WO1999061815A1

WO1999061815A1 - Active oscillation damper

Info

Publication number: WO1999061815A1
Application number: PCT/EP1999/002541
Authority: WO
Inventors: Mathias Gugsch
Original assignee: Btr Avs Technical Centre Gmbh
Priority date: 1998-05-27
Filing date: 1999-04-15
Publication date: 1999-12-02
Also published as: DE19823716A1

Abstract

The invention relates to an active oscillation damper comprising a magnetically excitable damping material (14, 15, 16) fixed on a support (11) by means of interspaced leaf springs (20, 21), whereby the damping material (14, 15, 16) can be moved back and forth in a direction perpendicular to the leaf springs (20, 21) in such a way that the movements of the support (11) in said direction are suppressed at least in part, whereby the leaf springs (20, 21) have at least two arms (35) bent in the shape of a spiral and running from the outer (32) to the inner area (33) of the leaf springs (20, 21).

Description

Active vibration absorber

The invention relates to an active vibration damper with a magnetically excitable damper mass which is fastened to a support by means of mutually parallel, spaced leaf springs, the damper mass being movable to and fro in a direction perpendicular to the leaf springs in such a way that movements of the support in this direction at least partially suppressed.

Such a vibration damper is used in particular in engine mounts for motor vehicles and suppresses vibrations emanating from the engine. The vibration damper is usually attached to the body side.

A vibration damper of the type mentioned is known from JP-A 6-58368. This publication describes an active vibration damper with a magnetically excitable door mass. The absorber mass is fastened to a support designed as a housing by means of two leaf springs spaced apart from one another and can oscillate in a direction perpendicular to the leaf springs. For magnetic excitation, the absorber mass has a magnet and an air gap into which a moving coil attached to the support engages. A magnetic field is generated by applying an electric current to the moving coil the magnet of the absorber mass acts. This sets the absorber mass in motion. The movement of the absorber mass serves to at least partially suppress movements of the support in the same direction. A disadvantage of this known vibration damper is that the absorber mass can only make small movements, since the deformable length of the leaf springs is only very small. In order to achieve satisfactory movements, the support surrounding the absorber mass must be made large so that the entire vibration damper has large dimensions.

Another active vibration damper is known from DE 43 01 845 C1. This document describes an active vibration damper with a magnetically excitable damper mass, which is attached to a support by leaf springs spaced apart. The absorber mass is provided with an additional guide opposite the support. This guide must be worked very precisely to ensure good mobility of the absorber mass and to prevent tilting.

DE 1 96 05 551 A1 describes an active vibration damper with a magnetically excitable damper mass which is fastened to a support by means of several segment-like leaf spring elements. Each of the leaf spring elements is connected at one end to the absorber mass and at the other end to the support. A disadvantage of this construction is the large number of connection points required between the leaf spring segments and the absorber mass and the support. The object of the present invention is therefore to develop an active vibration damper of the type mentioned at the outset such that a large movement path for the damper mass is achieved with small dimensions.

According to the invention, to achieve this object it is provided that the leaf springs have at least two spirally curved leaf spring arms which extend from an outer region to an inner region of the leaf springs.

The invention is based on the fact that the possibility of movement of the absorber mass is determined by the deformable length of the leaf springs. This deformable length is increased by the spiral design of the leaf spring arms without changing the overall dimensions of the vibration damper. At the same time, great rigidity in the radial direction is achieved. An additional guidance of the absorber mass in relation to the support is therefore not necessary. The vibration damper according to the invention allows the use of one-piece leaf springs, so that the assembly effort can be minimized.

Advantageous further developments and refinements of the invention emerge from the subclaims.

In an advantageous embodiment, the leaf spring arms are involute-curved. In this way, a maximum length of the leaf spring arms is achieved, and the diameter of the leaf spring can be kept small. The leaf springs preferably have three leaf spring arms which are bent in a spiral shape and distributed uniformly over the circumference. Very good radial guidance of the absorber mass is achieved by using three leaf spring arms.

The inner area of the leaf springs advantageously has an opening for attachment to the absorber mass. In an advantageous development, clamping rings engage in these openings and can be fixed to the absorber mass. Leaf springs and absorber mass are reliably held together and centered through the openings and the clamping rings.

