AT518999B1 - friction plate - Google Patents

Abstract

The invention relates to a friction disk (10) with a disk body (5) on which at least one vibration damping element (11) is arranged, which is arranged on a radially outer end face (12) of the disk body (5) and / or which has a groove (15). has, in which the lamellar body (5) protrudes.

Description

Description: [0001] The invention relates to a disk set comprising, in the axial direction, a plurality of friction disks arranged one behind the other with a disk body on which, if appropriate, at least one friction lining is arranged.

Vibration-damped couplings are already known from the prior art in various designs. For example, DE 32 28 673 A1 describes a torsional vibration damper for vehicle friction clutches in which the torque is transmitted from the wave-like primary part carried by him about drum-like secondary part via an annular coupling body arranged therein, which engages with a longitudinal displacements permitting thrust device in the primary part and is slidably connected to the periphery of the secondary part by an axial toothing, wherein on both sides of the coupling body is a disc spring, which is supported on the wall of the secondary part. The mutual chambers of the springs are filled with damping oil, which can flow from one chamber into the other when loaded by a throttle body located in the coupling body. The disadvantage here is that in each direction of rotation is always only one plate spring in action, while the other remains uninvolved. In addition, additional space must be provided for the hydraulic damping.

Clutch discs with torsion springs are also known.

DE 10 2012 005 908 A1 describes a brake disc for a disc brake of a motor vehicle, comprising a brake disc hub and a friction ring, wherein the friction ring on the outer circumference has a groove in which a separate additional element is held for vibration damping, which is formed corresponding to the hat shape is.

From GB 1469115 A, a brake disc with reduced noise behavior is known. The brake disc for a disc brake has in its outer periphery a circumferential groove in which an annular element is arranged. This has a certain elastic mobility.

WO 2007/121231 A2 describes an insert for a casting mold for a sound-damping rotor of a caliper brake, comprising a ring with an inner diameter, an outer diameter and at least one lobe, and an inner core made of a bonded sand material, wherein the inner core is adjacent to the ring.

From DE 38 11 222 A1 discloses a brake disc for disc brakes, especially for motor vehicles, known, with a cooperating with a brake caliper brake ring with which a vibration-damping mass is resiliently coupled.

The present invention is based on the object to provide a Reiblamellenpaket with simple vibration damping.

This object is achieved with the disc pack mentioned above in that at least one friction plate at least one vibration damping element is arranged on the disk body, wherein the vibration damping element is arranged on a radially outer end face of the disk body and / or that the vibration damping element has a groove in which protrudes the lamellar body.

The advantage here is that it is possible in a simple manner by this arrangement of the vibration damping element to change the natural frequency of the friction plate. It can thus reduce friction vibrations and torque peaks are damped in the torque transmission in the disk set. The arrangement of the vibration damping element directly on the friction plate can be directly influenced on the vibration behavior of the friction plate. It is possible to equip friction plates of a disk set with different vibration damping elements, whereby the vibration behavior of the disk set can be more accurately influenced. In addition, the vibration damping element can be simple. The installation of the vibration damping element in the friction plate can thus be simplified.

According to a variant of the friction plate is provided that the radially outer end face of the plate body has at least one recess and the vibration damping element is at least partially disposed in this recess. It is thus achievable a better connection of the vibration damping element to the disk body.

It can be provided according to an embodiment to the fact that the recesses are formed by the tooth gaps of a tooth-like outer contour of the radially outer end face of the disk body, whereby the connection strength between the vibration damping element and the disk body can be further improved.

According to another embodiment of the friction plate may be provided that the disk body below the radially outer end face has at least one recess in which the vibration damping element is arranged. Thereby, the radial height of the friction plate can be reduced if the or the Schwingungsdämpfungsele-element (s) are arranged exclusively in this / these recess (s) / are. It is thus also a simpler distribution and arrangement of several, distributed in the circumferential direction of the friction plate vibration damping elements on the fin body reached.

