RU2652020C1 - Method for acoustic isolation of equipment - Google Patents

Abstract

FIELD: acoustics.

SUBSTANCE: invention relates to acoustic isolation of equipment with means of broadband acoustic suppression and can be used in all sectors of the national economy as a means of protection against noise. Technical result is achieved by the fact that the method of sound insulation of equipment, consisting in the fact that the sound-insulating enclosure is installed on the floor of the building by means of at least four vibration-proof supports, made of the elastic material, for example, soft rubber, polyurethane, and it is lined from the inside with the sound-absorbing element, differs in that the sound-insulating enclosure is made in the form of a rectangular parallelepiped with the cutout in its lower face under the base of the process equipment, at the same time the base of the process equipment is installed on at least four vibration-proof supports that are based on the floor of the building, the clearance between the base of the process equipment and the cutout in the lower face of the rectangular parallelepiped is designed in order to prevent the transmission of vibrations from the process equipment to the sound-insulating enclosure, in which the ventilation channels are performed in order to eliminate equipment overheating, while the internal walls of the ventilation ducts are treated with the sound-absorbing material and with the acoustically transparent material of the "poviden" type, wherein the sound-absorbing element is fixed to the inner surface of the sound-insulating enclosure and it is made in the form of a smooth and perforated surface, between which the multi-layered sound-absorbing structure is placed, the sound-absorbing element, which is fixed to the inner surface of the sound-insulating enclosure, is made in the form of a rigid and perforated wall, between which a multi-layered sound-absorbing element is provided, which is made in the form of two layers: one of which, adjacent to the rigid wall, is sound-absorbing, and the other one, which is adjacent to the perforated wall, is made with the perforation from the sound-reflecting material of a complex profile, which consists of uniformly distributed hollow tetrahedra, while the material based on aluminum-containing alloys is used as a sound-reflecting material, followed by filling with titanium hydride or air with the density within 0.5…0.9 kg/m³ with the following strength properties: compressive strength within 5…10 MPa, bending strength within 10…20 MPa, for example foam aluminum, or soundproofing plates based on the glass staple fiber of the "Shumostop" type with the material density of 60÷80 kg/m³, or the material based on the magnesia binder with reinforcing fiberglass or glass wool.

EFFECT: technical result is the increased efficiency of noise suppression.

1 cl, 4 dwg

Description

The invention relates to sound insulation of equipment with means of broadband sound attenuation and can be used in all sectors of the economy as a means of protection against noise.

To reduce noise at workplaces of industrial premises, both sound-absorbing cladding and structures, as well as sound-insulating barriers installed on the most noisy equipment taking into account their acoustic characteristics are used. At the same time, the installation of soundproof fencing can be carried out both on the equipment as a whole, and on its individual nodes.

The closest technical solution to the claimed object is an acoustic casing for equipment according to the patent of the Russian Federation No. 2311286 (prototype), containing a housing and damping elements located inside it, as well as a sound-absorbing insert with sound-absorbing material.

A disadvantage of the known devices is the relatively low efficiency of sound attenuation due to the absence of silencers in the holes of the casing, designed to maintain thermal balance.

The technical result is an increase in the efficiency of noise suppression.

This is achieved by the fact that in the method of soundproofing the equipment, which consists in the fact that the soundproofing fence is installed on the floor of the building by means of at least four vibration isolating supports made of elastic material, for example soft rubber, polyurethane, and is lined on the inside with a sound-absorbing element, soundproofing the fencing is performed in the form of a rectangular parallelepiped with a cutout in its lower face under the base of the technological equipment, while the base of the technological At least four vibration isolating supports are installed on the floor of the building, based on the floor of the building, while a gap is made between the base of the processing equipment and the cutout in the lower face of the rectangular parallelepiped to prevent transmission of vibrations from the processing equipment to the soundproof enclosure in which the ventilation ducts to eliminate overheating of the equipment, while the internal walls of the ventilation ducts are treated with sound-absorbing ma erialom and acoustically transparent material such as "poviden", the sound absorbing member is fixed on the inner surface of the sound-insulating fence and operate in a smooth and perforated surfaces, between which is placed a multilayered acoustic structure, the calculation of required insulation casing as the unsealed enclosure is carried out according to the following relationship:

