DE102006028705B3 - Passive vibration damper for use in automobile engineering, has coupling surface running parallel to main extension plane of damper, in which cantilever arm is extended along elastomer spring and damping mass - Google Patents

Abstract

The vibration damper has a rigid base (2) comprising a coupling surface (5) for providing a rigid coupling of the base to a structure, which is to be damped. An elastomer spring (8) is connected to the coupling surface of the base, where a damping mass (10) is connected to an elastomer spring with its end. The coupling surface runs parallel to a main extension plane of the vibration damper, in which a cantilever arm (12) is extended along the elastomer spring and the damping mass.

Description

TECHNICAL FIELD OF THE INVENTION

The The present invention relates to a passive vibration absorber with the features of the preamble of independent claim 1.

Especially The present invention relates to such passive vibration absorbers with several absorber masses.

STATE OF TECHNOLOGY

passive Vibration damper with the features of the preamble of the independent claim 1 having two absorber masses elastically coupled to a base, are usually to provided oscillations of a structure to be damped at two different excitation frequencies and / or natural frequencies of the To dampen structure. These are the Tilgereigenfrequenzen the two absorber masses on different values matched. This can be done through different ones Sizes, d. H. different weights of the absorber masses, different moments of inertia with respect to their Coupling to the base and / or different properties the elastomer springs are realized.

alternative can several with the same natural frequency synchronously oscillating absorber masses a vibration damper to be provided on linear damping forces the structure to be damped provide. This application is by the present Invention, although they are primarily such passive vibration absorber which several absorber masses on different Tilgereigenfrequenzen are coordinated.

At the Use of passive vibration absorbers in the automotive industry demanded that their absorber masses not only on elastomer springs with their Bases are connected, but also provided Verliersicherungen which contribute to an uncontrolled dropping of the absorber masses prevent a total failure of the elastomer springs.

From the DE 100 41 993 C1 is a passive vibration absorber with a single absorber mass is known in which a captive is formed by the absorber mass and the elastomeric spring having a central recess through which engages a fastening screw for fixing the base to the structure to be damped. In this case, a head of the fastening screw is greater than the minimum diameter of the recess in the absorber mass. Thus, the head of the fastening screw captures the absorber mass, if it separates from the elastomeric spring or with this from the base. For a passive vibration damper with several absorber masses, this principle of forming a captive is not suitable.

A passive vibration absorber having the features of the preamble of claim 1 is known from US 5,887,843 known. Here, the base on a bracket with two opposing areas, which form two attachment surfaces for a damping mass. The coupling surface for rigidly coupling the base to a structure to be damped is formed in the central region of the bracket between the attachment surfaces. In this case, the coupling surface extends approximately perpendicular to the attachment surfaces and perpendicular to a main extension plane of the vibration absorber. Through holes through the base for fixing the vibration damper via the coupling surface extend in the main extension plane of the vibration damper.

Another vibration damper with the features of the preamble of claim 1 is known from US 5,180,147 known. Here, the base is formed by a hat-shaped profile, in the edge regions perpendicular to its main extension plane extending coupling surfaces and extending in the main extension plane through holes are provided for fixing to a structure to be damped. The absorber mass is connected via four spring arms, each extending from one of its corners to a corner of the free cross section of the hat profile.

From the DE 698 27 037 T2 It is known to arrange over a damping mass of a vibration damper serving as a captive and secured at the base of the vibration absorber hat-shaped profile. In this case, an attachment surface of an elastomer spring for the absorber mass at the base extends parallel to a coupling surface of the base to a structure to be damped, and through holes through the base for attachment to the structure to be damped run perpendicular thereto.

From the DE 90 03 365 U1 For example, a vibration damper is known for placement in the handle of an electrical appliance.

TASK THE INVENTION

Of the Invention is based on the object, a passive vibration absorber to show with the features of the preamble of the independent patent claim 1 the basic construction makes it easy to deploy a reliable one Captive also for several absorber masses possible.

SOLUTION

According to the invention Object of the invention by a passive vibration damper with the Characteristics of the independent Patent claim 1 solved. Preferred embodiments of the new passive vibration absorber are defined in the dependent claims.

