KR102663460B1 - Clutch unit, hybrid module and drive train - Google Patents

Abstract

The present invention relates to clutch devices, hybrid modules, and drive trains for automobiles. The clutch device includes a separation clutch (10) capable of transmitting torque from the internal combustion engine to the clutch device and capable of separating the clutch device from the internal combustion engine; a coupling element (43) for mechanically coupling the electric machine (90) to generate drive torque; and a main torque transmission element, in particular a double clutch device, capable of transmitting torque from the coupling element of the electric machine and/or from the separating clutch 10 to the drive train, wherein the output side of the main torque transmission element is connected to the shaft ( 40), in particular coupled with a hollow shaft, which forms a coupling element 43 for mechanically coupling the electric machine 90. Using the clutch device proposed herein, a device is provided that combines the advantages of a substantially externally arranged electric machine with reduced friction losses and savings in axial installation space.

Description

Clutch unit, hybrid module and drive train

The present invention relates to a clutch device and hybrid module for automobiles such as passenger cars, trucks or other commercial vehicles for coupling to an internal combustion engine and transmission, and to a drive train for automobiles equipped with the hybrid module according to the present invention. It's about.

The hybrid module typically includes a coupling device for mechanically coupling the internal combustion engine, a separation clutch capable of transmitting torque from the internal combustion engine to the hybrid module and separating the hybrid module from the internal combustion engine, and a rotor to provide driving torque. an electric machine for generating, and a main torque transmission element capable of transmitting torque from the electric machine and/or from the separating clutch to the drive train, for example another clutch device, usually a double clutch device. The double clutch device includes a first partial clutch and a second partial clutch. Each deployed clutch is assigned a respective actuation system.

Electric machines enable electrical drive, increased power for internal combustion engine operation, and regenerative braking. The separation clutch and its operating system provide for coupling or decoupling of the combustion engine.

If the hybrid module is integrated into the drive train so that it is located between the combustion engine and the transmission in the direction of torque transmission, the combustion engine, the hybrid module, the double clutch with its own operating system and the transmission must be arranged in series or side by side in the vehicle. .

Depending on how the combustion engine and electric machine are integrated within the drive train, different vehicle characteristics can be achieved. For hybrid vehicles with double clutches, in particular the P2 arrangement (the electric machine supplies its torque to the drive train between the separate clutch and the double clutch) and the P2.5 arrangement (the electric machine supplies its torque to the rear of the double clutch). supplied as a transmission) is common. Once the torque of the electric machine is introduced in front of the double clutch, this torque is equally available in all gears. In the P2.5 application, the arrangement of the electric machine and the introduction of torque from the electric machine in the transmission can in most cases be technically more easily implemented.

The electric machines of a P2 hybrid system are usually arranged concentrically or axially parallel to the transmission input shaft. For concentric arrangement, electric motors with a large diameter and axially short structure are used. Although this motor structure is somewhat complex, it can be matched to a typical installation space. The parallel-axis arrangement allows for a more cost-effective construction of electric machines, most of which can be integrated into existing vehicles with relative simplicity and ease. In the axis-parallel arrangement of electric machines, torque transmission between the concentric clutch and the axis-parallel electric motor is difficult.

For this purpose, a gear transmission has already been introduced, which directs the torque of the electric machine to the rest of the drive train between a (main) torque transmission element, which can for example be a clutch, a double clutch or a torque converter, and a separate clutch. This solution requires a certain structural complexity and assembly cost in the case of wet clutches, which are usually much lower than in the case of dry clutches.

On this basis, the task of the present invention is to provide a hybrid module that combines cost-effective manufacturing with durable construction and a small installation space.

The above problem includes a clutch device for an automobile for coupling an internal combustion engine and a transmission according to claim 1, a hybrid module for an automobile for coupling an internal combustion engine and a transmission according to claim 7, and a drive train according to claim 9. is solved by

Preferred embodiments of the clutch device according to the invention are specified in dependent claims 2 to 6. One preferred embodiment of the hybrid module according to the invention is specified in dependent claim 8. One preferred embodiment of the drive train according to the invention is specified in dependent claim 10.

The features of the claims may be combined in any technically reasonable type and manner, for which reference may also be made to the description from the following description and the features from the respective drawings, including supplementary embodiments of the invention.

