DE1475062B2 - COMPONENT FOR VIBRATION DAMPING - Google Patents

Description

In the case of a component, this is described at the outset Type achieved according to the invention in that both damping layers are made of tough elastic Materials exist that the modulus of elasticity of the second damping layer is several times greater than the modulus of elasticity of the first damping layer, but much smaller than the modulus of elasticity of the component, and that the internal damping of the second damping layer is high in comparison to the internal damping of the component.

In the invention, therefore, there is the second damping layer not made of a practically rigid material. As with the well-known training, the The modulus of elasticity of the second damping layer is several times greater than the modulus of elasticity of the first Damping layer, but in contrast to the known training it is much smaller than the Modulus of elasticity of the component. In contrast to the known training, there is also the internal damping of the second damping layer is high compared to the internal damping of the component.

The design of the component according to the invention results in a significantly improved loss factor at low frequencies in the range of 100 Hertz and below and in the range of 1000 Hertz and above. This has the particular advantage that the component according to the invention has a high loss factor over the entire frequency range. The improved frequency behavior at low and high frequencies is based on the use of the two viscoplastic damping layers. .

In a preferred embodiment of the component according to the invention, in which in known Way at least one of the damping layers on at least one side with a top layer of load-bearing Material is provided, the cover layer can be arranged between the two viscoplastic damping layers. Such a training has proven to be particularly advantageous in practice. . ■■ '.-

In a further development of the invention, three damping layers can be used made of solid viscoplastic materials, of which the second and the third Damping layer have a modulus of elasticity several times greater than that of the first damping layer, wherein the second and the third damping layer on opposite sides of the component or the die first damping layer enclosing cover layers are arranged. Such a component has particularly favorable frequency properties because of the use of three damping layers.

Finally, the component according to the invention can be designed so that the tough elastic material the second damping layer with a higher modulus of elasticity contributes its maximum damping has a higher temperature than the material of the first damping layer. This is also used for different temperatures a damping over a wide frequency range, so a so-called Broadband temperature attenuation achieved. Various tough elastic materials are used, whose attenuation is strongest at different temperatures. The broader one achieved thereby Up to now, the temperature range could only be achieved by means of mixtures of substances.

Embodiments of the invention are set out below described on the basis of the drawing.

Fig. 1 shows a section through a component with three damping layers;

2 shows a section through a component with two damping layers; Fig. 3 shows damping curves;

F i g. 4 and 5 are sections through further exemplary embodiments, each with two damping layers. 1 shows a section through a component in composite construction which has two solid or rigid composite or cover layers 2 and 3 and three tough-elastic layers 1, 5 * and 6. The composite layers 2 and 3 adhere to opposite sides of the tough-elastic layer 1 and provide damping through transverse shear of the viscoplastic layer 1. Compared to the viscoplastic layer 1, the composite layers 2, 3 have a low hysteresis and a high modulus of elasticity. The composite component made of layers 1, 2 and 3 is characterized by the loss curve 4 shown in FIG. 3. The level of the loss factor achieved with the composite component 1, 2, 3 depends on the internal damping or hysteresis of the viscoplastic layer 1, the general shape of the curve 4 always remaining the same.

The outer sides of the composite layers are used to increase the attenuation and to expand the frequency range 2 and 3 provided with viscoplastic damping layers 5 and 6. The damping layers 5 and 6 have a high internal damping or hysteresis and a low modulus of elasticity compared to the composite layers 2 and 3. Compared to the viscoplastic damping layer 1, however, the viscoplastic damping Fungschichten 5 and 6 at least several times as large a modulus of elasticity. At one of the maximum The frequency corresponding to curve 4 does not show any great increase in the total attenuation. At this maximum damping frequency (reference number 7 in FIG. 3) the damping takes place predominantly by transverse shear stress on the viscoplastic damping layer 1 between the composite layers 2 and 3. This stress causes a certain deformation of the composite layers 2 and 3, while the damping layers 5 and 6 offer resistance to bending, whereby the course of the loss curve is somewhat improved.

However, a significant improvement in the loss curve takes place at low and high frequencies, which are denoted in FIG. 3 by the reference numerals Ta and Ib . The shear stress on the damping layer 1 is reduced. At these low and high frequencies there is still bending stress on the composite layers 2 and 3, the stress caused by the internal friction or hysteresis of the damping layers 5 and 6, 6. The component according to FIG. 1 not only has better attenuation, but also attenuation over a larger frequency range.