DESCRIPTION THE INVENTION

at The new passive vibration absorber covers the base in Form at least one cantilever on one of its sides along the Elastomer spring and attached absorber mass behind the end of the absorber mass, that of the said connection surface of the Base is turned away. In this way, the base prevents removal the absorber mass in the direction of the connection surface of the base for the elastomeric spring, to which the absorber mass is connected, away shows, and in the direction in which the boom along the Absorber mass extends. Although this alone is not a complete captive provided, such a complete captive results but how the further description of the present invention will show through a supplement of the new vibration absorber with simple additional elements in the same step can be attached to the base, in the base to the one to be damped Structure is coupled.

The coupling surface for rigidly coupling the base to the structure to be damped runs in the new vibration absorber perpendicular to the connection surface. To the Attach the base to the one to be damped Structure may be the base one perpendicular to the coupling surface and thus again parallel to the connection surface extending through hole exhibit. Here is the term through hole only here meant a cylindrical or otherwise different recess, the from one side of the base to the other side. These Recess does not have to be made by drilling.

The dimensional stability the base can with respect to which along the elastomeric spring and the absorber mass extending boom are significantly increased, when the base in the form of two arms on each other like Sides along the elastomeric spring and the absorber mass connected to it extends, so the two outriggers make a closed ring around the absorber mass formed. This ring also secures the absorber mass against losing in every direction of the plane defined by the ring.

The Outrigger of the base allowed behind the other ends of the absorber mass it, the absorber mass also with its other end over another elastomeric spring to connect to the base. As a result, the Tilgereigenfrequenz the absorber mass are specifically influenced. By a bilateral Connecting the absorber masses at both ends will also be their transverse movement limited, allowing a striking of the absorber mass to the boom the base is avoided.

If such striking at the desired natural frequency of the absorber mass not in principle is avoidable, can lateral bump stop made of elastomer material between the absorber mass and the base be provided. These bumpers can on the absorber mass and / or formed at the base, d. H. to this be vulcanized.

The entire base of the new vibration absorber including the Boom and a possible through hole for attachment to the one to be damped Structure can be a cut to length Section of a profile. That is, the base becomes complete by that designed so that a section is cut to length from such a profile.

Especially The base may be a closer Be section of a Leichmetallstrangpressprofils that too comparatively Great Manufacturing costs with high variability in relation available on the profile design is.

Also the absorber mass of the new vibration absorber can be achieved by simple Shorten a rod material are provided. For example, she has to not be made of a rotatable steel to any to be able to train central recesses. At the new vibration absorber the absorber mass in cross section is usually not cylindrical but rectangular to the open space opposite the outriggers of the base fully exploit.

Yet can the absorber masses of the new vibration absorber also with a Be provided transverse bore, with "transverse bore" a course transverse to the direction between the two ends of the respective absorber mass means.

By such a transverse bore may be a loop secured to the base extend from malleable band to a captive for the absorber mass train. A securing of the loop at the base results for example, automatically when the base is annular around the Tilgermassen extends and the loop through the holes of the Tilgermassen engages in this ring of the base.

It is particularly preferred in the new passive vibration absorber, however, if the captive is formed by an at least one free side along the absorber masses extending shielding and / or intercepting sheet. Such a shielding or Abfangblech or a plurality of such sheets then forms together with the base of a closed cage for the absorber mass. A shielding plate can also have the function to limit a thermal load of the elastomer material from the side of the structure to be damped.

A Possibility, a shielding or Abfangblech, the reliable Verliersicherung together Training with the base train is to be the base to arrange with the associated absorber masses in a pipe section. In the direction of the open tube ends, the absorber masses secured by the jibs of the base.

at particularly preferred embodiments of the new vibration absorber, the base has two attachment surfaces, wherein at each of the two attachment surfaces an elastomeric spring and To each of the two elastomeric springs a Tigermasse with their one End is tethered and being the base in the form of outliers on at least one of their sides along each of the two elastomeric springs and the associated absorber masses behind the ends of the Absorber masses which have turned away from the said connection surfaces of the base, extends. The basis for both absorber masses is the basic structure a captive ready.

