SU1143868A2 - Noise muffler - Google Patents

Abstract

1. NOISE SILENT on avt.Sv. 1064023, ra t and h and rant and so that, in order to increase the efficiency of noise reduction. the cylindrical housing and the vortex chamber are made with a single end wall, the tangential nozzles for supplying liquid and gas are located in the upper and lower parts of the vortex chamber respectively, and the vortex chamber is provided with a transverse diaphragm with a hole installed along the axis of the tangential gas inlet. 2. The silencer according to claim 1, wherein the center of the aperture of the transverse diaphragm is offset relative to the axis of the vortex chamber.

Description

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CO 00 Ot) CX) The invention relates to mechanical engineering, in particular engine building, namely to the muffler of the noise of an internal combustion engine. . According to the main auth. No. 1064P23 is a well-known exhaust silencer for an internal combustion engine, containing a vortex chamber with a tangential inlet pipe connected to the mixing chamber and an exhaust chamber installed around the mixing chamber and fitted with a tangential exhaust pipe, the mixing chamber is cylindrical in shape of the partition wall of the partition wall. material and is equipped with a cylindrical casing with a tangectic pipe for supplying liquid, is also coaxially with a gap relative to the mixing chamber, and the chamber OSCAL provided with guide baffle disposed coaxially with a gap relative to the cylindrical housing SP. . However, in the well-known silencer, there is a lack of efficiency in noise dampening due to incomplete use of the central part of the vortex and mixing chambers. The aim of the invention is to increase the efficiency of sound attenuation. . , This goal is achieved by the fact that in the silencing (exhaust gas noise of an internal combustion engine, which contains a vortex chamber with a tangential inlet pipe connected to the mixing chamber, an exhaust chamber located around the mixing chamber and provided with a tangential exhaust pipe, the mixing chamber is cylindrical wall of porous material and provided with a cylindrical casing with a tangential pipe for supplying liquid, is located coaxially and with a gap relative to the mixing The camera and the outlet chamber are equipped with a guide deflector located coaxially with a gap relative to the cylindrical housing, the latter and the vortex chamber are made with a single end wall, the tangential nozzles of the liquid supply 82 and gas are located in the upper and lower parts of the vortex chamber respectively and the vortex. The chamber is equipped with a transverse diaphragm with a hole installed along the axis of the tangential nozzle for supplying gas, Figure 1 shows a silencer, and a longitudinal section in Figure 2 shows section A-A in Figure 1. The silencer contains a vortex chamber 1 with a tangential inlet gas nozzle 2 connected to a mixing chamber 3 and an exhaust chamber 4 located around the mixing chamber 3 and equipped with a tangential outlet nozzle 5, the mixing chamber 3 is cylindrical in shape with a wall of porous material and is equipped with a cylindrical casing with a tangential pipe 7 supply, fluid, located coaxially and with. a gap relative to the mixing chamber 3, and the outlet chamber 4 is equipped with a guide deflector 8, made in the form of a single-cavity hyperboloid and aligned with the clearance relative to the cylindrical casing 6, the cylindrical housing and the vortex chamber 1 are filled with a single end wall 9, tangential nozzles for supplying liquid 7 and gas 2 are dispersed in the vortex and lower parts of the vortex chamber 1, respectively, the vortex chamber 1 is divided into two parts by a transverse diaphragm 10 with a hole 11 installed along the axis of the nozzle 2 for gas supply. The cylindrical housing with the outer surfaces of the vortex I and mixing 3 chambers form an annular liquid cavity 12, the nozzle 13 of the liquid outlet is located in the lower part of the exhaust chamber, and the section 14 of the toroidal shape to rotate the gas flow on the stabilizers 15. The exhaust silencer of the internal combustion engine works as follows. The flow of pulsating exhaust gases from the engine through a tangential inlet pipe 2, divided into two parts by a transverse diaphragm 10, enters the upper and lower parts of the vortex chamber 1. At the lower part of the vortex chamber 1, gas swirls, moving 3

Going down towards the mixing chamber 3, and in the upper part also whirling, moving, towards the dead end zone of the chamber,. When it reaches the dead end zone, the gas rotates along the central part of the vortex chamber 1 to the orifice 11 of the transverse diaphragm 10, while the pulsations are partially extinguished due to the friction against the chamber wall and the deceleration of the vortex in the impasse zone of the chamber. the formation of a wave tube obstructing the passage of sound below the cutoff frequency for this camera.

In addition to lowering the noise level and shaping the frequency characteristics of the silencer (increasing the length of the upper part of the vortex chamber 1 shifts the frequency of the first mechanism to low frequencies), an axial gaseous flow, which passes through the opening 11 of the diaphragm 10, is formed in the upper part of the chamber, causing the flow of gases to spin around the helical the lines along which the ring whirls rotate, which

- permits additional quenching of the pulsation structure of the gas flow due to its energy dissipation

A more intense twist of the ring vortices is observed when the center of the orifice 11 of the transverse diaphragm 10 is displaced relative to the axis of the vortex chamber 1. In this case, the friction between the central and rotating vortexs increases,

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and mass transfer effect between the liquid on the wall of the mixing chamber 3 and the volume of gas. The formation is intensified in a blender. 5 chamber 3 of the finely dispersed structure of a liquid that absorbs two waves due to diffraction effects on droplets.

Exit mixing chamber 3,

10, the gas is separated at the site 14 with its rotation into the deflector 8, and the liquid collects in the lower part of the gas injection chamber 4 and is discharged from the silencer through the nozzle 13. In injection into the deflector 8, the gas enters and leaves the exhaust gas 4. through the pipe 5 exhaust gases.

Liquid to mixing chamber

20 3 is supplied from the liquid cavity 12 through the porous walls of the mixing chamber 3. In the annular liquid cavity 12, the liquid enters through the nozzle 7, which is located

5 above the pipe 2 tangential gas supply. Changing the location of the nozzles allows you to create a liquid cooling jacket in the upper part of the vortex chamber 1.

Q into the annular liquid cavity 12 in the upper part of the vortex chamber 1, the liquid is heated to the point of boiling and then expanding. volume of mixing chamber through it

porous walls, the liquid boils with the formation in its thickness of vapor bubbles, which are an effective absorber of sound vibrations.

Thus, the implementation of the invention makes it possible to increase the efficiency of noise absorption.

Liquid

15

Liquid

Figure 1 ff. g

Claims (2)

1. NOISE MUFFLER No. 1064023, characterized in that, in order to increase the efficiency of sound absorption, the cylindrical casing and the vortex chamber are made with a single end wall, the tangential nozzles for supplying liquid and gas are located in the upper and lower parts of the vortex chamber, respectively, and the vortex chamber is equipped with a transverse diaphragm with an opening installed along the axis of the tangential gas supply pipe. 2. The muffler according to claim 1, characterized in that the center of the hole of the transverse diaphragm is offset relative to the axis of the vortex chamber. ’Ω np 1143868