WO2014202068A2

WO2014202068A2 - Drive train topology and actuation device therefor

Info

Publication number: WO2014202068A2
Application number: PCT/DE2014/200224
Authority: WO
Inventors: Christoph Maier; Thomas Eckenfels; Martin Dilzer
Original assignee: Schaeffler Technologies Gmbh & Co. Kg
Priority date: 2013-06-20
Filing date: 2014-05-21
Publication date: 2014-12-24
Also published as: DE112014002946A5; DE102014209620A1; WO2014202068A3

Abstract

The invention relates to a hybrid drive train topology comprising an internal combustion engine and an electric traction machine and a downstream transmission in the torque flux, a freewheel mechanism being arranged in the torque flux between the internal combustion engine and the traction machine, and a clutch, especially a starting clutch, being arranged between the traction engine and the transmission. The invention further relates to a corresponding actuation device.

Description

Powertrain topology and actuator therefor

The invention relates to a drive train topology, in particular a hybrid powertrain topology, in particular for motor vehicles. The invention also relates to an actuating device for this purpose.

The invention relates to a parallel hybrid (P2) powertrain topology for manual (MT) or automated manual transmissions (AMT). In the typical P2 powertrain topology 1 according to the prior art according to FIG. 1 for manual or automated manual transmissions 2 there is a separating clutch (KO) between the traction engine 3 and the internal combustion engine 4 (VKM). The starting clutch (K1) is arranged between traction machine 3 and transmission 2 in the drive train. Furthermore, a starter 5 or belt starter generator can be present, so to speak as a small traction machine. But this small traction machine can also be omitted if the internal combustion engine 4 is started by means of the traction machine 3. Also, a damping element 6 may be provided in the drive train. In this case, the number of damping elements 6 may be different and these may also be arranged at different positions in the drive train, such as a disc damper of a clutch disc or as a dual mass flywheel.

The following main operating states of the clutches (KO and K1) must be fulfilled in order to be able to represent the full functionality of the powertrain topology, see the table according to FIG. 2. There are six operating states, which are shown in the table. In the table, a 0 means that the clutch does not transmit torque and a 1 that the clutch transmits torque. For example, for hybrid combustion with an internal combustion engine and electric traction engine, the two clutches KO and K1 are engaged, see state # 1. The same applies to operating mode # 6 for parking. When changing gear in the gearbox 2, both clutches KO and K1 are disengaged, see states # 4 and # 5. The clutch KO may also be closed during gear changes in state # 5 of hybrid driving. When driving electrically by means of the traction machine 3, the clutch KO is disengaged and the clutch K1 engaged, see operating state # 2. When charging in stand, the clutch KO is engaged and the clutch K1 disengaged, see operating state # 3. A disadvantage of the prior art is that in case all four possible shift positions of the clutches KO and K1 are to be represented, the two clutches KO and K1 are to be actuated independently of each other via an actuator system. When both clutches are actuated via an actuator, ie sequentially, it is only possible to represent three switch positions of K1 and KO. This means that not the full functionality of the system can be displayed.

Serving such a system by means of two actuators, so the axial space requirement increases and the system costs increase. Assuming that such a system is primarily used for lower vehicle segment classes and front-to-back applications, the issues of large axial space requirements and high system costs are critical.

The invention had the object of finding a drive train topology for a vehicle with manual transmission (MT) or automated manual transmission (AMT), with full functionality, operated via an actuator, such as actuators, and with little additional axial space requirements to find.

The inventive solution to the problem consists in a new drive train topology with a freewheel and possibly a coupling element, instead of the previous clutch between the engine and transmission. This new topology can be operated with just one actuator to show full functionality.

The object of the invention is achieved with the features of claim 1.

An embodiment of the invention relates to a hybrid powertrain topology with an internal combustion engine and an electric traction machine and a downstream transmission in the torque flow, wherein in the torque flow between the engine and the traction machine, a freewheel and between the traction machine and the transmission, a clutch, in particular as a starting clutch, is arranged ,

It is particularly advantageous if a mechanical coupling element is provided in the torque flow parallel to the freewheel. This mechanical coupling element is preferably mechanically actuated by means of an actuator. It is also advantageous if in the torque flow between the freewheel and the

Internal combustion engine and / or after the freewheel a damper is arranged.

Additionally or alternatively, the clutch may advantageously comprise a clutch disc, wherein a damper is arranged in the clutch disc.

