CN213298277U - Intelligent control system of air compressor - Google Patents
Intelligent control system of air compressor Download PDFInfo
- Publication number
- CN213298277U CN213298277U CN202021614724.2U CN202021614724U CN213298277U CN 213298277 U CN213298277 U CN 213298277U CN 202021614724 U CN202021614724 U CN 202021614724U CN 213298277 U CN213298277 U CN 213298277U
- Authority
- CN
- China
- Prior art keywords
- air compressor
- control unit
- frequency
- control
- upper computer
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Landscapes
- Control Of Positive-Displacement Pumps (AREA)
- Control Of Positive-Displacement Air Blowers (AREA)
Abstract
The utility model discloses an air compressor machine intelligence control system relates to air compressor machine control technical field. The system comprises a variable frequency control unit, a data acquisition unit and an upper computer control unit; the data acquisition unit converts the pressure signals acquired on site into digital signals and transmits the digital signals to the upper computer control unit, and the digital signals are compared with a user set value, so that the frequency converter control unit automatically adjusts the output frequency to the motor of the air compressor. The utility model discloses an amount of wind in the air compressor machine air feed system and the change of pressure control converter output frequency or increase and reduce the unit, optimize unit control, operation configuration, make unit operation and speed governing as required, reach energy-conserving purpose.
Description
Technical Field
The utility model relates to an air compressor machine control technical field specifically is an air compressor machine intelligence control system and method.
Background
In the coal mine construction and production, the pneumatic equipment is powered by an air compressor, and a screw air compressor is adopted at present. The air compressor has long continuous working time and large energy consumption ratio. At present, the air compressor is controlled to be started and stopped manually, the regulating valve controls the on-load operation and the no-load operation, the control mode determines that the air compressor works or does not work, energy loss is caused, meanwhile, manual intervention is needed for inspection and starting and stopping, and the labor intensity of workers is increased.
The power source of pneumatic tools or equipment in the process of coal mine well construction and production is mostly 40 cubic/minute air compressors, the power of a dragging motor is 250KW, the voltage is 10000V or 6000V, the control mode is high-voltage direct starting, the starting mode has large impact on the motor and a main machine, and the failure rate of the motor and a main machine bearing is high; secondly, a single unit adopts the variable frequency starting and the speed regulation of a high-voltage frequency converter, and the starting control mode has large investment in the early stage, poor cost performance and uneconomical operation.
With the development of modern electronic technology, the frequency conversion control technology has been developed to a rather mature stage. The frequency converters of various domestic brands can achieve stable performance and reliable operation. The pressure and air quantity monitoring and variable-frequency speed regulating system are combined, a variable-frequency energy-saving control system of the air compressor is researched and developed, the operation mode of the unit is optimized, and the method has important significance for prolonging the service life of equipment, improving the production efficiency of the equipment and saving electric energy; the system collects the operation data of the air compressor unit, alarms when the abnormal data exceeds a threshold value, visually checks the operation data, ensures that the air compressor operates in a stable state, and creates more economic benefits for enterprises.
Disclosure of Invention
In order to overcome the shortcoming of above-mentioned prior art, the utility model provides an air compressor machine intelligence control system and method controls converter output frequency or increase reduction unit through the amount of wind in the air compressor machine air feed system and the change of pressure, optimizes unit control, operation configuration, makes unit operation and speed governing as required, reaches energy-conserving purpose.
The utility model discloses a realize with following technical scheme: an intelligent control system of an air compressor comprises a variable frequency control unit, a data acquisition unit and an upper computer control unit; the data acquisition unit converts the pressure signals acquired on site into digital signals and transmits the digital signals to the upper computer control unit, and the digital signals are compared with a user set value, so that the frequency converter control unit automatically adjusts the output frequency to the motor of the air compressor.
Preferably, the data acquisition unit comprises a pressure transmitter and a flow transmitter which are installed on a pipeline of the air compressor system.
Preferably, the upper computer control unit is connected with a display screen.
Preferably, the display screen is a touch screen.
