CONTROLLING A DRIVE SYSTEM FOR AN AXLE OF A MOTOR VEHICLE

Abstract

The invention relates to a method for controlling a drive system for an axle of a motor vehicle, wherein the drive system has at least one drive unit, a drive shaft driven by the drive unit, a first output shaft and a second output shaft, as well as a first clutch connecting the drive shaft to the first output shaft and a second clutch connecting the drive shaft to the second output shaft, and furthermore comprises a control unit for controlling the clutches, wherein the clutches are able to be operated at least at certain operating points with a micro-slip control in which a speed differential between the drive shaft and the output shaft of more than zero revolutions per minute and no more than 50 revolutions per minute is set at the respective clutch, wherein the method comprises at least the following steps: a) establishing a travel state of the motor vehicle, wherein at least the following travel states are detected: traveling straight ahead and cornering in the pull mode; b) selecting and applying a control strategy for each clutch, wherein the control strategy is different for different travel states.

Claims

1-13. (canceled)

14. A method for controlling a drive system for an axle of a motor vehicle, the drive system having at least one drive unit, a drive shaft driven by the drive unit, a first output shaft and a second output shaft, as well as a first clutch connecting the input shaft to the first output shaft and a second clutch connecting the input shaft to the second output shaft, and furthermore comprising a control unit for controlling the clutches; wherein the clutches are operable at least at certain operating points with a micro-slip control in which a speed differential between the drive shaft and the output shaft of more than zero revolutions per minute and no more than 50 revolutions per minute is set at the respective clutch, wherein the method comprises: a) establishing a travelling state of the motor vehicle, wherein at least the following travel states are detected: traveling straight ahead and cornering in the pull mode; and b) selecting and applying a control strategy for each clutch, wherein the control strategy is different for different travel states.

15. The method of claim 14, wherein the axle is steerable by a steering system which has a steering drive for actuating the steering system; wherein when cornering in the pull mode, the steering drive is impinged by a restoring torque for resetting the steering system toward the straight-ahead travel state.

16. The method of claim 15, wherein the restoring torque is determined as a function of at least one steering angle of the steering system or of a torque differential, wherein the torque differential is the difference between a first torque transmitted by way of the first clutch and a second torque transmitted by way of the second clutch.

17. The method of claim 15, wherein the steering system is automatically set to the straight-ahead travel state by way of the restoring torque.

18. The method of claim 14, wherein a first control strategy for the straight-ahead travel state comprises mutually independent micro-slip controls for the first clutch and for the second clutch.

19. The method of claim 18, wherein the first control strategy is used for the straight ahead travel state in the forward gear and in the reverse gear.

20. The method of claim 18, wherein at least the following travel state is additionally recorded: cornering in the push mode, wherein a second control strategy for the cornering in the push mode travel state comprises a micro-slip control for the clutch on the inside of the curve, wherein the clutch on the outside of the curve as a function of the clutch on the inside of the curve is controlled so that a first torque transmitted by the clutch on the outside of the curve corresponds to the second torque of the clutch on the inside of the curve, said second torque having been varied by a factor.

21. The method of claim 20, wherein a third control strategy for the cornering in the pull mode travel state comprises a micro-slip control for the clutch on the outside of the curve, wherein the clutch on the inside of the curve is controlled as a function of the clutch on the outside of the curve such that a first torque transmitted by the clutch on the inside of the curve corresponds to the second torque of the clutch on the outside of the curve, said second torque having been varied by a second factor.

22. The method of claim 20, wherein the factor is determined as a function of at least one of the following parameters: a steering angle of a steering system of the motor vehicle; speed of the motor vehicle; minimum torque differential between a wheel on the inside of the curve and a wheel on the outside of the curve; yaw rate; torque of the drive shaft; or speed differential of the wheels of the axle.

23. The method of claim 14, wherein by actuating each clutch one wheel of the common axle of the motor vehicle can be connected in a torque-transmitting manner to the drive unit.

24. The method of claim 14, wherein the drive unit is an electric machine.

25. The method of claim 14, wherein a torque differential between the drive shaft and the output shaft of more than zero revolutions per minute and of at most 5 revolutions per minute is set at the micro-slip control on the respective clutch.

