WO2006092256A1 - Bearing arrangement - Google Patents

Abstract

The invention relates to a bearing arrangement (1) comprising two bearings (2, 3) pressable towards each other in the bearing axis direction (A), wherein said bearings (2, 3) are arranged in a sleeve-like body (4), which is fixed in the axial direction in the borehole (5) of a housing (6) or on a shaft part (7). In order to create an exact and nonetheless low-cost solution, a sleeve-like body (4, 4', 4") comprises at least one sheet metal part whose substantially constant thickness (d) is shaped in such a way that at least one axial stop (8, 9, 10) for at least one bearing (2, 3) is formed.

Description

 Description

bearing arrangement

The invention relates to a bearing assembly consisting of two bearings which are adjustable against each other in Lagerachsrichtung, wherein the bearings are arranged in a sleeve-shaped body which is axially fixed in the bore of a housing or on a shaft portion.

From EP 0 752 537 B1 a rolling bearing arrangement is known in which sleeve-shaped elements are used for storage. It can be provided that a tubular sleeve is provided in an axial end region with a raceway for rolling elements. The sleeve-shaped body thus serves simultaneously as a bearing ring and as a spacer to position a second bearing relative to the first at a defined distance.

A solution of the generic type is known from DE 41 35 565 A1. Two angular contact ball bearings, which are employed against each other, are mounted here in a sleeve-shaped carrier element, which in turn can be inserted into a housing bore. In order to keep the two bearings at a distance, a further sleeve is arranged between the outer rings.

In particular, in applications in vehicle construction, where very large quantities are incurred, it is necessary to design the bearing assemblies used for use in such a way that they are as simple and therefore inexpensive to produce. Furthermore, the bearing assemblies used must have a good running behavior, which requires precise production. A particularly relevant application in this regard is the pinion bearing unit of a car or truck Hinterachsgetriebes. In this application, the shaft of the pinion must be stored both radially and axially exactly, the bearing must absorb high axial forces. In most cases, such bearings consist of two by means of a shaft nut against each other employed tapered roller bearings in O or X arrangement. Occasionally, two biased angular contact ball bearings are used in this application.

In this case, a sleeve-like, solid part is often used, which has in its axial end portions grooves for receiving the two bearing outer rings. The sleeve-shaped part has a radially extending flange in an end region, so that the completely pre-assembled unit, consisting of pinion and pinion shaft, bearings and sleeve, inserted into the bore of a receiving housing and fixed in the flange with screws in the housing. The two inner rings of the bearings rest on the pinion shaft to be supported and are spaced apart by a sleeve. The bias is adjusted by a shaft nut which is screwed onto the one axial end of the pinion shaft.

There is a need, in particular the said bearings even cheaper to produce than before, while still ensuring that the pinion shaft to be stored is precisely and stably held in their desired position.

The invention is therefore based on the object, a bearing arrangement of the type mentioned in such a way that it is very simple and therefore inexpensive to produce and keeps the part to be stored precisely in high load conditions in position. The solution to this problem by the invention is characterized in that the sleeve-shaped body consists of at least one sheet metal part of substantially constant thickness, which is formed so that it forms at least one axial stop for at least one of the bearings.

Advantageously, it is thus achieved that a bearing-carrying element is formed by a simple Blechumformprozess that not only allows easy installation, for example in a housing bore, but at the same time ensures a precise spacing of the bearings in the axial direction.

A complex machining a carrier sleeve deleted; the sleeve-shaped body can be easily, quickly and inexpensively produced, for example by deep drawing.

A first development of the invention provides that the sleeve-shaped body consists of two sheet metal parts of substantially constant thickness, which are permanently connected to each other. This is particularly thought that the one part of the sleeve-shaped body has a hollow cylindrical shape, at the end of a radially extending flange is formed, and that the other part in its axial end portions hollow cylindrical portions for receiving a respective ring of the bearing and between the hollow cylindrical portions having a radially offset portion having a hollow cylindrical shape, wherein the transition between the hollow cylindrical portions in the axial end portions and the intermediate hollow cylindrical portion in each case forms an axial stop for each of the bearing (see Figure 1). It is advantageously provided that one part of the sleeve-shaped body and the other part are permanently connected to one another in at least one of the axial ends of the other part.

