RU205834U1 - Sound absorbing panel - Google Patents

Abstract

The utility model relates to devices for protection against sound waves and their capture, suppression and absorption, and can be used in buildings and structures to ensure normal acoustic conditions, in particular in measures for sound absorption in industrial premises, in protective screens for equipment that is noise sources, in roadside noise suppression screens, in suction and exhaust shafts of engine test benches, in gas pumping units, compressors Sound-absorbing panel containing a Helmholtz resonator and a layer of sound-absorbing material, lining of the working surface of the panel in the form of sound-permeable material and / or perforated sheet, panel is assembled into a single structure due to the presence of a carrier shell in the form of a housing, the Helmholtz resonator consists of a volumetric element and a cover or bottom, in which the resonator inlet openings are located, made in the form of hollow tubes, a layer of sound-absorbing material is located in front of the resonator Or, in the direction of sound vibrations entering the panel, between the sound-permeable lining and the resonator, the cavity tubes of the resonator are located in a layer of sound-absorbing material, and the height of the tubes is equal to the thickness of the layer of sound-absorbing material or greater than its thickness, the tubes are evenly distributed over the area of the sound-absorbing panels.

Description

The utility model relates to devices for protection against sound waves, their capturing, suppression and absorption, and can be used in buildings and structures, to ensure normal acoustic conditions, in particular in measures for sound absorption in industrial premises, in protective screens for equipment that is noise sources, in roadside noise suppression screens, in suction and exhaust shafts of engine test benches, in gas pumping units, compressors.

Known invention No. 2155252, the noise shield is mounted on the foundation and consists of a set of acoustic panels made in the form of parallelepipeds, the cavities of which are filled with sound-absorbing modules made of mineral wool and having perforations. Each panel is formed by two U-shaped sheets and is equipped in the upper and lower parts with vibration-damping clamps, the material for which can be polyethylene. The retainers are made in the form of covers with trough-shaped cross-sections. Along the perimeter of the upper part of the outer surface of each retainer, a tide is made, in the body of which a vertical groove is formed, into which the walls of the acoustic panel are inserted with an interference fit. The disadvantage of these panels is that they have a low sound absorption coefficient at low noise frequencies, which is typical for panels filled with mineral and glass wool, with their thicknesses of 100 mm or less.

Known invention No. 2266997, in which the noise-insulating and noise-absorbing acoustic sandwich panel is formed by the rear and front panels. A noise-absorbing block is placed between the panels. The acoustic sandwich panel is equipped with noise flow dividers made of a profile with a resonating cavity, which are located on the side of the front panel with inclined plates with visors mounted horizontally and parallel to each other to form slot traps. Acoustic sandwich panel provided with a flat unit formed by at least one layer of fibrous material having a basis weight in the range from 100 to 1500 g / m ^2, and a planar speaker diaphragm, at least one layer zvukopronitsaemogo material having areal density in the range from 25 to 200 g / m ² . The latter, together with dividers of the noise flow and inclined plates with peaks, are mounted in a volumetric module of at least two vertically oriented dividers of the noise flow, from a profile with a resonating cavity and a flat acoustic membrane and inclined plates with peaks fixed in series on them. The flat and volumetric modules are mounted in series on the outside of the front panel, and the noise-absorbing unit is fixed relative to the front and rear panels by means of glue and / or mechanically. The disadvantage of this invention is its structural complexity due to the multistage sequential passage of sound, first through a volumetric module consisting of inclined plates with visors that form slot traps, through acoustic membranes, through noise flow dividers made of a profile with a resonating cavity, through a flat module from a sound-permeable canvas and finally through a noise-absorbing sandwich panel with perforation and a rear wall, while resonators that are effective at low noise frequencies are not evenly located over the entire panel area, but only from the ends of the volume module, in the noise flow dividers, respectively, the main volume of sound low-frequency oscillations passes through the panel outside the resonator operation zone.

Known invention No. 2151839, a protective screen for roadside noise absorption is made with a flat mixing chamber of the active components of the high-frequency spectrum of the noise flow, formed between plates of materials with differentiated properties of noise absorption, communicated through transverse through holes with resonator cavities in hollow dividers installed along the inner contour of a rectangular frame. The front inclined plates are equipped with shortened shanks made with a reverse inclination, the edges directed to the adjacent inclined plates. The front inclined plates, the rectangular frame, the hollow spacer and the rear flat wall are made of glass-basalt plastic, the rear flat wall can be made, in another version, of foam aluminum or foam concrete. Slabs of materials with differentiated sound absorption properties can be made of glass or basalt fiber material, or foam aluminum, or foam concrete, or in combination with glass or basalt fibers reinforcing them. The disadvantage of this invention is a small percentage of sound absorption of low-frequency noise, due to the fact that low frequencies can be captured not by the entire area of the screen, but by a narrow strip of rod dividers, in the form of resonators, which are located only along the inner contour of the rectangular frame of the protective screen.

