a technical solution, which is a method for generating the vehicle quality value; the specific time and specific device of the vehicle motion balance calculation for establishing the vehicle quality reference value are not important, and even the vehicle input by other devices can be read. The output of the motion balance calculation; it may even be the result of the vehicle motion balance calculation in the previous running process, and this value may also be referred to as the history value.
本方案的技术效果说明:本方案是本发明非常关键的一个技术方案,当测算对象为除车辆质量之外参数时,只有通过在先的车辆运动平衡建立车辆质量的基准值,才能相对准确进行当前、甚至之后的车辆运动平衡计算、才能进行正常的动力传递状况监控;才能自动适应幅值可能大幅变化的车辆质量(如公交车辆、货车、普通私家车辆的运行),才能自动跟随运载物品质量的大幅度变化。The technical effect of the solution is as follows: This solution is a very technical solution of the present invention. When the measurement object is a parameter other than the vehicle quality, the reference value of the vehicle mass can be established only by the prior vehicle motion balance. Current or even subsequent calculations of vehicle motion balance can be used to monitor normal power transmission conditions; automatically adapt to vehicle quality (such as buses, trucks, and ordinary private vehicles) whose amplitude may vary greatly in order to automatically follow the quality of the carried goods. Great changes.
13.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括下述方案(识别运行工况提高计算性能的方案1):所述联合运算值是根据不同的动力装置运行工况分别进行计算所得;也即先获取动力装置运行工况,将动力装置运行工况与所述计算关联。13. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes the following scheme (the scheme 1 for identifying the operating condition to improve the computing performance): the joint operation The values are calculated according to different operating conditions of the power plant; that is, the operating conditions of the power plant are first obtained, and the operating conditions of the power plant are associated with the calculation.
本方案的实施细节:Implementation details of this program:
车辆在加速、或平坦路面、或上坡运行中,通常处于动力装置驱动状态;车辆在减速、或下坡运行时,很容易进入动力装置制动状态;当源动力参数可简便的测出正负极性时(如电机驱动参数、或其他通过转矩传感器测量所得的源动力参数)也允许在动力装置制动状态进行进行测算对象的联合运算或动力传递异常监控; When the vehicle is in acceleration, flat road or uphill operation, it is usually in the driving state of the power unit; when the vehicle is decelerating or running downhill, it is easy to enter the braking state of the power unit; when the source power parameter can be easily measured The negative polarity (such as motor drive parameters, or other source dynamic parameters measured by the torque sensor) also allows the joint calculation of the measurement object or the power transmission abnormality monitoring in the braking state of the power unit;
如实施例17中或实施例41的替代实施例9所示,先可以用前文内容所提供方法识别所述车辆的动力装置运行工况,再分别进行下述计算;也即先获取动力装置运行工况,将动力装置运行工况与所述计算关联:As shown in the embodiment 17 or the alternative embodiment 9 of the embodiment 41, the power device operating conditions of the vehicle may be identified by the method provided in the foregoing, and the following calculations are respectively performed; that is, the power device operation is first obtained. Working conditions, correlating the operating conditions of the power plant with the calculation:
当动力装置运行工况为动力装置驱动状态时,能量/动力传递方向通常为从动力装置经机械传动系统再传递到车体,计算测算对象的联合运算值时需要将源动力参数的值乘以小于1的效率系数;When the operating condition of the power unit is the driving state of the power unit, the energy/power transmission direction is usually transmitted from the power unit to the vehicle body through the mechanical transmission system, and the value of the source power parameter needs to be multiplied by calculating the joint operation value of the measurement object. An efficiency coefficient less than one;
如实施例17中,当动力装置运行工况为动力装置制动状态时,能量/动力传递方向通常为从车体经机械传动系统再传递到动力装置,计算测算对象的联合运算值需要将源动力参数的值除以小于1的效率系数;As in the embodiment 17, when the operating condition of the power unit is the braking state of the power unit, the energy/power transmission direction is usually transmitted from the vehicle body to the power unit via the mechanical transmission system, and the joint operation value of the calculation object is required to be the source. The value of the dynamic parameter is divided by the efficiency factor less than one;
本方案的有益意义:因为车辆必然经常进入减速或下坡过程,经常进入动力装置制动状态;现有公知技术在进行测算对象的联合运算时对于动力装置制动状态的研究还处于盲区,现有公知技术在驱动时和制动时采用同样的计算公式,从而降低了测算对象的联合运算值的计算/以及动力传递异常监控的准确度;本发明所提供的该技术方案,获取动力装置运行工况,将动力装置运行工况与所述计算关联,相对于现有技术可大幅度测算对象的联合运算值的计算/以及动力传递异常监控的准确度、降低误报率。The beneficial significance of this scheme: Because the vehicle must often enter the deceleration or downhill process, it often enters the braking state of the power unit; the existing known technology is still in the blind zone for the research of the braking state of the power device when performing the joint calculation of the measuring object. The well-known technique adopts the same calculation formula at the time of driving and braking, thereby reducing the calculation of the joint operation value of the measurement object and the accuracy of the power transmission abnormality monitoring; the technical solution provided by the present invention acquires the operation of the power device In the working condition, the operating condition of the power unit is associated with the calculation, and the calculation of the joint calculation value of the object and the accuracy of the power transmission abnormality monitoring and the false alarm rate can be greatly reduced compared with the prior art.
14.进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括下述方案(获取燃料质量提高计算性能的方案1):参与所述计算的参数中包括质量变化型物品质量。14. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes the following scheme (solution 1 for obtaining fuel quality improvement calculation performance): among the parameters participating in the calculation Includes quality of quality change items.
本方案的实施说明:The implementation of this program:
本发明所述质量变化型物品质量主要包括燃料质量;本发明提供的实施例1到实施例33,均忽略了燃料质量,车辆总质量m2采用下述计算公式:m2=m0+m1;在插电式纯电动车辆和外部电源供电式电动车辆(如高铁车辆、动车、电力机车、有轨电车)可应用良好;The quality of the quality change article of the present invention mainly includes the fuel quality; the embodiment 1 to the embodiment 33 provided by the present invention all neglect the fuel quality, and the total mass m2 of the vehicle adopts the following formula: m2=m0+m1; Electric pure electric vehicles and external power supply electric vehicles (such as high-speed rail vehicles, motor trains, electric locomotives, trams) can be applied well;
如大众某款1.6L汽油轿车,整备质量约为1300KG/邮箱容积为55L/燃料为93汽油密度约为0.725KG/L,则该车的燃料质量可在0-40KG变动;与整备质量比值约为0-3%,如联合运算值计算中不考虑燃料质量将导致0-3%的计算误差;For example, a Volkswagen 1.6L petrol car with a kerb mass of about 1300KG/mailbox capacity of 55L/fuel of 93 gasoline density of about 0.725KG/L, the fuel quality of the car can vary from 0-40KG; 0-3%, if the fuel quality is not considered in the calculation of the joint operation value, it will result in a calculation error of 0-3%;
在燃料动力车辆中(或包含燃料动力的插电式混合动力车辆)、燃料电池型电动车辆中,在计算测算对象联合运算值时如考虑燃料质量,则将进一步提供参数测算精度/动力传递异常监控灵敏度;In a fuel-powered vehicle (or a plug-in hybrid vehicle including fuel power) or a fuel cell type electric vehicle, if the fuel mass is considered in calculating the joint calculation value of the measurement object, the parameter measurement accuracy/power transmission abnormality is further provided. Monitoring sensitivity;
剩余燃料质量mf0的获取方法:传感器称重测量mf0值;或通过液位容积、油表等,先测量出剩余燃料体积,再通过相关系数计算出mf0值;The method for obtaining the residual fuel mass mf0: measuring the mf0 value of the sensor weighing; or measuring the remaining fuel volume by the liquid volume, the oil meter, etc., and calculating the mf0 value by the correlation coefficient;
已消耗燃料质量mf1的获取方法:通过流量计测量或读取OBD数据或读取燃料电控喷射系统数据获取已消耗燃料的流量或体积,再通过相关系数计算出mf1的值;The method for obtaining the consumed fuel mass mf1: measuring or reading the OBD data by the flow meter or reading the fuel electronically controlled injection system data to obtain the flow or volume of the consumed fuel, and calculating the value of mf1 by the correlation coefficient;
燃料质量的推算法:用前述方法推算mf1或剩余燃料质量mf0的值;The fuel mass is derived by estimating the value of mf1 or the remaining fuel mass mf0 by the aforementioned method;
当测算对象为运载物品质量m1时,先通过车辆运动平衡计算获取车辆总质量m2的联合运算值, 进而通过m2计算m1值(m1=m2-m0);如获取mf0的值或获取(mf2-mf1)的值并通过下述公式计算m1值;m1=m2-m0-mf0,或m1=m2-m0-(mf2-mf1),从而从而比未包含燃料质量计算所得m1值更能提高动力传递状况判断准确度;When the measured object is the mass m1 of the carrying item, the joint operation value of the total mass m2 of the vehicle is first calculated by calculating the vehicle motion balance. Further, the m1 value (m1=m2-m0) is calculated by m2; if the value of mf0 is obtained or the value of (mf2-mf1) is obtained and the m1 value is calculated by the following formula; m1=m2-m0-mf0, or m1=m2- M0-(mf2-mf1), thereby improving the power transmission condition judgment accuracy more than the m1 value calculated without including the fuel mass;
当测算对象为车辆总质量m2时,通过车辆运动平衡计算获取m2的联合运算值;因为车辆运行中燃料质量在不断的消耗,mf1不断增大/mf0不断变小,实际值m2_org也在不断变小;如获取mf0的值或获取(mf2-mf1)的值并通过下述公式计算实际值m2_org:m2_org=m1+m0+mf0,或m2_org=m1+m0+mf2-mf1;从而比未包含燃料质量计算所得实际值m2_org(该实际值通常用于设定参考数据),更能提高动力传递状况判断的准确度;When the measured object is the total mass m2 of the vehicle, the joint operation value of m2 is obtained by the vehicle motion balance calculation; since the fuel quality is continuously consumed during the running of the vehicle, mf1 is continuously increased/mf0 is continuously smaller, and the actual value m2_org is constantly changing. Small; if the value of mf0 is obtained or the value of (mf2-mf1) is obtained and the actual value m2_org is calculated by the following formula: m2_org=m1+m0+mf0, or m2_org=m1+m0+mf2-mf1; The actual value m2_org calculated by the quality (this actual value is usually used to set the reference data), which can improve the accuracy of the judgment of the power transmission condition;
当测算对象为源动力参数或系统运行参数(非燃料质量的)时,通过车辆运动平衡计算测算对象的联合运算值所需求的车辆质量的值(通常为车辆总质量m2的实际值),也可以获取mf0的值或获取(mf2-mf1)的值进行实时调整(如:m2=m1+m0+mf0,或m2=m1+m0+mf2-mf1);从而间接的调整测算对象的联合运算值计算准确度,从而提高动力传递异常判断的准确度;When the measured object is the source dynamic parameter or the system operating parameter (non-fuel mass), the vehicle mass value (usually the actual value of the total mass m2 of the vehicle) required by the joint calculation value of the measured object is calculated by the vehicle motion balance. You can obtain the value of mf0 or obtain the value of (mf2-mf1) for real-time adjustment (for example: m2=m1+m0+mf0, or m2=m1+m0+mf2-mf1); thus indirectly adjust the joint operation value of the measured object Calculate the accuracy, thereby improving the accuracy of the power transmission abnormality judgment;
实施例43:当测算对象为剩余燃料质量时,先通过车辆运动平衡计算获取车辆总质量m2的联合运算值,进而获取剩余燃料质量的联合运算值mf0_cal:mf0_cal=m2-m0-m1;获取与联合运算值mf0_cal取值时同一时间范围内的剩余燃料质量的(通过油表测量所得的)实测值mf0,且将该实测值作为参考数据中的实际值,同时设动力传递状况识别差值为mf0/5;判断(|mf0_cal-mf0|>(mf0/5))是否成立,如果(|mf0_cal-mf0|>(mf0/5))则判断动力传递异常;Embodiment 43: When the measured object is the remaining fuel mass, the joint operation value of the total mass m2 of the vehicle is first obtained by calculating the vehicle motion balance, and then the joint operation value mf0_cal of the remaining fuel mass is obtained: mf0_cal=m2-m0-m1; The measured value mf0_cal is the measured value mf0 of the remaining fuel mass (measured by the oil meter) in the same time range, and the measured value is used as the actual value in the reference data, and the power transmission condition identification difference is Mf0/5; judge whether (|mf0_cal-mf0|>(mf0/5)) is established, if (|mf0_cal-mf0|>(mf0/5)), it is determined that the power transmission is abnormal;
当所述质量变化型物品质量除了燃料质量外,还包含其他物品的质量的时,也可参照上述方法计算获取;When the quality of the mass change type item includes the quality of other items in addition to the fuel quality, it can also be calculated and obtained by referring to the above method;
本方案的有益意义:通过获取、处理所述车辆的质量变化型物品质量,可在燃料质量波动情况提高参数的计算精度,提高监控的灵敏度、准确度;尤其对于燃料电池式电动车辆,该技术方案可跟踪燃料电池中燃料质量的变化,具有重要意义。The beneficial significance of the scheme: by acquiring and processing the quality of the vehicle of the quality change type, the calculation accuracy of the parameter can be improved in the fluctuation of the fuel quality, and the sensitivity and accuracy of the monitoring can be improved; especially for the fuel cell type electric vehicle, the technology The program can track changes in fuel quality in fuel cells and is important.
15.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中参与所述计算的参数中包括效率系数、滚阻系数、路面坡度中任意一种或多种参数。15. Further, the parameters participating in the calculation in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) include any one of an efficiency coefficient, a rolling resistance coefficient, and a road gradient. A variety of parameters.
本方案的实施说明:(两次变速差值式车辆运动平衡计算参数的方案1)The implementation of this program: (1 of the two-speed differential vehicle motion balance calculation parameters)
车辆运动平衡有多种实现方式:There are several ways to achieve vehicle motion balance:
如实施例3的计算公式:m1=(fq2-fq1)/(a2-a1)-m0;(公式A3-4-3)The calculation formula as in Embodiment 3: m1 = (fq2-fq1) / (a2-a1) - m0; (Formula A3-4-3)
如实施例15的计算公式:m2=((P2o_2/Vx2)-(P2o_1/Vx1))/(a2-a1)The calculation formula as in Example 15: m2 = ((P2o_2/V x 2) - (P2o_1 / V x 1)) / (a2-a1)
(运行条件为:忽略燃料质量;且动力装置运行工况为动力装置驱动状态);(The operating conditions are: ignoring the fuel quality; and the operating condition of the power unit is the driving state of the power unit);
通过上述实施例3或实施例15可归纳出:显而易见的,因fq=(Ke*Km)*(Te*im/R),fq实质为基于电气参数测算的作用于驱动轮的机械驱动力;单次运行的典型的车辆运动平衡计算公式为 fq=fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw;两次变速差值式(也即基于两个不同时间点所获取的参数的差值的)车辆运动平衡计算公式:(m2=ΔF/Δa);该类计算公式,因采取两次变速差值式车辆运动平衡计算公式联合运算车辆质量值,公式中消除了滚阻系数f、路面坡度θ参数,计算简单,但须保证两次变速运行中的滚阻系数f、路面坡度θ值接近或相等时计算才准确(且还需保证两次运行时的风阻fw、车辆总质量m2接近),当两次运行中θ或f或fw或m2不等时,该方式计算结果不准;且该类公司还有一重大缺陷,车辆大多数时候可能运行在匀速状态,(即使滚阻系数f、路面坡度θ值、风阻fw均接近)此时因Δa=(a2-a1)=0时反而无法运行;如果(ΔF=(fq2-fq1)=0)也无法计算出相关参数的值。显而易见的,该(m2=ΔF/Δa)并非简单的(m=F/a)公式,该Δa是指两次运行时的加速度的差值,该ΔF并非指单次运行的合外力,也非某一时间点所测的驱动力(fq=(Ke*Km)*(Te*im/R));而指驱动力在两个不同时间点计算所得的差值(fq2-fq1);该(m2=ΔF/Δa)为基于两次不同时间点所获取的参数的差值的车辆运动平衡计算所得。如果用牛顿第二定律描述车辆运动平衡计算,实施例29中计算公式(fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw)变形可得:fq_cal-(m2*(g*f*cosθ+g*sinθ)+fw)=m2*a;该(fq_cal-(m2*(g*f*cosθ+g*sinθ)+fw))才为某单一时间点牛顿第二定律中的合外力F。简而言之,尽管公式的外形相识,因为与车辆质量有关的滚动阻力和坡阻、风阻的影响,这些阻力的分量之和可能远大于变速阻力m2*a,如果不考虑坡度、滚动阻力、风阻,而仅仅将当次获取的驱动力作为合外力根据牛二定律计算出车辆质量或加速度是错误的。同理,如果不采用车辆运动纵向动力平衡计算,(在忽略车辆总质量、滚动阻力、坡阻、变速阻力、风阻等参数的大小不同及变化不同时)仅仅用电机的功率公式(P=Te*n1/9.55)也是无法计算出控制车辆运行的正确结果。It can be concluded from the above-mentioned Embodiment 3 or Embodiment 15 that it is obvious that fq=(Ke*Km)*(Te*im/R), fq is substantially a mechanical driving force acting on the driving wheel based on the electrical parameter measurement; The typical vehicle motion balance calculation formula for a single run is Fq=fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw; two-speed differential equation (that is, the difference between the parameters obtained based on two different time points) Formula: (m2=ΔF/Δa); This kind of calculation formula combines the vehicle mass value by taking the two-speed difference-type vehicle motion balance calculation formula, and eliminates the rolling resistance coefficient f and the road gradient θ parameter in the formula, which is simple to calculate. However, it must be ensured that the rolling resistance coefficient f and the road surface slope θ value of the two shifting operations are close to or equal to each other (and the wind resistance fw and the total mass m2 of the vehicle are required to be close), when running twice When θ or f or fw or m2 is not equal, the calculation result of this method is not accurate; and there is a major defect in this type of company, the vehicle may run at a constant speed most of the time (even if the rolling resistance coefficient f, the road gradient θ value, The wind resistance fw is close to each other. At this time, since Δa=(a2-a1)=0, the operation cannot be performed; if (ΔF=(fq2-fq1)=0), the value of the relevant parameter cannot be calculated. Obviously, this (m2=ΔF/Δa) is not a simple (m=F/a) formula, which is the difference in acceleration between two runs, which does not refer to the external force of a single run, nor The driving force measured at a certain point in time (fq=(Ke*Km)*(Te*im/R)); and refers to the difference (fq2-fq1) calculated by the driving force at two different time points; M2 = ΔF / Δa) is calculated from the vehicle motion balance based on the difference of the parameters acquired at two different time points. If Newton's second law is used to describe the vehicle motion balance calculation, the calculation formula (fq_cal=m2*(g*f*cosθ+g*sinθ+a)+fw) in Example 29 can be obtained: fq_cal-(m2*(g *f*cosθ+g*sinθ)+fw)=m2*a; the (fq_cal-(m2*(g*f*cosθ+g*sinθ)+fw)) is the second law of Newton in a single time point The external force F. In short, although the shape of the formula is acquainted, the sum of the components of these resistances may be much larger than the shift resistance m2*a because of the rolling resistance and the resistance of the slope and the wind resistance, if the slope, rolling resistance, Wind resistance, and it is wrong to calculate the vehicle mass or acceleration based on the two laws of the external force. Similarly, if the longitudinal dynamic balance calculation of the vehicle motion is not used, (only when the parameters such as the total mass, rolling resistance, slope resistance, variable speed resistance, and wind resistance are different and the changes are different), only the power formula of the motor is used (P=Te). *n1/9.55) is also unable to calculate the correct result of controlling the operation of the vehicle.