It is particularly advantageous if an actuator is provided by means of which the coupling and the coupling element can be actuated.

The invention further relates to an actuator for clutch assemblies in which two clutches or clutch systems are to be actuated with an actuator. In particular, the two clutch systems are designed as a friction clutch starting clutch and designed as a positive jaw clutch coupling element. The actuating force that the actuator has to provide to actuate both clutches acts unidirectionally.

One prior art solution for operating the two clutch systems described above provides for two actuators and two independent actuation systems for both clutches. An actuation of both coupling systems with two actuation systems brings increased costs and increased space requirements.

It is also the object of the invention to provide a simple actuating device which allows to operate two clutches with an actuator.

The object is achieved with the features of claim 6.

The clutches are advantageously a friction clutch and a dog clutch. The friction clutch should be actively opened by the actuation system, wherein the clutch is closed in the unactuated state, that is engaged. The contact force required for transmitting the acting moments is provided by means of an energy storage device, such as a disk spring. The jaw clutch should only be closed and opened when the friction clutch is closed. About the jaw clutch only thrust moments of the engine should be transmitted. The moments to be transmitted therefore always work in the same direction. The inventive solution of the problem is advantageous in an actuating system, which combines a lever system, spring systems and other functional parts so that a unidirectionally acting actuator / Ausrückersystem for sequential operation of friction and claw coupling can be used.

It is particularly advantageous if the actuating device is designed with an electric machine, a friction clutch and a dog clutch, wherein the friction clutch and the dog clutch are arranged radially inside the electric machine.

It is particularly advantageous if a lever system is provided by means of which the actuation of the friction clutch and of the dog clutch takes place.

It is expedient if an actuator is provided which exerts an actuating force on a release system, wherein depending on the position of the release system and thus the lever system, the friction and dog clutch are open or the friction clutch is closed and the dog clutch is open or friction and Claw clutch are closed.

It is particularly advantageous if the actuation is unidirectional.

According to the invention, it is particularly advantageous if both clutches or both

Coupling systems, such as friction and dog clutch, closed in the unactuated state, as are closed by a spring force. Thus, both clutches are advantageously closed when no force is applied from the outside, ie from the actuator. This allows unidirectional operation.

It is also advantageous if the actuation of the clutch systems takes place sequentially. The actuation of the dog clutch via pressure fingers, which are guided outside the friction clutch. The actuation of both coupling systems via a lever which takes the spring preload of the pressure fingers in the first operating stroke, the springs are tensioned against the tie rods, strikes in the further path to a tie rod and opens the friction clutch in the following way.

It is also particularly advantageous if the toothing of the dog clutch is designed as a sawtooth toothing. This advantageously only transmits moments in one direction. In particular, the force-bearing flanks are made steep and thus the reaction forces can be kept low on the actuation system

The present invention will be explained in more detail below with reference to preferred exemplary embodiments in conjunction with the associated figures:

Showing:

Figure 1 is a schematic view of a drive train topology according to the prior

Technology,

FIG. 2 shows a table for explaining the operating states of the couplings of the drive train topology according to FIG. 1,

FIG. 3 shows a schematic view of a drive train topology according to the invention,

FIG. 4 shows a table for explaining the operating states of the couplings of the drive train topology according to FIG. 3,

FIG. 5 shows a schematic view of a drive train topology according to the invention,

6 shows a table for explaining the operating states of the couplings of the drive train topology according to FIG. 5, FIG.

FIG. 7 is a diagram for explaining the operation of the actuator;

FIG. 8 shows a sectional view of an actuating device,

Figure 9 is a perspective view of an actuator, and

Figure 10 is a perspective view of an actuator. FIG. 3 shows a parallel hybrid (P2) powertrain topology for manual (MT) or automated manual transmissions (AMT). In the Antnebsstrangtopologie 10 of Figure 3 for manual or automated manual transmission 1 1 is a freewheel 12 in Drehrmo- ment flow between the engine 14 and the traction engine 13. The starting clutch (K1) is located between the traction machine 13 and gear 1 1 in the drive train. Furthermore, a starter 15 or belt starter generator can be present, so to speak as a small traction machine. However, this small traction machine 15 can also be omitted if by means of the traction engine 13 of the engine 14 is started.

