DE102013200390A1 - Device for varying volume of hydraulic machine in vehicle drive train, has supplementary mechanism provided between control valve mechanism and piston cylinder mechanism, where pressure is applied to area of surface in operating states - Google Patents

Abstract

The device has press axles (39, 40) coupled with a piston cylinder mechanism and hydraulic machines (23, 28) in a pumping operation, where the axles comprise a pressure-dependant back swivel behavior in a direction of smaller promotion volumes. The piston-cylinder mechanism is adjustable in an area of an active surface with a control valve mechanism for pivoting the press axles. A supplementary mechanism is provided between the control valve mechanism and the piston cylinder mechanism, where pressure is applied to the area of the surface in first or second operating states.

Description

The invention relates to a device having at least two interconnected via lines and operable both as a pump and as a motor hydraulic machines according to the closer defined in the preamble of claim 1. Art.

Vehicle drive trains known mobile work machines, such as construction vehicles or tractors, usually comprise a mostly designed as a diesel engine prime mover, a hydrodynamic or hydrostatic transmission and one or more drivable vehicle axles and wheels, the translations in the transmission of such vehicle drive trains are continuously variable. For this purpose, hydrostatic units with at least two hydraulic machines, which are designed as axial piston machines or are designed in swash plate or oblique axis design, are provided in the area of continuously power-split transmissions. Usually, one hydraulic machine takes over the pumping function, while the other is operated as a motor. By varying the ratio of hydraulic fluid volume delivered in the area of the hydraulic machine operated as a pump to the intake volume taken in the area of the hydraulic motor operated as a motor, the desired stepless adjustment of the ratio and modulation of the tractive force available in the region of the output can be carried out a change in the rotational speed of the drive machine can be realized. In order to change the delivery volume and the displacement of the hydraulic machines each to the desired extent, the hydraulic machines or axes of the hydraulic machines are pivoted to vary the piston stroke.

For space and cost reasons, the hydraulic machines usually combined to form a hydrostatic unit are actuated via a so-called double yoke. Both hydraulic machines listed as axial piston machines or in oblique axis design are arranged in a common housing and the pivoting angle of the two hydraulic machines can only be changed together. The double yoke is actuated by a double-acting hydraulic cylinder. As is known, this hydraulic adjusting cylinder is acted upon by the high pressure present in the region of the hydrostatic unit in the region of pressure chambers or of active surfaces of such a piston-cylinder device. In order to be able to actuate the hydraulic machines via the piston-cylinder device or the hydraulic adjusting cylinder as required, the hydraulic pressure respectively applied in the region of the piston-cylinder device is adjusted to the required extent via a control valve device.

The hydraulic machines of such a hydrostatic unit are connected to each other for example via lines of a closed circuit. Are the hydraulic machines operable both as a pump and as a motor, change the pressure-carrying channels in the circuit at a change between a tensile and a push mode, their function, the respective high-pressure line leading the pressure side of the hydraulic pump operated as a hydraulic pump to the feed of the as a motor-operated hydraulic machine connects, after a change between a pulling and a pushing operation state, the suction side of the pump-operated hydraulic machine with the outlet side of the motor-operated hydraulic machine connects.

If a transmission is designed with several switchable gear stages, several gear ratios can be displayed in the area of the gearbox, within which the gear ratio can be infinitely varied by adjusting the hydrostatic gear. Within each range of translation, the entire pivoting range of a hydrostatic unit is traversed once, the delivery and displacement volume via a double-acting hydraulic cylinder and thus standing in operative connection double yoke in conjunction with a position control in the desired extent can be changed. Depending on the operating status, direction of travel and engaged transmission range, the two hydraulic machines each change their function between pump operation and engine operation. Thus, during a positive acceleration process of a vehicle and a concomitant increase in the driving speed, the hydrostatic unit is not only adjusted in a pivoting direction. Depending on the respective engaged in the transmission area in the transmission range is carried out an adjustment in one or the other direction.

When the first transmission range is engaged, the swivel angle with respect to the hydraulic unit of the hydrostatic unit, which is operated as a pump, is increased at a vehicle acceleration of substantially zero in the direction of a maximum swivel angle, until a so-called synchronization point is reached in the transmission, to which two range clutches to be shifted in the transmission are respectively have their synchronous speed and can be actuated with little effort. By switching the two range couplings, the second transmission range is engaged in the transmission and the first transmission range is designed from the force flow of a vehicle drive train. Subsequently, the previously operated as a pump hydraulic machine is operated as a motor, while the other hydraulic machine passes from the engine operation in the pump mode. In order to continue with a second transmission area, a vehicle on To be able to accelerate, the tilt angle of the hydrostatic unit is again reduced in the direction of zero degrees.

The procedure described in more detail above illustrates that pressure is not always applied to the same pressure chamber of the double-acting piston-cylinder device during an acceleration process of a vehicle since this depends on the respective operating state of the vehicle drive train, the currently engaged transmission range and also a control range of the control valve device , In addition, it should be noted that especially in normal operation, both pressure chambers of the piston-cylinder device are pressurized, wherein the amount of pressure significantly from the current driving condition, d. H. a static operation, an acceleration, a deceleration or a pulling or pushing operation and the hydraulic bias depends. Depending on the particular driving state, corresponding torques acting in the region of the hydrostatic unit and, in turn, dependent actuating forces in the region of the piston-cylinder device result.

For example, if the transmission is operated in traction operation of the vehicle driveline running therewithin the limit power curve or above it, the transmission ratio is changed by reducing the displacement of the hydraulic machine operated as a pump and increasing the displacement of the engine hydraulic motor. As a result, the limit load acting in train operation is limited. This is possible, for example, with a corresponding design of the transmission and with the first transmission range engaged, by reducing the pivoting angle in the region of the hydrostatic unit. In contrast, this is implemented with inserted second driving range by increasing the pivot angle of the hydrostatic unit accordingly.

