阅读说明：本技术 双离合器变速器组件以及机动车 (Double-clutch transmission assembly and motor vehicle ) 是由 M·罗斯克 J·卡尔滕巴赫 T·罗泽迈尔 J·帕夫拉克维奇 R·库伯茨克 于 2018-02-19 设计创作，主要内容包括：本发明涉及一种用于双离合器变速器的双离合器组件,该双离合器组件具有第一离合器和第二离合器,其特征在于,所述第一离合器的输出端与所述第二离合器的输入端连接。本发明还涉及一种双离合器变速器组件。本发明还涉及一种机动车。(The invention relates to a dual clutch assembly for a dual clutch transmission, having a first clutch and a second clutch, characterized in that the output of the first clutch is connected to the input of the second clutch. The invention also relates to a dual clutch transmission assembly. The invention also relates to a motor vehicle.)

1. Double clutch assembly (48) for a double clutch transmission having a first clutch (K0) and a second clutch (K1), characterized in that the output (16) of the first clutch (K0) is connected to the input (18) of the second clutch (K1).

2. The dual clutch assembly as claimed in claim 1, characterized in that the dual clutch assembly (48) is configured as a preassembled module.

3. The dual clutch assembly as claimed in claim 1 or 2, characterized in that the first clutch (K0) is a disconnect clutch for disconnecting the internal combustion engine (2) from the rest of the powertrain.

4. The dual clutch assembly as claimed in one of the preceding claims, characterized in that the second clutch (K1) is configured for connection with a transmission input shaft (22, 24).

5. The dual clutch assembly as claimed in one of the preceding claims, characterized in that the second clutch (K1) is designed for connection to two shafts (22, 24), in particular to two transmission input shafts (22, 24).

6. The double clutch assembly as claimed in one of the preceding claims, characterized in that the first clutch (K0) and the second clutch (K1) are arranged radially nested.

7. The dual clutch assembly as claimed in one of the preceding claims, characterized in that the input of the first clutch (K0) can be connected to the first drive unit (2).

8. The dual clutch assembly as claimed in one of the preceding claims, characterized in that it can be connected with a second drive unit (3).

9. The dual clutch assembly as claimed in one of the preceding claims, characterized in that the input (18) of the second clutch (K1) can be connected to the second drive unit (3).

10. The double clutch assembly as claimed in one of the preceding claims, characterized in that the clutches (K0, K1) are configured as multiplate clutches.

11. The dual clutch assembly as claimed in one of the preceding claims, characterized in that the output disk carrier of the first clutch (K0) and the input disk carrier of the second clutch (K1) have a common section.

12. A dual clutch transmission assembly having a dual clutch assembly, characterised in that the dual clutch assembly is constructed in accordance with one of the preceding claims.

13. Motor vehicle with a dual clutch transmission assembly, characterized in that the dual clutch transmission assembly (4) is constructed according to one of the preceding claims.

Technical Field

The invention relates to a dual clutch transmission assembly for a dual clutch transmission having a first clutch and a second clutch.

Background

Dual clutch transmissions are known in which two clutches are provided as a dual clutch module or dual clutch assembly between the engine and the transmission, which clutches are used to connect the internal combustion engine to in each case one transmission input shaft.

In order to compound a dual clutch transmission, it is also known to have an electric motor act on the transmission or on one or both transmission input shafts. In order to completely decouple the internal combustion engine from the drive train, a disconnect clutch is additionally required. In this case, configurations are known in which the clutch and the separating clutch are nested as a triple clutch assembly.

Disclosure of Invention

Starting from this, the object of the invention is to provide a dual clutch assembly with which a hybrid drive train can be achieved, but with low construction and manufacturing costs.

In order to solve this problem, it is proposed in a dual clutch assembly of the type mentioned at the outset that the output of the first clutch is connected to the input of the second clutch. In other words, this means that the first clutch is a separating clutch which is preferably used in hybrid drive, and the second clutch is used to establish a connection between the internal combustion engine or, in general, the first drive unit and the transmission. The two clutches form one module, while the third clutch, which is still required for connecting the engine to the second sub-transmission, is located elsewhere in the transmission housing.