Preferably, the upper computer control unit realizes remote control and comprises a platform and a mobile phone APP, the management client side adopts a PC to log in the platform through a browser to manage and work, and a mobile phone user uses the platform function through the APP.
Preferably, the upper computer control unit adopts a PLC.
The utility model discloses beneficial effect: 1. automatic control, accurate calibration, high efficiency and energy saving;
2. the system is provided with a frequency converter for starting and adjusting the air supply quantity, and has the advantages of high automation degree, complete functions, energy conservation and economic investment;
3. the operation is reasonable, and the average torque and the abrasion on the shaft are reduced due to the reduction of the average rotating speed in one day, so that the service life of the air compressor is prolonged;
4. soft start is realized, the start and stop of the load are stable, the mechanical impact is reduced, and the mechanical service life of the equipment is prolonged;
5. the starting is stable, and the starting current can be limited within the rated current, so that the impact on a power grid during starting is avoided;
6. collecting and storing the running data of the air compressor set system, and alarming when the parameters are abnormal and exceed a warning threshold value;
7. friendly man-machine interface, interactive, viewable and adjustable parameters;
8. the industrial standard construction is movable and detachable.
Drawings
FIG. 1 is a pressure control variable frequency block diagram;
FIG. 2 is a system diagram of a high voltage inverter of a structural topology;
FIG. 3 is a system diagram of a high voltage inverter;
FIG. 4 is a flow chart of control system operation;
FIG. 5 is a system fabric topology diagram;
fig. 6 is a system configuration diagram of the present invention.
Detailed Description
As shown in fig. 1, an air compressor control system includes a frequency conversion control unit, a data acquisition unit, and an upper computer control unit. The data acquisition unit converts the pressure signals acquired on site into digital signals (4-20 mA) and transmits the digital signals to the upper computer control unit, a microcomputer intelligent system in the frequency converter control unit automatically adjusts output frequency to the motor by comparing with user set values, the system automatically adjusts the output power of the motor, the optimal energy-saving effect is achieved, and the system can communicate with an industrial touch screen to realize system detection and man-machine interaction.
The utility model discloses realize closed-loop control
According to the process control requirement, the frequency converter compares the data values collected by the PLC from the pressure transmitter and the flow transmitter arranged on the air compressor system pipeline with the set value, performs PID operation according to the deviation, controls the motor by the frequency converter, and changes the rotating speed of the motor, thereby realizing the change of increasing and reducing the air supply quantity. Because the air outlet quantity is increased and reduced, the change adversely affects the change of the air outlet pressure, the change of the air outlet pressure and the air outlet flow is fed back to the frequency converter through the measurement of the pressure and flow transmitter, the frequency of the frequency converter is changed again through operation, so that the rotation speed of the motor is adjusted, the rotation speed is changed, the flow is adjusted, the purpose of automatically controlling and stabilizing the air outlet pressure and the air outlet flow is achieved, and the closed-loop control is realized, which is shown in a structural topological diagram of fig. 2 and a system flow diagram of fig. 4.
The control system is in an initial state of QS1, QS2 and QS3 and is prepared for electrifying 3 motors, a KM1 is closed under the instruction of a master control PLC, a high-voltage frequency converter is started under the instruction of the master control PLC, an A motor drives a screw compressor to start, the frequency converter automatically adjusts the frequency to operate according to the set outlet pressure of the screw compressor, when the output of the frequency converter reaches the power frequency, the outlet pressure and the air volume still cannot reach the set value, the master control PLC sends an instruction to close QF1 and disconnect KM1, so that the A screw compressor operates at the power frequency, a KM2 is closed, the frequency converter drives a B motor to start, the B screw compressor operates in a frequency modulation. When the outlet pressure and the air volume reach set values, the frequency converter maintains the current running state, when the air volume is reduced, the frequency converter operates in a frequency reduction mode, when the lowest allowable rotating speed of the screw machine is reduced (the frequency is about 25Hz), the main control PLC sends an instruction to the screw machine which is running at the power frequency to stop the screw machine, and meanwhile, the screw machine which is running at the frequency conversion mode automatically operates in a frequency conversion mode according to the set values and the air volume. If only 1 screw machine runs in a frequency conversion mode, the frequency is reduced to the lowest running frequency of the screw machine, the outlet pressure of the screw machine reaches a set value (such as 0.75MPa) and is not reduced, the screw machine is unloaded and runs for a certain time (such as 3 minutes) without being reduced, the master control PLC gives an instruction to the frequency converter to stop working, and meanwhile, the corresponding circuit breaker is switched off to be standby. When the system pressure is reduced to a set value (such as 0.65MPa), the master control PLC starts the operation according to the operation time of each unit, preferably the variable frequency of the screw machine with the minimum working time, and the operation is circulated. See FIG. 3 a system diagram and FIG. 4 a system flow diagram
The system can set an automatic and manual control operation mode through a touch screen. The air compressor can realize the operation modes of variable frequency starting, variable frequency operation, power frequency switching, stopping and the like by controlling the frequency converter and the executing element through the PLC, and also can realize the power frequency emergency starting operation mode.
