RU2599669C1 - Tubular rectangular silencer - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: silencer is intended for silencing car or engine exhausts. Silencer comprises a housing of rectangular section, rigidly connected with end inlet and outlet pipes, sound absorber located between housing and perforated element, and an acoustically transparent material, placed between perforated element and sound absorber, and sound absorber is made of mineral wool on basalt base of “Rockwool” type, or “URSA” mineral wool, basalt wool P-75, or glass wool with glass felt.

EFFECT: higher efficiency of noise suppression.

1 cl, 3 dwg

Description

The invention relates to a technique for damping noise.

The closest solution in technical essence is a silencer according to RF Patent No. 2306431, F01N 1/00, containing a cylindrical body, inlet and outlet pipes and a sound absorber (prototype).

Its disadvantage is the relatively low efficiency of sound attenuation.

The technical result is an increase in the efficiency of sound attenuation.

This is achieved by the fact that in a tubular rectangular silencer containing a rectangular housing, rigidly connected to the end inlet and outlet pipes, a sound absorber located between the body and the perforated element, and an acoustically transparent material located between the perforated element and the sound absorber, the ratio of the lengths of the sides of the rectangular the external cross section of the muffler housing B / H lies in the optimal range of values: B / H = 1.0 ... 1.5; and the ratio of the lengths of the sides of the rectangular internal section of the silencer body B / H lies in the optimal range of values: b / h = 1.0 ... 2.0; and the ratio of the difference in the lengths of the sides of the rectangular external and internal sections of the silencer body to its length lies in the optimal range of values: (B-H) / L = (b-h) / L = 0.2 ... 0.42; and the ratio of the lengths l of the pipes to the length L of the silencer lies in the optimal range of values: l / L = 0.051 ... 0.104; and the ratio of the lengths of the sides of the axial marking of the mounting holes on the flanges of the nozzles lies in the optimal range of values: d / t = 0.5 ... 1.5; and the ratio of the free cross-sectional area F to the length of the silencer L lies in the optimal range of values: F / L = 0.02 ... 0.34; and the sound absorber is made of rockwool basalt mineral wool or URSA mineral wool or P-75 basalt wool or glass wool lined with glass wool or foamed polymer, such as polyethylene or polypropylene, the sound absorbing element throughout it is lined with an acoustically transparent material, for example, fiberglass type EZ-100 or polymer type "Poviden."

In FIG. 1 shows a frontal section of the proposed silencer, FIG. 2 is a profile projection, in FIG. 3 - embodiment of the sound absorber 2.

A rectangular tubular silencer comprises a rectangular housing 3 rigidly connected to the end inlet 4 and exhaust 5 nozzles, a sound absorber 2 located between the housing and the perforated element 1, and an acoustically transparent material 6 located between the perforated element 1 and the sound absorber 2. In this case: the ratio of the side lengths of the rectangular external section of the silencer housing B / H lies in the optimal range of values: B / H = 1.0 ... 1.5; and the ratio of the lengths of the sides of the rectangular internal section of the silencer body B / H lies in the optimal range of values: b / h = 1.0 ... 2.0; the ratio of the difference in the lengths of the sides of the rectangular external and internal sections of the silencer body to its length lies in the optimal range of values: (B-H) / L = (b-h) / L = 0.2 ... 0.42; the ratio of the lengths l of the pipes to the length L of the silencer lies in the optimal range of values: l / L = 0.051 ... 0.104; the ratio of the lengths of the sides of the axial marking of the mounting holes on the flanges of the nozzles lies in the optimal range of values: d / t = 0.5 ... 1.5; the ratio of the free cross-sectional area F to the length of the silencer L lies in the optimal range of values: F / L = 0.02 ... 0.34.

The casing 3 and the nozzles 4 and 5 are made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material applied on their surface from one or two sides, and the ratio between the thicknesses of the material and vibration-damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5).

Sound absorber 2 is made of rockwool basalt mineral wool or URSA mineral wool or P-75 basalt wool or glass wool lined with glass wool or foamed polymer, such as polyethylene or polypropylene, the sound absorbing element throughout it is lined with an acoustically transparent material, for example, fiberglass type EZ-100 or polymer type "Poviden."

Sound absorber 2 is made on the basis of aluminum-containing alloys, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range of 5 ... 10 MPa, bending strength in the range 10 ... 20 MPa.

Sound absorber 2 is made of a rigid porous sound-absorbing material, for example, foam aluminum or cermets, or metal foam, or a shell rock with a degree of porosity in the range of optimal values: 30 ... 45%. The sound absorber is made in the form of crumbs from solid vibration-damping materials, for example, elastomer, polyurethane, or plastic compound of the type “Agat”, “Anti-vibration”, “Shvim”, and the size of the fractions of the crumb lies in the optimal range of values: 0.3 ... 2.5 mm.

A tubular rectangular silencer operates as follows.