Likewise, a damping element 16 may be provided in the drive train. In this case, the number of damping elements 16 may be different and these may also be arranged at different positions in the drive train, such as disc damper a clutch disc of the clutch K1 or as a dual mass flywheel.

The Antnebsstrangtopologie has various operating conditions of the freewheel 12 (FL) and the clutch (K1), see the table of Figure 4. In this case, six operating states are distinguished, which are shown in the table of Figure 4.

In the table, a 0 means that the freewheel or the clutch does not transmit torque and a 1 that the freewheel or the clutch transmit torque.

For example, for hybrid driving with an internal combustion engine and an electric traction machine, the clutch K1 is engaged, while the freewheel FL locks in the traction mode and does not lock in the overrun mode, see state # 1. The same applies to operating mode # 6 for parking.

When changing gear in the transmission 1 1, the freewheel 12 and the clutch K1 are disengaged, see the states # 4 and # 5.

When driving electrically by means of the traction machine 3, the freewheel 12 is not locked and the clutch K1 is engaged, see operating state # 2.

When charging in the state of the vehicle, the freewheel 12 is locked and the clutch K1 is disengaged, see operating state # 3. Since no drag torques can be available at the output, in some situations a critical condition can arise, see flashes at # 1 and # 6 in the table of FIG. 4.

In overrun of the vehicle and when the battery is fully charged, so no

Recuperation is possible, no drag torque is displayed, see # 1. This can be avoided by adding an additional consumer advantageous with a consumption power greater than the recuperation, such as a heating element in the cooling water, an air conditioning compressor or the like. Also, a corresponding brake management or dimensioning of the brake of the vehicle can be used.

When parking a vehicle with a manual gearbox without an electronic parking lock, the vehicle can roll away in one direction when parking with the gear engaged, see # 6. This can be avoided by an electronic parking brake or electric parking brake.

FIG. 5 shows a parallel hybrid (P2) powertrain topology for manual (MT) or automated manual transmissions (AMT). In the Antnebsstrangtopologie 20 of Figure 3 for manual or automated manual transmission 21 is a freewheel 22 in Drehrmo- ment flow between the engine 24 and the traction engine 23. The starting clutch (K1) is located between the traction engine 23 and transmission 21 in the drive train. Furthermore, a mechanical coupling element 25 (KE) in the torque flow is arranged parallel to the freewheel 22. Also, a starter 26 or belt starter generator can continue to be present, so to speak as a small traction machine. However, this small traction machine 26 can also be omitted if the combustion engine 24 is started by means of the traction machine 23.

Likewise, a damping element 27 may be provided in the drive train. In this case, the number of damping elements 27 may be different and these may also be arranged at different positions in the drive train, such as disk damper a clutch disc of the clutch K1 or as a dual mass flywheel.

The Antnebsstrangtopologie has various operating states of the freewheel 22 (FL), the coupling element 25 and the clutch (K1), see the table of Figure 6. In this case, seven operating states are distinguished, which are shown in the table of Figure 6. In the table, a 0 means that the one-way clutch, the coupling member, or the clutch does not transmit torque and that the one-way clutch, the coupling member or the clutch transmits torque.

For example, for hybrid driving with an internal combustion engine and an electric traction machine, the clutch K1 is engaged, while the freewheel FL locks in traction mode and does not lock in the overrun mode, see state # 1. The coupling element 25 is disengaged.

In hybrid driving with internal combustion engine in overrun and drag torque and with electric traction engine clutch K1 and the coupling element 25 is engaged while the freewheel does not lock, see Condition # 2.

For the operating state # 7 for parking, the same applies to the freewheel and the

Clutch K1, wherein the coupling element 25 is engaged.

When changing gear in the transmission 21, the coupling element 25 and the clutch K1 are disengaged, see the states # 5 and # 6. The freewheel 22 is locked or not, depending on pulling or pushing operation.

When driving electrically by means of the traction machine 23, the freewheel 22 is not locked, the coupling element 25 is disengaged and the clutch K1 is engaged, see operating state # 3.

When charging in the state of the vehicle, the freewheel 12 is locked and the clutch K1 and the coupling element 25 are disengaged, see operating state # 4.

This topology has the advantage that the drag torque of the internal combustion engine 24 at the output, with closed coupling element 25, is available and the disadvantages of the prior art are not present. In addition, only a very small amount of space is required for this topology.