Another embodiment of the invention provides that the one part of the sleeve-shaped body has a hollow cylindrical shape, at the end of a radially extending flange is formed, and that the other part in its one axial end portion has a hollow cylindrical portion for receiving a ring of the bearing, which merges to form an axial stop for this bearing in a radially offset portion which has a substantially hollow cylindrical shape and forms at its axial end an axial stop for the other bearing (see Figures 2 and 4). In this solution, it may be provided that one part and the other part of the sleeve-shaped body are formed concentrically adjacent to each other over the essential axial extent of the other part. Alternatively, it is also possible that the one part and the other part of the sleeve-shaped body over a part of the axial extent of the other part are arranged concentrically with a radial distance from each other.

Furthermore, it can be provided in this solution that one part and the other part of the sleeve-shaped body in the axial end of the other part in the region of the hollow cylindrical portion of the other part are permanently connected to each other.

Another alternative embodiment of the invention provides that the one part of the sleeve-shaped body has two hollow cylindrical sections, which have different radial widths, wherein at the end of a hollow cylindrical

Section a radially extending flange is formed, and that the other

Part in its one axial end portion of a hollow cylindrical section to

Receiving a ring of one of the bearing, which merges to form an axial stop for this bearing in a radially offset portion which has a substantially hollow cylindrical shape and at its axial end an axial

Stop for the other camp forms (see Figure 5).

Advantageously, it is provided in this embodiment that the one part and the other part of the sleeve-shaped body in the axial region between the two bearings are permanently connected to each other. A further alternative embodiment of the invention is characterized in that the one part of the sleeve-shaped body has a hollow cylindrical shape for radially receiving a ring of one of the bearings, wherein at the end of the part a radially extending flange is formed, and that the other part in his axial hollow end portions having hollow cylindrical portions, wherein the one hollow cylindrical portion for receiving a ring of the bearing and the other hollow cylindrical portion for receiving the hollow cylindrical portion of the one part is formed, wherein between the hollow cylindrical portions a radially offset arranged portion is arranged with a hollow cylindrical shape and wherein the transition between the hollow cylindrical sections and the intermediate hollow cylindrical section in each case forms an axial stop for one of the bearings (see FIG. 3).

Preferably, it is provided in this solution that the hollow cylindrical portion of the one part of the sleeve-shaped body extends axially no further than over the axial extent of one of the bearings.

According to a further alternative embodiment of the inventive concept it is provided that the sleeve-shaped body is axially fixed on the shaft part, wherein it forms an axial end formed by beading of the sheet axial stop for one of the bearings at its one axial end and wherein at its other axial end a sheet metal ring is permanently set, which forms an axial stop for one of the bearings (see Figures 6 and 7).

A last alternative embodiment of the invention provides that the sleeve-shaped body is axially fixed in the bore of the housing, which forms at its one axial end formed by beading of the sheet axial stop for one of the bearings and wherein at its other axial end radially extending flange is formed, and that in the axial Area of the flange, a sheet metal ring is set permanently fixed to the sleeve-shaped body, which forms an axial stop for one of the bearings (see Figure 8).

In the two last-mentioned solutions can be provided according to the fact that the sleeve-shaped body between the axial stop formed by the flange and the axial stop forming sheet metal ring is under a biasing force.

Furthermore, a spacer sleeve can be arranged within the sleeve-shaped body between the bearings.

With particular advantage, it is provided that the said storage units, due to the biasing force generated during assembly, are completely pre-assembled and thus used ready to install and be mounted in a simple manner during assembly of a transmission or rear axle. The gearbox assembly can be considerably simplified and thus made cheaper. In particular, it is not necessary to take any measures during the gear assembly for the targeted generation of a biasing force.

In all the above solutions, in which the sleeve-shaped body consists of two sheet metal parts, it can be provided that the permanent connection between the parts of the sleeve-shaped body and possibly the sheet metal ring is a welded connection, in particular laser welding connection. Alternatively, the permanent compound may also be a solder joint, in particular a braze joint. Tapered roller bearings which are particularly preferably positioned in an O arrangement are preferably used as bearings in the proposal of the invention.

All embodiments of the invention are characterized in that the required sheet metal parts are produced in a very simple and therefore cost-effective manner can. Furthermore, the assembly process is very easy to carry out, so that the proposed bearing arrangement is particularly suitable for mass production. The particularly preferred application of the proposed bearing arrangement is the storage of the pinion shaft of a rear axle of a vehicle.

In the drawings, embodiments of the invention are shown. Show it:

FIG. 1 shows, in radial section, the pinion shaft of a passenger car together with its mounting and the housing receiving it;

FIG. 2 to FIG. 8 show further alternative embodiments of the bearing arrangement according to FIG. 1.

