EP4127501A1

EP4127501A1 - Friction clutch with a cover made from sheet metal with folded anti-friction bearing seats, transmission arrangement and production method

Info

Publication number: EP4127501A1
Application number: EP21712016.1A
Authority: EP
Inventors: Viktor Wiege
Original assignee: Schaeffler Technologies AG and Co KG
Current assignee: Schaeffler Technologies AG and Co KG
Priority date: 2020-03-31
Filing date: 2021-02-22
Publication date: 2023-02-08
Also published as: DE102020108818B3; CN115176093A; WO2021197532A1; US20230341005A1; KR20220139961A

Abstract

The invention relates to a friction clutch (1) for a drive train (2) of a motor vehicle (3), with a cover (8) which, in order to be mounted in a transmission housing (4) and/or in order to mount a shaft (5), has an inner bearing seat (6) and/or an outer bearing seat (7) for respective receiving of an anti-friction bearing (9, 10), wherein the cover (8) is a (deep-drawn) sheet metal component, and wherein there is a contour (11), which has folds, in the region of at least one of the bearing seats (6 and/or 7)/the bearing seat (6 or 7). The invention also relates to a transmission arrangement with a transmission housing (4), in which the friction clutch (1) according to the invention is inserted in a manner which is supported via an anti-friction bearing (9 or 10), and an input shaft (5) is mounted via a further anti-friction bearing (10 or 9) in the cover (8) of the friction clutch (1). The invention also relates to a method for the production of a friction clutch (1) according to the invention, wherein the bearing seat (6 or 7) or the bearing seats (6 and 7) is/are folded.

Description

FRICTION COUPLING WITH A SHEET METAL COVER WITH FOLDED ROLLING BEARING SEATS,

GEAR ARRANGEMENT AND MANUFACTURING PROCESS

The invention relates to a friction clutch for a drive train of a motor vehicle, for example a hybrid vehicle, with a cover which has an inner bearing seat and / or an outer bearing seat for receiving a roller bearing in order to be mounted in a transmission housing and / or a shaft. where the cover is a (deep-drawn) sheet metal component.

There are already numerous friction clutches from the prior art, including those that are used in hybrid vehicles. For example, DE 102017 127 917 A1 discloses a clutch arrangement for a vehicle. This clutch arrangement comprises a friction clutch which is arranged between a drive shaft and a gear input shaft for the transmission of torques. It further comprises a transmission input shaft and a release bearing, the friction clutch having a counter plate, a pressure plate displaceable in an axial direction for opening and closing the friction clutch through the release bearing and a clutch disc arranged between the counter plate and the pressure plate. The transmission input shaft extends, starting from a transmission input shaft tra lowing main bearing through the release bearing, the pressure plate and the clutch disc to a first end, the first end being supported by a pilot bearing in the counterplate. In a clutch arrangement, the first end of the transmission input shaft is encompassed by a compensating element, which is in operative connection with the pilot bearing when the friction clutch is tilted relative to the transmission input shaft.

Friction clutches are often used as rotor carriers in electrical machines for hybrid modules of a motor vehicle. In the present case, this is also the aim.

The covers for clutch pressure plates and double clutches, which are formed from a piece of steel sheet metal, are known from applications in the automotive sector, these having a bearing seat arranged coaxially to the axis of rotation of the clutch exhibit. The bearing seat can be provided either for the outer ring or for the inner ring of a roller bearing. The bearing seat can be equipped with a shoulder to axially support the roller bearing. The bearing seat can be provided with one or more grooves for mounting the circlips. The bearing seats are usually machined after reshaping the cover. In some cases it is necessary to provide the cover with two position seats, namely for an inner ring of the roller bearing for storage, for example in a gear housing and for an outer ring of the roller bearing for storage, for example a shaft. The La gersitze must be arranged radially one above the other or with only a slight axial offset in order to make the whole construction as compact as possible in the axial direction. The two diameters of the outer and inner rings of the selected roller bearings usually differ in such a way that either the cover must be made from at least two interconnected components, or the sheet thickness for the other areas apart from the bearing seats is unnecessarily large.

It is the object of the present invention to eliminate or at least mitigate the disadvantages known from the prior art. In particular, the task is to find a solution which, despite the given difference between the outer and inner rings of inner and outer rolling bearings with a thin sheet metal thickness, shows ways to manufacture the cover from one piece. Furthermore, be the task is to enable the preparation of the shoulder and the grooves for the assembly of the hedging rings, despite the axial offset between the outer and the inner roller bearing.

In the case of a generic friction clutch, this object is achieved according to the invention in that a wrinkled contour is present in the area of at least one of the bearing seats / the bearing seat.

In other words, the inventive solution consists in folding the sheet metal after / during a deformation of the cover between the two future bearing seats in a radial direction so that the material for later machining is partly for the first and partly for the second Bearing seat remains in place. The proportion of material for both bearing seats can be distributed as desired. The sheet metal when forming the cover between the two future bearing seats should be folded / creased / bent over in the axial direction so that the material for a later machining of the shoulder and groove to accommodate the circlips of both bearing seats is partly for the first and partly remains available for the second bearing seat. The amount of material for both bearing seats can be distributed as desired and required.