而实施例7、11、12或实施例41中的车辆运动平衡计算公式中包含滚阻系数、路面坡度,车辆在匀速和变速时均可计算,且结果相对准确,所以相对于实施例3或15具有更高的准确度、实用性。The calculation formula of the vehicle motion balance in the embodiment 7, 11, 12 or the embodiment 41 includes the rolling resistance coefficient and the road surface gradient, and the vehicle can be calculated at both the constant speed and the shifting speed, and the result is relatively accurate, so relative to the embodiment 3 or 15 has higher accuracy and practicality.
本方案的有益意义:参与车辆运动平衡计算的系统运行参数组包括滚阻系数、路面坡度,比不包含该两参数时(通常以纵向加速度为核心计算参数的)的计算方案更能大幅度的提高监控准确度、灵敏度、适用范围。The beneficial significance of this scheme: the system operation parameter group participating in the calculation of vehicle motion balance includes the rolling resistance coefficient and the road gradient, which is more significant than the calculation scheme that does not include the two parameters (usually the longitudinal acceleration is the core calculation parameter). Improve monitoring accuracy, sensitivity, and scope of application.
16.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括步骤:16. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes steps:
输出和/或保存车辆质量的值;和/或:输出和/或保存系统固有参数、纵向速度、源动力参数中任意一种或多种参数基于车辆运动平衡计算公式计算所得的值;Outputting and/or preserving values of vehicle mass; and/or: outputting and/or preserving any one or more of system intrinsic parameters, longitudinal speed, source dynamic parameters based on a vehicle motion balance calculation formula;
本方案的实施说明:The implementation of this program:
当测算对象为车辆质量时,车辆质量的值即联合运算值;当测算对象为源动力参数或系统运行 参数时,车辆质量的值即参与所述运动平衡计算的车辆质量的值(通常为实际值、基准值);可将车辆质量的数值输出到车内人机界面、网络系统、通讯端口中;或将车辆质量的数值保存保存到车内存储设备、网络系统中等;显而易见的,本发明中所述车内人机界面包括车内电子设备和/或便携式个人消费电子产品的人机界面;When the measured object is the vehicle mass, the value of the vehicle mass is the joint operation value; when the measured object is the source power parameter or the system is running When the parameter is, the value of the vehicle mass is the value of the vehicle mass (usually the actual value, the reference value) participating in the calculation of the motion balance; the value of the vehicle mass can be output to the man-machine interface, the network system, and the communication port; Or saving the value of the vehicle quality to the in-vehicle storage device, the network system; obviously, the in-vehicle human-machine interface in the present invention includes a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product;
本方案的有益意义:The usefulness of this program:
如果测算对象为源动力参数或系统运行参数时,用车辆运动平衡计算获取车辆质量的值是较优选择,可自动跟随运载物品质量的大幅度变化,提高动力传递异常监控准确度;If the measured object is the source dynamic parameter or the system operating parameter, it is a better choice to obtain the vehicle mass value by using the vehicle motion balance calculation, which can automatically follow the large change of the quality of the carried item and improve the accuracy of the power transmission abnormality monitoring;
输出所述车辆质量的数值,便于操作人员直观的判断车辆动力传递状况,对于提高本监控方法的可信度有重大意义,有助于操作人员一眼识别当前的动力传递异常判断是否正常;Outputting the value of the vehicle mass is convenient for the operator to intuitively judge the power transmission condition of the vehicle, which is of great significance for improving the credibility of the monitoring method, and helps the operator to recognize at a glance whether the current power transmission abnormality judgment is normal;
例如当体重70kg的司机单人驾车时,如果车辆显示运载质量为200KG15重如小牛,或为20KG轻如小绵羊,司机可立马识别是否正常;For example, when a driver with a weight of 70 kg is driving alone, if the vehicle shows that the carrying quality is 200KG15 and the weight is as small as a calf, or if the 20KG is as light as a small sheep, the driver can immediately identify whether it is normal;
例如电动大巴,如一个体重45KG的乘客上车,车辆显示新增质量为100KG或10KG,司机与乘客都可以很直观识别车辆运行是否正常;For example, an electric bus, such as a passenger with a weight of 45KG, can display a new quality of 100KG or 10KG. The driver and the passenger can visually recognize whether the vehicle is running normally.
例如无人驾驶的汽车在自动行驶中时,如果车辆总质量的计算值发生明显变化(如从1200KG变成1600KG或800KG),远程控制人员通过网络系统可实时识别车辆运行是否正常;For example, when an unmanned car is driving automatically, if the calculated value of the total mass of the vehicle changes significantly (for example, from 1200KG to 1600KG or 800KG), the remote control personnel can recognize whether the vehicle is running normally through the network system;
当然,如果单独的显示车辆质量的联合运算值,而不采用可自动触发的动力传递异常监控功能,则必然导致司乘人员需要时时刻刻目视关注车辆质量的显示值,反而影响车辆的安全运行;Of course, if the joint operation value of the vehicle mass is displayed separately, and the power transmission abnormality monitoring function that can be automatically triggered is not used, it will inevitably cause the driver and the passenger to pay attention to the display value of the vehicle quality at all times, thereby affecting the safety of the vehicle. run;
保存车辆质量的联合运算值,如同飞机安全的黑匣子功能,便于事后分析。The joint operation value of the vehicle mass is saved, like the black box function of the aircraft safety, which is convenient for post-mortem analysis.
同理;因为车辆内通常会输出和/或显示/和/或保存纵向速度、源动力参数中任意一种或多种参数的实际值;所以,输出和/或保存纵向速度、源动力参数中任意一种或多种参数基于车辆运动平衡计算公式计算所得的值;可有助于司乘人员直观的对比、识别车辆的运行状况是否正常;Similarly, since the actual value of any one or more of the longitudinal speed and source dynamic parameters is normally output and/or displayed in the vehicle; therefore, the output and/or save longitudinal velocity, source dynamic parameters Any one or more parameters are calculated based on the calculation formula of the vehicle motion balance; it can help the passengers to intuitively compare and recognize whether the running condition of the vehicle is normal;
17.进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中,当源动力参数为能量类型的源动力组合型参数时,能量累计的时间控制在一天之内或以1小时之内或30分钟之内或10分钟之内或一分钟之内或30秒之内或20秒之内或10秒之内或5秒之内或2秒之内或1秒之内或100毫米之内或10毫秒之内或1毫秒之内或0.1毫米之内。17. Further, in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3), when the source dynamic parameter is the source-power combination type parameter of the energy type, the time of the energy accumulation is controlled in one day. Within 1 hour or within 30 minutes or within 10 minutes or within one minute or within 30 seconds or within 20 seconds or within 10 seconds or within 5 seconds or within 2 seconds or 1 second Within 100 millimeters or within 10 milliseconds or within 1 millisecond or within 0.1 millimeters.
18.进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中还包括下述方案(优选源动力参数为电机驱动参数的方案1):所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。18. Further, the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3) further includes the following scheme (preferably the source dynamic parameter is the motor driving parameter scheme 1): the The source dynamic parameter in the vehicle motion balance calculation calculation is any one or more of the motor drive parameter and the back end electrical power parameter.
本方案的有益意义:The usefulness of this program:
以电机驱动参数作为源动力参数进行车辆运动平衡计算,进而监控车辆监控动力传递异常,成本低廉且测量精度高灵敏度高,比采用成本高昂的转矩传感器采集信号,具有重大成本优势和性能 优势,可大幅度降低监控系统成本、提升监控性能,对于车辆安全运行具有重大意义;The motor drive parameter is used as the source dynamic parameter to calculate the vehicle motion balance, and then the vehicle monitoring power transmission abnormality is monitored, the cost is low, the measurement accuracy is high, the sensitivity is high, and the signal is collected by using a costly torque sensor, which has significant cost advantages and performance. Advantages can greatly reduce the cost of monitoring system and improve monitoring performance, which is of great significance for the safe operation of vehicles;
以后端的电气动力参数作为源动力参数进行车辆运动平衡计算,提供了一种新的源动力参数来源,可以对单独以电机驱动参数作为源动力参数作为验证依据;The vehicle dynamic balance calculation is carried out with the back-end electrical power parameters as the source dynamic parameters, and a new source power parameter source is provided. The motor drive parameters can be used as the source power parameters alone as the verification basis.
因为电气动力参数,尤其是电机驱动参数的运用通常属于电力电子领域行业知晓的技术,便于低成本、高精度的测量、获取;Because the use of electrical power parameters, especially motor drive parameters, is generally a technology known in the power electronics industry, which facilitates low-cost, high-precision measurement and acquisition;
而车辆运动平衡计算,属于整车车辆运行控制领域行业技术;The calculation of vehicle motion balance belongs to the industry technology in the field of vehicle vehicle operation control;
这是两个完全不同的领域,本发明创造性的将电气动力参数、尤其是电机驱动参数与车辆运动平衡计算跨领域的相结合,进而创造性的应用于一个全新的车辆的动力传递异常监控领域,对于车辆运行安全具有重要意义。This is two completely different fields. The invention creatively combines electrical power parameters, especially motor drive parameters, with vehicle motion balance calculations across fields, and is thus creatively applied to a new vehicle power transmission anomaly monitoring field. It is of great significance for the safety of vehicle operation.
19.进一步的,所述监控方法(#1)或监控方法(#2)或监控方法(#3)中,还包括下述方案(优选燃料动力参数中源动力参数的方案1):当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。19. Further, in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3), the following scheme (preferably the scheme 1 of the source dynamic parameters in the fuel dynamic parameter) is further included: When the source power parameter in the vehicle motion balance calculation calculation is based on the fuel power parameter, the fuel power parameter includes any one or more parameters of the cylinder pressure, the fuel consumption rate, the engine air flow, and the engine load report data.
本方案的有益意义:燃料发动机的基础原理为燃料在气缸内燃烧产生压力推动活塞运行,进而形成曲轴的旋转运动,进而驱动车辆运行;所以气缸压力是车辆运行最核心参数之一,其可以直接监控发动机活塞及后端的旋转工作型动力或传动部件运行情况,在车辆运行条件下(如载重、坡度、速度等)同等时,如果气缸拉缸/活塞运行阻力增大时/则将导致气缸压力增大;且气缸压力可以通过设置于气缸燃烧室内(如气缸盖内壁)的压力传感器进行便利的测量(因为气缸盖是非活动部件,便于传感器及其线缆的安装),所以将气缸压力作为源动力参数是理想的选择;相对于其他参数获取的源动力参数,准确度高;The beneficial significance of this scheme: The basic principle of the fuel engine is that the fuel is burned in the cylinder to generate pressure to push the piston to run, thereby forming the rotary motion of the crankshaft, thereby driving the vehicle to run; therefore, the cylinder pressure is one of the core parameters of the vehicle operation, which can be directly Monitor the operation of the rotating working power or transmission components of the engine piston and the rear end. When the vehicle operating conditions (such as load, slope, speed, etc.) are equal, if the cylinder pull cylinder/piston running resistance increases, the cylinder pressure will be caused. Increased; and the cylinder pressure can be conveniently measured by a pressure sensor placed in the combustion chamber of the cylinder (such as the inner wall of the cylinder head) (because the cylinder head is an inactive part, which facilitates the installation of the sensor and its cable), so the cylinder pressure is used as the source. The dynamic parameters are ideal choices; the source dynamic parameters obtained from other parameters are highly accurate;
燃料的燃烧是燃料动力车辆的驱动能量和动力之源,且燃料消耗率可通过流量传感器或燃料喷射参数准确获取,所以将燃料消耗率作为源动力参数也是较优的选择;以发动机内燃料消耗率fm1(燃料喷射系统喷射输出侧的燃料消耗率)作为源动力参数监控动力传递异常虽不如气缸压力直接,但通过燃料消耗率不仅仅可以监控发动机活塞及后端的旋转工作型动力或传动部件运行情况,还可以直接监控气缸内燃料的燃烧是否正常,消耗的燃料是否正常转化为动力;燃料的燃烧不良本身也属于车辆异常的一种;如果燃料消耗率的信号采集点为燃料喷射系统输入侧,则可更宽范围的监控燃料喷射系统工作是否正常;也即通过消耗的几滴油,就可计算出测算对象(如车辆质量)的联合运算值,进而可监控车辆的燃料喷射系统、发动机气缸燃烧系统、发动机活塞及后端的旋转工作型动力或传动部件的运行情况,对于车辆的安全具有重大意义;Fuel combustion is the source of driving energy and power for fuel-powered vehicles, and the fuel consumption rate can be accurately obtained through flow sensor or fuel injection parameters, so the fuel consumption rate is also a preferred source power parameter; The rate fm1 (fuel consumption rate on the injection output side of the fuel injection system) is used as the source power parameter to monitor the power transmission abnormality, although it is not as direct as the cylinder pressure, but the fuel consumption rate can not only monitor the rotary working power or the transmission component of the engine piston and the rear end. In the case, it is also possible to directly monitor whether the combustion of the fuel in the cylinder is normal, and whether the fuel consumed is normally converted into power; the combustion failure of the fuel itself is also a kind of abnormality of the vehicle; if the signal collection point of the fuel consumption rate is the input side of the fuel injection system , it can monitor the fuel injection system in a wider range of work; that is, through the consumption of a few drops of oil, the joint calculation value of the measured object (such as vehicle mass) can be calculated, and then the fuel injection system and engine of the vehicle can be monitored. Cylinder combustion system, engine piston and rear end The operation of the rotating working power or transmission components is of great significance to the safety of the vehicle;
以发动机空气流量作为源动力参数,实质为间接的通过燃料消耗率监控车辆监控动力传递异常,意义同上; Taking the engine air flow as the source power parameter, the indirect monitoring of the vehicle's power transmission abnormality through the fuel consumption rate is the same as above;
以发动机负荷报告数据作为源动力参数监控车辆监控动力传递异常,比采用成本高昂的转矩传感器采集信号,具有大幅度成本优势。Using the engine load report data as the source power parameter to monitor the vehicle monitoring power transmission anomaly is more cost-effective than using a costly torque sensor to collect signals.
20.进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中,所述车辆运行参数包括车辆质量、源动力参数、系统运行参数,所述系统运行参数包括机械运行参数、系统固有参数、质量变化型物品质量;20. Further, in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3), the vehicle operating parameters include vehicle quality, source power parameters, system operating parameters, and the system operating parameters include Mechanical operating parameters, system inherent parameters, quality of quality changes;
当然,也允许测算对象为车辆运行参数之外的任一数据,只要该数据能为基于基于车辆运动平衡计算计算所得联合运算值,根据该值和该数据的参考数据判断车辆的动力传递状况是否异常。Of course, the measurement object is also allowed to be any data other than the vehicle operating parameter, as long as the data can be a joint operation value calculated based on the vehicle motion balance calculation, and based on the value and the reference data of the data, whether the power transmission condition of the vehicle is determined. abnormal.
21.进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。21. Further, in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3), the vehicle is a high-speed rail vehicle, an electric train, an electric locomotive, a tram, a maglev train, an in-pipe train, Buses, trucks, ordinary private vehicles, regular trains, tracked vehicles, electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles or tricycles with powertrains, operating on land and their air lift below a preset threshold or Any vehicle in which the longitudinal speed is lower than the preset value.
该技术方案的有益意义:相对于其他的车辆,如电动单车、独轮车;在上述车辆进行动力传递监控具有更重大安全意义。The beneficial significance of this technical solution: compared with other vehicles, such as electric bicycles and wheelbarrows; the power transmission monitoring of the above vehicles has more significant safety significance.