In an advantageous embodiment, the absorber mass has a central inner bore, which is penetrated by a screw for fastening the clamping rings, one clamping ring receiving the head of the screw and the other clamping ring having an internal thread into which the screw engages. The clamping rings can thus be easily clamped against each other by the screw.

In an advantageous further development, the damper mass has cylindrical, centrally arranged projections onto which spacers are attached. The inner areas of the leaf springs are clamped between the spacers and the clamping rings. With this configuration, the distance between the attachment points of the leaf springs on the absorber mass can be varied by using different spacers. Changes to the absorber mass or the clamping rings are not necessary. The outer areas of the leaf springs are advantageously clamped to the support. This results in a simple assembly of the leaf spring on the support.

In an advantageous further development, the outer regions are clamped between a coil carrier and a cover, which are rigidly attached to the support. The bobbin is used to attach a bobbin, while the lid provides protection against dirt, dust and moisture. Separate fastening elements are not required, so that the overall weight of the vibration damper according to the invention is reduced and assembly is made easier.

To set the distance between the fastenings of the leaf spring on the support side, a spacer tube arranged between the leaf springs and on which the coil carrier rests is advantageously provided. The distance between the supports on the leaf spring supports corresponds to the total length of the spacer tube and coil holder. This distance can be changed quickly and easily by changing the spacer tube.

In an advantageous embodiment, the support has a jacket for receiving and guiding the leaf springs, the spacer tube, the bobbin and the cover. All of the components mentioned are accommodated in the jacket and are aligned and guided concentrically to one another by this. For assembly, the individual elements only have to be inserted into the jacket. The centering takes place automatically, so that the assembly is simplified. At the same time, the jacket serves as protection against dirt, dust and moisture. In an advantageous further development, the jacket has an extension on its inside as a stop for a first leaf spring. This approach ensures a defined position of the first leaf spring in relation to the support. The spacer tube, the bobbin, the second leaf spring and the cover are placed on the first leaf spring. All components are thus in a defined position in relation to the shoulder and thus to the support.

The absorber mass advantageously has a magnet and two masses which enclose the magnet between them. This configuration allows the use of a relatively small magnet, so that the costs for the absorber mass are reduced.

The absorber mass advantageously forms a gap into which a coil engages for the magical excitation of the absorber mass. Due to the very good radial guidance of the absorber mass, a particularly narrow air gap can be achieved, which is an advantage for a good energy yield.

The invention is explained in more detail below on the basis of exemplary embodiments, which are shown schematically in the drawing. It shows:

1 shows a cross section through an active according to the invention

Vibration absorber; Figure 3 is a plan view of a leaf spring.

Figure 2 shows a section along the line II-II in Figure 1;

FIG. 4 shows an enlargement of the detail X from FIG. 1;

FIG. 5 shows an enlargement of the detail Y from FIG. 1; Figure 1 shows an active vibration damper 1 0 with a support 1 1, which has a jacket 1 2 with an inner shoulder 1 3. The jacket 1 2 delimits an interior in which a damper mass is arranged which has a magnet 1 4 and two masses 1 5, 1 6 adjoining the magnet. The absorber mass 1 4, 1 5, 1 6 forms a gap 1 7, in which a coil 1 8 engages. The coil 1 8 is attached to a coil support 1 9.

Two mutually parallel spaced leaf springs 20, 21 are provided for fastening and guiding the damper mass 1 4, 1 5, 1 6. The leaf springs 20, 21 are attached to the absorber mass 1 4, 1 5, 1 6 with an inner region 33 and to the support 1 1 with an outer region 32. Spacers 23, 24 and a spacer tube 22 connected to the damper mass 1 4, 1 5, 1 6 are used to adjust the distance between the leaf springs 20, 21.

Clamping rings 25, 26 are provided for fastening the leaf springs 20, 21 to the absorber mass 1 4, 1 5, 1 6. These clamping rings 25, 26 pass through an opening 39 in the inner region 33 of the leaf springs 20, 21 (cf. FIG. 5). The inner regions 33 of the leaf springs 20, 21 are accommodated between the clamping rings 25, 26 and the associated spacers 23, 24. To fasten the clamping rings 25, 26 to the absorber mass 1 4, 1 5, 1 6, a screw 27 is provided which passes through an inner bore 28 in the mass 1 5. The upper clamping ring 26 receives the screw head, while the lower clamping ring 25 has an internal thread 42 into which the screw 27 is screwed. By tightening the screw 27, the clamping rings 25, 26 are braced against each other and thus press the inner regions 33 of the Leaf springs 20, 21 on the spacers 23, 24 and the spacers 23, 24 on the mass 1 5.