The vibration damping element may be in the form of a clip, whereby the installation of the vibration damping element can be simplified in the disk body. On the two side cheeks of the clip can also be a friction pair (based on the friction pairings friction plate / counter plate) are introduced into the disk set, which (in addition to the mass of the vibration damping element) also the vibration behavior of the friction plate can be influenced. The friction pair is formed between the inner sides of the clip and the disk body.

The clip may have at least one (elastic) securing element, which bears against the plate main body. About this securing element, the vibration damping element can be biased against the slats main body, whereby vibration movements of the vibration damping element can be intercepted. It can thus be designed to be safer on the seat of the vibration damping element or in the disk body.

The arrangement of the vibration damping element in the above-mentioned recess also has the advantage that so that the clip in the radial direction and / or in the axial direction relative to the slats main body can be slidably disposed without the vibration damping element is lost. About this mobility of the vibration damping element can be further influenced on its vibration damping behavior.

It can further be provided that the lamellar body has a plurality of recesses, and in each of these recesses, a vibration damping element is arranged, wherein the vibration damping elements have different masses. Since the mass of the vibration damping element influences its damping behavior, the vibration damping of the friction plate can be adjusted better or more accurately by the arrangement of different vibration damping elements.

The vibration damping element, the lamellar body and optionally arranged on the disc body friction lining in the axial direction are arranged outstanding, which in turn different friction pairings can be formed, which influence the damping behavior of the vibration damping element different. Even with this embodiment of the friction plate so a better or more accurate tuning of the damping behavior of the vibration damping element is possible.

To reduce the axially required space of the friction plate or the disk set can be provided that an outer surface of the Schwingungsdämpfungsele Mentes is formed in alignment with a friction surface of the friction lining. This embodiment variant of the friction disk is primarily of advantage when the vibration damping element projects beyond the disk body in the axial direction.

It is also advantageous if the vibration damping element or the vibration damping elements is connected to an elastomer with the plate body or are, since thus the vibration damping element can be connected vibration damped with the plate body, whereby the design of the vibration damping or training and Arrangement of or the vibration damping element (s) can be simplified.

According to a further embodiment of the friction plate may be provided that the vibration damping element has a core part and an outer part. It is thus possible, for example, to change the mass of the vibration damping element. For example, can thus be increased in small-volume vibration damping elements whose mass is used by a core material with a higher weight. In addition, but also the rigidity behavior of the vibration damping element can be changed when the core part has a different stiffness, as the outer part.

For a better understanding of the invention, this will be explained in more detail with reference to the following figures.

In a simplified, schematic representation: [0024] FIG. 1 shows a section of a lamella packet according to the prior art in FIG

Side view; FIG. 2 a perspective view of a first embodiment of a friction plate; FIG. FIG. 3 shows a detail of the friction plate according to FIG. 2 in cross section; FIG. Fig. 4 shows a detail of another embodiment of the friction plate in

Cross-section; Fig. 5 shows a detail of another embodiment of the friction plate in

Cross-section; Fig. 6 shows a detail of another embodiment of the friction plate in

Cross-section; 7 shows a detail of another embodiment variant of the friction plate in FIG

Cross-section; 8 shows a further embodiment of the friction plate in an oblique view; 9 shows a detail of the friction plate of Figure 8 in cross section ..; Fig. 10 shows another embodiment of the friction plate in an oblique view and partially wiser exploded view; 11 shows a further embodiment of the friction plate in front view; FIG. 12 shows a detail of the friction plate according to FIG. 11 in cross section; FIG. Fig. 13 shows a variant of a vibration damping element in cross-section.

Introductoryly it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or identical component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or the same component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and to transmit mutatis mutandis to the new situation in a change in position.

In Fig. 1 a section of a known disk pack 1 is shown. The disk set 1 has a plurality of inner disks 2 and a plurality of outer disks 3, which can also be referred to as friction disks. The inner disks 2 are arranged alternately with the outer disks 3 in an axial direction 4. Via a corresponding actuating mechanism, the inner disks 2 are adjustable relative to the outer disks 3 in the axial direction 4, so that a frictional engagement is formed between the inner disks 2 and the outer disks 3.