If the vehicle drive train is in overrun mode, two borderline cases are also to be considered, during which unacceptably high loads occur in the area of a vehicle drive train. Thus, for example, in overrun, during which a rotational speed of the drive engine increases, there is the possibility that the rotational speed of the drive engine assumes unacceptably high rotational speed values. If the transmission in the region of the transmission is adjusted in such a way that the delivery volume of the hydraulic machine operated as a pump is reduced and at the same time the absorption volume of the hydraulic machine operated as a motor is increased in order to avoid impermissible rotational speeds. With an appropriate design of the hydrostatic unit and the transmission, the swivel angle in the region of the hydrostatic unit is increased for this when the first transmission range is engaged, while the swivel angle is reduced when the second transmission range is engaged.

In order to operate a vehicle drive train in particular during the above-described borderline cases in towing and pushing operation to a suitable extent, it must be permanently detected which driving range is engaged in the transmission and whether the vehicle drive train is currently in push or pull operation. In the event of an erroneous determination of the current operating state, there is the possibility that an intervention due to a determined limit load triggers an unwanted deceleration or acceleration of a vehicle.

One possible procedure for detecting a currently present pulling or pushing operation is the use of at least two high-pressure sensors in order to determine the high-pressure line in the region of a hydrostatic unit.

Taking into account the coupling combination currently engaged in the area of the transmission, the current operating state of a vehicle drive train can then be determined.

Disadvantageously, the high-pressure sensors required for this purpose are characterized by high production costs and low robustness, which is why it is generally the aim to minimize the use of high-pressure sensors to a minimum.

Another possibility is the evaluation of provided by an engine controller torques of the prime mover. About such an evaluation of the train or overrun operation of the prime mover can be determined. From the operating state of the prime mover, however, is not necessarily closed to the current operating state of the entire vehicle drive train, since the current operating state of a working hydraulics of a working machine in this way can not be determined. Therefore, the operating state of the working hydraulics of a vehicle, which is also supplied by the vehicle drive train with drive torque and therefore crucially influenced between the prime mover and an output of a vehicle drive train torque, would be determined and evaluated separately, but this increases a control and regulatory effort to an undesirable extent ,

The present invention is therefore an object of the invention to provide a device with at least two interconnected lines and operated both as a pump and as a motor hydraulic machines available in a cost effective manner and with high robustness at the same time low tax and Regular effort to the desired extent, in particular in the limit load range is operable.

According to the invention this object is achieved with a device having the features of claim 1.

In the device according to the invention with at least two interconnected via lines and operable as a pump and as a motor hydraulic machines whose stroke volumes are each dependent on pivot positions of adjustable axes of the hydraulic machine, the axes are coupled to a piston-cylinder device and the hydraulic machines each have a pressure-dependent return pivoting behavior in the direction of smaller delivery volumes during pump operation. The piston-cylinder device is acted upon in the region of active surfaces with adjustable in the range of a control valve device pressures for pivoting the axes, wherein the control valve device can be coupled in each case with the line connecting the hydraulic machines, in which the higher pressure exists.

 According to the invention, a device is provided between the control valve unit and the piston-cylinder device, which device can be acted upon by pressures applied in the region of the active surfaces of the piston-cylinder device and can be transferred from these into a first or a second operating state.

 About the inventive design of the device with the device in each case the active surface or the respective associated pressure chamber of the piston-cylinder device can be determined in the area currently applied to the higher pressure to between a pulling and pushing operation of a running with the device vehicle drive train differentiate simple way and to be able to determine this each. The solution according to the invention is based on the knowledge that, in the area of hydraulic machines in pump operation, respective torques are present which have an effect on the swivel angle of a hydraulic machine. Known manner act in the range of a hydrostatic piston pump differential pressure-dependent restoring moments, which always adjust a operated as a pump hydraulic machine in the direction of smaller pivot angle and thus in the direction of lower delivery volumes. These differential pressure-dependent restoring moments in turn result in the area of the piston-cylinder device actuating moments whose direction is dependent on whether a hydraulic machine is operated as a pump or motor.

 Depending on the operating state and currently engaged in a transmission device transmission range, these control moments vary and each lead to a pressure increase in the range of one of the active surfaces or piston chambers of the piston-cylinder device. This respective higher in the range of a pressure chamber or an effective surface of the piston-cylinder device applied pressure is in turn support in the region of one of the two pressure chambers of the piston-cylinder device and for determining the current operating condition of a vehicle drive train in a simple manner.

 If the device can be converted into the first operating state or the second operating state by a total force component that is dependent on the pressure difference between the pressures in the region of the active surfaces of the piston-cylinder devices, the determination of the current operating state, d. H. whether a train or push operation is present, feasible with little effort.

 In a further structurally simple embodiment of the device according to the invention, the device has an axially displaceable slide element, in the region of which the total force component acts and which can each be converted into a first position equivalent to the first operating state or into a second position equivalent to the second operating state of the device. Then, the current operating state of a vehicle drive train or a pulling or pushing operation of a vehicle drive train in a simple manner depending on the axial position of the axially displaceable slide element, for example via a Hall sensor or the like, can be determined.

 If the total force component is also dependent on a spring device acting on the slide element, which adjusts the slide element to the first position with pressures in the area of the active surfaces of the piston-cylinder device, the device is in each case converted into a defined basic operating state and becomes it Undefined operating conditions of the device, which lead to a faulty determination of the current operating state of a vehicle drive train, avoided in a simple manner.

At one with little effort operable embodiment of the device according to the invention, the axial position of the slide element via a displacement measuring unit, preferably via a slider element associated with the Hall sensor, determined.