The terms radial, axial and circumferential within the framework of the invention always relate to the axis of rotation of the clutch device or hybrid module.

The invention comprises a separation clutch capable of transmitting torque from an internal combustion engine to a clutch device, capable of disconnecting the clutch device from the internal combustion engine, and a coupling element for mechanically coupling an electric machine to generate drive torque. It is related to a clutch device for automobiles for coupling an internal combustion engine and a transmission. Additionally, the clutch device has a main torque transmission element, in particular a double clutch device, capable of transmitting torque from the coupling element of the electric machine and/or from the separating clutch to the drive train. The output side of the main torque transmission element is coupled to a shaft, in particular a hollow shaft, where the shaft forms a coupling element for mechanically coupling the electric machine.

The main torque transmission element, in particular the output side of the double clutch device, is capable of transmitting the torque introduced into the main torque transmission element back to an element or module arranged on the output side, for example a shaft provided according to the invention. It is an element or area.

This means that, in addition to a conventional transmission input shaft, the shaft according to the invention provided with a coupling element can also be designed to supply the torque provided from the electric machine or the main torque transmission element directly to the transmission. Torque can be transmitted in both directions through the coupling element and shaft. Torque can be transmitted from the electric machine to the main torque transmission element and from the main torque transmission element to the electric machine. The torque flow from the electric machine to the gear wheels forming the gear ratio of the transmission is preferably firstly outward from the transmission housing, that is, by means of a shaft arranged according to the invention, and then again inside the transmission housing, i.e. This is achieved by a connected transmission input shaft.

Preferably, the output side of the separation clutch is fixedly connected to rotate in unison with the input side of the main torque transmission element. In particular, the main torque transmission element is designed as a double clutch device. By connecting this double clutch device to the separation clutch, the torque provided from the internal combustion engine can be transmitted to the double clutch device via the input side of the separation clutch and from there via the output side of the separation clutch.

Preferably, the main torque transmission element is a double clutch device with a first partial clutch and a second partial clutch. However, alternatively a single clutch, torque converter and/or CVT transmission may also be used as the main torque transmission element.

In particular, the clutch device according to the present invention may be designed so that the clutch device has a housing and a seal between the housing and the shaft, in particular a second seal, whereby the internal space of the housing is controlled by the clutch. For assemblies to be connected to the output side of the device, for example to a transmission, it can be sealed, in which case the coupling element is located outside the internal space of the housing sealed by the seal. Correspondingly, the electric machine connected to the coupling element and any intermediately connected gear transmission are arranged in a lubricated gear chamber, the gear chamber being sealed against the space in the housing in which the clutch is arranged, so that the clutch is operated as a dry clutch. It can be implemented.

When the clutch device according to the invention is integrated into a drive train, two seals are preferably arranged to seal the coupling element from the inner space of the housing. In this case, there is one seal between the housing and the shaft and another seal between the shaft and the housing or transmission input shaft. When deploying two transmission input shafts, another seal is required between the two transmission input shafts. Compared to a drive train with the same number of transmission input shafts, but without the arrangement of the shafts according to the invention, only one additional seal is needed to seal the shafts.

Also preferably, a configuration is proposed in which the main torque transmission element is a double clutch device with a first partial clutch and a second partial clutch, in which case the clutch device forms a counter plate for the separating clutch and also for the partial clutch. It further includes a carrier assembly, in which case the carrier assembly is fixedly connected to rotate integrally with the shaft.

In an embodiment of the clutch device as described above, the cylinder of the operating unit of the clutch of the clutch device is at least partially formed on the radial outer surface of the shaft, and the shaft is connected to each operating unit for supplying operating fluid to the individual operating units. A configuration forming a flow channel is provided.

Additionally, the clutch device may be provided with a rotating penetration for each clutch to supply fluid to the individual actuating units via the shaft in a rotating state.

Another aspect of the present invention is a hybrid module for an automobile for coupling an internal combustion engine and a transmission, comprising a clutch device and an electric machine according to the present invention, wherein the rotor of the electric machine is mechanically coupled to the coupling element of the clutch device. By being coupled, the torque provided by the rotor of the electric machine can be transmitted to the coupling element.

