DE102017111996A1 - bearing arrangement - Google Patents

Abstract

The invention relates to a bearing assembly 1 comprising an inner part 2 and an outer sleeve 3 and a stiffening structure 4, which is arranged on the inner part 2 in a radial direction r of the bearing assembly 1 to the outer sleeve 3, and an elastic material 5, in the radial direction r between the stiffening structure 4 and the outer sleeve 3 is arranged. The stiffening structure 4 has at least one projection 6 with a height A and a width B and at least one sole region 7 with a height C and a width D, wherein in an axial direction a of the bearing assembly 1, the sole regions 7 and projections 6 are arranged alternately. The projections 6 point in the radial direction r away from the outer surface 11 of the inner part 2. In the axial direction a of the bearing assembly 1, the height A of the projections 6 and / or the height C of the sole regions 7 is varied and / or the height A of the projections 6 and / or the height C of the sole regions 7 varies in a circumferential direction U.

Description

The invention relates to a bearing arrangement comprising an inner part and an outer sleeve and a stiffening structure and an elastic material according to the features of claim 1.

In many areas of technology, especially in the automotive industry, multifarious bearing arrangements are used. They are subject to various forces that introduce axial, radial, gimbal or torsional loads in a bearing assembly. In some cases, the bearing assemblies are loaded differently in different load directions, so that different stiffnesses of the bearing are required, for example, in the axial and radial directions of the bearing assembly.

In the EP 1 589 251 A1 a bearing arrangement is disclosed with an inner part, which has a wave contour on its outer lateral surface, and with an outer sleeve, which also has a wave contour on its inner lateral surface. By this configuration, a higher rigidity is set in the axial direction than in the radial direction. However, the axial load is significantly supported only on a wave crest and variability of the bearing assembly with respect to the adjustment of the stiffnesses for different loads is limited.

It is the object of the invention to provide a bearing assembly which has improved stiffness properties over the prior art.

This object is achieved by a bearing arrangement with the features of claim 1. Further advantageous embodiments of the invention are the subject of the dependent claims 2 to 12.

The invention relates to a bearing assembly comprising an inner part and an outer sleeve and a stiffening structure, which is arranged on the inner part in a radial direction of the bearing assembly to the outer sleeve, and an elastic material which is arranged in the radial direction between the stiffening structure and the outer sleeve. The stiffening structure has at least one projection with a height A and a width B and at least one sole area with a height C and a width D wherein in an axial direction of the bearing assembly, the sole portions and projections are arranged alternately, wherein the projections in the radial direction away from the outer surface of the inner part and wherein in the axial direction of the bearing assembly, the height A the projections and / or the height C the sole areas is varied and / or the height A the projections and / or the height C the sole region is varied in a circumferential direction.

The basic idea of the invention is that the stiffening structure is geometrically designed so that the occurring loads of a specific load case can be optimally absorbed. The bearing assembly is then tailored to the expected load cases.

Usually, such bearing assemblies, which are particularly suitable for motor vehicles, largely cylindrical in shape. As the axial direction is considered in the invention a direction parallel to the height of the cylinder, a radial direction is considered in a corresponding manner as a direction parallel to a radius of the cylinder.

The bearing arrangements may be, for example, rubber bearings, rubber-metal bearings or plain bearings.

The inner part can be designed as a cylindrical sleeve or as a cylindrical bolt. The outer sleeve is usually also a cylindrical sleeve. Both components can be made of metallic materials or of plastic.

The elastic material is ideally cohesively connected to the adjacent components of the bearing assembly, for example, anvulkansiert or glued. The elastic material can also be injected into the bearing assembly.

On the outer surface of the inner part is followed by a stiffening structure in the radial direction. The stiffening structure has at least one projection, which in the radial direction by a height A and in the axial direction by a width B is characterized. In the axial direction, sole regions are arranged alternately to the projections, which also extend through a height C and a width D are characterized.

The stiffening structure may for example be made of a metallic material or plastic.

The heights of protrusions and sole regions are measured from the outer surface of the inner part. Basically, the height means the maximum extent of the projections or sole regions in the radial direction. It is thus possible that the respective radial extent varies over the width of a projection or sole region. In particular, in the projections, it is also possible that the axial extent the projections on the height changes, for example, the projections to its radial, pointing to the outer sleeve end are successively narrower. Then, the width of the protrusions is understood to mean an average extent in the axial direction.