The actuator for actuating the clutch (K1) and the coupling element (KE) can be operated in a manual transmission (MT) via a so-called clutch-by-wire system. The Coupling element 25 can act positively or non-positively and be executed in any manner.

In addition to the starting clutch (K1), the coupling element 25 (KE) can also be actuated in this drive train topology 20. This can be realized by means of a sequentially operating actuator, see FIG. 7. The freewheel locks or unlocks itself, according to whether the vehicle is in pulling or pushing operation. With such a concept, full functionality can be enabled with a sequential actuator. FIG. 7 shows schematically a mode of operation of an actuator in which, depending on the actuator position, the clutch and / or the coupling element 25 are actuated. In a first position, the clutch K1 and the coupling element 25 are closed, that is engaged. In a second position, the clutch K1 is engaged and the coupling element 25 is disengaged, so opened. In a third position, the clutch K1 and the coupling element 25 are opened, that is disengaged.

Figures 8 to 10 show an embodiment of an actuator 100 according to the invention for actuating two clutches, such as a friction clutch 1 1 1 and a jaw clutch 1 17 as a coupling element.

The actuation of the friction clutch 1 1 1 and the dog clutch 1 17 via a

Lever system 103, on the inner pad, the actuating force of an actuator via a release system 150 acts. The lever system 103 is supported on the cover 108 of the friction clutch 1 1 1. Depending on the position of the disengagement system 150 and thus of the lever system 103 friction and jaw clutch 1 1 1, 1 17 are opened, the release system is fully disengaged or the friction clutch 1 1 1 closed and the jaw clutch 1 17 open, the release system is in center position or friction and jaw clutch 1 1 1, 1 17 are closed, the release system is fully engaged.

The lever system 1 13 is applied to its outer support on an intermediate plate 105 and transmits the Ausrückweg and the disengaging force with the appropriate leverage on the intermediate plate.

The intermediate plate 105 is connected via a spring system 106 to a tie rod 107. The spring system 106 may consist of any or various tension or compression springs depending on the connection side and thus effective direction. About the spring system 106 only forces are transmitted in the axial direction, no moments. In middle position, as shown, of Ausrückers is the spring system 106 under bias, so that the release system is not force-free in the center position and the actuator has a holding force must be applied.

Does the release system from the center position on, see the solid arrow, pivots the lever system 1 13 to its support point and moves the intermediate plate 105 in the direction of the tie rod support. The spring system 106 between the intermediate plate 105 and tie rod 107 is further stretched here. After a certain dead path 1 19, the intermediate plate 105 is applied to the tie rod 107. If the release system retreats further, the intermediate plate and tie rods are moved in the same way and the spring system is thus no longer tensioned. The opposite side of the tie rod 107 abuts against a plate spring 121, which thus follows the Zugankerbewegung at this point of support.

The inner support of the plate spring 121 is in the clutch cover. Depending on the design of the tie rod 107, the plate spring 121 can be designed both as a simple force edge without tongues or as a force edge with tongues arranged around the outer diameter. A composite of several disc springs is conceivable. To open the clutch, the disc spring force must be applied to the release system according to the lever ratio. Upon further pivotal movement of the lever thus the friction clutch is opened. The contact pressure on the clutch disc decreases and pad suspension and a leaf spring 109 between pressure plate and clutch cover, optionally arranged inside or outside, ventilate the friction clutch 1 1 1.

The described dead path between intermediate plate and tie rod must be provided in a clutch without wear adjustment due to the wear of the friction surfaces over the clutch life. With increasing clutch wear decreases this dead path, since the tie rod 107 moves in the direction of the friction clutch 1 1 1. In clutch systems with wear adjustment, this dead path changes or may possibly completely disappear.

As described above, the release system is in mid-position due to the biased spring system between the intermediate plate 105 and tie rod 107 under preload, which must be applied by the clutch actuator. When the force on the actuator is reduced, the release system is pushed back by the lever, therefore continues to engage and the intermediate plate 105 moves in the direction of the dog clutch according to the pivotal movement of the lever. The force of the spring system is supported on the one hand via the intermediate plate 105 on the lever, on the other hand via the tie rod 107 on the plate spring. The tie rod 107 remains in its position due to the lower power level of the spring system compared to the plate spring. Either the intermediate plate 105 or the lever abuts in its movement in the direction of the coupling against pressure fingers 120, which may be part of a pressure pot 1 15 or may be executed as individual parts. The force of the relaxing spring system is transmitted via these pressure fingers on a ring 1 16, which forms the movable side of a dog teeth. This ring 1 16 is therefore charged with the spring force of the relaxing spring system and moves according to the movement of the lever system and the intermediate plates 105 and the jaw clutch 1 17 closed.