In particular, the hybrid module between the rotor and the coupling element of the electric machine includes a transmission, for transmitting the torque provided by the electric machine to the shaft; Gear transmissions, especially spur gear transmissions; or a traction drive transmission such as a chain drive or belt drive.

Preferably, in this case the coupling element is arranged in the second axial end region of the shaft, which is implemented as a hollow shaft, so that the transmission is also arranged in this axial position. In this case, the electric machine can, if desired, be located outside the housing of the hybrid module. In this case, the transmission passes through the opening in the housing and acts on the coupling element. Accordingly, the component that transmits the torque of the electric machine to the coupling element is located substantially inside the transmission housing between the clutch device according to the invention or the remaining hybrid module and the transmission to be connected to the automobile drive train, in which case the electric machine is connected to the transmission or It is placed next to the hybrid module. However, the present invention is not limited to this embodiment, and the electric machine may be placed inside the transmission housing or inside the hybrid module housing.

In one alternative embodiment, a configuration is proposed in which the rotor of the electric machine is fixedly connected so as to rotate in one piece with a carrier assembly forming a rotor carrier. In this case, the axis of rotation of the electric machine is arranged coaxially with respect to the common axis of rotation of the clutch device according to the invention or the hybrid module according to the invention.

Another aspect of the present invention is a drive train for an automobile including an internal combustion engine, a hybrid module according to the present invention, and a transmission, in which case the hybrid module may be mechanically connected to the internal combustion engine and the transmission through a clutch of the hybrid module. It is connected.

Preferably, the drive train according to the invention is designed so that it has at least one transmission input shaft which mechanically couples or is capable of coupling the hybrid module with the transmission, in this case a shaft implemented as a hollow shaft. is sealed against the transmission input shaft by a first seal and against the housing by a second seal.

As a result, if a double clutch device is provided, two transmission input shafts are also provided, in which case the transmission input shafts are arranged coaxially, sealing of the hollow shaft and, if necessary, rotational mounting on the radially external transmission input shaft. You can.

Due to the axially offset arrangement of the seals of the hollow shaft in the transmission input shaft and housing, the rotating penetration fluidically coupled with the hollow shaft is functionally located in the transmission wet chamber or, likewise, contains lubricating oil, as the case may be, originating from the transmission. It is located within the exposed volume. This has the advantage that in case of inevitable leakage or slight leakage of the rotating penetration, the hydraulic fluid does not reach the clutch installation space.

In a preferred manner, the first rotating bearing is used to rotationally mount the hollow shaft. In a corresponding manner, the clutch is at least partially supported on said first rotating bearing. In this case, the first rotating bearing and, if necessary, the second rotating bearing can also be arranged in a space sealed by a seal, and as this space is opened towards the transmission, the individual rotating bearings can be wetted by transmission oil. This has the advantage that the clutch does not have to be supported by individually sealed grease lubricated bearings, which have lower efficiencies than oil lubricated bearings, especially when using dry clutches.

Additionally, due to the preferred axial distribution of the individual assemblies, only two bearings in total are required for operation and support of the three clutches. Due to the application of the rotating penetration, there is no need for a clutch actuation bearing that limits the maximum transmittable force. This enables high compression forces, so that the torque typical of hybrid vehicles can be transmitted by only one clutch disc per clutch. This means that the clutch device according to the invention or the hybrid module according to the invention can be configured axially very short, so that the hybrid module and the radially offset arranged electric machine are connected to adjacent assemblies, namely the internal combustion engine and It can be installed in a limited installation space of a car without the need to move the transmission axially.

In another preferred embodiment of the drive train, it is proposed that the drive train has one or more transmission input shafts that mechanically couple or can couple the hybrid module with the transmission, in this case the shaft as a hollow shaft. is sealed against the transmission input shaft by a first seal and against the housing by a second seal.

Additionally or alternatively, the shaft may be coupled to the transmission such that torque can be supplied from the shaft to the transmission. This means that, in addition to a conventional transmission input shaft, a shaft according to the invention formed with a coupling element can also be provided to supply torque provided from an electric machine or a main torque transmission element directly to the transmission.

The above-described invention is explained in detail below, based on related art, and the corresponding drawings showing preferred embodiments. It is noted that the invention is not in any way limited by the purely schematic drawings and that the embodiments shown in the drawings are not limited to the dimensions shown.

