DE102011008612A1 - Shaft bearing arrangement for use in gearbox of vehicle, has thermal adapter interconnecting bearing shells, and bearing seats formed into shells, where and axial distance is formed between bearing seats of axial thermal expansion of shaft - Google Patents

Abstract

The arrangement (1) has an angular contact bearing (9) i.e. rolling taper bearing, comprising an outer bearing shell (10) and arranged at an end (8) of a shaft (5) e.g. sleeve shaft and countershaft. Another outer bearing shell (6) fixedly bears another end of the shaft at a housing (14) of the arrangement, and the former outer bearing shell bears the former end of the shaft. A thermal adapter (2) i.e. sleeve, interconnects the shells, and axial distance (a) is formed between outer bearing seats of an axial thermal expansion of the shaft, where the bearing seats are formed into the shells.

Description

A shaft bearing assembly with a thermal adapter will be described. The shaft bearing assembly has a shaft which is mounted in a salaried rolling bearing.

In order to hold such a shaft, the opposing bearing seats are often biased by being clamped between two housing walls. A housing having the bearing seats, however, is usually made of a different material than a shaft held between the bearing shells, so that the set bias voltage changes with increasing operating temperature.

The variations in the bias of the angular contact bearings at different operating temperatures can thus be ensured only for a limited range of temperatures while maintaining the required bias.

A shaft bearing assembly with thermal adaptation device is from the document EP 0 448 239 B1 known. The known thermal adaptation device has at least one compensation ring, which serves as an abutment of a bearing shell and has a high coefficient of thermal expansion. Thus, due to the high coefficient of thermal expansion, the difference between a thermal expansion of a housing holding the bearing shells and the shaft held between the tapered roller bearings can be compensated. However, a complete compensation of the thermal expansion differences to avoid a press fit or loss of the shaft shaft between the tapered roller bearings under extreme heating is usually possible only in a limited operating temperature range with the known compensation ring.

It is an object of one aspect of the present invention to provide a shaft bearing assembly having improved properties in terms of variations in operating temperature.

This object is achieved with the subject matter of independent claim 1. Advantageous developments emerge from the dependent claims.

According to one aspect of the invention, a shaft bearing assembly is provided with a thermal matching device having a mounted in a salaried roller bearing shaft with a first angular contact bearing and a second angular contact bearing. The first angular contact bearing has a first outer bearing shell and is arranged at a first end of the shaft. The second angular contact bearing has a second outer bearing shell and is disposed at a second end of the shaft. The first outer bearing shell is fixed to the fixed bearing of the first end of the shaft to a housing of the shaft bearing assembly and the second outer bearing shell for supporting the second end of the shaft is axially movable.

The shaft bearing assembly further includes a thermal matching device interconnecting the outer races. The thermal adapter adjusts an axial distance between outer bearing seats formed in the outer bearing shells for axial thermal expansion of the shaft.

This shaft bearing arrangement with elongated thermal adaptation device makes it possible to compensate even the largest thermal changes in length with corresponding operating temperature differences by the elongated thermal adjustment device with respect to the thermal expansion behavior of the shaft between the two skew bearings.

The roller bearing may in particular have tapered roller bearings and / or rolling bearings.

According to one embodiment, the employed angular contact bearings have an X arrangement.

In this embodiment, the shaft may be formed as a hollow shaft with an axial bore or an axial passage. In this case, the thermal adaptation device can extend within the bore between the ends of the shaft. Through the hollow shaft, it is possible to arrange a thermal adjustment rod in the center of the hollow shaft such that it corresponds in its length to the axial length of the shaft and thus can follow the thermal expansion of the shaft.

According to one embodiment, the thermal adaptation device has a thermal balance bar, which is mechanically rigidly connected at a first end to a first outer bearing seat of the first outer bearing shell and is adjustably connected at a second end to a second outer bearing seat of the second outer bearing shell.

Under a balance bar is understood here and in the following also a compensation rope.

