RU2652852C2 - Industrial vacuum cleaner noise combined silencer - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to noise suppression. Silencer contains a body consisting of a cylindrical shell rigidly connected to end round plates having, respectively, inlet and outlet branch pipes, in the body, perpendicular to the aerodynamic flow movement direction, at least three reactive chambers formed by circular disks with holes are located, wherein the openings in the discs are alternately displaced relative to the body axis in such a way, that the openings in two adjacent discs do not coincide, at that, the three successively connected reactive chambers are connected to the housing inlet branch pipe, as well as to the combined chamber and the outlet branch pipe, and the combined chamber is formed by the annular perforated disk and end circular plate, which are interconnected by means of a central bushing, which inner surface is lined with sound absorbing material and coaxial to the cylindrical shell, wherein one of discs facing the inlet branch pipe is lined with a sound-absorbing round element, while the sound-absorbing round elements are also installed on discs with holes forming the jet chambers. Coaxially to the cylindrical body, in the chambers, sound-absorbing ring elements are installed, each of which is made in the form of a rigid and perforated walls, between which two layers are located: sound-reflecting layer adjoining rigid wall, and sound-absorbing layer, which adjoins the perforated wall, wherein sound reflecting material layer is made from complex profile composed of evenly distributed hollow tetrahedrons, allowing to reflect sound waves incident in all directions.

EFFECT: technical result is increased efficiency of noise suppression.

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Description

The invention relates to a technique for damping noise.

The closest technical solution to the technical nature is a multi-chamber silencer according to the patent of the Russian Federation No. 2305779, F01N 1/00, (prototype), comprising a cylindrical body, an end exhaust pipe, rigidly connected to a central pipe having perforation, the perforated partitions are made in the form of coaxially located to the casing and the central pipe of the additional perforated pipe, and the ends of all pipes are rigidly connected to the casing by means of blind partitions.

The disadvantage of the prototype is the relatively low efficiency of sound attenuation due to the possibility of the occurrence of a "radiation effect" and, as a result, the penetration of sound waves both along the axis of the muffler and through its two walls.

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

This is achieved by the fact that in the combined silencer of an industrial vacuum cleaner containing a housing consisting of a cylindrical shell rigidly connected to the end circular plates, respectively, with inlet and outlet nozzles, at least three are placed in the housing perpendicular to the direction of the aerodynamic flow reactive chambers 6, 7, 8, formed by circular disks with holes, and the holes in the disks are alternately offset relative to the axis of the housing so that the holes in two adjacent disks are not the three reactive chambers are connected in series with the inlet nozzle of the housing, as well as with the combined chamber and the outlet nozzle, and the combined chamber is formed by an annular perforated disk and an end round plate, which are interconnected by a central sleeve, the inner surface of which is lined sound-absorbing material and coaxial to the cylindrical shell, while one of the disks facing the inlet pipe is lined with a sound-absorbing round e with a sound absorber, round sound absorbing elements are also mounted on disks with holes forming reactive chambers, and the ratio of the housing length L ₁ to its diameter D lies in the optimal range of values: L ₁ / D = 3.5 ... 4.0; and the ratio of the diameter of the housing D to the diameter D _{1 of the} exhaust pipe lies in the optimal range of values: D / D ₁ = 4.5 ... 5.5; and the ratio of the diameter of the casing D to the diameter d of the hole of the disks lies in the optimal range of values: D / d = 5.0 ... 6.0, and the ratio of the diameter of the casing D to the length of the chamber L _K lies in the optimal range of values: D / L _K = 2 , 0 ... 4.5, while the case is made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material deposited on its surface on one or two sides, and the ratio between the thickness lining and vibration damping coating lies in the optimal range of values - 1: (2.5 ... 3.5).

In FIG. 1 shows a frontal section of the proposed silencer, FIG. 2 - sound-absorbing ring elements mounted coaxially to the cylindrical body 1, in the chambers 4 (axial section), in FIG. 3 - sound-absorbing round elements (axial section) mounted on disks 2 with holes 3 forming chamber 4.

Combined silencer industrial vacuum cleaner (Fig. 1) contains a housing consisting of a cylindrical shell 1, rigidly connected to the end circular plates 2 and 3, respectively, with inlet 4 and outlet 5 pipes. At least three reaction chambers 6, 7, 8 are formed in the casing, perpendicular to the direction of movement of the aerodynamic flow, formed by circular disks with openings, the openings in the disks being alternately offset relative to the axis of the casing so that the openings in the two adjacent disks do not coincide . At the same time, three reactive chambers 6, 7, 8 connected in series to the inlet 4 of the housing, as well as to the combined chamber 9, and the outlet 5 of the nozzle.

