Hybrid module and drive arrangement for a motor vehicle

Abstract

A hybrid module includes a hybrid module housing which forms a housing interior divided by a partition. The housing interior includes at least one chamber designed as a dry space which is separated from a wet region by the partition, wherein the hybrid module has an electric machine and a first clutch device, in particular a separating clutch, in the dry space and has a second clutch device, in particular a dual clutch apparatus, in the wet region. An output side of the first clutch device is mechanically coupled to the input side of the second clutch device by an intermediate shaft, wherein the intermediate shaft is supported at least radially on the partition via at least one bearing unit.

Claims

1. A hybrid module for a motor vehicle for coupling an internal combustion engine and a transmission, comprising a hybrid module housing forming a housing interior divided by a partition, wherein the housing interior includes at least one chamber configured as a dry space separated from a wet region by the partition, and wherein an electric machine and a first clutch device, is disposed in the dry space and a second clutch device is disposed in the wet region, and an output side of the first clutch device is mechanically coupled to an input side of the second clutch device by an intermediate shaft, wherein the intermediate shaft is supported at least radially on the partition via at least one bearing unit.

2. The hybrid module according to claim 1, wherein the partition is integral with the hybrid module housing.

3. The hybrid module according to claim 1, further comprising: a rotor unit non-rotatably coupled in the dry space to a rotor of the electric machine and to the output side of the first clutch device and is coupled to the intermediate shaft so that the rotor unit is mounted together with the intermediate shaft on the partition via the bearing unit.

4. The hybrid module according to claim 1, wherein the second clutch device is a dual clutch apparatus that comprises two partial clutches, wherein both partial clutches are arranged in the wet region.

5. The hybrid module according to claim 1, wherein the second clutch device is a dual clutch apparatus that comprises two partial clutches, wherein only one of the two partial clutches is arranged in the wet region.

6. The hybrid module according to claim 1, wherein a sealing element is provided on an outside of the hybrid module housing and configured for implementing a liquid-tight connection with a transmission housing.

7. The hybrid module according to claim 1, wherein the second clutch device is assigned at least one actuating device designed as a piston-cylinder unit, wherein a cylinder of the actuating device is supported on the partition and is at least partially enclosed by material forming the partition.

8. The hybrid module according to claim 1, further comprises a centrifugal pendulum non-rotatably connected to an input side of the second clutch device.

9. A drive arrangement for a motor vehicle, comprising a hybrid module according to claim 1 and a drive unit including an internal combustion engine and a transmission, wherein the hybrid module is mechanically connectable to the drive unit and the transmission via at least one of the first clutch device or the second clutch device of the hybrid module.

10. The drive arrangement according to claim 9, wherein the hybrid module housing is mechanically connected to a transmission housing of the transmission, wherein the connection between the hybrid module housing and the transmission housing is configured to be sealing and the transmission housing forms a wet region of the drive arrangement at least in sections together with the partition, which drive arrangement comprises the wet region of the hybrid module.

11. A hybrid module for a motor vehicle for coupling an internal combustion engine and a transmission, comprising: a hybrid module housing arranged to form a housing interior divided by a partition, wherein the housing interior includes at least one chamber configured as a dry space separated from a wet region by the partition; an electric machine disposed in the dry space; a first clutch device disposed in the dry space; and a second clutch device disposed in the wet region, wherein an output side of the first clutch device is mechanically coupled to an input side of the second clutch device by an intermediate shaft, wherein an input side of the first clutch device is rotatably mounted on the intermediate shaft.

12. The hybrid module according to claim 11, further comprising an actuating device supported on the partition and configured to actuate the first clutch.

13. The hybrid module according to claim 11, wherein the second clutch is a dual clutch including a first partial clutch and a second partial clutch.

14. The hybrid module according to claim 13, further comprising a centrifugal pendulum mounted on a respective one of the first partial clutch or the second partial clutch.

15. The hybrid module according to claim 14, further comprising a protective element fixed to and extending radially outward from the respective partial clutch, wherein the protective element is arranged to surround the centrifugal pendulum on one side axially and radially.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0045] The disclosure described above is explained in detail below based on the relevant technical background with reference to the associated drawings, which show advantageous embodiments. The disclosure is in no way restricted by the purely schematic drawings, although it should be noted that the embodiments shown in the drawings are not limited to the dimensions shown. In the drawings:

[0046] FIG. 1: shows a hybrid module according to the disclosure according to a first embodiment;

[0047] FIG. 2: shows a hybrid module according to the disclosure according to a second embodiment;

[0048] FIG. 3: shows a hybrid module according to the disclosure according to a third embodiment; and

[0049] FIG. 4: shows a hybrid module according to the disclosure according to a fourth embodiment.

DETAILED DESCRIPTION

[0050] FIG. 1 shows a hybrid module 1 according to the disclosure according to a first embodiment.

[0051] The hybrid module 1 comprises a hybrid module housing 2, an electric machine 3, a first clutch device 4 and a second clutch device 5. The rotatable components of the hybrid module 1 rotate here about an axis of rotation 6 of the hybrid module, which at the same time corresponds to the axis of rotation of the intermediate shaft 12 shown.

