SU1733590A1 - V-shaped sound absorber - Google Patents

Abstract

The invention relates to building acoustics and can be used in the construction of silenced sound cameras designed for precise acoustic measurements. The purpose of the invention is to increase the sound absorption coefficient. To do this, in a wedge sound absorber with a frame, the transverse elements of which are made in the form of gratings 3, and the longitudinal in the form of rods, the latter are equipped with at least one partition 7 in the form of a plate that breaks formed by sound-absorbing material 2, an acoustically transparent material 5 and gratings 3 cavities 6 to a larger number of cavities, and lattices 3 are mounted on the rods at such a distance that the volumes of the cavities divided by them 6 are related to each other as mutually simple numbers, for example 1: 3: 5. 1 hp f-ly, 3 ill.

Description

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The invention relates to building acoustics and can be used in the construction of silenced sound cameras designed for precise acoustic measurements.

The aim of the invention is to increase the sound absorption coefficient.

FIG. 1 shows a wedge sound absorber with breakouts; in fig. 2 - the same, longitudinal section; in fig. 3 - the same cross section.

The wedge sound absorber includes rigid sound absorbing material 1 filled in the form of a wedge, pyramid or cone with a height of 1.51 m from basalt microthin fiber (BMTV) or mineral wool, on top of which a soft sound absorbing material 2 is laid, superthin basalt fiber BSTV 0.02 m thick, which is sewn to

hard material with glass threads using a sewing machine or glued with a polyvinyl acetate emulsion.

Material 2, under certain conditions, may be absent when a semi-rigid sound-absorbing material is used as material 1. A wedge with transverse elements in the form of rectangular grids 3 with a thickness of 0.15 m with grooves and longitudinal elements made from rods 4 placed in them is made to the wedge (pyramid, cone) so made (for the cone, the grating 3 is in the form of a circle).

Lattice 3 is made of non-combustible plastic, light metal corners, wooden slats, impregnated with anti-pyrene, etc. A bag of acoustically transparent material is rigidly attached to the frame

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ala 5, stitched in the form of the frame. Glass fiber of brands EZ-100, TST-6, TST-8, etc., can be used as such material, it is acoustically transparent for high and some part of middle frequencies.

Between the sound-absorbing material and the acoustically transparent material 5, air cavities 6 are formed, limited by elements of the lattice 3 and partitions 7 of plates with a thickness of 0.001 m. To expand the active sound absorption region of the lattice 3, they are installed on rods x 4 at distances of 0.13 m (from wedge tops) 0.39 and 0.65 m so that the volumes of the 3 lattice elements 6 separated by the lattice elements are related to each other as mutually simple numbers (1: 3: 5).

For rhythmic camera with a larger lower boundary frequency of sound absorption, the number of partitions can be increased. With a further increase in the cut-off frequency of the chamber, the glass cloth adheres to the grille, forming caissons with a sound-absorbing bottom.

A wedge sound absorber with a base 8 0.2 x 0.2 m is attached to a special metal structure installed in a chamber (not shown) having slots for hooking it with hooks, bolts, rods, etc., located in the base 8.

A sound wave, falling on a wall of wedge elements, is partially dispersed at their tops. Under the action of a sound wave, fiberglass, works like a membrane, fixed at some distance from the sound-absorbing material 2, causing dissipative losses and increasing sound absorption at low frequencies. Fluctuations of fiber glass fibers cause dissipative energy losses of sound vibrations. At the same time, a bag made of fiberglass in the form of a wedge, cone or pyramid, rigidly stretched onto the framework, can be considered as a system of membranes separated by stiffeners. A significant contribution to the sound absorption is also due to the attached (soothing vibrating) air masses on both sides of the stretched glass fabric, especially in the case when the glass fabric is rigidly fixed (glued) along the contour of the grille and ribs. In this case, the added masses from the external sides of the neighboring wedges oscillate in antiphase and, due to interference, increase sound absorption at low frequencies.

Opposite sides of material 5 acoustically transparent for certain frequencies oscillate in antiphase and

initiate in air volumes of cavities 6 opposite or phase-shifted oscillations interfering with each other. This shift may be different depending on the number of partitions. When the number of partitions is more than three in cavity 6, standing waves are set up, which decay very quickly due to the presence of a closely located sound-absorbing material. It also enhances sound absorption in the low and partially mid frequency range. With four partitions 7 located along the rods 9, and a greater number of them, they form like caissons with an absorbing bottom, due to which the sound absorption band near the resonant frequency of the membrane oscillations on the air layer expands.

With respect to the air volumes located in the cavities separated by the lattices of the 3 caissons, as mutually simple numbers, the frequencies of resonant oscillations of the membranes do not coincide, which increases the acoustic efficiency of the wedge sound absorber.

Hard or semi-rigid sound-absorbing material 1 can be made with an internal cavity. This leads to an additional attenuation of sound at the resonant frequency determined by the size of cavity 6.

This wedge sound absorber allows you to expand the active absorption area and increase the coefficients

sound absorption, as well as with the same dimensions of sound, absorb and vary within certain limits the lower limit frequency of active sound absorption in the muffled chamber.

Claims (2)

1. A wedge sound absorber, comprising a frame with longitudinal and transverse elements, filled with sound-absorbing material and covered with an acoustically transparent material with the formation of cavities between them, bounded by transverse elements of the frame, characterized in that, in order to increase the sound absorption coefficient, the cavities are made at least with one longitudinal partition adjacent to the longitudinal frame member. 2. A sound absorber according to claim 1, of which there is, so that, in order to expand the areas of active sound absorption, the volumes of cavities separated by transverse elements of the framework, are related to each other as mutually simple numbers. Fig- 2 5 b z. L Editor N.Gorvat Compiled by A. Maslov Tehred M. Morgental five . TO Fig.Z Proofreader N.Korol