The combined chamber 9 is formed by an annular perforated disk 13 and an end round plate 2, which are interconnected by a central sleeve 10, the inner surface of which is lined with sound-absorbing material 12 and is aligned with the cylindrical shell 1, while one of the disks 13, facing the inlet 4 of the pipe, lined with a sound-absorbing round element 11 (axial section in Fig. 3), and the sound-absorbing round elements 11 are also installed on disks with holes that form the reaction chamber 6, 7, 8 ( not shown in the drawing).

The ratio of the length of the housing L ₁ to its diameter D lies in the optimal range of values: L ₁ / D = 3.5 ... 4.0; and the ratio of the diameter of the housing D to the diameter D _{1 of the} exhaust pipe lies in the optimal range of values: D / D ₁ = 4.5 ... 5.5; and the ratio of the diameter of the casing D to the diameter d of the hole of the disks lies in the optimal range of values: D / d = 5.0 ... 6.0, and the ratio of the diameter of the casing D to the length of the chamber L _K lies in the optimal range of values: D / L _K = 2 , 0 ... 4.5.

The case is made of structural materials with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material applied on one or two sides of the surface, and the ratio between the thickness of the lining and the vibration-damping coating lies in the optimal range of values - 1: (2.5 ... 3.5).

Each of the sound-absorbing ring elements (Fig. 2) is made in the form of a rigid 14 and perforated 17 walls, between which two layers are located: a sound-reflecting layer 15 adjacent to the rigid wall 14, and a sound-absorbing layer 16 adjacent to the perforated wall 17. The layer sound-reflecting material is made of a complex profile, consisting of uniformly distributed hollow tetrahedrons, which allow reflecting sound waves incident in all directions, and the perforated wall has the following perforation parameters: diameter from versts - 3 ÷ 7 mm, perforation percentage 10% ÷ 15%, and according to the shape of the hole can be made in the form of holes of a round, triangular, square, rectangular or diamond-shaped profile, while in the case of non-circular holes, the maximum diameter should be considered as a conditional diameter circle inscribed in a polygon. As the sound-absorbing material of layer 10, 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.

On the disks, from the inlet side of the 4 pipe, sound-absorbing round elements are placed (Fig. 3), overlapping the openings connecting the reaction chambers.

Each of the sound-absorbing round elements 14 (Fig. 3) is made in the form of a sound-absorbing element in the form of an external 18 and an internal 19 perforated surfaces, between which is placed a sound absorber consisting of three layers of sound-absorbing material, while the first layer 20, more rigid, is made continuous and profiled and fixed on the outer surface 18, the second layer 21, softer than the first, is intermittent and located in the focus of the sound-reflecting surfaces of the first layer 20.

The intermittent sound-absorbing layer 21 located at the focus of the continuous profiled layer 20 is made in the form of bodies of revolution, for example, in the form of balls, ellipsoids of revolution and is fastened with rods 23 (a section with one rod 23 is shown in the drawing) parallel to the perforated surfaces 18 and 19, which rigidly interconnected by means of vertical fastening elements perpendicular to them, for example, in the form of plates 14, one end of which is rigidly fixed to the outer surface 18, and the second is made in the form of a clamp 24, covering rod of 23 and tightening the screw (not shown).

The continuous profiled layer 19 of the sound-absorbing element is made of a more rigid sound-absorbing material, in which the reflection coefficient of sound is greater than the sound-absorption coefficient, and the profiles 22 are formed by spherical surfaces interconnected so that in general each of the profiles 22 forms a solid dome-shaped profile focusing reflected sound on the same soft intermittent sound-absorbing layer 23.

The third layer 25 of the sound-absorbing element is made of foamed sound-absorbing material, for example, construction sealing foam, which increases the sound-insulating properties of the structure as a whole by filling the voids formed by layers 18 and 19, and also increases the reliability of the structure as a whole when installed on equipment operating in conditions with increased shock and vibration loads. The third layer 25 is located between the first, more rigid layer, and the perforated surface 19 of the sound-absorbing element.

As a sound-absorbing material of the first, more rigid layer 20, a material based on aluminum-containing alloys was used, 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 5 ... 10 MPa, bending strength in the range of 10 ... 20 MPa, for example foam aluminum.

As a sound-absorbing material of the second, softer layer, 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, for example, can be used. polyethylene or polypropylene.

