RU207372U1 - Sound absorbing sandwich panel - Google Patents

Abstract

The utility model relates to devices for noise protection and can be used in buildings and structures to ensure the standard acoustic regime, in particular in measures for sound absorption in industrial and residential premises, in protective screens for equipment that are sources of noise, in roadside noise screens and The sound-absorbing sandwich panel consists of two sheet external facings, one of which is solid, soundproof, and the other is perforated in the form of holes for sound waves to pass through them into the panel. Inside the panel there is an array of sound-absorbing material in the form of mineral wool lamellas fixed by gluing to the cladding, the direction of the fibers in which is perpendicular to the planes of the outer cladding. ... The lamellas are cut from standard mineral wool slabs and have an inclination of the edge surfaces to the perforated facing of the sandwich panel in the range from 0 ° to 65 °, i.e. can have edges from parallel arrangement with respect to the perforated lining to different from parallel in their various combinations for the entire array of sound-absorbing material. Due to the difference in the height of the lamellas that make up the array of sound-absorbing material of the sandwich panel, only the edges of the lamellas of greater height protruding to the same height from the array of sound-absorbing material are glued to the perforated, sound-permeable, flat facing of the sandwich panel. And lamellas of lower height remain glued with only one edge to the non-perforated cladding. The purpose of the utility model is to reduce the amount of sound waves reflected from the surface of a sound-absorbing sandwich panel made of non-combustible, piece, standard, mineral wool, plate, sound-absorbing materials, and thereby increase the sound absorption coefficient panels.

Description

The utility model relates to devices for noise protection and can be used in buildings and structures to ensure the standard acoustic regime, in particular in measures for sound absorption in industrial and residential premises, in protective screens for equipment that are sources of noise, in roadside noise screens and other sound-absorbing structures.

Known acoustic diffuser HolzAkustika Diffuser 700-2200 Hz (https://market.yandex.ru/search?text=acoustic%20diffuser%20holzakustika%20diffuser%20700-2200%20hz&1r=43&clid=545), this diffuser allows you to change the acoustic properties of the structure ... This is achieved by the presence of special removable cassettes installed in a frame. The cassettes differ in their functional purpose: absorbers (absorbers) and diffusers (diffusers). The presence of cassettes is due to the ability to balance sound dispersion in all directions over a wide range. If it is necessary to make the sound more dull, absorbers are used, and if a drier sound is needed, then diffusers. This product has as the main function, not the maximum increase in sound absorption, but the function of uniform dispersion of sound, the structure may have sound-absorbing elements as an auxiliary, not the main function, while the maximum increase in the sound absorption coefficient of these elements does not occur due to the fact that, as at least, the protruding side surfaces of the frame, which determine the structural strength of the diffuser, are made of solid dense sound-reflecting material, and therefore the sound reflected from it returns to the room practically without attenuation. Also, as a rule, diffusers are made using combustible materials such as wood or polymers. In addition, the mineral wool cassette itself, installed in the frame, does not fulfill the function of creating the structural strength of the product. 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 noise flow dividers and inclined plates with peaks, are mounted in a volumetric module of at least two vertically oriented noise flow dividers, and a flat acoustic membrane and inclined plates with peaks sequentially fixed 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 or mechanically. The disadvantage of this design is the large metal consumption and laboriousness of manufacturing the guiding visors of the sound flow and the entire structure of the sound-absorbing panel as a whole, as well as a high level of sound pressure from the front side of the acoustic sandwich panel in view of the large percentage of sound reflected from the visors of the panel, outside the sandwich panel , accordingly, the sandwich panel has a reduced sound absorption coefficient.

Of the existing effective methods for reducing the fraction of reflected sound from a sound-absorbing structure, one of the most effective methods for forming a free field is the use of sound-absorbing material in the form of wedges, or pyramids.

The wedge-shaped geometry provides a gradual change in the acoustic impedance of the transmission medium, allowing sound waves to be absorbed by the material, but not reflected on the surface, over a wide range of sound frequencies.

The absorption efficiency depends on the geometry and properties of the materials used.

The disadvantage of acoustic wedges and pyramids is that, in the material for a wide range of applications, with a relatively low price, they are usually produced from combustible materials, which is often unacceptable for sound-absorbing structures. For example, the EchoKor acoustic wedges have a fire hazard class of KM1 material, i.e. they are not non-flammable (https://echocor.ru/klinya-dlya-bezekhovykh-kamer/).