 The device is formed in a further structurally simple and operable with little effort embodiment of the device according to the invention as a 3/2-way valve, the valve spool of the total force component respectively in a first equivalent to the first operating state position or in a second to the second operating state of the device equivalent position can be transferred, wherein in the first position of the valve slide an applied pressure in the direction of another device can be forwarded. Also in this embodiment of the device according to the invention, the current operating state of a vehicle drive train or a pulling or pushing operation of the vehicle drive train in response to an axial position of a slide element can be determined, since in the first position of the valve slide in the region of the device applied pressure in the direction of another device can be forwarded, which rests only in overrun or in the train operation of the vehicle drive train in the area of the device. In this case, the further device may be designed as a pressure switch, as a pressure sensor or the like.

 If a high-pressure sensor is provided in the region between a connecting line connecting the hydraulic machines with the control valve device and the control valve device, the magnitude of the high pressure prevailing in the hydraulic machines can be determined in a simple manner and the control valve device can be used to avoid unduly high loads and to maintain compliance an adjustable via the control valve device pressure in the region of the piston-cylinder device with a small extent operable.

 Are the axes of the hydraulic machines together via a double yoke, which is coupled to the piston-cylinder device, adjustable, a design effort and a control effort to operate the hydraulic machines is low, since only a piston-cylinder unit for actuating the two hydraulic machines is to be provided and the operation of the two hydraulic machines is not tuned to each other as in a separate operation.

 In an alternative embodiment of the device according to the invention, the axes of hydraulic machines with high degree of freedom are independently adjustable by means of the piston-cylinder device, then for each of the hydraulic machines a separate piston-cylinder unit is provided with each associated control valve unit of the control valve device.

 In a cost-effective embodiment of the device according to the invention, the control valve unit is designed as a 4/2 control valve whose valve slide is adjustable from a variable actuating force against a preferably variable further acting on the valve spool actuator between a first end position in the direction of a second end position.

 Is a piston of the preferably double-acting piston-cylinder device operatively connected to the valve spool of the control valve unit and varies the further acting on the valve spool actuator in response to a position of the piston, the valve spool of the control valve device moves with little effort in a stable position.

 In a structurally simple and inexpensive embodiment of the device according to the invention acting on the valve spool of the control valve device actuating force is variable depending on a detectable in the range of a device and in dependence on the stroke volumes of the hydraulic machinery varying gear ratio of the hydraulic machines running gear, as a mechanical feedback connection between the Piston-cylinder device and the control valve unit can be omitted. Furthermore, in comparison to the mechanical connection between the piston-cylinder device and the valve slide of the control valve device, an improved resolution of the drive unit can be represented, since the high pressure in the area of the hydraulic machines is very strong when using a mechanically coupled system with feedback in certain situations only slight variation of the operation of the control valve device changes.

 In the last-described embodiment of the device according to the invention without mechanical feedback between the piston of the piston-cylinder device and the valve slide of the control valve device, the entire force control range of a proportional solenoid for the high-resolution adjustment of the volume flow in the region of the control valve device can be used. This results in particular advantages when the control valve device is used to adjust the load sensitivity of a running with the hydraulic machinery transmission. In addition, the system behavior is more accurately predictable, since the flow is adjustable directly in the range of the control valve device and without the influence of the pivoting of the hydraulic machines.

If the stroke volumes of the hydraulic machines above a preferably variable pressure limit value in the region of the lines connecting the hydraulic machines can be adjusted to values by which the pressure in the lines is at least approximately equal to the pressure limit value by a corresponding adjustment of the actuating force acting on the valve slide of the control valve device has the appropriate level, an operating mode of Hochdruckbegritierung or a high pressure control with a safe distance to a possibly damage in the field of hydraulic machines and the hydraulic machines actuated components causing operating pressure to desired extent feasible, which unacceptably high pressure values in the hydraulic system with high probability are avoidable.

 Furthermore, in addition to the transmission protection, it is also possible to lower the maximum pressure acting in the area of the hydraulic machines, with the result that, for example, handling of a wheel loader during operation in the pile or the like, preferably by avoiding spinning wheels, can be improved. A load sensitivity of a CVT transmission (continuously-variable transmission) in conjunction with a targeted target pressure specification, for example by a driver's request, the specification of a driving strategy computer or as a function of a necessary brake pressure for a transmission protection, in the desired or required extent achievable. In general, due to the easily available and operating state-dependent adjustable high-pressure limitation, a sensitive handling, for example in a heap, can be achieved.

 If the pressure limit value is less than or equal to a desired pressure value to be set in the region of the lines connecting the hydraulic machines, which is required for transmitting a defined torque between the hydraulic machines, on the one hand the mode of operation of a transmission designed with the device according to the invention and thus of a vehicle again executed therewith while avoiding damaging operating conditions and ensures the desired load sensitivity feasible.

Both the features specified in the claims and the features specified in the subsequent embodiments of the device according to the invention are each suitable alone or in any combination with each other to further develop the subject invention. The respective feature combinations represent no limitation with respect to the development of the subject matter according to the invention, but essentially have only an exemplary character.

Further advantages and advantageous embodiments of the device according to the invention will become apparent from the claims and the embodiments described in principle below with reference to the drawings, wherein the same reference numerals are used in the description of the various embodiments in favor of clarity for construction and functionally identical components.

It shows:

1 a highly schematic representation of a vehicle drive train with a hydrostatic having stepless power split transmission;

2 a simplified hydraulic diagram of a first embodiment of the device according to the invention of the vehicle drive train according to 1 ; and

3 a 2 corresponding representation of a second embodiment of the device according to the invention.

1 shows a schematic representation of a vehicle drive train 1 with a drive device 2 and with a continuously variable power-split transmission device which can be coupled thereto 3 , The prime mover 2 is presently as an internal combustion engine, preferably as a diesel engine, executed and can in other embodiments of the vehicle drive train 1 be designed as an electric machine or as a combination of an internal combustion engine of any type and an electric machine.

