SU1687821A1 - Nozzle - Google Patents

Abstract

The invention makes it possible to simplify the design and increase the efficiency of sound attenuation. The gas flow, passing through the exhaust system, through the inlet pipe 2, enters the housing 1, where, due to the deformation of the sound absorber 3 and the mesh of the housing 1, the hysteresis and the friction slip friction, the sound pressure is absorbed, which ensures effective noise reduction. During operation, the nozzle due to the spherical support 4 has a rolling movement, which additionally increases the dissipation of the energy of the flow and its volume dissipation into the surrounding space. It promotes sound absorption efficiency and the mutual arrangement of chips in the layers due to the difference in the scattering coefficients of the vibrational energy. Colored chips reduce contact friction and reduce deformability and wrinkling of chips in ferrous layers. Contacting black and color chips further increases the damping rate of 6 hp. -l, 2 il. yo

Description

The invention relates to mechanical engineering, in particular to engine-building, namely to noise-insulating and filtering nozzles of a predominantly exhaust system of an internal combustion engine.

The aim of the invention is to simplify the construction and increase the efficiency of sound attenuation.

FIG. 1 shows a nozzle with an exhaust silencer assembly, general view; figure 2 - node I in Fig 1 (longitudinal section of the nozzle).

The nozzle includes a housing 1 with an inlet pipe 2 and a sound absorber 3. placed in the housing 1 and made in the form

drain chips from metal-cutting wastes, with compressed and heat-treated packages used in the form of chips of ferrous and non-ferrous metals used as drain chips, and the layers of drain chips in bags are arranged respectively perpendicularly, at an angle to one another and in a spiral. from the grid, the inlet 2 from the end part is provided with a spherical support 4. and the sound absorber 3 has a cavity adjoining to the spherical support 4 a pipe 2 with the possibility of swinging-rotary motion.

The housing 1 can be made in the form of a cylinder and mounted on the inlet pipe

with

XI 00

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Yc. 2 with external clamp 5. Spring steel in the form of an average bind can be used as ferrous metal chips, and brass chips in the form of a small bind can be used as non-ferrous metal chips. The ratio of width to chip thickness may be 3 -1. and the ratio of the scattering coefficients of the vibrational energy in the chip layers can be mind: 7/2: no. -0.8: 0.9: 1, where 1 / M is the scattering coefficient for the perpendicular arrangement of the layers;

) / s is the scattering coefficient when the layers are arranged at an angle;

7/3 the scattering coefficient when the layers are arranged in a spiral.

The average density of the absorbent 3 may be 3-4 g / mm with a ratio of diameter and height of the packages of chips exceeding 0.5 0.7.

Nozzles can be installed on the exhaust pipe b exhaust system, including the muffler 7 and its inlet 8.

Nozzles works as follows. The gas flow, passing through the inlet 8, the silencer 7 and the exhaust pipe 6 of the exhaust system, through the inlet pipe 2, which is integral with the pipe 6, enters the body 1 of the nozzle, In the cavity of the body I due to the deformation of the sound absorber chip 3 and the grid of the body 1. hysteresis and friction friction consumes sound pressure energy, which provides effective noise reduction. During operation, the nozzle due to the spherical support A has a swinging-rotational movement, which additionally increases the dissipation of the energy of the flow and its volume dissipation into the surrounding space. It contributes to the effectiveness of sandblasting and the mutual positioning of chips in the layers due to the difference in the scattering coefficients of the vibrational energy. The colored chips help reduce contact friction and reduce the deformation and wrinkling of the chips in ferrous layers. Contacting black and color chips in layers of compressed color chips further increases the damping by about 10%. and the presence of lubricant on the contact areas of the chips contributes to the emergence of the ascending effect and, accordingly, an increase in the damping.

Claims (7)

1. An overhead, preferably an exhaust system for an internal combustion engine, comprising a housing with an inlet manifold and a sound absorber placed in the housing and made in the form of drain chips from metal-cutting treatment, and pressed and thermally treated packages are used as the drain chips There are 5 layers of ferrous and non-ferrous metal chips, and the layers of drainage chips in packages are arranged perpendicularly, at an angle to one another and in a spiral, so that they are, so that, in order to simplify 0 design and efficiency, sound attenuation. the body is made of a grid, the inlet pipe in the end part is provided with a spherical support, and the sound absorber is provided with a cavity adjoining 5 spherical support pipe with the possibility of swinging rotational motion. 2. An assembly according to claim 1, characterized in that the body is designed as a cylinder. 3. Nozzle according to claims 1 and 2, characterized by the fact that the housing is fixed on the inlet pipe with an external clamp. 4. Nozzle on the PP.1 -3, about tl and h and y y and y with. that spring steel was used as ferrous metal chips. 5 kind of middle loach. 5. Nozzle popp.1-4. Distinguishing - with the fact that brass chips in the form of fine loach are used as non-ferrous metal chips. 06. Nozzles for PP.1-5, about tl and h a y i and because the ratio of the width to the chip thickness is 3-7. 7. Nozzles on PP. 1 6. characterized by the fact that the ratio of the coefficients of the distribution of the oscillation energy in the layers of the chip is / h: 1/5: V 0.8: 0.9: 1 where / 1 is the dissipation coefficient at the perpendicular arrangement layers; t / 5 - scattering coefficient when the layers are at an angle; 1/3 is the scattering coefficient when the layers are arranged in a spiral. / Fig. / If Fig. /