In the axial direction, projections and sole regions alternate, it is irrelevant whether a projection or a sole region is arranged in axial end regions of the bearing arrangement. The bearing arrangement preferably has at least one projection and two sole regions or two projections and a sole region.

By the variation of the height A the projections and / or the height C the sole regions in the axial direction, it is possible to optimally adjust the stiffness of the bearing assembly for a variety of load cases. For example, there is a varying radial stiffness in the axial direction. By appropriate design of the sequence of different height projections and / or sole areas axial, radial, torsional or gimbal loads can be met.

By a variation of the height A the projections and / or the height C The sole areas in a circumferential direction, in particular while maintaining a round inner part and a round outer sleeve, resulting in different thicknesses over the circumference and thus different radial or cardanic stiffnesses for the elastic material.

Preferably, the height increases A the projections and / or the height C the sole regions from a first axial end of the bearing assembly to a second axial end. That means, for example, that the height A the projections from one axial end to successively from projection to projection becomes larger and the greatest height at the other axial end of the bearing assembly is achieved.

Further preferred, the height A the projections and / or the height C the sole areas in the axial direction to a minimum value. That means, for example, that the height A the projections of an axial end of successively from projection to projection becomes smaller. After reaching the projection with the smallest height, the height decreases A the projections to the other axial end of the bearing assembly back towards gradually again.

Further preferred, the height A the projections and / or the height C the sole areas in the axial direction to a maximum value. That means, for example, that the height A the protrusions gradually increase from one axial end to the other. After reaching the projection with the greatest height, the height decreases A the projections to the other axial end of the bearing assembly again successively from.

But beyond that, any course of the heights of protrusions and / or sole areas is possible. The variation of the heights can be linear, exponential or parabolic. Several maximum or minimum values can be provided.

In a further particular embodiment of the invention is in the axial direction of the bearing assembly, the width B the protrusions and / or the width D the sole areas varies. The widths of the protrusions and sole regions provide another parameter to adjust the local stiffnesses of the bearing assembly. It can be provided, for example, that the width B the protrusions varies and the width D the sole areas remain constant. For example, it may also be provided that the width is relative to a plane which is perpendicular to the axial direction B the protrusions and / or the width D the sole areas are asymmetrically varied.

Furthermore, it is preferably provided that the height A the projections and / or height C the sole areas in the circumferential direction is elliptical or oval varies. By this measure, the arrangement according to the invention can also be optimized adapted to the installation situation in the vehicle and the resulting loads. By rotating the bearing assembly in the installed position, with a geometric design and different load cases can be considered.

In addition to an elliptical or oval embodiment, further embodiments are possible. Thus, for example, over a circumferentially alternating height A the projections and / or height C the sole areas a kind of gear structure are generated, which additionally causes a rotation.

Furthermore, provision may be made for a second stiffening structure with second projections and second sole areas to be arranged between the elastic material and the outer sleeve, wherein the projections point away from the inner surface of the outer sleeve in the radial direction.

Preferably, the projections of the stiffening structure and the second projections of the second stiffening structure are designed to be overlapping in the axial direction. That is, the protrusions of one stiffening structure are disposed opposite to a sole region of the other stiffening structure and project into the region between two protrusions of the other stiffening structure.

More preferably, the second stiffening structure is executed complementary to the stiffening structure. This means that each projection and each sole region of the one stiffening structure is assigned one sole region and one projection of the other stiffening structure. However, it is not necessary that the heights and widths of the projections and sole structures are formed with corresponding dimensions.

By using a second stiffening structure in a bearing arrangement according to the invention, in particular the axial rigidity is increased.

In a further embodiment, it is provided that the stiffening structure is configured in one piece and with the same material as the inner part. This has the advantage that fewer parts must be installed in the production of the bearing assembly. A joining of the inner part with the stiffening structure as an additional step is eliminated.

In the context of the invention, it is also possible that the stiffening structure is designed as a separate component. This has advantages in terms of the choice of materials, since the stiffening structure can be designed independently of the rest of the bearing assembly and designed in terms of stiffness requirements.

In particular, the stiffening structure is arranged at a distance from the inner part. This is necessary in particular in the case of a bearing arrangement constructed as a slide bearing. The resulting gap between the inner part and the stiffening element may for example be filled with a lubricant or lubricant.

The above-mentioned embodiments of the stiffening structure can be readily transferred to the second stiffening structures in connection with the outer sleeve. There is also a corresponding dimensioning of the heights and widths of second projections or second sole areas possible, as well as, for example, a one- or multi-part design of the second stiffening structure with the outer sleeve.