Between the prime mover 2 and the transmission device 3 is in this case a reversing gear 4 provided, the two frictional switching elements 5 . 6 includes, which are each designed as direction-of-travel couplings. In this case, a drive rotational movement of the drive device 2 with closed frictional switching element 5 with such a direction of rotation in the transmission device 3 initiated that with the vehicle powertrain 1 executed vehicle is driven in the forward direction. In contrast, is the frictional switching element 6 closed and at the same time the frictional switching element 5 opened, the drive rotational movement of the drive device 2 with an opposite direction of rotation in the transmission device 3 initiated and one with the vehicle drivetrain 1 executed vehicle operated in the reverse direction.

A wave 7 the transmission device 3 is with a downforce 8th of the vehicle drive train 1 operatively connected, via which a drivable vehicle axle 9A and 9B can be acted upon with torque. In the area of the steplessly power-split transmission device 3 several translation ranges are adjustable, within which in turn the translation of the transmission device 3 is infinitely variable by adjusting a variator. The transmission device 3 can be both primary be designed as a secondary coupled continuously variable power split transmission.

Instead of the reversing gear 4 can the vehicle powertrain 1 in the area between the drive device 2 and the transmission device 3 also be designed with a conventional starting element, such as with a frictional clutch, wherein a possibly desired reverse drive then, for example, in the range of a separate gear ratio for reverse drive of the transmission device 3 can be represented.

Regardless of the version of the vehicle drive train 1 with the reversing gear 4 or with a single frictional starting clutch is a force flow between the drive means 2 and the downforce 8th in the region of the frictional switching element 5 or the frictional switching element 6 or in the region of a frictional starting clutch by appropriately setting the transmission capability of one of these switching elements produced. In the presence of a request for starting is in the range of the transmission device 3 set a Anfahrübersetzung and a drive torque from the drive device 2 in appropriately converted form in the direction of the output 8th or the drivable vehicle axle 9A and 9B over the transmission device 3 forwarded as soon as the power flow is at least partially made.

A transmission input shaft 10 the transmission device 3 is with the drive device 2 rotatably connected. The transmission input shaft 10 drives over a fixed wheel 11 and a festival bike 12 a shaft for a power take-off 13 and first switching element halves of the frictional switching elements 5 and 6 at. The frictional switching element 5 is coaxial with the transmission input shaft 10 arranged while the frictional switching element 6 or the direction of travel coupling for reverse drive on the coaxial shaft of the power take-off 13 is positioned. In the closed operating state of the frictional switching element 5 or the direction of travel clutch for forward drive drives the transmission input shaft 10 over a loose wheel 14 that is on the transmission input shaft 10 is rotatably mounted, a loose wheel 15 on which with a planet carrier 16 rotatably coupled. In the closed operating state of the frictional switching element 6 drives the transmission input shaft 10 over a loose wheel 17 the idler wheel 15 at.

On the planet carrier 16 are several double planet wheels 18 rotatably mounted. The double planet wheels 18 stand with a first sun gear 19 and a second sun gear 20 and a ring gear 21 engaged. The first sun wheel 19 is with a wave 22 a first hydraulic machine 23 a hydrostatic unit 24 rotatably connected. The ring gear 21 is about a festival bike 25 and a festival bike 26 with a wave 27 a second hydraulic machine 28 the hydrostatic unit 24 operatively connected.

The wave 7 the transmission device 3 is over a coaxial to the shaft 7 arranged frictional switching element 29 for the first transmission range of the transmission device 3 , a loose wheel 30 and a festival bike 31 with the second wave 27 the hydrostatic unit 24 connectable. Furthermore, the wave 7 over a fixed bike 32 a festival bike 33 and another frictional switching element 34 for the second transmission range of the transmission device 3 as well as a loose wheel 35 and a festival bike 36 with the second sun gear 20 coupled. The fixed wheel 62 is coaxial with the second sun gear 20 arranged while the fixed wheel 33 , the frictional switching element 34 for the second driving range and the idler gear 35 are arranged coaxially with each other. The fixed wheel 32 , the frictional switching element 29 for the first driving range and the loose wheel 30 are again coaxial with the shaft 7 intended. In addition, the fixed gear meshes 32 both with the fixed wheel 33 as well as with a fixed bike 36 a transmission output shaft 37 , in turn, with the drivable vehicle axle 9 or with several drivable vehicle axles 9 of the vehicle drive train 1 is connectable.

The directional control clutches 5 and 6 In the present case, these are designed as wet couplings which are not only used to establish the flow of force between the drive device 2 and the downforce 8th are provided, but at the same time to determine the direction of travel to the extent described above. According to their capacitive design, the frictional switching elements 5 and 6 of the vehicle drive train 1 according to 2 also usable as starting elements. This is the case when, by a driver, starting from a neutral operating state of the transmission device 3 to which the switching elements 29 and 34 are opened, one direction of travel is engaged and at the same time an accelerator pedal is actuated to deliver a speed request. The frictional switching elements 5 and 6 In the present case, they are designed in such a way that a change in direction of travel or a so-called reversing procedure based on higher driving speeds in the forward or reverse direction is also possible via them.

During such a reversing process, a vehicle speed is first reduced starting from the current vehicle speed in the direction of zero, for which purpose both the transmission capability of the frictional switching element 5 as well as the transfer capability of the frictional switching element 6 adjusted accordingly. The two frictional switching elements 5 and 6 become predominantly slipping during the reversing process operated. If the vehicle speed is substantially zero, the transmission capabilities of the two switching elements become 5 and 6 set such that the vehicle is started against the previously operated direction of travel in the opposite direction until the requested vehicle speed is reached.