For this purpose, the first outer bearing shell and the first end of the thermal balance bar can be mechanically rigidly connected to a housing in which the shaft is mounted. The second End of the thermal balance bar can be frictionally or positively connected via a disc-shaped pressure plate with the second bearing shell.

Thus, the distance between the bearing shells at the operating temperatures occurring is constantly and without temperature limit adapted to the change in length of the shaft by the balance bar.

In one embodiment, the disk-shaped pressure plate acts on the second end of the thermal balance bar via an adjusting screw with the balance bar axially adjustable while setting a bearing clearance together.

The bearing clearance can be adjustable, for example, via washers of different thickness, which are arranged between the second end of the thermal balance bar and the pressure plate.

This allows, for a basic setting, the concentricity of the shaft and the angular bearing to be adjusted by means of the adjusting screw or washers between the pressure plate and the second end of the thermal balance bar and this setting is maintained despite temperature variations at any operating temperature due to the elongated thermal compensator ,

According to one embodiment, hubs of spur gears are rotatably supported on the shaft and supplied with lubricant from the balance bar via lubricant bores in the hollow shaft.

The balance bar in one embodiment has lubricant-distributing guide grooves.

In one embodiment, the angular bearings have an O-arrangement.

In this case, the thermal adjustment device may be formed as a sleeve which is arranged concentrically to the shaft around the shaft. In this embodiment, too, the thermal matching device connects the outer bearing shells to one another and adjusts the axial distance between outer bearing seats formed in the outer bearing shells to an axial thermal expansion of the shaft.

It can be provided that the material of the shaft and the material of the thermal matching device have the same axial thermal expansion coefficient.

The shaft may in particular be designed as a transmission shaft, for example as a transmission shaft of a vehicle transmission.

According to one aspect of the invention, the shaft bearing assembly is used in the transmission of a vehicle.

Embodiments of the invention will now be described with reference to the accompanying figures.

1 shows a schematic cross section through a shaft bearing assembly according to a first embodiment;

2 shows a cross section through a shaft bearing assembly according to a second embodiment.

1 shows a cross section through a shaft bearing assembly 1 a wave 5 in a housing 14 is stored.

A first end 4 the wave 5 is in a first tapered roller bearing 3 stored, which is a first outer bearing shell 6 having. A second end 8th the wave 5 is in a second tapered roller bearing 9 stored, which is a second outer bearing shell 10 having. The tapered roller bearings 3 . 9 in the in the 1 and 2 shown embodiment on an X-arrangement. Instead of tapered roller bearings 3 . 9 can also be used, for example, ball bearings.

The two outer cups 6 and 10 with their outer bearing seats 34 ' and 34 '' be in the case 14 held under a bias. While the first outer bearing shell 6 of the first tapered roller bearing 3 on the case 14 is the second outer bearing shell 10 concentric in an opening 28 arranged, but axially in the opening 28 displaceable. Inner bearing seats 33 the tapered roller bearing 3 . 9 are over inner cups 41 . 42 on the ends 4 and 8th the hollow shaft 5 arranged.

The wave 5 is designed as a hollow shaft and has a thermal balance bar in its center 11 on. This balance bar 11 has the same length extension as the shaft 5 and is made of the same material as the shaft 5 manufactured so that the thermal expansion coefficient and thus the thermal length changes of balance bar 11 and wave 5 almost coincide. A change in the bias, which maintains the bearing clearance is thus largely avoided when operating temperature changes occur.

A first end 12 of the balance bar 11 supports itself together with the first outer bearing shell 6 on a housing inside 32 off and is on a housing wall 38 by means of a fixing screw 37 mechanically fixed. At a second end 13 is a disc-shaped pressure plate 15 with an adjusting screw 16 arranged, with the adjusting screw 16 with the balance bar 11 is engaged via a thread.