1 is a partial section of a cross-sectional view of a hybrid module according to the present invention in a first embodiment.
Figure 2 is a partial area of a cross-sectional view of a hybrid module according to the present invention in a second embodiment.
Figure 3 is a partial area of a cross-sectional view of a hybrid module according to the present invention in a third embodiment.
Figure 4 is a partial area of a cross-sectional view of the hybrid module according to the present invention in the fourth embodiment.

The shaft provided according to the invention is a hollow shaft 40 in the embodiments shown in the drawings.

Embodiments of the clutch device according to the present invention shown in each drawing all have a common basic structure.

The embodiments are all mechanically coupled on their respective input sides with a torsional vibration damper 200 connectable to the internal combustion engine, from which torque is transmitted to the input side 14 of the separation clutch 10. . Since the separation clutch 10 is fixedly connected to rotate integrally with the carrier assembly 70 on its output side 10, the torque transmitted from the separation clutch 10 can be introduced into the carrier assembly 70. The introduced torque is transmitted from the carrier assembly 70 via the partial clutches 20, 30 of the double clutch device used as the main torque transmission element 16, which are fixedly connected to rotate mechanically integrally with the carrier assembly, to the transmission. It is transmitted to the input shafts 120 and 121.

An additional shaft 40, in particular a hollow shaft, is fixedly connected for rotation in one piece with the carrier assembly 70, which protrudes from the housing 2 of the clutch device or hybrid module at the output side 6 of the clutch device. . The shaft 40 includes a coupling element 43 to which an electric machine 90 is connected to form a hybrid module. In the illustrated embodiment, the connection is realized by means of a transmission 100 between the electric machine 90 and the coupling element 43 . In this way, the torque provided from the electric machine 90 can be guided via the coupling element 43 of the shaft 40 to the carrier assembly 70, from which the corresponding partial clutches 20, 30 It can be supplied to the transmission input shafts 120 and 121 through .

Figure 1 shows a clutch device according to the invention and matched to applications in electric machines 90 and transmissions. The clutch device includes a double clutch device with a first partial clutch 20 and a second partial clutch 30 as main torque transmission elements.

The double clutch device includes a hollow shaft 40 rotatably mounted on one section of the housing 2 as a rotatable unit.

In addition, the carrier assembly 70 is fixedly connected to the hollow shaft 40 through a welded joint 77, and the carrier assembly 70 implements a counter plate 74 for the separation clutch 10, thereby forming a hollow shaft ( 40) is also connected to the output side of the separation clutch 10.

The section of the housing 2 supporting the hollow shaft 40 is formed as a tubular body 64 and includes a channel 3 for the first partial clutch 20, a channel 4 for the separating clutch 10 and It includes a channel (5) for the second partial clutch (30). These channels 3, 4, 5 are a flow channel 45 for the separating clutch 10, a flow channel 46 for the second partial clutch 30 and a flow channel for the first partial clutch 20. (47) and corresponding rotational penetrations 60 for the separating clutch 10, a rotational penetration 61 for the first partial clutch 20 and a rotational penetration for the second partial clutch 30. It forms part 62.

Through the rotating penetrating portions 60, 61, 62, fluid is guided to the operating unit of the separation clutch 50, the operating unit of the first partial clutch 51, and the operating unit of the second partial clutch 52, respectively. These actuating units are located on the radially outer surface 44 of the hollow shaft 40 .

The actuating units 50 , 51 , 52 are piston/cylinder assemblies, in which case the radial inner surface 56 and the end surfaces 57 of the cylinder 53 are at least partially radially aligned with the hollow shaft 40 . It is formed by the outer surface 44.

Furthermore, the cylinder 53 also forms a compensating cylinder 55. The centrifugal force due to the rotational speed causes the same pressure rise in the cylinder 53 and in the compensating cylinder 55 disposed on the other side of the piston, so that the axial force exerted by the piston 54 on the clutch is determined by the clutch rotational speed. will not be influenced by

Since the electric machine 90 is not arranged concentrically with respect to the clutch and the axial clutch installation space is therefore not limited, the entire clutch device and, as a result, the hybrid module including the clutch device are also made very short in the axial direction. It can be.