进一步的,监控方法(#1)或监控方法(#2)或监控方法(#3)中:以车辆质量、系统固有参数、质量变化型物品质量中任意一种参数作为测算对象;或以除纵向加速度之外的车辆运行参数中任意一种参数作为测算对象;或以除源动力参数之外的车辆运行参数中任意一种参数作为测算对象;或以除纵向加速度和/或源动力参数之外的车辆运行参数中任意一种参数作为测算对象;Further, in the monitoring method (#1) or the monitoring method (#2) or the monitoring method (#3), any one of the vehicle quality, the system inherent parameter, and the quality of the quality item is used as a measurement target; or Any one of the vehicle operating parameters other than the longitudinal acceleration is used as the measuring object; or any one of the vehicle operating parameters other than the source dynamic parameter is used as the measuring object; or in addition to the longitudinal acceleration and/or the source dynamic parameter Any one of the external vehicle operating parameters is used as the measurement object;
本方案的有益意义:The usefulness of this program:
将源动力参数(如燃料消耗率、气缸压力、发动机输出转矩、发动机输出功率、电磁转矩、电流、电气功率等)或机械运行参数(如纵向速度、纵向加速度等)作为测算对象是效果最差监控方案,测控难度/成本高,也降低了精度/性能;该类测算对象的测量联合运算值的幅值可能快速变化从而增大第一诱因的测量误差,通常还需要获取实测值/或指令值/或历史记录值进而设定参考值,参考值幅值也可能快速变化进而带来第二诱因的测量误差;且因联合运算值、参考值随时可能处于低幅值状态(相对于满量程测量)更容易造成第三诱因的测量误差,甚至监控失效;因为车辆质量在不同的运行流程中可能大幅度变化,如果将源动力参数或系统运行参数作为测算对象,又必须先获取车辆质量的值,从而导致第四诱因的测量误差,且使测算/监控系统更为复杂/高成本;显而易见的,车辆大部分时候可能均处于匀速运行状态(包括高速匀速运行),此时纵向加速度接近零;所以监控方法(#1)或监控方法(#2)或监控方法(#3)中:相较于以除纵向加速度之外的车辆运行参数中任意一种参数作为测算对象的方案,以纵向加速度作为测算对象是很差的选择,会导致在大部分时候监控不准;其次,相较于以除纵向加速度和/或源动力参数之外的车辆运行参数中任意一种参数作为测算对象的方案,以源动力参数(例如其中的电磁转矩、电流、电气功率等)作为测算对 象,也是不佳的选择,会导致监控效果明显变差;It is the result of measuring the source power parameters (such as fuel consumption rate, cylinder pressure, engine output torque, engine output power, electromagnetic torque, current, electrical power, etc.) or mechanical operating parameters (such as longitudinal speed, longitudinal acceleration, etc.) The worst monitoring scheme, the difficulty/measurement of measurement and control, and the accuracy/performance are also reduced; the amplitude of the measured joint operation value of the measured object may change rapidly to increase the measurement error of the first incentive, and usually the measured value is also required to be obtained/ Or the command value/or historical value further sets the reference value, and the reference value amplitude may also change rapidly to bring the measurement error of the second incentive; and the joint operation value and the reference value may be in a low amplitude state at any time (relative to Full-scale measurement) is more likely to cause measurement errors of the third incentive, and even monitor failure; because the vehicle quality may vary greatly in different operating processes, if the source dynamic parameters or system operating parameters are used as the measurement targets, the vehicle must first be acquired. The value of the quality, which leads to the measurement error of the fourth incentive and makes the measurement/monitoring system more complicated/high cost Obviously, the vehicle may be in a constant speed operation (including high speed and constant speed operation) for most of the time, and the longitudinal acceleration is close to zero; therefore, in the monitoring method (#1) or monitoring method (#2) or monitoring method (#3): Compared with the scheme of measuring any one of the vehicle operating parameters except the longitudinal acceleration, it is a poor choice to use the longitudinal acceleration as the measurement object, which will result in the monitoring being inaccurate for most of the time. Secondly, compared with For the solution of any one of the vehicle operating parameters except the longitudinal acceleration and/or the source dynamic parameter, the source dynamic parameters (such as electromagnetic torque, current, electrical power, etc.) are used as the measurement pair. Elephants, which are also poor choices, can cause significant deterioration in monitoring results;
所述测算对象优选为车辆质量,车辆质量值在车辆当次运行中相对稳定,且便于车辆操作人员直观目视判断监控效果,大为提高监控可信度;The measurement object is preferably a vehicle mass, and the vehicle quality value is relatively stable in the current operation of the vehicle, and is convenient for the vehicle operator to visually judge the monitoring effect, thereby greatly improving the monitoring reliability;
测算对象次优为系统固有参数(尤其滚阻系数或效率系数);滚阻系数、效率系数实质代表车辆机件的磨损状况、机件安全状况,且该参数在车辆运行中幅值变化不大,易于测控比较;但该种方式也存在上述第四诱因的测量误差,且不便于车辆操作人员直观目视判断监控效果;The sub-optimal object is the inherent parameters of the system (especially the rolling resistance coefficient or the efficiency coefficient); the rolling resistance coefficient and the efficiency coefficient essentially represent the wear condition of the vehicle parts and the safety condition of the machine, and the parameter does not change much during the running of the vehicle. It is easy to measure and compare; however, this method also has the measurement error of the above fourth incentive, and it is not convenient for the vehicle operator to visually judge the monitoring effect;
其次是测算对象为质量变化型物品质量(燃料质量),因为燃料质量的变化相对缓慢,效果比将源动力参数或机械运行参数作为测算对象要好,但也需要随时跟踪测量当前实际值而设定参考值,存在第二诱因测量误差;且联合运算值和参考值均可能逼近零值(如油量不足时)无法准确计算/监控,存在第三诱因的误差和失效。Secondly, the measurement object is the quality of the quality change item (fuel quality), because the change of fuel quality is relatively slow, the effect is better than the source dynamic parameter or mechanical operation parameter as the measurement object, but it also needs to track and measure the current actual value at any time. For the reference value, there is a second incentive measurement error; and both the joint operation value and the reference value may approach zero value (if the oil quantity is insufficient) cannot be accurately calculated/monitored, and there is a third incentive error and failure.
测算对象的联合运算值有多种计算方式,一种是查表计算;如先预设车辆的车辆质量、源动力参数、系统运行参数的关联表格;当输入其中任意两种参数时,可查表计算出另一参数的值;例如获取车辆的源动力参数、系统运行参数的值;根据该源动力参数、系统运行参数的值查表计算出车辆质量的联合运算值;There are many calculation methods for the joint operation value of the measurement object, one is the table lookup calculation; for example, the vehicle quality, the source power parameter and the system operation parameter association table of the vehicle are preset; when any two parameters are input, the check can be checked. The table calculates the value of another parameter; for example, obtaining the source dynamic parameter of the vehicle and the value of the system operation parameter; and calculating a joint operation value of the vehicle mass according to the value of the source dynamic parameter and the system operation parameter;
一种是用模型(也可称为数学公式)计算;本发明前述的实施例1~33、实施例41均为通过模型计算联合运算值;One is calculated by using a model (also referred to as a mathematical formula); the foregoing embodiments 1 to 33 and 41 of the present invention all calculate a joint operation value by a model;
本方案有益效果:因为不同车辆的原理、构造、车况、路况、载况千差万别;通过查表方式计算测算对象的联合运算值有很多局限性;一来表格的容量受限与硬件器件成本,二来表格中所有参数都需要预先设定或学习才能运行;表格容量大/参数设置越多,则硬件成本越高参数设置/学习成本越高;;The beneficial effects of this scheme: Because the principle, structure, vehicle condition, road condition and load condition of different vehicles are very different; there are many limitations in calculating the joint operation value of the measurement object by looking up the table; the capacity of the table is limited and the cost of the hardware device is two. All the parameters in the table need to be preset or learned to run; the larger the table capacity/parameter setting, the higher the hardware cost and the higher the parameter setting/learning cost;
如果用车辆运动平衡模型,用数学计算方式获取测算对象的联合运算值,则只需预先设置好模型规则/或数学运算规则,调整好相关的参数值,相较于查表计算,可大幅度降低联合运算值的获取成本/或大幅度提高联合运算值获取精度低/动力传递异常监控判断灵敏度。If the vehicle motion balance model is used to obtain the joint operation value of the measurement object by mathematical calculation, it is only necessary to set the model rule and/or the mathematical operation rule in advance, and adjust the relevant parameter value, which is significantly larger than the table calculation. Reduce the acquisition cost of the joint operation value / or greatly improve the joint operation value acquisition accuracy / power transmission abnormality monitoring judgment sensitivity.
本发明还提供一种与监控方法(#1)相对应的车辆由动力装置控制运行时的监控系统(#36),测算对象是车辆的车辆运行参数中任意一种参数,所述监控系统包括判断参数获取模块(1)、动力传递状况判断模块(2);所述监控系统还包括动力传递异常处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;所述车辆由动力装置控制运行时的监控系统(#36)还包括:测算对象确定模块,用于以车辆运行参数中的任意一种为测算对象;The present invention also provides a monitoring system (#36) when the vehicle corresponding to the monitoring method (#1) is controlled by the power device, and the measuring object is any one of the vehicle operating parameters of the vehicle, and the monitoring system includes Determining a parameter acquisition module (1) and a power transmission status determination module (2); the monitoring system further includes any one or more of a power transmission abnormality processing module (3), an output module (4), and a saving module (5) The monitoring system (#36) of the vehicle when the vehicle is controlled by the power device further includes: a measuring object determining module, configured to use any one of the vehicle operating parameters as the measuring object;
所述判断参数获取模块(1)用于:获取所述车辆的测算对象的联合运算值和所述测算对象的参考数据;所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描 述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;The determining parameter obtaining module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle and reference data of the measurement object; the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion Balance calculation formula The formula of the balance between the dynamic direction of the vehicle and the related resistance in the running direction or the formula of the deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance;
所述动力传递状况判断模块(2)用于:根据车辆的测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;The power transmission status determination module (2) is configured to: determine whether the power transmission status of the vehicle is abnormal according to a joint operation value of the measurement object of the vehicle and reference data of the measurement object;
所述动力传递异常处理模块(3)用于:如所述判断的结果为是,则启动设定的动力传递异常处理机制;The power transmission abnormality processing module (3) is configured to: if the result of the determining is yes, initiate a set power transmission abnormality processing mechanism;
所述输出模块(4)用于:输出所述动力传递状况判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the power transmission status determination module (2);
所述保存模块(5)用于:保存所述动力传递状况判断模块(2)的判断结果。The saving module (5) is configured to: save the determination result of the power transmission status determination module (2).
该监控系统还包括还包括启动模块,用于开机自启动或者接收人工收操作指令后启动监控系统中的其他各个模块开始进行工作,具体的功能与上述监控方法相对应,具体可参考上述监控方法。The monitoring system further includes a startup module, which is configured to start other work in the monitoring system after the startup or receiving the manual operation instruction, and the specific function corresponds to the foregoing monitoring method, and the specific monitoring method may be referred to. .
与上述的车辆动力传递状况的监控方法(#2)相对应,本发明还提供了一种车辆动力传递状况的监控系统,包含下述模块,Corresponding to the above-mentioned monitoring method (#2) for the vehicle power transmission condition, the present invention also provides a monitoring system for the vehicle power transmission status, comprising the following modules,
测算对象确定模块,用于以车辆运行参数中的任意一种为测算对象;a measuring object determining module, configured to use any one of vehicle operating parameters as a measuring object;
车辆运动平衡计算公式确定模块,用于确定计算该测算对象的车辆运动平衡计算公式;该车辆运动平衡计算公式为描述车辆移动方向的动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;a vehicle motion balance calculation formula determining module, configured to determine a vehicle motion balance calculation formula for calculating the measurement object; the vehicle motion balance calculation formula is a formula for describing a balance between power and related resistance of a vehicle moving direction or a formula thereof; the correlation resistance The rolling resistance, the slope resistance, the shift resistance, and the wind resistance include any one or any of a plurality of; or the related resistance includes any one of rolling resistance, slope resistance, shift resistance, and wind resistance, or includes rolling resistance, slope resistance, The sum of any of the variable speed resistance and wind resistance;
实测个数确定模块,用于设定输入参数中以实测取值的参数个数,获取输入参数的值,所述输入参数为所述车辆运动平衡计算公式中除所述测算对象外的所有参数;并根据该输入参数、车辆运动平衡计算公式计算该测算对象;获取车辆当前运动状态下该测算对象的参考数据;The measured number determining module is configured to set the number of parameters in the input parameter to be actually measured, and obtain the value of the input parameter, where the input parameter is all parameters except the measured object in the vehicle motion balance calculation formula And calculating the measurement object according to the input parameter and the vehicle motion balance calculation formula; acquiring reference data of the measurement object in the current motion state of the vehicle;
比较判断模块,用于比较计算所得该测算对象的值和该测算对象的参考数据,判断所述车辆的动力传递状况是否异常。The comparison judging module is configured to compare the calculated value of the measurement object with the reference data of the measurement object, and determine whether the power transmission status of the vehicle is abnormal.
本发明还提供一种The invention also provides a
本发明要解决的技术问题之三是提供一种简便的车辆运行参数的监视方案;The third technical problem to be solved by the present invention is to provide a simple monitoring scheme for vehicle operating parameters;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
22.本发明提供一种车辆运行参数的监视方法(#22),所述监视方法包括步骤:22. The present invention provides a monitoring method (#22) for vehicle operating parameters, the monitoring method comprising the steps of:
获取测算对象的联合运算值,该联合运算值为基于车辆运动平衡计算公式计算所得的结果;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述测算对象的联合运算值。 Obtaining a joint operation value of the measurement object, wherein the joint operation value is a result calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance of the vehicle dynamic direction and the related resistance in the running direction or a formula thereof; The related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; and the joint operation value of the measurement object is output on the human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
该车辆运动平衡计算公式及计算方法及参数的设置方法可参考本文中任一位置的内容进行;The vehicle motion balance calculation formula and the calculation method and the parameter setting method can be referred to the content of any position in this document;
该监视方法(#1)中,该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;In the monitoring method (#1), the vehicle motion balance calculation formula is a formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or a deformation thereof; the related resistance includes any one of rolling resistance, slope resistance, shift resistance, and wind resistance. One or any of a plurality of; or the related resistance includes one of rolling resistance, slope resistance, shift resistance, wind resistance, or a combination of rolling resistance, slope resistance, shift resistance, and wind resistance;
该车辆运动平衡计算公式的输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;The input parameter of the vehicle motion balance calculation formula is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula;
优选的,设定输入参数中以实测取值的参数个数,这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Preferably, the number of parameters in the input parameter to be measured is set, and the parameters are set based on the measured value; other parameters may be set by preset values; the more the measured parameters, the higher the accuracy will be, the better the monitoring performance is. The measured parameters are less costly; the user and the manufacturer can customize according to their different situations.
优选的,可参考前述测算方法(#1)、及其动力Fx的变形、输入参数的值的基础设置方案、测算对象类型或输入参数的值的设置方案2及其各优选方案、开机自启动或者接收人工收操作指令后启动中任意一个或多个方案,用于该监视方法中。Preferably, reference may be made to the foregoing measurement method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and various preferred schemes thereof, and the booting from the startup Or any one or more schemes in the startup after receiving the manual operation instruction for the monitoring method.
该监视方法开机自启动或者接收人工收操作指令后启动。在本发明中,该监视方法可以开机自启动,无需人为操作,在集成该监视方法的电子设备上电后自行运行,该自行运行可以是在上电后立刻开始运行,也可以是在经过预设时间后可以运行。其中,上述预设时间内可以仅作为一个待机时间,在该时间段内不执行其他应用程序,同时也可以在上述预设时间内执行其他应用程序,并可以进一步的以其他应用程序执行到一定程度(如执行一半或者执行完毕等)作为时间点来开始启动本监控方法或者直接以该些其他应用程序发送的启动指令来启动本监控方法。在接收人工操作指令后启动的工作模式中,该操作指令是用于控制本监视方法开始运行,其是在车内的操作按钮、触控屏或者其他移动电子设备(如手机)等在经过人为操作后产生。The monitoring method is started after starting up or receiving a manual receiving operation instruction. In the present invention, the monitoring method can be booted from the startup, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running may start immediately after power-on, or may be pre-evented. It can be run after setting the time. The preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications. The degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications. In the working mode initiated after receiving the manual operation instruction, the operation instruction is used to control the start of operation of the monitoring method, and the operation button, touch screen or other mobile electronic device (such as mobile phone) in the vehicle is subjected to artificial action. Produced after the operation.
实施说明:本发明前述的监控方法(#1)提供了一种针对测算对象的联合运算值与实际值的偏差值超许可范围的自动监控方法;本监视方法(#22)中所述车内电子设备,包括专用的电子监视设备、车内导航系统、倒车雷达、车内中控台、驾驶屏显系统、车内仪表盘、行车记录仪、车内视频监控系统中任意一种或多种设备;所述便携式个人消费电子产品包括手机、掌上电脑、智能手表、智能手环、数码相机、游戏机等;出于实验目的,临时置于车内的,其他的电子设备(例如实验用的电脑、示波器等)不属于本发明中所述车内电子设备;只有用于在车辆正常运营中,随车配置的电子设备才称为车内电子设备。Implementation Description: The foregoing monitoring method (#1) of the present invention provides an automatic monitoring method for the deviation value of the deviation between the joint operation value and the actual value of the measurement object; the vehicle in the monitoring method (#22) Electronic equipment, including dedicated electronic monitoring equipment, in-vehicle navigation system, parking sensor, in-vehicle center console, driving screen display system, in-vehicle instrument panel, driving recorder, in-vehicle video monitoring system The portable personal consumer electronic product includes a mobile phone, a palmtop computer, a smart watch, a smart wristband, a digital camera, a game machine, etc.; for experimental purposes, other electronic devices temporarily placed in the vehicle (for example, for experimental use) Computers, oscilloscopes, etc.) are not included in the in-vehicle electronic device of the present invention; only electronic devices configured for on-board configuration in the normal operation of the vehicle are referred to as in-vehicle electronic devices.