And in the variant of non-combustible, mineral materials, as a rule, these are not technologically advanced, small-scale products, which are very labor-intensive to manufacture and cost, because are made of filling or stuffed materials that require the manufacture of a frame and cladding, or tension structures that have a spatial shape other than a flat shape, which increases the cost and complicates their production (ACOUSTIC JOURNAL. 2015. vol. 61. No. 5. p. 636-644 , PHYSICAL BASIS OF TECHNICAL ACOUSTICS UDC 534.8.081.7 EXPERIMENTAL STUDY OF SOUND ABSORPTION OF ACOUSTIC WEDGES FOR MUFFLED CAMERAS, Ch. 3.2 Wedges from BSBV, © 2015 I.V.Belyaev * - * - A.Yu. ** Y. Zverev *, S.Yu. Makashov *, V.V. Nalchikovsky **, A.F. Sobolev * - **, V.V. Chernykh * * Federal State Unitary Enterprise NAGI. Research Moscow Complex NAGI 105005 Moscow, 17 Radio str. ** Perm National Research Polytechnic University 614990 Perm, Komsomolsky pr. 29 E-mail: vvpal@perm.ru Received and editors 09.04.2015).

In addition, the scope of tasks to reduce the noise level to the standard in residential and industrial premises does not require the complete elimination of reflected sound waves from sound-absorbing structures, i.e. absolutely anechoic rooms are not required, therefore, the geometry of sound-absorbing structures with ideal planes in the form of wedges or pyramids is very rarely required, i.e. to effectively and sufficiently reduce the reflection of sound waves from the surface of sound-absorbing structures, you can use more technological geometric shapes that form the required surface from standard mineral wool pieces.

There are scattering acoustic panels (Jvori, Reflex, Stripe Combi, Stripe Fuser ...) from the ATP line produced by Jocavi (https://www.redsector.ru/catalog/akusticheskie-materialy/atp/scattering-diffusers/), which also can be produced in the form of inserts made of sound-absorbing materials, or a combination of them. These panels are produced from polymeric materials that can take any complex shape, but the disadvantage of these panels is that they consist of combustible materials (polyurethane, extruded polystyrene ...), and not from non-combustible sound-absorbing mineral materials, which are less processable in forming complex surfaces of panels. Also, these panels do not have structural strength and cannot be used as independent self-supporting enclosing structures.

Known wall and roof acoustic sandwich panels "Kraft SPAN ACOUSTIC", which consist of two external steel cladding, an insulating filler of mineral wool slabs with perpendicularly oriented fibers (lamellas cut from standard mineral wool slabs) to the plane of the sheet cladding, to create maximum rigidity constructions. One of the liners is a sound-permeable, perforated steel sheet, and the other is a solid steel sheet. The lamellas and steel cladding sheets are glued together to form a single flat, rigid sandwich panel.

The disadvantage of these acoustic sandwich panels is that the layer of sound-absorbing material, consisting of a set of many lamellas, in it, has a flat, rather than wedge, or embossed surface, to the front of sound waves, respectively, a significant proportion of sound waves are not absorbed, but are reflected from a given flat layer of sound-absorbing material, for these reasons the panels have a reduced sound absorption coefficient. This design is a prototype of the proposed solution.

(https://kraftspan.com/).

The purpose of the utility model is to reduce the amount of sound waves reflected from the surface of a sound-absorbing sandwich panel made of non-combustible, piece, standard, mineral wool, plate, sound-absorbing materials and thereby increase the sound absorption coefficient of the panel.

This problem is solved due to the transition from the flat outer surface of the sound-absorbing array of a sandwich panel to a relief surface, combining the alternation of protruding and falling elements from the plane of the array, consisting of lamellas of different heights, cut from standard mineral wool slabs.