This implementation is such that in the clutch device according to the invention, the separate clutch 10 and the two partial clutches 20, 30 of the double clutch device are each implemented as single-plate clutches and are compactly fixed directly to a common carrier assembly 70. The carrier assembly is supported by identically forming counter plates 74, 75, 76 for all three clutches.

The separation clutch 10 is located immediately next to a torsional vibration damper 200, preferably designed as a dual mass flywheel, and includes a clutch disc 11 connected to the torsional vibration damper, which clutch disc is a pressure plate of the separation clutch ( 12) can be pressed towards the counter plate 74 formed by the carrier assembly 70.

The pressure plate 12 operates through a tie rod 13 connected to a piston 54 arranged to rotate together on the hollow shaft 40.

In this case, the counter plate 74 of the separation clutch 10 is formed by a substantially U-shaped profile 71 of the carrier assembly 70, the first leg 72 of the profile of the separation clutch 10 ) and the function of the counter plate 74 of the second partial clutch.

The clutch discs of the partial clutches 21 and 31 of the double clutch device are inside the carrier assembly 70 and are pressed against the counter plates 75 and 76 by pressure plates 22 and 32 assigned to these partial clutches, respectively. These counter plates are formed as a carrier assembly 70.

For this purpose, the pressure plate of the first partial clutch 22 is pulled by the tie rod 23, and the pressure plate of the second partial clutch 32 is pressed by the pressure port 33. Actuating force is provided for all three clutches by pistons 54 arranged to rotate together on a hollow shaft.

The piston 54 is supplied with hydraulic fluid through rotating penetrations 60 , 61 , 62 on the radial inner surface of the hollow shaft 48 .

The carrier assembly 70 of the clutch and at least a section of the cylinder 53 , such as the cylinder housing or cylinder wall of the piston cylinder unit of the clutch actuating system, are supported on the hollow shaft 40 . The hollow shaft is again mounted on the tubular body 64 of the rotating penetration, which is connected to the transmission housing 2 or is also formed by the transmission housing 2.

The hollow shaft 40 is sealed against the housing 2 on the side facing the transmission by a second seal 131, for example in the form of a shaft seal ring, and on the side facing the combustion engine by a first seal 130. By being sealed against the first transmission input shaft 120 , the hollow shaft 40 forms a boundary between the clutch and transmission housings 2 filled with different media/fluids. This also applies if sealing of the hollow shaft to the tubular body 64 of the rotating penetrations 60, 61, 62 is implemented.

There is a second transmission input shaft 121 inside the radial direction of the first transmission input shaft 120 implemented as a hollow shaft. The first transmission input shaft 120 is fixedly connected to rotate integrally with the first partial clutch 20, and the second transmission input shaft is fixedly connected to rotate integrally with the second partial clutch 30.

The bearings of the first transmission input shaft 120 lie inside an area wetted by transmission oil. This simplifies bearing design and reduces bearing friction and bearing losses. Shaft 40 and transmission input shaft 120 are supported on different bearings.

The seals 63 of the rotating penetrations 60, 61, 62, which are used to transfer the working fluid of the clutch from the stationary part of the rotating penetration to the rotating part, are also inside the area that functionally belongs to the transmission. If a small mixing of working fluid (eg hydraulic oil) and transmission oil is allowed, or if the transmission oil is equally used as clutch operating fluid, small leaks from the rotating penetrations 60, 61, 62 can be tolerated. This allows the use of few and additional low-friction seals (63) in the rotating penetrations, which reduces the friction losses of the hybrid module and increases the efficiency of vehicles equipped with the hybrid module. . The co-rotating pistons 54 arranged on the radially outer surface 44 of the hollow shaft 40 likewise act to reduce friction, since the co-rotating actuating pistons cause the actuating piston and the actuating piston to rotate together. This is because there is no need for operating bearings between the assigned clutches.

In order to ensure that the force action of the clutch is not affected by the clutch rotation speed, a compensating cylinder 55 is substituted for each actuating cylinder 53. As the rotational speed increases, the hydraulic pressure increases in the same way by the centrifugal force acting on the fluid in the actuating cylinder 53 and in the compensating cylinder 55, so that the effect of the rotational speed of the two cylinders is canceled out. The fluid supply that ensures that the compensating cylinder 55 is always filled with fluid is not shown in FIGS. 1 and 2 . The fluid supply to the compensating cylinder 55 must be carried out at a consistently low pressure. All three compensating cylinders 55 can be supplied with fluid via a common fluid supply, for example a rotating penetration. However, the fluid supply to the compensating cylinder 55 must be separate from the fluid supply to the actuating cylinder 53.