The inner disks 2 have an at least approximately annular disk body 5 with a first surface 6 and one of these in the axial direction 4 opposite second surface 7. At least one friction lining 8 is arranged in each case on the first and / or the second surface 6, 7. The inner plates 2 are so-called lining plates.

The friction linings 8 may be formed according to the prior art.

It can also be provided that the inner disks 2 have no friction linings 8.

The outer disks 3 also have an at least approximately annular disk body 9, which, however, is free of friction linings. The outer disks 3 are therefore the so-called counter blades, which can be spent in frictional engagement with the friction linings 8 of the inner disk 2.

But it is also possible that 3 friction linings 8 are arranged on the outer disk, in particular when no friction linings are arranged on the inner disk 2.

Preferably, the inner plates 2 and the outer plates 3 made of a steel or include this. However, they can also consist of another suitable, in particular metallic, material. For example, the inner lamellae may consist of a resin-bonded composite material or of a sintered material, as is known per se. The friction linings 8 arranged on the inner disks can consist, for example, of a carbon material or of a resin-bonded, optionally fiber-reinforced, paper covering or a resin-bonded covering or a sintered material. Such friction linings are known from the prior art, so reference is made to this. It is also possible that the friction linings 8 are arranged on a support (the above-mentioned lamellar body 5). The carrier is preferably made of steel or another suitable material.

This basic structure of a disk set 1 is known from the prior art. For further details, therefore, reference is made to this relevant prior art.

The disk set 1 is part of a disk friction system, for example, a (wet-running) multi-plate clutch, a brake, a holding device, a differential lock, etc ..

2 and 3, a first embodiment of a friction plate 10 is shown, as used in the plate pack 1 of FIG. Specifically, an inner fin 2 is shown as shown in FIG. However, the friction plate 10 can also be an outer plate 3 (FIG. 1), in which case it has no friction lining 8.

The friction plate 10 may have at least one driver element 10, for example in the form of an internal toothing, on a radially inner end face.

It should be mentioned at this point that the outer plates 3 may have at least one driver element on a radially outer end face.

About the driver elements, a rotationally fixed connection with another component of the Lamella friction system, such as a shaft in the case of the inner disk 2 or the housing of the disk friction system in the case of the outer disk 3, are produced, as is well known.

It is also possible that the inner disk 2 or the outer disk 3 so-called free-floating fins are formed, so have no such driver elements, as is well known.

At the fin body 5 (in the case of an outer fin 3 fin body 9) of the friction plate 10, at least one vibration damping element 11 is arranged and connected to the fin body 5. For this purpose, the vibration damping element 11 is arranged on a radially outer end face 12 of the disk body 5. The vibration damping element 11 thus projects beyond the disk body in the radial direction. In particular, the vibration damping element 11 rests on the entire circumference of the disk body 5 in the circumferential direction 13 at this.

The vibration damping element 11 is annular in this embodiment of the friction plate 10. It thus extends over the entire circumference of the end face 12 of the disk body 5 in a circumferential direction 13, in particular continuously. In principle, however, it is also possible that the vibration damping element 11 extends only over a partial region of the circumference of the end face 12. In this case, a plurality of vibration damping members 11 may be arranged in the circumferential direction 13 one behind the other and apart from each other. However, the annular configuration of the vibration damping element 11 is preferred.

There is a possibility that the vibration damping member 11 made of the same material as the friction blade 10, i. as the inner and / or outer plates 2, 3, or a different material. For example, the vibration damping element 11 may consist of a spring steel or a polymeric material. Thus, therefore, the further friction pairing vibration damping element 11 / friction plate 10 may have the same or a different coefficient of friction, as the friction pair inner plate 2 / outer plate 3. It is thus possible to influence the vibration damping behavior of the vibration damping element 11. In addition, an influence on the vibration damping performance of the vibration damping member 11 can be taken by varying the mass of the vibration damping member 11. The vibration damping element 11 may therefore have the same, a larger or a smaller mass, such as an inner plate 2 and / or an outer plate third

The vibration damping element 11 of the embodiment according to FIGS. 2 and 3 has a circular cross-section viewed in the circumferential direction.