To a starting process starting from a vehicle standstill and the neutral operating state of the transmission device 3 within short operating times and to be able to represent essentially instantaneous, the switching element 29 the first transmission range of the transmission device 3 closed and additionally the switching element 5 or the switching element 6 converted into its closed operating state as a function of the respectively present driver request for forward or reverse travel. During the connection of the switching element 29 and the switching element 5 or 6 become the hydraulic machines 23 and 28 via an adjustable yoke 38 adjusted so that the desired starting ratio is set in the transmission device. In this case, the transmission capability of the frictional switching element 5 or 6 during setting of the starting ratio of the transmission device 3 set to values greater than zero to one with the vehicle driveline 1 according to 1 executed vehicle already during the closing process of the frictional switching element 5 or 6 to be able to approach.

During such a starting process of the vehicle drive train 1 This is in train operation, to which the first hydraulic machine 23 as a pump and the second hydraulic machine 28 be operated as a motor. By an operation of the yoke described in more detail below 38 become axes 39 . 40 the hydraulic machines 23 and 28 for accelerating the vehicle powertrain 1 running vehicle adjusted so that the translation of the transmission device 3 is reduced and an output speed increases. With increasing pivot angle of the axes 39 and 40 in the direction of a maximum pivoting angle, which in the present case is about 44 °, and with continued driver-side request for further acceleration of the vehicle or a further increase in the vehicle speed is for a further stepless change in the ratio of the transmission device 3 in the field of transmission equipment 3 insert the second translation area. This is the switching element 29 turn off and the other frictional switching element 34 to convert into its closed operating state. At a defined swivel angle of the axes 39 and 40 are the frictional switching elements 29 and 34 essentially simultaneously in a synchronous operating state, with which the change between the first transmission region and the second transmission region can be represented without traction interruption.

Is in the transmission device 3 the second transmission range inserted, to which the frictional switching element 34 closed and the frictional switching element 29 is open, the first hydraulic machine is in train operation 23 as engine and the second hydraulic machine 28 operated as a pump. In train operation, the acceleration process is curtailed. In overrun mode, the hydraulic machines work in opposite directions. The two axes 39 and 40 the hydraulic machines 23 and 28 be over the yoke 38 starting together from the current pivot position, ie the maximum pivoting angle, pivoted back in the direction of the starting position at the beginning of the starting process, wherein by the pivoting of the hydrostatic unit 34 the complete translation area of the second translation area is traversed. This causes the speed of the vehicle powertrain 1 vehicle continues to increase until the maximum vehicle speed is reached.

In 2 is a device 41 for varying the stroke volumes of the first hydraulic machine 23 and the second hydraulic machine 28 shown, which are designed as Schrägachsenkolbenmaschinen and their stroke volumes each depending on the pivot positions of the via a double-acting piston-cylinder device 42 jointly adjustable axles 39 . 40 the hydraulic machines 23 . 28 stand. A piston 43 the piston-cylinder device 42 is via a piston rod 44 and the yoke 38 with the axes 39 . 40 the hydraulic machines 23 . 28 operatively connected. There is a mechanical connection between actuator piston and yoke.

The hydraulic machines 23 . 28 are over lines 45 . 46 connected, which is part of the CVT transmission or the transmission device 3 form. About the hydraulic machines 23 . 28 is part of the engine 2 of the vehicle drive train 1 applied torque hydrostatic in the direction of the output 8th feasible. Such transmission devices 3 are used, for example, in wheel loaders, skidders or other construction machines and forestry machines, in which gearboxes are preferably used with continuously variable ratios and on a so-called load-sensitivity can be displayed.

In addition to the above-described change in the operation of the two hydraulic machines 23 and 28 During the transition from the first gear range to the second gear range, the mode of operation of the two hydraulic machines changes 23 and 28 even with a change of Vehicle drive train 1 from train operation to overrun operation. This is the first hydraulic machine 23 when the first transmission range is engaged in overrun mode as a motor and the second hydraulic machine in overrun mode as a pump, while the first hydraulic unit 23 when the second transmission range is engaged, it is operated as a pump in overrun mode and the second hydraulic machine as a motor. This means that the first hydraulic unit 23 is operated in the train operation with inserted first gear range as a pump and a change to the overrun mode of the vehicle drive train 1 goes into engine operation while the second hydraulic engine 28 in train operation first as an engine and a transition to the overrun operation in the pump mode changes.

The function of the device will be described below 41 based on the in 1 illustrated transmission device 3 described, in each of which two driving ranges for forward and reverse travel can be displayed. However, the device can also be used for transmissions with more than two transmission ranges.

In the transmission device 3 inserted first driving range and at the same time stationary vehicle is the device 41 in a so-called rest position and the first hydraulic machine 23 is operated as a pump, while the second hydraulic machine 28 in engine mode. The delivery volume of the first hydraulic machine 23 is minimal in this operating state and the displacement of the second hydraulic machine 28 is maximum, with the axes 39 and 40 the two hydraulic machines 23 . 28 each in the 1 and 2 having shown pivot position.

The piston-cylinder device 42 is present a control valve device 47 assigned, which represents a position control valve and is designed as a 4/2 control valve. At the control valve device 47 lies in each case in the field of hydraulic machines 23 and 28 or in the area of the lines 45 and 46 acting hydraulic pressure, the corresponding actuation of the control valve device 47 in a first piston chamber 48A or in a second piston chamber 48B the piston-cylinder device 42 on active surfaces 43A or 43B of the piston 43 can be applied. The control valve device 47 is via a presently designed as a shuttle valve device 49 each with the line 45 or 46 coupled, currently in the higher pressure applied. In addition, the control valve device 47 in the embodiments of the device shown in the drawing 41 via a proportional magnet 50 actuated, wherein the control of the control valve device 47 can also be done via a proportionally adjustable control pressure valve.

The actuating force of the proportional solenoid 50 acts a spring force of a spring device 51 contrary, whose spring force in response to a mechanical coupling 52 between the spring device 51 with the piston 43 the piston-cylinder device 42 varied. About the mechanical coupling 52 becomes the position of the piston 43 the piston-cylinder device 42 on the control valve device 47 or their valve slide 53 confirmed and the actuation of the two hydraulic machines 23 and 28 regulated.