The dual clutch assembly is advantageously designed as a preassembled module. That is, the first clutch and the second clutch are preassembled in the housing and assembled, for example, by being slipped onto the transmission input shaft. Correspondingly, even if the second partial transmission clutch is fitted directly next to the double clutch assembly, the double clutch assembly is not a triple clutch assembly. In particular, the design and assembly advantages are achieved by slightly modifying the known dual clutch module in such a way that the output of the first clutch is located at the input of the second clutch, rather than at one of the transmission input shafts, but otherwise the design is entirely acceptable. Therefore, no recalculation is required in terms of space requirements, manufacturing methods, or the like. These advantages are of course not only obtained when the dual clutch assembly is constructed as a preassembled module. In practice, however, the dual clutch assembly is used only as a preassembled module.

In the present invention, a clutch is understood to mean a clutch which can transmit the torque output by an engine, in particular an internal combustion engine and an electric motor, as a drive unit. This is merely used to further define the synchronizing device, which is sometimes also referred to as a shifting clutch. The shifting clutch can only absorb a torque that is much smaller than the torque output by the engine.

Preferably, the clutch is designed as a friction clutch.

As described, the first clutch is advantageously a separating clutch for separating the internal combustion engine from the rest of the drive train. Such a disconnect clutch is used as already described in hybrid transmissions in order to disconnect an internal combustion engine from a drive train.

As described, the second clutch may be configured for connection with the transmission input shaft. The second clutch is thus a shifting clutch or more precisely a power shifting clutch. Preferably, the second clutch can also be configured as a starting clutch.

In this embodiment, the dual clutch arrangement comprises a separating clutch and a starting clutch, wherein the output of the separating clutch is connected to the input of the starting clutch.

Preferably, the second clutch may be configured for connection with two shafts. By definition, this is two transmission input shafts or one transmission input shaft and one connecting shaft for the second powershift clutch.

Furthermore, the second clutch may be designed for connection to a transmission input shaft and the second powershift clutch or the third clutch. In this case, the output of the second clutch can be designed in particular for connection to a transmission input shaft and the second clutch. It is immaterial here whether the third clutch is located spatially in the vicinity of the double clutch assembly. As described, the output of the second clutch can also be connected to the second clutch, for example, via a connecting shaft or a transmission input shaft.

Advantageously, the first clutch and the second clutch may be arranged radially nested. In this case, the first clutch can advantageously be arranged radially on the outside and the second clutch can be arranged radially on the inside. In this case, the first clutch and the second clutch at least partially overlap in the axial direction.

Preferably, the input of the first clutch is connectable to the first drive unit. In this case, a damping device, such as a dual mass flywheel or a vibration absorber or the like, can be provided between the first drive unit, which is usually designed as an internal combustion engine, and the first clutch. The fact that the first clutch can be connected to the first drive unit means that the first clutch is designed at the input in such a way that the first clutch can be connected. Here, flanges, or toothed sections or the like may be mentioned.

Furthermore, the dual clutch assembly can be connected with the second drive unit. In particular, the input of the second clutch can be connected to the second drive unit. This also means that the output of the first clutch can be connected to the second drive unit, since the output of the first clutch is connected to the input of the second clutch.

Preferably, these clutches can be configured as multiplate clutches. Furthermore, the clutch can be designed to be wet-running. In the design of the multiplate clutch, the input and output can be designed as disk carriers.

Advantageously, the output disk carrier of the first clutch and the input disk carrier of the second clutch can have a common section. In this case, the inner disc carrier or the outer disc carrier can be referred to accordingly, as is further shown below.

Furthermore, the present invention relates to a dual clutch transmission assembly. The dual clutch transmission assembly is characterized in that it has a dual clutch assembly as described above.