FIG. 1 shows a bearing arrangement 1 with which a shaft part 7 in the form of the pinion shaft of a car rear-axle transmission is mounted relative to a housing 6. For storage of the shaft part 7 two bearings 2 and 3 are used, which are designed as tapered roller bearings in O arrangement. The two bearings 2, 3 are arranged on the shaft part 7 at an axial distance from each other; they are fixed and prestressed on the shaft part 7 by a shoulder 25 of the shaft part 7 near the pinion, by a spacer sleeve 26 and by a shaft nut 27.

The inclusion of the two bearings 2, 3 in the bore 5 of the housing 6 takes place through a sleeve-shaped body 4. This is formed in two parts in the present case. A first, radially outer part 11 is designed as a hollow cylinder and has a radially outwardly extending flange 13 in its (right) axial end. The flange 13 can be fixed by means of screws 28 on the housing 6. A radially inner second part 12 of the sleeve-shaped body 4 has a total of three hollow cylindrical sections 14, 15 and 16. The two hollow cylindrical sections 14 and 15 form the axial ends of the second part 12 of the sleeve-shaped body 4. Between these two Sections 14, 15 is a radially inwardly staggered hollow cylindrical portion 16 is provided. By this axial stops 8 and 9 are defined, on which the outer rings of the two bearings 2, 3 can rest and be kept defined at an axial distance. The two parts 11, 12 of the sleeve-shaped body 4 are welded together in the two axial end portions of the radially inner part 12. The here forming welds are identified by the reference numerals 29 and 30.

Both the first sheet metal part 11 and the second sheet metal part 12 of the sleeve-shaped body 4 are made of sheet metal of constant thickness d.

The solution according to Figure 2 is characterized in that the first sheet metal part 11 of the sleeve-shaped body 4 is formed analogously. Here, however, the sheet metal part 11 in its one (left) axial end of an overlap 31, which surrounds the outer ring of the bearing 2 axially. The second sheet metal part 12 of the sleeve-shaped body 4 has here in its (right) axial end region - as in the solution according to Figure 1 - a hollow cylindrical portion 17 which merges to form an axial stop 9 in a radially inwardly offset arranged hollow cylindrical portion 18 , This section 18 defines at its axial end 19 an axial stop 10 for the outer ring of the bearing 2. In the area between the two bearings 2, 3 extend the two sheet metal parts 11 and 12 at a small radial distance x.

The solution according to FIG. 3 is characterized in that the first sheet-metal part 11 of the sleeve-shaped body 4 has only a small axial extension, which does not extend beyond the axial extent of the outer ring of the bearing 3. Both bearings 2, 3 are held by the second sheet metal part 12 of the sleeve-shaped body 4 at an axial distance, wherein the arranged in one (right) axial end of the hollow cylindrical Section 15 of the second

Sheet metal part 12 is formed so that it is the hollow cylindrical portion of the first Sheet metal part 11 engages radially from the outside. Both sheet metal parts 11, 12 are connected by welding (see weld 32) with each other permanently.

FIG. 4 shows a solution which is very similar to that according to FIG. Here, however, it is provided that the two sheet metal parts 11 and 12 of the sleeve-shaped body 4 in the region between the two bearings 2, 3 abut each other.

In the embodiment according to FIG. 5, it is provided that the sleeve-shaped body 4 is formed by two shaped sheet metal parts 11, 12, one of which radially surrounds one of the outer rings of one of the bearings 2, 3. The two sheet-metal parts 11, 12 are connected to each other by means of the weld 33 at a point which lies axially between the two bearings 2, 3.

The (left) bearing 2 is radially surrounded by the hollow cylindrical portion 17 of the second sheet metal part 12. By contrast, the first sheet-metal part 11 in its region adjoining the flange 13 has a hollow-cylindrical section 21 which radially surrounds the outer ring of the bearing 3 from the outside. The first sheet metal part 11 is placed (to the left) with a radially outwardly offset further hollow cylindrical

Section 20, whose end is welded to the hollow cylindrical portion 17 of the second sheet metal part 12 continues.

The application of the inventive concept to the bordering and fixing of the bearing inner rings can be seen in FIG. Here, the sleeve-shaped body 4 "is formed as a part, which is pushed onto the shaft part 7. In its one (left) axial end of the body 4" is beaded, whereby an axial stop 10 for the inner ring of the bearing 2 is defined. Between the two inner rings of the bearings 2, 3, a spacer sleeve 26 is arranged. The entire assembly consisting of body 4 ", the two bearing inner rings and the spacer sleeve 26 is connected by a welded sheet metal ring 22 into a unit, wherein before the welding of the sheet metal ring 22 on the sleeve-shaped body 4" a Preload force F is applied, so that a total of one ready to install unit forms.