As already mentioned in the beginning, several absorber masses are included the new vibration absorber usually on different Tilgereigenfrequenzen tuned. For this purpose, the two absorber masses be different heavy. This can be the same outer dimensions by different materials of the absorber masses or by different sizes Recesses, such as the holes already mentioned, in be realized in both absorber masses. The two absorber masses can also be different lengths, resulting in different moments of inertia the elastomer spring or with bilateral connection of the absorber masses via elastomer springs to the base also give different lengths of elastomeric springs. Also all other options known to those skilled in the different Tuning of Tilgereigenfrequenzen the absorber masses of a vibration absorber with several absorber masses can applied here. Which includes u. a. different elastomer materials of the individual elastomer springs.

The Basis itself can also with strongly different vote of the Tilgereigen frequencies of the two vibration absorber mirror-symmetrical to a symmetry plane extending between the two attachment surfaces be educated. So in particular a base in combination with different absorber masses and / or elastomeric springs for Training different passive vibration absorbers used whose absorber masses are not only different but also on differently far apart Tilgereigenfrequenzen are tunable.

advantageous Further developments of the invention will become apparent from the claims, the Description and the drawings. The in the introduction to the description advantages of features and combinations of several Features are merely exemplary and may be alternative or cumulative come into effect, without the benefits of mandatory embodiments of the invention must be achieved. Other features are the drawings - in particular the illustrated Geometries and the relative dimensions of several components to each other as well as their relative arrangement and operative connection - can be seen. The combination of features of different embodiments the invention or features of different claims is also different from the ones chosen The antecedents of the claims possible and is hereby stimulated. This also applies to such features as in separate drawings are shown or in their description to be named. These features can be combined with features of different claims. As well can in the claims listed Features for more embodiments the invention omitted.

SUMMARY THE FIGURES

in the The invention is described below with reference to the figures preferred embodiments further explained and described.

1 shows a first embodiment of the new passive vibration absorber with two absorber masses in a cross section parallel to the main extension plane of the vibration absorber.

2 shows a perspective view of the vibration absorber in the embodiment according to 1 ,

3 shows a second embodiment of the new passive vibration absorber with two absorber masses in one 1 corresponding cross-sectional view.

4 shows the vibration absorber in the embodiment according to 3 in a 2 ent speaking perspective view.

5 shows a further embodiment of the new passive vibration absorber with two absorber masses in an external view looking towards its main extension plane.

6 shows a further embodiment of the new passive vibration absorber with two absorber masses in the same direction as in 5 ,

7 shows yet another embodiment of the new passive vibration absorber with two absorber masses in the same direction as in 5 and 6 ,

8th shows the new passive vibration absorber in the embodiment according to the 1 and 2 or 3 and 4 in the mounted together with shielding and intercepting plates to a structure to be damped state in a side view.

9 shows the new passive vibration absorber in the embodiment according to the 1 and 2 or 3 and 4 or 5 in conjunction with a sheet-metal body attached to a structure to be damped state in a longitudinal view; and

10 shows the new passive vibration absorber in the embodiment according to 1 and 2 or 3 and 4 or 5 or 6 in the mounted within a pipe section to a structure to be damped state in a longitudinal view.

11 shows one of the embodiment according to the 1 and 2 related embodiment of the new passive vibration absorber with only one absorber mass, in an external view looking towards the main plane of extension of the vibration absorber.

12 shows a further embodiment of the new passive vibration absorber with an absorber mass also in an external view looking towards its main extension plane; and

13 shows one of the embodiment according to 12 related embodiment of the new passive vibration absorber again with two absorber masses again in an external view looking towards the main extension plane of the vibration absorber.

DESCRIPTION OF THE FIGURES

The in the 1 and 2 in two views shown vibration absorber 1 has a rigid base 2 on. The rigid base 2 is a cut to length section 3 a light metal extruded profile 4 from an aluminum alloy. At the base 2 is a docking area 5 educated about the the base 4 when using the vibration absorber 1 rigidly coupled to a structure to be damped. For fixing the vibration absorber 1 is a through hole 6 provided perpendicular to the coupling surface 5 opens and the passage of a head with her at the base 1 supported and allowed with its thread in the structure to be damped fastening screw. The through hole 6 is not a bore in the strict sense, ie not introduced by drilling, but directly when producing the light metal extruded profile 4 been omitted. Parallel to the through hole 6 and parallel to each other extend two attachment surfaces 7 , which are used to connect one elastomer spring each 8th are provided. To each of the elastomer springs 8th is an end 9 an absorber mass 10 Tied, the so on the elastomeric spring 8th elastic to the base 2 is coupled. Each of the absorber masses 10 serves to dampen the structure to which the base 2 is rigidly coupled to extract vibrational energy in the elastomeric spring 8th is dissipated. This withdrawal of vibration energy is effective when the natural absorption frequency of the respective absorber mass is effective 10 is tuned to the frequency of the vibrations of the structure to be damped. The at the vibration damper 1 existing two absorber masses 10 allow it, the vibration absorber 1 to tune to two different Tilgereigenfrequenzen so that it is effective for vibrations of the structure to be damped at two different frequencies. This different vote can be achieved by different design of the elastomer springs 8th For example, by using different elastomer materials 11 , or by different weights of the absorber masses 10 will be realized. Other possibilities have already been addressed in the general description of the invention. In the embodiment of the vibration absorber 1 in the 1 and 2 is shown, the base points 2 boom 12 on, on both sides of the absorber masses 10 until behind the rear ends 13 extend and merge into each other, so that each of the absorber masses 10 in the main extension plane according to 1 ring-shaped from the base 2 is enclosed. This will remove the absorber masses 10 from the base 2 in all directions in this main plane of extension through the arms 12 the base 2 prevented. The absorber masses 10 even here are cut to length sections 14 a rod material 15 of rectangular cross-section. The elastomer material 11 the elastomeric springs 8th extends all around the absorber masses 10 to form a corrosion protection coating. He also covers the inner circumference 16 the boom 12 , In this way, lateral stop puff fer 17 for the absorber masses 10 at the jibs 12 the base 2 formed a hard hitting the absorber masses 10 to the base 2 prevent. The construction of the base 2 is mirror symmetric to a in 1 drawn and there perpendicular to the plane extending symmetry plane 18 , The base 2 However, it is not rotationally symmetric to the there also drawn axis 19 , Nevertheless, both absorber masses can 10 so to the base 2 be coupled in accordance with the same natural sound frequencies for oscillations in the drawing plane 1 and perpendicular to it.

The embodiment of the vibration absorber 1 according to the 3 and 4 differs from the one according to the 1 and 2 in that the absorber masses 10 also at the back end 13 via one elastomeric spring each 20 at connection areas 21 the base 2 are coupled. As a result, the direction of movement of the absorber masses 10 from a tilting movement around the elastomer springs 8th on a parallel movement to the arms 12 postponed. Without changes to the elastomer springs 8th Of course, this is a significant increase in Tilgereigenfrequenzen both absorber masses 10 associated.

The 5 and 6 sketch two embodiments of the vibration absorber 1 in which the base 2 with the arms 12 the absorber masses 10 each non-annular in the main plane of extension of the base 2 encloses. Rather, are boom 12 provided, each only on one side along the absorber masses 10 until behind the ends 13 extend. Each of these outriggers 12 is essentially L-shaped. In the embodiment according to 5 Both arms extend 12 on the upper side of the absorber masses 10 , In the embodiment according to 6 extend the two arms 12 on different sides along the absorber masses 10 until behind the ends 13 , In addition is 6 to infer that the base 2 also in terms of the length of the boom 12 not symmetrical to the axis of symmetry 18 have to be. This is how the base stretches 2 here to the right in adaptation to a smaller absorber mass 10 less far than to the left.

The in 7 reproduced vibration absorber 1 indicates one of the jibs on the page shown here on the left 12 the base 2 ring-shaped absorber mass enclosed in the plane of the drawing 10 on, only at their end 9 via an elastomer spring 8th to the base 2 is coupled. On the left side there is only one boom 12 on one side along the absorber mass 10 until after the end 9 , Here is another elastomer spring 20 provided over the absorber mass 10 to another connection area 21 the base 2 is connected. Both absorber masses 10 Moreover, each have a transverse bore 22 on, through which a loop 23 made of deformable tape 24 extends. By doing that the loop 23 in the on the right side of the base 2 from the arms 12 formed ring, it provides a captive for both absorber masses 10 opposite the base 2 even if these are no longer from the elastomeric springs 8th and 20 being held.