Advantageously, the dual clutch transmission assembly may have a third clutch connecting the internal combustion engine with the transmission input shaft and disposed within the gear set housing. The third clutch is also a powershift clutch, like the second clutch, but the third clutch need not be designed as a starting clutch. The second and third clutches and the first clutch are in particular designed to transmit the entire torque provided by the first drive unit.

Advantageously, the third clutch may be disposed between two gear set planes. Here, the gear set plane generally refers to the axial region occupied by the gears of one or two gears. There is an axial spacing between the gear set planes, for example, in such a way that a shift element can be provided.

In this case, the third clutch can be arranged between the gear sets in the odd gears. Alternatively, the third clutch may be disposed between the gear sets of the even-numbered gears. Still alternatively, the third clutch may be disposed between the gear sets of the even-numbered gears and the odd-numbered gears. Each design has its own advantages and disadvantages. The arrangement between even and odd gear sets is preferred here. Irrespective of the precise arrangement of the gear sets, the third clutch can be arranged on the end of the hollow transmission input shaft. Typically, this is also the position of the third clutch between the even and odd gear set planes.

The reverse gear is in principle considered as an even-numbered gear, which applies here at least as long as the gear of the reverse gear is located on the transmission input shaft with the even-numbered gears. This arrangement is not always clearly implemented because it is partly considered to use two transmission input shafts or two countershafts to form the reverse gear. In a further alternative, it can therefore be provided that the third clutch is located between a gear set plane of the reverse gear and a further gear set plane, which can have even gears or odd gears.

instead of an arrangement between two gear set planes, the third clutch can be arranged downstream of the gear set planes on the transmission end side. In other words, the third clutch may be arranged on the end of the gear unit housing facing away from the engine.

Advantageously, the third clutch may surround one shaft. In an arrangement between the gear set planes, it is also possible for a third clutch to be provided between the shafts. The cavity normally present in the center of the third clutch can be utilized by pushing the third clutch onto the shaft. In this case, this includes the embodiment in which the third clutch is pushed onto the hollow transmission input shaft and then surrounds both shafts.

In a further embodiment, the third clutch may surround a plurality of shafts, here parallel, non-coaxial shafts. In the extreme case, the third clutch can be located on the inside of the transmission housing, but it is difficult to maneuver uniformly over the circumference due to the diameter achieved here. It is therefore preferred that the third clutch surrounds only one shaft.

Preferably, the dual clutch transmission assembly is designed in a countershaft configuration. This is for explanation only.

The invention also relates to a motor vehicle having a dual clutch transmission assembly and/or a dual clutch assembly. The motor vehicle is characterized in that the double clutch assembly and/or the double clutch transmission assembly are configured as described.

Drawings

Further advantages, features and details of the invention emerge from the following description of embodiments and the figures. In the drawings:

Figure 1 shows a motor vehicle in which the vehicle,

Figure 2 shows a schematic structure of a dual clutch transmission assembly in a first design,

Figure 3 shows a schematic structure of a dual clutch transmission assembly in a second design,

Figure 4 shows the double clutch assembly in a first design,

Figure 5 shows the double clutch assembly in a second design,

Figure 6 shows the double clutch assembly in a third design,

Figure 7 shows the double clutch assembly in a fourth design,

Figure 8 shows the dual clutch assembly in a fifth design,

Figure 9 shows a portion of a dual clutch transmission assembly in a first view,

FIG. 10 shows a portion of a dual clutch transmission assembly in a second design, an

FIG. 11 illustrates the dual clutch transmission assembly in a third view.

Detailed Description

Fig. 1 shows a motor vehicle 1 having a first drive unit 2, a second drive unit 3, a dual clutch transmission assembly 4 and a differential 5. The transmission housing 6 is generally composed of two parts, namely a clutch bell 7 and a gear unit housing 8 which accommodates the gear units. The clutch bell 7 and the gear unit housing 8 are usually flange-connected fixedly to one another, between which an intermediate wall 9 can be provided. The intermediate wall 9 is designed to be oil-tight, depending on whether the oil chamber of the clutch bell and the oil chamber of the gear unit housing are to be separated. In any event, the intermediate wall generally serves to support at least a portion of the shaft of the dual clutch transmission assembly 4.

