RU2652166C1 - Method of investigation of acoustic characteristics of the objects in the echo-free chamber - Google Patents

Abstract

FIELD: acoustics.

SUBSTANCE: invention relates to industrial acoustics. In the eco-free chamber, in which the sound falling from the object under test is absorbed, the test object is placed onto the floating floor, while the echo-free chamber is placed in a separate building with the foundation, walls, overhead bulkhead, inside of which, on an independent foundation, its walls, the floating floor, on which the test object and a light overhead bulkhead are installed, are placed, the echo-free chamber is hermetically lined on all sides by the newly developed sound-absorbing element, which is to be tested on all the sides, where the sound power level L_p of the test object is determined according to the results of measurements of the average sound pressure level L_cp on its measuring surface, for which the hemisphere S area is assumed, m², i.e. S = 2πr², where r is the distance from the center of the test object to the measurement points; S₀=1 m², then the corrected sound power level L_pA is determined.

EFFECT: increased accuracy of measuring the efficiency of noise attenuation of the acoustic characteristics of the new sound-absorbing elements under investigation.

1 cl, 3 dwg

Description

The invention relates to industrial acoustics and can be used to study the acoustic characteristics of the sound-absorbing elements of the drive machines, facing industrial premises and other sound-absorbing structures.

The closest technical solution in terms of technical nature and the achieved result is a stand in which the sound power level L _p is determined by measuring the average sound pressure level L _cp on the measuring surface S, m ² , for which the hemisphere area, known from RF patent No. 2557332, is taken (prototype).

The disadvantage of the technical solution adopted as a prototype is the relatively low accuracy of measuring the noise attenuation efficiency of the studied acoustic characteristics of new sound-absorbing elements.

The technical result is to increase the accuracy of measuring the effectiveness of sound attenuation of the investigated acoustic characteristics of new sound-absorbing elements.

This is achieved by the fact that in the method for studying the acoustic characteristics of objects in a muffled chamber, which consists in installing a test object on a floating floor in a muffled chamber in which sound from the object being tested is absorbed, while the muffled chamber is placed in a separate building with a foundation, walls, ceiling, inside which, on an autonomous foundation, place its walls, a floating floor, on which the test object is installed and a light ceiling, muffled the chamber is hermetically lined on all sides with a newly developed and to be tested sound-absorbing element, while the sound power level L _{p of the} test object is determined by measuring the average sound pressure level L _cp on its measuring surface, for which the hemisphere area S, m ² , those. S = 2πr ² :

where r is the distance from the center of the test object to the measurement points; S ₀ = 1 m ²

then determined by the corrected sound power level L _pA , dB:

where L _Acp is the average sound level on the measuring surface of the test object.

In FIG. 1 shows a diagram of a device for studying the acoustic characteristics of objects in a muffled chamber, FIG. 2 is a diagram of an investigated new sound-absorbing element.

A device (Fig. 1) for studying the acoustic characteristics of objects, for example, new sound-absorbing elements, in a muffled chamber (Fig. 2), includes a muffled chamber 7, in which sound falling on the walls (there is no reflection) from the test object is almost completely absorbed, mounted on a floating floor 8. The muffled chamber 7 is hermetically lined on all sides with a newly developed and to be tested sound-absorbing element (Fig. 2). The muffled chamber 7 is placed in a separate building with a foundation 1, walls 2, ceiling 3, inside of which, on an autonomous foundation 4, its walls 5, floating floor 8, on which the test object and light ceiling 6 are installed, are placed.

A device (Fig. 1) for studying the acoustic characteristics of objects, for example, new sound-absorbing elements in a muffled chamber, operates as follows.

The sound power level L _{p of the} test object is determined by the results of measurements of the average sound pressure level L _cp on its measuring surface 10, for which the hemisphere S, m ² , is taken, i.e. S = 2πr ² :

where r is the distance from the center of the test object to the measurement points; S ₀ = 1 m ² .

Then, the corrected sound power level L _pA , dB is determined:

where L _Acp is the average sound level on the measuring surface 10 of the test object.

The studied sound-absorbing element (Fig. 2) contains a smooth 11 and perforated 12 surface, between which there is a layer of sound-absorbing material of complex shape, which is an alternation of solid sections 13 and hollow sections 15, and the hollow sections 15 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 gear structure 16, or wavy, or a surface with spherical surfaces (not shown about). Cavities 14 formed by smooth 11 and perforated 12 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 are turned inward to the prismatic surfaces, and the ribs of the prismatic surfaces are fixed respectively on the smooth 11 and perforated 12 walls. The cavities 17 of the hollow sections 15 formed by prismatic surfaces are filled with construction foam. Between the smooth 11 surface and the continuous sections 13 of the layer of sound-absorbing material of complex shape, as well as between the perforated 12 surface and the continuous sections 13, there are resonant plates 18 and 19 with resonant inserts 20 that serve as the neck of the Helmholtz resonators.

A material based on aluminum-containing alloys was used as a sound-absorbing 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, tensile strength bending within 10 ... 20 MPa, for example foam aluminum.

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 are used as sound absorbing material.

The material of the perforated surface is made of solid, decorative vibration-damping materials, for example, agate, antivibrate, and shvim plastic compounds, 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 "Poviden" type polymer.

The studied sound-absorbing element (Fig. 2) 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, 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. Between the smooth 11 surface and the continuous sections 13 of the layer of sound-absorbing material of complex shape, as well as between the perforated 12 surface and the continuous sections 13, there are resonant plates 18 and 19 with resonant inserts 20 that serve as the neck of the Helmholtz resonators.

The resonant holes 20 (inserts) located in the resonant plates 18 and 19, 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 20.

A method for studying the acoustic characteristics of objects in a muffled chamber is as follows.

In the silenced chamber, in which sound from the test object incident on the walls is absorbed, the test object is mounted on a floating floor, while the silenced chamber is placed in a separate building with a foundation, walls, ceiling, inside which, on an autonomous foundation, its floating walls are placed the floor on which the test object is installed and a light ceiling, the muffled chamber is hermetically lined on all sides with a newly developed and to be tested sound-absorbing element, while Level of sound pressure L _p of the test object is determined by the results of the average sound pressure level L _cp measurements on its measuring surface, which take over the area of the hemisphere S, m ^2, i.e. S = 2πr ² :

where r is the distance from the center of the test object to the measurement points; S ₀ = 1 m ²

then determined by the corrected sound power level L _pA , dB:

where L _Acp is the average sound level on the measuring surface of the test object.

The studied sound-absorbing element, as an option (Fig. 3), is made in the form of a rigid wall 21 and a perforated wall 22, between which there is a two-layer combined sound-absorbing element, and the layer 23 adjacent to the rigid wall 21 is made sound-absorbing, and adjacent to the perforated wall 22 layer 24 is made with perforation 25 of a sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedrons, allowing reflecting sound waves incident in all directions.

As sound-absorbing material of layer 23, 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. The surface of the fibrous absorbers is treated with porous paints that allow air to pass through, for example, Acutex T, or coated with breathable fabrics or non-woven materials, such as Lutrasil,

As the material of the sound-reflecting layer 24, 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 in the range of 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 glass fiber were used New or fiberglass.

Sound-absorbing element operates as follows.

Sound energy from equipment located in the room, or other object emitting intense noise, passing through the perforated wall 22, enters the layer 24 of 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 layer 24 of sound-reflecting material and interacts with layer 3 of sound-absorbing material, where the final dissipation of sound energy gii. 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 25 and scatter on the layer 23 of sound-absorbing material.

Claims (6)

A method for studying the acoustic characteristics of objects in a muffled chamber, which consists in installing a test object on a floating floor in a muffled chamber in which sound from the object being tested is absorbed, while the muffled chamber is placed in a separate building with a foundation, walls, ceiling a ceiling, inside of which, on an autonomous foundation, its walls are placed, a floating floor, on which a test object and a light ceiling are installed, while the muffled chamber is sealed but they are lined on all sides with a newly developed and to be tested sound-absorbing element, while the sound power level L _{p of the} test object is determined by measuring the average sound pressure level L _cp on its measuring surface, for which the hemisphere area S is taken, m ² , i.e. . S = 2πr ² :

where r is the distance from the center of the test object to the measurement points; S ₀ = 1 m ² then determined by the corrected sound power level L _pA , dB:

where L _Acp is the average sound level on the measuring surface of the test object, characterized in that the studied sound-absorbing element is made in the form of rigid and perforated walls, between which there is a multilayer sound-absorbing element made in the form of two layers: one of which is adjacent to the rigid wall, is sound-absorbing, and the other, adjacent to the perforated wall, is made with perforation of sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetras aedrons, in this case, 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, the flexural strength in the range of 10 ... 20 MPa, such as foamed aluminum or sound insulating plate on the base glass staple fiber type "Shumostop" material with a density of 60 ÷ 80 kg / m ^3, or material based on magnesia binder with reinforcing steklot Anya or with glass.

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