Furthermore, it has proven to be advantageous if provided at the axial ends of the bearing assembly lenses. These mostly circular discs are pressed onto the inner part and serve as a stop in the axial direction.

Further features will become apparent from the following drawings. Identical or corresponding features are provided with identical reference numerals.

• 1 ein erstes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 2 ein zweites Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 3 ein drittes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 4 ein viertes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 5 ein fünftes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 6 ein sechstes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 7 ein siebtes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 8 ein achtes Ausführungsbeispiel für eine erfindungsgemäße Lageranordnung
• 9 ein neuntes Ausführungsbeispiel für eine Lageranordnung mit Variation der Versteifungsstruktur im Umfangsrichtung
• 10 das Ausführungsbeispiel der 9 im Querschnitt

Show it

• 1 a first embodiment of a bearing assembly according to the invention
• 2 A second embodiment of a bearing arrangement according to the invention
• 3 a third embodiment of a bearing assembly according to the invention
• 4 A fourth embodiment of a bearing assembly according to the invention
• 5 a fifth embodiment of a bearing assembly according to the invention
• 6 a sixth embodiment of a bearing arrangement according to the invention
• 7 a seventh embodiment of a bearing assembly according to the invention
• 8th an eighth embodiment of a bearing assembly according to the invention
• 9 A ninth embodiment of a bearing assembly with variation of the stiffening structure in the circumferential direction
• 10 the embodiment of 9 in cross section

A first embodiment of a bearing arrangement according to the invention 1 shows 1 , Here, as in all other figures, only part of the bearing assembly 1 shown, which is cylindrical about an axis of symmetry 8th is executed.

The bearing arrangement 1 includes an inner part 2 , in the form of a cylindrical, metallic sleeve and an outer sleeve 3 and a stiffening structure 4 attached to the inner part 2 in a radial direction r the bearing arrangement 1 to the outer sleeve 3 is arranged. An elastic material 5 is in the radial direction r between the stiffening structure 4 and the outer sleeve 3 arranged, the stiffening structure 4 several projections 6 with a height A and a width B as well as several sole areas 7 with a height C and a width D having. In an axial direction a the bearing arrangement 1 are the sole areas 7 and projections 6 arranged alternately, wherein the projections 6 in the radial direction r from the outside surface 11 of the inner part 2 point away. In the axial direction a the bearing arrangement 1 is the height A the projections 6 varied. Specifically, the height indicates A the projections 6 in the axial direction a a maximum value. At a first axial end 9 the bearing arrangement 1 is a lead 6 with a height A arranged. In the axial direction a alternately follow several sole areas 7 and projections 6 , where the height A of the projections 6 steadily increases while the altitude C the sole areas 7 stays the same. The height A the projections 6 reached in the middle of the bearing assembly 1 a maximum value and then takes to a second axial end 10 the bearing arrangement 1 out again.

The stiffening structure 4 is one of the inner part 2 separate component and not designed in one piece with this. This offers the advantage that the stiffening structure can be adapted in terms of material to the existing rigidity requirements.

The stiffening structure may be embodied in this example as a plastic component, which is produced for example by casting or injection molding technology.

A bearing arrangement 1 according to 1 is suitable for applications where axially rigid and gimbal soft bearings are necessary.

The embodiment in 2 indicates an opposite course of the height A the projections 6 on. Here are the projections 6 at the first axial end 9 and second axial end 10 the bearing arrangement 1 are arranged with the greatest height A fitted. In the axial direction a to the center of the bearing assembly 1 the height decreases A always further and finally reaches a minimum value in the middle. The height C the sole areas 7 remains, however, over the entire length of the bearing assembly 1 constant. Again, the stiffening structure 4 between a sleeve-shaped inner part 2 and an equally cylindrical outer sleeve 3 arranged between the stiffening structure 4 and the outer sleeve 3 another elastic material 5 is arranged.

A bearing arrangement 1 according to 2 is suitable for applications where axially rigid and gimbal stiff bearings are necessary.

In the 3 shown bearing assembly shows a steadily increasing profile of the height A the projections 6 from a first end 9 to a second end 10 the bearing arrangement 1 , The height C the sole areas 7 remains constant.

A bearing arrangement 1 according to 3 is suitable for applications where one-sided axially stiff bearings are necessary.