The second drive unit 3, in particular in the form of an electric motor, acts here on the drive train either as can be indicated by the line 10 or by the line 12 shown in dashed lines. The interaction with one or both transmission input shafts is referred to herein as a P2 arrangement, and the interaction with the transmission itself is referred to as a P3 arrangement.

The clutches used to connect the first drive unit 2 to a respective one of the transmission input shafts of the dual clutch transmission assembly 4 are referred to below as clutches. The clutch used to disengage the internal combustion engine from the dual clutch transmission assembly 4 is referred to as disconnect clutch K0.

Fig. 2 shows a first embodiment of the dual clutch transmission assembly 4, namely as a gear set. The separator clutch K0 is coupled to the first drive unit 2. A damping device, such as a dual mass flywheel or a speed-adaptive vibration absorber, can be arranged between the first drive unit 2 and the separating clutch K0. In these embodiments, the disconnect clutch K0 also disconnects the first drive unit 2 from the rest of the drive train. In particular in the presence of a dual mass flywheel or a rotational speed-adaptive vibration absorber, the connection between the first drive unit 2 and the separating clutch K0 is also regarded as a direct connection, since the components mentioned should only reduce vibrations, but not cancel the connection between the drive unit 2 and the separating clutch K0.

Accordingly, the drive unit 2 is located at the input 14 of the separating clutch K0. While the output 16 of the separator clutch K0 is connected to the input 18 of the first clutch K1. The output of the first clutch K1 is coupled to the first transmission input shaft 22. The coupling is usually effected by means of a toothed segment. Fig. 2 shows a design of the transmission input shaft 22 as a hollow shaft. Thus, the separating clutch K0 can be connected to the input 26 of the second clutch K2 via the connecting shaft 24. The output 28 of the second clutch K2 is then connected to the second transmission input shaft 30, which is also designed as a hollow shaft and surrounds the connecting shaft 24. Different gear steps can be realized by means of the fixed gear 32, the loose gear 34 and the shift element 36. A gear set plane 38 and a gear set plane 40 are formed, wherein the gear set plane 38 is the gear set plane associated with the first transmission input shaft 22 and the gear set plane 40 is the gear set plane associated with the second transmission input shaft 30. The illustration of the gear set planes 38 and 40 is schematic here, since the illustration is intended to show only the presence of the gear set plane 38 (for example for even gears) and the gear set plane 40 (for example for odd gears). However, it should not be limited to a certain number of fixed gears on, for example, first transmission input shaft 22 or second transmission input shaft 30. The gear set 42 also comprises one or two countershafts 44 which interact with fixed gears 46 leading to the output or to the differential. The second drive unit 3 can be attached by means of a gear 48, which is arranged in fig. 2 between the separating clutch K0 and the first clutch K1. In this way, the second drive unit 3 can be connected to the two transmission input shafts, and the arrangement corresponds to the P2 configuration.

The design of the gear set 42 is basically arbitrary, and the dual clutch transmission assembly 4 is distinguished from the prior art in that the clutch K2 is arranged in the gear set housing 8, while the clutch K1 is arranged in the clutch bell 7. In the embodiment according to fig. 2, the clutch K2 is arranged downstream of the gear unit planes 38 and 40 on the transmission end side. The clutch is thus located at the end of the transmission housing 6 facing away from the motor.

Fig. 3 shows a similar embodiment to fig. 2. The statements made with respect to fig. 2 therefore also apply to fig. 3. The differences are set forth below.

In contrast to fig. 2, the clutch K2 is arranged between different gear set planes, specifically between the gear set planes 38 and 40, i.e. therefore between the gear set plane of the even gear and the gear set plane of the odd gear. Due to this arrangement, the second transmission input shaft 30 is also not designed as a hollow shaft and does not surround the connecting shaft 24. In other respects, the gear set 42 according to fig. 3 corresponds to the gear set 42 according to fig. 2.