[0052] The hybrid module housing 2 forms a housing interior 20 which is subdivided by means of a partition 23 of the hybrid module housing 2 that extends radially inward in the radial direction, namely into a chamber 22 as a dry space 10 on a first axial side 24 of the partition 23 and into a wet region 11 on a second axial side 25 of the partition 23, wherein the partition 23 spatially separates the dry space 10 and the wet region 11 from one another.

[0053] The electric machine 3 and the first clutch device 4 are arranged in the dry space 10, wherein the second clutch device 5 is arranged in the wet region 11. The first clutch device 4 is designed as a separating clutch, wherein the second clutch device 5 is designed as a dual clutch apparatus with a first partial clutch 52 and a second partial clutch 53.

[0054] The first clutch device 4 is positioned radially within a space formed by a rotor 31 of the electric machine 3 arranged on a rotor holder 30, wherein the stator 32 of the electric machine 3 is arranged in the radially outer section of the housing interior 20 on the hybrid module housing 2. Furthermore, a rotor position sensor 76 is arranged radially within the space formed by the rotor 31 axially between the first clutch device 4 and the partition 23 for scanning the angular position of the rotor 31.

[0055] A vibration damping unit 70, which is non-rotatably connected to a crankshaft 75 and which is arranged on the side of the electric machine 3 facing away from the intermediate wall 23 in the axial direction next to the electric machine 3 and the first clutch device 4, is non-rotatably connected to an input side 40 of the first clutch device 4 for transmitting torque from an internal combustion engine (not shown) connected to the crankshaft 75 to the first clutch device 4.

[0056] An actuating device 42 of the first clutch device 4 is arranged on a first axial side of the partition 24 of the partition 23, wherein the actuating device 42 of the first clutch device 4 is designed as a hydraulic actuating device and has a hydraulic line 78 for this purpose, which extends from outside the housing interior 20 through the hybrid module housing 2 and applied to the first axial side 24 of the partition 23 to the actuating device 42 of the first clutch device 4 and is fluidically connected to this.

[0057] A rotor unit 16 extends axially between the rotor position sensor 76 and the first clutch device 4 and, starting from the rotor 31, radially inwards, wherein it is non-rotatably connected to the rotor holder 30 and thus to the rotor 31 of the electric machine 3 and to an output side 41 of the first clutch device 4.

[0058] The hybrid module 1 further comprises an intermediate shaft 12, which is non-rotatably connected to the rotor unit 16, that is to say to the output side 41 of the first clutch device 4 and to the rotor 31 of the electric machine 3, and which is connected to an input side 50 of the second clutch device 5, that is to say is connected to the first partial clutch 52 and the second partial clutch 53.

[0059] The intermediate shaft 12 runs in the axial direction from the dry space 10 to the wet region 11, wherein the intermediate shaft 12 is supported via a bearing unit 13 on the radial inside 26 of the partition 23. The bearing unit 13 is designed as a roller bearing, in particular a double-row ball bearing, and is configured to support the intermediate shaft 12 on the partition 23 in both the axial and radial directions. A sealing device 14 is arranged between the radial inside 26 of the partition 23 and the intermediate shaft 12 for the fluidic separation of the dry space 10 from the wet region 11. The sealing device 14 is arranged axially next to the bearing unit 13 on the side of the bearing unit 13 facing the dry space 10, so that the bearing unit 13 itself is arranged in the wet region 11.

[0060] The two partial clutches 52, 53 of the second clutch device 5 configured as a double clutch are arranged next to one another in the radial direction, wherein the first partial clutch 52 is arranged radially inside the second partial clutch 53. An actuating device 54 of the first partial clutch 52 is designed as a concentric first piston-cylinder unit 60 with a first piston 61 and a first cylinder 62, wherein the first cylinder 62 is arranged on the second axial side 25 and the radial inside 26 of the partition 23. An actuating device (not shown here) of the second partial clutch 53 is designed as a further concentric piston-cylinder unit.

[0061] The two partial clutches 52, 53 each comprise a return spring 56, 57 for implementing a normally open position of the respective partial clutch 52, 53 in the load-free or actuation-free state. The two partial clutches 52, 53 are connected to a first transmission input shaft 73 and a second transmission input shaft 74 on an output side 51 of the second clutch device 5 facing away from the electric machine 3. A torque made available by an internal combustion engine (not shown) is thus introduced into the hybrid module 1 via the crankshaft 75 and transmitted via the vibration damper unit 70 to the first clutch device 4, from which the torque in turn is transmitted to the electric machine 3 or its rotor 31 and is transmitted from there via the rotor unit 16 to the intermediate shaft 12. The torque transmission path from the electric machine 3 to the transmission output shafts 73, 74 thus runs via the rotor unit 16 to the intermediate shaft 12 and from this with the first partial clutch 52 of the second clutch device 4 to the first transmission output shaft 73 or when the second partial clutch 53 of the second clutch device 4 to the second transmission output shaft 73.

