DE102014203200B4 - Damping element - Google Patents

Abstract

Damping element (1) for a vibration damper, with an annular flange (29) and annular side shells (3, 4) arranged on both sides of the flange (2), wherein a first energy storage device (13) is arranged between the flange (2) and a first side shell (3) for axially bracing the side shells (3) relative to the flange (2) and wherein a second energy storage device (14) is arranged between the flange (2) and the second side shell (4) for axially bracing the side shell (4) relative to the flange (2), wherein the side shells (3, 4) are arranged to be axially displaceable relative to one another and to overlap the flange (2) radially on the outside, the flange (2) has at least one wing (6) projecting in the radial direction on the outside, which wing extends through an opening (7) in at least one of the side shells (3, 4) and the flange (2) protrudes radially on the inside from the side shells (3, 4), characterized in that the first and/or the second side shell (3, 4) is arranged on its radially inner circumferential Edge (19,20) has a sealing lip (21,22) which seals against the flange (2) or comes close to it.

Description

The invention relates to a damping element of a vibration damper, in particular for the drive train of motor vehicles.

In motor vehicles, especially those with combustion engines, torsional vibrations occur during operation because the combustion engine does not produce a uniform torque development, but rather generates a torque shock during each combustion process in a cylinder.

For example, vibration dampers are used in the drive train of a motor vehicle to dampen the torsional vibrations in the drive train so that the noise caused by the torsional vibrations does not reach the vehicle cabin undamped and is perceived as unpleasant.

For example, so-called dual-mass flywheels have been created in which the flywheel of the internal combustion engine is divided by a spring damper into a primary flywheel and a secondary flywheel, whereby the spring damper dampens the vibration of the secondary flywheel relative to the primary flywheel.

To improve vibration damping, damping elements are used which isolate the vibration even better through friction damping. Such damping elements are designed as friction damping elements which are connected on the one hand to one of the components vibrating relative to one another and which, on the other hand, are supported by friction against at least one friction surface of another component of the components vibrating relative to one another. This causes friction with every relative movement of the components that can be moved relative to one another. The friction can also be delayed so that it only starts after a predefined clearance angle. The damping elements have two friction elements which are supported against the intended counter friction surface by means of a disc spring.

These damping elements are preferably arranged radially inside the springs of the vibration damper and are exposed to dirt and moisture, which also move under centrifugal force from radially inside to radially outside and penetrate into the damping elements.

From the revelations of EN 10 2012 212 174 A1 , US 2011/012 0831 A1 and EN 10 2012 216 363 A1 The person skilled in the art is familiar with corresponding damping elements in torsional vibration dampers.

It is the object of the invention to provide a damping element which at least reduces the disadvantages of the prior art and has an improved seal against dirt and moisture.

The object of the invention is solved with the features of claim 1.

An embodiment of the invention relates to a damping element, such as a friction damping element, in particular for a vibration damper, with an annular flange and annular side shells arranged on both sides of the flange, wherein a first energy accumulator is arranged between the flange and a first side shell for axially bracing the side shells against the flange and wherein a second energy accumulator is arranged between the flange and the second side shell for axially bracing the side shell against the flange, wherein the side shells are arranged to be axially displaceable relative to one another and overlap the flange radially on the outside, the flange has at least one wing projecting in the radial direction on the outside, which reaches through an opening in at least one of the side shells and the flange protrudes radially on the inside from the side shells, wherein the first and/or the second side shell has a sealing lip on its radially inner circumferential edge, which seals against the flange or comes close to it. As a result, the damping element is largely sealed from the radial inside so that little or no dirt and/or water can enter the damping element, which protects the elements of the damping device from corrosion and increased wear.

It is particularly useful if at least one side shell has a sealing lip adjacent to the opening for the flange wing to pass through, which lip rests against the flange wing or comes close to it. This seals the interior of the side shells in the area of the flange as well.