Because the frequency converter integrates strong current control and weak current control, harmonic current of an output main loop generates interference on a control loop, and input PID signals are influenced, so that the frequency converter cannot work normally. Therefore, when the device is designed and installed, the control signal wire is laid by adopting a shielding cable strictly according to the technical specification requirement, the control signal wire is spaced from the main loop at a certain interval during wiring, and the shielding layer is reliably grounded.
The system mainly comprises various sensors on site, such as a pressure transmitter, a flow transmitter and the like. Test signals are transmitted back to the PLC through the signal special communication cable, and the signals are transmitted to the touch screen to be processed, so that the interface with various functions, convenience and simplicity and the interaction display of operators are realized. The working state of the frequency converter can be set and modified by field operators through the touch screen, so that the aim of remote control is fulfilled.
As shown in fig. 6, with the popularization of the internet, the mobile internet technology and the smart phone, by building a cloud working condition remote monitoring platform, data checking, alarm reminding and remote control of a remote PC and a mobile phone are realized, the purpose of efficiently and quickly monitoring and recording a mining area system becomes possible, and the modernized management level is improved.
The platform adopts a B/S, A/S mixed architecture mode, and the system mainly comprises a platform program and a mobile phone APP. And the management client adopts a PC to log in the platform through a browser to manage the office. The mobile phone user can use the platform function through the APP.
3.2.1.1 platform program: the platform program is deployed in the cloud. The system can adopt Linux or Windows Server. The platform data service is mainly used for providing support for APP and front-end services and coordinating registration and communication between the air compressor control system and the user. The mobile phone APP mainly achieves personnel information registration, monitoring data checking, alarm recording and remote control.
The function of the system
Core module | Main content |
User registration | Split-rights real-name registration |
Information query | The user can use the APP query function according to the authority |
Remote control | The user can use APP to control the system according to the authority |
Alarm module | Alarm reminding, alarm record inquiry |
TABLE 1 Mobile phone APP Main Functions
TABLE 2 platform Primary function
TABLE 3 basic framework function
Numbering | Name (R) | Description of functions |
JK-010 | PLC interface | |
JK-020 | Frequency converter interface |
TABLE 4 data interface function
The working principle is as follows: the air compressor machine can be according to the operation quantity and the rotational speed of pressure variation automatically regulated motor in the system. The air compressor control system calculates the required air production quantity according to the actual use condition, thereby calculating the required number of units and the rotating speed of the air compressor, and automatically controlling electric appliances (an incoming line breaker, a frequency converter, an outgoing line contactor and an air compressor lamp) in the whole system through a PLC (programmable logic controller) so as to achieve the required outlet pressure. When the required requirements are met, the frequency converter keeps running in the current state; when the outlet pressure is larger than a set value, the pressure sensor transmits information to the control system, the control system transmits an instruction to the frequency converter according to the running state of the frequency converter (standby or variable-frequency dragging motor), the frequency converter controls the motor to slow down, if the motor cannot meet the requirement of reducing the outlet pressure, the master control PLC sends a shutdown instruction, the air compressor with the longest running working time is selected to be shut down, and the number of running air compressors is reduced; when the outlet pressure is less than the set value, the speed is increased or the running unit is increased. If all the units do not reach the set outlet pressure all the time when operating at the full power frequency, the master control sends out an alarm signal, and managers can check the site and deal with the problems in time.