Is that in the range of the proportional magnet 50 generated force greater than that on the valve spool 53 the control valve device 47 engaging spring force of the spring device 51 , which is in the field of hydraulic machines 23 . 28 present pressure or high pressure in the line 45 or in the line 46 in one of the in 2 shown position of the valve spool 53 deviating position of the valve spool 53 the control valve device 47 in the second piston chamber 48B the piston-cylinder device 42 guided while hydraulic fluid from the first piston chamber 48A via the control valve device 47 in a pressureless area 54 or a tank is drained.

This causes the piston 43 starting from the in 2 shown position together with the piston rod 44 shifted and the volume of the first piston chamber 48A is reduced while the volume of the second piston chamber 48B increased. By adjusting the piston rod 44 is the delivery volume of the pump operated as the first hydraulic machine 23 increases and the displacement of the second hydraulic machine operated as a motor 28 reduced accordingly. Corresponds to those in the range of the proportional magnet 50 generated force of the spring force of the spring device 51 , is the position of the piston 43 adjusted.

The respective position of the piston 43 the piston-cylinder device 42 each determines the gear ratio between the stroke volumes of each operated as a pump hydraulic machine 23 or 28 and each operated as a motor hydraulic machine 28 or 23 , Is that from the two hydraulic machines 23 and 28 formed hydrostatic device 24 attached to a secondary coupled power split transmission, so that the driving speed of a running with this transmission vehicle is continuously adjusted or regulated.

About the control valve device 47 is also a stepless pressure limiting function over the entire operating range of the hydraulic machines 23 and 28 can be displayed with appropriate control. The aim of the pressure limiting function is that the pressure limit in the field of hydraulic machines 23 and 28 only in emergencies in the area of high-pressure relief valves 55 . 56 is limited and hydraulic fluid in the field of high pressure relief valves 55 and 56 from the high pressure side to the low pressure side. At a pressure relief via the high-pressure relief valves 55 and 56 The power losses occur from the two hydraulic machines 23 and 28 existing hydrostatic transmission overheat very quickly and the fuel consumption of a preferably designed as an internal combustion engine prime mover with the transmission device 3 executed vehicle drive train 1 unnecessarily increase.

The high pressure relief valves 55 and 56 are primarily intended for system protection during highly dynamic load changes, as these have a shorter response time than the control valve device 47 are executed. This will cause unwanted damage in the hydrostatic system of the device 41 avoided by the control valve device 47 alone can not be prevented due to the slower response.

About the pressure limiting function is a maximum high pressure in the range of hydraulic machines 23 and 28 to a lower pressure level than the opening pressure of the high pressure relief valves 55 . 56 be limited. Is the response limit of the high-pressure relief valves 55 . 56 for example, at 500 bar, the proportional solenoid 50 energized so that the piston chamber 48A or the piston chamber 48B is pressurized and the stroke volumes of the hydraulic machines 23 and 28 be changed in such a way that the high pressure in the system is performed below critical pressure values. The high pressure is dependent on the driving strategy and limiting components, eg. B. drive axles, limited.

From the response time of the control valve device 47 The output speed of each operated as a motor hydraulic machine 23 or 28 decreases or increases its swallowing volume. At the same time the delivery volume of each operated as a pump hydraulic machine 28 or 23 reduced and thus reduced power consumption. The high pressure limitation is via the device 1 over the entire operating range of the transmission device 3 , ie over all driving ranges, provided.

In order to implement the high-pressure limitation function to the desired extent, the device has 41 An institution 57 for determining a currently existing actual pressure upstream of the control valve device 47 in the area between the valve device 49 and the control valve device 47 on. The device 57 is in the present case formed with a high pressure sensor. Furthermore, between the control valve device 47 and the piston-cylinder device 42 another facility 58 provided with those in the area of the active surfaces 43A . 43B or the piston chambers 48A . 48B the piston-cylinder device 42 be applied to adjacent pressures and of these in a first or a second operating state can be transferred. The further device 58 in this case represents a simple pressure compensator and is designed as a 3/2-way valve, the valve spool 59 in the area of a first effective area 59A with the in the piston chamber 48A present pressure and in the range of another effective area 59B with one in the area of the piston chamber 48B present pressure can be acted upon. In addition, the valve spool engages 59 a spring device 60 to who the further device 58 below a limit pressure level in the region of the piston-cylinder device 42 adjacent pressures in the in 2 Defined converted first operating state defined and holds in this.

The in the area of the piston chamber 48A applied pressure engages the valve spool 59 in the area of the effective area 59A of the valve spool 59 the spring device 60 counteracting, while in the region of the piston chamber 48B present pressure in the same direction as the spring force of the spring device 60 can be applied to the valve spool.

In the in 2 illustrated switching position or in the first operating state of the other device 58 becomes one at the further device 58 applied pressure signal pS in the direction of an additional device 61 forwarded, creating the additional facility 61 in a defined operating state, the transition to the first operating state of the further device 58 is equivalent. Depending on the respective available availability, the pressure signal pS can be a lubrication pressure, a system pressure of the transmission device 3 or another suitable preferably regulated regulated pressure or the like. The further device 58 and the additional facility 61 are in space and cost-effective manner downstream of the control valve device 47 and upstream of the piston-cylinder device 42 For example, in the base plate of the hydrostatic unit 24 integrated.

The axial position of the valve spool 59 depends on the valve slide 59 each attacking total force component, each resulting from the compressive force in the range of effective area 59A the compressive force in the area of the effective surface 59B and the spring force of the spring device 60 composed. Therefore, the valve spool changes 59 its axial switching position depending on which of the active surfaces 59A and 59B is subjected to the higher pressure. The further device 61 puts in each case Dependence of the axial position of the valve spool 59 the device 58 a usable signal ready, the additional device 61 a simple opener or closer or a correspondingly suitable pressure sensor can be.

