DE4141343A1 - Lining system for vibration damping - has damping plastic mass attached to structure to be damped, over which counter-plate is fitted - Google Patents

Abstract

A first damping layer (2) is applied, on which then counter plate (3) is fitted. A second damping layer (4) is then applied between the first counter plate (3) and a second such plate (5). The first counter plate (3) on the one side (8) is rigidly connected to the structure (1) to be damped, and the second counter plate (5) is likewise connected to the structure on the opposite side (7). The two counter plates and angle-shaped extensions (10, 9) which have a direct contact with the structure to be damped. USE/ADVANTAGE - To damp vibrations emanating from moving machine parts. It is also possible to have more than two counter plates and more than two damping layers.

Description

Vibrations of flat or rod-shaped structures, e.g. B. of machine parts such as housing walls or shafts usually undesirable because they often emit sound and thus lead to annoying noise because sometimes they Functionality of the machine impaired by e.g. B. reduce the machining accuracy of machine tools, or because in extreme cases due to material fatigue lead to machine damage. As a countermeasure, you try dampen this vibration. For this purpose, e.g. B. single layer or multilayer vibration damping layers applied. Especially when the order thickness or weight of these damping layers due to the special conditions of applications are limited - e.g. B. A car is not allowed become heavy - the effectiveness of these layers often remains significantly below what would be desirable.

The object of the present invention is the effectiveness to significantly increase such damping layers.  

In the simplest case, there is such a damping layer the current state of the art from a simple Layer of plastic or resin suitable chemical Composition, which if z. B. a steel sheet can be damped should be at least twice the thickness of the sheet must to achieve a sensible damping. The damping The effect of these simple damping pads is based in principle insist that these coatings are caused by the bending vibration of the structure are also forced to vibrate. In the the deformation of the coating taking place becomes vibration energy converted into thermal energy.

A significantly better effect is achieved according to the prior art on the principle of the constrained covering (see Fig. 1). In this case, a suitable damping layer is first applied to the structure to be damped, the most important components of which are resin, bitumen or plastics of suitable chemical composition. A counter plate is in turn applied to this damping layer. The damping coating therefore consists of two layers. If now the structure to be damped, e.g. B. a steel sheet is set in vibration, the surface undergoes alternating stretching and compression and tries to transfer this stretching and compression to the damping layer. The damping layer in turn tries to transfer this stretching and compression to the counter plate. If the counter plate is dimensioned correctly, it will only undergo this expansion and compression to a very limited extent due to its inherent stiffness. This then leads to a shear deformation of the damping layer and in turn to the conversion of vibrational energy into thermal energy. A sensible damping is achieved with layer thicknesses of damping layer plus counter plate, which correspond to approximately half to simple layer thickness of the steel plate to be damped (the structure to be damped). However, the damping effects which can thus be achieved under practically occurring conditions are still often unsatisfactory.

The task of this damping effect of such covering systems to increase, the task can be reduced Increase shear stress on the damping layer. These The problem is solved with the present invention.

A basic idea of the invention is through rigid Connection between the counter plate and the structure to be damped to increase the shear stress of the damping layer. A Another basic idea of the invention is through more than a counter plate and more than a damping layer Increase shear stress. The greatest advantage of the present Invention is achieved in that these two Basic ideas used simultaneously in a damping system will. Therefore, the following description focuses of the invention on systems that have at least two counter plates and contain at least two damping layers. The rigid one-sided connection of the counter plate and the one to be damped Structure in a damping system that only one damper layer and contains only one counter plate, however also subject of the present invention.  

The concept of the solution on which the invention is based will first be explained with reference to FIG. 2.