,

,

- реверберационный коэффициент звукопоглощения внутри i-го кожуха, где α_о - реверберационный коэффициент звукопоглощения для ограждений без звукопоглощающего материала; α_м - реверберационный коэффициент звукопоглощения звукопоглощающего материала; ΣS_м - площадь нанесения звукопоглощающего материала, м²; τ_i - энергетический коэффициент прохождения звука через глушитель технологического отверстия (для простого отверстия τ_i=1, причем простым отверстием считается отверстие без глушителя шума, как в нашем случае); ΣS_oi - суммарная площадь технологических отверстий для i-го кожуха машины, м²; ΣS_i - суммарная площадь сплошной части ограждения, м².where R _leather.tr is the required sound insulation of the casing, dB: R _si is the average sound insulation of the solid part of the fencing of the i-th casing, dB;

- reverberation coefficient of sound absorption inside the i-th casing, where α _о - reverberation coefficient of sound absorption for fences without sound-absorbing material; α _m - reverberation coefficient of sound absorption of sound-absorbing material; ΣS _m - the area of application of sound-absorbing material, m ² ; τ _i is the energy coefficient of sound transmission through the silencer of the technological hole (for a simple hole, τ _i = 1, and a simple hole is considered to be a hole without a silencer, as in our case); ΣS _oi is the total area of technological holes for the i-th machine casing, m ² ; ΣS _i - total area of the solid part of the fence, m ² .

In FIG. 1 shows a diagram of a soundproof fence designed to implement a method of soundproofing equipment, FIG. 2, 3, 4 - variants of the schemes of the sound-absorbing element fixed on the inner surface of the soundproof fence.

A soundproof fence (Fig. 1) for implementing the method of soundproofing equipment is intended for installation on vibro-acoustically active technological equipment 1 by shelter. Covering technological equipment 1, a soundproofing fence 6 is installed on the ceiling 5 of the building by means of at least four vibration isolating supports 12 and 13 made of an elastic material, for example, soft rubber, polyurethane. The soundproof fence 6 is lined on the inside with a sound-absorbing element 7 (Fig. 2) and has the shape of a rectangular parallelepiped with a cutout in its lower face under the base 2 of the technological equipment 1. The base 2 of the technological equipment 1 is installed on at least four vibration isolating supports 3 and 4, which are based on the overlap 5 of the industrial building, while a gap is made between the base 2 of the technological equipment 1 and the cutout in the lower face of the rectangular parallelepiped To exclude the transmission of vibrations from technological equipment 1 to the soundproof fence 6. Ventilation channels 8 and 9 are made in the soundproof fence 6 to eliminate overheating of the equipment, while the inner walls 10 of the ventilation channels 8 and 9 are treated with sound-absorbing material 11 and an acoustically transparent “see” material . The calculation of the required sound insulation of the casing as an unpressurized fence is carried out according to the following relationship:

,

,

- реверберационный коэффициент звукопоглощения внутри i-го кожуха, где α_o - реверберационный коэффициент звукопоглощения для ограждений без звукопоглощающего материала; α_м - реверберационный коэффициент звукопоглощения звукопоглощающего материала; ΣS_м - площадь нанесения звукопоглощающего материала, м²; τ_i - энергетический коэффициент прохождения звука через глушитель технологического отверстия (для простого отверстия τ_i=1, причем простым отверстием считается отверстие без глушителя шума, как в нашем случае); ΣS_oi - суммарная площадь технологических отверстий для i-го кожуха машины, м²; ΣS_i - суммарная площадь сплошной части ограждения, м².where R _skin..tr is the required sound insulation of the casing, dB; R _si - average sound insulation of the solid part of the fencing of the i-th casing, dB;

- reverberation coefficient of sound absorption inside the i-th casing, where α _o is the reverberation coefficient of sound absorption for fences without sound-absorbing material; α _m - reverberation coefficient of sound absorption of sound-absorbing material; ΣS _m - the area of application of sound-absorbing material, m ² ; τ _i is the energy coefficient of sound transmission through the silencer of the technological hole (for a simple hole, τ _i = 1, and a simple hole is considered to be a hole without a silencer, as in our case); ΣS _oi is the total area of technological holes for the i-th machine casing, m ² ; ΣS _i - total area of the solid part of the fence, m ² .

In FIG. 2 shows a diagram of a sound-absorbing element 7 mounted on the inner surface of a soundproof fence 6.

