SU838029A1 - Resonance-type absorber - Google Patents

Description

The invention relates to acoustics, mainly building acoustics, and can be used to combat noise in industrial premises in the range of low and infrasound frequencies. ^s

A device for absorbing sound is known, which is a hollow club with perforated walls, separated inside by partitions, about * 10 times a few acoustic PP resonators.

The disadvantage of this device is its low acoustic and economic efficiency in the field of low and infrasound frequencies. This is due to the fact that as structural elements using acoustic resonators, each of which provides effective absorption _m schenie self-resonant frequency that is determined by its dimensions. Therefore, to increase the acoustic efficiency of the structure in the low and infrasonic frequencies range, it is necessary to increase its dimensions, which leads to significant material consumption of the structure and complicates its use in the practice of noise control in industrial premises. A device for absorbing sound is also known, including a sound-absorbing element - an acoustic resonator, in the form of a hollow half-cylinder with holes in the side wall [23.

The disadvantage of this device is its low acoustic and economic efficiency in the field of low and infrasonic frequencies, which is due to the fact that in this device, acoustic resonators in the form of a hollow half cylinder with holes in the side wall, which realize effective absorption at the natural resonant frequency, are used, which determined by the dimensions of the half cylinder. Therefore, to increase the acoustic3 838029 ”efficiency of the device in the low and infrasonic frequencies range, it is necessary to increase the dimensions of the semi-cylinders, which leads to significant material consumption of the device and complicates its use in the practice of noise control in industrial premises.

Closest to the proposed device is a sound absorption device, which is a structure consisting of a group of parallel-connected acoustic resonators, each of which is bounded by rigid blank walls and has an air cavity connected to the surrounding air through a hole (or holes) in the front wall I.

The disadvantage of this device is its low acoustic and economic efficiency in the field of low and infrasound frequencies. The disadvantages are due to the fact that the use of this design as effective sound absorbers in the low and infrasonic frequencies range entails a significant increase in their dimensions, since the dimensions of the air cavity increase with a decrease in the resonance frequency of the structure10

The boundary depth is determined from the condition of complete damping of the resonant absorber. In the low-frequency region, the active component of the normal impedance of the proposed design in fractions of the wave resistance of the air is expressed by the following relation: '₽ α L) ^С 0 β'

- active component of normal impedance;

- distance from the screen to the litte panel;

- area of the front panel;

- area of the hole;

- screen area;

. = 1,711 · 10 g / s · cm - coefficient of internal friction;

'= 1,29-1СГ’г / см ^ - density, air;

= 342'10 ^g cm / s - anchorness, sound in the air;

// = 3.141592.

If greater than 20, then the maximum absorption coefficient of the structure is not. exceeds 0.2. From this condition, the ratio for is obtained in the GHS system. ^GR 'In _gr = 5.7 - 1 O ^ -fs-enCSg / Sp).

So0n

where -Re

S

So

S ₃ gs, which complicates their use in the indicated sound range.

The purpose of the invention is to increase the acoustic and economic efficiency of resonant sound-absorbing structures in the field of low and infrasound frequencies without increasing their dimensions.

This object is achieved by the fact that the device 40 consisting of a group connected in series or in parallel acoustic resonators, each defined by rigid walls and the blind ⁴⁵ has Airforce hydrochloric cavity connected with the surrounding air through openings (or holes) in the flat front wall, in the center of the cavity opening parallel to the inner or outer surface of the front wall, a hard screen is installed having an area larger than the area of the cavity opening, but smaller than the front area nki, at a distance whose magnitude is not ⁵ ? exceeds 0.1 depths of the air cavity of the resonant absorber and not less than the boundary depth In _gR .

In a preferred embodiment of the device, it is provided that the surface area of the screen is not more than 0.95 of the area of the front wall and not less than 1.1 of the area of the hole in this wall.

In addition, the thickness of the screen does not exceed 0.1 of the length of the canceled sound wave.

Haha. 1 schematically shows an acoustic resonator with a hard screen mounted parallel to the inner surface of the front panel, sectional view; figure 2 is the same with a rigid screen mounted parallel to the outer surface of the front panel.

The device has an air cavity 1 bounded by rigid walls 2,. connected to the ambient air through a hole 3 in the flat faceplate 4. A hard screen 5 is mounted in the center of the hole 3 parallel to the inner or outer surface of the faceplate 4 using a mounting system 6.

The device operates as follows.

When sound falls on the resonator due to diffraction of the sound wave on the hard screen 5, the attached mass of the hole 3 increases, which leads to an increase in the inertial reactive component of the input impedance of the resonator and, consequently, to a decrease in its resonant frequency. A decrease in the resonant frequency of the resonator leads, in turn, to an increase in its acoustic efficiency in the region of low and infrasound frequencies, without an increase in its dimensions.