本发明所述在人机界面上输出联合运算值,包括以文字、图像、声音、语音等任意一种或多种方式显示和/或语音提示联合运算值;The invention outputs the joint operation value on the human-machine interface, including displaying the combined operation value and/or the voice prompt in any one or more manners such as text, image, sound, voice, and the like;
本方案中所述获取,可包括通过无线接收方式接收外部设备所发出的测算对象的联合运算值、或通过USB、CAN总线等有线方式接收外部设备所发出的测算对象的联合运算值等方式;也可通过用 有线/或无线方式直接接收车辆运行参数,然后在该电子设备内部用所接收的车辆质量、源动力参数、系统运行参数中参数,然后进行为基于基于车辆运动平衡计算计算得出测算对象的联合运算值;The obtaining in the solution may include receiving a joint operation value of the measurement object sent by the external device by using a wireless receiving manner, or receiving a joint operation value of the measurement object sent by the external device through a wired manner such as a USB or a CAN bus; Can also be used Directly receiving the vehicle operating parameters in a wired/wireless manner, and then using the received vehicle mass, source dynamic parameters, and system operating parameters in the electronic device, and then performing a joint calculation based on the vehicle motion balance calculation Operational value
本技术方案的有益效果:本技术方案有助于、用于(司乘人员非常直观的、以目见耳闻的方式)反映或分析或判断车辆运行状况是否正常;本技术方案,尤其可用于反映或分析或判断车辆的动力传递状况是否正常,也即可用于反映或分析或判断车辆中与动力的传递相关的系统的运行状况和/或运行环境的状况是否正常;车辆中与动力的传递相关的系统包括待监控的动力传动部件和/或第二车轮;第二车轮和/或传动部件中所包括的驱动轮均可称为车轮;该系统,尤其指旋转工作型动力或传动部件;车辆中与动力的传递相关的系统的运行状况,尤其指待监控的动力传动部件的动力传递的效率状况(也即效率系数的大小)和/或车轮的滚动阻力系数(尤其为其中的与车辆相关的滚阻系数分量fc)的大小;该司乘人员指车内的司机和/或乘客,司乘人员也即车内人员;比如以车辆质量中运载物品质量作为测算对象时,司乘人员通过电子设备上显示的乘客的体重的联合运算值直接判断车辆当前运行是否正常;比如以纵向速度作为测算对象时,司乘人员可通过电子设备上显示的纵向速度的联合运算值与观察仪表盘或直接感知所得的车辆运行实际速度,直接判断车辆当前运行是否正常;比如:以源动力参数作为测算对象时,该源动力参数优先指电磁转矩、电流、电气功率中任意一种或多种参数;司乘人员可通过电子设备上显示的源动力参数的联合运算值与观察仪表盘所得的实际源动力参数,直接判断车辆当前运行是否正常;因此本技术方案相比较于现有技术也是一种重要进步;所述监视方法(#22)中,优选的,测算对象为车辆质量、纵向速度、源动力参数中任意一种或多种参数;Advantageous Effects of the Technical Solution: The technical solution is helpful for, for example, a very intuitive and audible way to reflect or analyze or judge whether the vehicle is in a normal state of operation; the technical solution is particularly useful for reflecting Or analyzing or judging whether the power transmission condition of the vehicle is normal, or can be used to reflect or analyze or judge whether the operating condition of the system related to the transmission of power in the vehicle and/or the condition of the operating environment is normal; the vehicle is related to the transmission of power System includes a power transmission component to be monitored and/or a second wheel; the drive wheel included in the second wheel and/or the transmission component may be referred to as a wheel; the system, in particular, a rotary working power or transmission component; The operating condition of the system related to the transmission of power, in particular the efficiency of the power transmission of the power transmission component to be monitored (ie the magnitude of the efficiency factor) and/or the rolling resistance coefficient of the wheel (especially for the vehicle The size of the rolling resistance coefficient component fc); the driver of the division refers to the driver and/or passenger in the vehicle, and the passenger of the driver is also the personnel inside the vehicle; If the quality of the goods carried in the vehicle quality is taken as the calculation object, the passengers directly judge whether the current operation of the vehicle is normal through the joint calculation value of the weight of the passenger displayed on the electronic device; for example, when the longitudinal speed is used as the calculation object, the passenger can By directly calculating the combined operation speed of the longitudinal speed displayed on the electronic device and observing the dashboard or directly sensing the actual running speed of the vehicle, directly determining whether the current running of the vehicle is normal; for example, when the source dynamic parameter is used as the measurement object, the source dynamic parameter is prioritized. Refers to any one or more of electromagnetic torque, current, and electrical power; the passenger can directly determine the current vehicle's current state by using the combined operational value of the source dynamic parameters displayed on the electronic device and the actual source dynamic parameters obtained by observing the instrument panel. Whether the operation is normal; therefore, the technical solution is also an important improvement compared to the prior art; in the monitoring method (#22), preferably, the measurement object is any one of vehicle mass, longitudinal speed, and source power parameters or Multiple parameters;
进一步的,所述监视方法(#22)中:以车辆质量、系统固有参数、质量变化型物品质量中任意一种参数作为测算对象;或以除纵向加速度之外的车辆运行参数中任意一种参数作为测算对象;或以除源动力参数之外的车辆运行参数中任意一种参数作为测算对象;或以除纵向加速度和/或源动力参数之外的车辆运行参数中任意一种参数作为测算对象;以取得更好的安全监视效果;Further, in the monitoring method (#22): any one of a vehicle quality, a system inherent parameter, and a quality variable item quality is used as a measurement target; or any one of vehicle operating parameters other than the longitudinal acceleration The parameter is used as the measurement object; or any one of the vehicle operating parameters except the source dynamic parameter is used as the measurement object; or any one of the vehicle operating parameters except the longitudinal acceleration and/or the source dynamic parameter is used as the measurement object. Object; for better security surveillance;
进一步的,所述监视方法(#22)还包括步骤:Further, the monitoring method (#22) further includes the steps of:
获取所述测算对象的相关数据,在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的相关数据;当所述测算对象为车辆质量、需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时,该测算对象的相关数据为该测算对象的第二许可范围、实际值、联合运算值与实际值的差值、第一许可范围中任意一种或多种数据;当所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时,该测算对象的相关数据为该测算对象的第二许可范围、实际值、联合运算值与实际值的差值、标定值、联合运算值与标定值的差值、第一许可范围中任意一种或多种数据;Obtaining relevant data of the measurement object, and outputting relevant data of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product; when the measurement object is a vehicle quality and needs to be measured When the parameter and/or the measurable parameter and/or the source dynamic parameter and/or the mechanical operating parameter and/or the quality variable item quality are any one of the parameters, the relevant data of the measuring object is the second permitted range of the measuring object, The actual value, the difference between the joint operation value and the actual value, and any one or more of the first permission ranges; when the measurement object is an unmeasurable parameter and/or a preset parameter and/or a system inherent parameter When a parameter is used, the relevant data of the measurement object is a second permission range, an actual value, a difference between the joint operation value and the actual value, a calibration value, a difference between the joint operation value and the calibration value, and a first permission range. Any one or more of the data;
综合而言,测算对象的相关数据或车辆运动平衡计算公式中的输入参数中所包括的的路面坡度θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信 息计算所得或传感器测量数据获取;In general, the correlation data of the measurement object or the road surface gradient θ, the rolling resistance coefficient f included in the input parameter in the vehicle motion balance calculation formula, and one or more parameters of the rolling resistance coefficient component fr related to the road condition Value based on the location of the road Gain calculation or sensor measurement data acquisition;
本技术方案的实施说明与有益效果:可在同一个电子设备的显示界面上,同时显示测算对象的联合运算值和测算对象的相关数据,便于司乘人员更直观的比较判断,便于以目视方式判断车辆是否存在安全隐患。The implementation description and beneficial effects of the technical solution can display the joint operation value of the measurement object and the related data of the measurement object simultaneously on the display interface of the same electronic device, so that the passengers can more intuitively compare and judge, which is convenient for visual observation. Ways to determine whether the vehicle has a safety hazard.
进一步的,所述监视方法(#22)中,测算对象为车内电子设备和/或便携式个人消费电子产品的人机界面上已输出的一种或多种参数;该已输出的指已显示和/或输出该参数的实际值;Further, in the monitoring method (#22), the measurement object is one or more parameters that have been output on the human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product; the outputted finger has been displayed And/or output the actual value of the parameter;
本技术方案的实施说明与有益效果:同上;Implementation description and beneficial effects of the technical solution: ibid.
进一步的,所述监视方法(#22),所述车内电子设备包括车内导航系统、倒车雷达、车内中控台、驾驶屏显系统、车内仪表盘、行车记录仪、车内视频监控系统中任意一种或多种设备。Further, in the monitoring method (#22), the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle dashboard, a driving recorder, and an in-vehicle video. Monitor any one or more devices in the system.
本技术方案的实施说明与有益效果:在车内现有或现需的电子设备上进行监视,相较于专用的监视系统进行监视,可大幅度的降低监视的硬件成本。The implementation description and beneficial effects of the technical solution: monitoring on existing or currently needed electronic equipment in the vehicle, and monitoring compared with a dedicated monitoring system can greatly reduce the hardware cost of monitoring.
进一步的,所述监视方法(#22),所述便携式个人消费电子产品包括手机、智能手表、智能手环中任意一种或多种设备。Further, the monitoring method (#22), the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart bracelet.
本技术方案的实施说明与有益效果:手机、智能手表、智能手环具有广泛被司乘人员携带的特点,在其上进行监视,相较于其他产品具有更良好的便携性,可大幅度的降低监视的硬件成本。The implementation description and beneficial effects of the technical solution: the mobile phone, the smart watch, the smart wristband have the characteristics of being widely carried by the passengers, and monitoring on the same, which has better portability than other products, and can be greatly improved. Reduce the hardware cost of monitoring.
进一步的,所述监视方法(#22),所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。Further, the monitoring method (#22) is that the source dynamic parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor driving parameter and an electric power parameter of the back end.
进一步的,所述监视方法(#22),当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。Further, the monitoring method (#22), when the source power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter, the fuel power parameter includes a cylinder pressure, a fuel consumption rate, and an engine air flow rate. Any one or more parameters in the engine load report data.
进一步的,所述监视方法(#22),所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。Further, the monitoring method (#22), the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, a general private vehicle, a general train, a crawler vehicle. An electric vehicle, a fuel cell powered vehicle, a motorcycle, a two-wheeled vehicle or a tricycle with a power system, any one of the aircraft that operates on land and whose air lift is lower than a preset threshold or whose longitudinal speed is lower than a preset value.
进一步的,所述监视方法(#22),测算对象为车辆质量、纵向速度、电气功率中任意一种或多种参数。Further, in the monitoring method (#22), the measurement object is any one or more of vehicle mass, longitudinal speed, and electric power.
本技术方案的实施说明与有益效果:相较于其他测算对象(如坡度、加速度、效率系数等),车辆质量(尤其是其中的运载物品质量)最为司乘人员熟知和关注;其次是纵向速度,司乘人员均可直接感知实际速度;电气功率的实际值通常也会直接显示与仪表盘;这几种参数均便于提供司乘人员直观的对于车辆运行状况的监控效果,更有助于提升安全监控效果。 The implementation description and beneficial effects of the technical solution: compared with other measuring objects (such as slope, acceleration, efficiency coefficient, etc.), the vehicle quality (especially the quality of the carried goods therein) is most familiar and concerned by the passengers; secondly, the longitudinal speed The passengers can directly perceive the actual speed; the actual value of the electric power is usually displayed directly with the instrument panel; these parameters are all convenient to provide the visual observation of the vehicle's operating conditions and help to improve. Security monitoring effect.
本发明还提供一种车辆运行参数的监视系统(#37),测算对象是车辆的车辆运行参数中任意一种或多种参数,所述监视系统包括联合运算值获取模块(1)、指示模块(2):The invention also provides a monitoring system (#37) for vehicle operating parameters, the measuring object is any one or more parameters of vehicle operating parameters of the vehicle, and the monitoring system comprises a joint operation value acquiring module (1) and an indicating module. (2):
所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值;联合运算值为基于车辆运动平衡计算公式计算所得的结果;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle; the joint operation value is a result calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a description The formula of the balance between the dynamic direction of the vehicle and the associated resistance in the running direction or the formula of the deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance;
所述指示模块(2)用于在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的联合运算值。The indication module (2) is configured to output a joint operation value of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
该监视系统还可包括启动模块,用于开机自启动或者接收人工收操作指令后启动监视系统中的其他各个模块开始进行工作,具体的功能与上述监视方法相对应,具体可参考上述监视方法。The monitoring system may further include a startup module, which is configured to start other operations in the monitoring system after the startup or receiving the manual operation instruction, and the specific function corresponds to the foregoing monitoring method, and the specific monitoring method may be referred to.
进一步的,所述监视方法(#22),所述车内电子设备包括车内导航系统、倒车雷达、车内中控台、驾驶屏显系统、车内仪表盘、行车记录仪、车内视频监控系统中任意一种或多种设备。Further, in the monitoring method (#22), the in-vehicle electronic device includes an in-vehicle navigation system, a reversing radar, an in-vehicle center console, a driving screen display system, an in-vehicle dashboard, a driving recorder, and an in-vehicle video. Monitor any one or more devices in the system.
进一步的,所述监视方法(#22),所述便携式个人消费电子产品包括手机、智能手表、智能手环中任意一种或多种设备。Further, the monitoring method (#22), the portable personal consumer electronic product includes any one or more of a mobile phone, a smart watch, and a smart bracelet.
本发明还提供一种车辆数据的处理方法(#1),测算对象为车辆运行参数中任意一个或多个参数,包括步骤:The invention also provides a method (#1) for processing vehicle data, wherein the measurement object is any one or more parameters of the vehicle operation parameter, and the steps include:
获取测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得的结果;Obtaining a joint operation value of the measurement object, wherein the joint operation value is a result calculated based on a vehicle motion balance calculation formula;
还包括下列任意一个或多个步骤:Also includes any one or more of the following steps:
20A1.所述测算对象为车辆运行参数中不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出和/或保存;20A1. The measurement object is any one or more parameters of the vehicle operating parameter and/or the preset parameter and/or the system inherent parameter, and the combined operation value is output and/or saved;
20A2、当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,所述处理方法还需获取所述测算对象的相关数据;将所述联合运算值和所述相关数据输出和/或保存。20A2, when the measurement object is any one of vehicle operation parameters other than unmeasurable parameters and/or preset parameters and/or system inherent parameters, the processing method further needs to acquire correlations of the measurement objects. Data; outputting and/or saving the joint operation value and the related data.
当所述测算对象为车辆质量、需测量的参数和/或可测量的参数和/或源动力参数和/或机械运行参数和/或质量变化型物品质量中任一参数时,该测算对象的相关数据为该测算对象的第二许可范围、实际值、联合运算值与实际值的差值、第一许可范围中任意一种或多种数据;当所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任一参数时,该测算对象的相关数据为该测算对象的第二许可范围、实际值、联合运算值与实际值的差值、标定值、联合运算值与标定值的差值、第一许可范围中任意一种或多种数据;When the measurement object is any one of a vehicle mass, a parameter to be measured, and/or a measurable parameter and/or a source dynamic parameter and/or a mechanical operation parameter and/or a mass change type item quality, the measurement object The relevant data is a second permission range, an actual value, a difference between the joint operation value and the actual value, and any one or more data in the first permission range; when the measurement object is an unmeasured parameter and/or When any one of the parameter and/or the system intrinsic parameter can be preset, the relevant data of the measurement object is the second permitted range, the actual value, the difference between the joint operation value and the actual value, the calibration value, and the joint operation of the measurement object. The difference between the value and the calibration value, any one or more of the first permitted range;
该车辆运动平衡计算公式及计算方法及参数的设置方法可参考本文中任一位置的内容进行;The vehicle motion balance calculation formula and the calculation method and the parameter setting method can be referred to the content of any position in this document;
综合而言,测算对象的相关数据或车辆运动平衡计算公式中的输入参数中所包括的的路面坡度 θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信息计算所得或传感器测量数据获取;In summary, the road surface gradient included in the input data of the measurement object or the input parameter in the vehicle motion balance calculation formula The value of any one or more of θ, the rolling resistance coefficient f, and the rolling resistance coefficient component fr related to the road condition may be calculated based on the position information of the road or obtained by the sensor measurement data;
该处理方法(#1)中,该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;In the processing method (#1), the vehicle motion balance calculation formula is a formula describing a formula of the balance between the dynamic direction and the related resistance of the vehicle in the running direction or a deformation thereof; the correlation resistance includes any one of rolling resistance, slope resistance, shift resistance, and wind resistance. One or any of a plurality of; or the related resistance includes one of rolling resistance, slope resistance, shift resistance, wind resistance, or a combination of rolling resistance, slope resistance, shift resistance, and wind resistance;
该车辆运动平衡计算公式的输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;The input parameter of the vehicle motion balance calculation formula is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula;
优选的,设定输入参数中以实测取值的参数个数,这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Preferably, the number of parameters in the input parameter to be measured is set, and the parameters are set based on the measured value; other parameters may be set by preset values; the more the measured parameters, the higher the accuracy will be, the better the monitoring performance is. The measured parameters are less costly; the user and the manufacturer can customize according to their different situations.
优选的,可参考前述测算方法(#1)、及其动力Fx的变形、输入参数的值的基础设置方案、测算对象类型或输入参数的值的设置方案2及其各优选方案、开机自启动或者接收人工收操作指令后启动中任意一个或多个方案,用于该处理方法中。Preferably, reference may be made to the foregoing measurement method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and various preferred schemes thereof, and the booting from the startup Or any one or more schemes in the startup after receiving the manual operation instruction for use in the processing method.
该处理方法开机自启动或者接收人工收操作指令后启动。在本发明中,该处理方法可以开机自启动,无需人为操作,在集成该处理方法的电子设备上电后自行运行,该自行运行可以是在上电后立刻开始运行,也可以是在经过预设时间后可以运行。其中,上述预设时间内可以仅作为一个待机时间,在该时间段内不执行其他应用程序,同时也可以在上述预设时间内执行其他应用程序,并可以进一步的以其他应用程序执行到一定程度(如执行一半或者执行完毕等)作为时间点来开始启动本监控方法或者直接以该些其他应用程序发送的启动指令来启动本监控方法。在接收人工操作指令后启动的工作模式中,该操作指令是用于控制本监控方法开始运行,其是在车内的操作按钮、触控屏或者其他移动电子设备(如手机)等在经过人为操作后产生。与之对应,在车辆数据的处理系统中,该处理系统还包括还包括启动模块,用于开机自启动或者接收人工收操作指令后启动处理系统中的其他各个模块开始进行工作,具体的功能与上述处理方法相对应,具体可参考上述处理方法。The processing method is started after starting up or receiving a manual receiving operation instruction. In the present invention, the processing method can be booted and self-started, without human operation, and the electronic device integrated with the processing method runs after self-powering, and the self-running may start immediately after power-on, or may be pre-evented. It can be run after setting the time. The preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications. The degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications. In the working mode initiated after receiving the manual operation instruction, the operation instruction is used to control the start of operation of the monitoring method, and the operation button, touch screen or other mobile electronic device (such as mobile phone) in the vehicle is subjected to artificial action. Produced after the operation. Correspondingly, in the processing system of the vehicle data, the processing system further includes a startup module, configured to start other work in the processing system after the booting or receiving the manual receiving operation instruction, and the specific function and the specific function and The above processing methods are corresponding, and specific reference can be made to the above processing method.