For the manufacture of sound-absorbing sandwich panels, lamellas of different heights are cut from standard mineral wool slabs, lamellas of greater height equal to the distance between the sheet cladding of a flat sandwich panel, i.e. equal to the thickness of the sandwich panel and lamellas of lower height are also cut. The lamellas are cut into polyhedrons. These lamellas are collected in a dense array of sound-absorbing material, in which one surface adjacent to the cladding, in the form of a solid steel sheet, has a set of lamellas, the edges of which lie in one plane, tightly pressed against each other without gaps and these edges of all lamellas of different heights of this surface massifs are glued to the sheet external cladding. Accordingly, due to the difference in the height of the lamellas that make up the array of sound-absorbing material of the sandwich panel, only the edges of the lamellas of greater height protruding to the same height from the array of sound-absorbing material are glued to the opposite, perforated, sound-permeable, flat lining of the sandwich panel. And the lamellas of lower height remain glued only with one edge to the non-perforated cladding, while, with their lateral edges of the lamellas, relative to their glued edge, they are mechanically tightly compressed and rigidly fixed between the lateral edges of the lamellae of greater height, which are glued with their opposite edges to both outer edges. sandwich panel facings. Also, lamellas with a lower height, the edges of which face the perforated cladding, have an inclination of the surfaces of these edges to the perforated cladding of the sandwich panel, in the range from 0 ° to 65 °, i.e. can have edges, from a parallel arrangement with respect to the perforated lining, to other than parallel, in their various combinations for the entire array of sound-absorbing material.

FIG. 1 shows how the aforementioned sandwich panels are made from a standard mineral wool board (item 1), which has a horizontal arrangement of fibers (item 3) in the original board (Section 1-1, Fig. 2).

Mineral wool slab, standard height H, is cut with transverse (pos. 2), or longitudinal cuts into lamellas of the required height, i.e. on lamellas of greater height this is dimension B, which corresponds to the thickness of the sandwich panel (see Fig. 4, Fig. 5) and on lamellas of lower height it is dimension C. Further, lamellas with a greater (pos. 4) and with a lower height (pos. 5), are collected in a dense, without gaps, sound-absorbing array (Fig. 4, Fig. 5), in which the direction of the fibers of the mineral wool lamellas is perpendicular to the sound-permeable lining (item 6) and not sound-permeable lining (item 7). The sound-permeable cladding of a sandwich panel (item 6), with a panel length equal to the size L, is shown in FIG. 3, it has a through perforation (item 11). All the edges of the lamellas with higher and lower heights (pos. 5 and pos. 4, Fig. 4, Fig. 5) of the sound-absorbing array, from the side of the non-sound-permeable lining (pos. 7), are in the same plane, without gaps relative to each other and are glued to this continuous cladding in a single array. To the opposite, sound-permeable lining (pos. 6), they are glued with their edges, only lamellas of a greater height (pos. 4). Thus, the spatial rigidity of the sound-absorbing sandwich panel is created by external facings, which are connected to each other in a volumetric structure by an adhesive bond with lamellas having a perpendicular orientation of fibers to these facings. At the same time, sound waves passing through the sound-permeable lining of the sandwich panel (pos. 6) fall, as on the horizontal surface of the sound-absorbing material, in the form of lamellas of greater height (pos. 8, Fig. 4), as well as sound waves (pos. 9 ) fall on the front (pos. 12) and lateral faces (pos. 13) lamellas, acoustic traps (pos. 10). The presence in the acoustic traps (pos. 10) of lamellas of different heights (pos. 4, pos. 5), from the side of the sound-permeable lining (pos. 6), leads to an increase in the contact surface, with sound waves (pos. 9), of the sound-absorbing material, for account of the scattering effect, in which the direction of the reflected sound waves from the side faces of the lamellas of a greater height (pos. 13) and the front faces of the lamellas of a lower height (pos. 12), i.e. sinking lamellas, occurs not outside the array of sound-absorbing material of the sandwich panel (pos. 8), but back into its adjacent sound-absorbing surfaces (pos. 9), which, accordingly, in general, leads to an increase in the sound absorption coefficient of the sandwich panel. A constructive technique, with the use of lamellas, when the maximum rigidity of the mineral wool filler, in the form of the direction of the fibers, is oriented in a direction parallel to the direction, the possible mechanical effect on the sound-absorbing structure - in the direction of the outer facings, makes it possible to create a rigid sound-absorbing panel, when using a standard, slab mineral wool material with a minimum density, which does not contain a binder in its composition, that is, from non-combustible mineral wool.