Sound waves, together with a turbulent stream of compressed air, enter the silencer cavity and interact with sound absorber 2. The design of the noise silencer is simple to manufacture and maintain. The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of the sound absorber, which are the Helmholtz resonator model, where energy losses occur due to friction of the mass of air in the resonator neck oscillating with the excitation frequency against the wall of the neck itself, which has the form branched pore network of the sound absorber 2. The perforation coefficient of the perforated element 1 is taken to be equal to or more than 0.25. To prevent the eruption of the soft sound absorber, an acoustically transparent material 6 is provided, for example, fiberglass type EZ-100, located between the sound absorber 2 and the perforated element 1.

A possible embodiment of the sound absorber 2 in the form of a sound-absorbing element of rectangular cross section (Fig. 3), the walls of which are made in the form of a rigid 5 and perforated 8 walls, between which there are two layers: a sound-reflecting layer 6 adjacent to the hard wall 5, and a sound-absorbing layer 7, adjacent to the perforated wall 8. The layer of sound-reflecting material is made of a complex profile, consisting of uniformly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, and the perforated wall has the following perforation parameters: the diameter of the holes is 3 ÷ 7 mm, the percentage of perforation is 10% ÷ 15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or rhomboid profile, while in the case of non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon. As sound-absorbing material of layer 7, rockwool-type mineral wool or URSA-type mineral wool, or P-75-type basalt wool or glass wool lined with glass wool, or foamed polymer, such as polyethylene or polypropylene can be used. The surface of the fibrous absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T) or coated with breathable fabrics or non-woven materials, such as Lutrasil.

As the sound-absorbing material, a porous sound-absorbing material can be used, for example, foam aluminum or cermets or a shell rock with a porosity degree in the range of optimal values: 30–45%, or metal foam, or a material in the form of pressed chips from solid vibration-damping materials, for example, elastomer , polyurethane, or plastic compound such as "Agate", "Anti-Vibrate", "Shvim", moreover, the size of the fractions of the crumbs lies in the optimal range of values: 0.3 ... 2.5 mm, and poros can also be used mineral piece materials, such as pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers, while the surface of the fibrous absorbers is treated with special porous paints that allow air to pass through, for example, Acutex T or coated with breathable fabrics or non-woven materials, for example Lutrasil.

The perforated wall 8 can be made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic, or “Gerlen-D” type material deposited on one or two sides of the surface, and the ratio between the thicknesses of the material and the vibration-damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5).

The perforated wall 8 can be made of solid, decorative vibration-damping materials, for example, Agate, Anti-Vibrate, Shvim plastic compounds, the inner surface of the perforated surface facing the sound-absorbing structure, lined with an acoustically transparent material, such as fiberglass type EZ- 100 or with a “see-through” polymer, or with non-woven materials, for example, “lutrasil”.

Sound-absorbing element (Fig. 3) works as follows.

Sound energy from equipment located in the room, or other object emitting intense noise, passing through the perforated wall 8 enters the layer 7 of soft sound-absorbing material, where it is absorbed, and then to layer 6 of the sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, again directing them to sound-absorbing material for secondary absorption and dissipation of sound energy. In fibrous absorbers, the dissipation of the energy of air vibrations and its transformation into heat occurs at several physical levels. Firstly, due to the viscosity of the air, and there is a lot of it in the interfiber space, the oscillation of air particles inside the absorber leads to friction. The transition of sound energy into heat (dissipation, energy dissipation) occurs in the pores of a sound absorber, which are a model of Helmholtz resonators.

Claims (1)

1. A tubular rectangular silencer comprising a rectangular housing rigidly connected to an inlet and outlet end pipe, a sound absorber located between the body and the perforated element, and an acoustically transparent material located between the perforated element and the sound absorber, the ratio of the side lengths of the rectangular external section of the silencer body V / N lies in the optimal range of values: V / N = 1.0 ... 1.5; and the ratio of the lengths of the sides of the rectangular internal section of the silencer body B / H lies in the optimal range of values: b / h = 1.0 ... 2.0; and the ratio of the difference in the lengths of the sides of the rectangular external and internal sections of the silencer body to its length lies in the optimal range of values: (B-H) / L = (b-h) / L = 0.2 ... 0.42; and the ratio of the lengths l of the pipes to the length L of the silencer lies in the optimal range of values: l / L = 0.051 ... 0.104; and the ratio of the lengths of the sides of the axial marking of the mounting holes on the flanges of the nozzles lies in the optimal range of values: d / t = 0.5 ... 1.5; and the ratio of the free cross-sectional area F to the length of the silencer L lies in the optimal range of values: F / L = 0.02 ... 0.34, characterized in that the sound absorber is made in the form of a sound-absorbing element of rectangular cross section, the walls of which are made in the form of rigid and perforated walls between which there are two layers: a sound-reflecting layer adjacent to the rigid wall, and a sound-absorbing layer adjacent to the perforated wall, while the layer of sound-reflecting material is made of a complex profile, consisting of evenly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, and the perforated wall has the following perforation parameters: hole diameter - 3 ÷ 7 mm, perforation percentage 10% ÷ 15%, and the shape of the holes can be made in the form of round, triangular holes , square, rectangular or rhomboid profile, while in the case of non-circular holes, the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon, and as sound-absorbing material, Rockwool-type basalt mineral wool, or URSA-type mineral wool, or P-75 basalt wool, or glass wool with glass-wool lining is named.

Images