It is also expedient if the first side shell has an annular side surface in which recesses are made, with projections projecting in the axial direction being provided on the second side shell, with the projections radially extending over the outside of the flange and engaging in the recesses. This ensures displaceability with simultaneous guidance, so that the side shells can be displaced axially relative to one another, but are essentially fixed radially relative to one another.

It is also expedient if at least one of the projections is designed as a locking hook, which has a locking lug on its front end area, which rests against the edge of a recess. This ensures that the side shells cannot be lost during assembly.

It is also expedient if the locking lug is effected by a recess of the projection on its radially outer surface.

According to a further idea, it is advantageous if at least one of the projections is designed as a centering pin, which is designed with a bevel on the inside radially for contact with a wall of a recess. This achieves the clear position of the two side shells. The dimensions of the projections and/or recesses can also be selected so that the relative position of the two side shells is defined and relative rotation during assembly can be avoided.

It is also expedient if the flange has an S-shaped curved profile in cross section, wherein the first and/or the second side shell has an arcuate profile radially inward which follows the arcuate profile of the flange.

It is also useful if the side shells have a shoulder on their inner surface, against which a disc spring rests with its force edge. In this way, a certain degree of sealing is achieved by the disc springs themselves.

It is advantageous if at least one of the force accumulators or the two force accumulators have a substantially circular contour on their outer edge and/or on their inner edge.

It is also useful if the side shells have ring-shaped friction surfaces on their outer lateral surfaces. These serve to create friction with counter friction surfaces.

In this case, it is expedient if an at least substantially closed circular ring surface is formed as friction surfaces on both side shells, starting from the radially outer edge towards the radially inner side, by means of which the side shells are in frictional contact with counter friction surfaces of surrounding parts.

It is also advantageous if the flange has an internal toothing, wherein a spring-loaded ring element is arranged adjacent to the flange, which has tongues which engage in the toothing, wherein at least one side shell is arranged radially outside the ring element and is supported against the flange by means of a sealing lip.

It is particularly expedient if substantially all gaps between the flange and the side shells and/or in the contact areas of the side shells are minimized to such an extent that they are not larger than 2 mm.

The present invention is explained in more detail below using preferred embodiments in conjunction with the associated figures:

• 1 eine Ansicht eines Dämpfungselements,
• 2 eine Detailansicht des Dämpfungselements,
• 3 eine Detailansicht des Dämpfungselements,
• 4 eine Ansicht eines Schnitts durch das Dämpfungselement,
• 5 eine Ansicht eines Schnitts durch das Dämpfungselement,
• 6 eine Ansicht eines Schnitts durch das Dämpfungselement,
• 7 eine Ansicht eines Schnitts durch das Dämpfungselement,
• 8 eine erste Ansicht einer ersten Seitenschale,
• 9 eine zweite Ansicht einer ersten Seitenschale,
• 10 eine Ansicht einer zweiten Seitenschale, und
• 11 eine Detailansicht der zweiten Seitenschale.

Showing:

• 1 a view of a damping element,
• 2 a detailed view of the damping element,
• 3 a detailed view of the damping element,
• 4 a view of a section through the damping element,
• 5 a view of a section through the damping element,
• 6 a view of a section through the damping element,
• 7 a view of a section through the damping element,
• 8th a first view of a first side shell,
• 9 a second view of a first side shell,
• 10 a view of a second side shell, and
• 11 a detailed view of the second side shell.

The 1 shows a damping element 1, in particular for a vibration damper in the drive train of a motor vehicle. The damping element 1 has an annular flange 2 and two annular side shells 3, 4 arranged on both sides of the flange 2. The side shell 3 is in the 1 can be seen at the front, with the other, second side shell 4 being arranged behind the flange 2 and therefore in the 1 cannot be recognized.

