RU76743U1 - CAMERA REVERB - Google Patents

Abstract

The utility model is aimed at expanding the ability to measure the sound absorption characteristics of materials and structures under conditions of pulsed noise of a gas jet with a shock wave and increasing the accuracy of measurements by equalizing the overpressure in a limited volume of the chamber and by increasing its sound insulating properties. This problem is achieved in that the camera has an external box in the form of a straight quadrangular prism with non-parallel walls, truncated non-parallel to the base. Inside, an additional smaller box is installed, separated from the external soundproofing material, and a source of impulse noise is located in one of the upper trihedral angles, and relief valves are installed on the walls of the chamber with the highest overpressure of the gas stream. Soundproofing properties of the camera are improved due to the manufacture of the camera in the form of two loose fastened rigid ties and enclosed into each other boxes with rigid walls, but in contact with each other through an elastic soundproofing material. 1 n.p. f-ly, 1 ill.

Description

The utility model relates to the field of acoustics, analysis of sound waves and can be used to determine the sound absorption characteristics of materials and structures.

In accordance with GOST 26417-85 “Sound-absorbing building materials. Test method in a small reverberation chamber "(GOST 26417-85. Sound-absorbing building materials. Test method in a small reverberation chamber [Text]. Introduced 01.01.86. - M .: Publishing house of standards, 1985. - 15 p.) Accelerated method for determining the coefficients sound absorption of building materials on small samples with an area of 1-1.5 m ² and a thickness of not more than 100 mm is based on the use of a small camera with a total volume of 1.5-2 m ³ , where white noise generator and loudspeaker with a working frequency range are sound transmitting devices 50-8000 Hz creating a plurality of sound pressure levels up to 100 dB with an overall sound pressure level outside the chamber up to 70 dB.

An interferometer is also known (Piskarevsky NN, Golubkova LV. An experimental setup for measuring the characteristics of sound-absorbing structures by the interference method at high sound pressure levels. - Transactions of TsAGI, 1976, issue 1806, p. 54-73.), Which allows determine the sound-absorbing characteristics of high-level materials, which is a seamless metal pipe with a test sample diameter of 30 mm (with a total area of 7.1 · 10 ^-3 m ² ), where the conical horn is used as the sound source and

loudspeaker, in aggregate generating a sound level of up to 145 dB in the frequency range 630-6300 Hz.

The closest technical solution, selected as a prototype, is a small camera (K.A. Velizhanina, V.V. Yastrebov. The small-camera method as applied to studies of sound-absorbing systems at high sound levels. - Acoustic Journal. Volume 14, issue 1 , 1978 - S. 130-132.), In the form of a closed rectangular volume (chamber) of size l × h × b = 80 × 50 × 10 cm, where an exponentially tapering horn is used as a sound source, the inlet of which is connected to electrodynamic loudspeaker and together giving a sound level pressure of 143 dB. The test sample has dimensions of 0.05 or 0.08 m ² and is mounted on one of the respective sides with dimensions of 50 × 10 cm or 80 × 10 cm.

The disadvantage of such a camera is the area of its use, limited by the possibility of studying in it the sound emitted from a speaker with an electrodynamic loudspeaker. In addition, the use of a camera with rigid walls does not provide acceptable soundproofing of its walls.

The objective of the utility model is to expand the ability to measure the sound absorption characteristics of materials and structures under the conditions of pulsed noise of a gas jet with a shock wave and to increase the accuracy of measurements by equalizing the overpressure in a limited chamber volume and by increasing its sound insulating properties.

The problem is achieved in that the camera has an external box in the form of a straight quadrangular prism with non-parallel walls, truncated non-parallel to the base. Inside, the same smaller box is additionally installed, separated from the external by soundproofing material, and in one of the upper trihedral corners

a source of pulsed noise is located, and in the zone of the greatest excess pressure of the gas stream, relief valves are installed on the walls of the chamber.

Soundproofing properties of the camera are improved due to the manufacture of the camera in the form of two loose fastened rigid ties and enclosed into each other boxes with rigid walls, but in contact with each other through an elastic soundproofing material.

The essence of the utility model is illustrated in the drawing, where figure 1 shows a General view with a section of the reverberation chamber.

The reverberation chamber consists of an external 1 and an internal 2 ducts with a soundproofing gasket 3 between them, a removable cover 5 with a microphone 6 in it, an impulse noise source 4 installed, and relief valves 7 located on the faces of the upper trihedral angles opposite to the cover 5.

The reverberation chamber consists of two straight quadrangular prisms, truncated not parallel to the base, the smaller of which 1 fits tightly into the large 2, isolated from each other only by elastic soundproofing material 3. The rigid walls of the prisms are perpendicular to the base, but none of them are parallel to each other. In one of the upper trihedral angles, a source of impulse noise 4 is installed (for example, a gas jet from a starting gun or from a pneumatic distribution device), the propagation axis of which (normal to the exhaust cross-sectional area) is directed to the diagonal opposite trihedral angle. From the inside of the two-layer removable cover 5, the walls of which are also separated by an elastic soundproofing material 3, the studied material or structure with a total area of 1.5 m ² is attached. In the center of the material and the lid is a microphone 6 of the measuring system that processes the parameters of the sound signal.

Additionally, at the distance of the greatest effect of the overpressure of the gas stream from the apex of the angle in the direction of the diagonal axes of the chamber walls forming the trihedral angle, relief valves 7 are installed. Valves 7 are installed on each face of the two upper trihedral corners opposite the removable cover 5. Method of measuring sound absorption of materials in the reverberation the camera is implemented as follows.

Before starting work on the inner side of the removable cover 5 is placed the studied material. The cover 5 is mounted in the right place with a microphone 6. The shock wave is reproduced using a pulsed noise source 4. Excess pressure is released through the relief valves 7. The signal parameters are sensed by the microphone 6 and then fed to the processing of the measuring system.

An additional positive effect is that the volume of the camera allows you to simulate the limited space of the working area of workers when exposed to high-intensity pulsed noise. The use of a limited volume facilitates the use of computational models to simulate the generated high-intensity pulsed fields and the behavior of materials under their influence.

Claims (1)

A reverberation chamber, consisting of a rectangular duct with non-parallel walls, characterized in that the same duct is additionally installed inside, separated from the external soundproofing material, and in one of the upper trihedral angles there is a source of impulse noise, and in the zone of the greatest excess gas pressure jets on the walls of the chamber installed relief valves.