About the device 57 and the further furnishings 58 is in conjunction with the additional facility 61 a load sensitivity of the transmission device 3 independent of the pressure side of the hydraulic machines 23 and 28 during a push or pull operation and independently of each in the field of transmission device 3 inserted driving range feasible. For this purpose, via the high pressure sensor of the device 57 the amount and the course of the actual pressure in the area of the line 45 or 46 determined. Furthermore, in connection with the further device 58 and the additional facility 61 the print sides of the hydraulic machines 23 and 28 determined and provided to a stored in a controller software logic as information or as input variables available. About the software logic train and thrust cases are distinguished and depending on the current operating condition, the translation of the transmission device 3 specifically adjusted to short or long, thus limiting the high pressure in the field of hydraulic machines over the entire operating range or in all driving situations 23 and 28 is achievable. It generally applies that the control valve device 47 for high-pressure limitation in overrun mode by means of an appropriate current supply of the proportional solenoid set by the software 50 is to be operated such that the reciprocal gear ratio of the transmission device 3 is increased, while in the train operation, the reciprocal transmission ratio to reduce high pressure limitation or the transmission device 3 to be adjusted shortly.

In principle, it is also true that both the amount of high pressure and the information about the overrun or traction mode must be made available for implementing the high-pressure limitation function. In the present case, this is via the further device designed as a pressure compensator 58 in conjunction with the additional facility 61 in a simple manner possible, since in each case the pressure chamber 48A or 48B the piston-cylinder device 42 about the further device 58 and the additional facility 61 can be determined, currently in the higher pressure is applied.

The determination of a currently existing train operation or a currently available overrun operation on the further device 58 and the additional facility 61 is therefore possible because in the area of the hydrostatic unit 24 or in the area of each operated as a pump hydraulic machine 23 or 28 each return pivotal forces lie in the direction of smaller delivery volumes in operation, via the yoke 38 on the piston-cylinder device 42 be transmitted. The in the range of operated as a pump hydraulic machine 23 or 28 Returning torques generated by differential pressure are applied to the axle 39 or 40 each in the direction of smaller tilt angle and shape the yoke 38 Stellmomente on. The direction of the control moments in turn depends on whether the hydraulic machine 23 or the hydraulic machine 28 operated as a pump. Depending on the operating condition and in the gearbox 3 engaged transmission area and the currently requested direction of travel is in the area of the piston chamber 48A or the piston chamber 48B for supporting in the area of the hydrostatic unit 24 acting restoring moments apply a higher pressure. About acting as a pressure compensator further device 58 is dependent on the pressure-dependent varying axial position of the valve spool 59 each the pressure chamber 48A or 48B determinable, in which the respective higher pressure is applied, whereby a currently present pulling or pushing operation of the vehicle drive train 1 can be determined in a simple manner.

Exceeds the high pressure in the region of the line 45 or the line 46 a predefined pressure limit and is the vehicle driveline 1 in Zugbetrieb, a Zugkraftlimitierung is generally by the shortly after the transmission device 3 realizable. In this case, the control valve device 47 with inserted first driving range into the in 1 shown position on the proportional magnet 50 and the spring device 51 to transfer, with the valve spool 53 the control valve device 47 then in Durchlassstellung located. In the transmission device 3 inserted second driving range or translation range is the valve spool 53 the control valve device 47 to convert into a cross position, wherein the proportional magnet 50 is to be energized accordingly. In general, the transmission device 3 for a high-pressure limitation in the train operation via the control valve device 47 as far as to adjust shortly until the desired high pressure or the desired tensile force sets.

In overrun operation is a Zugkraftlimitierung or the high pressure limitation in general by the long places the transmission device 3 realizable. For this is the control valve device 47 with inserted first driving range in the transmission device 3 to transfer in his crossing position and with inserted second driving range in the in 2 bring shown passage position.

That after short places in the train operation or after long places in overrun always takes place until the measured high pressure in the line 45 or the line 46 is equal to the predetermined maximum target high pressure. A load sensitivity of the transmission device 3 can be achieved in the desired or required extent in connection with a targeted maximum target pressure specification, for example by a driver request, the specification of a driving strategy computer or as a function of a necessary brake pressure for a transmission protection.

This in 3 illustrated embodiment of the device 41 is different from the one in 2 shown embodiment of the device 41 constructive in that the device 41 according to 3 without the mechanical coupling 52 is trained. About the mechanical feedback of the mechanical coupling 52 Stable setting of a ratio in the range of the two hydraulic machines 23 and 28 over the device 41 according to 3 To be able to make, is the control valve device 47 the device 41 according to 3 or its proportional magnet 50 in addition, depending in turn on the stroke volumes of the hydraulic machines 23 and 28 varying translation of the hydraulic machines 23 and 28 executed transmission device 3 actuated. For this purpose, for example, signals from in the range of the transmission device 3 provided speed sensors or a swivel angle sensor for detecting the pivoting angle of the axes 39 and 40 the hydraulic machines 23 and 28 usable to balance whether the currently engaged actual gear ratio of the transmission device 3 corresponds to the requested target translation. If this is the case, then further adjustment of the piston 43 prevented, in which the over the control valve device 47 guided hydraulic fluid volume flow via a suitable actuation or a suitable energization of the proportional magnet 50 is set to zero.