一种车辆数据的处理方法的20A1分支方案的实施细节:Implementation details of a 20A1 branching scheme for a method of processing vehicle data:
通过输出和/或保存系统固有参数(尤其为其中的效率系数、滚阻系数等)的联合运算值中的联合运算值,形成了该参数的历史记录原值。The historical value of the historical record of the parameter is formed by outputting and/or saving the joint operation value in the joint operation value of the system inherent parameter (especially the efficiency coefficient, the rolling resistance coefficient, etc.).
一种车辆数据的处理方法的20A2分支方案的实施细节:Implementation details of a 20A2 branching scheme for a method of processing vehicle data:
通过输出和/或保存测算对象的联合运算值,形成了该参数的历史记录原值,通过输出和/或保存测算对象的实际值,形成了该参数的历史记录实际值;其联合运算值和实际值的具体获取方式,可参照本文前述内容;因测算对象可能为除系统固有参数之外的其他的车辆运行参数中参数时(如 纵向速度),因为该类型参数的实际值和联合运算值均可能大幅波动(如从零到120KM/H),在此时如果仅仅单独凭借其历史记录原值或历史记录实际值,均不便于作为设置用于车辆动力传递状况监控的参考数据的数据源,也不便于用户/或交警/或保险人员直观评估车辆状况,所以需要同时输出和/或保存历史记录原值和历史记录实际值;输出和/或保存该测算对象的联合运算值和实际值的差值,可以形成该测算对象的历史记录差值;By outputting and/or saving the joint operation value of the measured object, the original value of the historical record of the parameter is formed, and the actual value of the historical record of the parameter is formed by outputting and/or saving the actual value of the measured object; the joint operation value and For the specific acquisition method of the actual value, refer to the foregoing content; if the measurement object may be other parameters of the vehicle operating parameters other than the inherent parameters of the system (such as Longitudinal speed), because the actual value of the type parameter and the joint operation value may fluctuate greatly (such as from zero to 120KM/H), at this time, it is inconvenient to rely solely on its historical original value or historical actual value. As a data source for setting reference data for vehicle power transmission condition monitoring, it is also inconvenient for the user/or traffic police/insurer to visually evaluate the vehicle condition, so it is necessary to simultaneously output and/or save the historical original value and the historical record value; Outputting and/or saving the difference between the joint operation value and the actual value of the measurement object, may form a historical record difference value of the measurement object;
本处理方法(#1),可用于反映或分析或判断车辆的运行状况是否正常,尤其可用于反映或分析或判断车辆的动力传递状况是否正常,尤其可用于反映或分析或判断车辆的动力传递状况是否正常,也即可用于反映或分析或判断车辆中与动力的传递相关的系统的运行状况和/或运行环境的状况是否正常;车辆中与动力的传递相关的系统包括待监控的动力传动部件和/或第二车轮;第二车轮和/或传动部件中所包括的驱动轮均可称为车轮;该系统,尤其指旋转工作型动力或传动部件;车辆中与动力的传递相关的系统的运行状况,尤其指待监控的动力传动部件的动力传递的效率状况(也即效率系数的大小)和/或车轮的滚动阻力系数(尤其为其中的与车辆相关的滚阻系数分量fc)的大小。The processing method (#1) can be used to reflect or analyze or judge whether the running condition of the vehicle is normal, and particularly can be used for reflecting or analyzing or judging whether the power transmission condition of the vehicle is normal, and particularly can be used for reflecting or analyzing or judging the power transmission of the vehicle. Whether the condition is normal or not can be used to reflect or analyze or judge whether the operating condition of the system related to the transmission of power in the vehicle and/or the condition of the operating environment is normal; the system related to the transmission of power in the vehicle includes the power transmission to be monitored. The components and/or the second wheel; the drive wheel included in the second wheel and/or the transmission component may be referred to as a wheel; the system, in particular, a rotary working power or transmission component; a system related to the transmission of power in the vehicle The operating condition, in particular the efficiency condition of the power transmission of the power transmission component to be monitored (ie the magnitude of the efficiency factor) and/or the rolling resistance coefficient of the wheel (especially the rolling factor component fc associated with the vehicle therein) size.
进一步的,该处理方法(#1)中:以车辆质量、系统固有参数、质量变化型物品质量中任意一种参数作为测算对象;或以除纵向加速度之外的车辆运行参数中任意一种参数作为测算对象;或以除源动力参数之外的车辆运行参数中任意一种参数作为测算对象;或以除纵向加速度和/或源动力参数之外的车辆运行参数中任意一种参数作为测算对象;以更好的反映或分析或判断车辆的运行状况是否正常;Further, in the processing method (#1): any one of a vehicle quality, a system inherent parameter, and a quality change item quality is used as a measurement target; or any one of vehicle operating parameters other than the longitudinal acceleration As the measurement object; or as one of the vehicle operating parameters other than the source dynamic parameter; or any one of the vehicle operating parameters other than the longitudinal acceleration and/or the source dynamic parameter as the measurement object To better reflect or analyze or judge whether the vehicle's operating conditions are normal;
一种车辆数据的处理方法的20A1分支方案的有益效果:A beneficial effect of the 20A1 branching scheme of a method of processing vehicle data:
系统固有参数(尤其为其中的效率系数、滚阻系数等)还与车辆旋转工作型动力或传动部件的磨损/或老化/或安全状况紧密关联;当所处理的数据包括滚阻系数时,其与汽车轮胎的气压、轮胎形变(失圆度)、磨损状况、爆胎几率紧密相关相关;对于高铁等车辆的刚性滚动轮(即车轮),该系数与其磨损状况相关;当所处理数据包括效率系数时:该参数通常直接与车辆的动力及传动系统的磨损、安全状况相关;效率过低就意味着车辆磨损老化严重,效率突变意味着动力系统可能存有严重隐患;保存该参数具有重要意义;The inherent parameters of the system (especially the efficiency factor, rolling resistance coefficient, etc.) are also closely related to the wear/or aging/safe condition of the vehicle's rotating working power or transmission components; when the processed data includes the rolling resistance coefficient, Automobile tire pressure, tire deformation (roundness), wear condition, and puncture probability are closely related; for rigid rolling wheels (ie, wheels) of vehicles such as high-speed rail, the coefficient is related to the wear condition; when the processed data includes the efficiency coefficient : This parameter is usually directly related to the vehicle's power and transmission system's wear and safety conditions; low efficiency means that the vehicle wears out aging seriously, and the sudden change in efficiency means that the power system may have serious hidden dangers; it is important to save this parameter;
本文中前述动力传递状况监控方案,需要设置其中的参考数据(如动力传递状况识别数据),本方案中形成的历史记录值,可以作为动力传递状况识别数据的理想设置依据,比依靠人工试凑法或经验法设置可以提高监控灵敏度,从常规的模糊控制变为精确控制;In the foregoing power transmission condition monitoring scheme, the reference data (such as power transmission status identification data) needs to be set, and the historical record value formed in the scheme can be used as an ideal setting basis for the power transmission status identification data, rather than relying on manual trial and error. Method or empirical method settings can improve monitoring sensitivity, from conventional fuzzy control to precise control;
现有技术对车辆的动力传递异常监控研究不足,对于能相对准确衡量的车辆动力传递状况的定量数据的测算方法更为盲区;当前车联网、互联网,需要采集庞杂繁多的数据(甚至需要构建成本高昂、庞大的大数据系统),尚不容易准确识别车辆动力系统的磨损/老化/安全状况;本发明所提供 方法,仅仅通过一个或两个数据,还可以用于直接、简便、低成本的诊断车辆的旋转工作型动力或传动部件的性能状况,如果历史记录差值偏大,或者历史记录差值与历史记录实际值偏差过大,用户/交警/保险公式可以很直观的可鉴别出车辆旋转工作型动力或传动部件的磨损/或老化/或安全状况。The prior art has insufficient research on the abnormality monitoring of power transmission of vehicles, and the measurement method of quantitative data of vehicle power transmission status that can be relatively accurately measured is more blind. The current Internet of Vehicles and the Internet need to collect a large amount of data (even the construction cost is required). High and large big data systems), it is not easy to accurately identify the wear/age/safety conditions of the vehicle's power system; The method, which can only be used for direct, simple and low-cost diagnosis of the rotational working power of the vehicle or the performance of the transmission component, with only one or two data, if the historical difference is too large, or the historical difference and history Recording the actual value deviation is too large, the user / traffic police / insurance formula can be very intuitive to identify the vehicle's rotating working power or transmission parts wear / or aging / or safety conditions.
进一步的,该处理方法(#1)中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。Further, in the processing method (#1), the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor driving parameter and an electric power parameter of the back end.
30.进一步的,该处理方法(#1)中,所述车辆数据的处理方法还包括:获取并输出和/或保存所述测算对象的动力传递状况关联因子的值。30. Further, in the processing method (#1), the processing method of the vehicle data further includes: acquiring and outputting and/or saving a value of a power transmission condition correlation factor of the measurement object.
该技术方案的实施细节:获取并输出和/或保存所述测算对象的动力传递状况关联因子的值,可生成历史记录关联因子值;根据所得的历史记录关联因子值、历史记录差值、历史记录原值、历史记录实际值建立综合关联的历史记录数据库;Implementation details of the technical solution: acquiring and outputting and/or saving the value of the power transmission condition correlation factor of the measurement object, and generating a history correlation factor value; according to the obtained history, the correlation factor value, the history difference value, and the history Record the original value, the historical value of the historical record to establish a comprehensive history database;
车辆运行时,不同的动力传递状况关联因子的值,可能导致参与车辆运动平衡计算的车辆运行参数的值发生幅度不同的变化,进而可能导致计算所得的联合运算值或/和参考数据发生变化,进而可能导致动力传递异常的判断结果发生变化;设立具有一个或多个动力传递状况关联因子的动力传递状况关联因子数据库,并且该数据库的参数多少可由用户可由用户任意设定、任意裁剪、任意扩充;When the vehicle is running, the values of different power transmission condition correlation factors may cause different values of the values of the vehicle operating parameters participating in the vehicle motion balance calculation, which may cause the calculated joint operation values or/and reference data to change. Further, the judgment result of the power transmission abnormality may be changed; a power transmission condition correlation factor database having one or more power transmission condition correlation factors is established, and the parameters of the database may be arbitrarily set by the user, arbitrarily tailored, and arbitrarily expanded. ;
本发明所述调整调整动力传递异常判断数据,包括直接调整动力传递异常判断数据,如参考数据、联合运算值、动力传递异常的判断结果等;也包括通过调整参与车辆运动平衡计算的车辆运行参数的值间接调整动力传递异常判断数据;The adjustment and adjustment power transmission abnormality determination data of the present invention comprises directly adjusting power transmission abnormality determination data, such as reference data, joint operation value, determination result of power transmission abnormality, etc.; and also includes adjusting vehicle operating parameters by participating in vehicle motion balance calculation. The value of the indirect adjustment of the power transmission abnormality determination data;
例如不同的路面坡度、不同的纵向速度、不同的车况均可能导致车辆的滚阻系数发生变化,进而导致包含滚阻系数的车辆运动平衡计算所得联合运算值、参考数据发生变化,进而导致动力传递异常的判断结果发生变化;例如车辆速度越高时车辆可能发飘,如同飞机原理车辆也可能产生空气升力从而导致滚阻系数值(或车辆质量承受的重力)变化;所以可以通过设立路面坡度、纵向速度、车况指数与滚阻系数(或重力加速度g值)的关联表格,用调整后的参数值参与车辆运动平衡计算,从而间接性调整动力传递异常判断数据;For example, different road gradients, different longitudinal speeds, and different vehicle conditions may cause the rolling resistance coefficient of the vehicle to change, which may result in a change in the joint operation value and reference data of the vehicle motion balance calculation including the rolling resistance coefficient, thereby causing power transmission. The abnormal judgment result changes; for example, the vehicle may float when the vehicle speed is higher. Like the aircraft principle, the vehicle may generate air lift and cause the rolling resistance coefficient value (or the gravity of the vehicle mass) to change; therefore, it is possible to establish the road gradient and the longitudinal direction. The association table of the speed, the vehicle condition index and the rolling resistance coefficient (or the gravitational acceleration g value) participates in the vehicle motion balance calculation with the adjusted parameter value, thereby indirectly adjusting the power transmission abnormality determination data;
例如车况良好指数高时,或路况良好指数高时,或载况良好指数高时,可减少动力传递状况识别差值的绝对值幅度以提高监控灵敏度;反之如车况良好指数低时,或路况良好指数低时,或载况良好指数低时,可增加动力传递状况识别差值的绝对值幅度以降低误报率;如负向的纵向加速度超过某个阈值(如车辆急剧减速时),可将动力传递异常的判断结果直接设置为未发生动力传递异常;本方案的有益意义:根据不同动力传递状况关联因子的值调整动力传递异常判断数据,可在不同的车况、路况、载况、位置、车辆的车辆质量、源动力参数、系统运行参数的值时,提高参数计算精 度、动力传递异常监控灵敏度,降低误报率。For example, when the good condition of the vehicle is high, or when the road condition is high, or when the good condition is high, the absolute value of the difference in the power transmission condition can be reduced to improve the monitoring sensitivity; otherwise, if the good condition is low, or the road is good. When the index is low, or when the good load index is low, the absolute value of the difference in power transmission condition can be increased to reduce the false alarm rate; if the negative longitudinal acceleration exceeds a certain threshold (such as when the vehicle is decelerating rapidly), The judgment result of the power transmission abnormality is directly set as the power transmission abnormality does not occur; the beneficial significance of the scheme: the power transmission abnormality judgment data is adjusted according to the values of the different power transmission condition correlation factors, and can be in different vehicle conditions, road conditions, load conditions, positions, Improve the parameter calculation when the vehicle's vehicle quality, source dynamic parameters, and system operating parameters are used. Degree, power transmission abnormal monitoring sensitivity, reduce false positive rate.
本技术方案的有益效果:建立综合关联的历史记录数据库,有助于进一步提高动力传递状况判断所需参考数据的设置的准确度,便于动力传递异常监控灵敏度提高。The beneficial effects of the technical solution: establishing a comprehensive associated history database helps to further improve the accuracy of the setting of reference data required for power transmission status judgment, and facilitates the improvement of power transmission abnormality monitoring sensitivity.
优选的,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。Preferably, the vehicle is a high-speed rail vehicle, a motor train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, an ordinary private vehicle, a general train, a tracked vehicle, an electric vehicle, a fuel cell powered vehicle, A motorcycle, a two-wheeled vehicle or a tricycle with a power system, any one of the aircraft that operates on land and whose air lift is lower than a preset threshold or whose longitudinal speed is lower than a preset value.
本发明还提供The invention also provides
(40.)一种车辆数据的处理系统,测算对象为车辆运行参数中任意一个或多个参数,所述处理系统包括联合运算值获取模块(1)、所述处理系统还包括输出模块(2)和/或保存模块(3):(40.) A processing system for vehicle data, the measurement object being any one or more parameters of vehicle operating parameters, the processing system comprising a joint operation value acquisition module (1), the processing system further comprising an output module (2) ) and / or save module (3):
所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得的结果;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,还需获取所述测算对象的相关数据;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle, and the joint operation value is a result calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula a formula for describing the balance between the dynamic direction of the vehicle in the running direction and the associated resistance or a variant thereof; the relevant resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; When measuring parameters and/or any one of the vehicle operating parameters other than the preset parameters and/or the system inherent parameters, the related data of the measuring object is also acquired;
所述输出模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出;和/或The output module (2) is configured to: output the joint operation value; and/or the measurement object is an unmeasured parameter and/or any one or more of a preset parameter and/or a system inherent parameter; and/or
当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,还需获取所述测算对象的相关数据,将所述联合运算值和所述相关数据输出;When the measured object is any one of the vehicle operating parameters except the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the related data of the measuring object is also acquired, and the joint is An operation value and the related data output;
所述保存模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值保存;和/或The saving module (2) is configured to: save the joint operation value as: the unmeasured parameter and/or any one or more parameters of the preset parameter and/or the system intrinsic parameter; and/or
当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,还需获取所述测算对象的相关数据,将所述联合运算值和所述相关数据保存。When the measured object is any one of the vehicle operating parameters except the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the related data of the measuring object is also acquired, and the joint is The calculated value and the related data are saved.
本发明要解决的技术问题之四是提供一种简便的监控车辆超载的技术方案;The fourth technical problem to be solved by the present invention is to provide a simple technical solution for monitoring vehicle overload;
本发明的目的是通过以下技术方案来实现的:The object of the present invention is achieved by the following technical solutions:
本发明提供一种车辆由动力装置控制运行时超载的监控方法,所述监控方法包括步骤:The invention provides a monitoring method for controlling overload of a vehicle by a power device, and the monitoring method comprises the steps of:
A.获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载;A. acquiring a joint operation value of the vehicle mass of the vehicle, the joint operation value being calculated based on a vehicle motion balance calculation formula; determining, according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle Whether the vehicle is overloaded;
B.进行下述B1、B2、B3中任意一种或多种方案处理:B. Perform any one or more of the following B1, B2, and B3 treatments:
B1.如所述判断结果包括是,则启动设定的超载处理机制;B1. If the judgment result includes yes, the set overload processing mechanism is started;
B2.输出所述判断结果; B2. outputting the judgment result;
B3.保存所述判断结果。B3. Save the judgment result.