The flange 2 has a toothing 5 radially inside and two wings 6 radially outside, which extend from the annular base body of the flange 2 in a radial direction outwards. In the embodiment of the 1 are two radially outward extending Wings 6 are provided which preferably engage between two energy accumulators as spring arrangements or between two arc springs in the installation situation of the vibration damper. The wings 6 protrude through openings 7 in at least one of the side shells 3, 4.

The 2 or the 3 each show an enlarged detailed view of the damping element 1 with the flange 2 with the internal toothing 5. The wings 6 protrude through openings 7 of the side shell 3, whereby the side shell 4 has no opening. In the area of the opening 7, both the side shell 4 and the side shell 3 have a sealing lip 8, 9. The side shell 3 also has a sealing lip 9 in the area of the opening 7, which, however, is in the 2 and 3 cannot be seen because it is located behind the flange shown.

The sealing lips 8, 9 protrude from the side shells 3, 4 essentially vertically or at least slightly inclined to the vertical and rest against the foot 10 of the wing 6 of the flange 2.

In 4 a section of the damping element 1 can be seen, in which the sealing lip 9 of the side shell 3 can also be seen in addition to the sealing lip 8 of the side shell 4. The sealing lips 8, 9 are essentially vertical or angled upwards to the vertical and rest against the foot 10 of the wing 6. The sealing lip 8 is essentially vertical, with the sealing lip 9 being arranged at an angle of 45°.

Adjacent to the flange 2 there is also an annular disk 11 which has elements 12 which engage in the toothing 5 of the flange 2 in order to avoid rattling when the toothing 5 is engaged by another toothed element, by pre-tensioning the annular disk 11 and the elements 12 with a spring and thus pre-tensioning the toothing which engages in the toothing 5.

In 4 It can also be seen that between the flange 2 and the respective side shell 3, 4 a force accumulator 13, 14 is provided, which in the embodiment of the 4 is designed as a disc spring. The disc spring preferably has a closed force edge on the radial inside and radial outside. The radially inner force edge of the force accumulator 13, 14 is supported on the flange 2 and the radially outer force edge of the force accumulator 13, 14 is supported on the respective side shell 3, 4 in the area of a shoulder 15, 16. As a result, the respective force accumulator 13, 14 acts on the respective side shell 3, 4 in the axial direction, so that in the event that the damping element 1 is arranged between two friction surfaces, the respective friction surface 17, 18 of the side shells 4, 3 comes into frictional contact with the corresponding friction surfaces as counter friction surfaces.

Radially inward, the side shells 3, 4 have a circumferential edge 19, 20 which has a sealing lip 21, 22 which seals against the flange. The sealing lip is arranged in such a way that it protrudes in the direction of the flange 2.

The 5 to 7 show various sectional views of the damping element 1, where the 5 the section according to line XX of the 1 show the 6 the section YY of the 1 and the 7 the section ZZ of the 1 .

The two side shells 3, 4 can be seen as they are arranged adjacent to the flange 2 and their sealing lips 21, 22 rest against the flange 2 radially on the inside or at least come close to it. Radially on the outside, the side shells 3, 4 overlap the flange 2, with the side shells 3, 4 having recesses 23 and projections 24 in the area radially outside the flange 2, with the projections 24 engaging in the recesses 23. The projections 24 are preferably attached to one of the side shells 3, 4, while the recesses 23 are provided on the other side shell 4, 3. This achieves axial displacement between the two side shells 3, 4, because the movement of the projections in the recesses of the side shells provides guidance.

The 8th , 9 show the side shell 3 with the recesses 23 and the radially arranged sealing lip 22. It can be seen that the sealing lip 22 has an offset on the side shell 3, so that the sealing lip 23 has a different positioning in the axial direction in different angular ranges of the annular side shell 3.

The 10 and 11 show the side shell 4 with the projections 24, wherein a part of the projections 24 are designed as projections with a bevel on their radially inner surface in order to act as a centering pin when joining the side shells 3, 4. The projections slide into the recesses 23 and center the two side shells 3, 4 relative to one another.