The bearing arrangement 1 according to the embodiment in 4 indicates a variation of height C the sole areas 7 on while the height A the projections 6 remains constant. The bearing arrangement 1 includes an inner part 2 , an outer sleeve 3 and a stiffening structure 4 attached to the inner part 2 in a radial direction r the bearing arrangement 1 to the outer sleeve 3 is arranged. An elastic material 5 is in the radial direction r between the stiffening structure 4 and the outer sleeve 3 arranged, the stiffening structure 4 several projections 6 with a height A and a width B as well as several sole areas 7 with a height C and a width D having. In an axial direction a the bearing arrangement 1 are the sole areas 7 and projections 6 arranged alternately, wherein the projections 6 in the radial direction r from the outside surface 11 of the inner part 2 point away. In the axial direction a the bearing arrangement 1 is the height C the sole areas 7 varied. Specifically, the height indicates C the sole areas 7 in the axial direction a a maximum value. At a first axial end 9 the bearing arrangement 1 is a lead 6 with a height A arranged. In the axial direction follows a sole area 7 with a height C and subsequently alternately several sole areas 7 and projections 6 , where the height C the sole areas 7 steadily increases while the altitude A the projections 6 remains constant. The height C the sole areas 7 reached in the middle of the bearing assembly 1 a maximum value and then takes to a second axial end 10 the bearing arrangement 1 out again.

A bearing arrangement 1 according to 4 is suitable for applications where axially rigid and gimbal soft bearings are necessary.

In 5 is a bearing arrangement 1 with a contrary course of height C the sole areas 7 shown. Again, in the axial direction a projections 6 with constant height A alternating with sole areas 7 arranged. The first each at the first axial end 9 and second axial end 10 arranged sole areas 7 have the highest altitude C on. To the middle of the bearing arrangement 1 the height decreases C the sole areas 7 gradually from and finally reached in the middle of the bearing assembly 1 a minimum value.

A bearing arrangement 1 according to 5 is suitable for applications where compared to the execution in 4 a stiffening of the highly loaded axial ends 9 . 10 necessary is. Such a bearing arrangement 1 is stabilized against kinking and / or bumps.

In the 6 shown bearing assembly shows a steadily increasing profile of the height C the sole areas 7 from a first end 9 to a second end 10 the bearing arrangement 1 , The height A the projections 6 remains constant.

A bearing arrangement 1 according to 5 is suitable for applications where one-sided axially stiff soft bearings are necessary, the inner part 2 is stabilized.

An embodiment with a second stiffening structure 12 is in 7 shown. This embodiment is based on an embodiment of the bearing assembly 1 as in 1 shown. Between the elastic material 5 and the outer sleeve 3 is a second stiffening structure 12 with second protrusions 14 with a height e and a width F and second sole areas 15 with a height G and a width H is arranged, wherein the projections 14 in the radial direction r from an inner surface 13 the outer sleeve 3 point away.

The second sole areas 15 the second stiffening structure 12 are in the radial direction r opposite the projections 6 the stiffening structure 4 arranged. The second projections 14 the second stiffening structure 12 are opposite the sole areas 7 the stiffening structure 4 arranged. This results in a complementary embodiment of the stiffening structures 4 . 12 , At the same time are the heights A . e the projections 6 . 14 so dimensioned, that in each case a projection 6 . 14 between two radially opposite projections 6 . 14 protrudes. In the axial direction a considered are the projections 6 the stiffening structure 4 and the second protrusions 14 the second stiffening structure 12 formed overlapping.

Also on the embodiment according to 1 Based on the embodiment according to 8th , Unlike the embodiment according to 1 but is the stiffening structure 4 spaced from the inner part 2 arranged. The resulting gap 17 is filled with a lubricant, which is a low-friction sliding movement of the stiffening structure 4 opposite the inner part 2 allows. The entire outer construction of the bearing assembly 1 comprising stiffening structure 4 , elastic material 5 and outer sleeve 3 is thus rotatable about the inner part 2 stored.

At the same time, the bearing assembly 1 with two lenses 16 provided at the first axial end 9 and the second axial end 10 the bearing arrangement 1 serve as a stop. The lenses 16 are on the inner part 2 pressed and thus form a press fit and are held captive.

An embodiment of the invention, in which the height A the projections 6 and the height C the sole areas 7 in a circumferential direction U is varied, is the subject of 9 and 10 , In 10 is a longitudinal section through the corresponding bearing assembly 1 to see. It can be seen that the height A the projections 6 and the height C the sole areas 7 here in the axial direction is not varied. The variation of the height A the projections 6 and the height C the sole areas 7 is in the cross-sectional view in 10 clear. The stiffening structure 4 is in the circumferential direction U elliptical shaped. Both the projection shown 6 as well as the sole area 7 have an elliptical cross-section. The lead 6 is in the circumferential direction U through a maximum height A _max and a minimum height amine marked. In the same way, the sole area 7 by its maximum height C _max and minimum height C _min described.