FIG. 4 schematically illustrates a dual clutch assembly having a disconnect clutch K0 and a clutch K1. In this embodiment, the separating clutch K0 and the clutch K1 are arranged radially inside one another, with the separating clutch K0 being radially outside. The input 14 of the disconnect clutch K0 is formed by the inner disk carrier 50 of the disconnect clutch K0. The separating clutch K0 is designed as a multiplate clutch and accordingly has, in addition to the inner disk carrier 50, an outer disk carrier 52 and a disk stack of outer and inner disks which are interleaved with one another. The second drive unit 3 is attached to the outer disk carrier 52 of the separator clutch K0 and thus to its output 16. The input 18 of the clutch K1 is also connected to the output 16 in the form of the outer disk carrier 52. The input 18 of the clutch K1 is formed by the outer disk carrier 54. The output 20 of the clutch K1 is realized by means of an inner disk carrier 56, which inner disk carrier 56 connects the clutch K1 to the transmission input shaft 22. The transmission input shaft is designed as a hollow shaft. In the clutch K1 (which may also be designed as a multiplate clutch), the inner and outer disks forming the disk set are also located between the input and output or between the outer disk carrier 54 and the inner disk carrier 56.

Furthermore, the input 18 of the clutch K1 (i.e., the outer disk carrier 54) is connected to the connecting shaft 24. In this way, the second drive unit 3 can also be connected to the input of the clutch K2 via the input of the clutch K1.

In all embodiments, the transmission input shaft 30 can be understood as a multi-part shaft or the connecting shaft 24 can also be considered as a transmission input shaft. In this case, the shaft designated as transmission input shaft 30 in fig. 2 and 3 can also be considered as the first output shaft. Thus, strict functional definitions should not be associated with these terms, which are primarily used to distinguish the various components of the dual clutch transmission assembly 4.

The interconnection of the two input sides of the clutches of a dual clutch transmission is basically known. However, the disk holders are usually directly connected to each other and not via the connecting shaft 24. The connection of the input side 18 of the clutch K1 and the input side 26 of the clutch K2 by means of one shaft enables a spatially separate arrangement of the clutch K1 and the clutch K2. Such arrangements are not known from the prior art.

Fig. 5 to 8 show further embodiments of the dual clutch arrangement 48. In these embodiments, the clutch K1 is located radially outward and the separating clutch K0 is located radially inward. Depending on the design of the disk carrier, the second drive unit 3 can be realized here either on the transmission side or on the motor side, i.e. on each side of the first drive unit 2.

In the embodiment according to fig. 5, the inner disk carrier 50 forms the input 14 of the separating clutch K0, and the outer disk carrier 52 forms the output 16. In this case, the output 16 or the outer disk carrier 52 is connected to the input 18 of the clutch K1 (here the outer disk carrier 54) and to the connecting shaft 24. The output 16 of the disconnect clutch K0 is therefore connected not only to the input of the clutch K1 but also to the input of the clutch K2. The output of clutch K1 is formed by an inner disk carrier 56, which connects clutch K1 with transmission input shaft 22. As already explained several times, the connection is usually made by means of a plug-in toothing. In this embodiment, the second drive unit 3 is attached on the gear set side of the double clutch assembly 48. The attachment takes place here via the input of the clutch K1 and thus automatically via the output of the separator clutch K0.

Fig. 6 shows a design similar to fig. 5, which corresponds even to the design according to fig. 5 with regard to the separating clutch K0. However, in the clutch K1, the inner disc carrier 56 is used as the input 18 and the outer disc carrier 54 is used as the output 20. The second drive unit 3 can therefore also be arranged on the motor side, that is to say on the side of the drive unit 2. The output 20 of the clutch K1 is in turn connected to the transmission input shaft 22.

Fig. 7 shows a variant of the embodiment according to fig. 5, in which the input of the separating clutch K0 is formed by the outer disk carrier 52 and the output 16 of the separating clutch K0 is formed by the inner disk carrier 50. Since this embodiment is identical with respect to the clutch K1, the second drive unit 3 is in turn attached on the transmission side. In this embodiment, the output 16 of the disconnect clutch K0, i.e. the inner disk carrier 50, is also connected to the input 18 (here the outer disk carrier 54) of the clutch K1 and to the input 26 via the connecting shaft 24.