The spacers 23, 24 are seated on centrally arranged, cylindrical projections 40, 41 of mass 1 5 and are thus aligned concentrically with absorber mass 1 4, 1 5, 1 6. The clamping rings 25 26 engage in inner recesses of the spacers 23, 24 and are thereby centered. The centering of the leaf springs 20, 21 takes place by the inner region 33 abutting the clamping rings 25, 26. Thus, the damper mass 14, 15, 16 and the leaf springs 20, 21 are connected to one another concentrically and securely. The spacers 23, 24 can also be formed in one piece with the mass 1 5.

To assemble the vibration damper 1 0 according to the invention, the coil carrier 1 9 with the coil 1 8 is first placed on the absorber mass 1 4, 1 5, 1 6. The coil 1 8 engages in the gap 1 7. Then the spacer tube 22 is slipped over the absorber mass 1 4, 1 5, 1 6, so that it bears against the coil carrier 1 9. Then the above-described attachment of the leaf springs 20, 21 via the spacers 23, 24, the clamping rings 25, 26 and the screw 27. The assembly thus created is inserted from above into the casing 1 2 of the support 1 1 until the lower Leaf spring 20 rests on the neck 1 3. Then the cover 29 is inserted and connected to the jacket 1 2 in a manner not shown. The Til ^¬ germasse 14, 1 5, 1 6 is thus displaceable in the axial direction via the leaf springs 20, 21 relative to ^¬ over the support 1 1, but rigidly attached in the radial direction. An opening, not shown, is provided for the energy supply, through which suitable supply lines (not shown) are passed.

For attachment, the support 11 is provided with a plurality of bores 31. These bores can either be formed in a circumferential flange or, as shown in particular in FIG. 2, in an extension 30 of the support 11. The use of approaches 30 reduces the total weight of the vibration damper 10.

FIG. 3 shows a top view of a leaf spring 20, which is identical to the leaf spring 21. The leaf spring 20 has an outer region 32 and an inner region 33 with the opening 39. The outer region 32 and the inner region 33 are connected via three spirally curved leaf spring arms 35, which are separated from one another by recesses 34 which also run spirally. The edges 36 of each leaf spring arm 35 are involute-curved, and the end regions 37, 38 of the recesses 34 are each rounded.

The leaf spring arms 35 extend spirally around the inner region 33 before they open into the latter. A displacement of the inner region 33 in the radial direction deforms all leaf spring arms 35 so that high restoring forces are achieved. At the same time, the length of the leaf spring arms 35 is increased.

The permissible total displacement of the damper mass 14, 1 5, 1 6 is proportional to the length of the leaf spring arms 35, so that with a constant outer diameter of the leaf spring 20, 21 a larger permissible total displacement is achieved with very good guidance. FIG. 4 shows an enlarged illustration of the detail X from FIG. 1, in which the fastening of the outer region 32 of the leaf spring 21 is shown. The outer diameter of the leaf spring 21 is matched to the inner diameter of the casing 1 2 such that the leaf spring 21 is received in the casing 1 2 essentially without play. The outer region 32 is clamped in from below by the coil support 19 and from above by the cover 29 and is axially fixed in this way.

FIG. 5 shows an enlarged illustration of the detail Y from FIG. 1, in which the fastening of the inner region 33 of the leaf spring 21 is shown. The clamping ring 26 has an essentially cylindrical section 43 which is provided at one end with an outwardly projecting flange 44 and at the other end with an inwardly projecting flange 45 with an opening 46 for the screw 27. The head of the screw 27 is received in the interior of section 43.

The outer diameter of the section 43 corresponds to the inner diameter of the opening 39 in the inner region 33 of the leaf spring 21 and the inner diameter of the spacer 24.