Known invention RU 2544349, a resonant noise absorber containing interconnected panel with technological holes, which are inserted replaceable bushings that serve as the neck of the resonator, and a box with stiffening ribs. The disadvantage of the device is the relatively low efficiency of noise damping due to the partial reflection of sound waves of medium and high frequencies from the sound absorber, as well as a relatively narrow (extremely low frequencies) range of sound absorption.

Known invention RU 2598236, in which the sound-absorbing structure is made in the form of two perforated walls, between which there is a multilayer sound-absorbing element, the multilayer sound-absorbing element is made two-layer, and the layer adjacent to one of the walls is made sound-absorbing, and the layer adjacent to the other perforated wall , is made of a sound-reflecting material of a complex profile, consisting of evenly distributed hollow tetrahedrons, which allow reflecting sound waves incident in all directions. The disadvantage of this design is that it does not well dampen noise at low frequencies.

Known sound-absorbing panel (invention No. 2649209), containing a perforated wall with resonance holes that perform the functions of the neck of the Helmholtz resonator, and sidewalls filled with soundproof material placed in a protective sound-permeable shell, and end caps of the channel profile, the sidewalls are made with longitudinal grooves in them for laying vibration damping material and shoulders for abutting and fixing a sound-insulating material with a protective sound-permeable shell on a perforated wall by enclosing its edges, and the shoulders are equipped with elements of a sound-absorbing panel hinge on the wall of the room, and the end covers contain projections and grooves of a spike connection with the possibility of their subsequent pairing with vibration damping material ... The disadvantage of this sound-absorbing panel in such a design solution is that if it is effective at low frequencies of sound absorption, like a Helmholtz resonator, then it will not be effective at medium and high frequencies, like a sound-absorbing panel made of sound-insulating materials, and vice versa, because subject to the conditions for the design of resonators, with standard ratios between their volume, the area of the throat openings and the height of the throat, with a widespread thickness of plates made of sound-absorbing material of 50, 100, 150 mm and the corresponding depth, a sound-absorbing panel, it will have a perforation percentage of less than 15- 20%, which is ineffective for a panel made of sound-absorbing material, designed for sound absorption of medium and high frequencies, in order to increase this percentage of perforation, it is necessary to reduce the volume, i.e. the thickness of the resonator, respectively, and the thickness of the layer of sound-absorbing material, less than 50 mm, which is also not effective for a sound-absorbing panel designed to absorb noise at medium and high frequencies, with the required sound absorption coefficient of at least 0.8, i.e. in the version of this panel, it will work effectively, either as a resonator at low and partly at medium frequencies and not work at high frequencies, with a wall perforation ratio of less than 20%, or as a sound-absorbing panel, operating due to the properties of sound-absorbing material, at medium and high frequencies and does not work at low frequencies, like a resonator, with wall perforation of about 20% or more, i.e. in both cases, the frequency range of this sound absorbing panel will be limited.

Known resonators with filling their internal volume with sound-absorbing fibrous material (Approved by the Order of the Scientific Research Institute of the State Construction of the USSR dated September 24, 1985 N 39-i. MANUAL FOR CALCULATING AND DESIGNING MULTILAYER SOUND-ABSORBING SYSTEMS (DESIGNS) II-K SNiP. Scientific and Technical Council of NIISF Gosstroy of the USSR, Appendix 4, pp. 24-30, Tables 1, 2). In this embodiment, the resonators not only have effective sound absorption coefficients of more than 0.8, at low frequencies, but also fragmentarily even at medium frequencies, but in the form of peak rather than stable linear values, which is typical for sound-absorbing panels, without the effect of resonance at medium and high frequencies. The lack of these structures, the lack of effective sound absorption in the entire range of medium and high frequencies.

The known design of a sound-absorbing plate (Designer Handbook. Protection against noise. Edited by E.Ya. Yudin. M. Stroyizdat, 1974, Table 8.4, No. 16, p. 129) using sound-absorbing material in the form of mineral wool, where the effective sound absorption coefficient at medium and high frequencies with a value of more than 0.8 and not the effective sound absorption coefficient at low frequencies.

The purpose of the utility model is to create a universal sound-absorbing panel, in which a unit of external area will have an effective sound absorption coefficient in a wide frequency range, i.e. both at low frequencies and at mid and high frequencies.

This problem is solved due to the fact that in one sound-absorbing panel, per unit of its area, both a resonator unit, providing sound absorption at low frequencies, and a layer of sound-absorbing materials, providing sound absorption at medium and high frequencies, are simultaneously present and evenly distributed on it.

The Helmholtz resonator unit and the layer of sound-absorbing materials are located in series, along the thickness of the structure of the sound-absorbing panel, in the direction of sound propagation. The resonator unit consists of a volumetric element of the Helmholtz resonator and its removable cover, in which the throat openings of the resonator in the form of cylindrical tubes of estimated length are located perpendicular to its plane.