According to a preferred embodiment, it may be provided that the radially outer end face 12 of the disk body 5 has at least one recess 14 and the vibration damping element 11 is at least partially disposed in this recess 14. However, the vibration damping element 11 can also be arranged entirely in this recess 14.

This recess 14 may be designed as a groove or groove. The cross section of this recess 14 in the circumferential direction 13 of the disk body 5 may be adapted to the cross section of the vibration damping element 11, thus, for example, in the embodiment of the friction plate 10 of FIGS. 2 and 3 also has a round, in particular circular section, cross section.

The recess 14 may extend in the axial direction of the friction plate 10 up to the edge for the transition in the radial end face 12 in the axial end faces or may be spaced-formed to this edge. In other words, the recess 14 may extend in the axial direction over the entire width of the disk body 5 or only over a portion of this width. Preferably, in the latter case, it is formed centrally in the end face 12.

It is also possible that more than one such depressions 14 are formed on the radially outer end face 12 of the disk body 5, for example, two or three, etc., which may be arranged side by side in the axial direction of the friction plate 10.

FIGS. 4 to 12 show different embodiments of the friction disk 10, which may be independent of one another, wherein the same reference numerals or component designations are used for the same parts as in FIGS. 1 to 3. In order to avoid unnecessary repetition, reference is therefore made to the above detailed description of these parts and reference is made and therefore can be read in the following embodiments of the friction plate 10.

4 to 7 make it clear that the vibration damping element 11 may have different cross-sectional shapes, viewed in the circumferential direction 13 (FIG. 2) of the disk body 5.

For example, the vibration damping element 11 may have an at least approximately oval (FIG. 4) or an at least approximately rectangular (FIG. 5) cross section. It should be noted, however, that other than the illustrated cross-sectional shapes of the vibration damping element 11 are possible, so that they are therefore not restrictive. For example, the vibration damping element 11 may also have an at least approximately square or at least approximately trapezoidal, etc., cross-section.

It is further possible, as is the case in the embodiment of the friction plate 10 of FIG. 6, that the vibration damping element 11 has a, in particular groove-like, groove 15, in the circumferential direction 13 (FIG. 2) of the friction plate 10th runs. In this embodiment variant, the vibration damping element 11 is pushed over the lamellar body 5, so that the latter projects into the groove 15 of the vibration damping element 1 or is accommodated therein.

In the embodiment of the friction disk 10 shown in FIG. 6, the disk body 5 in the region of the entrance into the groove 15 of the vibration damping element 11 in the axial direction no cross-sectional taper, so that the vibration damping element 11 with the side walls 16, 17 in FIG Projected axially. But it is also possible that the lamellar body 5 has such a cross-sectional taper and thus the axially outer surfaces of the vibration damping element 11 are formed in alignment with the axial surfaces of the plate body 5. However, the vibration damping element 11 can also have a smaller width in the axial direction of the friction disk 10 than the disk body 5 viewed in the same direction, so that therefore the disk body 5 projects beyond the vibration damping element 11 in the axial direction.

It is also possible that analogous to the aforementioned recesses 14 in the end face 12 of the disk body 5, the vibration damping element 11 has a plurality of circumferentially 13 (Fig. 2) extending grooves which are arranged side by side in the axial direction. In this case, the lamellar body 5 at the radially outer end surface 12 a plurality, preferably one of the number of grooves in the vibration damping element 11 corresponding number of webs (in particular ring lands), wherein in each case a web is received in one of the grooves of the vibration damping element 11.

According to one embodiment variant of the friction disk 10, in which it has at least one axial, in particular two, at least one friction lining 8, it can be provided, as shown in FIG. 6, that - as described - the vibration damping element 11 forms the disk body 5 in the axial direction with at least one of the side walls 16, 17, in particular with both, surmounted and that at least one axial outer surface, in particular both axial surfaces, of the vibration damping element 11 with a friction surface 18,19 of the friction lining 8 or the friction linings 8 is aligned or are.