Advantageous embodiments are claimed in the subclaims and who will be explained in more detail below.

It is therefore advantageous if there are radial folds in the bearing seat. The Reibkupp ment can then comprise a cover which is made from a piece of sheet steel. The insertion of a roller bearing in the bearing seat to support an input shaft is then cleverly possible. Furthermore, a groove can be made in order to mount a locking ring. The coupling can then be provided with the roller bearing during assembly, which is, for example, installed in a transmission housing of a motor vehicle. The clutch cover is inserted with the bearing seat into an inner ring of a roller bearing and secured against axial displacement by means of a safety ring mounted on a groove.

It has proven useful if the contour in the region of the at least one bearing seat or the two bearing seats runs around sinusoidally in the circumferential direction. The cover can then be manufactured in such a way that the material for later machining of the bearing seats was obtained by folding in the radial direction / folding over in the radial direction. The material distribution between the two bearing seats can be selected as required.

Production is facilitated if the radial folds are chosen so tightly and so close to one another that enough residual material remains for a machining of the bearing seat when the planned disposal material is withdrawn for a desired stability. A virtual material thickness is thus kept available, which is then reduced, for example by machining, for the final state. The cover is made in such a way that the material is sufficiently large that the shoulders for the roller bearing rings and the grooves for the assembly of circlips remain in place during machining. So folding in the axial direction is used. These folds in the axial direction thus support the working out of the shoulder and the grooves for the retaining rings. Here, too, the material distribution between the shoulder and the groove with respect to the inner bearing seat and / or the outer bearing seat must be selected in accordance with the requirements.

It has also proven useful if a groove is introduced into the folds, preferably over the circumference, for receiving a locking ring. Securing against axial slipping can then be achieved with inexpensive means. The assembly also remains simple.

If the wrinkled contour is machined on its inside and outside to form a bearing seat, then a sufficient surface quality can also be provided.

An advantageous embodiment is also characterized in that the cover has axial folds on a surface which is oriented perpendicular to the axis of rotation of the cover, for example an end face, in particular on one end.

It is conducive to assembly if a groove for a locking ring assigned to an inner bearing is moreover the area with axial folds than a groove for a locking ring assigned to an outer bearing.

The invention also relates to a gear arrangement with a gear housing in which the friction clutch according to the invention is used supported by a roller bearing and an input shaft is mounted in the cover of the friction clutch via a further roller bearing. Ultimately, the invention also relates to a method for producing the friction clutch according to the invention, wherein the bearing seat or the bearing seats are (for example, radially) folded.

The focus of the invention is ultimately a clutch cover, the bearing seat (s) of which is / are obtained by radial folding of the sheet metal. Shoulders are obtained by folding axially. Machining can then be provided.

The invention is explained in more detail below with the aid of a drawing. A first embodiment is shown. Show it:

Fig. 1 is a longitudinal section through a friction clutch according to the invention, not all components valuable for the friction clutch are shown,

Fig. 2 is an enlarged longitudinal section through the cover of the friction clutch shown singularly from Fig. 1,

3 shows a cross-sectional view along the line III from FIG. 2 through the cover of the friction clutch according to the invention,

Fig. 4 shows a cross section through the cover of the friction clutch from Fig. 1 with Wälzla like, which are assigned to an inner bearing seat and an outer bearing seat, and

5 shows the structure of a drive train of a motor vehicle with an inserted friction clutch according to FIG. 1.

The figures are merely of a schematic nature and are only used for understanding the invention. The same elements are provided with the same reference symbols. 1 shows a first embodiment of a friction clutch 1 according to the invention. The friction clutch 1 is intended to be installed in a drive train 2 of a motor vehicle 3, for which reason reference is made in particular to FIG. 5.

Returning to FIG. 1, it should be explained that the friction clutch 1 is rotatably inserted in a transmission housing 4. Inside the friction clutch 1, a shaft 5, such as an input shaft, is inserted so that it can rotate. For this double storage there is a neren bearing seat 6 and an outer bearing seat 7 on a cover 8 of the friction clutch 1. There bearings are provided.

The cover 8 is a sheet metal component, in particular a deep-drawn component. The inner bearing seat 6 is provided for receiving an inner roller bearing 9, whereas the äu ßere bearing seat 7 is provided for receiving an outer roller bearing 10. More precisely, an inner (bearing) ring 25 of the outer roller bearing 10 sits on the outer bearing seat 7, whereas an outer (bearing) ring 26 of the inner roller bearing 9 sits on the inner bearing seat 6.

In the area of the inner bearing seat 6 and the outer bearing seat 7, a contour 11 with folds is formed. In the area of this contour 11, which runs around a Rotati onsachse 12, radial folds 13 are present. These radial folds 13 of the cover 8 can also be seen clearly in FIGS. 3 and 4. It is noticeable, however, that due to the waviness of the folds 13, the bearing seat 6 is not located above the axis of rotation 12 in the longitudinal sectional plane.