The same applies to the embodiment according to FIG 7. The definition of the two inner rings of the bearings 2, 3 on the shaft part 7 takes place in a similar manner as in the solution according to FIG 6. Indes is for recording and defined

Spacing of the two bearing outer rings a sleeve-shaped body 4 'is used, which again defines the axial stops 8 and 9 for the bearing outer rings by a central radially inwardly offset hollow cylindrical section. In the present case, a sheet metal ring 34 in a (right) axial end of the sleeve-shaped body 4 'is welded to a flange for the determination of the bearing assembly on

To form housing 6.

The sheet-metal ring 22 welded to the sleeve-shaped body 4 "forms an axial stop 23 for the inner ring of the bearing 3 both in the solution according to FIG. 6 and in FIG. 7.

A last alternative embodiment is shown in FIG. There, a solution is provided for the outer rings of the two bearings 2, 3, as is intended in Figures 6 and 7 for the inner rings. The sleeve-shaped body 4 has in its one (left) axial end an overlap 35, which forms an axial stop 10 for the outer ring of the bearing 2. The two outer rings of the bearings 2, 3 are held by a spacer sleeve 24 at the desired distance. In order to obtain a prestressed unit here as well, after the application of a pretensioning force F in the bearing axis direction A, a sheet-metal ring 22 is firmly welded to the sleeve-shaped body 4. It also results in a ready to install unit, which merely needs to be inserted into the housing bore and then fixed by means of screws 28 on the housing 6. LIST OF REFERENCE NUMBERS

1 bearing arrangement

2 bearings

3 bearings

4 sleeve-shaped body

4 'sleeve-shaped body

4- sleeve-shaped body

5 hole

6 housing

7 shaft part

8 axial stop

9 axial stop

10 axial stop

11 first sheet metal part

12 second sheet metal part

13 flange

14 hollow cylindrical section

15 hollow cylindrical section

16 radially offset hollow cylindrical section

17 hollow cylindrical section

18 radially offset hollow cylindrical section

19 axial end

20 hollow cylindrical section

21 hollow cylindrical section

22 sheet metal ring

23 axial stop 24 spacer sleeve

25 shoulder

26 spacer sleeve

27 shaft nut

28 screw

29 weld

30 weld

31 Assault

32 weld

33 weld

34 sheet metal ring

35 attack

A bearing axis direction d Thickness of the sheet

X radial distance

F preload force

Claims

P atentanspr e ch e bearing arrangement

1. Bearing arrangement (1), consisting of two bearings (2, 3), which can be set against each other in Lagerachsrichtung (A), wherein the bearings (2, 3) in a sleeve-shaped body (4) are arranged in the bore ( 5) of a housing (6) or on a shaft part (7) is axially fixed, characterized in that the sleeve-shaped body (4, 4 ', 4 ") consists of at least one sheet metal part of substantially constant thickness (d), the reshaped in that it forms at least one axial stop (8, 9, 10) for at least one of the bearings (2, 3).

2. Bearing arrangement according to claim 1, characterized in that the sleeve-shaped body (4) consists of two sheet metal parts (11, 12) of substantially constant thickness (d), which are permanently connected to each other.

3. Bearing arrangement according to claim 2, characterized in that the one part (11) of the sleeve-shaped body (4) has a hollow cylindrical shape, at the end of a radially extending flange (13) is integrally formed, and that the other part (12) in its axial end portions hollow cylindrical

Sections (14, 15) for receiving in each case a ring of the bearings (2, 3) and between the hollow cylindrical sections (14, 15) has a radially offset portion (16) with a hollow cylindrical shape, wherein the transition between the hollow cylindrical sections (14, 15) in the axial End regions and the intermediate hollow cylindrical portion (16) each have an axial stop (8, 9) for each one of the bearings (2, 3) forms (Fig. 1).

4. Bearing arrangement according to claim 3, characterized in that the one part (11) of the sleeve-shaped body (4) and the other part (12) in at least one of the axial ends of the other part (12) are permanently connected to each other.

5. Bearing arrangement according to claim 2, characterized in that the one part (11) of the sleeve-shaped body (4) has a hollow cylindrical shape, at the end of a radially extending flange (13) is integrally formed, and that the other part (12) in its one axial end portion has a hollow cylindrical portion (17) for receiving a ring of the bearing (2, 3), forming an axial stop (9) for this bearing

(2, 3) merges into a radially offset portion (18) which has a substantially hollow cylindrical shape and at its axial end (19) an axial stop (10) for the other bearing (2, 3) forms (Fig. 2, 4).