To increase the specific percentage of the area of acoustic traps (pos. 10) in the total area of the sound-permeable lining (pos. 6) of the sound-absorbing sandwich panel, the thickness H _{1 of the} lamella with a higher height (pos. 4) is taken to be less than the thickness of the H ₂ lamellae with a lower height (pos. . 5), respectively, the specific percentage of sound waves (pos. 8, Fig. 4) decreases with a large percentage of reflected waves outside the array of sound-absorbing material, and the specific percentage of sound waves (pos. 9, Fig. 4) increases with a large percentage of re-reflected waves into the thickness of the sound-absorbing material, which increases the sound absorption coefficient of the sandwich panel. At the same time, lamellas with different thicknesses are cut from standard mineral wool slabs, respectively, with different initial thicknesses.

Acoustic traps (pos. 10) can have a different linear direction in the array of sound-absorbing material, i.e. direction of lamellas of lower height, relative to the dimensions of the sandwich panel. FIG. 4, figs. 5 shows an exclusively transverse direction of acoustic traps in a sandwich panel, i. E. direction perpendicular to the length of the sandwich panel L. Acoustic traps can also have an exclusively longitudinal direction, or mixed longitudinal-transverse directions in any percentage combinations.

The above-described sound-absorbing sandwich panel can combine, in addition to sound-absorbing properties, also heat-insulating properties, i.e. it can be used in enclosing wall structures, in the coatings of buildings and structures, when orienting the sound-permeable cladding inside the room, these panels are also effective and can be used in protective screens for equipment that are sources of noise, roadside noise absorption screens and other sound-absorbing structures.

FIG. 1 shows a diagram of cutting a mineral wool slab into lamellas of different heights;

FIG. 2 shows a cross-section 1-1 of the same mineral wool board and shows the direction of the fibers in the body of this board;

FIG. 3 shows a sound-absorbing sandwich panel from the side of a sound-permeable cladding;

FIG. 4 shows a longitudinal section 2-2 of a sound-absorbing sandwich panel in the composition of facings and a sound-absorbing array of lamellas with acoustic traps; the direction of the incident, absorbed and reflected sound waves from the lamellae in the composition of the sandwich panel is also shown;

FIG. 5 shows the same section of a sound-absorbing sandwich panel 2-2, but in a different version of the edges of the lamellas of a shorter length, which have a different combination of their inclination planes to the sound-permeable cladding.

Claims (6)

1. Sound-absorbing sandwich panel, consisting of two sheet external facings, one of which is solid, soundproof, and the other lining has through perforations in the form of holes for sound waves to pass through them into the panel, inside the panel there is an array of sound-absorbing material in the form of fixed by gluing to cladding lamellas made of mineral wool, the direction of the fibers in which is perpendicular to the planes of the outer cladding, characterized in that the lamellas inside the sandwich panel have different heights, one part of the lamellae has a greater height, and the other part of the lamellae has a lower height, while the edges of all lamellas having different heights facing the continuous facing of the panel, which does not have a through perforation, lie in the same plane, and all lamellas are fixed to this facing with an adhesive bond, and the opposite edges of the lamellas, facing towards the through perforated facing, have an adhesive connection with this facing only in lamellas from higher heights oh, these differences in the heights of adjacent lamellas form acoustic traps inside the sound-absorbing panel, formed by the lateral edges of the lamellas of a greater height and the front edges of the lamellas of a lower height. 2. Sound-absorbing sandwich panel according to claim 1, characterized in that the lamellas of a greater height have a smaller thickness than the lamellae of a lower height. 3. Sound-absorbing sandwich panel according to claim 1, characterized in that the acoustic traps have a transverse direction in the array of sound-absorbing material relative to the length of the sandwich panel. 4. Sound-absorbing sandwich panel according to claim 1, characterized in that the acoustic traps have a longitudinal direction in the array of sound-absorbing material relative to the length of the sandwich panel. 5. Sound-absorbing sandwich panel according to claim 1, characterized in that the acoustic traps have mixed longitudinal-transverse directions in the array of sound-absorbing material. 6. Sound-absorbing sandwich panel according to claim 1, characterized in that the lamellae with a lower height, the front edges of which face the perforated cladding, have an inclination of these edges to the perforated cladding of the sandwich panel in the range from 0 ° to 65 °, i.e. ... can have these edges from a parallel arrangement with respect to the perforated lining to other than parallel, in their various combinations for the entire array of sound-absorbing material.

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