On the surface of the resonator, in the direction of the noise effect on the panel, there is a block of sound-absorbing materials, occupying the area of the entire resonator and having the same overall dimensions, or part of its area. The sound-absorbing material occupies the space between the throat holes of the resonator, which pierce the array of the sound-absorbing materials block, this design allows to increase the durability of the sound-absorbing material, due to the additional obstacle to its vertical subsidence, shedding and caking, which is typical for fibrous, loose and crushed sound-absorbing materials, in the vertical version hanging sound-absorbing panels on walls. Also, this allows, in addition to plate fibrous materials with a density of more than 30-35 kg / m ³ , to use roll effective fibrous sound-absorbing materials with a lower density, for which horizontal cylindrical neck tubes will act as additional anchors, and for bulk materials they will be an obstacle to their caking with subsidence and compaction. Also, the surface of the boundary of the resonator block, with a block of sound-absorbing materials, can be made in the form of an additional element - a sound diffuser, the relief working surface of which can be made on the resonator cover, during the manufacture of this cover, or this diffuser can be formed in the form of separate plates with a relief surface, which are put on the resonator tubes, due to the existing holes in this plate. The sound diffuser is designed to reflect back the sound that has passed through the block of sound-absorbing materials, in the version of its more complete absorption. The resonator unit and the layer of sound-absorbing materials, with their lateral surfaces, are enclosed in a housing, on the front surface of which there is a panel lining in the form of a sound-permeable material, for example, in the form of fiberglass, also as a lining, in addition there may be a perforated sheet.

FIG. 1, 2 shows a noise-absorbing panel consisting of a Helmholtz resonator 1, which is assembled from two elements, from a single volumetric element of the resonator 3 and its cover 4, the cover 4 has a working surface on which the resonator inlet openings in the form of hollow tubes 5 of a certain height are located. The working surface of the cover 4 can have the configuration of the diffuser of the sound incident on it 6, due to stamping on this surface, in addition to the necks of the resonator, relief, with plane angles less than 180 ° to the plane perpendicular to the sound propagation front, this diffuser 6 can also be formed from a relief insert , put on the tube 5 of the resonator, due to the holes in it. FIG. 2 (section 1-1) shows the work of the panel for sound absorption of noise impact at low 10, medium and high frequencies 11. The entire area of the sound-absorbing panel participates in the absorption of low frequencies, due to the holes of the tubes 5 of the resonator 1, evenly spaced on the surface of the acoustic panel, between the tubes 5 of the entrance holes of the resonator, a layer of sound-absorbing material 2 is laid, for sound absorption of medium and high frequencies of sound impact 11, its thickness can be equal to the height of the tubes 5, and can also be less than a given height. The outer surface of the sound-absorbing panel is covered with a cladding in the form of a sound-permeable fabric, or a film 8, or a perforated metal sheet 9, or both.

Thus, a unit of the surface of a noise-absorbing panel will have an effective sound absorption coefficient over a wide frequency range, i.e. both at low frequencies and at mid and high frequencies.

The structures of the resonator unit, consisting of the volumetric element of the resonator 3 and its removable cover 4, can be made of metal, by stamping, pressing with drawing, or welding, can be made of concretes using mineral, polymer binders, by pouring them into forms, as well as from any other sheet materials, by cutting them and hermetically sealed into the structure of the resonator. The materials of the sound-absorbing layer should be porous in the form of acoustic foam rubber, bulk materials; fibrous in the form of mineral or glass wool, or polymer or natural fibers; both natural and artificial substances can be used as bulk materials.

A sound-absorbing panel consisting of a resonator unit 1, a layer of sound-absorbing materials 2, a lining of the working surface of the panel in the form of a sound-permeable material 8, a perforated sheet 9 is assembled into a single structure due to the presence of a supporting shell in the form of a housing 7.

This sound-absorbing panel can be used as part of sound absorption structures in industrial premises, in protective screens for equipment that are sources of noise, in roadside noise suppression screens, in suction and exhaust shafts of engine test benches, in gas pumping units, compressors.

FIG. 1 shows a view of a sound absorbing panel.

FIG. 2 is a cross-sectional view of a sound absorbing panel 1-1.

Claims (2)

1. Noise-absorbing panel containing a Helmholtz resonator and a layer of sound-absorbing material, facing the working surface of the panel in the form of a sound-permeable material, the panel is assembled into a single structure due to the presence of a supporting shell in the form of a body, the Helmholtz resonator consists of a volumetric element and a cover, the inlet openings of the resonator are made in in the form of hollow tubes, a layer of sound-absorbing material is located in front of the resonator, in the direction of sound vibrations entering the panel, between the sound-permeable lining and the resonator, characterized in that the hollow tubes of the resonator are in a layer of sound-absorbing material, and the height of the tubes is equal to the thickness of the layer of sound-absorbing material. 2. The panel according to claim 1, characterized in that the surface of the boundary of the resonator block with the block of sound-absorbing materials can be made in the form of an additional element - a sound diffuser.

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