Some of the projections are designed as projections 25 as locking hooks, which have locking lugs 26 at their front end area, which are formed by a recess 27 of the projection 25. When the two side shells 3, 4 are put together, a A certain degree of cohesion can be ensured if the locking hooks engage and hook into the recesses 23.

As the figures show, the flange 2 has a partially S-shaped or double-S-shaped course from radially inside to radially outside, which serves to improve the rigidity of the flange and the installation space adaptation, wherein the first and/or the second side shell 3, 4 at least partially follows the arcuate course of the flange 2 and thus an improved sealing of the interior of the side shells 3, 4 can be ensured.

List of reference symbols

1

Damping element

2

flange

3

Side shell

4

Side shell

5

Gearing

6

wing

7

opening

8th

Sealing lip

9

Sealing lip

10

Foot

11

Ring disc

12

element

13

Energy storage

14

Energy storage

15

Paragraph

16

Paragraph

17

Friction surface

18

Friction surface

19

edge

20

edge

21

Sealing lip

22

Sealing lip

23

Recess

24

head Start

25

head Start

26

locking lug

27

Return

Claims (10)

Damping element (1) for a vibration damper, with an annular flange (29) and annular side shells (3, 4) arranged on both sides of the flange (2), wherein a first energy storage device (13) is arranged between the flange (2) and a first side shell (3) for axially bracing the side shells (3) relative to the flange (2), and wherein a second energy storage device (14) is arranged between the flange (2) and the second side shell (4) for axially bracing the side shell (4) relative to the flange (2), wherein the side shells (3, 4) are arranged to be axially displaceable relative to one another and overlap the flange (2) radially on the outside, the flange (2) has at least one wing (6) projecting in the radial direction, which extends through an opening (7) in at least one of the side shells (3, 4), and the flange (2) protrudes radially on the inside from the side shells (3, 4), characterized in that the first and/or the second side shell (3, 4) are arranged at their radially inner peripheral edge (19,20) has a sealing lip (21,22) which seals against the flange (2) or comes close to it. Damping element according to Claim 1 , characterized in that at least one side shell (3,4) adjacent to the opening (7) for the passage of the wing (6) of the flange (2) has a sealing lip (8,9) which rests against the wing (6) of the flange (2) or comes close to it. Damping element according to one of the preceding claims, characterized in that the first side shell (3, 4) has an annular side surface in which recesses (23) are made, wherein projections (24, 25) projecting in the axial direction are provided on the second side shell (4, 3), wherein the projections overlap the flange radially on the outside and engage in the recesses (23). Damping element according to one of the preceding claims, characterized in that at least one of the projections (25) is designed as a latching hook which has a latching nose (26) at its front end region which is supported against an edge of a recess (23). Damping element according to Claim 4 , characterized in that the locking lug (26) is effected by a recess (27) of the projection (25) on its radially outer surface. Damping element according to one of the preceding claims, characterized in that at least one of the projections (24) is designed as a centering pin which is formed radially on the inside with a bevel for contact with a wall of a recess (23). Damping element according to one of the preceding claims, characterized in that the flange (2) has an S-shaped curved profile in cross section, wherein the first and/or the second side shell (3, 4) has an arcuate profile radially inward which follows the arcuate profile of the flange (2). Damping element according to one of the preceding claims, characterized in that the side shells (3, 4) have a shoulder (15, 16) on their inner surface, on which a force accumulator (13, 14), such as a disc spring, is supported with its force edge. Damping element according to one of the preceding claims, characterized in that the side shells (3,4) have annular friction surfaces (17,18) on their lateral outer surfaces. Damping element according to one of the preceding claims, characterized in that the flange (2) has an internal toothing (5), wherein a spring-loaded ring element is arranged adjacent to the flange, which has tongues which engage in the toothing, wherein at least one side shell is arranged radially outside the ring element and is supported against the flange by means of a sealing lip.

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