The sound-absorbing element contains a smooth 14 and perforated 15 surface, between which is placed a multilayer sound-absorbing structure.

The sound-absorbing structure is made of complex shape and is an alternation of solid sections 16 and hollow sections 17. Solid sections 16, in turn, are formed by smooth prismatic surfaces 18 located perpendicular to smooth 14 and perforated 15 surfaces and fixed to a smooth surface 14, as well as two connected with them and inclined relatively smooth prismatic surfaces 18 surfaces 19 of complex shape, having on one side a smooth surface, and on the other hand, serrated and and undulating portions or formed spherical shape (not shown) surface, the top teeth or projections directed inward of these surfaces, and the surfaces themselves fixed to the perforated surface 15. Embossed sound-absorbing elements 20 are attached to the smooth surface 14, for example, in the form of tetrahedrons.

As a sound-absorbing material, a material based on aluminum-containing alloys was 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, tensile strength bending within 10 ... 20 MPa, for example foam aluminum, or rockwool basalt mineral wool, or URSA mineral wool, or P-75 basalt wool, or glass wool lined with glass wool, or foamed polymer, such as polyethylene or by lipropylene.

The material of the perforated surface is made of solid decorative vibration-damping materials, for example, plastic compound such as Agate, Anti-Vibrate, Shvim, and the inner surface of the perforated surface facing the sound-absorbing structure is lined with an acoustically transparent material, such as fiberglass type EZ-100 or polymer like "Shaped". Hollow sections 17 are filled with sound-absorbing material, for example, construction foam.

Sound-absorbing element 7 operates as follows.

Sound energy from technological equipment 1, passing through a layer of perforated surface 15 and layer 17 of a sound-absorbing element made of foamed sound-absorbing material (construction foam), falls on sound-absorbing layers 16, 19, 20, where sound energy is dissipated due to its transition into heat (dissipation, energy dissipation), i.e. in the pores of the sound absorber, which are the Helmholtz resonator model, there are energy losses due to friction, which fluctuates with the excitation frequency of the mass of air in the resonator neck against the walls of the neck itself, which has the form of an extensive network of micropores of the sound absorber. The perforation coefficient of the perforated surface is taken to be equal to or more than 0.25.

The method of soundproofing equipment is as follows.

Soundproofing fence 6 (Fig. 1) is installed on the floor 5 of the building by means of at least four vibration isolating supports 12 and 13 made of an elastic material, for example, soft rubber, polyurethane. Soundproof fence 6 is lined (fixed on it) from the inside with a sound-absorbing element 7 (Fig. 2). The soundproofing fence 6 is made in the form of a rectangular parallelepiped with a cutout in its lower face under the base 2 of the technological equipment 1. The base 2 of the technological equipment 1 is installed on at least four vibration-isolating supports 3 and 4, which are based on the ceiling 5 of the industrial building, while between the base 2 of the technological equipment 1 and the cutout in the lower face of the rectangular parallelepiped, a gap is made to prevent transmission of vibrations from the technological orudovaniya 1 to 6. In the sound-insulating fence sound-insulating fence 6 operate ventilation ducts 8 and 9 to eliminate overheating, the inner wall 10 of ventilation ducts 8 and 9 treated with sound-absorbing material 11 and acoustically transparent material such as "poviden".

The sound-absorbing element 7 is fixed on the inner surface of the sound-insulating fence 6 and is made in the form of smooth 14 and perforated 15 surfaces, between which a multilayer sound-absorbing structure is placed.

The sound-absorbing structure (Fig. 3) is made of complex shape in the form of alternating solid sections 16 and hollow sections 17. The solid sections 16, in turn, are formed by smooth prismatic surfaces 18 located perpendicular to smooth 14 and perforated 15 surfaces and fixed to smooth 14 surface, as well as two surfaces 19 of complex shape associated with them and inclined with respect to smooth prismatic surfaces 18, having a smooth surface on one side and a gear or wave on the other a surface or formed by spherical sections (not shown) of the surface, the tops of the teeth or protrusions facing inward of these surfaces, and the surfaces themselves are fixed to the perforated surface 15. Embossed sound-absorbing elements 20 are attached to the smooth surface 14, for example, in the form of tetrahedrons.