LIST OF REFERENCE NUMBERS

1

Vehicle powertrain

2

driving means

3

transmission device

4

Reverse gear

5

frictional switching element

6

frictional switching element

7

wave

8th

output

9A, 9B

drivable vehicle axle

10

Transmission input shaft

11

fixed gear

12

fixed gear

13

PTO shaft

14

Losrad

15

Losrad

16

planet carrier

17

Losrad

18

double planet

19

first sun gear

20

second sun wheel

21

ring gear

22

wave

23

first hydraulic unit

24

hydrostatic unit

25

fixed gear

26

fixed gear

27

wave

28

second hydraulic unit

29

frictional switching element

30

Losrad

31

fixed gear

32

fixed gear

33

fixed gear

34

frictional switching element

35

Losrad

36

fixed gear

37

Transmission output shaft

38

adjustable yoke

39, 40

axis

41

contraption

42

Piston-cylinder device

43

Piston of the piston-cylinder device

43A, 43B

Effective area of the piston

44

piston rod

45

management

46

management

47

Control-valve device

48A, 48B

piston chamber

49

valve means

50

proportional solenoid

51

spring means

52

mechanical coupling

53

Valve slide of the control valve device

54

pressureless area

55, 56

High-pressure relief valve

57

Facility

58

further equipment

59

Valve slide the other device

59A, 59B

Working surface of the valve spool of the other device

60

spring means

61

additional facility

62

fixed gear

pS

pressure signal

Claims (14)

Contraption ( 41 ) with at least two via lines ( 45 . 46 ) and operable both as a pump and as a motor Hydraulic machines ( 23 . 28 ), whose stroke volumes in each case in dependence on pivot positions of adjustable axes ( 39 . 40 ) of hydraulic machines ( 23 . 28 ), the axes ( 39 . 40 ) with a piston-cylinder device ( 42 ) and the hydraulic machines ( 23 . 28 ) in the pump operation in each case have a pressure-dependent return pivoting behavior in the direction of smaller delivery volumes, wherein the piston-cylinder device ( 42 ) in the area of active surfaces ( 43A . 43B ) in the region of a control valve device ( 47 ) adjustable pressures for pivoting the axes ( 39 . 40 ) is acted upon, and wherein the control valve device ( 47 ) each with which the hydraulic machines ( 23 . 28 ) connecting line ( 45 . 46 ) is coupled, in which the higher pressure is present, characterized in that between the control valve device ( 47 ) and the piston-cylinder device ( 42 ) An institution ( 58 . 61 ) provided with in the area of the active surfaces ( 43A . 43B ) of the piston-cylinder device ( 42 ) applied pressure and can be converted by these in a first or a second operating state. Device according to claim 1, characterized in that the device ( 58 . 61 ) in each case depending on the pressure difference between those in the area of the active surfaces ( 43A . 43B ) of the piston-cylinder device ( 42 ) Existing pressures standing total force component in the first operating state or the second operating state can be transferred. Device according to claim 1 or 2, characterized in that the device ( 58 ) an axially displaceable slide element ( 59 ), in whose region each of the total force component engages and in each case in a first to the first operating state equivalent position or in a second to the second operating state ( 58 ) the device equivalent position can be transferred. Apparatus according to claim 3, characterized in that the total force component also in dependence on the slide element ( 59 ) acting spring device ( 60 ), which the slide element ( 59 ) in the area of the active surfaces ( 43A . 43B ) of the piston-cylinder device ( 42 ) applied pressures smaller than a pressure limit in the first position adjusted. Apparatus according to claim 3 or 4, characterized in that the axial position of the slide element via a displacement measuring unit, preferably via a the slider element associated Hall sensor, can be determined. Device according to one of claims 1 to 5, characterized in that the device ( 58 ) is designed as a 3/2-way valve whose valve slide ( 59 ) of the total force component in each case in a first to the first operating state equivalent position or in a second to the second operating state of the device equivalent position can be transferred, wherein in the first position of the valve spool ( 59 ) an applied pressure (pS) in the direction of another device ( 61 ) is forwarded. Device according to one of claims 1 to 6, characterized in that a high-pressure sensor ( 57 ) in the area between one of the hydraulic machines ( 23 . 28 ) connecting lines ( 45 . 46 ) operatively connected shuttle valve ( 49 ) and the control valve device ( 47 ) is provided. Device according to one of claims 1 to 7, characterized in that the axes ( 39 . 40 ) of hydraulic machines ( 23 . 28 ) together over a yoke ( 38 ) are adjustable, that with the piston-cylinder device ( 42 ) is coupled. Device according to one of claims 1 to 7, characterized in that the axes of the hydraulic machines are independently adjustable from the piston-cylinder device. Device according to one of claims 1 to 9, characterized in that the control valve device ( 47 ) is designed as a 4/2 control valve whose valve slide ( 53 ) of a variable actuating force against a preferably variable further on the valve spool ( 53 ) engaging actuating force between a first end position in the direction of a second end position is adjustable. Apparatus according to claim 10, characterized in that a piston ( 43 ) of the preferably double-acting piston-cylinder device ( 42 ) with the valve slide ( 53 ) of the control valve device ( 47 ) is operatively connected and the other at the valve spool ( 53 ) engaging force as a function of a position of the piston ( 43 ) varies. Apparatus according to claim 10 or 11, characterized in that the force acting on the valve spool of the control valve means actuating force is variable depending on a detectable in the region of a device and in dependence on the stroke volumes of the hydraulic machines varying ratio of running with the hydraulic machines gear device. Device according to one of claims 10 to 12, characterized in that the stroke volumes of the hydraulic machines ( 23 . 28 ) above a preferably variable pressure limit value in the region of the hydraulic machines ( 23 . 28 ) interconnecting lines ( 45 . 46 ) by a corresponding adjustment of the valve spool ( 53 ) of the control valve device ( 47 ) acting force to values are feasible, to which the pressure in the lines ( 45 . 46 ) has at least approximately a pressure threshold corresponding level. Apparatus according to claim 13, characterized in that the pressure limit value is less than or equal to one in the region of the hydraulic machines ( 23 . 28 ) connecting lines ( 45 . 46 ) is to be set nominal pressure value, which is used to transmit a defined torque between the hydraulic machines ( 23 . 28 ) is requested.

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