Both in the area of the inner bearing seat 6 and in the area of the outer bearing seat 7 there is a groove 14 for receiving a locking ring 15. The axis of rotation 12 specifies the axial direction 16, with a radial direction 17 running perpendicular thereto. For the principle of the friction clutch 1, it is valuable if a counter-plate 18 is used which, together with a pressure plate 19, clamps a clutch disc 20 in the force-transmitting / torque-transmitting state. In Fig. 2, the presence of the radial folds 13 in the area of the inner bearing seat 6 and the outer bearing seat 7 is visualized. The material 21 removed during machining is indicated by means of a dashed line. In such a machining process, shoulders 22 are then also worked out for an axial contact of the roller bearings 9 and 10, which are not shown in FIG. 2. Centrally between the bearing seats 6 and 7 there is an area with axial folds 23. By means of the machining on the outside, the inner bearing seat 6 is ultimately worked out.

A sheet metal thickness that is established after the non-cutting forming and before the milling operation is referenced with the reference numeral 24.

The radial folds 13 are chosen so thick and are so close to one another that enough / sufficient residual material remains for a predetermined / desired stability for a machining of the bearing seat 6 and / or 7 when the planned removal material 21 is subtracted. The thickness is measured in the radial direction. Before the machining, an initial thickness / virtual thickness (shown in dashed lines in FIG. 2) is greater than after the machining. The processed state is shown in FIG. As a result of the folding, the area of the bearing seat is artificially thickened. It is thickened to such a level that sufficient material is available so that the desired contour can be achieved during machining and still enough residual material remains.

In Fig. 3, the sinusoidal contour 11, including the radial folds 13 is clearly Lich. The machined shoulders 22 at the base of each radial fold 13 are also evident.

If a cross section through the cover 8 in the area of the inner and outer bearing seats 6 and 7 is detected when the roller bearing 9 and 10 is mounted, the situation shown in FIG. 4 arises. In the present case, the inner and outer roller bearings 9 and 10 are ball bearings. The inner ring of the outer roller bearing 10 is referenced with the reference number 25 Be. An outer ring of the inner roller bearing 9 is referenced with the reference numeral 26 Be. An overall overview is ultimately shown in FIG. 5, the drive train 2 of the motor vehicle 3 also having a hybrid module 27. Furthermore, an internal combustion engine 28 is coupled to a flywheel 29 in order to ultimately pass on torque selectively via a friction clutch to the hybrid module and then via a transmission 30 to two drive wheels 31.

Bezuqszeichenliste Friction clutch Drivetrain Motor vehicle Gearbox housing Shaft Inner bearing seat Outer bearing seat Cover inner roller bearing Outer roller bearing creased contour Axis of rotation Radial fold groove Circlip axial direction radial direction Counter plate Pressure plate Clutch disk module Removed material / removal material Shoulder bearing axial fold Sheet metal thickness Inner ring of the outer roller bearing internal roller bearing

Claims

1. Friction clutch (1) for a drive train (2) of a motor vehicle (3), with a cover (8) which has an inner bearing seat (6) to be stored in a gear housing (4) and / or a shaft (5) and / or an outer bearing seat (7) for receiving a roller bearing (9, 10), the cover (8) being a (deep-drawn) sheet metal component, characterized in that a fold-having contour (11) in the area of at least one the bearing seats (6 and / or 7) / the bearing seat (6 or 7) is present.

2. Friction clutch (1) according to claim 1, characterized in that the bearing seat (6 and / or 7) radial folds (13) are present.

3. Friction clutch (1) according to claim 1 or 2, characterized in that the contour (11) runs sinusoidally in the circumferential direction.

4. friction clutch (1) according to claim 2 or 3, characterized in that the radial folds (13) are chosen so thick and so close together that for machining of the bearing seat (6 and / or 7) when deducting the ge Planned disposal material (21) enough / sufficient residual material remains for a given / desired stability.

5. Friction clutch (1) according to one of claims 2 to 4, characterized in that a groove (14) for receiving a securing ring (15) is introduced into the folds (13).

6. Friction clutch (1) according to one of claims 1 to 5, characterized in that the wrinkled contour (11) is machined on its inside and outside to form a bearing seat (6 and 7).

7. Friction clutch (1) according to one of claims 1 to 6, characterized in that the cover (8) has axial folds (23) on a surface which is oriented perpendicular to the axis of rotation (12) of the cover (8).

8. Friction clutch (1) according to claim 7, characterized in that a groove (14) for a locking ring (15) associated with an inner bearing is a Be rich with axial folds (23) further than a groove (14) for a one Außenla ger assigned locking ring (15).

9. Gear arrangement with a gear housing (4), in which the friction clutch (1) supported by a roller bearing (9 and / or 10) according to one of the preceding claims is used and an input shaft (5) via a further roller bearing (9 or 10 ) is mounted in the cover (8) of the friction clutch (1).

10. A method for producing the friction clutch (1) according to one of claims 1 to 8, wherein the bearing seat (6 or 7) or the bearing seats (6 and 7) are folded.