8th shows the installation situation of a vibration damper 1 according to the 1 and 2 or 3 and 4 , About a fixing screw 25 is the vibration absorber 1 to a console 26 bolted to the structure to be damped 27 is provided. There are between the console 26 and the vibration absorber 1 a shielding plate 28 and between the vibration absorber 1 and the head 29 the fixing screw 25 a tray 30 trapped. The shielding plate 28 has the function of heat radiation from the structure to be damped 27 , For example, an exhaust system of a motor vehicle, of the elastomeric springs 8th and 20 or in total of the elastomer material 11 keep. In addition, forms the shield 28 also a protection against the escape of the absorber masses 10 between the base 2 and the structure 27 off when the elastomer springs 8th and 20 should fail.

Outwardly (up here) is an escape of the absorber masses through the intercepting plate 30 prevented. This tray 30 is then sufficient as captive, ie there is no additional shielding 28 needed when the distance between the structure 27 and the base 2 is sufficiently small (and no thermal stress on the vibration absorber 1 are to be feared).

9 outlines an embodiment in which the shielding 28 and the interceptor 30 from a one-piece shaped sheet metal body 31 be formed. The sheet metal body 31 prevents in case of destruction of the elastomer springs 8th and 20 also a lateral leakage of the absorber masses 10 from the base 2 , So forms the sheet metal body 31 also a complete captive for the vibration absorber 1 according to 5 out.

10 shows the case that the vibration absorber 1 in a sheet metal body 31 is arranged, consisting of a pipe section 32 is shaped. The sheet metal body 31 extends so in the drawing plane 10 all around the base 2 and prevents removal of the absorber masses in all directions 10 from the base 2 even with a total failure of the elastomer springs 8th and 20 , So will the vibration absorber 1 according to 6 a complete captive in terms of the absorber masses 10 educated. The captive in the direction of the 9 and 10 is in each case by the there behind the absorber masses 10 gripping boom 12 the base 2 guaranteed.

11 shows an embodiment of the vibration absorber 1 , the one according to the 1 and 2 corresponds, except that here only one absorber mass 10 provided in the reproduced main extension plane of two arms 12 is enclosed in a ring. In addition, the stop buffers 17 on the inner circumference 16 the boom 12 punctually at the height of the connection surface 7 turned away end 13 the absorber mass 10 intended. A complete captive for the absorber mass 10 the vibration absorber 1 according to 11 can basically be designed in the same way as on the previous ones 8th to 10 was explained.

The embodiment of the vibration absorber 1 according to 12 points to the embodiment according to 11 the following differences: Instead of a through hole are two through holes 6 for each a fixing screw for fixing the base 2 provided on the structure to be damped. This allows lateral forces about the axis of the through holes without a mutual guidance between the base 2 and the structure to be damped are easily absorbed. Furthermore, the elastomeric springs 8th and 20 that's here at both ends 9 and 13 the absorber mass 10 are provided, each in two sub-springs 33 respectively. 34 divided up. Each of the part springs 33 respectively. 34 connects an edge of the cuboid absorber mass 10 with a corner of the free cross section of the base 2 , in this arrangement, the elastomeric springs 8th and 20 there is no danger of an impact of the absorber mass 10 to the booms 12 the base 2 , so that no additional stop buffers are provided here accordingly.

The embodiment of the vibration absorber 1 according to 13 in contrast to that according to 12 again two absorber masses 10 on, being the base 2 mirror-symmetric to the plane of symmetry 18 through the through holes 6 is trained. In addition, here are both absorber masses 10 each cube-shaped, so that they in the view of 13 appear square. Here is the absorber mass reproduced here on the left 10 smaller than the absorber mass reproduced here on the right 10 , The resulting at the same density of absorber masses 10 tends to increase the natural absorptive frequency of the left absorber mass 10 but is due to the longer and thus softer elastomer springs 8th and 20 or the longer part springs 33 and 34 compensated, provided the elastomer springs 8th and 20 not solid or made of a harder elastomer material 11 are formed as the right absorber mass 10 , The left absorber mass 10 But due to a higher density it can be heavier than the basically bigger right absorber mass 10 and therefore in conjunction with the longer part springs 33 and 34 specifically tuned to a lower Tilgereigenfrequenz than the right absorber mass 10 ,