In this case, the present invention is not limited to the arrangement of the compensating cylinder 55; rather, the present invention can be implemented without such compensation, as long as no adverse centrifugal force is generated and sufficiently accurate clutch control can be performed.

The illustrated transmission 100 may be a gear transmission with an illustrated gear wheel 101 , which acts on the coupling element 43 through an opening 102 in the housing 2 . Alternatively, a traction drive transmission may also be used, or a shaft may be used to transmit torque as a component of the transmission. Additionally, the rotor of the electric machine 90 may be fixedly connected to rotate integrally with the pinion, which is directly engaged with the coupling element 43.

Furthermore, unlike the illustrated embodiment, the electric machine 90 can also be arranged in a bent form with respect to the rotation axis 1 of the hybrid module, in which case a suitable transmission, for example a bevel gear transmission, can compensate for the angular deviation. there is.

Figure 2 clearly shows that the triple clutch concept according to the invention with rotating penetrations can also be used for various arrangements of the electric machine 90. In this case, Figure 2 shows a hybrid module with an electric machine 90 arranged concentrically around the clutch. Here too, the advantages of the concept according to the invention are revealed, in particular the compact structure and the reduction of friction and bearing losses. A wide and stable bearing base with oil-lubricated rotary bearings 80, 81 has a very particularly advantageous effect, since the first rotary bearing arranged in the first axial end region 41 of the hollow shaft 40 Rotating bearings 80 , 81 with a second rotating bearing 81 disposed in the second axial end region 42 of the hollow shaft 80 and opposite thereto, rotate the rotor carrier 110 . This is because a stronger load is received by the rotor of the electric machine 90, which is mechanically connected to the forming carrier assembly 70.

The embodiments shown in Figures 1 and 2 show all single-plate clutches implemented as direct-acting clutches. This allows for a very compact installation space in the axial direction. However, unlike the illustrated embodiments, the clutch may also be designed as a multi-plate clutch and/or as a clutch with force reinforcing elements (eg levers). Additionally, the clutch can be realized not only as an active open clutch but also as an active closed clutch. Various clutch concepts can be combined into a double or triple clutch as desired. Furthermore, the torque converter may even take charge of the function of the separation clutch 10 or the main torque transmission element.

In the embodiments shown in FIGS. 3 and 4, unlike the embodiments shown in FIGS. 2 and 3, the carrier assembly 70 is connected to the output side 15 of the separation clutch 10 in a rotationally fixed manner. Includes an intermediate shaft 78. The intermediate shaft 78 forms a counter plate 75 of the first partial clutch 20 and a counter plate 76 of the second partial clutch 30 of the double clutch device, which are used as the main torque transmission element 16. transferred to the area where

Figure 3 shows a clutch device according to the invention for a P2-hybrid module. This clutch device further comprises a support wall 7 as part of the housing 2 , within which an operating unit 50 of the separating clutch 10 , an operating unit of the first partial clutch 20 51 and the operating unit 52 of the second partial clutch 30 are received.

The double clutch device, which serves as the main torque transmission element 16, is supported on the intermediate shaft 78 of the carrier assembly 70. By means of the carrier assembly 70 shown in Figure 3, the clutch disk 11 of the separation clutch 10; intermediate shaft (78); Counter plates 75, 76 of the first partial clutch 20 and the second partial clutch 30; and shaft 40; are fixedly connected to each other to rotate integrally. The electric machine 90 is likewise mechanically connected to these parts so as to rotate integrally, but in a coupled state with the transmission 100 .

The transmission 100 is realized by a gear wheel 101 meshing with a pinion 93 on the rotor 91 of the electric machine 90 and a coupling element 43 on the shaft 40 . The transmission 100 allows the electric machine 90 to operate in a different rotational speed band than the combustion engine to which it is connected. It is reasonable for the electric machine 90 to be connected to rotate slightly faster than the combustion engine. Due to this, the electric machine 90 can be implemented geometrically more compact for the required output.