A further embodiment variant of the friction plate 10 is shown in FIG. 7. In this embodiment variant, the vibration damping element 11 having at least one groove 15 projects beyond not only the plate main body 5 in the axial direction (in particular on both sides), but also one or both friction linings 8 Thus, the vibration damping element 11 can also be connected to at least part of the side walls 16, 17 on the

Apply friction lining 8 or the friction linings 8.

Thus, depending on the design of the vibration damping element 11, different friction pairings can be formed, for example the friction pairing vibration damping element 11 / disk body 5 and / or the friction pairing vibration damping element 11 / friction lining 8. If both of said friction pairings are formed, the vibration damping element can at least one the groove side walls can be stepped, so that the vibration damping element 11 rests against both the lamella body 5 and at least one of the friction linings 8, which in this case are offset radially inwardly from the outer periphery of the lamella body 5.

It is also possible to provide the outside of the lamellar body 5 or the inside of the side walls 16, 17 of the groove 15 and / or the groove bottom or the outside of the vibration damping element 11 with a coating in order to influence the friction coefficient and in the Follow the friction pairing. Such coatings may be, for example, DLC coatings (diamond-like carbon), stray sintered coatings, in particular of a grit sintering material known from the prior art for friction laminations, polymer coatings, in particular paints, etc.

From Fig. 7 it is also apparent that the lamellar body 5, the groove 15 does not have to fill completely, but the one between the radially outer end face 12 of the lamellar body 5 and the groove bottom a distance is present. It can thus also influence the vibration damping behavior of the vibration damping element 11 influence.

Further, it can be seen from Fig. 7 that the vibration damping element 11 may be formed in the axial direction projecting with bead-like projections 20.

In all embodiments of the friction plate 10 with in the axial direction of the disk body 5 and / or the friction lining 8 überragendem vibration damping element 11 is the respective friction with the friction plate 10 further friction plate, so for example, the outer plate 3 in the case of the formation of the friction plate 10th as inner disk 2, as shown in Fig. 7, at least in the region of the axial projection of the vibration damping element 11 is formed with a recess 21 which is preferably at least so great that the vibration damping element 11 in the frictional engagement of the slats not to rest against the further friction plate , For example, the outer fin 3, passes. This recess 21 can be made for example by forming or by multipart design of the further friction plate.

In this, the vibration damping element 11 is not disposed on the outer circumference of the disk body 5, as in the embodiments described above, but has the disk body 5 at least one recess 22, in particular at least a breakthrough, in which the vibration damping element 11 is at least partially included. The at least one recess is formed in the radial direction between the radially outer end face 12 and a radially inner end face 23. Preferably, it has a larger dimension in the circumferential direction 13 than in the radial direction.

As can be seen in particular from FIG. 9, the oscillation damping element 11 is designed as a clip 24 (clip-like), and has the groove 15, into which the laminar body 5 protrudes. The bracket 24 thus projects beyond the lamellar body 5 and possibly at least one friction lining 8 (preferably both friction linings 8) arranged on the lamellar body 5 in the axial direction. The groove side walls of the groove 15 are on the disk body 5 and / or on the friction lining 8 (as described above) and form a corresponding friction pairing.

The clamp 24 extends only over a portion of the lamellar body 5 in the circumferential direction 13, so it is not annular.

According to an embodiment variant, it can be provided that the clamp 24 has at least one elastic or bendable securing element 25, which bears against the lamella main body 5. Preferably, the clip 25, or generally the vibration damping element 11, two such securing elements 25, which may be formed, for example, to a bottom wall 26 of the bracket 24 and extending in the circumferential direction 13. When installing the clip 24 in the recess 22, the securing elements 25 can be bent due to their bendability into a ring and inserted into the recess 22. When the clip 24 is properly placed, the securing elements 25 are omitted and thus abut against the lamellar body 5 in the region of the recess (as shown in FIGS. 8 and 9). Due to their elastic properties, the securing elements 25 have the tendency to return to the starting position prior to installation and thereby build up a bias by which the clamp 24 is biased against the laminar body 5.

But it is also possible that the securing elements 25 are already made preformed so that they form at least approximately a ring before installation in the recess 22 together with the clip. In this case, the securing elements 25 can also be designed resiliently. The spring elasticity of the securing elements 25 can be made smaller if the groove bottom of the bracket 24 in the installed position objects to the side wall of the recess 22, as shown in Fig. 9.

For reasons mentioned above, according to a variant embodiment, it may be provided that the clamp 24 is arranged so as to be displaceable relative to the lamellar body 5 in the radial direction and / or in the axial direction. The recess 22 has correspondingly larger dimensions in the respective direction than the bracket 24.

It can be provided according to a further embodiment of the friction plate 10, that the disk body 5 below the radially outer end face 12 more of said recess 22, wherein in each of these recesses 22 a vibration damping element 11, in particular a clamp 24, is arranged. The vibration damping elements 11 preferably have different masses (weights), whereby the vibration damping of the friction plate 10 can be tuned or adjusted better. For example, it is possible to provide two different masses, which are provided symmetrically distributed in the circumferential direction 13 in the disk body. A vibration damping element 11 with a first mass thus follows in the circumferential direction a vibration damping element 11 with a second, different mass to the first mass, this again a vibration damping element 11 with the first mass, etc .. Preferably, the number of vibration damping elements 11 with the first mass equal to the number of vibration damping elements 11 with the second mass.

It is also possible to provide vibration damping elements 11 with more than two different masses, for example three or four, etc.

It should be noted that the number of vibration damping elements 11 shown in Fig. 8 is not to be understood as limiting, It may also be a different number of vibration damping elements 11 are provided in the friction plate 10.

Fig. 10 shows a section of a friction plate 10 in an exploded view. To improve the bond strength between the, in particular annular, vibration damping element 11 and the disk body 5 may be provided that the disk body 5 has a toothing 27 on the radially outer end face 12. The above-mentioned recess 14 (FIG. 3) is formed by the tooth gaps of the toothing 27 in this embodiment variant of the friction disk 10, so that a plurality of such depressions 14 are distributed over the circumference.

In general, it can be provided that the lamellar body 5 at the radially outer end surface 12 recurring multiple recesses 22 and elevations, so that therefore not necessarily the toothing 27 must be provided.

It is also possible that on the inner, the radially outer surface 12 facing surface of the vibration damping element 11 a complementary surface design is provided, so for example also a toothing or the recurring multiple recesses and elevations. The elevations of the vibration damping element 11 may be arranged engaging in the recesses 22 of the disk body 5 and vice versa.

The recurring depressions and elevations of the vibration-damping element 11 and the disk body 5 can also be provided in the embodiments of the friction disk 10 with the arrangement of the vibration damping element 11 in the recess 22 in the disk body 5.

In order to improve the bond strength between the vibration damping member 11 and the disk body 5, it may be further provided that the vibration damping member 11 or the vibration damping members 11 is connected to the disk body 5 with an elastomer. As the elastomer, for example, natural rubber, (carboxylated) nitrile-butadiene rubber, isoprene rubber, silicone elastomers can be used. The elastomer can be provided for example in the region of the groove bottom of the vibration damping element 11.

11 and 12, a further embodiment of the friction plate 10 is shown, in which the at least one vibration damping element 11 has an axial securing. For this purpose, the at least one vibration damping element 11 is provided in the axial direction with a greater width than the lamellar body 5. After inserting the vibration damping element 11 in the recess 22 of the lamella body 5, the two in the axial direction on the lamellar body 5 protruding portions of the vibration damping element 11 are formed , in particular cold-formed. This creates shelves 28, 29, which surround the lamellar body 5 on the outside, as can be seen in particular from FIG. 12.

