SU1703917A1 - Swivel gas duct - Google Patents

Abstract

The invention relates to power engineering, is designed to silence the noise of moving fluids of liquids and gases, in particular, in external ducts using tonnage equipment and can be used in the gas industry. The aim of the invention is to increase the effectiveness of sound attenuation without changing the hydraulic resistance and increase efficiency. The rotary gas duct contains inlet 1 and outlet 2 areas, lined with noise absorbing material 3, sound-reflecting screen 6, fixed by means of transverse vibration oscillations. When a gas stream hits, the high-number sound waves are silenced by the noise-absorbing material of the input section 1, the zero normal wave is reflected by the screen 6 to the input section 1, and a part of it is fed to the radius part of the output section 2 and reflected from the noise absorbing material. 1 l. f-ly, 5 ill. G /

Description

The invention relates to power engineering, is designed to silence the noise of moving streams of liquids and gases, in particular, in external ducts located behind TTP power supply equipment, and can be used in other industries, such as gas to silence gas pumping stations.

The purpose of the invention is to increase the efficiency of sound attenuation without changing the hydraulic resistance and increase efficiency.

Nafig 1 shows a rotary gas duct, a longitudinal section (an embodiment of the screen with a small radius of rounding of the outer edge); in fig. 2 is the same embodiment of the screen with a large turning radius: in FIG. 3 - the same, the embodiment of the screen for direct radial rotation of the flue; in fig. 4 — node I in FIG. 1, the option of mounting the screen to the wall of the duct by means of transverse vibration compensators; in fig. 5 shows a variant of the location of sound insulation opposite the exit duct while saving material.

The swivel flue duct contains inlet and outlet sections 1 and 2, lined from inside with noise absorbing material 3, angled to each other with the formation on the inner wall 4 of the outlet section 2 opposite the inlet section 1 of the duct of the acoustic reflection zone 5 of the zero sound wave 1 additionally provided with a sound reflecting screen 6 fixed on the inner wall 4 of the output section 2 on top of the noise absorbing material 3 in the acoustic reflection zone 5 of the zero sound wave in the input section approx 1 flue. Sound-reflecting screen 6 can be fixed on the inner wall 4 of the output section 2 of the duct through compensators 7 transverse vibrations.

Rotary flue works as follows.

The perturbed gas flow after the t-gas installation, for example, a smoke exhauster, enters the inlet section 1 of the flue. Since it is lined with noise absorbing material from the inside, the sound waves of high numbers are effectively damped at a distance of 3-5 calibers of the input section 1. However, low number waves and a zero normal wave make up a significant part of the sound power and practically do not dampen in near-wall zones. When a zero normal wave is incident on screen 6, it is reflected back into the input section 1 of the flue, not falling into the output section 2. In this case, screen 6 is a source of secondary directional sound radiation and a reliable obstacle to the propagation of a zero sound wave. A portion of the normal wave falls on the radius of the output portion 2 and is reflected from the sound-absorbing material covering the radius portion. But in this case

the sound wave is dissipated in the output section 2 and is suppressed by the sound-absorbing material 3 covering it. The installation of compensators 7 prevents the sound from escaping beyond the flue through the internal

wall 4, and also allows the screen to slide an audible normal zero wave.

The height H of the screen 6 can be calculated from the geometrical parameters

gas flue by equation

X. (PK) (+ gH / 7 G-1b

RV R2 R2)

 0,

where X is the height of the part of the reflecting screen on the rounding of the outer edge;

D is the transverse dimension of the flue at a rectangular section or hydraulic diameter for other forms of the section; R is the radius of the rounding of the outer edge of the flue.

The height of the screen Н D - R + X.

When performing R 0 there is no reflection of the sound wave in the input section

When performing R About - X - 0, and H About

there is a full reflection of the sound normal wave in the input section of the flue.

Thus, the condition for the possibility of installing a reflective screen is the condition R D, which does not contradict the possibility of obtaining satisfactory hydraulic characteristics with proper selection of rounding radii. Installing reflective screens does not increase the hydraulic resistance of the gas duct and improves the known gas ducts. Installing the screen in the rotary duct reduces the noise level produced by thermal power equipment by 12–15 dB, which gives an economic effect of about 170 thousand rubles. on one smoke exhauster.

To save sound-absorbing material, it is advisable to install the lining only on the inner wall of the inlet section of the duct opposite its outlet section. In this case, the sound insulation prevents direct reflection of the sound wave in the output duct without its repeated reflection from the wall of the rotary duct. This significantly reduces the noise level at the exit of the flue compared to the rotary flue that is not faced with noise absorbing material.

Claims (2)

Claim 1. Rotary gas duct containing inlet and outlet portions lined from inside with noise absorbing material, at an angle to each other, characterized in that, in order to increase 0 Nor is the sound suppression efficiency without changing the hydraulic resistance, it is additionally equipped with a sound reflecting screen fixed on the inner wall of the exit section above the noise absorbing material opposite the entrance section. 2. Flue duct according to claim 1, characterized in that the sound reflecting screen is fixed on the inner wall of the exit portion of the flue duct by means of lateral vibration compensators. L FIG. I figs 2 k .five