The leaf spring 21 is thus guided to the section 43 of the clamping ring 26 essentially without play. The clamping ring 26 is in turn guided without play on the spacer 24, which in turn is guided without play on the shoulder 41 of the mass 15. Very good radial guidance is achieved in this way. The inner region 33 of the leaf spring 21 is received between the spacer 24 and the flange 44 of the clamping ring 26. The clamping ring 26 is clamped to the mass 15 by the flange 45 and the screw 27 with the opposite clamping ring 25. As a result, the inner region 33 of the leaf spring 21 is axially immovably fastened to the absorber mass. The opposite leaf spring 20 is attached analogously.

Overall, the absorber mass 1 4, 1 5, 1 6 is thus guided in a direction perpendicular to the leaf springs 20, 21 opposite the support 1 1. An additional guide, for example between the spacer tube 22 and the absorber mass 14, 15, 16 is not necessary.

Due to the spiral design, the length of the leaf spring arms 35 is significantly increased while the outer diameter of the leaf spring 20 remains the same. This will allow the total allowable movement of the absorber mass

1 4, 1 5, 1 6 in a direction perpendicular to the leaf springs 20, 21 also increased. The external dimensions of the vibration damper 10 can remain unchanged or can be reduced in size, with the spiral spring leaf arms 35 still offering very good movement possibilities for the damper mass 1 4, 1 5, 1 6.

Claims

claims

1 . Active vibration damper with a magnetically excitable damper mass (1 4, 1 5, 1 6), which is fastened to a support (1 1) by leaf springs (20, 21) spaced apart from one another, the damper mass (1 4, 1 5, 1 6 ) is movable back and forth in a direction perpendicular to the leaf springs (20, 21) in such a way that movements of the support (11) in this direction are at least partially suppressed, characterized in that the leaf springs (20, 21) have at least two Have leaf spring arms (35) bent spirally, which run from an outer region (32) to an inner region (33) of the leaf springs (20, 21).

2. Vibration damper according to claim 1, characterized in that the leaf spring arms (35) are involute curved.

3. ^' vibration damper according to claim 1 or 2, characterized in that the leaf springs (20, 21) have three spirally curved, evenly distributed over the circumference leaf spring arms (35).

4. Vibration damper according to one of claims 1 to 3, characterized in that the inner region (33) of the leaf springs (20, 21) has an opening (39) for attachment to the absorber mass (14, 1 5, 1 6).

5. Vibration damper according to claim 4, characterized in that for fastening the leaf springs (20, 21) to the absorber mass (1 4, 1 5, 1 6) clamping rings (25, 26) are provided which engage in the openings (39) of the inner regions (33).

6. Vibration damper according to claim 5, characterized in that the damper mass (1 4, 1 5, 1 6) has a central inner bore (28) which is penetrated by a screw (27) for fastening the clamping rings (25, 26), one clamping ring (26) receiving the head of the screw (27) and the other clamping ring (25) having an internal thread (42) into which the screw (27) engages.

7. Vibration damper according to claim 5 or 6, characterized in that the absorber mass (1 4, 1 5, 1 6) has cylindrical, centrally arranged approaches (40, 41) on which spacers (23, 24) are attached, and Leaf springs (20, 21) are clamped with their inner regions (33) between the spacers (23, 24) and the clamping rings (25, 26).

8. Vibration damper according to one of claims 4 to 7, characterized in that the outer regions (32) of the leaf springs (20, 21) are fixed by clamping on the support (1 1).

9. Vibration damper according to claim 8, characterized in that the outer regions (32) between a coil support (1 9) and a cover (29) are clamped, which are rigidly attached to the support (1 1).

1 0. Vibration damper according to claim 9, characterized in that for adjusting the distance between the support side Fastening of the leaf springs (20, 21) is provided between the leaf springs (20, 21) spacer tube (22) on which the coil carrier (19) rests.

11. Vibration damper according to claim 10, characterized in that the support (11) has a jacket (12) for receiving and guiding the leaf springs (20, 21), the spacer tube (22), the coil carrier (19) and the cover (29) having.

12. Vibration damper according to claim 11, characterized in that the jacket has on its inside a shoulder (13) as a stop for a first leaf spring (20).

13. Vibration damper according to one of claims 1 to 12, characterized in that the absorber mass (14, 15, 16) has a magnet (14) and two masses (15, 16) which enclose the magnet (14) between them.

14. Vibration damper according to one of claims 1 to 13, characterized in that the absorber mass (14, 15, 16) forms a gap (17) into which a coil (18) for electromagnetic excitation of the absorber mass (14, 15, 16) intervenes.