The toothed ring 1 16 is in turn connected by means of leaf springs 1 14 with a co-rotating, axially fixedly positioned component, in this case a support wall 1 13. In the fully engaged state, the dog clutch 1 17 is closed and acted upon by the residual force of the spring system between the intermediate plate 105 and tie rod 107 minus the leaf spring force on the toothed ring.

The leaf springs transmitted in the case of a positive axial toothing transmitted via the positive coupling coupling moments. When opening the dog clutch 1 17 these leaf springs pull back the toothed ring until it hangs on a fixed stop, in this case formed by the support wall, and thus lift the lever system or the intermediate plate of the pressure fingers.

The maximum acting release force is determined by the disc spring and the leverage. The spring travel of the spring system is limited due to the introduction between tie rods and intermediate plate 105 on the dead path of the wear reserve and the closing path of the dog clutch 1 17. It does not have to be laid out the entire way the outer lever support. Alternatively, the spring system for closing the jaw clutch 1 17 between the intermediate plate 105 and clutch cover can be arranged. In this case, in addition to the design of the spring system, the release stroke of the friction clutch 1 1 1 must be considered.

In order to keep the force to hold the dog clutch 1 17 and thus the forces in the spring systems as low as possible, a sawtooth toothing is provided in the solution shown here. This is possible because only one moment direction should be transmitted. The Flanks over which the circumferential forces are transmitted, can thus be carried out steeply and the axially acting reaction forces in the toothing are kept low.

When torque reversal lift the steep edges due to the flat edges in the opposite direction from each other and opening the jaw clutch 1 17 under low power level is possible. As an alternative axially acting positive coupling a toothing with conical teeth can be provided. This can be designed free of play. As an alternative to an axial form-locking coupling, a coupling can be provided in which two toothed carrier are connected by means of a sliding sleeve.

In the design of the lever system several variants are conceivable. Thus, individual levers which are hung on the clutch cover or support ring are usable. Alternatively, a lever spring can be used with force margin, which can act depending on the size and installation supporting the closing spring system, or may be designed so that can be dispensed with the closing spring system, since all closing forces are applied by the lever spring.

The clutch cover is connected to the rotor carrier 102 of the electric machine, such as screwed, riveted or the like.

The coupling system with actuation system described allows a space-efficient and cost-effective design of P2 (parallel) hybrid head applications. Since only one unidirectional actuator system is used to operate two clutches, costs may be saved. Such an actuation system can also be used in other applications with two couplings.

Claims

claims

1 . Hybrid powertrain topology with an internal combustion engine and an electric traction machine and a downstream transmission in the torque flow, characterized in that in the torque flow between the engine and the traction machine, a freewheel and between the traction machine and the transmission, a clutch, in particular as a starting clutch, is arranged.

2. powertrain topology according to claim 1, characterized in that in the torque flow parallel to the freewheel, a mechanical coupling element is provided.

3. powertrain topology according to claim 1 or 2, characterized in that a damper is arranged in the torque flow between the freewheel and the internal combustion engine and / or after the freewheel.

4. powertrain topology according to claim 1, 2 or 3, characterized in that the coupling comprises a clutch disc, wherein a damper is arranged in the clutch disc.

5. powertrain topology according to any one of the preceding claims, characterized in that an actuator is provided, by means of which the coupling and the coupling element can be actuated.

6. actuating device for actuating two clutches or a clutch and a coupling element with an actuator, in particular a drive train topology according to one of the preceding claims 1 to 5.

7. Actuator according to claim 6 comprising an electric machine, a friction clutch and a dog clutch, wherein the friction clutch and the dog clutch are arranged radially within the electric machine.

8. Actuating device according to one of claims 6 or 7, characterized in that a lever system is provided, by means of which the actuation of the friction clutch and the dog clutch takes place.

9. Actuator according to claim 8, characterized in that an actuator is provided, which exerts an actuating force on a release system, wherein depending on the position of the release system and thus the lever system, the friction and dog clutch are open or the friction clutch is closed and the dog clutch open is or friction and dog clutch are closed.

10. Actuating device according to claim 9, characterized in that the actuation is unidirectional.