该车辆运动平衡计算公式及计算方法及参数的设置方法可参考本文中任一位置的内容进行;The vehicle motion balance calculation formula and the calculation method and the parameter setting method can be referred to the content of any position in this document;
该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;或者说:该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中一种,或包括滚动阻力、坡度阻力、变速阻力、风阻中任意多种之和;The vehicle motion balance calculation formula is a formula for describing a balance between the dynamic direction of the vehicle and the related resistance in the running direction or a deformation thereof; the related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance; or The related resistance includes one of rolling resistance, slope resistance, shift resistance, wind resistance, or a combination of rolling resistance, slope resistance, shift resistance, and wind resistance;
该车辆运动平衡计算公式的输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;The input parameter of the vehicle motion balance calculation formula is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula;
优选的,设定输入参数中以实测取值的参数个数,这些参数为基于实测值设定;其它的参数可由预设值设定;实测的参数越多精度自然会越高、监控性能好;实测的参数少成本越低;用户与生产厂家可根据各自不同情况自由定制。Preferably, the number of parameters in the input parameter to be measured is set, and the parameters are set based on the measured value; other parameters may be set by preset values; the more the measured parameters, the higher the accuracy will be, the better the monitoring performance is. The measured parameters are less costly; the user and the manufacturer can customize according to their different situations.
优选的,可参考前述测算方法(#1)、及其动力Fx的变形、输入参数的值的基础设置方案、测算对象类型或输入参数的值的设置方案2及其各优选方案、开机自启动或者接收人工收操作指令后启动中任意一个或多个方案,用于该监控方法中。Preferably, reference may be made to the foregoing measurement method (#1), the deformation of the power Fx, the basic setting scheme of the value of the input parameter, the setting scheme 2 of the value of the input object or the value of the input parameter, and various preferred schemes thereof, and the booting from the startup Or any one or more schemes in the startup after receiving the manual operation instruction for the monitoring method.
综合而言,车辆运动平衡计算公式中的输入参数中所包括的的路面坡度θ、滚阻系数f、与路况相关的滚阻系数分量fr中任一种或多种参数的值,可基于该道路的位置信息计算所得或传感器测量数据获取;In general, the value of any one or more of the road surface gradient θ, the rolling resistance coefficient f, and the road condition-related rolling resistance component fr included in the input parameter in the vehicle motion balance calculation formula may be based on the Acquisition of position information of the road or acquisition of sensor measurement data;
该监控方法开机自启动或者接收人工收操作指令后启动。在本发明中,该监控方法可以开机自启动,无需人为操作,在集成该监控方法的电子设备上电后自行运行,该自行运行可以是在上电后立刻开始运行,也可以是在经过预设时间后可以运行。其中,上述预设时间内可以仅作为一个待机时间,在该时间段内不执行其他应用程序,同时也可以在上述预设时间内执行其他应用程序,并可以进一步的以其他应用程序执行到一定程度(如执行一半或者执行完毕等)作为时间点来开始启动本监控方法或者直接以该些其他应用程序发送的启动指令来启动本监控方法。在接收人工操作指令后启动的工作模式中,该操作指令是用于控制本监控方法开始运行,其是在车内的操作按钮、触控屏或者其他移动电子设备(如手机)等在经过人为操作后产生。The monitoring method is started after starting up or receiving a manual receiving operation instruction. In the present invention, the monitoring method can be started up automatically, without human operation, and the electronic device integrated with the monitoring method runs after self-powering, and the self-running may start immediately after power-on, or may be pre-evented. It can be run after setting the time. The preset time may be only used as a standby time, and other applications are not executed during the time period, and other applications may be executed within the preset time, and may be further executed by other applications. The degree (such as half of execution or execution completion, etc.) is used as a point in time to start the monitoring method or to start the monitoring method directly with the startup instructions sent by the other applications. In the working mode initiated after receiving the manual operation instruction, the operation instruction is used to control the start of operation of the monitoring method, and the operation button, touch screen or other mobile electronic device (such as mobile phone) in the vehicle is subjected to artificial action. Produced after the operation.
进一步的,所述监控方法中,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。Further, in the monitoring method, the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more parameters of a motor driving parameter and a back end electrical power parameter.
进一步的,所述监控方法中,当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。Further, in the monitoring method, when the source power parameter in the calculation based on the vehicle motion balance calculation is a fuel power parameter, the fuel power parameter includes a cylinder pressure, a fuel consumption rate, an engine air flow, and an engine load. Report any one or more parameters in the data.
进一步的,所述监控方法中,当所述车辆处于非稳定驱动状态时使本次监控无效或取消本次判断过程或取消本次判断结果;其中,当车辆的源动力参数、机械类综合运行力、速度中的至少一种 小于预设阀值时,或者车辆的动力装置运行工况为动力装置制动状态时,所述车辆处于非稳定驱动状态。Further, in the monitoring method, when the vehicle is in an unsteady driving state, the current monitoring is invalidated or the current judgment process is cancelled or the current judgment result is cancelled; wherein, when the vehicle's source dynamic parameters and mechanical types are comprehensively operated At least one of force and speed When the vehicle is less than the preset threshold, or when the power running condition of the vehicle is the power unit braking state, the vehicle is in an unsteady driving state.
本技术方案的有益效果为:现有公知技术对于车辆非稳定驱动状态的研究还处于盲区,因为车辆必然经常进入减速或下坡过程,经常进入非稳定驱动状态,所以识别所述车辆的非稳定驱动状态并屏蔽在该状态的监控,非常有必要,否则将大幅度升高监控系统的误报率,导致监控失效。The beneficial effects of the technical solution are as follows: the prior art research on the unsteady driving state of the vehicle is still in a blind zone, because the vehicle must often enter the deceleration or downhill process, often enters the unstable driving state, so the identification of the vehicle is unstable. It is very necessary to drive the state and shield the monitoring in this state. Otherwise, the false alarm rate of the monitoring system will be greatly increased, resulting in monitoring failure.
27.本发明还提供一种车辆超载的监控系统,所述监控系统包括联合运算值获取模块(1)、超载判断模块(2);所述监控系统还包括超载处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;27. The present invention also provides a vehicle overload monitoring system, the monitoring system includes a joint operation value acquisition module (1), an overload determination module (2); the monitoring system further includes an overload processing module (3), an output module (4) saving any one or more of the modules (5);
所述联合运算值获取模块(1)用于:获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;The joint operation value obtaining module (1) is configured to: acquire a joint operation value of a vehicle mass of the vehicle, where the joint operation value is calculated based on a vehicle motion balance calculation formula;
所述超载判断模块(2)用于:根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载;The overload judgment module (2) is configured to: determine whether the vehicle is overloaded according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle;
所述超载处理模块(3)具有下述功能:如所述判断结果包括是,则启动设定的超载处理机制;The overload processing module (3) has the following functions: if the determination result includes yes, the set overload processing mechanism is activated;
所述输出模块(4)用于:输出所述超载判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the overload determination module (2);
所述保存模块(5)用于:保存所述超载判断模块(2)的判断结果。。The saving module (5) is configured to: save the determination result of the overload determination module (2). .
该监控系统还包括启动模块,用于开机自启动或者接收人工收操作指令后启动监控系统系统中的其他各个模块开始进行工作,具体的功能与上述监控方法相对应,具体可参考上述监控方法。The monitoring system further includes a startup module, which is used for starting the self-starting or receiving the manual receiving operation instruction, and then starting other working modules in the monitoring system to start the work. The specific function corresponds to the above monitoring method, and the specific monitoring method may be referred to.
本技术方案的实施说明:Description of the implementation of this technical solution:
本技术方案与前述的一种车辆由动力装置控制运行时的监控方法和系统,具有部分相同的技术特征,如前述技术方案中获取所述车辆的测算对象的联合运算值的方案,包含了本技术方案中获取所述车辆的车辆质量的联合运算值的方案,两者联合运算值的都为基于车辆运动平衡计算公式计算所得;本发明所述无效,包括在任何位置中止测算、中止参数获取、中止判断、或使判断结果无效等任意一种或多种处理方式。The technical solution and the foregoing monitoring method and system for controlling the operation of the vehicle by the power device have partially the same technical features, and the solution for acquiring the joint operation value of the measurement object of the vehicle in the foregoing technical solution includes the The solution for obtaining the joint operation value of the vehicle mass of the vehicle in the technical solution, the joint operation values of the two are calculated based on the vehicle motion balance calculation formula; the invalidity of the invention includes stopping the calculation and stopping the parameter acquisition at any position. Any one or more of the processing methods, such as aborting the judgment, or invalidating the judgment result.
但是后续的步骤中,本技术方案的超载判断,与前述技术方案的动力传递状况判断,两者又有本质、重大区别;However, in the subsequent steps, the overload judgment of the technical solution and the judgment of the power transmission condition of the foregoing technical solution have essential and significant differences;
超载判断的目的如下:判断车辆所载人员/物品是否超重;The purpose of the overload judgment is as follows: to determine whether the person/item contained in the vehicle is overweight;
超载判断的技术方案:基准的设置方式:根据车辆法定载重量,也即某种安全极限阈值设置判断基准;具体触发方式:只要车辆质量超过1.0倍车辆最大法定载重量即启动报警;Technical solution for overload judgment: the setting method of the reference: according to the legal load capacity of the vehicle, that is, a certain safety limit threshold setting judgment criterion; the specific trigger mode: as long as the vehicle mass exceeds 1.0 times the maximum legal load of the vehicle, the alarm is activated;
超载判断的输出动作:输出超载信号,提醒司乘人员减少运载人员/物品质量。Output action of overload judgment: Output overload signal to remind the passenger to reduce the quality of the carrier/item.
超载判断的对于动力传递状况故障识别的效果:如本发明背景说明中所示典型状况,当车辆的旋转工作型动力或传动部件在高速运行中发生异常磨损或变形/运行阻力增大/效率变低时,如车辆质量联合运算值由4人变为6人/480KG/车辆动力传递状况严重故障/继续运行可能发生严重的、不 可预测的安全事故(包括断轴、车毁人亡等)/急需警示处理,车辆的超载系统会报告:情况正常/未超载;当3人坠车/车辆质量联合运算值变为80KG时,车辆的超载系统也会报告:情况正常/未超载。所以常规的超载系统对车辆动力传递异常(特别是动力传递故障)监控保护几乎无效。Effect of Overload Judgment on Power Transmission Condition Fault Identification: As in the typical situation shown in the background description of the present invention, abnormal wear or deformation/running resistance increase/efficiency change occurs when the rotating working power or transmission component of the vehicle is in high speed operation When low, such as the vehicle quality joint operation value changed from 4 to 6 people / 480KG / vehicle power transmission situation serious failure / continue to operate may occur serious, no Predictable safety incidents (including broken axles, car crashes, etc.) / urgent need for warning handling, the vehicle's overload system will report: normal / not overloaded; when the three-person crash/vehicle quality joint operation value becomes 80KG, The vehicle's overload system will also report: normal / not overloaded. Therefore, the conventional overload system is almost ineffective in monitoring and protecting the vehicle power transmission abnormality (especially power transmission failure).
本发明所述动力传递状况异常判断;The power transmission condition abnormality judgment of the present invention;
动力传递状况判断目的:识别车辆的动力或传动系统的工作异常乃至故障;Power transmission status judgment purpose: to identify the vehicle's power or the operation of the transmission system is abnormal or even faulty;
动力传递状况判断的参考数据的设置方式:动力传递状况识别值要求尽量靠近车辆质量的实际值,且该值可跟随车辆质量实际值柔性漂移;动力传递状况识别值既可远小于车辆最大法定载重量,也可大于车辆最大法定载重量;如车辆短期在1.5倍额定负载工作,则动力传递状况识别范围可设在1.4到1.6倍负载值之间;与固定式、极限式的车辆最大法定载重量设置基准是完全不同的。The setting method of the reference data for the judgment of the power transmission condition: the power transmission status identification value is required to be as close as possible to the actual value of the vehicle mass, and the value can follow the flexible deviation of the actual vehicle mass value; the power transmission status identification value can be much smaller than the maximum legal load of the vehicle. The weight can also be greater than the maximum legal load of the vehicle; if the vehicle is working at 1.5 times the rated load for a short period of time, the power transmission condition identification range can be set between 1.4 and 1.6 times the load value; and the fixed and limit type vehicle can be the maximum legal load. The weight setting benchmark is completely different.
本技术方案的有益效果:车辆的超载监控,虽然对于动力传递异常监控没有效果,但是超载也是影响车辆安全的重要诱因之一,车辆超载了则导致控制性能变差,制动效果差、超负荷易于损坏;本技术方案提供一个自动而无需人工干预的超载保护系统,可自动监控超载,并发出语音提示告警,还可以将告警信息传输到网络系统,从而利于与车辆运行相关的人员或机构(如驾乘人员、运营管理方、交警、故障诊断中心)及时发觉超载安全运行隐患,保障车辆的运行安全;优于现有靠人工计算乘客数量或磅秤称量运载质量的超载监控方案;尤其是用低成本、易测量的电机驱动参数监控超载,相对于现有技术更是大幅度进步。The beneficial effects of the technical solution: the overload monitoring of the vehicle has no effect on the abnormal monitoring of the power transmission, but the overload is also one of the important incentives for the safety of the vehicle. When the vehicle is overloaded, the control performance is deteriorated, the braking effect is poor, and the overload is overloaded. It is easy to damage; the technical solution provides an automatic overload protection system without manual intervention, which can automatically monitor the overload and issue a voice prompt alarm, and can also transmit the alarm information to the network system, thereby facilitating the personnel or institutions related to the operation of the vehicle ( Such as driver and passenger, operation management, traffic police, fault diagnosis center) timely detection of overloaded safe operation hidden dangers, to ensure the safety of the vehicle; better than the existing manual calculation of the number of passengers or scale weighing quality of the overload monitoring program; especially Monitoring overload with low-cost, easy-to-measure motor drive parameters is a significant advance over the prior art.
因为电气动力参数,尤其是电机驱动参数的运用通常属于电力电子领域行业知晓的技术,便于低成本、高精度的测量、获取;车辆运动平衡计算,属于整车车辆运行控制领域行业技术;当前主流的超载监控通常属于车辆运营管理范畴(基本与技术无关,通常由人工目视进行);本发明创造性的将电气动力参数、尤其是电机驱动参数与车辆运动平衡计算相结合,进而而超载监控相结合,对于车辆超载的运营管理具有重要意义。Because the use of electrical power parameters, especially motor drive parameters, is generally a technology known in the power electronics industry, which facilitates low-cost, high-precision measurement and acquisition; vehicle motion balance calculation, which belongs to the industry technology of vehicle vehicle operation control; The overload monitoring is usually in the scope of vehicle operation management (basically related to technology, usually by manual visual observation); the inventive combination of electrical power parameters, especially motor drive parameters and vehicle motion balance calculation, and thus overload monitoring phase The combination is of great significance for the operation management of vehicle overload.
因为现代车辆均具有成熟的动力控制装置、中央控制器、导航系统、网络传输系统;具有成熟的软件硬件平台、动力控制装置内部具有成熟源动力参数测量系统、成熟的车内人机交互界面(显示或语音方式);Because modern vehicles have mature power control devices, central controllers, navigation systems, and network transmission systems; they have mature software and hardware platforms, power control devices with mature source dynamic parameter measurement systems, and mature in-vehicle human-computer interaction interfaces ( Display or voice mode);
所以本发明提供的一种车辆由动力装置控制运行时的监控方法、一种车辆超载的监控方法既可以在独立的设备中运行,也可以集成入现有的中央控制器、或动力控制装置、或导航系统、或其他车载电子设备中运行。Therefore, the present invention provides a monitoring method for controlling a running time of a vehicle by a power device, and a monitoring method for overloading a vehicle, which can be operated in a separate device or integrated into an existing central controller or power control device. Or run in a navigation system, or other in-vehicle electronic device.
所以本发明提供的一种车辆由动力装置控制运行时的监控系统、一种车辆超载的监控系统,既可以作为独立的设备存在,也可以集成入现有的中央控制器、或动力控制装置、或导航系统、或其他车载电子设备中。Therefore, the present invention provides a monitoring system for controlling a running state of a vehicle by a power device, and a monitoring system for overloading the vehicle, which can be used as an independent device or integrated into an existing central controller or power control device. Or in navigation systems, or other in-vehicle electronic devices.
因为现有技术,可以便利实现参数网络传输,所以本发明提供的上述所有技术方案,也完全可 以在各种有线或无线的移动3G、4G网、互联网、物联网、车联网、交警网络中心、运营管理中心、车辆故障诊断中心、GPS网、车内网、局域网(等各种网络云端)中实现。通过网络系统来实现本发明技术方案,既可适用于有人驾驶车辆的网络监控,也可适用于无人驾驶的智能车辆的网络监控。Because the prior art can facilitate the transmission of the parameter network, all the above technical solutions provided by the present invention are also fully applicable. In various wired or wireless mobile 3G, 4G network, Internet, Internet of Things, car networking, traffic police network center, operation management center, vehicle fault diagnosis center, GPS network, in-vehicle network, local area network (such as various network clouds) Implemented in . The technical solution of the present invention is implemented by a network system, and can be applied to network monitoring of a manned vehicle or network monitoring of an unmanned intelligent vehicle.
本发明所提供技术方案,基本上可以在硬件新增成本远低于车辆制造成本的情况下实现,可以大幅度的提高车辆的安全运行系数,利于保障车辆乘员的生命财产安全,降低交警、运营部门管理成本。The technical solution provided by the invention can basically be realized under the condition that the new hardware cost is far lower than the vehicle manufacturing cost, and the safety running coefficient of the vehicle can be greatly improved, the life and property safety of the vehicle occupant can be guaranteed, and the traffic police and operation can be reduced. Department management costs.