26. A control unit for a motor vehicle, the motor vehicle at least having a drive system for at least one axle of the motor vehicle, wherein the drive system has at least one drive unit, a drive shaft driven by the drive unit, a first output shaft and a second output shaft, and a first clutch connecting the drive shaft to the first output shaft and a second clutch connecting the drive shaft to the second output shaft, and furthermore a control unit for controlling the clutches, wherein the control unit comprises a computer including a processor and is configured for operating the drive system, including by: a) establishing a travelling state of the motor vehicle, wherein at least the following travel states are detected: traveling straight ahead and cornering in the pull mode; and b) selecting and applying a control strategy for each clutch, wherein the control strategy is different for different travel states.

27. The control unit of claim 26, wherein the axle is steerable by a steering system which has a steering drive for actuating the steering system; wherein when cornering in the pull mode, the steering drive is impinged by a restoring torque for resetting the steering system toward the straight-ahead travel state.

28. The control unit of claim 15, wherein the restoring torque is determined as a function of at least one steering angle of the steering system or of a torque differential, wherein the torque differential is the difference between a first torque transmitted by way of the first clutch and a second torque transmitted by way of the second clutch.

29. The control unit of claim 28, wherein the steering system is automatically set to the straight-ahead travel state by way of the restoring torque.

30. The control unit of claim 26, wherein a first control strategy for the straight-ahead travel state comprises mutually independent micro-slip controls for the first clutch and for the second clutch.

31. The control unit of claim 30, wherein at least the following travel state is additionally recorded: cornering in the push mode, wherein a second control strategy for the cornering in the push mode travel state comprises a micro-slip control for the clutch on the inside of the curve, wherein the clutch on the outside of the curve as a function of the clutch on the inside of the curve is controlled so that a first torque transmitted by the clutch on the outside of the curve corresponds to the second torque of the clutch on the inside of the curve, said second torque having been varied by a factor.

32. The control unit of claim 31, wherein a third control strategy for the cornering in the pull mode travel state comprises a micro-slip control for the clutch on the outside of the curve, wherein the clutch on the inside of the curve is controlled as a function of the clutch on the outside of the curve such that a first torque transmitted by the clutch on the inside of the curve corresponds to the second torque of the clutch on the outside of the curve, said second torque having been varied by a second factor.

33. The control unit of claim 30, wherein a torque differential between the drive shaft and the output shaft of more than zero revolutions per minute and of at most 5 revolutions per minute is set at the micro-slip control on the respective clutch.

Description

SUMMARY OF THE DRAWINGS

[0060] The invention as well as the technical field will be explained in more detail hereunder with reference to the figures. It should be pointed out that the invention is not intended to be limited by the exemplary embodiments shown. In particular, unless explicitly stated otherwise, it is also possible to extract partial aspects of the substantive matter explained in the figures and to combine them with other constituent parts and knowledge from the present description and/or figures. The same reference signs denote the same objects and therefore where appropriate explanations from other figures can be used in a supplementary manner. In the figures, in each case schematically:

[0061] FIG. 1: shows a motor vehicle with a drive system for driving in each case one wheel of the motor vehicle;

[0062] FIG. 2: shows a further motor vehicle;

[0063] FIG. 3: shows an axle of the motor vehicle according to FIG. 2, said axle being controlled with the first control strategy;

[0064] FIG. 4: shows the axle according to FIG. 3, said axle being controlled with the third control strategy; and

[0065] FIG. 5: shows the axle according to FIG. 3, said axle being controlled with the second control strategy; and

[0066] FIG. 6: shows a driven and steerable axle that is controlled with the third control strategy.

DESCRIPTION

[0067] FIG. 1 shows a motor vehicle 3 having a drive system 1 for driving a first wheel 16 and a second wheel 17 of a common axle 2 of the motor vehicle 3. The drive system 1 comprises a drive unit 4, a drive shaft 5 driven by the drive unit 4, a first output shaft 6 and a second output shaft 7, as well as a first clutch 8 connecting the drive shaft 5 to the first output shaft 6, and a second clutch 9 connecting the drive shaft 5 to the second output shaft 7. A control unit 10 for controlling the two clutches 8, 9 is furthermore provided.

[0068] Here, a drive system 1 is shown in which two clutches 8, 9 are provided on a common axle 2 of the motor vehicle 3, wherein one wheel 16, 17 of the motor vehicle 3 is in each case connected in a torque-transmitting manner to the drive unit 4 of the motor vehicle 3 by way of each of the two clutches 8, 9. The two clutches 8, 9 replace an otherwise usual differential 18 (illustrated here on the other axle of the motor vehicle), by means of which different speeds of the wheels can be compensated.

[0069] A transmission 19 is disposed between the drive unit 4 and the output shafts 6, 7.

