RU2656419C1 - Acoustic casing - Google Patents

Abstract

FIELD: acoustics.

SUBSTANCE: invention relates to industrial acoustics, in particular, to the broadband soundproofing, and can be used as the protection means against noise. Acoustic casing contains rigid walls, fitting the protective equipment in shape, and associated with them perforated walls, between which the sound-absorbing lining is located, rigid walls form the congruent to the equipment profile, equipped with noise silencers for the process units output and heat removal, at that the rigid walls form the profile of removable, sliding or bonnet types, which is mounted on the base by means of vibration isolating pads, for example of KV-1 or KV-2 type rugs; according to the invention, the sound-absorbing lining is made with resonant inserts and comprises smooth and perforated surfaces, between which a complex shaped sound-absorbing material layer is arranged, which is an alternation of solid areas and hollow sections, the hollow sections being formed by prismatic surfaces having cross-section, parallel to the plane of the drawing, the shape of a parallelogram, which internal surfaces have a toothed structure, herewith the vertices of the teeth face the inside of the prismatic surfaces, and the edges of the prismatic surfaces are fixed respectively on the smooth and perforated walls, the cavities of the hollow sections formed by the prismatic surfaces being filled with a sound absorber, and between a smooth surface and solid sections of a layer of sound-absorbing material of a complex shape, as well as between the perforated surface and solid areas, there are resonant plates with resonant inserts that perform the functions of the throats of the Helmholtz resonators.

EFFECT: increase the noise reduction efficiency by increase in the sound absorption coefficient by increase in the sound absorption surfaces while preserving the casing overall dimensions.

1 cl, 6 dwg

Description

The invention relates to industrial acoustics, in particular to broadband sound attenuation, and can be used as a means of protection against noise.

The closest technical solution to the technical nature and the achieved result is an acoustic casing according to AS USSR No. 348755, [prototype], containing a perforated wall and a sound-absorbing layer.

The disadvantage of the technical solution adopted as a prototype is the relatively low efficiency of sound attenuation due to the relatively low coefficient of sound absorption.

The technical result is an increase in the efficiency of sound attenuation.

This is achieved by the fact that in an acoustic casing containing rigid walls that fit the protected equipment in shape and perforated walls associated with them, between which a sound-absorbing cladding is located, the rigid walls form a profile congruent to the equipment, equipped with noise mufflers for removing process units and heat removal while the rigid walls form a profile of removable, sliding or bonnet types, which is installed on the base by means of vibration-isolating gaskets, for example, rugs of the KV-1 type or KV-2, the sound-absorbing lining is made with resonant inserts and contains smooth and perforated surfaces, between which there is a layer of sound-absorbing material of complex shape, which is an alternation of solid sections and hollow sections, and the hollow sections are formed by prismatic surfaces having a section parallel to the plane the drawing, the shape of a parallelogram, the inner surfaces of which have a toothed structure, with the tops of the teeth facing the prismatic surfaces, and the edges of the prismatic surfaces are mounted respectively on the smooth and perforated walls, the cavities of the hollow sections formed by the prismatic surfaces are filled with a sound absorber, and resonant plates are located between the smooth surface and the solid sections of the layer of sound-absorbing material of complex shape, as well as between the perforated surface and the solid sections with resonant inserts that serve as the necks of Helmholtz resonators.

As a sound-absorbing material, cermet with a degree of porosity in the range of optimal values is used: 30 ... 45%, or an element in the form of layer-wise and cross winding of porous threads wound on an acoustically transparent frame, for example, a wire frame, or an element made of a rigid porous noise-absorbing material such as metal foam or shell stone.

In FIG. 1 shows a general view of an acoustic enclosure; FIG. 2 - section aa of figure 1; in FIG. 3, 4, 5 - variants of the structural embodiment of the casing, in FIG. 6 is an embodiment of a sound-absorbing cladding 2 with resonant inserts.

The acoustic casing contains rigid walls 1 that fit the protected equipment 3 in shape, and associated perforated walls 8 between which sound-absorbing cladding 2 is located, and the hard walls 1 form a profile congruent to equipment 3, equipped with noise mufflers 6 and 7 for outputting technological units and heat dissipation, which may contain sound absorbers 9 (Fig. 1 and 2). Rigid walls form a profile of removable (Fig. 3), sliding (Fig. 4) or bonnet (Fig. 5) types, which is mounted on the base by means of vibration-isolating gaskets 5, for example, rugs of the KV-1 or KV-2 type. Equipment 3 is installed on vibration isolators 4. Metal-ceramic with a degree of porosity in the range of optimal values: 30 ... 45% is used as a sound-absorbing material. As a sound-absorbing material, an element in the form of a layer-wise and cross-wound of porous threads wound on an acoustically transparent frame, for example a wire frame (not shown) or an element of a rigid porous noise-absorbing material, for example, metal foam or shell rock, can be used.