本发明所述阈值,也可称为阀值,在本文中两者实质意义相同,两者等同;The threshold value of the present invention may also be referred to as a threshold value, and the two have the same meaning in the present text, and the two are equivalent;
本发明提供的技术方案,不仅仅适用于车辆;当飞行器(如可飞行的车辆等)在陆地以车辆模式运行时也可直接适用;或当飞行器(如喷气式飞机、活塞式飞机等)在陆地上低速运行且纵向运行速度低于一定的幅值,产生的空气升力低于预设阈值(如飞机重量5-10%时),将该飞行器当做本发明所述的车辆,也即该车辆为在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器,将该飞行器的动力装置当做本发明所述动力装置,将该飞行器的动力参数作为本发明所述的源动力参数,将该飞行器的质量作为本发明所述的车辆质量,其余的系统运行参数设置方法可参照本发明所述方法进行(飞机起飞时路面坡度θ通常更小、路面更平整);其测算对象的联合运算值沿用车辆运动平衡原理进行计算;飞行器的源动力参数除了可采用前述的源动力参数多种采集方式外,还可以在发动机喷口后某一位置设置一压力传感器或流量传感器,通过传感器信号计算出发动机输出的驱动力信号;也可在发动机的燃料供应系统、发动机内部采集燃料消耗率、发动机内空气压力或燃烧气体压力等;采用本发明技术方案,便于飞行器在陆地上低速运行时监控动力传递状况是否正常,一旦发现异常可在飞行器上天之前发出动力传递异常预警信号,启动动力传递异常处理机制(如排查异常原因、故障原因、拒绝起飞等);发现异常于地面、避免飞行器上天后才发现故障(可能导致机毁人亡),对飞行器的安全运行有重大价值。The technical solution provided by the present invention is not only applicable to vehicles; it can also be directly applied when an aircraft (such as a flightable vehicle, etc.) operates in a vehicle mode on land; or when an aircraft (such as a jet aircraft, a piston aircraft, etc.) is in use Running on low speed on land and the longitudinal running speed is lower than a certain amplitude, and the generated air lift is lower than a preset threshold (such as 5-10% of the weight of the aircraft), and the aircraft is regarded as the vehicle according to the present invention, that is, the vehicle For an aircraft operating on land and whose air lift is lower than a preset threshold or the longitudinal speed is lower than a preset value, the power device of the aircraft is regarded as the power device of the present invention, and the dynamic parameters of the aircraft are taken as the present invention. Source power parameter, the mass of the aircraft is taken as the vehicle mass according to the present invention, and the remaining system operating parameter setting methods can be referred to the method of the present invention (the road gradient θ is generally smaller and the road surface is flatter when the aircraft takes off); The joint operation value of the measured object is calculated according to the principle of vehicle motion balance; the source power parameters of the aircraft can be multiplied by the aforementioned source dynamic parameters. In addition to the collection mode, a pressure sensor or a flow sensor may be disposed at a position after the engine nozzle, and the driving force signal of the engine output is calculated by the sensor signal; the fuel consumption rate and the engine may also be collected in the fuel supply system of the engine and the engine. The internal air pressure or the combustion gas pressure and the like; adopting the technical scheme of the invention, is convenient for monitoring whether the power transmission condition of the aircraft is normal when the aircraft is running at a low speed on the land, and if an abnormality is found, an abnormal warning signal of the power transmission can be issued before the aircraft is launched, and the power transmission abnormality treatment is started. Mechanisms (such as troubleshooting the cause of the abnormality, the cause of the failure, refusing to take off, etc.); discovering the abnormality on the ground and avoiding the failure of the aircraft before the day (which may lead to the destruction of the aircraft) is of great value to the safe operation of the aircraft.
数据的研究本身就是重要的科学课题;未来的世界、网络的世界就是数据的世界;所谓大数据的实质之一,就说明研究各种关键类型数据的重要性;The research of data itself is an important scientific subject; the world of the future and the world of the Internet are the world of data; one of the essences of the so-called big data illustrates the importance of studying various key types of data;
车辆运动平衡计算,本身就可以视为一种独特的数据;Vehicle motion balance calculation can be regarded as a unique data in itself;
现有技术中,对于“车辆运动平衡计算”对于车辆运行安全的影响缺乏研究;现有技术,对可参与车辆运动平衡计算中的数据,尤其是系统固有参数类的数据(特别是其中的效率系数、滚阻系数)对于车辆运行安全的影响研究不足;现有技术,即使是车辆质量,对其在不同运行流程中幅值是否固定的数据特性对于车辆运行安全的影响研究不足;综合起来,所以现有技术,无法构建一个完整的、自动的动力传递监控系统;In the prior art, there is a lack of research on the impact of "vehicle motion balance calculation" on vehicle operation safety; prior art, data that can participate in vehicle motion balance calculation, especially data of system inherent parameters (especially efficiency therein) Coefficients, rolling resistance coefficient) have insufficient research on the safety of vehicle operation; the prior art, even for vehicle quality, has insufficient research on the influence of the data characteristics of whether the amplitude is fixed in different operating processes on vehicle operation safety; Therefore, the prior art cannot construct a complete and automatic power transmission monitoring system;
本发明对“车辆运动平衡计算”与“车辆运行安全”的关系进行深入研究,并基于以“车辆运 动平衡计算”所获取的数据作为关键技术手段构建多种监控系统或处理系统,从而实现对车辆运行安全技术的一种重大突破;这也是本发明思路一个重要创造点;The invention deeply studies the relationship between "vehicle motion balance calculation" and "vehicle operation safety", and based on "vehicle transportation The data obtained by the dynamic balance calculation is used as a key technical means to construct a variety of monitoring systems or processing systems, thereby achieving a major breakthrough in vehicle operation safety technology; this is also an important creative point of the inventive idea;
本发明对“车辆运动平衡计算”与“车辆运行安全”进行深入研究,提出了以某个参数作为测算对象,通过获取其“车辆运动平衡计算”所得数据(联合运算值),与不同途径或不同时间所设定的参考数据对比,进而判断车辆的动力传递状况是否异常,以此作为关键技术手段构建监控系统,从而实现对车辆运行安全技术的一种重大突破;这也是本发明思路一个重要创造点;The invention makes an in-depth study on "vehicle motion balance calculation" and "vehicle operation safety", and proposes to take a certain parameter as a calculation object, and obtain the data obtained by "vehicle motion balance calculation" (joint operation value), and different ways or Comparing the reference data set at different times to determine whether the vehicle's power transmission status is abnormal, as a key technical means to build a monitoring system, thereby achieving a major breakthrough in vehicle safety technology; this is also an important idea of the present invention. Create a point;
本发明对车辆运动平衡中的数据(尤其是系统固有参数)对车辆运行安全的影响,对其中的科学规律进行深入研究;提出了以系统固有参数作为测算对象作为关键技术手段构建监控系统,从而实现对车辆运行安全技术的一种重大突破;这也是本发明思路一个重要创造点;The invention studies the influence of the data in the vehicle motion balance (especially the inherent parameters of the system) on the operation safety of the vehicle, and deeply studies the scientific law therein; and proposes to construct the monitoring system by using the inherent parameters of the system as the measurement object as a key technical means, thereby A major breakthrough in the implementation of vehicle safety technology; this is also an important creative point of the idea of the invention;
甚至在同样以车辆质量作为测算对象时,而针对其在不同运行流程中幅值是否固定的数据特性进行深入研究;根据该数据特性的不同,制定不同的基准值设置的技术方案;进而构建一个完整的、自动的动力传递异常的监控系统,从而实现对车辆运行安全监控技术的一种重大突破;这也是本发明思路一个重要创造点;Even when the vehicle quality is also used as the measurement object, the data characteristics of whether the amplitude is fixed in different running processes are deeply studied; according to the different data characteristics, different technical solutions for setting the reference value are formulated; Complete and automatic power transmission abnormal monitoring system, thus achieving a major breakthrough in vehicle safety monitoring technology; this is also an important creative point of the inventive idea;
同为为基于基于车辆运动平衡计算计算中的源动力参数,而针对电机驱动参数、非电机驱动参数(在获取途径、获取成本、参数灵敏度、精度等方面)的数据特性进行深入研究;优先以电机驱动参数作为车辆运动平衡计算中的源动力参数,从而带来在成本、灵敏度、精度等性能的重大提升,也即对车辆运行安全监控系统(性价比、灵敏度、精度)的一种重大突破;这也是本发明思路一个重要创造点;The same is based on the source dynamic parameters in the vehicle motion balance calculation calculation, and the data characteristics of the motor drive parameters, non-motor drive parameters (in terms of acquisition path, acquisition cost, parameter sensitivity, accuracy, etc.) are studied in depth; The motor drive parameter is used as the source power parameter in the vehicle motion balance calculation, which brings about a significant improvement in the performance of cost, sensitivity, accuracy, etc., that is, a major breakthrough in the vehicle safety monitoring system (cost performance, sensitivity, accuracy); This is also an important creative point of the inventive idea;
本发明根据多种不同特性的数据对于车辆运行安全的影响,制定多种科学的基准值的设置方案(如实测方式、自学习方式、标定方式),进而构建一个完整的、自动的动力传递异常的监控系统,从而实现对车辆运行安全监控技术的一种重大突破;这也是本发明思路一个重要创造点;The invention develops a set of scientific reference values (such as actual measurement mode, self-learning mode, calibration method) according to the influence of data of a plurality of different characteristics on vehicle operation safety, thereby constructing a complete and automatic power transmission abnormality. Monitoring system to achieve a major breakthrough in vehicle safety monitoring technology; this is also an important creative point of the invention;
本发明针对为基于基于车辆运动平衡计算计算所得数据(也即联合运算值),在不同的场合显示场合对于车辆运行安全的影响进行深入研究;将为基于基于车辆运动平衡计算计算所得数据显示在便于车内司乘人员目视监控的器件或区域内,将显著提高车辆运行安全监控性能;这也是本发明思路一个重要创造点;The present invention is directed to an in-depth study of the impact of vehicle-based operational safety calculations based on vehicle motion balance calculations (ie, joint operational values) on different occasions; It is convenient for the vehicle to monitor and monitor the equipment or area of the vehicle, which will significantly improve the safety monitoring performance of the vehicle; this is also an important creative point of the inventive idea;
本发明针对为基于基于车辆运动平衡计算计算所得数据(也即联合运算值),可以作为一种历史记录值,可以用一个或两个数据即可清晰体现车辆安全状况,避免用无目的、无针对性、纷繁杂乱的大数据去衡量车辆安全状况所带来的成本提升、性能缺失;这也是本发明思路一个重要创造点;The invention is directed to calculating the calculated data based on the vehicle motion balance calculation (that is, the joint operation value), and can be used as a historical record value, and one or two data can be used to clearly represent the vehicle safety condition, avoiding useless purposes and no Targeted, confusing big data to measure the cost increase and lack of performance brought by the vehicle safety situation; this is also an important creative point of the inventive idea;
本发明针对多种数据(如滚阻系数、路面坡度、质量变化型物品质量、动力装置运行工况、运行环境信息、甚至在车辆运行中以车辆质量作为显示对象所带来的独特点)的数据特性,对车辆运行安全监控性能的影响进行深入研究,从而提出各种优化方案;这也是本发明思路一个重要创造点。The invention is directed to a variety of data (such as rolling resistance coefficient, road gradient, quality of quality goods, power plant operating conditions, operating environment information, and even the unique point brought by the vehicle mass as a display object in vehicle operation) Data characteristics, in-depth study of the impact of vehicle safety monitoring performance, to propose various optimization programs; this is also an important creative point of the idea of the present invention.
同为燃料动力参数,而针对气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据、 转矩传感器输出信号等(在获取途径、获取成本、参数灵敏度、精度等方面)的数据特性进行深入研究;优先以(气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据)作为车辆运动平衡计算中的源动力参数,从而带来在成本、灵敏度、精度等性能的重大提升,也即对车辆运行安全监控系统(性价比、灵敏度、精度)的一种重大突破;这也是本发明思路一个重要创造点。Same as fuel power parameters, and for cylinder pressure, fuel consumption rate, engine air flow, engine load report data, In-depth study of the data characteristics of torque sensor output signals (in terms of acquisition path, acquisition cost, parameter sensitivity, accuracy, etc.); priority is given to (vehicle pressure, fuel consumption rate, engine air flow, engine load report data) as vehicle motion Balancing the source dynamic parameters in the calculation, resulting in a significant improvement in performance such as cost, sensitivity, accuracy, etc., that is, a major breakthrough in vehicle safety monitoring system (cost performance, sensitivity, accuracy); Important creation point.
以及将完全不同领域的知识,如飞行器领域的空气升力因素,与本发明构思中在地面运行的车辆,与为基于基于车辆运动平衡计算计算,动力传递状况监控,将该些因素创造性的结合,进而构建可适用于地面低速运行的飞行器的安全监控,也是本发明思路一个重要创造点。And creatively combining these factors with knowledge of completely different fields, such as air lift factors in the field of aircraft, and vehicles operating on the ground in the concept of the present invention, and calculations based on vehicle motion balance calculations, power transmission conditions monitoring, It is also an important creative point to construct the safety monitoring of the aircraft that can be applied to the ground at low speed.
本申请文件中任意一处的名词解释、文字说明、计算公式、参数获取方法、实施方式、实施例及各替换实施例、各延伸实施例等内容均可应用于前、后的任意一个技术方案中;且各部分内容可任意组合、替换;例如本申请文件的监视方法、超载监控方法中的联合运算值的计算方法、获取方法等,可任意调用前述的动力传递状况监控方法、参数测算方法中的内容。The terms of the nouns, the text descriptions, the calculation formulas, the parameter acquisition methods, the implementation modes, the embodiments, the alternative embodiments, the extended embodiments, and the like can be applied to any one of the preceding and following technical solutions. And the contents of each part can be arbitrarily combined and replaced; for example, the monitoring method of the present application, the calculation method of the joint operation value in the overload monitoring method, the acquisition method, etc., the above-mentioned power transmission condition monitoring method and parameter calculation method can be arbitrarily invoked. In the content.
以上内容是结合具体的优选实施方式对本发明所作的进一步详细说明,不能认定本发明的具体实施只局限于这些说明。对于本发明所属技术领域的普通技术人员来说,在不脱离本发明构思的前提下,还可以做出若干简单推演或替换,都应当视为属于本发明的保护范围。 The above is a further detailed description of the present invention in connection with the specific preferred embodiments, and the specific embodiments of the present invention are not limited to the description. It will be apparent to those skilled in the art that the present invention may be made without departing from the spirit and scope of the invention.

Claims (29)

  1. 一种车辆由动力装置控制运行时的监控方法,其特征在于:A monitoring method for controlling a running time of a vehicle by a power device, characterized in that:
    以车辆运行参数中的任意一种为测算对象,获取所述车辆的测算对象的联合运算值,获取所述测算对象的参考数据,根据车辆的测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种。Taking any one of the vehicle operating parameters as a measurement object, acquiring a joint operation value of the measurement object of the vehicle, acquiring reference data of the measurement object, and a joint operation value of the measurement object of the vehicle and a reference of the measurement object The data is used to determine whether the power transmission condition of the vehicle is abnormal; the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a formula of the balance between the power and the related resistance of the vehicle in the running direction or a variant thereof; The related resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance.
  2. 如权利要求1所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,所述监控方法还包括下述步骤:获取所述车辆的运行环境信息;根据所述联合运算值、所述参考数据和所述运行环境信息判断是否发生动力传递异常中的动力传递故障情况。A monitoring method for controlling a running time of a vehicle by a power unit according to claim 1, wherein said monitoring method further comprises the steps of: acquiring operating environment information of said vehicle; The reference data and the operating environment information determine whether a power transmission failure condition in a power transmission abnormality occurs.
  3. 如权利要求1所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,当所述车辆处于非稳定驱动状态时使本次监控无效或取消本次判断过程或取消本次判断结果;其中,当车辆的源动力参数、机械类综合运行力、速度中的至少一种小于预设阀值时,或者车辆的动力装置运行工况为动力装置制动状态时,所述车辆处于非稳定驱动状态。A monitoring method for controlling operation of a vehicle by a power unit according to claim 1, wherein when the vehicle is in an unsteady driving state, the current monitoring is invalidated or the current judgment process is cancelled or the current judgment is cancelled. a result; wherein, when at least one of a source power parameter, a mechanical type comprehensive running force, and a speed of the vehicle is less than a preset threshold, or the power plant operating condition of the vehicle is a power unit braking state, the vehicle is at Unsteady drive state.
  4. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein
    4A1.当所述测算对象为车辆质量中任一参数时:所述参考数据中实际值、第二许可范围中任意一种或多种数据为根据满足设定条件时所进行车辆运动平衡计算获取的联合运算值设定;4A1. When the measurement object is any one of the vehicle quality: any one or more of the actual value and the second permission range in the reference data is calculated according to the vehicle motion balance calculated when the set condition is satisfied. Joint operation value setting;
    或,or,
    4A2.当所述测算对象为除车辆质量之外的车辆运行参数中任一参数时,计算所述联合运算值所需求的车辆质量为基于时间在先的车辆运动平衡计算所得。4A2. When the measurement object is any one of vehicle operating parameters other than the vehicle mass, the vehicle mass required to calculate the joint operation value is calculated based on the time-first vehicle motion balance.
  5. 如权利要求1、2、3中任一项所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,当所述测算对象为系统固有参数和/或为除系统固有参数之外的车辆运行参数中任一参数时,所述监控方法包括下述5A1、5A2、5A3、5A4、5A5中任意一种或多种方案:A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein said measuring object is a system inherent parameter and/or is a system specific parameter. When any of the external vehicle operating parameters is used, the monitoring method includes any one or more of the following 5A1, 5A2, 5A3, 5A4, and 5A5:
    5A1.当参考数据中包括或为第二许可范围时,第二许可范围在安全范围之内;5A1. When the reference data includes or is the second license range, the second license range is within the safe range;
    5A2.当参考数据中包括或为第一许可范围与实际值时,第一许可范围与实际值的和值在安全范围之内;5A2. When the reference data includes or is the first permitted range and the actual value, the sum of the first permitted range and the actual value is within the safe range;
    5A3.当参考数据中包括或为第一许可范围与标定值时,第一许可范围与标定值的和值在安全范围之内;5A3. When the reference data includes or is the first permitted range and the calibration value, the sum of the first permitted range and the calibration value is within the safe range;
    5A4.当根据实际值和根据联合运算值设定的下限值判断所述车辆的动力传递状况是否异常时,该根据联合运算值设定的下限值大于安全极限阈值中最小值,和/或该实际值大于安全极限阈值中最小值;5A4. When it is determined whether the power transmission condition of the vehicle is abnormal according to the actual value and the lower limit value set according to the joint operation value, the lower limit value set according to the joint operation value is greater than the minimum value of the safety limit threshold, and / Or the actual value is greater than the minimum value of the safety limit threshold;
    5A5.当根据实际值和根据联合运算值设定的上限值判断所述车辆的动力传递状况是否异常时,该根据联合运算值设定的上限值小于安全极限阈值中最大值,和/或该实际值小于安全极限阈值中最 大值。5A5. When it is determined whether the power transmission state of the vehicle is abnormal according to the actual value and the upper limit value set according to the joint operation value, the upper limit value set according to the joint operation value is smaller than the maximum value of the safety limit threshold value, and / Or the actual value is less than the safest limit threshold Great value.