The in the 1 and 2 shown wave 5 is designed as a gear shaft and has shift sleeves 17 and 18 on, over the shift forks 30 and 31 axially opposite the shaft 5 are movable and those with hubs 19 . 20 or 21 of spur gears 22 . 23 respectively. 24 can be brought into engagement. The hubs 19 . 20 and 21 the spur wheels 22 . 23 respectively. 24 are rotatable relative to the shaft 5 mounted on sliding or needle bearings, with the help of lubricant bores 25 . 26 and 27 in the wave 5 be supplied with lubricant.

The lubricant supply can also be done via the balance bar 11 be made possible, for example, if this is designed as a tube and the lubricant via a lubricant channel in the housing wall 38 at which the balance bar 11 with his first end 12 is fixed, is supplied. Using appropriate lubricant holes or lubricant grooves can then from the fixed balance bar 11 about in the wave 5 arranged lubricant holes 25 . 26 and 27 the storage of the spur gears are supplied.

During operation of the shaft bearing assembly 1 the distance a between the outer cups changes 6 . 10 with changing operating temperature. As the operating temperature increases, the shaft expands 5 in the axial direction. Likewise, the thermal balance bar expands 11 the adaptation device 2 in the axial direction about the same distance. He transmits over the housing 14 or over the disk-shaped pressure plate 15 Forces on the outer bearing shells 6 . 10 , He thus provides a constant preload for the tapered roller bearings 3 and 9 between which the shaft 5 is held available.

The desired preload can be applied to the adjustment screw 16 the bias voltage can be adjusted. The through the adjusting screw 16 Preset preload is over a cranked edge 29 the disc-shaped pressure plate 15 on the outer bearing shell 10 the second tapered roller bearing 9 transfer. This preset preload does not change when the operating temperatures change because of the shaft 5 and balance bar 11 subject in the same sense a change in length and thus the distance a between the two tapered roller bearings 3 and 9 the expansion behavior of the shaft 5 is adjusted.

2 shows a cross section through a shaft bearing assembly 40 according to a second embodiment. Components with the same functions as in 1 are denoted by like reference numerals and will not be discussed separately.

The difference from the embodiment according to 1 is that between the pressure plate 15 and the end of the thermal balance bar 11 washers 35 and 36 are arranged, with which the bearing clearance and thus the bias voltage is adjustable. This is indicated by the washers 35 and 36 adjusted thicknesses and thus secure the position of the adjusting screw 16 ,

In addition, in the second embodiment, the first end protrudes 12 of the thermal balance bar 11 from the housing via a central bore in the housing wall 38 out and is from a central fixing nut 39 held, which has a paragraph of the first end 12 against the inside of the housing 32 pressed.

Will the thermal balance bar 11 designed as a hollow rod, so can over the protruding end 12 of the thermal balance bar 11 a lubricant can be supplied.

LIST OF REFERENCE NUMBERS

1

Shaft bearing arrangement (1st embodiment)

2

adapter

3

first tapered roller bearing

4

first end of the wave

5

hollow shaft

6

outer bearing shell

7

Rotary axis of the shaft

8th

second end of the shaft

9

second tapered roller bearing

10

outer bearing shell

11

balance beam

12

first end of the balance bar

13

second end of the balance bar

14

casing

15

Pressure plate (disk-shaped)

16

adjustment

17

shift sleeve

18

shift sleeve

19

Hub of a spur gear

20

Hub of a spur gear

21

Hub of a spur gear

22

spur gear

23

spur gear

24

spur gear

25

lubricant bore

26

lubricant bore

27

lubricant bore

28

opening

29

cranked edge of the printing plate

30

shift fork

31

shift fork

32

case side

33

inner tapered roller bearing seat

34 '

first outer tapered roller bearing seat

34 ''

second outer tapered roller bearing seat

35

washer

36

washer

37

fixing screw

38

housing wall

39

fixing nut

40

Shaft bearing arrangement (2nd embodiment)

41

inner bearing shell

42

inner bearing shell

a

Distance between the outer bearing shells

α

Inclination angle of the bearing shells

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0448239 B1 [0004]

Claims (15)