The acoustic casing works as follows.

The sound energy from equipment 3, passing through the perforated wall 8, enters the layers of sound-absorbing cladding 2. The transition of sound energy into heat (dissipation, energy dissipation) occurs in the pores of the sound absorber, representing the Helmholtz resonator model, where energy losses occur due to friction oscillating with the frequency of excitation of the mass of air in the neck of the resonator against the walls of the neck itself, which has the form of a branched network of pores of a sound absorber. The perforation coefficient of the perforated wall 8 is taken to be equal to or more than 0.25.

A possible embodiment of the sound-absorbing cladding 2 (Fig. 6) with resonant inserts (holes) containing a smooth 13 and perforated 14 surface, between which is a layer of sound-absorbing material of complex shape, which is an alternation of solid sections 15 and hollow sections 17, with hollow sections 17 formed by prismatic surfaces having in cross section parallel to the plane of the drawing, the shape of a parallelogram, the inner surfaces of which have a gear structure 18, or wavy, or rhnost with spherical surfaces (not shown). Cavities 16 formed by smooth 13 and perforated 14 surfaces between which a layer of sound-absorbing material of complex shape is located are filled with a sound absorber. 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 13 and perforated 14 walls. The cavities 19 of the hollow sections 17 formed by prismatic surfaces are filled with construction foam. Between a smooth 13 surface and continuous sections 15 of a layer of sound-absorbing material of complex shape, as well as between a perforated 14 surface and continuous sections 15, there are resonant plates 20 and 21 with resonant inserts 22, which serve as the neck of Helmholtz resonators.

Sound-absorbing element with resonant inserts works as follows. Sound energy, passing through a layer of perforated surface 12 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, representing the Helmholtz resonator model, there are energy losses due to friction, which fluctuates with the excitation frequency of the mass of air in the mouth of the resonator, against the wall of the neck itself, which has the form of a branched network of micropores of the sound absorber. Between a smooth 11 surface and solid sections 13 of a layer of sound-absorbing material of complex shape, as well as between a perforated 12 surface and solid sections 13 there are resonant plates 18 and 19 with resonant holes 22, which serve as the neck of Helmholtz resonators.

The resonant holes 22 (inserts) located in the resonant plates 20 and 21, serve as the neck 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 22.

It is possible that inside the hollow sections 17, the inner surfaces of which have a toothed structure 18, additional resonant elements 23 are arranged, made in the form of spherical shells, the inner surface of which is connected by the resonant inserts 24 with cavities located between the perforated surface 14 and the solid sections 15 sound-absorbing element.

Claims (2)

1. An acoustic casing containing rigid walls that shape the equipment to be protected, and perforated walls associated with them, between which a sound-absorbing cladding is located, the hard walls form a profile congruent to the equipment, equipped with noise mufflers for removing process units and removing heat, while hard the walls form a profile of removable, sliding or bonnet types, which is installed on the base by means of vibration-isolating gaskets, for example, rugs of the KV-1 or KV-2 type, characterized in that the sound-absorbing cladding is made with resonant inserts and contains smooth and perforated surfaces, between which there is a layer of sound-absorbing material of complex shape, which is an alternation of solid sections and hollow sections, and the hollow sections are formed by prismatic surfaces having a parallelogram shape in cross section parallel to the plane of the drawing , the inner surfaces of which have a toothed structure, with the tops of the teeth facing the inside of the prismatic the edges of the prismatic surfaces are fixed respectively on the smooth and perforated walls, the cavities of the hollow sections formed by the prismatic surfaces are filled with a sound absorber, and resonant plates are located between the smooth surface and the continuous sections of the layer of sound-absorbing material of complex shape, as well as between the perforated surface and the continuous sections with resonant inserts that serve as the necks of Helmholtz resonators. 2. The acoustic casing according to claim 1, characterized in that inside the hollow sections of the sound-absorbing lining, the inner surfaces of which have a toothed structure, there are additional resonant elements made in the form of spherical shells, the inner surface of which is connected by resonant inserts with cavities located between perforated surface and solid sections of the sound-absorbing element.

Images