As a sound-absorbing material, a material based on aluminum-containing alloys was 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, tensile strength bending within 10 ... 20 MPa, for example foam aluminum, or rockwool basalt mineral wool, or URSA mineral wool, or P-75 basalt wool, or glass wool lined with glass wool, or foamed polymer, such as polyethylene or by lipropylene.

The sound-absorbing element, which is fixed on the inner surface of the soundproof fence, is made in the form of rigid and perforated walls (Fig. 4), between which there is a multilayer sound-absorbing element, which is made in the form of two layers: one of which, adjacent to the rigid wall, is sound-absorbing, and the other, adjacent to the perforated wall, is made with perforation from a sound-reflecting material of a complex profile consisting of uniformly distributed hollow tetrahedrons, while e sound-reflecting material, material based on aluminum-containing alloys was used, followed by filling them with titanium hydride or air with a density in the range 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range 5 ... 10 MPa, bending strength within 10 ... 20 MPa, for example foam aluminum, or soundproofing boards based on glass staple fiber of the “Shumostop” type with a material density of 60 ÷ 80 kg / m ³ , or a material based on a magnesian binder with reinforcing fiberglass or fiberglass.

The calculation of the required sound insulation of the casing as an unpressurized fence is carried out according to the following relationship:

where R _skin.tr - the required sound insulation of the casing, dB, determined by the formula

L _i - octave sound pressure level at the design point from a single-working insulated machine, dB; L _add - permissible sound pressure level at the design point, dB; R _si - average sound insulation of the solid part of the fencing of the i-th casing, dB; α is the reverberation coefficient of sound absorption inside the i-th casing; τ _i is the energy coefficient of sound transmission through the silencer of the technological hole (for a simple hole, τ _i = 1, and a simple hole is considered to be a hole without a silencer, as in our case); ΣS _oi is the total area of technological holes for the i-th machine casing, m ² ; ΣS _i - total area of the solid part of the fence, m ² , determined by the formula

where l _i , b _i , h _i - respectively, the length, width and height of the i-th casing, m

The value of the reverberation coefficient of sound absorption inside the fence is determined by the formula

where α _about - the reverberation coefficient of sound absorption for fences without sound-absorbing material; α _m - reverberation coefficient of sound absorption of sound-absorbing material; ΣS _m - the area of application of sound-absorbing material, m ² .

A variant is possible when the sound-absorbing element 7 (Fig. 3), which is fixed on the inner surface 6 of the sound-insulating fence, is made in the form of smooth and perforated surfaces, between which a combined sound-absorbing layer of complex shape is placed, which is an alternation of solid sections 23 and hollow sections 25, whose frame is made of hard sound-absorbing material. Moreover, the hollow sections 25 are formed by prismatic surfaces having a parallelogram in cross section parallel to the drawing plane, the inner surfaces of which have a toothed structure 26, or wavy, or a surface with spherical surfaces (not shown). In this case, the tops of the teeth face the inside of the prismatic surfaces, and the edges of the prismatic surfaces are fixed respectively on the smooth 21 and perforated 22 surfaces. Cavities 24 formed by smooth 21 and perforated 22 surfaces, between which a combined sound-absorbing layer of complex shape is located, are filled with soft sound-absorbing material. The cavities 27 of the hollow sections 25 formed by the prismatic surfaces are filled with foamed polymer, for example polyethylene or polypropylene. Cavities 27 of the hollow sections 25 formed by prismatic surfaces are connected by resonant holes 28,29 and 30 with cavities 24 formed by smooth 21 and perforated 22 surfaces, between which a combined sound-absorbing layer of complex shape is located.

Sound-absorbing element 7 operates as follows.

Sound energy, passing through a layer of perforated surface 22 and a combined sound-absorbing layer of complex shape, decreases, since the transition of sound energy into thermal energy (dissipation, energy dissipation) occurs, i.e. in the pores of the sound absorber, which are the Helmholtz resonator model, there are energy losses due to friction, which fluctuates with the excitation frequency of the mass of air in the resonator neck against the walls of the neck itself, which has the form of an extensive network of micropores of the sound absorber. The resonant holes 28, 29 and 30 in the cavities 27 of the hollow sections 25 serve as the necks of the Helmholtz resonators, the frequency band of the damping of sound energy of which is determined by the diameter and number of resonant holes 28, 29 and 30.

A variant is possible when the sound-absorbing element 7 (Fig. 4), which is mounted on the inner surface 6 of the sound-insulating fence, is made in the form of a rigid wall 31 and a perforated wall 32, between which there is a two-layer combined sound-absorbing element, and the layer 33 adjacent to the rigid wall 31 is made sound-absorbing, and the layer 34 adjacent to the perforated wall 32 is made with a perforation 35 of a sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedra, which reflect sound waves incident in all directions.

As the sound-absorbing material of layer 33, rockwool-type mineral wool or URSA-type mineral wool, or P-75-type basalt wool or glass wool lined with glass wool, or a foamed polymer, such as polyethylene or polypropylene can be used. The surface of the fibrous absorbers is treated with porous paints that allow air to pass through, such as Acutex T, or coated with breathable fabrics or non-woven materials, such as Lutrasil.

As the material of the sound-reflecting layer 34, a material based on aluminum-containing alloys was 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 within 10 ... 20 MPa, for example foam aluminum, or soundproofing boards based on “Shumostop” glass staple fiber with a material density of 60 ÷ 80 kg / m ³ or a material based on magnesian binder with reinforcing fiberglass were used Anyu or fiberglass.

Sound-absorbing element 7 operates as follows.

Sound energy from equipment located in the room, or other object emitting intense noise, passing through the perforated wall 32, enters the layer 34 of the sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedrons, which allow reflecting sound waves incident in all directions, and part sound energy passes through a layer 34 of sound-reflecting material and interacts with a layer 33 of sound-absorbing material, where the final dissipation of sound energy occurs gies. The sound absorption coefficient of fibrous materials is in the range of 0.4 ... 1.0. Performing perforation on the sound-reflecting layer contributes to a more effective sound attenuation at medium frequencies, as part of the sound waves will pass through the perforation 35 and scatter on the layer 33 of sound-absorbing material.

Claims (3)

The method of soundproofing the equipment, namely, that the soundproofing fence is installed on the floor of the building by means of at least four vibration isolating supports made of elastic material, for example soft rubber, polyurethane, and is lined on the inside with a sound-absorbing element, characterized in that the soundproofing fence in shape in the form of a rectangular parallelepiped with a cutout in its lower face under the base of technological equipment, while the base is technological of the equipment installed on at least four vibration isolating supports, which are based on the floor of the building, while a gap is made between the base of the technological equipment and the cutout in the lower face of the rectangular parallelepiped to prevent transmission of vibrations from the technological equipment to the soundproof enclosure in which the ventilation ducts to eliminate overheating of the equipment, while the internal walls of the ventilation ducts are treated with sound-absorbing material ohm and acoustically transparent material such as "poviden", the sound absorbing member is fixed on the inner surface of the sound-insulating fence and operate in a smooth and perforated surfaces, between which is placed a multilayered acoustic structure, the calculation of required insulation casing as the unsealed enclosure is carried out according to the following relationship:

where R _skin.tr - the required sound insulation of the casing, dB; R _si - average sound insulation of the solid part of the fencing of the i-th casing, dB;

- reverberation coefficient of sound absorption inside the i-th casing, where α _o is the reverberation coefficient of sound absorption for fences without sound-absorbing material; α _m - reverberation coefficient of sound absorption of sound-absorbing material; ∑S _m - area of application of sound-absorbing material, m ² ; τ _i is the energy coefficient of sound transmission through the silencer of the technological hole (for a simple hole, τ _i = 1, and a simple hole is considered to be a hole without a silencer, as in our case); ∑S _oi is the total area of technological holes for the i-th machine casing, m ² ; ∑S _i is the total area of the solid part of the fence, m ² , while the sound-absorbing element, which is fixed on the inner surface of the sound-proof fence, is made in the form of a rigid and perforated wall, between which there is a multilayer sound-absorbing element, which is made in the form of two layers: one of which, adjacent to the rigid wall, are sound absorbing, and the other, adjacent to the perforated wall, is perforated from a sound-reflecting material of a complex profile, consisting of uniformly aspredelennyh hollow tetrahedrons, wherein a reflecting material as a material applied to aluminum-based alloys followed by filling them with air or titanium hydride having a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength within 5 ... 10 MPa, the flexural strength in the range of 10 ... 20 MPa, such as foamed aluminum or sound insulating plate on the base glass staple fibers "Shumostop" type material with a density of 60 ÷ 80 kg / m ^3, or magnesia based material yazhuschego with reinforcing glass fiber or glass-fiber.

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