The use of the proposed resonators as structural elements of resonant sound absorbers in the low and Infrasonic frequencies range makes it possible to several times reduce the dimensions of these structures in comparison with the known ones, which significantly increases the cost-effectiveness of measures to combat noise in the specified sound range.

f

Claims (3)

The invention relates to acoustics, mainly structural acoustics, and can be used to combat noise in production rooms in the low and infrasonic frequency range. A device for sound absorption is known, which is a hollow club with perforated walls. internally divided by partitions forming several acoustic resonators. A disadvantage of this device is its low acoustic and economic efficiency at low and infrasonic frequencies. This is due to the fact that acoustic resonators are used as structural elements, each of which performs effective absorption at its own resonant frequency, which is determined by its dimensions. Therefore, in order to increase acoustic efficiency and design in the low and infrasonic frequency range, it is necessary to increase its dimensions, which leads to considerable material consumption of the structure and makes it difficult to use it in practice to combat noise in industrial premises. It is also known a device for absorbing sound, including a sound-absorbing element - an acoustic resonator, in the form of a hollow half-cylinder with holes in the side wall 123. A disadvantage of the device is its low acoustic and economic efficiency in the low and infrasonic frequencies region, which is due to This device is used as sound absorbing elements. Acoustic resonators in the form of a hollow half-cylinder with holes in the side wall perform effective absorption on their own second resonance frequency which is determined by the dimensions of the half-cylinder. Therefore, in order to increase the acoustic efficacy of the device in the low and infrasonic frequency range, it is necessary to increase the dimensions of the semicylinders, which leads to significant material consumption of the device and makes it difficult to use it in noise control practice in industrial premises. Closest to the present invention is a device for sound absorption, which is a structure consisting of a group of parallel-connected acoustic resonators, each of which is bounded by rigid deaf walls and has an air cavity connected to the surrounding air by holes (or apertures) in the front wall of Hz1 The disadvantage of such a device is its low acoustic and economic efficiency at low and infrasonic frequencies. The disadvantages are due to the fact that the use of this design as effective sound absorbers in the low and infrasonic frequency range entails a significant increase in their dimensions, since the dimensions of the air cavity increase with a decrease in the resonant frequency of the structure, which makes them difficult to use. The purpose of the invention is to increase the acoustic and economic efficiency of resonant sound-absorbing structures in the region of low and infrasonic frequencies without increasing their dimensions. This goal is achieved by the fact that in a device consisting of a group of acoustic resonators connected in series or in parallel, each of which is bounded by rigid blank walls and has an air cavity connected to the surrounding air by an opening (or apertures) in the flat front wall, The center of the resonator hole, parallel to the inner or outer surface of the face wall, is set to a rigid screen, with an area larger than the resonator hole area, but smaller face area howl wall at a distance, whose value does not exceed the depth of 0.1 air cavity resonance absorber and at least a boundary depth. The marginal depth is determined from the word of the complete damping of the resoans absorber. In the low-frequency region, the active component of the normal impedance of the proposed design, in terms of the wave impedance of the air, is expressed by the following ratio sen pe where -RC, the active component of the normal impedance; 1 distance from the screen to the lit panel; front panel; hole area; screen area; 1.711-10 g / s-cm-internal friction coefficient; 1.29-10 g / cm - density, air; 342-10 cm / s - 1 speed of sound in the air; 3.141592. If RCJ is greater than 20, then the maximum absorption coefficient of the structure does not exceed 0.2. From this condition, the ratio for USR 5,7-lo is-en (53 / Sp) is obtained in the GHS system. In a preferred embodiment of the device, it is provided that the surface area of the screen is not more than 0.95 of the area of the front wall and not less than 1.1 the area of the hole in this wall. In addition, the thickness of the screen does not exceed -0, 1 the length of the canceled sound wave. FIG. 1 shows schematically an acoustic resonator with a rigid screen mounted parallel to the inner surface of the front panel, a section; figure 2 - the same, with a rigid screen mounted parallel to the outer surface of the front panel. The device has an air cavity 1, limited by rigid walls 2,. connected to the ambient air through the hole 3 in the flat front panel 4. The center of the hole 3. parallel to the internal or external surface of the front panel 4 is installed hard screen 5 using mounting system 6. The device works as follows When sound is incident on the resonator due to diffraction of the sound wave on the hard screen 5 an increase in the added mass of the aperture 3 occurs, cht leads to an increase in the inertial reactive component of the input impedance of the resonator and, consequently, to a lowering of its resonance nsnoy frequency. A decrease in the resonant frequency of the resonator leads, in turn, to an increase in its acoustic efficiency in the region of low and infrasonic frequencies, without an increase in its dimensions. The use of the proposed resonators as structural elements of resonant sound absorbers in the low and infrasonic frequency range makes it possible to reduce the dimensions of these structures several times in comparison with the known ones, which significantly increases the cost-effectiveness of measures to combat noise in the specified sound range. Claim 1. A resonant absorber consisting of a group of acoustic resonators connected in series or in parallel, each of which is bounded by rigid deaf walls and has an air cavity connected to the surrounding air by an opening in the front wall, which is distinguished by the fact that in order to increase its acoustic and economic efficiency. In the region of low and infrasonic frequencies, a thin rigid screen is installed in the center of the resonator opening parallel to the inner or outer surface of the front wall, having an area larger than the cavity opening area but smaller than the front wall area and the distance from it is not more than 0.1 of the depth of the air cavity of the resonant absorber and not less than the boundary depth 1 defined by the ratio r, -7-io- - fsQ (s), where the boundary depth, cm; S is the area of the front wall, E is the area of the screen, SP is the hole area, see 2. Absorber according to claim 1, in which the surface area of the screen is not more than 0.95 of the area of the front wall and not less than 1 , 1 hole area in this wall. 3. The absorber according to Clause I., of that, and with the fact that the thickness of the screen does not exceed 0.1 of the length of the canceled sound wave. Sources of information taken into account in the examination 1. Abramchik M. and Maletsky I. Volumetric multiresonant absorber. Hustle Journal, 1959, V, 3. 2. Authors certificate of the USSR 573548, cl. E 04 B 1/74, 1974. 3. Yudin E.Ya. and Osipov G.L. Sound absorbing and sound insulating materials. M., stroiizdat ,. 1966, pp. 1338–39. / well FIG. T to: