Damping Valve For A Vibration Damper

Abstract

Damping valve having a damping valve body with at least one passage channel between two cover sides. An outlet opening of the passage channel leads into a cover-side annular channel which is limited by an outer annular valve support surface and by an inner annular valve support surface, the at least one annular valve support surface for at least one valve disk has a substantially constant width along the circumference, and the annular channel has a varying width along the circumference, and at least one valve support surface has a varying radius of curvature along the circumference.

Claims

1.-9. (canceled)

10. A damping valve comprising: two cover sides; a damping valve body with at least one passage channel between the two cover sides; an outer annular valve support surface; an inner annular valve support surface; and an outlet opening of the at least one passage channel that leads into a cover-side annular channel limited by the outer annular valve support surface and the inner annular valve support surface, wherein at least one of the outer annular valve support surface and the inner annular valve support surface for at least one valve disk has a substantially constant width along a circumference, wherein the annular channel has a varying width along the circumference, and wherein at least one of the outer annular valve support surface and the inner annular valve support surface has a varying radius of curvature along the circumference.

11. The damping valve according to claim 10, wherein the outer annular valve support surface has the varying radius of curvature.

12. The damping valve according to claim 10, wherein the inner annular valve support surface has the varying radius of curvature.

13. The damping valve according to claim 10, wherein the varying radius of curvature has two extreme values, a minimum R3 and a maximum R1, wherein the two extreme values have a distance of less than 180° along the circumference of at least one of the outer annular valve support surface and the inner annular valve support surface.

14. The damping valve according to claim 10, wherein the annular channel has at least one supporting segment for the at least one valve disk.

15. The damping valve according to claim 14, wherein the at least one supporting element has an arc shape.

16. The damping valve according to claim 14, wherein a distance of the at least one supporting segment from the inner annular valve support surface is less than the distance from the outer annular valve support surface in a region of a greatest width of the annular channel.

17. The damping valve according to claim 14, wherein the at least one supporting segment has a smaller height proceeding from the annular channel than at least one of the outer annular valve support surface and the inner annular valve support surface.

18. The damping valve according to claim 10, wherein the at least one valve disk has a constant outer diameter.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] The invention will be described more fully referring to the following description of the drawings.

[0019] In the drawings:

[0020] FIG. 1 is an installation situation of a damping valve;

[0021] FIG. 2 is an exploded view of the damping valve; and

[0022] FIG. 3 is a top view of the damping valve body according to FIG. 2.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS

[0023] FIG. 1 shows, by way of example, a section from a vibration damper 1 constructed as a two-tube damper that has a damping valve 7 between a working chamber 3 filled with damping medium and a compensation space 5. In principle, the damping valve 7 can also be used for a piston rod or as pre-valve for an adjustable damping valve. The possible applications are not limited to the graphic representation or the above-mentioned cases.

[0024] As can be seen more clearly when viewed in conjunction with FIG. 2, the damping valve 7 has a damping valve body 9 having two cover sides 11, 13. At least one passage channel 15, 17 connects the two cover sides 11, 13. In the present embodiment example, passage channels 15 are available for a first flow direction proceeding from the compensation space into the working chamber 3 and passage channels 17 are available for a flow proceeding from working chamber 3 into the compensation space 5. The quantity, shape and size of the passage channels are dependent, inter alia, on the diameter of the damping valve body 9. Simple circle cross sections or combinations of groove shapes and circle shapes can also be selected instead of the groove-shaped cross sections of the passage channels.

[0025] Outlet openings of the passage channels 15 lead into an annular channel 19 limited by an outer valve support surface 21 and inner valve support surface 23. At least one valve disk 25 is seated on this valve support surface. The outlet openings of the passage channels 17 are also covered by valve disks 27. The entire assembly of valve disks 25, 27 and damping valve body 9 is held together under a defined preloading by a bolt 29 with a locking ring 21. The outfitting of the damping valve body with valve disks depends on a targeted damping force characteristic so that this representation is likewise meant to be exemplary.

[0026] FIG. 3 shows the damping valve body 9 in a top view. As will now be seen more clearly, the passage channels 15, 17 are arranged on a common pitch circle for one flow direction in each instance. This arrangement is not compulsory. Within the scope of manufacturing tolerances, the valve support surfaces 21, 23 have a constant width. Consequently, viewed along the circumference of the valve support surfaces, the adhesive forces between the valve disk 25 and the valve support surfaces 21, 23 are substantially constant.

[0027] It can be seen clearly that the annular channel 19 has a varying width considered along the circumference and is accordingly formed asymmetrically with reference to the center point of the damping valve body 9, since at least one valve support surface 21, 23 has a varying radius of curvature along the circumference. In this graphic depiction, the outer valve support surface 21 has the varying radius of curvature along the circumference. In principle, the inner valve support surface could also have the varying radius of curvature. A combination of both valve support surface shapes would also be conceivable and meaningful.

[0028] In the example according to FIG. 3, the radius of curvature of the outer valve support surface has a maximum and a minimum. The distance between the two extreme values amounts to less than 180°. The outer valve support surface 21 is formed symmetrically with reference to a main axis 33. Proceeding from a center point of the valve body, the length of the main axis 33 for the valve support surface is R1+R2. R1 is greater than R2. The length of the normals 35 to the main axis 33 is two times R3 and is shorter than the main axis 33. The outer valve support surface has no radial offsets, resulting in an egg-shaped geometry of the valve support surface. The geometry can be constructed by drawing an arc with radius R1/2 around the center point and an arc with radius R1/2 opposite the latter. These two arcs are connected to one another tangentially via a connecting arc having a distance from the center point of 2×R3.

[0029] This geometry of the valve support surface 21 is meant only as an example of an asymmetrical shaping. A pentagon, for example, could also be used as foundation and the distances of the corner points from the center point could be configured differently and connected to one another as corner points along an arc contour.

[0030] During an incident flow proceeding from working chamber 3, the valve disk 25 is exposed to a bending load. In order to limit the bending of the valve disk 25 particularly in the area of the greatest width of the annular channel 19, the damping valve body 9 has at least one supporting segment 37 for the valve disk 25 in the annular channel 19. The at least one supporting segment 37 preferably has an arc shape. The distance of the supporting segment 33 from the center point of the damping valve body 9 is constant within the scope of manufacturing tolerance, i.e., the distance of the supporting segment 37 from the inner valve support surface 23 is less than the distance from the outer valve support surface 21 in the area of the greatest width of the annular channel 17. Accordingly, the supporting segment 37 divides the annular channel 17 into two circumferential regions of different width, wherein the region with the greatest width extends radially outside of the supporting segment 37. The supporting segments 37 are separated by the outlet openings of the passage channels 15.

[0031] Basically, the supporting segments 37 do not form any valve support surface comparable with the inner valve support surface 21 or outer valve support surface 23, since the front side of the supporting segments 37, proceeding from annular channel 17, has a smaller height than valve support surfaces 21, 23. Therefore, during an incident flow of the valve disk 25 proceeding from annular channel 17, there remains a smaller gap into which the damping medium can enter, and accordingly the entire region between the inner valve support surface 21 and the outer valve support surface 23 is available as pressure-impinged surface at the valve disk 25.

[0032] The valve disk 25 used has a constant outer diameter. As a result of the comparatively small dimensional difference between R1, R2 and R3, the valve disk projects radially only slightly over the outer valve support surface 21, particularly in region R1.

[0033] During an incident flow of the damping valve 7 proceeding from the compensation space 5, a pressure application point in the area of R1 lies slightly farther radially outside than along the further circumferential area of the annular channel. Therefore, the lever arm operative on the valve disk 25 is also the largest at the above-mentioned location corresponding to the distance from the center point of the valve disk 25. Consequently, the valve disk lifts in a defined manner in the area of R1 first and then progressively on both sides without discontinuities of force.