According to the state of the art, the two-layer system consisting of a damping (plastic) layer and a counter plate is replaced by a multi-layer system, which consists of two damping layers and two counter plates in Figure 2. On the structure to be damped 1 (z. B. steel sheet) is initially a damping layer 2 , which is covered by the counter plate 3 . Counter plate 3 has, according to the invention, an angular extension 10 which has a direct contact to structure 1 in area 8 . In area 8 , the counter plate is rigid according to the invention, for. B. connected by a weld to the structure to be damped 1 . According to the invention, a damping layer 4 is located on the counter plate 3 , which in turn is covered by the counter plate 5 according to the invention. Counter plate 5 is, according to the invention, analogous to counter plate 3 by an angular extension 9 in area 7 with structure 1 to be damped, in direct contact and according to the invention rigid, e.g. B. connected by a weld in the area 7 with the structure 1 . The area 6 represents an intermediate space which is either only air or a slightly compressible material, e.g. B. contains a foam.

If the structure 1 to be damped is deformed in the bending speed process in such a way that the side facing the damping system becomes concave according to FIG. 2a, the neutral fiber 11 retains its length, the surface 13 is stretched, the surface 12 of the structure to be damped is compressed. In accordance with this upsetting, the two counter plates 3 and 5 are now shifted against one another in direction 15 . The damping layers 2 and 4 are subjected to strong shear or shear deformation. The counter plate 3 moves in the direction of the angular extension 9 into the intermediate space 6 . If, in the course of the bending speed, the structure 1 deforms in the opposite direction in such a way that the side facing the damping system deforms convexly, the surface 13 is compressed and the surface 12 is stretched. In this case, the two counter plates 3 and 5 are displaced relative to one another in the direction 14 in accordance with the expansion, the intermediate layers 2 and 4 experiencing a strong shear deformation in the opposite direction of the shear deformation with a concave bending. The shear deformations occurring in the damping system according to the present invention are considerably greater than in the known two-layer system without a one-sided rigid connection between the counter plate and the structure to be damped. This higher shear deformation causes higher damping.

The damping effect can be increased if the thickness available for the damping system is divided over more than four layers. B. on six layers with three damping layers and three counter plates or on eight layers with four damping layers and four counter plates. The more layers are used, the better the damping effect. Here, a counter plate on one side and a counter plate on the other side are alternately rigidly connected to the structure to be damped in the same way as in the four-layer system. Such an eight-layer system is shown by way of example in FIG. 3.

A two-layer system, in which, in contrast to the previously known systems and in accordance with the present invention, the counter plate is rigidly connected on one side to the structure to be damped, has an increased damping effect compared to conventional systems. Such a two-layer system according to the invention is shown in FIG. 5.

Damping systems of the type according to the invention can also be applied to a carrier, which in turn is glued, screwed, riveted or welded onto the structure to be damped. In this case, the counter plates are rigidly connected to the carrier in the manner described above (see FIGS. 6 and 7). With the aid of such a carrier, simpler final assembly of the system is possible.

Damping systems of the type according to the invention are in their Application is not limited to the use of flat structures, but can also be curved to dampen Structures are applied. For example, round rods can also be used shaped structures such as z. B. in mechanical engineering and vehicle construction are used as shafts with a multilayer damper tion system of the type according to the invention advantageously equipped will. Surfaces of any shape can also be invented damping systems according to the invention.  

Damping systems of the type according to the invention can not only one-sided, but also two-sided symmetrical or asymmetrical be applied to the structure to be damped. With round systems there is a rotationally symmetrical arrangement possible. Rotationally symmetrical damping systems can either can be applied in one piece or segmented.

Multi-layer damping systems of the type according to the invention can advantageously z. B. in machine and vehicle construction Reduction of noise emissions or in machine tool construction to increase the smoothness and thus to increase the bear processing accuracy can be used.

The term is repeated in the following claims "Counter plate" used. This counter plate can be found here used sense z. B. made of metal, plastic, glass, wood, paper, Resins or mineral materials exist. It can have considerable thickness. The thickness does not necessarily have to be be small against the transverse dimensions.