According to another embodiment variant shown in FIG. 13, it may be provided that the vibration damping element 11 has a core part 30 and an outer part 31. The core member 30 may be made of the material of the outer member 31 or a different material, for example, a material with higher mass (weight) and / or stiffness exist. Furthermore, the core part 30 can be completely surrounded by the outer part 31. But it is also a sandwich layer structure possible in which the core member 30 is not surrounded by the outer part 31 at its end faces.

In general, the vibration damping element 11 is preferably made in one piece.

The friction plate 10 may be designed as an inner plate 2 or 3 as an outer plate. It can thus the damping behavior of the vibration damping element 11 can be influenced. If the vibration damping element 11 is arranged on a friction disk 10 designed as an inner disk 2, then its damping effect increases with increasing rotational speed of the friction disk 10. However, if the vibration damping element 11 is arranged on a friction disk 10 designed as an outer disk 3, then the behavior is exactly the opposite, so that So the damping effect decreases with increasing speed.

The embodiments show possible embodiments of the friction plate 10, it being noted at this point that various combinations of the individual embodiments are possible with each other.

For the sake of order, it should finally be pointed out that, for a better understanding of the structure of the friction disk 10, these or their components have not necessarily been shown to scale.

REFERENCE LIST 1 lamella pack 30 core part 2 inner lamella 31 outer part 3 outer lamella 4 axial direction 5 lamella body 6 surface 7 surface 8 friction lining 9 lamellar body 10 friction lamella 11 vibration damping element 12 end surface 13 circumferential direction 14 depression 15 groove 16 side wall 17 side wall 18 friction surface 19 friction surface 20 projection 21 recess 22 recess 23 End face 24 Clip 25 Securing element 26 Bottom wall 27 Gearing 28 Bord 29 Bord

Claims (12)

claims 1. lamella packet (1) comprising in the axial direction (4) a plurality of successively arranged friction plates (10) with a lamellar body (5) on which optionally at least one friction lining (8) is arranged, characterized in that on the lamellar body (5) at least one friction plate at least one vibration damping element (11) is arranged, wherein the vibration damping element (11) is arranged on a radially outer end face (12) of the disk body (5) and / or that the vibration damping element (11) has a groove (15) into which the disk body (5) protrudes. 2. disc pack (1) according to claim 1, characterized in that the radially outer end face (12) of the lamellar body (5) has at least one recess (14) and the vibration damping element (11) is at least partially disposed in this recess (14). 3. disc pack (1) according to claim 2, characterized in that the recesses (14) through the tooth spaces of a tooth-like outer contour of the radially outer end face (12) of the lamellar body (5) are formed. 4. disc pack (1) according to one of claims 1 to 3, characterized in that the lamellar body (5) below the radially outer end face (12) has at least one recess (22) in which the vibration damping element (11) is arranged. 5. plate pack (1) according to one of claims 1 to 4, characterized in that the vibration damping element (11) in the form of a clamp (24) is formed. 6. disc pack (1) according to claim 5, characterized in that the clip (24) has at least one securing element (25) which bears against the plate body (5). 7. plate pack (1) according to claim 5 or 6, characterized in that the clip (24) in the radial direction and / or in the axial direction relative to the plate body (5) is arranged displaceably. 8. plate pack (1) according to one of claims 4 to 7, characterized in that the lamellar body (5) below the radially outer end face (12) has a plurality of recesses (22), wherein in each of these recesses (22) has a vibration damping element (11 ), wherein the vibration damping elements (11) have different masses. 9. disc pack (1) according to one of claims 1 to 8, characterized in that the vibration damping element (11) projects beyond the disc body (5) and optionally on the disc body (5) arranged friction lining (8) in the axial direction. 10. plate pack (1) according to one of claims 1 to 8, characterized in that an outer surface of the vibration damping element (11) with a friction surface (18, 19) of the friction lining (8) is formed in alignment. 11. disc pack (1) according to one of claims 1 to 10, characterized in that the vibration damping element (11) or the vibration damping elements (11) is connected to an elastomer with the lamellar body (5) or are. 12. disc pack (1) according to one of claims 1 to 11, characterized in that the vibration damping element (11) has a core part (30) and at least one outer part (31). 4 sheets of drawings