Shaft bearing arrangement with a thermal adaptation device ( 2 ), comprising: - a shaft mounted in a salaried bearing ( 5 ) with a first angular contact bearing ( 3 ) and a second angular contact bearing ( 9 ), - whereby the first angular contact bearing ( 3 ) a first outer bearing shell ( 6 ) and at a first end ( 4 ) the wave ( 5 ) and wherein the second angular contact bearing ( 9 ) a second outer bearing shell ( 10 ) and at a second end ( 8th ) the wave ( 5 ), and - wherein the first outer bearing shell ( 3 ) for the fixed storage of the first end ( 4 ) the wave ( 5 ) on a housing ( 14 ) of the shaft bearing assembly is fixed and the second outer bearing shell ( 10 ) for storage of the second end ( 8th ) the wave ( 5 ) is axially movable; A thermal adaptation device which seals the outer bearing shells ( 6 . 10 ) and an axial distance (a) between in the outer bearing shells ( 6 . 10 ) formed outer bearing seats ( 34 ) an axial thermal expansion of the shaft ( 5 ) adapts. Shaft bearing arrangement according to claim 1, wherein the angular contact bearings ( 3 . 9 ) have an X-arrangement. Shaft bearing arrangement according to claim 2, wherein the shaft ( 5 ) is formed as a hollow shaft with an axial bore and the thermal matching device within the bore between the ends ( 4 . 8th ) the wave ( 5 ). Shaft bearing arrangement according to claim 3, wherein the thermal adaptation device ( 2 ) a thermal balance bar ( 11 ) having a first end ( 12 ) with a first outer bearing seat ( 34 ' ) of the first outer bearing shell ( 6 ) is mechanically rigidly connected and with a second end ( 13 ) with a second outer bearing seat ( 34 '' ) of the second outer bearing shell ( 10 ) is adjustably connected. Shaft bearing arrangement according to claim 4, wherein the first outer bearing shell ( 6 ) and the first end ( 12 ) of the thermal balance bar ( 11 ) with a housing ( 4 ) are mechanically rigidly connected, in which the shaft ( 5 ), and wherein the second end ( 13 ) of the thermal balance bar ( 11 ) via a disc-shaped pressure plate ( 15 ) with the second bearing shell ( 10 ) is positively connected. Shaft bearing arrangement according to claim 5, wherein the disc-shaped pressure plate ( 15 ) at the second end ( 13 ) of the thermal balance bar ( 11 ) via an adjusting screw ( 16 ) with the balance bar ( 11 ) interacts axially adjustable setting a bearing clearance. Shaft bearing arrangement according to claim 6, wherein the bearing clearance via shims ( 35 . 36 ) of different thickness between the second end ( 13 ) of the thermal balance bar ( 11 ) and the pressure plate ( 15 ) are arranged, is adjustable. Shaft bearing arrangement according to one of claims 4 to 7, wherein hubs ( 19 . 20 . 21 ) of spur gears ( 22 . 23 . 24 ) on the shaft ( 5 ) are rotatably mounted and by the balance bar ( 11 ) from via lubricant bores ( 25 . 26 . 27 ) are supplied in the hollow shaft with lubricant. Shaft bearing arrangement according to one of claims 4 to 8, wherein the balance bar ( 11 ) has lubricant-distributing guide grooves. Shaft bearing arrangement according to claim 1, wherein the angular contact bearings ( 3 . 9 ) have an O-arrangement. Shaft bearing arrangement according to claim 10, wherein the thermal adaptation device is formed as a sleeve which concentric with the shaft ( 5 ) around the shaft ( 5 ) is arranged around. Shaft bearing arrangement according to one of claims 1 to 11, wherein the material of the shaft ( 5 ) and the material of the thermal adaptation device ( 2 ) have the same axial thermal expansion coefficient. Shaft bearing arrangement according to one of the preceding claims, wherein the shaft ( 5 ) is designed as a transmission shaft. Vehicle transmission comprising a shaft bearing arrangement ( 1 ) according to one of claims 1 to 13. Vehicle having a transmission with a shaft bearing arrangement ( 1 ) according to one of claims 1 to 13.

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