The term "damping layer" is also used. It is stated that this "damping layer" has a sufficiently high damping capacity for the application. A further narrowing of their chemical nature has not been achieved. You can e.g. B. made of plastic, resins, bitumen or lead. The term "damping system" refers to the entire structure located on the structure to be damped.
Fig. 1
Layer structure based on the principle of the constrained covering (= state of the art)

1 Structure to be damped
2 suitable plastic layer = damping layer
3 counter plate

Fig. 2
Structure of the damping system according to the invention with two counter plates and two damping layers
1 Structure to be dampened, e.g. B. sheet steel
2 First (plastic) intermediate layer = first damping layer
3 first counter plate
4 second (plastic) intermediate layer = second damping layer
5 second counter plate
6 space, either empty or filled with slightly compressible medium
7 attachment point or attachment area of the counter plate 5 with the structure to be damped 1
8 Attachment point or attachment area of the counter plate 3 with the structure to be damped 1
9 Angular attachment of the counter plate 5 for direct rigid contact between the counter plate 5 and the structure to be damped 1
10 Angular attachment of the counter plates 3 for direct rigid contact between the counter plate 3 and the structure to be damped
11 neutral fiber
12 face of the structure facing the damping system
13 surface of the structure facing away from the damping system
14 Direction of movement of the counter plates 3 and 5 in the case of convex deformation of the surface 12 of the structure 1 to be damped which is connected to the damping system
15 Direction of movement of the counter plates 3 and 4 in the case of concave deformation of the surfaces 12 of the structure 1 to be damped which are connected to the damping system

Fig. 2a
Explanation of the shear deformation in the damping system according to the invention with two counter plates and two damping layers with concave deformation of the damping system

Fig. 2b
Explanation of the shear deformation in the damping system according to the invention with two counter plates and two damping layers with convex deformation of the damping system

Fig. 3
Damping system according to the invention with eight layers as an example of a system with more than four layers and common angular approaches of the counter plates

1 structure to be dampened
2 first damping layer
3 first counter plate
4 second damping layer
5 second counter plate
6 third damping layer
7 third counter plate
8 fourth damping layer
9 fourth counter plate
10 cavities, either with easily compressible material or filled with air
11 common angular approach of the counter plates with an even counter plate number, counted from below
12 common angular approach of the counter plates with odd counter plate number, counted from below

Fig. 4
Damping system according to the invention with eight layers as an example of a system with more than four layers and a separate angular attachment for each of the counter plates

1 structure to be damped
2 first damping layer
3 first counter plate
4 second damping layer
5 second counter plate
6 third damping layer
7 third counter plate
8 fourth damping layer
9 fourth counter plate
10 angular attachment of the second counter plate
11 angular attachment of the fourth counter plate
12 angular attachment of the first counter plate
13 angular attachment of the third counter plate
14 cavities either empty or filled with slightly compressible material

Fig. 5
Damping system with a damping layer and a counter plate rigidly connected to the structure to be damped via an angular extension

1 structure to be damped
2 damping layer
3 counter plate
4 angular approach
5 Area of the rigid connection between the structure to be damped and the counter plate

Fig. 6
Four-layer cushioning system with support

1 structure to be damped
2 supports of the damping system for easier assembly
3 first damping layer
4 first counter plate
5 second damping layer
6 second counter plate

Fig. 7
Eight-layer cushioning system with support

1 structure to be damped
2 supports of the damping system for easier assembly
3 eight-layer damping system as in Fig. 4, points 2-14

attachment
Literature:
Dietzel: To determine the loss factor of constrained damping pads on thin sheets, high-frequency technology and electroacoustics 76 (1967) 5, pp. 151-162
VDI guideline 3723 sheet 1: Sound insulation through structure-borne noise damping Physical principles and estimation methods

Claims (33)