In this case, the invention is not limited to the illustrated embodiment with the transmission 100 realized by a gear wheel 101, but rather almost arbitrary other types of torque transmission elements can be used with the shaft 40 and the electric machine ( 90) can be placed between. Hereby, for example, a plurality of gear wheels, belt means, traction drive transmission or shafts can also be used for torque transmission. Alternatively, the pinion 93 on the rotor 91 of the electric machine 90 engages directly with the teeth of the coupling element 43 of the shaft 40, thereby eliminating the need for an intermediate gear wheel 101. , and thereby directly connection of the electric machine 90 can be carried out.

Furthermore, the electric machines 90 need not necessarily be arranged parallel to the common axis of rotation 1 . Transmission 100 may be used to ensure torque transmission while compensating for an angled or oblique arrangement of the rotational axis of electric machine 90 with respect to shaft 40 .

In the embodiment shown in FIG. 3 , on the input side of the main torque transmission element 17 the carrier assembly 70 is connected to the housing 2 or to the support wall of the housing 2 via two first rotating bearings 80. 7) is supported. On the output side of the main torque transmission element 18 , a shaft 40 is also supported in the housing via a second rotary bearing 81 , which is fixedly connected for rotation in one piece with the carrier assembly 70 . In addition to the second rotating bearing 81, there is a second seal 131 facing the inside of the housing 2.

This ensures that the second rotating bearing 81 is in the internal space of the connected transmission (not shown in the figure) substantially wetted with lubricant.

Figure 4 shows one embodiment of a clutch device according to the invention with an alternative variant bearing of the first transmission input shaft 120. Instead of supporting all three shafts 40, 120, 121 against each other, finally the outer shaft 40 is supported on the housing 2 by a second rotating bearing 81, as shown in FIG. 3. By disposing one or more bearings acting radially or radially and axially, respectively, between the shafts 40, 120, and 121, the shaft 40 and the first transmission input shaft 120 Each is supported directly on the housing (2). This means that the extension portion 8 attached to the housing 2 wraps around the transmission side end of the shaft 40 and/or is located axially behind the shaft 40 on the output side, wherein the third rotary bearing and This is made possible by forming a bearing point 9 for the first transmission input shaft 120.

By means of the clutch device proposed here or the hybrid module proposed herein, a device is provided that combines the advantages of a substantially externally arranged electric machine with reduced friction losses and savings in axial installation space.

1: Common axis of rotation
2: Housing
3: Channel for first part clutch
4: Channel for disconnect clutch
5: Channel for second part clutch
6: Output side of clutch device
7: Support wall
8: extension
9: Bearing point
10: Separation clutch
11: Clutch disc of separation clutch
12: Pressure plate of separation clutch
13: Tie rod of split coupling
14: Input side of separation clutch
15: Output side of separation clutch
16: Main torque transmission element
17: Input side of main torque transmission element
18: Output side of the main torque transmission element
20: first part clutch
21: Clutch disc of first partial clutch
22: Pressure plate of first partial clutch
23: Tie rod of first partial clutch
30: second part clutch
31: Clutch disc of second partial clutch
32: Pressure plate of second partial clutch
33: pressure port of second partial clutch
40: shaft, hollow shaft
41: first axial end region
42: second axial end region
43: Coupling element
44: Radial outer surface
45: Flow channel for separation clutch
46: flow channel for first partial clutch
47: flow channel for second partial clutch
48: Radial inner surface
50: Operating unit of the separation clutch
51: Actuating unit of the first partial clutch
52: Actuating unit of the second partial clutch
53: cylinder
54: piston
55: Compensating cylinder
56: Radial inner surface
57: end face
60: Rotating penetration part of the separation clutch
61: rotational penetration portion of the first partial clutch
62: rotational penetration portion of the second partial clutch
63: Seal in rotating penetration
64: tubular body
70: Carrier assembly
71: U-shaped profile
72: 1st leg
73: 2nd leg
74: Counter plate for disconnect clutch
75: Counter plate for first part clutch
76: Counter plate for second part clutch
77: Weld joint
78: middle shaft
80: first rotating bearing
81: second rotating bearing
82: Third rotating bearing
90: electric machine
91: rotor
92: stator
93: pinion
100: Transmission
101: gear wheel
102: opening
110: rotor carrier
120: first transmission input shaft
121: second transmission input shaft
130: first seal
131: second seal
200: Torsional vibration damper