6. Bearing arrangement according to claim 5, characterized in that the one part (11) and the other part (12) of the sleeve-shaped body (4) over the substantial axial extension of the other part (12) are formed concentrically adjacent to each other.

7. Bearing arrangement according to claim 5, characterized in that the one part (11) and the other part (12) of the sleeve-shaped body (4) over a part of the axial extent of the other part (12) concentric with a radial distance (x) are arranged to each other.

8. Bearing arrangement according to one of claims 5 to, characterized in that the one part (11) and the other part (12) of the sleeve-shaped body (4) in the axial end of the other part (12) in the region of the hollow cylindrical portion (17) the other part (12) are permanently connected to each other.

9. Bearing arrangement according to claim 2, characterized in that the one part (11) of the sleeve-shaped body (4) has two hollow cylindrical portions (20, 21) having different radial widths, wherein at the end of a hollow cylindrical portion (21) radially extending flange (13) is formed, and that the other part (12) in its one axial

Endbereich a hollow cylindrical portion (17) for receiving a ring of the bearing (2, 3), which merges to form an axial stop (9) for this bearing (2, 3) in a radially offset portion (18) in the has substantially hollow cylindrical shape and at its axial end (19) an axial stop (10) for the other bearing (2, 3) forms (Fig. 5).

10. Bearing arrangement according to claim 9, characterized in that the one part (11) and the other part (12) of the sleeve-shaped body (4) in the axial region between the two bearings (2, 3) are permanently connected to each other.

11. Bearing arrangement according to claim 2, characterized in that the one part (11) of the sleeve-shaped body (4) has a hollow cylindrical shape for radially receiving a ring of the bearing (2, 3), wherein at the end of the part (11) a radially extending flange (13) is formed, and that the other part (12) in its axial end portions hollow cylindrical portions (14, 15), wherein the one hollow cylindrical portion (14) for receiving a ring of the bearing (2, 3 ) and the other hollow cylindrical portion (15) for receiving the hollow cylindrical

Section of the one part (11) is formed, wherein between the hollow cylindrical sections (14, 15) a radially offset arranged portion (16) is arranged with a hollow cylindrical shape and wherein the transition between the hollow cylindrical sections (14, 15) and the intermediate hollow cylindrical section (16) each having an axial stop (8, 9 ) for each one of the bearings (2, 3) forms (Fig. 3).

12. Bearing arrangement according to claim 11, characterized in that the hollow cylindrical portion of the one part (11) of the sleeve-shaped body (4) extends axially no further than over the axial extent of one of the bearings (2, 3).

13. Bearing arrangement according to claim 1, characterized in that the sleeve-shaped body (4 ") on the shaft part (7) is fixed axially, wherein at its one axial end formed by beading of the sheet axial stop (10) for one of the bearings (2, 3) and wherein at its other axial end a sheet metal ring (22) is fixed permanently, which forms an axial stop (23) for one of the bearings (2, 3) (Fig. 6, 7).

14. Bearing arrangement according to claim 1, characterized in that the sleeve-shaped body (4) in the bore (5) of the housing (6) is axially fixed, wherein it has at its one axial end formed by beading of the sheet axial stop (10). for one of the bearings (2, 3) and wherein at its other axial end a radially extending flange (13) is integrally formed, and in that in the axial region of the flange (13) has a sheet metal ring (22) on the sleeve-shaped body (4) is permanently set, which forms an axial stop (23) for one of the bearings (2, 3) (Fig. 8).

15. Bearing arrangement according to claim 13 or 14, characterized in that the sleeve-shaped body (4, 4 ") between the axial stop formed by the flanging (10) and the axial stop (23) forming the sheet metal ring (22) is under a biasing force ,

16. Bearing arrangement according to claim 14 or 15, characterized in that within the sleeve-shaped body (4) between the bearings (2, 3) a spacer sleeve (24) is arranged.

17. Bearing arrangement according to one of claims 2 to 16, characterized in that the permanent connection between the parts (11, 12) of the sleeve-shaped body (4) and optionally the sheet metal ring (22) is a welded joint, in particular a laser welding connection.

18. Bearing arrangement according to one of claims 2 to 16, characterized in that the permanent connection between the parts (11, 12) of the sleeve-shaped body (4) and optionally the sheet metal ring (22) is a solder joint, in particular a brazed joint.

19. Bearing arrangement according to one of claims 1 to 18, characterized in that the two bearings (2, 3) are tapered roller bearings.

20. Bearing arrangement according to claim 19, characterized in that the two tapered roller bearings (2, 3) are positioned in an O arrangement.