RU2561389C1 - Sound-absorbing structure - Google Patents

Abstract

FIELD: physics, acoustics.

SUBSTANCE: invention relates to industrial acoustics. The sound-absorbing structure is in the form of two perforated walls with a multilayer sound-absorbing element in between. The multilayer sound-absorbing element is two-layered. The layer adjoining one of the walls is sound-absorbing and the layer adjoining the other perforated wall is made of sound-reflecting material with a complex profile, which consists of uniformly distributed hollow tetrahedrons, which enable to reflect sound waves incident in all directions. Each of the perforated walls has the following perforation parameters: hole diameter 3-7 mm, perforation percentage 10-15%, wherein the holes can be circular, triangular, square, rectangular or rhomboid. In case of non-circular holes, the nominal diameter should be considered the maximum diameter of the circle inscribed in the polygon. As the sound-absorbing material in the form of Rockwool mineral wool boards on a basalt base or URSA mineral wool or P-75 basalt wool or glass wool lined with glass felt is used. The sound absorbing element on its entire surface is lined with an acoustically transparent material, for example, EZ-100 glass cloth or Poviden polymer.

EFFECT: high efficiency of sound-proofing and reliability of the structure as a whole.

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Description

The invention relates to industrial acoustics.

Sound-absorbing structures [1, 2, 3] are known, comprising a rigid wall on which a sound-absorbing element is made made of a hard sound-absorbing material, for example foam concrete.

The disadvantage of this type of sound-absorbing structures is the relatively low degree of sound attenuation at medium and low frequencies of the spectrum.

Sound-absorbing structures are known [4, 5, 6], which contain rigid and perforated walls, between which a soft sound-absorbing element is located, made for example of polyurethane foam.

The disadvantage of this type of sound-absorbing structures is the relatively low degree of noise attenuation at high and low frequencies of the spectrum.

Sound-absorbing structures are known [7, 8], which contain rigid and perforated walls, between which a sound-absorbing element is made, made of a sound absorber with respect to the rigid wall.

The disadvantage of this type of sound-absorbing structures is the relatively low degree of noise attenuation at medium frequencies of the spectrum.

The closest technical solution to the technical nature and the achieved result is a sound-absorbing element used as a facing of industrial premises, known from RF patent No. 2463412 (prototype [9]).

The disadvantage of the technical solution adopted as a prototype is the relatively low noise reduction due to the presence of voids between the layers, where there is no sound absorption between the layers of the sound absorber.

The technical result is an increase in the efficiency of sound attenuation and the reliability of the structure as a whole.

This is achieved in that in a sound-absorbing structure made in the form of two perforated walls, between which a multilayer sound-absorbing element is located, the multilayer sound-absorbing element is made two-layer, the layer adjacent to one of the walls is made sound-absorbing, and adjacent to the other perforated wall is made of sound-reflecting complex profile material, consisting of uniformly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, to Each of the perforated walls has the following perforation parameters: the diameter of the holes is 3–7 mm, the percentage of perforation is 10 %–15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or diamond-shaped profile, in this case non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon, and as a sound-absorbing material, mineral wool slabs based on a basaltic rockwool type, or mineral wool type «URSA», or basalt wool type P-75, or glass lined steklovoylokom, wherein the sound-absorbing element over its entire surface is lined with an acoustically transparent material, such as fiberglass-type EG-100 or a polymer type "poviden".

The drawing shows a diagram of a sound-absorbing structure.

The sound-absorbing structure is made in the form of two perforated walls 1 and 2, between which there is a two-layer combined sound-absorbing element, the layer 3 adjacent to one of the walls 1 is made sound-absorbing, and adjacent to the other perforated wall 2 is made of a sound-reflecting material of a complex profile, consisting of evenly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions. The perforated wall has the following perforation parameters: the diameter of the holes is 3 ÷ 7 mm, the percentage of perforation is 10% ÷ 15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or rhomboid profile, while in the case of non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon. At the same time, the sound-absorbing layer 3 is placed in an acoustically transparent material 5, for example, fiberglass type EZ-100, or a polymer of the “visible” type, or a non-woven material, for example, “lutrasil”.

Each of walls 1 and 2 can be made of structural materials with a layer of soft vibration-damping material deposited on their surface on one or two sides, for example, VD-17 mastic, or “Gerlen-D” type material, and the ratio between the thicknesses of the material and vibration-damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5).

Each of walls 1 and 2 can be made of stainless steel or a galvanized sheet with a thickness of 0.7 mm with a protective and decorative polymer coating such as Pural 50 μm thick or Polyester 25 μm thick, or an aluminum sheet 1.0 mm thick and coating thickness 25 microns. The perforation coefficient of perforated sheets is taken to be equal to or more than 0.25.

Each of walls 1 and 2 can be made of solid, decorative vibration damping materials, for example, plastic compounds such as Agate, Anti-Vibrate, and Shvim.

As the material of the sound-reflecting layer 4, a material based on aluminum-containing alloys can be used, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range of 5 ... 10 MPa, bending strength in the range of 10 ... 20 MPa, for example foam aluminum, or soundproof boards based on glass staple fiber of the Shumostop type with a material density of 60 ÷ 80 kg / m ^{3 were used} .

As the sound-absorbing material of layer 3, rockwool-type mineral wool or URSA-type mineral wool, or P-75-type basalt wool or glass wool lined with glass wool, or foamed polymer, such as polyethylene or polypropylene can be used. Moreover, the sound-absorbing material is lined with an acoustically transparent material over its entire surface, for example, EZ-100 fiberglass or a “visible” polymer, or the surface of the fibrous sound absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T) or coated with breathable fabrics or non-woven materials, e.g. Lutrasil.

In addition, as the sound-absorbing material of layer 3, a porous sound-absorbing material can be used, for example, foam aluminum or cermet or a shell rock with a degree of porosity that is in the range of optimal values: 30–45%, or metal foam, or a material in the form of pressed crumbs from solid vibration damping materials, for example, elastomer, polyurethane, or plastic compound such as Agate, Anti-Vibrate, Shvim, and the size of the fractions of the crumbs lies in the optimal range of values: 0.3 ... 2.5 mm, and can also be used Porous mineral piece materials, such as pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers are used, while the surface of the fibrous absorbers is treated with special porous paints that allow air to pass through, for example, Acutex T or coated with breathable fabrics or non-woven materials, e.g. Lutrasil.

To reduce or correct the reverberation time of premises, sound-absorbing materials and structures (sound absorbers) are used in its decoration.

Porous sound absorbers are made in the form of plates that are attached to the enclosing surfaces directly or on the basis of light and porous mineral piece materials - pumice, vermiculite, kaolin, slag, etc. with cement or other binders. Such materials are quite durable and can be used to reduce noise in the corridors, foyer, staircases of public and industrial buildings.

The raw materials for their production are wood fibers, mineral wool, glass wool, synthetic fibers. The surface of the fibrous absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T) or coated with breathable fabrics or non-woven materials, such as Lutrasil.

Currently, fibrous sound absorbers are the most common in construction practice. They not only proved to be the most effective from an acoustic point of view in a wide frequency range, but also meet the increased requirements for room design.

As a sound-reflecting material, a material based on a magnesian binder with a reinforcing fiberglass or fiberglass was used.

Polyester is used as a sound-absorbing material.

As a sound-absorbing material, a porous fibrous or foamy sound-absorbing material is used, which is made on the basis of basalt or glass fibers, or open-cell polyurethane foam with a protective sound-transparent sheath made of thin fiberglass or aluminized lavsan film.

As the sound-absorbing material, a porous sound-absorbing ceramic material having a bulk density of 50 ÷ 1000 kg / m ³ and consisting of 100 mass parts of perlite with a particle diameter of 0.5 ÷ 2.0 mm, 100 ÷ 200 mass parts of one or more sintering materials and 10 ÷ 20 mass parts of binder materials. During sintering, perlite particles at adjacent points form adjacent pores. This material has good sound absorption in a wide frequency range, but has a high density associated with the content of a large number of sintering materials.

Sound-absorbing design works as follows.

Sound energy from equipment located in the room, or another object that emits intense noise, passing through the perforated walls 1 and 2 falls on layers 3 and 4. Layer 4 allows you to reflect sound waves incident in all directions, and part of the sound energy passes through the layer 4 from sound-reflecting material, and interacts with layer 3 of sound-absorbing material, where the final dissipation of sound energy occurs. In fibrous absorbers, the dissipation of the energy of air vibrations and its transformation into heat occurs at several physical levels. Firstly, due to the viscosity of the air, and there is a lot of it in the interfiber space, the oscillation of air particles inside the absorber leads to friction. The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of a sound absorber, which are the Helmholtz resonator model, where energy losses occur due to friction of the mass of air in the resonator neck oscillating with the frequency of excitation on the neck wall, which has the form of a branched sound absorber pore network. In addition, there is air friction on the fibers, the surface of which is also large. Thirdly, the fibers rub against each other and, finally, energy dissipation occurs due to the friction of the crystals of the fibers themselves. This explains that at medium and high frequencies the sound absorption coefficient of fibrous materials is in the range of 0.4 ... 1.0.

Sources of Bibliography Cited in Patent Search

1. Kochetov O.S., Kochetova M.O., Khodakova T.D. Sound-absorbing panel // Application for invention No. 2004115479 A. Published on November 10, 2005. Bulletin of inventions No. 31.

2. Kochetov O.S., Kochetova M.O., Khodakova T.D. Sound-absorbing panel // Application for invention No. 2004115481 A. Published on November 10, 2005. Bulletin of inventions No. 31.

3. Kochetov O.S., Kochetova M.O., Khodakova T.D. Acoustic panel // Application for invention No. 2005101161 A. Published on June 27, 2006. Bulletin of inventions No. 18.

4. Kochetov O.S., Sazhin B.S. Noise and vibration reduction in production: theory, calculation, technical solutions. M .: MSTU im. A.N. Kosygina, 2001 .-- 319 p. (Fig. 3.9, p. 54)

5. Kochetov O.S. Textile vibroacoustics. Textbook for universities. M .: MSTU im. A.N. Kosygina, the group "Sovezh Bevo" 2003.-191 p. (Fig. A.2, p. 176).

6. Kochetov O.S. Sound-absorbing structures to reduce noise in the workplace of industrial premises. The journal "Occupational Safety in Industry", No. 11, 2010, pp. 46-50. (fig. 1; p. 48 and fig. 2; p. 48)

7. Kochetov O.S., Golubeva M.V., Zubova I.Yu., Kostyleva A.V., Bobrova E.O., Gornushkina N.I., Pavlova D.O., Dukhanina E.V., Kolaeva L.V., Shevchenko N.V., Sokolova T.V. Sound-absorbing acoustic fence // Patent for the invention of the Russian Federation No. 2344488 C2. Published on January 20, 2009. Bulletin of inventions No. 2.

8. Kochetov O.S., Golubeva MV, Zubova I.Yu., Kostyleva A.V., Bobrova E.O., Gornushkina N.I., Pavlova D.O., Dukhanina E.V., Kolaeva L.V., Shevchenko N.V., Sokolova T.V. Sound-absorbing construction // Patent for the invention of the Russian Federation No. 2344490 C2. Published on January 20, 2009. Bulletin of inventions No. 2.

9. Kochetov O.S., Stareeva M.O. Sound-absorbing construction of the production room // Patent for the invention of the Russian Federation No. 2463412 C2. Published on October 10, 2012. Bulletin of inventions No. 28.

Claims (4)

1. Sound-absorbing structure made in the form of two perforated walls, between which there is a multilayer sound-absorbing element, characterized in that the multilayer sound-absorbing element is made two-layer, the layer adjacent to one of the walls is made sound-absorbing, and adjacent to the other perforated wall is made of sound-reflecting complex profile material, consisting of uniformly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, each one of the perforated walls has the following perforation parameters: hole diameter - 3 ÷ 7 mm, perforation percentage 10% ÷ 15%, moreover, the shape of the hole can be made in the form of holes of a round, triangular, square, rectangular or diamond-shaped profile, in this case non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon, and as a sound-absorbing material, slabs made of mineral wool based on basalt rockwool type, or mineral you type «URSA», or basalt wool type P-75, or glass lined steklovoylokom, wherein the sound-absorbing element over its entire surface is lined with an acoustically transparent material, such as fiberglass-type EG-100 or a polymer type "poviden". 2. The sound-absorbing structure according to claim 1, characterized in that a material based on aluminum-containing alloys is used as a sound-reflecting material, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties : compressive strength in the range of 5 ... 10 MPa, bending strength in the range of 10 ... 20 MPa, for example foamed aluminum, or soundproofing boards based on glass staple fiber of the “Shumostop” type with a material density of 60 ÷ 80 kg / m ³ . 3. The sound-absorbing structure according to claim 1, characterized in that the perforated wall can be made of structural materials with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material, deposited on their surface. the ratio between the thicknesses of the material and the vibration damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5), or stainless steel, or a galvanized sheet 0.7 mm thick with a polymer protective and decorative coating of the “Pural” type "Thick th 50 microns, or Polyester 25 microns thick, or 1.0 mm thick aluminum sheet and 25 microns coating thickness, or from hard decorative vibration-damping materials, for example, plastic compounds such as Agate, Anti-Vibrate, Shvim. 4. The sound-absorbing structure according to claim 1, characterized in that a material based on a magnesian binder with a reinforcing fiberglass or fiberglass is used as a sound-reflecting material.