[0062] If the first clutch device 4 is closed, the torque provided by the internal combustion engine (not shown) also runs substantially along the torque transmission path via the electric machine 3 or its rotor 31 to the transmission output shafts 73, 74.

[0063] FIG. 1 also shows a contour 71 of a housing of a transmission, which extends substantially on the side of the second clutch device 5 facing away from the electric machine 3 and is placed against the outside 21 of the hybrid module housing 2. The housing of the transmission thus forms, together with the second axial side 25 of the partition 23, a wet space 72 which encompasses the wet region 11. A sealing element 15 is provided between the housing of the transmission and the outside 21 of the hybrid module housing 2, which in the axial direction effects a flat contact or sealing effect between the contour 71 of the housing of the transmission and the outside 21 of the hybrid module housing 2 and thus fluidically seals the wet space 72.

[0064] The hybrid module and the transmission together form part of the drive arrangement according to the disclosure.

[0065] FIG. 2 shows an alternative embodiment in which, in contrast to the embodiment shown in FIG. 1, for the two partial couplings 52, 53 of the second clutch device 5, in addition to the concentric first piston-cylinder unit 60 shown in FIG. 1, a single, circumferentially arranged actuating device 55 of the second partial clutch 53 is shown, which is designed accordingly as an eccentric further piston-cylinder unit 63. It is advantageously provided that a plurality of such further piston-cylinder units 63 are arranged on the circumference shown here, at least three such units at an angular distance of 120°. Otherwise, the hybrid module shown in FIG. 2 substantially corresponds to the hybrid module shown in FIG. 1.

[0066] The embodiment of the hybrid module according to the disclosure shown in FIG. 3 is substantially realized according to the embodiment shown in FIG. 3, with the difference that, contrary to the versions shown in FIGS. 1 and 2, a sealing element 15 on the hybrid module housing 2 is arranged on a radial outside of the hybrid module housing 2 as a sealing ring, and not as shown in FIGS. 1 and 2 as a flat seal which is aligned to one axial side. Otherwise, reference is made to the description of FIGS. 1 and 2 with regard to the further elements of this embodiment of the hybrid module 1.

[0067] This seal 15, designed as a sealing ring, thus rests on a complementarily shaped radial inner wall of an adjoining housing of a transmission (not shown here) in order to separate the wet region 11 or the wet space formed thereby from the surroundings.

[0068] FIG. 4 shows an embodiment of the hybrid module 1 according to the disclosure which largely corresponds to the embodiment shown in FIG. 1, so that reference is made to the description of FIG. 1 with regard to the matching elements and features of the hybrid module 1.

[0069] The difference between the embodiment shown in FIG. 4 and the embodiment shown in FIG. 1 is the arrangement of a centrifugal pendulum 80 on the second clutch device 5, which is surrounded on one side axially and radially by a protective element 81. The centrifugal pendulum 80 is coupled to the second clutch device 5 in such a way that it is non-rotatably connected to the intermediate shaft 12 and thus also to the rotor unit 16 via the input side 50 of the second clutch device 5, so that all torsional vibrations acting on these elements can be at least partially eliminated or minimized by the centrifugal pendulum 80.

[0070] With the configuration according to the disclosure of the hybrid module proposed here, a simpler and more efficient design is combined with little need for construction space.

LIST OF REFERENCE NUMBERS

[0071] 1 Hybrid module [0072] 2 Hybrid module housing [0073] 3 Electric machine [0074] 4 First clutch device [0075] 5 Second clutch device [0076] 6 Axis of rotation [0077] 10 Dry space [0078] 11 Wet region [0079] 12 Intermediate shaft [0080] 13 Bearing unit [0081] 14 Sealing device [0082] 15 Sealing element [0083] 16 Rotor unit [0084] 20 Housing interior [0085] 21 Outside of the hybrid module housing [0086] 22 Chamber [0087] 23 Partition [0088] 24 First axial side of the partition [0089] 25 Second axial side of the partition [0090] 26 Radial inside of the partition [0091] 27 Radial outside of the partition [0092] 30 Rotor holder [0093] 31 Rotor [0094] 32 Stator [0095] 40 Input side of the first clutch device [0096] 41 Output side of the first clutch device [0097] 42 Actuating device of the first clutch device [0098] 50 Input side of the second clutch device [0099] 51 Output side of the second clutch device [0100] 52 First partial clutch [0101] 53 Second partial clutch [0102] 54 Actuating device of the first partial clutch [0103] 55 Actuating device of the second partial clutch [0104] 56 Return spring of the first partial clutch [0105] 57 Return spring of the second partial clutch [0106] 60 First piston-cylinder unit [0107] 61 First piston [0108] 62 First cylinder [0109] 63 Further piston-cylinder unit [0110] 70 Vibration damper unit [0111] 71 Contour of the transmission housing [0112] 72 Wet space [0113] 73 First transmission input shaft [0114] 74 Second transmission input shaft [0115] 75 Crankshaft [0116] 76 Rotor position sensor [0117] 77 Torsional vibration damper [0118] 78 Hydraulic line [0119] 80 Centrifugal pendulum [0120] 81 Protective element