[0070] FIG. 2 shows a further motor vehicle 3. Reference is made to the explanations pertaining to FIG. 1. Here, the drive unit 4 transmits the torque directly by way of the drive shaft 5 to the axle 2 or by way of the first clutch 8 to the first output shaft 6, and by way of the second clutch 9 to the second output shaft 7. The first clutch 8 is controlled by way of a first valve 22 and the second clutch 9 by way of a second valve 23. The valves 22, 23 are actuated in a controlled manner by a pump 21 driven by a pump motor 20.

[0071] FIG. 3 shows an axle 2 of the motor vehicle 3 according to FIG. 2, said axle 2 being controlled with the first control strategy 11.

[0072] The first control strategy 11 for the straight-ahead travel state comprises a mutually independent micro-slip control for the first clutch 8 and for the second clutch 9. This means that each clutch 8, 9 is controlled individually, in particular, for example (exclusively) as a function of the slip between the respective wheel 16, 17 and the road surface.

[0073] FIG. 4 shows the axle 2 according to FIG. 3, said axle 3 being controlled with the third control strategy 13. Reference is made to the explanations pertaining to FIG. 3.

[0074] The third control strategy 13 for the cornering in the pull mode travel state comprises a micro-slip control for the clutch on the outside of the curve (here the second clutch 9), wherein the clutch on the inside of the curve (here the first clutch 8) is controlled as a function of the (second) clutch 9 on the outside of the curve such that a first torque transmitted by the (first) clutch 8 on the inside of the curve corresponds to the second torque of the (second) clutch 9 on the outside of the curve, the latter torque having been varied by a factor. The steering system 15 has a steering angle 14, so that the (first) wheel 16 on the inside of the curve and the (second) wheel 17 on the outside of the curve can be determined.

[0075] FIG. 5 shows the axle 2 according to FIG. 3, said axle 2 being controlled with the second control strategy 12. Reference is made to the explanations pertaining to FIGS. 3 and 4.

[0076] The second control strategy 12 for the cornering in the push mode travel state comprises a micro-slip control for the clutch on the inside of the curve (here the first clutch 8), wherein the (second) clutch 9 on the outside of the curve is controlled as a function of the clutch 8 on the inside of the curve such that a first torque transmitted by the clutch 9 on the outside of the curve corresponds to the second torque of the clutch 8 on the inside of the curve, said latter torque having been varied by a factor.

[0077] In the second control strategy 12 and the third control strategy 13, one clutch 8, 9 is in each case controlled by way of the micro-slip control (indicated in each case by a dotted line in FIGS. 4 and 5), wherein the respective other clutch 9, 8 is operated as a function of this clutch 8, 9 that is controlled by the micro-slip control.

[0078] FIG. 6 shows a driven and steerable axle 2, which is controlled with the third control strategy 13. Reference is made to the explanations pertaining to FIG. 4.

[0079] The third control strategy 13 for the cornering in the pull mode travel state comprises a micro-slip control. The steering system 15 has a steering angle 14, so that the (first) wheel 16 on the inside of the curve and the (second) wheel 17 on the outside of the curve can be determined.

[0080] In the present case, the axle 2 can be steered by way of a steering system 15 (e.g. comprising a steering wheel, e.g. activatable by a driver so as to deflect the wheels 16, 17 of the axle 2) which has a steering drive 24 (e.g. power steering or similar) for activating the steering system 15. The steering system 15 proceeding from a non-deflected state (e.g. driving straight ahead or steering angle 14 of zero angular degrees) can be deflected such that a steering angle 14 greater than zero angular degrees is present.

[0081] When cornering in the pull mode, the steering drive 24 is impinged by an additional restoring torque 25 (dependent on the torque differential on the steered axle) for resetting the steering system 15 to the straight-ahead travel state.

LIST OF REFERENCE SIGNS

[0082] 1 Drive system

[0083] 2 Axle

[0084] 3 Motor vehicle

[0085] 4 Drive unit

[0086] 5 Drive shaft

[0087] 6 First output shaft

[0088] 7 Second output shaft

[0089] 8 First clutch

[0090] 9 Second clutch

[0091] 10 Control unit

[0092] 11 First control strategy

[0093] 12 Second control strategy

[0094] 13 Third control strategy

[0095] 14 Steering angle

[0096] 15 Steering system

[0097] 16 First wheel

[0098] 17 Second wheel

[0099] 18 Differential

[0100] 19 Transmission

[0101] 20 Pump motor

[0102] 21 Pump

[0103] 22 First valve

[0104] 23 Second valve

[0105] 24 Steering drive