1. flooring system for vibration damping of excited to oscillations planar or rod-shaped structures shown in FIG. 2, consisting of a first surface adhesively attached to the structure to be damped 1 Dämp deposition layer 2, a first areal integral with the cushion layer 2 lock plate 3, a second areal Damping layer 4 firmly connected to the counter plate 3 and a second counter plate 5 firmly connected to the second damping layer 4 , characterized in that it consists of two damping layers and two counter plates, with a damping layer 2 between structure 1 to be damped and the first counter plate and the second damping layer 4 is located between the first counter plate 3 and the second counter plate 5 . 2. flooring system for vibration damping of excited to oscillations planar or rod-shaped structures accordingly Fig. 2, consisting of a first with the structure to be damped 1 areally fixedly connected Dämp deposition layer 2, a first surface adhesively to the damping layer 2 associated lock plate 3, a second area-tightly connected to the counter plate 3 damping layer 4 and a second counter plate 5 firmly connected to the second damping layer 4 , characterized in that the counter plate 3 on one side (in the area 8 ) is rigidly connected to the structure 1 and the counter plate 5 the opposite side (in area 7 ) is rigidly connected to structure 1 . 3. covering system for vibration damping of vibrations flat or rod-shaped structures according to one or both of the preceding claims, characterized in that the counter plate 3 has an angular projection 10 and the counter plate 5 has an angular projection 9 and both angular approaches a direct contact with have the structure to be damped and the rigid connection of the two counter plates with the structure to be damped is carried out via these angular approaches. 4. covering system for vibration damping of flat or rod-shaped structures excited to vibrate accordingly Fig. 3, characterized in that the covering system consists of more than two counter plates and more than two damping layers. 5. covering system for vibration damping according to claim No. 4, characterized in that the first, third, fifth, etc. Counter plate, i.e. each counter plate with an odd number, on one side rigid with the structure to be damped and the second, fourth, sixth, etc. counter plate, So every counter plate with an even number the opposite side rigid with the one to be damped Structure is connected. 6. Pad system for vibration damping according to claim No. 4 or 5 according to Figure 3, characterized in that the first, third, fifth, etc. counter plate, that is, each counter plate with an odd number, on the one side with a common angular approach rigid with the damping structure is connected, and the second, fourth, sixth, etc. counter plate, that is, each counter plate with an even number, is rigidly connected to the structure on the opposite side via a common angular extension. 7. Pad system for vibration damping according to claim No. 4 and / or 5 corresponding to FIG. 4, characterized in that with more than two counter plates each counter plate is rigidly connected to the structure via its own angular approach. 8. covering system for vibration damping of flat or rod-shaped structures excited to vibrations according to FIG. 5, consisting of a damping layer and a counter plate, characterized in that the counter plate is rigidly connected to the structure on one side. 9. Pad system for vibration damping after one or more the previous claims, characterized in that the rigid connection between Counter plates and structure to be damped by Ver welding is made. 10. Pad system for vibration damping after one or more the preceding claims, characterized in that the rigid connection between Counter plates and structure to be dampened by gluing he follows. 11. Pad system for vibration damping after one or more the preceding claims, characterized in that the rigid connection between Counter plates and structure to be damped Riveting takes place.   12. Pad system for vibration damping after one or more the preceding claims, characterized in that the rigid connection between Counter plates and structure to be damped Screws. 13. Pad system for vibration damping after one or more of the preceding claims, characterized in that the rigid connection between Counter plates and structure to be damped Form locking takes place. 14. flooring system for vibration damping of excited to oscillations planar or rod-shaped structures accordingly Fig. 6, consisting of a first surface adhesively attached to the carrier 2 cushioning layer 3, a first surface adhering firmly to the cushion layer 3 associated counter-plate 4, a second surface adhesively with the counter plate 4 connected damping layer 5 and a second with the second damping layer 5 area firmly connected counter plate 6 , characterized in that two damping layers and two counter plates are used, with a damping layer 3 between the carrier 2 and the first counter plate 4 and the second damping layer 5 is located between the first counter plate 4 and the second counter plate 6 . 