RU1825853C - Acoustic piece - Google Patents

Abstract

The invention relates to the field of noise control and can be used to make noise absorbing walls in industrial premises. The purpose of the invention is to increase acoustic efficiency in the field of low and medium sound frequencies, as well as to increase sound absorption in the high frequency region. For this, in the acoustic element, a two-layer elastic membrane 4 is fixed on the frame in the form of a frame 1. and its layers are made of polymer films of the same thickness, but of different polymers with sharply different dielectric constants, for example, polyethylene-polyvinyl chloride and polyethylene-polyamide, in frame 1 through holes 2 are made, and a protective acoustically transparent screen is made in the form of membranes of two layers of 6.7 fiberglass with different blowing resistance, fixed on the frame of 5 different thicknesses, installed x on different sides of the frame 1, and the layers of fiberglass 7 with less resistance to blowing are fixed on the outside of the frames 5. On the inner surface of the frame 1 above the holes 2 a strip of fabric 8 is glued, having a blowing resistance greater than that of layers 6, 7, during installation soundproofing partition elements are interconnected by means of strips 14 with the formation of resonant cavities 13.4 zp f-ly, 3 ill. h 00 yo eat 00 eat with tpltff

Description

The invention relates to the field of noise control and can be used to make noise absorbing walls in industrial premises.

The purpose of the invention is to increase acoustic efficiency in the field of low and medium sound frequencies, as well as to increase sound absorption in the high frequency region.

In FIG. 1 is a cross-sectional view of an acoustic element; in FIG. 2 is a cross section of a partition made of acoustic elements; in FIG. 3 is a fragment of a septum in an isometry with breakouts.

The acoustic element contains a frame about the form of frame 1 with holes 2 made in its opposite walls. Inside the frame, strips 3 are attached along the perimeter with a two-layer elastic membrane L, the layers of which are made of polymer films of the same thickness, but of different polymers with sharply different dielectric constants (for example , polyethylene-polyvinyl chloride and polyethylene-polyamide, etc.) and on its sides are attached frames 5, covered with fiberglass 6 and 7. Fiberglass membranes 6,7 have different resistance vaniyu. A strip of fabric 8 is glued onto the inner surface of the carcass 1 above the holes 2, which has a blow resistance higher than that of the membranes 6 and 7. When installing the partition, the acoustic elements are interconnected by means of strips 14 to form a cavity 13.

The acoustic element works as follows.

Sound waves falling on the side surface of the element lead to membrane vibrations of the fiberglass 7, which in turn excite air pulsation in the cavity 9. This pulsation forces the membrane 6 to vibrate and causes air pulsation in the cavity 10. The pulsation in cavity 10 is damped by elastic deformations 4. elastic membrane 4. and leakage of air through openings 2 at high hydraulic losses. Due to the active losses arising from the transitions of the oscillatory process, the dissipation of sound energy occurs. A similar process proceeds on the other side of the element. Therefore, the elastic membrane 4 undergoes bilateral bending deformations. During bending deformations, a shear occurs between the layers of the membrane 4 and friction occurs. Friction damps the propagation of vibrations across the membrane and the dissipation of sound energy occurs. Friction between the polymer layers gives rise to triboelectricity. Due to the arising Coulomb forces, between the layers of the membrane, increases

coefficient of friction and provides additional sound absorption.

The execution of the sidewalls in the form of fabric membranes with different resistance to blowing and not the same air

the gap between them increases the frequency range of noise reduction. Placement of a two-layer elastic membrane diagonally inside the element, due to the use of the effect of triboelectricity,

contributes to additional sound absorption in the midrange. In addition, with the help of the membrane 4 two resonator volumes are formed, which contribute to effective sound absorption on

low frequencies.

Thus, the system of cavities and membranes, when interacting with perforation of the frame walls, provides effective sound absorption in a wide range

frequencies. Therefore, acoustic performance is improved without the use of sound-absorbing material with the same dimensions of the elements.

Using the proposed element as a noise absorber increases the effectiveness of noise reduction measures and improves working conditions for workers. The exclusion of the use of sound-absorbing material increases

profitability of noise control.

Claims (5)

1.Acoustic element, including the frame in the form of a frame on which is fixed a two-layer membrane and a protective acoustically transparent screen, characterized in that, in order to increase acoustic efficiency in the low and medium frequencies, the membrane is mounted diagonally in the frame, and its layers are made of different materials with different dielectric constants, and the frame is made through holes. 2. The element according to claim 1, characterized in that the protective screen is made in the form bilayer membranes fixed to frames installed on opposite sides of the frame. 3. The element according to claim 2, characterized in that it is fixed on the membrane made of materials with different resistance to blowing. 4. An element according to claim 3, characterized in that, in order to increase the sound absorption capacity in the high frequency region, layers of material with a lower resistance to 5. The item according to paragraphs. 3 and 4, with the exception of blowing, they are fixed from the outside and so that the frames are made on different sides of the frames. Thickness. d., x uuu uuuol YvsNyyv A if / li // m / 7Ww // i; //// l li /// t FIG. Editor Compiled by A. Maslov Tehred M. Morgenthal Corrector L. Livrints FIG 3