  6. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,还包括步骤:The method for monitoring a vehicle when the vehicle is controlled by the power device according to any one of claims 1, 2, and 3, further comprising the steps of:
    6A1.如所述判断的结果为是,则启动设定的动力传递异常处理机制;6A1. If the result of the determination is yes, the set power transmission abnormality processing mechanism is activated;
    和/或,and / or,
    6A2.输出和/或保存所述判断的结果。6A2. Output and/or save the result of the determination.
  7. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法,其特征在于,获取的车辆的输入参数的值,根据获取的车辆的输入参数的值计算所述联合运算值,所述输入参数为计算所述联合运算值所需求的参数。A monitoring method for controlling operation of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein the value of the input parameter of the acquired vehicle is calculated based on the value of the input parameter of the acquired vehicle. The joint operation value is the parameter required to calculate the joint operation value.
  8. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,所述监控方法还包括下述方案:获取动力装置运行工况,将动力装置运行工况与所述计算关联。A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein the monitoring method further comprises the following scheme: acquiring a running condition of the power unit, and driving the power The device operating conditions are associated with the calculations.
  9. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,参与所述计算的参数中包括质量变化型物品质量。A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein the parameter participating in said calculating comprises a quality-variant item quality.
  10. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,参与所述计算的参数中包括效率系数、滚阻系数、路面坡度中任意一种或三种参数。A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, or 3, wherein the parameter participating in the calculation includes any one of an efficiency coefficient, a rolling resistance coefficient, and a road gradient. One or three parameters.
  11. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,输出和/或保存车辆质量的值。A method of monitoring when a vehicle is controlled by a power unit according to any one of claims 1, 2, 3, characterized in that the value of the vehicle mass is output and/or saved.
  12. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中任一方法中,其特征在于,当源动力参数为能量类型的源动力组合型参数时,能量累计的时间控制在一天之内或以1小时之内或30分钟之内或10分钟之内或一分钟之内或30秒之内或20秒之内或10秒之内或5秒之内或2秒之内或1秒之内或100毫米之内或10毫秒之内或1毫秒之内或0.1毫米之内。The method according to any one of claims 1, 2, 3, wherein the vehicle is controlled by the power device, wherein the source power parameter is a source type combination parameter of an energy type, The time of energy accumulation is controlled within one day or within 1 hour or within 30 minutes or within 10 minutes or within one minute or within 30 seconds or within 20 seconds or within 10 seconds or within 5 seconds Within 2 seconds or within 1 second or within 100 millimeters or within 10 milliseconds or within 1 millisecond or within 0.1 millimeters.
  13. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein the source power parameter in the calculation based on the vehicle motion balance calculation is a motor driving parameter. Any one or more of the electrical dynamic parameters of the back end.
  14. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,当所述为基于基于车辆运动平衡计算计算中的源动力参数为燃料动力参数时,所述燃料动力参数包括气缸压力、燃料消耗率、发动机空气流量、发动机负荷报告数据中任意一个或多个参数。A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein said source power parameter in said calculation based on vehicle motion balance calculation is fuel power In the parameter, the fuel power parameter includes any one or more of a cylinder pressure, a fuel consumption rate, an engine air flow, and an engine load report data.
  15. 如权利要求1、2、3任一所述的一种车辆由动力装置控制运行时的监控方法中,其特征在于,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。 A monitoring method for controlling a running time of a vehicle by a power unit according to any one of claims 1, 2, 3, wherein the vehicle is a high-speed rail vehicle, an electric train, an electric locomotive, a tram, a maglev train, In-pipe trains, buses, trucks, ordinary private vehicles, ordinary trains, tracked vehicles, electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles or tricycles with power systems, operating on land and having lower air lift Any one of the aircraft whose preset threshold or longitudinal speed is lower than the preset value.
  16. 一种车辆运行的监视方法,测算对象是车辆的车辆运行参数中任意一种或多种参数,其特征在于,所述监视方法包括步骤:A monitoring method for vehicle operation, the measuring object is any one or more parameters of vehicle operating parameters of the vehicle, wherein the monitoring method comprises the steps of:
    获取测算对象的联合运算值,该联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;Obtaining a joint operation value of the measurement object, wherein the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance between the dynamic direction and the related resistance of the vehicle in the running direction or a deformation thereof; the correlation resistance Including any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance;
    在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述测算对象的联合运算值。The joint operation value of the measurement object is output on a human machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
  17. 如权利要求16所述一种车辆运行的监视方法,其特征在于,还包括步骤:获取所述测算对象的实际值,在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的实际值。A method for monitoring vehicle operation according to claim 16, further comprising the steps of: obtaining an actual value of said measurement object, and outputting it on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product. The actual value of the object of the vehicle.
  18. 如权利要求16所述一种车辆运行的监视方法,其特征在于,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数.The method for monitoring vehicle operation according to claim 16, wherein the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor drive parameter and a back end electrical power parameter. .
  19. 如权利要求16、17、18任一所述一种车辆运行的监视方法,其特征在于,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。The method for monitoring vehicle operation according to any one of claims 16, 17, 18, wherein the vehicle is a high-speed rail vehicle, an electric train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, Trucks, ordinary private vehicles, regular trains, tracked vehicles, electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles or tricycles with powertrains, operating on land and with air lift below a preset threshold or low longitudinal speed Any of the vehicles in the preset value of the aircraft.
  20. 一种车辆数据的处理方法,测算对象为车辆运行参数中任意一个或多个参数,其特征在于,包括步骤:A method for processing vehicle data, wherein the measurement object is any one or more parameters of a vehicle operating parameter, and the method comprises the steps of:
    获取测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;Obtaining a joint operation value of the measurement object, wherein the joint operation value is calculated based on a vehicle motion balance calculation formula; the vehicle motion balance calculation formula is a formula describing a balance of the vehicle dynamic direction and the related resistance in the running direction or a variant thereof; The resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance;
    还包括下列任意一个或多个步骤:Also includes any one or more of the following steps:
    20A1.所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出和/或保存;20A1. The measurement object is an unmeasurable parameter and/or any one or more parameters of a preset parameter and/or a system inherent parameter, and the joint operation value is output and/or saved;
    20A2、当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,所述处理方法还需获取所述测算对象的实际值;将所述联合运算值和所述实际值输出和/或保存,和/或将所述联合运算值和所述实际值的差值输出和/或保存。20A2, when the measurement object is any one of vehicle operation parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the processing method further needs to acquire the actual object of the measurement object. a value; outputting and/or saving the joint operation value and the actual value, and/or outputting and/or saving a difference between the joint operation value and the actual value.
  21. 如权利要求20所述一种车辆数据的处理方法,其特征在于,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。The method for processing vehicle data according to claim 20, wherein the source power parameter in the calculation based on the vehicle motion balance calculation is any one or more of a motor driving parameter and an electric power parameter of the back end. .
  22. 如权利要求20、21任一所述一种车辆数据的处理方法,其特征在于,所述车辆为高铁车辆、动车、电力机车、有轨电车、磁悬浮列车、管道内列车、公交车、货车、普通私家车辆、普通列车、履带式车辆、电动车辆、燃料电池动力车辆、摩托车、有动力系统的两轮车或三轮车、在陆地运行且其空气升力低于预设阈值或纵向速度低于预设值的飞行器中任意一种车辆。 The method for processing vehicle data according to any one of claims 20 to 21, wherein the vehicle is a high-speed rail vehicle, an electric train, an electric locomotive, a tram, a maglev train, an in-pipe train, a bus, a truck, Ordinary private vehicles, regular trains, tracked vehicles, electric vehicles, fuel cell powered vehicles, motorcycles, two-wheeled vehicles or tricycles with powertrains, operating on land and with air lift below a preset threshold or longitudinal speed below pre- Any vehicle of the value of the aircraft.
  23. 一种车辆超载的监控方法,其特征在于,所述监控方法包括步骤:A monitoring method for vehicle overload, characterized in that the monitoring method comprises the steps of:
    获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载。Obtaining a joint operation value of the vehicle mass of the vehicle, the joint operation value being calculated based on a vehicle motion balance calculation formula; determining the vehicle according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle Whether it is overloaded.
  24. 如权利要求23任一所述的一种车辆超载的监控方法,其特征在于,所述为基于基于车辆运动平衡计算计算中的源动力参数为电机驱动参数、后端的电气动力参数中任意一个或多个参数。The method for monitoring overload of a vehicle according to any one of claims 23 to 23, wherein the source power parameter in the calculation based on the vehicle motion balance calculation is any one of a motor drive parameter and a back end electrical power parameter or Multiple parameters.
  25. 一种车辆的车辆运行参数的测算方法,测算对象是所述车辆的车辆运行参数中任意一种或多种参数,其特征在于,所述测算方法包括步骤:A method for calculating a vehicle operating parameter of a vehicle, the measuring object being any one or more parameters of a vehicle operating parameter of the vehicle, wherein the calculating method comprises the steps of:
    S1、以车辆运行参数中的任意一种为测算对象,预设计算该测算对象的车辆运动平衡计算公式;该车辆运动平衡计算公式为描述车辆在运行方向动力与相关阻力平衡的公式或其变形的公式;该相关阻力包括滚动阻力、坡度阻力、变速阻力、风阻中任意一种或任意多种;S1: Calculating a vehicle motion balance calculation formula of the measurement object by using any one of the vehicle operating parameters as a calculation object; the vehicle motion balance calculation formula is a formula describing the balance between the dynamic direction and the related resistance of the vehicle in the running direction or a variant thereof Formula; the relevant resistance includes any one or any of rolling resistance, slope resistance, shift resistance, and wind resistance;
    S2、获取输入参数的值,该输入参数为该车辆运动平衡计算公式中除该测算对象外的所有参数,也即输入参数为根据该车辆运动平衡计算公式计算该测算对象的值所需求的参数;根据该所获取的输入参数的值和该车辆运动平衡计算公式计算该测算对象的值;S2. Obtain a value of an input parameter, where the input parameter is all parameters except the measurement object in the vehicle motion balance calculation formula, that is, the input parameter is a parameter required to calculate the value of the measurement object according to the vehicle motion balance calculation formula. Calculating a value of the measured object according to the obtained value of the input parameter and the vehicle motion balance calculation formula;
    本测算方法还包括方案A、B、C中任一方案:The calculation method also includes any one of the schemes A, B, and C:
    A、测算对象为动力或传动系统中的与安全紧密相关的参数或包含该参数的参数;A. The measurement object is a parameter closely related to safety in the power or transmission system or a parameter including the parameter;
    B、输入参数中所包括的车辆总质量的值为基于车辆总质量的预设的实际值所设定;B. The value of the total mass of the vehicle included in the input parameter is set based on a preset actual value based on the total mass of the vehicle;
    C、输入参数中所包括的动力或传动系统中的与安全紧密相关的参数中至少一种为基于预设值所设定。C. At least one of the power included in the input parameter or the safety-related parameter in the transmission system is set based on a preset value.
  26. 一种车辆由动力装置控制运行时的监控系统,测算对象是车辆的车辆运行参数中任意一种参数,其特征在于,所述监控系统包括判断参数获取模块(1)、动力传递状况判断模块(2);所述监控系统还包括动力传递异常处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;A monitoring system for controlling a running time of a vehicle by a power device, wherein the measuring object is any one of vehicle operating parameters of the vehicle, wherein the monitoring system comprises a determining parameter obtaining module (1) and a power transmission status determining module ( 2); the monitoring system further includes any one or more of a power transmission abnormality processing module (3), an output module (4), and a saving module (5);
    所述判断参数获取模块(1)用于:获取所述车辆的测算对象的联合运算值和所述测算对象的参考数据;所述联合运算值为基于车辆运动平衡计算公式计算所得;The determining parameter obtaining module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle and reference data of the measurement object; and the joint operation value is calculated based on a vehicle motion balance calculation formula;
    所述动力传递状况判断模块(2)用于:根据车辆的测算对象的联合运算值和所述测算对象的参考数据判断车辆的动力传递状况是否异常;The power transmission status determination module (2) is configured to: determine whether the power transmission status of the vehicle is abnormal according to a joint operation value of the measurement object of the vehicle and reference data of the measurement object;
    所述动力传递异常处理模块(3)用于:如所述判断的结果为是,则启动设定的动力传递异常处理机制;The power transmission abnormality processing module (3) is configured to: if the result of the determining is yes, initiate a set power transmission abnormality processing mechanism;
    所述输出模块(4)用于:输出所述动力传递状况判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the power transmission status determination module (2);
    所述保存模块(5)用于:保存所述动力传递状况判断模块(2)的判断结果。The saving module (5) is configured to: save the determination result of the power transmission status determination module (2).
  27. 一种车辆运行参数的监视系统,测算对象是车辆的车辆运行参数中任意一种或多种参数,其特征在于,所述监视系统包括联合运算值获取模块(1)、指示模块(2): A monitoring system for vehicle operating parameters, the measuring object is any one or more of the vehicle operating parameters of the vehicle, wherein the monitoring system comprises a joint operation value obtaining module (1) and an indicating module (2):
    所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值;联合运算值为基于车辆运动平衡计算公式计算所得;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle; the joint operation value is calculated based on a vehicle motion balance calculation formula;
    所述指示模块(2)用于在车内电子设备和/或便携式个人消费电子产品的人机界面上输出所述车辆的测算对象的联合运算值。The indication module (2) is configured to output a joint operation value of the measurement object of the vehicle on a human-machine interface of the in-vehicle electronic device and/or the portable personal consumer electronic product.
  28. 一种车辆数据的处理系统,测算对象为车辆运行参数中任意一个或多个参数,其特征在于,所述处理系统包括联合运算值获取模块(1)、所述处理系统还包括输出模块(2)和/或保存模块(3):A processing system for vehicle data, the measurement object being any one or more parameters of a vehicle operation parameter, wherein the processing system comprises a joint operation value acquisition module (1), and the processing system further comprises an output module (2) ) and / or save module (3):
    所述测算对象联合运算值获取模块(1)用于:获取所述车辆的测算对象的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,还需获取所述测算对象的实际值;The calculation object joint operation value acquisition module (1) is configured to: acquire a joint operation value of the measurement object of the vehicle, and the joint operation value is calculated based on a vehicle motion balance calculation formula; when the measurement object is When measuring the parameter and/or any one of the vehicle operating parameters other than the preset parameter and/or the system inherent parameter, the actual value of the measuring object is also acquired;
    所述输出模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值输出;和/或The output module (2) is configured to: output the joint operation value; and/or the measurement object is an unmeasured parameter and/or any one or more of a preset parameter and/or a system inherent parameter; and/or
    当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,将所述联合运算值和所述实际值输出,和/或将所述联合运算值和所述实际值的差值输出;When the measured object is any one of vehicle operating parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, the joint operation value and the actual value are output, and / Or outputting a difference between the joint operation value and the actual value;
    所述保存模块(2)用于:所述测算对象为不可测参数和/或可预设参数和/或系统固有参数中任意一个或多个参数,将所述联合运算值保存;和/或The saving module (2) is configured to: save the joint operation value as: the unmeasured parameter and/or any one or more parameters of the preset parameter and/or the system intrinsic parameter; and/or
    当所述测算对象为除不可测参数和/或可预设参数和/或系统固有参数之外的车辆运行参数中任一参数时,将所述联合运算值和所述实际值保存,和/或将所述联合运算值和所述实际值的差值保存。And when the measured object is any one of vehicle operating parameters other than the unmeasurable parameter and/or the preset parameter and/or the system inherent parameter, saving the joint operation value and the actual value, and/ Or saving the difference between the joint operation value and the actual value.
  29. 一种车辆超载的监控系统,其特征在于,所述监控系统包括联合运算值获取模块(1)、超载判断模块(2);所述监控系统还包括超载处理模块(3)、输出模块(4)、保存模块(5)中的任意一种或多种模块;A monitoring system for overloading a vehicle, characterized in that the monitoring system comprises a joint operation value acquisition module (1) and an overload determination module (2); the monitoring system further comprises an overload processing module (3) and an output module (4) ), saving any one or more of the modules (5);
    所述联合运算值获取模块(1)用于:获取所述车辆的车辆质量的联合运算值,所述联合运算值为基于车辆运动平衡计算公式计算所得;The joint operation value obtaining module (1) is configured to: acquire a joint operation value of a vehicle mass of the vehicle, where the joint operation value is calculated based on a vehicle motion balance calculation formula;
    所述超载判断模块(2)用于:根据所述获取的联合运算值和所述车辆的车辆最大载重安全许可值判断所述车辆是否超载;The overload judgment module (2) is configured to: determine whether the vehicle is overloaded according to the acquired joint operation value and a vehicle maximum load safety permission value of the vehicle;
    所述超载处理模块(3)具有下述功能:如所述判断结果包括是,则启动设定的超载处理机制;The overload processing module (3) has the following functions: if the determination result includes yes, the set overload processing mechanism is activated;
    所述输出模块(4)用于:输出所述超载判断模块(2)的判断结果;The output module (4) is configured to: output a determination result of the overload determination module (2);
    所述保存模块(5)用于:保存所述超载判断模块(2)的判断结果。 The saving module (5) is configured to: save the determination result of the overload determination module (2).
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CN117542377B (en) * 2024-01-05 2024-04-05 江西众加利高科技股份有限公司 Information prompting method and related device based on truck weighing

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