A comparable effect is achieved with the component according to FIG. 2, where a component 8, a the viscoplastic damping layer 9 corresponding to the damping layer 1 of FIG. 1 and a bonding layer 10 are shown, which either the composite layer 2 or the verburidschicht 3 in Fi g. 1 corresponds. If the composite layer 10 with a second

Coated damping layer 11 made of tough elastic material, which has a modulus of elasticity several times greater than the damping layer 9, but which compared to the composite layer 10 has a low modulus of elasticity and high internal damping, the same improvement in damping is conveyed as the curve Ta, 7, Tb in FIG. 3 is shown.

Acts on the component according to FIG. 1, a load a, this is taken up by the load-bearing composite layers 2 and 3, which are connected to the damping layer 1. At a Loading of the component according to FIG. 2 the load is mainly absorbed by the load-bearing component 8, although the composite layer 10 as a result of the connection with the damping layer 9 is also a part who can bear the burden.

The composite layers 2, 3 and 10 of FIGS. 1 and 2 are, as shown, with relative Bending resistant layers 5, 6 and 11 coated from damping materials. This can have the same effect be achieved that the damping properties built into the composite layers 2, 3 and 10 will. For example, a single layer of tough elastic material that is softer than the composite layers 2, 3 and 10, however, a modulus of elasticity several times higher than the damping layers 5, 6 and 11 has instead of the combined coating layers 2, 5 and 3, 6 and 10, 11 respectively Find use. High damping effects, which are not common, however, are used in Use of glass fiber reinforced plastics and with some metal alloys, for example Magnesium alloys or manganese copper alloys achieved. These natural vibration-free materials behave in the same way as the composite layers 2, 3 and 10, which are damped by the damping layers 5, 6 and 11.

The curve Ta, T, Tb shown in FIG. 3 was recorded on the basis of the component according to FIG. 1, the material of the central damping layer 1 having a transverse shear loss factor of 0.22 and the combined composite damping layers 2, 5 and 3, respectively , 6 had a total loss factor of 0.0475. In contrast, curve 4 in FIG. 3 shows the damping curve only with the composite layers 2 and 3 made of conventional, load-bearing material, with the damping layers 5 and 6 being omitted.

F i g. 4 shows a component in Verbun.dbauweise with a load-bearing component 12 to be damped, a rigid, stretchable damping layer 13, a soft one that dampens the shear stress Damping layer 14 and a composite layer 15. The maximum loss factor or: the maximum The damping capacity of the damping layer 13 is at a temperature above the maximum loss factor of the damping layer 14 low temperatures the damping of the component mainly due to the transverse loading of the

ίο Damping layer 14 mediates. At high temperatures the component is damped as a result of the bending deformation of the damping layer 13.

The composite layer 15 can be damped in accordance with the measures described above.

This achieves effective damping of the component over a larger temperature range, than with damping based either only on transverse stress or only on extensibility was possible alone.

F i g. 5 shows a component in composite construction, in which two identical load-bearing, load-bearing Components or composite layers 16 are provided, which by means of two damping layers 17 and 18 are connected to each other. The damping layer 17 consists of one rigid, stretchable damping material and the damping layer 18 made of a soft, the transverse shear stress damping material. The behavior of this component is essentially the same as that described with reference to FIG Component. The composite layer 16 can also be damped in accordance with the measures described above will.

In the components according to the Fi g. 4 and 5

the material for the damping layers 13 and 17 speaks to the material for the second damping layers 5 and 6 or 11 according to FIGS. 1 and 2. The material of the damping layers 13 and 17 has a modulus of elasticity several times as high as the material of the damping layers 14 and 18, which correspond to the first damping layer 1 and 9 according to FIGS. The loss factor for the components according to FIGS. 4 and 5 corresponds to the curve 7a, 7, Tb.

If in the components according to FIGS. 1 and 2, the material for the second damping layers 5, 6 and 11 is at its greatest damping a higher temperature than the material of the first damping layers 1 and 9 reached, extends the attenuation over a larger temperature range.

1 sheet of drawings

Claims (4)

1 2 has a modulus of elasticity that is several times greater than the modulus of elasticity of the first damping layer. 1. Component for vibration damping, in such a component is known (German the one component to be damped in composite construction 5 Auslegeschrift 1 126 684, in particular FIG. 1 and 2). wise with at least two damping layers. The known component consists like that is provided from solid damping materials, component according to the invention from a to dampen of which at least the first has a low fenden component, a first arranged above Modulus of elasticity in comparison to the elastic damping layer of a cover module arranged above it of the component and a high inner IO layer and one between the component and the first Damping compared to the inner damping damping layer arranged second damping des Component has, the second damping layer. The component to be damped is to be coated as a rigid layer has a modulus of elasticity that can be seen multiple times and has a very high modulus of elasticity is greater than the modulus of elasticity of the first and a low internal damping. The first dampening layer, this is characterized by a strong dampening effect; she has a niece e t that both damping layers (1, 9, 14, modulus of elasticity and a high internal damping 18; 5, 6, 11, 13, 17) made of tough elastic construction compared to the corresponding values materials exist that the modulus of elasticity that of the component. second damping layer (5, 6, 11, 13, 17) in the known component between the Although it is several times greater than the modulus of elasticity 20 component and the first damping layer angeordder first damping layer (1, 9, 14, 18), but nete second damping layer is proportionate much smaller than the modulus of elasticity of the dick and forms a spacer between the building component (2, 3, 8, 12, 16), and that also the part and the first damping layer. Although the inner damping of the second damping layer second damping layer damping, with loss is high compared to the internal cushioning 25 may contain contaminated material, such as honeycomb-like of the component. Components, rigid foamed plastics, stretched 2. Component according to claim 1, in which min- metals or ceramics, this damping layer should At least one of the damping layers has a shear stiffness that is much greater than that at least one side with a cover layer made from the first damping layer. The overall thrust Material is provided, thereby marked stiffness and the j shows that the top layer (2, 3, 10) between the loss factor of the combination of the first damping ' the two viscoplastic damping layers should essentially be the same as the damping layer. (1, 9; 5, 6, 11) is arranged (Fig. 1, 2). corresponding values of the first damping layer 3. Component according to one of the preceding be alone, provided that the thrust ^; Claims, characterized in that three 35 stiffness of the second acting as a spacer ^; Damping layers (1, 5, 6) made of solid tough damping layer at least ten times the elastic materials are provided by the first damping layer. The second dampening the second and the third damping layer fungsschicht thus acts in the known component (5, 6) a several times greater modulus of elasticity element practically as a rigid spacer than the first damping layer (1), and that 40 that the entire deformation in the resilient the second and the third cushioning layer occurs on the first cushioning layer. On the basis of the material specifications made for opposite sides of the component (2, 3) or the spacer, which include the first damping layer (1), it is evident that the modulus of elasticity of this spacer; the cover layers (2, 3) are arranged several times, even many times larger than the holder ^! (Fig. 1). 45 modulus of elasticity of the first damping layer and 4. Component according to one of the preceding practically the order of magnitude of the modulus of elasticity Claims, characterized in that that of the component reaches itself. The modulus of elasticity of the The viscoplastic material of the second damping layer (5, 6, 11, 13, 17), which acts as a spacer, with a higher elastic layer can therefore be several thousand times larger modulus of elasticity has its maximum damping at a temperature 5 ° higher than the modulus of elasticity of the first damping temperature than the material of the layer. first damping layer (1, 9, 14, 18). The same applies to the internal damping of the second damping layer. This may contain damping material, but it does not consist of 55 finally out of it. So this layer has a certain internal damping, but certainly not one high damping compared to the internal damping of the actual component. In the known component, the loss The invention relates to a component for vibration factor in the range between 100 and 1000 Hertz, in which a component to be damped has a pronounced maximum and falls sharply at lower frequencies in composite construction with at least two damping frequencies, while the values of the loss layers consist of solid damping material factor is not provided for high frequencies above 1000 Hertz, of which at least the first one or only partially is specified,
In contrast, the invention has the task of modulus of elasticity of the component and a high internal reason to improve the damping properties of a component damping compared to the internal damping in composite construction and the Fredes component, with the second damping layer having a frequency range to expand the effective damping.