15. flooring system for vibration damping of excited to oscillations planar or rod-shaped structures accordingly Fig. 6, consisting of a first surface adhesively attached to the carrier 2 cushioning layer 3, a first surface adhering firmly to the cushion layer 3 associated counter-plate 4, a second surface adhesively with the lock plate 4 cushioning layer 5 connected, and a second with the second damping layer 5 areally fixed to counter-plate 6, characterized in that the lock plate 4 on the one side is rigidly connected to the carrier 2 and the counter-plate 6 on the opposite side is rigidly connected to the carrier 2 is connected. 16. covering system for vibration damping of vibrations sheet-like or rod-shaped structures accordingly Fig. 7, characterized in that the covering system consists of more than two counter plates rigidly connected to the carrier and more than two damping layers. 17. Pad system for vibration damping of vibrations sheet or rod-shaped structures accordingly Fig. 7 according to claim No. 16, characterized in that the first, third, fifth, etc. counter plate, ie each counter plate with an odd number, rigid on one side is connected to the carrier 2 , and the second, fourth, sixth, etc. counter plate, ie each counter plate with an even number, is rigidly connected to the carrier 2 on the opposite side. 18. Pad system for vibration damping from vibrations excited flat or rod-shaped structures from a counter plate, a damping layer and a carrier, characterized in that the counter plate on a Side is rigidly connected to the carrier. 19. Pad system for vibration damping of vibrations excited flat or rod-shaped structures one or more of claims 14 to 18, characterized in that the counter plates each over angular approaches rigidly connected to the carrier are. 20. Pad system for vibration damping from to vibrations excited flat or rod-shaped structures according to claims nos. 14 to 17, characterized in that the first, third, fifth etc. counter plate, so every counter plate with odd Number on one side over a common angle shaped approach is rigidly connected to the carrier and the second, fourth, sixth, etc. counter plate, so each counter plate with an even number, on the opposite lying side over a common angular Approach rigidly connected to the carrier. 21. Pad system for vibration damping after one or more claims 14 to 20, characterized in that the rigid connection between Counter plates and beams are made by welding.   22. Pad system for vibration damping after one or more claims 14 to 20, characterized in that the rigid connection between Counter plates and carrier are made by gluing. 23. Pad system for vibration damping after one or more claims 14 to 20, characterized in that the rigid connection between Counter plates and beams are made by riveting. 24. Pad system for vibration damping after one or more claims 14 to 20, characterized in that the rigid connection between Counter plates and carrier are made by screws. 25. Pad system for vibration damping after one or more claims 14 to 20, characterized in that the rigid connection between Counter plates and beams are made by positive locking. 26. Covering system for vibration damping of flat or rod-shaped structures excited to vibrations according to FIG. 6 according to one or more of claims No. 14 to 25, characterized in that the connection between the carrier 2 and the structure 1 to be damped takes place by gluing. 27. Covering system for vibration damping of flat or rod-shaped structures excited to vibrations accordingly Fig. 6 according to one or more of claims Nos. 14 to 25, characterized in that the connection between the carrier 2 and the structure 1 to be damped takes place by welding. 28 covering system for vibration damping of flat or rod-shaped structures excited to vibrations according to FIG. 6 according to one or more of claims No. 14 to 25, characterized in that the connection between the carrier 2 and the structure 1 to be damped is effected by screws. 29 covering system for vibration damping of flat or rod-shaped structures excited to vibrations according to FIG. 6 according to one or more of claims Nos. 14 to 25, characterized in that the connection of carrier 2 and structure 1 to be damped is produced by riveting. 30. covering system for vibration damping of vibrating flat or rod-shaped structures accordingly Fig. 6 according to one or more of claims No. 14 to 25, characterized in that the connection of the carrier and the structure to be damped is made by positive locking. 31 covering system for vibration damping of flat or rod-shaped structures excited to vibrations according to one or more of the preceding claims, characterized in that in each case between one end of a counter plate and the opposite angular approach of the overlying counter plate or a differently designed connection of the overlying counter plate damping structure there is an intermediate space (e.g. point 6 in figure 2, point 14 in figure 4) which is filled with air or another slightly compressible medium that allows the end of the counter plate to bend at the angle or during the bending process to approximate the differently designed connection so that the compression work from the medium in the cavity is significantly smaller than the thrust work on the damping layers. 32. Pad system for vibration damping after one or more of claims 1 to 13, characterized in that the rigid connection between Counter plates and structure to be damped Pens done. 33. Pad system for vibration damping after one or more of claims 14-20, characterized in that the rigid connection between counter plates and carrier by pins.