Through the utility model discloses economic benefits that frequency conversion produced
(1) Direct benefit generated by frequency conversion transformation
Because the pressure fan is a square torque load, according to the data of practical statistics, the energy can be saved by 20-50% after the frequency conversion energy-saving transformation.
(2) Indirect benefit generated by frequency conversion transformation
By combining the application of the computer technology, after the air compressor is subjected to frequency conversion transformation, the whole control process is greatly improved, and the production cost is reduced to a certain extent.
(3) Prolong the service life of the equipment and reduce the working strength of personnel
The air compressor works under the frequency conversion working condition, when the outlet flow of the air compressor is smaller than the rated flow, the rotating speed of the motor is reduced, the abrasion and the heating of the bearing are reduced, the service life of the unit is prolonged, and meanwhile, the maintenance workload and the overhaul cost are reduced.
After the valve is transformed, the opening degree of the valve can be adjusted to 100%, the valve is not stressed in operation, and the problem that the control characteristic of the valve is poor due to the fact that the valve works at a fixed opening degree for a long time and the valve is abraded in the prior art is avoided.
The pressure of the pipe network is monitored in real time and automatically adjusted, so that the conditions that the sealing performance of system equipment is threatened by overhigh pressure, a valve is leaked, the valve cannot be tightly closed and the like are avoided.
The motor adopts a frequency conversion starting mode, so that the influence of current impact on the voltage of a power grid on the fluctuation when the motor is started is avoided. The frequency conversion changes the rotating speed of the motor, and the phenomenon that the service life of equipment is shortened due to full-load operation of the motor after the motor is started in the past is avoided.
The constant-pressure and constant-current automatic control is realized, frequent operation of operators is not needed, and the labor intensity of the operators is reduced.
The system is suitable for the condition that the voltage of a power grid is strong in fluctuation and wide in working voltage, and the system can normally operate when the voltage of the power grid fluctuates between + 10% and-10%.
(4) Increasing production, increasing efficiency and saving energy
Partial load state frequency conversion energy saving: according to pressure acquisition, pressure is less than the setting value, and the converter changes the motor power frequency, and reaches the regulation motor rotational speed and changes the air-out flow, has the efficiency of saving the power consumption, reduces pipeline resistance, the loss that significantly reduces dams.
Because the air compressor machine work is in frequency conversion operating condition, and the cube of motor power consumption and rotational speed is directly proportional, and motor rotational speed reduces slightly, and the power consumption can descend by a wide margin, so the energy-conserving effect of system in the operation process is obvious (on average more than 25%). And (3) monitoring data in real time, and dynamically tracking the process at any time to adjust the air volume, so that the system meets the requirements of the optimal process.
In conclusion, the air compressor is subjected to variable frequency transformation, the service life of equipment can be prolonged, the production efficiency is improved, the early-stage investment and the operation electric energy and cost are saved, and the generated social benefit is very objective.
Claims (5)
1. The utility model provides an air compressor machine intelligence control system which characterized in that: the device comprises a variable frequency control unit, a data acquisition unit and an upper computer control unit; the data acquisition unit converts the pressure and flow signals acquired on site into digital signals and transmits the digital signals to the upper computer control unit, and the digital signals are compared with a user set value, so that the frequency is automatically adjusted and output to a motor of the air compressor through the frequency converter control unit; the data acquisition unit comprises a pressure transmitter and a flow transmitter which are arranged on a pipeline of the air compressor system.
2. The intelligent air compressor control system of claim 1, wherein: the upper computer control unit is connected with a display screen.