The material of the perforated surfaces 18 and 19 can be made of solid, decorative vibration-damping materials, for example, plastic compounds such as Agate, Anti-Vibrate, Shvim, and the inner surface of the perforated surface 23 facing the sound-absorbing structure is lined with an acoustically transparent material, for example fiberglass type EZ-100 or polymer type "Poviden."

Each of the sound-absorbing round elements 25 (Fig. 3) works as follows.

Sound energy, passing through the layer of the outer perforated surface 12 and the third layer 16 of the sound-absorbing element made of foamed sound-absorbing material, falls on the intermittent sound-absorbing layer located at the focus of the continuous profiled layer 15, where the primary dissipation of sound energy occurs. Then sound energy enters the continuous profiled layer 15 of sound-absorbing material.

Combined silencer works as follows.

Sound waves, together with a turbulent stream of compressed air, enter the body cavity and encounter disks with openings forming reactive chambers 6, 7, 8 on their way, while the phenomenon of "radiation effect" is completely eliminated due to the fact that the openings of the disks are alternately offset relative to the axis cases so that the holes in the two adjacent disks do not match. Chamber cavities formed by disks serve as a low-frequency acoustic filter.

Claims (2)

1. The combined noise suppressor of an industrial vacuum cleaner, comprising a housing consisting of a cylindrical shell rigidly connected to end circular plates, respectively, with inlet and outlet nozzles, at least three reaction chambers are placed perpendicular to the direction of the aerodynamic flow, 6 7, 8, formed by circular disks with holes, and the holes in the disks are alternately offset relative to the axis of the housing so that the holes in the two adjacent disks do not coincide, while three, sequentially connected, reaction chambers are connected to the inlet pipe of the housing, as well as to the combined chamber and the outlet pipe, the combined chamber is formed by an annular perforated disk and an end round plate, which are interconnected by a central sleeve, the inner surface of which is lined with sound-absorbing material and is aligned with the cylindrical shell, while one of the disks facing the inlet pipe is lined with a sound-absorbing round element, while absorbing round elements are also mounted on disks with holes forming reactive chambers, and the ratio of the housing length L ₁ to its diameter D lies in the optimal range of values: L ₁ / D = 3.5 ... 4.0; and the ratio of the diameter of the housing D to the diameter D _{1 of the} exhaust pipe lies in the optimal range of values: D / D ₁ = 4.5 ... 5.5; and the ratio of the diameter of the casing D to the diameter d of the hole of the disks lies in the optimal range of values: D / d = 5.0 ... 6.0, and the ratio of the diameter of the casing D to the length of the chamber L _K lies in the optimal range of values: D / L _K = 2 , 0 ... 4.5, while the case is made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material deposited on its surface on one or two sides, and the ratio between the thickness facing and vibration damping coating lies in the optimal range of values - 1: (2.5 ... 3.5), excellent characterized in that, coaxially to the cylindrical body, in the chambers, sound-absorbing ring elements are installed, each of which is made in the form of a rigid and perforated wall, between which two layers are located: a sound-reflecting layer adjacent to the rigid wall, and a sound-absorbing layer adjacent to the perforated wall, the layer of sound-reflecting material is made of a complex profile, consisting of uniformly distributed hollow tetrahedrons, which allow reflecting sound waves incident in all directions. 2. The combined noise suppressor of an industrial vacuum cleaner according to claim 1, characterized in that on the disks with openings forming the chambers, from the side of the inlet pipe, sound-absorbing elements are placed that overlap the openings connecting the chambers, each of which, in axial section, is made in the form external and internal perforated walls, between which layers of sound-absorbing material are placed, while the stiffer first layer is solid, profiled and fixed to the external perforated wall, the second layer is softer than the first one, it is made intermittent, located at the focus of the sound-reflecting surfaces of the first layer and has the shape of bodies of revolution in the form of balls and ellipsoids of revolution, while the first layer is made of material with a sound reflection coefficient greater than its sound absorption coefficient in the form of profiles of spherical surfaces interconnected to form a solid dome-shaped profile focusing the reflected sound onto a second layer, the second layer being fixed with rods parallel to the perforated walls and containing there is a third sound-absorbing layer made of foamed sound-absorbing material in the form of building sealing foam and located in the voids formed between the first and second layer, while the outer perforated wall is rigidly connected to the second layer by means of vertical fastening elements in the form of plates perpendicular to it, one end which are rigidly fixed to the external perforated wall, and the second end is made in the form of a clamp covering the rod and the screw tightening it.

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