Fig. 8 shows a configuration in which the function of the inner disc holder and the outer disc holder as input and output, respectively, is exchanged compared to fig. 5. Accordingly, the outer disk carrier 52 forms the input of the separating clutch K0, and the inner disk carrier 50 forms the output 16. Accordingly, the input 18 of the clutch K1 is formed by the inner disk carrier 56 and the output 20 is formed by the outer disk carrier 54. Accordingly, the outer disk carrier 54 is connected to the transmission input shaft 22.

Common to all the embodiments of fig. 4 to 8 is: the output 16 of the disconnect clutch K0 (inner disk carrier 50 or outer disk carrier 52) is connected to the input 18 of the clutch K1 and to the input 26 of the clutch K2.

Fig. 9 shows a possible embodiment of the representation according to fig. 4, in which the separating clutch K0 is arranged radially on the outside and the clutch K1 is arranged radially on the inside. Here, details of the dual clutch transmission assembly are shown, which are basically known, except for the arrangement of the clutches K0 and K1 relative to each other. The drive train may have a dual mass flywheel 58, for example. The clutch can also have, for example, a pressure compensation chamber 60 in which a return spring 62 is present. In this case, a pressure compensation chamber 60 and a return spring 62 are found in the hydraulically actuated clutches K0, K1 and K2 in the case of electromechanical actuation. Fig. 9 shows an electrohydraulic actuation variant, in which the electric motor 64 is connected for actuation to an actuating element 68 via an actuating support 66. Also shown are a grooved ball bearing 70, a needle bearing 72 and an axial bearing 74.

Fig. 10 also shows a design of a part of the dual clutch transmission assembly corresponding to fig. 4. Here, elements already described for fig. 9, such as the actuating motor 64 or the actuating support 66, are also present and are therefore not further described.

In contrast to fig. 9, fig. 10 shows a possible solution for arranging the rotational speed adaptive vibration absorber 76 in the wet space. In any embodiment, a rotational speed-adaptive vibration absorber can be added to reduce vibrations. The speed-adaptive vibration absorber is usually arranged on the input element of the clutch.

Fig. 11 shows the overall dual clutch transmission assembly, wherein, in addition to clutches K1 and K0, clutch K2 is also shown. To avoid repetition, reference is made to the drawing description for fig. 9 and 10, in which these have been described, regarding the left half construction. The input 26 of the clutch K2 is connected to the connecting shaft 24, in this case the input 26 of the clutch K2 being formed by the inner disk carrier 78. The outer disc carrier 80 forms the output of the clutch K2. The output 28 is connected to a transmission input shaft 30. The clutch K2 is arranged between the gear wheel set planes of the transmission input shafts 22 and 30, and the configuration corresponds in this respect to the configuration according to fig. 3.

List of reference numerals

1 Motor vehicle

2 first drive unit

3 second drive unit

4 dual clutch transmission assembly

5 differential mechanism

6 Derailleur casing

7 Clutch bell

8 gear set shell

9 intermediate wall

10 line

12 line

14 input terminal

16 output terminal

18 input terminal

20 output terminal

22 variator input shaft

24 connecting shaft

26 input terminal

28 output terminal

30 speed variator input shaft

32 fixed gear

34 movable gear

36 switching element

38 gear set plane

40 gear set plane

42 gear set

44 auxiliary shaft

46 fixed gear

48 Dual clutch assembly

50 inner disc support

52 outer disc support

54 outer disc support

56 inner disc support

58 dual mass flywheel

60 pressure compensation chamber

62 return spring

64 steering motor

66 handling support

68 operating element

70 groove ball bearing

72 needle roller bearing

74 axial bearing

76 rotating speed adaptive vibration absorber

78 inner disc support

80 outer disc support

K0 disconnect clutch

K1 main clutch

K2 main clutch