Claims (10)

An automobile clutch device for coupling an internal combustion engine and a transmission,
- a separation clutch (10) capable of transmitting torque from the internal combustion engine to the clutch device and capable of separating the clutch device from the internal combustion engine,
- a coupling element (43) for mechanically coupling the electric machine (90) to generate a driving torque, and
- a clutch device comprising a main torque transmission element capable of transmitting torque from the electric machine and/or from the separating clutch (10) to the drive train,
The clutch device comprises a shaft (40), the shaft (40) forming a coupling element (43) for mechanically coupling the electric machine (90),
A clutch device has a housing (2) and has one or more seals between the housing (2) and the shaft (40), whereby the inner space of the housing (2) is connected to the assembly to be connected to the output side of the clutch device. Clutch device, characterized in that the coupling element (43) is located outside the internal space of the housing (2) sealed by the seal. The clutch device according to claim 1, characterized in that the output side of the separation clutch (10) is fixedly connected to rotate integrally with the input side of the main torque transmission element. delete 3. The method according to claim 1 or 2, wherein the main torque transmission element is a double clutch device with a first partial clutch (20) and a second partial clutch (30), the clutch device for the separating clutch (10) and also It further includes a carrier assembly (70) forming counter plates (74, 75, 76) for the partial clutches (20, 30), wherein the carrier assembly (70) is fixedly connected to rotate integrally with the shaft (40). Characterized by a clutch device. An automobile clutch device for coupling an internal combustion engine and a transmission,
- a separation clutch (10) capable of transmitting torque from the internal combustion engine to the clutch device and capable of separating the clutch device from the internal combustion engine,
- a coupling element (43) for mechanically coupling the electric machine (90) to generate a driving torque, and
- a clutch device comprising a main torque transmission element capable of transmitting torque from the electric machine and/or from the separating clutch (10) to the drive train,
The clutch device comprises a shaft (40), the shaft (40) forming a coupling element (43) for mechanically coupling the electric machine (90),
The main torque transmission element is a double clutch device with a first partial clutch 20 and a second partial clutch 30, the clutch device being a counter for the separating clutch 10 and also for the partial clutches 20, 30. It further includes a carrier assembly 70 forming plates 74, 75, and 76, wherein the carrier assembly 70 is fixedly connected to rotate integrally with the shaft 40,
The cylinder 53 of the actuating unit 50 , 51 , 52 of the clutch 10 , 20 , 30 of the clutch device is at least partially formed on the radial outer surface 44 of the shaft 40 , Clutch, characterized in that one flow channel (45, 46, 47) is formed for each operating unit (50, 51, 52) for supplying working fluid to the individual operating units (50, 51, 52). Device. 6. The method of claim 5, wherein the clutch device has one rotation for each clutch (10, 20, 30) to supply fluid to the individual actuating units (50, 51, 52) via the shaft (40) in rotation. A clutch device, characterized in that it has penetration parts (60, 61, 62). A hybrid module for an automobile for coupling an internal combustion engine and a transmission, comprising a clutch device according to claim 1 or 2 and an electric machine (90),
Hybrid module, wherein the rotor of the electric machine is mechanically coupled with the coupling element (43) of the clutch device, such that the torque provided by the rotor of the electric machine (90) can be transmitted to the coupling element (43). 8. The transmission (100) according to claim 7, wherein a hybrid module between the rotor of the electric machine (90) and the coupling element (43) is used to transmit the torque provided by the electric machine (90) to the shaft (40). A hybrid module comprising: A drive train for an automobile having an internal combustion engine, a hybrid module according to claim 7, and a transmission,
A drive train in which a hybrid module can be or is mechanically connected to an internal combustion engine and a transmission through a clutch (10, 20, 30) of the hybrid module. 10. The method of claim 9, wherein the drive train has one or more transmission input shafts (120) mechanically coupling or capable of coupling the hybrid module with the transmission, and the shaft (40) as a hollow shaft has a first seal ( Drive train, characterized in that it is sealed against the transmission input shaft (120) by means of a second seal (130) and against the housing (2) by a second seal (131).

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