Other possible, but not shown embodiments provide that the bearing assembly 1 a variation of height A the projections 6 and the height C the sole areas 7 both in the axial direction a as well as in the circumferential direction U having. For example, each of the embodiments of the 1 to 8th with the embodiment of 9 and 10 be combined.

Also, a second stiffening structure may also be used 12 as in 7 shown configured so that the second projections 14 with one in the circumferential direction U variable height e and a width F and / or the second sole areas 15 with a variable in the circumferential direction U height G and a width H are executed.

LIST OF REFERENCE NUMBERS

1

bearing arrangement

2

inner part

3

outer sleeve

4

stiffening structure

5

elastic material

6

head Start

7

sole area

8th

axis of symmetry

9

first axial end

10

second axial end

11

Outer surface of 2

12

second stiffening structure

13

Inner surface of 3

14

second lead

15

second sole area

16

lens

17

gap

A

Height of 6

A _max

maximum height of 6

A _min

minimum height of 6

B

Width of 6

C

Height of 7

C _max

maximum height of 7

C _min

minimum height of 7

D

Width of 7

e

Height of 14

F

Width of 14

G

Height of 15

H

Width of 15

a

axial direction

r

radial direction

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 1589251 A1 [0003]

Claims (12)

Bearing arrangement (1) comprising an inner part (2) and an outer sleeve (3) and a stiffening structure (4) which is arranged on the inner part (2) in a radial direction r of the bearing assembly (1) to the outer sleeve (3), as well an elastic material (5) which is arranged in the radial direction r between the stiffening structure (4) and the outer sleeve (3), wherein the stiffening structure (4) at least one projection (6) having a height A and a width B and at least one Sole region (7) having a height C and a width D, wherein in an axial direction a of the bearing assembly (1) the sole regions (7) and projections (6) are arranged alternately, wherein the projections (6) in the radial direction r of the outer surface (11) of the inner part (2) wegweisen characterized in that in the axial direction a of the bearing assembly (1) the height A of the projections (6) and / or the height C of the sole regions (7) is varied and / or the height A of the projections ( 6) and / or the height C of the sole regions (7) in a circumferential direction U is varied. Bearing arrangement (1) according to Claim 1 characterized in that the height A of the projections (6) and / or the height C of the sole regions (7) from a first axial end (9) of the bearing assembly (1) to a second axial end (10) increases. Bearing arrangement (1) according to Claim 1 characterized in that the height A of the projections (6) and / or the height C of the sole regions (7) in the axial direction a has a minimum. Bearing arrangement (1) according to Claim 1 characterized in that the height A of the projections (6) and / or the height C of the sole regions (7) in the axial direction a has a maximum. Bearing arrangement (1) according to one of Claims 1 to 4 characterized in that in the axial direction a of the bearing assembly (1) the width B of the projections (6) and / or the width D of the sole regions (7) is varied. Bearing arrangement (1) according to one of Claims 1 to 5 characterized in that the height A of the projections (6) and / or height C of the sole regions (7) in the circumferential direction U is elliptical or oval varies. Bearing arrangement (1) according to one of Claims 1 to 6 characterized in that a second stiffening structure (4) with second projections (14) and second sole regions (15) is arranged between the elastomer and the outer sleeve (3), the second projections (14) being in the radial direction r from the inner surface (13) of FIG Point outer sleeve (3) away. Bearing arrangement (1) according to Claim 7 characterized in that the projections (6) of the stiffening structure (4) and the second projections (14) of the second stiffening structure (12) are designed to be overlapping in the axial direction a. Bearing arrangement (1) according to Claim 7 or 8th characterized in that the second stiffening structure (12) is complementary to the stiffening structure (4). Bearing arrangement (1) according to one of Claims 1 to 9 characterized in that the stiffening structure (4) is designed in one piece and with the same material as the inner part (2). Bearing arrangement (1) according to one of Claims 1 to 9 characterized in that the stiffening structure (4) is designed as a separate component and in particular spaced from the inner part (2) is arranged. Bearing arrangement (1) according to one of Claims 1 to 11 characterized in that at the axial ends (9, 10) of the bearing assembly (1) end plates (16) are provided.

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