1

vibration absorber

2

Base

3

section

4

Light alloy extruded profile

5

contact surface

6

Through Hole

7

bonding surface

8th

elastomer spring

9

The End

10

absorber mass

11

Elastomer material

12

boom

13

The End

14

section

15

bar material

16

inner circumference

17

buffer

18

plane of symmetry

19

axis

20

elastomer spring

21

bonding surface

22

cross hole

23

loop

24

tape

25

fixing screw

26

console

27

structure

28

shield

29

head

30

clamp plate

31

Sheet metal moldings

32

pipe section

33

partial spring

34

partial spring

Claims (16)

A passive vibration absorber with a rigid base having a coupling surface for rigidly coupling the base to a structure to be damped and at least one bonding surface, with an elastomeric spring bonded to the bonding surface of the base and an absorber mass connected at one end to the elastomeric spring wherein along the elastomeric spring and the connected thereto absorber mass to behind the end of the absorber mass extends the base in the form of at least one boom on one of its sides which faces away from the connection surface of the base referred to, and wherein the bonding surface is perpendicular to the coupling surface, characterized characterized in that the coupling surface ( 5 ) parallel to a main plane of insertion of the vibration tilgers ( 1 ), in which the boom ( 12 ) along the elastomeric spring ( 8th ) and the associated absorber mass ( 10 ). A vibration damper according to claim 1, characterized in that the base ( 2 ) one perpendicular to the coupling surface ( 5 ) and parallel to the attachment surfaces ( 7 ) extending through bore ( 6 ) having. Vibration damper according to one of claims 1 and 2, characterized in that the base ( 2 ) in the form of two arms ( 12 ) on two opposite sides along the elastomeric spring ( 8th ) and the absorber mass ( 10 ), so that the two arms ( 12 ) a closed ring around the absorber mass ( 10 ) train. Vibration damper according to one of claims 1 to 3, characterized in that the absorber mass ( 10 ) also with their other end ( 13 ) via a further elastomeric spring ( 20 ) to the base ( 2 ) is attached. Vibration damper according to one of claims 1 to 4, characterized in that lateral stop buffers ( 17 ) made of elastomeric material ( 11 ) between the absorber mass ( 10 ) and the base ( 2 ) are provided. Vibration damper according to one of claims 1 to 5, characterized in that the base ( 2 ) a cut-to-length section ( 3 ) of a profile. A vibration damper according to claim 6, characterized in that the base ( 2 ) a cut-to-length section ( 3 ) of a light metal extruded profile ( 4 ). Vibration damper according to one of claims 1 to 7, characterized in that the absorber mass ( 10 ) a cut-to-length section ( 14 ) of a bar material ( 15 ). Vibration damper according to one of claims 1 to 8, characterized in that the absorber mass ( 10 ) a continuous transverse bore ( 22 ) having. Vibration damper according to claim 9, characterized in that through the transverse bore ( 22 ) one at the base ( 2 ) secured loop ( 23 ) of deformable band ( 24 ). Vibration damper according to one of claims 1 to 10, characterized in that a shielding plate ( 28 ) and / or an intercepting plate ( 30 ) provided on at least one free side along the absorber mass ( 10 ). Vibration damper according to one of claims 1 to 11, characterized in that the base ( 2 ) with the associated absorber mass ( 10 ) in a pipe section ( 21 ) is arranged. Vibration damper according to one of claims 1 to 12, characterized in that the base ( 2 ) two connection surfaces ( 7 ), to each of the two attachment surfaces ( 7 ) an elastomeric spring ( 8th ) and to each of the two elastomer springs ( 8th ) a tiger mass ( 10 ) is connected with its one end and whereby the base ( 2 ) in the form of arms ( 12 ) on at least one of their sides along each of the two elastomeric springs ( 8th ) and the associated absorber masses ( 10 ) until behind the ends ( 13 ) of the absorber masses ( 10 ), which correspond to the said connection surfaces ( 7 ) the base ( 2 ), extends. Vibration damper according to claim 13, characterized in that the connection surfaces ( 7 ) in opposite directions. Vibration damper according to one of claims 13 and 14, characterized in that the two absorber masses ( 10 ) are different heavy and / or have different lengths. Vibration damper according to one of the claims 13 to 15, characterized in that the base ( 2 ) mirror-symmetrical to one between the attachment surfaces ( 7 ) passing through symmetry plane ( 18 ) is trained.