DE1197242B - Broadband anechoic sound-absorbing layer - Google Patents

Description

Broadband anechoic sound-absorbing layer The invention relates to a broadband anechoic sound-absorbing layer. Various types of broadband anechoic sound-absorbing layers in the field of liquid and solid-borne sound are known. In the first area, the wedge and rib absorbers, which are made of lossy rubber-elastic materials, should be mentioned in particular. They are used to line non-reflective water tanks. In the field of solid-state acoustics, for example, there are arrangements that consist of a loose or more or less bound bulk of granular substances; Plastics with an increased and correspondingly graduated temperature are also used.

These arrangements have if they are in a wide frequency range should act, the disadvantage of a large, with the wavelength comparable layer thickness; so they are quite time-consuming.

Every sound-absorbing layer is based on the following principle: For On the one hand, sound absorption is an adaptation of the medium to the incident one Sound wave to the absorbing layer is necessary, and on the other hand, the in sound energy entering the absorbing layer, irreversible to any other forms of energy can be transferred. The latter condition is the complete irreversible conversion of the sound energy into another form of energy extremely difficult in thin layers because of the previously known absorption materials do not show sufficiently high internal losses. The possibility of built-in Resonance systems an increased shear deformation in the absorber layer and thus increased Achieving losses necessarily leads to the narrow band of the absorber layer.

The present invention creates an absorber that can also be used in thin Layer thicknesses is broadband effective.

The present invention is based on scientific knowledge from that a broadband high sound absorption can be achieved if it succeeds in converting the sound energy into the energy of a flowing liquid from thinner To convert layer thickness or plastic deformation of a suitable material. The flow resistances and thus the losses are in thin layers of liquid due to viscosity high when the liquid is forced into these thin layers to stream.

So there must be a broadband sound-absorbing layer with means which increase the attenuation. According to the invention this is achieved by that in the sound-absorbing layer preferably perpendicular to the direction of the incident There are sound inclusions that create an alternating fluid flow. This alternating flow can be caused by friction or other types of losses of a suitable amount be weakened. It is essential that strong components of the flow perpendicular to the direction of the sound wave. Because this allows produce the absorber in a very thin design.

So this is a new type of flow absorber, an to which the transformation of the velocity in direction and magnitude plays an essential role Has.

The compressible inclusions can be used to force a flow, because liquids and plastic materials are practically incompressible. So one Alternating flow of substances in the flow or transformation layer comes about comes, compressible inclusions are required in their original volume the flowing substance can partially penetrate. The surface layer serves here not only for making a seal for a thin layer of liquid, but they can also be used to achieve a good match between the medium and the incident sound wave and the liquid. The use of plastic Materials instead of a liquid often has beneficial effects due to the higher viscosity of the plastic material.

According to the invention, the one provided with compressible inclusions needs Layer of the liquid and / or the plastic material is not simply coherent but it is often quite beneficial if it is broken up into many parts and is arranged in a carrier material. Through this division, inehr Create a rolling surface. A good and solid distribution of the liquid can be achieved Preserved over the entire wall to be covered. The spaces in between serve at the same time between the individual parts of the liquid to support the surface layer on the wall to be lined.

The liquid or the plastic material divided into many parts is located in channels and / or flat spaces. The channels or flat spaces can be arranged next to one another and also one above the other. This arrangement in small channels and flat spaces has the advantage that the area surrounding the liquid or the plastic material becomes very large, as a result of which the friction losses increase sharply. It does not matter how the channels and flat spaces are embedded in the carrier material. A regular arrangement can serve to facilitate the production process. An irregular arrangement in a statistical distribution can have the effect that the frequency width of the absorption is increased and the directional dependency of the reflected sound wave is changed in a suitable manner. The channels or flat spaces are expediently embedded in the material as a carrier material from which the surface layer is made, e.g. B. a rubber elastic material.

In another embodiment of the absorber according to the invention, they are compressible Inclusions arranged in the carrier material in the vicinity of liquid inclusions. With this absorber the plightness flows with simultaneous elastic deformation of the carrier material> into the compressible inclusions. Through this additional elastic deformation of the substrate, the energy loss is increased.

The compressible inclusions can either be free gas bubbles consist or of gas bubbles provided with a dü = waiidigen htffie, which are compressible However, inclusions can also consist of substances containing gold, such as B. Swan pieces or pieces of cork.

It is often expedient for the carrier material and / or the plastic material to be admixed with fibrous and / or platelet-shaped substances in order to achieve the loss factor.

The compressible Einschltisse also need Juecht in the liquid, or to be included in the plastic substance, when present in the form of depressions in the wall to be covered. This is important for the production of the sound absorbers according to the invention: the lined wall does not need to be processed in a special way before the lining. If it has depressions, these can interact as compressible inclusions of air or gas with the sound absorber according to the invention.

Another embodiment of the broadband according to the invention Sound absorber has channels and / or flat spaces that open into the surface open and have a connection with the outside space from which the sound wave is incident. This sound absorber plays in particular for the production of liquid absorbers a role. Which needs to be applied to the wall to be clad & carrier layer must then only consist of the carrier material and compressible inclusions but show lots of incisions on the surface.

Regarding the mode of operation, it should be said that the flowing layer must be thinner, the lower the viscosity of the material.

Substances with a higher viscosity, such as B. plasticized, tough plastics, have a slightly greater layer thickness. Tests have shown that the layer thicknesses for these materials at audible frequencies in the order of millimeters or Fractions of millimeters and therefore extremely small compared to the wavelength are. The tests have also shown that strong reflection weakening in the area of a few octaves can be easily achieved. Reflection factors below 100/9 are to be achieved.

Is a sound-soft wall with the broadband according to the invention Lining sound absorbers, it is useful that between the lining acoustically soft wall and the liquid or plastic inclusions containing Layer another layer with parts of heavy mass is arranged.

If you want to expand the range of action of the sound absorption arrangement towards high frequencies, a combination of the absorber mentioned in this patent specification with the rib absorber often described in the literature and often used as a lining in water-borne technology is recommended. This combination has the advantage that the layer thickness of the rib absorber can be greatly reduced by adding the absorber described above, compared with the pall used on its own.

Injection processes can be used to produce the broadband sound absorbers according to the invention. According to the invention, the material for the carrier layer and the liquid or the plastic compressible material is sprayed simultaneously onto the wall to be lined from several spray guns. Of course, it is possible to use the material for the carrier layer, e.g. B. a self-curing two-component plastic, and mix the idleness and then spray with a nozzle of a spraying machine on the wall to be lined. There is also the option of applying this mixed material using a spatula method. Solid compressible inclusions, which generally have small external dimensions, can either be added to the spray material before the spraying process, but they can also be sprinkled onto the wall to be lined at the same time as the spraying process. Another manufacturing method is that the wall to be lined is simply misted or injected with water and that the carrier material is then sprayed on.

For the production of the broadband sound absorbers according to the invention, that are to be glued to a wall to be lined, one assumes sheet-shaped Carrier layer. The manufacturing process ordered that in the carrier layer Holes have been rolled in that the carrier layer is sprayed with liquid and / or is sprinkled with firm compressible inclusions, and that the whole is in a calender is rolled into a mixed material.

Some exemplary embodiments of the broadband sound-absorbing layer according to the invention are shown in the drawing, on the basis of which what is essential to the invention is explained below. It shows Fig. 1, a sound absorbing layer consisting of a surface layer and an underlying provided with compressible tinschlüssen layer of a liquid or a plastic, F i g. 2 a layer in which the compressible inclusions lie in the surface of the wall to be lined, FIG . 3 shows a layer in which the compressible inclusions are arranged in the surface layer, FIG . 4 shows a layer, the carrier layer of which has channels containing fluid and compressible inclusions, FIG . 5 shows a layer, the carrier layer of which has channels filled with liquid and compressible inclusions in a regular arrangement, FIG. 6 shows a layer, the carrier layer of which has channels filled with liquid and compressible inclusions in an irregular arrangement, FIG. 7 a layer for damping liquid-borne noise, the carrier material of which contains compressible inclusions and has incisions on the surface which have been filled with liquid from the environment.

In Fig. 1 , a liquid layer 4 with compressible inclusions 5 is applied to the wall 1 to be lined and is covered with a relatively rigid cover layer 2. This cover layer faces the incident sound wave 3 . The incident sound 3 exerts a pressure on the cover layer 2 which causes a flow of liquid perpendicular to the direction of sound. The practically incompressible liquid flows into the compressible inclusions. In this way, sound energy is converted into the energy of flowing liquid. The energy of the flowing liquid is irreversibly converted into heat by friction on the wall 1 and on the cover layer 2 as well as by internal friction. FIG. 2 shows another embodiment of this sound absorber. The compressible inclusions 5 lie in depressions in the wall 1 to be lined. They are covered by a film 6 . This film 6 contributes to the destruction of the energy of the sound wave through its own internal losses when deformed. 3 shows the compressible inclusions 5 in the surface side of the cover layer 2 facing the liquid 4. Here, too, the side containing the inclusions is covered by a film 6. It is not absolutely necessary to cover the compressible inclusions with a film 6. The foil 6 is intended to prevent all to a larger gas bubble only a steady wandering of the gas inclusions 5 and a possible combination. F i g. 4 shows a sound absorber in which the arrangement of small channels 8 is introduced into a carrier material 7, FIG. 1, which forms the surface layer at the same time, with a statistical spread. The liquid 4 and compressible egg locks 5 are located in the channels 8. Under the pressure of the sound wave, the liquid flows in these narrow channels to the places where the compressible locks 5 are located. With this flow, the sound energy is finally transferred to a Wärtne.

F i g. 5 shows another embodiment of the invention. Sound absorbers There, channels 8 with liquid 4 and compressible inclusions 5 are introduced into the carrier material 7 applied to the wall 1 to be clad. In this absorber there are channels 8 and compressible inclusions 5 in a regular arrangement.

F i g. 6 shows a similarly constructed absorber, but here the channels 8 or flat spaces as well as the compressible inclusions 5 are in a statistical distribution. Such an absorber is generally obtained when the injection processes already mentioned are used in the production.

F i g. 7 shows yet another embodiment of the sound absorber according to the invention. Here, liquid channels 8 or flat spaces are introduced into the carrier material 7 by making incisions in the carrier material 7 . Such an absorber is particularly suitable for liquid-borne sound applications, because liquid enters the incisions, so that channels and flat spaces with liquid are created here, which interact with compressible inclusions in the carrier material 7 .

Claims (2)

Claims: 1. Broadband, anechoic schalldämp.-fende layer, characterized in that inclusions (5) are present in this layer, in which an alternating fluid flow is generated when the sound is incident, preferably perpendicular to the direction of the incident sound. 2. Layer according to claim 1, characterized in that a thin layer of a liquid and / or a plastic material provided with compressible inclusions is arranged behind a surface layer struck by the sound to be absorbed. 3. Layer according spoke 1 and 2, characterized in that this layer is divided into many individual layers with inclusions. 4. Layer according to claim 1 to 3, characterized in that the liquid provided with compressible inclusions and / or the plastic material is located in channels and / or flat spaces. 5. Layer according spoke 1 to 4, characterized in that the channels and / or flat spaces are regularly or statistically embedded in a carrier material, the surface layer also consisting of this carrier material. 6. Layer according to claim 1 to 5, characterized in that compressible inclusions are arranged in the carrier material in the vicinity of liquid inclusions. 7. Layer according to claim 1 to 6, characterized in that the compressible inclusions consist of free gas bubbles. 8. Layer according to claim 1 to 7, characterized in that the compressible inclusions consist of gas bubbles provided with a thin-walled envelope. 9. Layer according to claim 1 to 8, characterized in that the compressible inclusions consist of gas-containing substances. 10. Layer according to claim 1 to 9, characterized in that the carrier material and / or the plastic material to increase the loss factor fibrous and / or platelet-shaped substances are added. 11. Layer according to claim 1 to 10, characterized in that the compressible inclusions are contained in the form of depressions in the wall to be clad. 12. Layer according to claim 1 to 11, characterized in that the channels and / or flat spaces open openly into the surface and have a connection with the outer space from which the sound wave is incident. 13. Layer according to claim 1 to 12, characterized in that a further layer with parts of heavy mass is arranged between a sound-absorbing wall to be lined and the layer containing liquid or plastic inclusions. 14. Broadband reflective sound absorber according to spoke 1 to 13, characterized in that known absorbers such as rib absorbers or the like are used in front of him to expand the frequency range. 15. Layer according to claim 1 to 14, characterized in that the material for the carrier layer and the liquid or the plastic compressible material from several spray gun nozzles is sprayed simultaneously onto the wall to be lined. 16. Layer according spoke 14, characterized in that solid compressible inclusions are sprinkled onto the wall to be lined at the same time as the spraying process. 17. Layer according spoke 1 to 13, characterized in that holes are rolled into the carrier layer, that the carrier layer is sprayed with liquid and / or sprinkled with solid compressible inclusions and that the whole is then rolled into a mixed material in a calender.