3. The intelligent air compressor control system of claim 2, wherein: the display screen adopts a touch screen.
4. The intelligent air compressor control system of claim 1, wherein: the upper computer control unit realizes remote control and comprises a platform and a mobile phone APP, the management client side adopts a PC to manage and work through a browser login platform, and a mobile phone user uses a platform function through the APP.
5. The intelligent control system of the air compressor according to any one of claims 1 to 4, wherein: the upper computer control unit adopts a PLC.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202021614724.2U CN213298277U (en) | 2020-08-06 | 2020-08-06 | Intelligent control system of air compressor |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202021614724.2U CN213298277U (en) | 2020-08-06 | 2020-08-06 | Intelligent control system of air compressor |
Publications (1)
Publication Number | Publication Date |
---|---|
CN213298277U true CN213298277U (en) | 2021-05-28 |
Family
ID=76023146
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202021614724.2U Active CN213298277U (en) | 2020-08-06 | 2020-08-06 | Intelligent control system of air compressor |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN213298277U (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112128107A (en) * | 2020-08-06 | 2020-12-25 | 中煤第五建设有限公司 | Intelligent control system and method for air compressor |
CN113153719A (en) * | 2021-06-02 | 2021-07-23 | 中车青岛四方车辆研究所有限公司 | Air supply control method and system for railway vehicle and railway vehicle |
CN113431767A (en) * | 2021-07-30 | 2021-09-24 | 深圳市中金岭南有色金属股份有限公司凡口铅锌矿 | Operation control method and device for hollow press in mine, terminal equipment and medium |
-
2020
- 2020-08-06 CN CN202021614724.2U patent/CN213298277U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112128107A (en) * | 2020-08-06 | 2020-12-25 | 中煤第五建设有限公司 | Intelligent control system and method for air compressor |
CN113153719A (en) * | 2021-06-02 | 2021-07-23 | 中车青岛四方车辆研究所有限公司 | Air supply control method and system for railway vehicle and railway vehicle |
CN113431767A (en) * | 2021-07-30 | 2021-09-24 | 深圳市中金岭南有色金属股份有限公司凡口铅锌矿 | Operation control method and device for hollow press in mine, terminal equipment and medium |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN112128107A (en) | Intelligent control system and method for air compressor | |
CN213298277U (en) | Intelligent control system of air compressor | |
CN110067764B (en) | Remote switching and intelligent regulation and control device for local ventilator of coal mine and control method | |
CN201496242U (en) | Automatic remote control and energy saving system of cluster pump station | |
CN206800507U (en) | Constant pressure water supply system | |
CN103306958A (en) | Running Method method of running of intelligent power-saving control system of air compression station | |
CN104153425A (en) | Constant-pressure water supply system | |
CN110865603B (en) | Electrical control system of aero-engine test bed | |
CN201347868Y (en) | Industry cycle water energy-saving control system | |
CN102022799B (en) | Energy-saving control method for central air conditioner system | |
CN104819141A (en) | Control method and system for air compression station | |
CN201292954Y (en) | Water pump and/or blower fan highly effective energy-conserving control system | |
CN201014677Y (en) | Central air-conditioning intelligent group control device | |
CN107289811B (en) | Energy-saving automatic control system and method for evaporative cooling/condensing equipment | |
CN111427268B (en) | Coal mine energy optimization control system and optimization control method | |
CN102045023A (en) | Novel multifunction energy-saving frequency conversion control device for oil pumping machine in oil field | |
CN203100068U (en) | Energy-conservation controlling device for central air conditioning system | |
CN102315821A (en) | Multifunctional energy-saving frequency-conversion control device | |
CN2716761Y (en) | Intellectualized controller for heat exchanging machine set | |
CN205478243U (en) | Energy -saving air compression station control system of unmanned on duty formula | |
CN109751243B (en) | Energy-conserving oil spout screw air compressor control system | |
CN214994342U (en) | Constant pressure frequency conversion water supply system based on ACS510 frequency converter | |
CN204677409U (en) | A kind of control system of air compressor plant | |
CN205297888U (en) | Oil pump energy -saving control system based on PLC | |
CN212060891U (en) | Coal mine energy optimization control system |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant |