FR2671899A1 - Coating for wide band passive acoustic absorption in a liquid - Google Patents

Abstract

The invention relates to a coating exhibiting properties of acoustic absorption in a liquid such as water. It consists of a stack of absorbing elements, each element being composed of a dense and rigid material (2) associated with an expandable material which can dissipate acoustic energy (4). The invention applies particularly to the production of anechoic chambers.

Description

COATING FOR BROADBAND PASSIVE SOUND ABSORPTION
IN A LIQUID
The present invention relates to a coating having sound absorption properties in a liquid such as water.

For acoustic waves to be absorbed in water, two simultaneous conditions must be met
- they are not reflected by the surface of the material, so that the acoustic impedance of the coating is identical to that of water,
- they are dissipated by viscosity, which implies a sufficiently dissipative material.

 It turns out to be impossible to use a coating made of a single material. Indeed a dense material (4000 Kg / m3 for example) and very damped will correctly absorb the low frequencies but will be bad for high frequencies.

There is generally a hole around 2000 Hz due to an anti-resonance.

 Under these conditions one can think of using a coating made up of several layers of different materials.

Thus for a thickness of 100 mm, the following distribution would be optimum for the first layer: 50 mm of material at Ç = 4000 Kg / m3 and - = 0.7
where is the density and X the ratio
between the imaginary part and the real part
the YOUNG module.

2nd layer: 30 mm of material at f = 3000 Kg / mS and 7 = 0.4 3rd layer: 20 mm of material at f = 2000 Kg / m3 and X = 0.2
The first layer is in contact with water and the third layer in contact with the wall to be protected.

 Unfortunately we do not know of any material meeting these conditions at present.

 The present invention aims to produce a coating whose structure will make it possible to obtain results equivalent to this superposition of theoretical layers.

 According to the invention, this covering consists of a stack of absorbent elements, each element being composed of a dense and rigid material associated with an expandable material dissipating acoustic energy. It is thus possible to obtain for an absorbent element a high density and the desired quality of absorption.

 Advantageously, the coating comprises several superimposed elementary coatings; each elementary coating is arranged to have a large absorption coefficient in a given frequency range and the various elementary coatings are calibrated on frequencies regularly distributed in the spectrum so as to obtain overall a substantially flat absorption curve.

 Preferably, an elementary coating is set essentially on frequencies of value greater than the cut-off frequency of the preceding coating so that, for the optimization of said elementary coating, said preceding coating can be considered as a rigid wall.

 Advantageously, each absorbent element may include a metal plate associated with one of elastic material.

This layer may include recesses and / or microbubbles so as to allow its expansion. Preferably, the elastic material consists of a plurality of pads arranged without contact and fixed to the metal plate.

 In one embodiment, the studs are in the form of bands, one of which is an endless band surrounding all the others, so as to seal between the metal plates.

 The present invention applies in particular to the production of anechoic chambers or even to the production of anechoic coatings for submersibles.

 Other characteristics, details and advantages of the invention will appear more clearly on reading the description which follows, given by way of example with reference to the accompanying drawings.

 Figure 1 is a perspective view showing a stack of cylindrical studs and plates.

 Figure 2 is a perspective view showing, in another embodiment, an absorbent element produced using strip-shaped pads.

Figure 3 is a sectional view, taken along the line
III - III of figure 2.

 Figure 4 is a sectional view of an embodiment of an elementary coating consisting of the stack of five absorbent elements.

 Figure 5 is a partial view of Figure 4, taken between lines V - V and V '- V' thereof. FIGS. 5 a to 5 f show the elementary coating at different frequencies.

 FIG. 6 is a diagram comprising on the ordinate the absorption coefficient and on the abscissa the frequency and showing the acoustic behavior of an elementary covering of FIGS. 4 and 5.

 FIG. 7 is a diagram similar to that of FIG. 6, illustrating the behavior of a coating constituted by the superposition of five elementary coatings.

 Figure 8 is a schematic view similar to that of Figure 5, of an embodiment of a coating consisting of the superposition of five elementary coatings.

 Figures 8a to 8f show the coating at different frequencies.

 FIG. 9 is a diagram similar to that of FIG. 7, showing the acoustic behavior of the covering of FIG. 8.

 Figure 10 is a sectional view, similar to Figure 3, illustrating another embodiment of an absorbent member.

 In Figure 1 we can see the wall 1 to be treated associated with the acoustic coating according to the invention. I1 comprises metal plates 2, for example of steel between which are arranged elastic pads 3 of cylindrical sections. The pads 3 may be glued to the plates 2 (or to the wall).

 In this embodiment, the coating has three layers. The lower layer consists of large 3 A studs (for example 50 mm in diameter and 50 mm high) connected to a thick 2 A steel plate.

This layer is intended to absorb low frequencies.

The intermediate layer consists of medium studs 3 B (for example of diameter 30 mm and height 30 mm) of more rigid material associated with a thinner plate 2 B
The upper layer consists of small studs
(for example with a diameter of 20 mm and a height of 20 mm) made of rigid material associated with an even thinner 2 C plate.

This plate is in contact with water.

 The total coating, in this exemplary embodiment, has a thickness of 100 mm. The use of cylindrical studs makes it necessary to provide sealing means (not shown) between the plates 2.

 In the embodiment of Figure 2, the elastic pads associated with the plates 2, are constituted by bands 4 of square or rectangular section. One of these bands 4a surrounds the others and makes it possible to ensure the seal between the plates.

 In Figures 4 and 5 we can see an elementary coating (5) consisting of the stack of five identical absorbent elements. In this example, an absorbent element has pads 4 made, for example of material UR 862 from the company HEXCEL and the plates 2 are made of steel.

The thickness of the studs is 20 mm and that of the plates 15 mm. Figures 5 a to 5 f show the elementary coating (5) at different frequencies, respectively 250 Hz 500 Hz, 1000 Hz, 2000 Hz, 4000 Hz, 8000 Hz.

 The absorption curve illustrated in FIG. 5 shows two maximums, then a very rapid decrease corresponding to the cut-off frequency Fc. The cut-off frequency is due to the fact that the elementary coating (5) is not homogeneous and can be roughly assimilated to a succession of masses and springs. Beyond the cut-off frequency, the coating no longer responds (the surface amplitude is zero); there is no longer any absorption. On the other hand, the covering behaves like a rigid wall.

If there is another elementary coating (5) set high in frequency, it will absorb as if it were placed on a rigid wall. Each elementary coating can thus be optimized separately by calculating it supported on a rigid wall.

This is how the diagram in FIG. 7 corresponds to the superposition of five elementary coatings (5), pectively
Curve A = 4 times 5 mm from UR 862 and 1 mm from steel,
Curve B = 3 times 10 mm from UR 862 and 2 mm from steel,
Curve C = 4 times 10 mm from UR 862 and 4 mm from steel,
Curve D = 3 times 20 mm from UR 862 and 8 mm from steel,
Curve E = 5 times 20 mm UR 862 and 15 mm of steel; the first coating is in contact with the liquid and the fifth in contact with the wall 1 to be protected.

 Curve F corresponds to the superposition of the five stacks and is roughly flat between 500 Hz to 16000 Hz.

FIG. 8 shows such a superposition of five elementary coatings 5 A, 5 B, 5 C, 5 D, 5 E,
To improve the absorption between 8000 and 16000 Hz, a high frequency layer (5 mm of UR 862 and 1 mm of steel) was added. This has the effect of decreasing the resonance frequency of the upper stack 5 A.

 Figure 8 shows the condition of the coating at 250 Hz.

 Figures 8 a to 8 f show the state of the coating at frequencies 500 Hz, 1000 Hz, 2000 HZ, 4000 hZ, 8000 Hz, and 16000 Hz.

 It can be seen that the elementary coatings have maximum efficiency for different frequencies.

 The curve in Figure 9 is remarkably flat between 500 Hz and 16000 Hz, the absorption coefficient being more than 0.94.

 The total thickness of the coating in this exemplary embodiment is 396 mm.

The invention allows easy optimization as a function of specific specifications (frequency band, areal mass, thickness, etc.)
By acting on the structure of an absorbent element, on the stack in each elementary coating and on the combination of said elementary coatings, an excellent absorption coefficient can be obtained in each particular case.

 FIG. 10 illustrates another embodiment of an absorbent element according to the invention.

 The plates 2 are no longer associated with separate pads but with a single layer 7 of an elastic material.

having recesses 8 or microbubbles.

 The material of layer 7 which is quasi-incompressible can expand thanks to these recesses.

 Naturally the studs described above could be made with a material having recesses or microbubbles.

Claims (9)

 1) Coating for broadband passive acoustic absorption in a liquid such as water, characterized in that it consists of a stack of absorbent elements, each element being composed of a dense and rigid material  (2) associated with an expandable material dissipating acoustic energy (3, 4, 7).  2) Coating according to claim 1, characterized in that it comprises several elementary coatings (5) superimposed and that each elementary coating (5) is arranged to have an absorption coefficient comprising in a given frequency range and that the different elementary coatings are calibrated on frequencies regularly distributed in the spectrum so as to obtain overall a substantially flat absorption curve.  3) Coating according to claim 2, characterized in that an elementary coating (5) is set on frequencies situated essentially beyond the cut-off frequency of the preceding coating so that, for the optimization of said elementary coating, may consider said previous coating as a rigid wall.  4) Coating according to claim 2 or 3, characterized in that an elementary coating (5) comprises several stacked absorbent elements.  5) Coating according to any one of the preceding claims, characterized in that each absorbent element comprises a metal or plastic plate (2) associated with a layer of elastic material (3, 4, 7).  6) Coating according to claim 5, characterized in that the layer of elastic material (7) has recesses and / or microbubbles so as to allow its expansion.  7) melon coating claim 5 or e, characterized in that the elastic material consists of a plurality of studs (3, 4) arranged without contact and fixed to the metal plate (2).  8) Coating according to claim 6, characterized in that the studs are in the form of bands (4), one of which is an endless band surrounding all the others so as to seal between the metal plates.  9) Coating according to claim 7, characterized in that the studs (3) are of cylindrical shape.