RU2724095C1 - Composite sound-absorbing panel - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: invention relates to sound-absorbing panels with resonance-type cells, which suppress sound vibrations generated by gas flows and their injectors. Composite sound-absorbing panel consists of several interconnected sections. Each section comprises inner perforated and outer bearing layers of skin and arranged between layers filler made as a single unit in form of separate cells of different shape and/or volume. Sections are made with possibility of disconnection from each other.

EFFECT: invention enables increase in the sound absorption, besides, proposed design has smaller weight, reliable connection of noise-protective and bearing parts.

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Description

The invention relates to sound-absorbing panels with resonant-type cells damping sound vibrations created by gas flows and their superchargers, and is intended for use in the field of aerospace engineering, transport equipment, radio engineering, construction, for example, as sound-absorbing panels in the manufacture of flow paths of modern aircraft turbojet engines.

Sound absorbing structures (ZPKs) are known, consisting of two walls, perforated and non-perforated, between which there is a single-layer or multi-layer sound-absorbing element. In this case, between the layers of the material of a complex profile adjacent to it, there is an element of a resonance type, the so-called Helmholtz resonator (RU No. 2002111099; RU No. 2533484; RU No. 67650; RU No. 2531154).

A disadvantage of the known structures is the relatively low noise attenuation efficiency, in particular, in the discrete absorption spectrum, i.e. in effective sound absorption in a narrow frequency spectrum and minimal absorption in the rest of the range, due to the fact that existing PPCs are tuned to a certain frequency range, which is limited by the natural frequency of the resonators used in the design.

Known sectional sound-absorbing structure, containing sequentially several of the above structures (sections) with different height of the filler, and accordingly, with different sound-absorbing ability [V.N. Krysin. Technological processes of forming, winding and gluing structures. M. Engineering, 1989, p. 110] In this case, the height of the filler of the individual sections is selected based on the actual operating conditions of the structure (noise level, sound frequency, value

sound pressure along sections of structures). Tuned to its own frequency, each section individually effectively dampens the noise in a narrow frequency band, but for the whole structure the frequency width is quite large.

A disadvantage of the known design is the low efficiency of noise reduction with a sufficient width of the absorbed spectrum due to the fact that adjacent resonators in the same section are tuned to the same frequency, which leads to the mutual influence of the resonators, and as a result to a decrease in their joint operation. In addition, significant aerodynamic drag due to the difference in the height of the filler leads to a decrease in acoustic efficiency. Also, the disadvantages of the known design are the technological difficulties in connecting the individual sections, insufficiently strong fastening of the noise-protecting part to the bearing part, the presence of defects and messages between adjacent cells, due to the complex gluing process, significant metal consumption, weight, and bulkiness.

The closest design of the same purpose to the claimed invention in terms of features is a composite sound-absorbing panel (US 20180114516 A1), consisting of several interconnected sections made with the possibility of detaching from each other, each section contains an inner perforated and outer bearing layers of the skin and Interposed aggregate. Moreover, in each section, the bearing layers of the casing and the filler between them are made in the form of separate cells of various shapes and / or volumes. This design is taken as a prototype.

Signs of the prototype, which coincides with the essential features of the claimed invention, is a composite sound-absorbing panel consisting of several interconnected sections made with the possibility of disconnecting from each other; each of the sections contains an inner perforated and an outer bearing layers of the skin and

placed between the layers of filler, made in the form of separate cells of various shapes and / or volumes.

A disadvantage of the known design adopted as a prototype is the low efficiency of noise reduction with a sufficient width of the absorbed spectrum due to the fact that adjacent resonators in the same section are tuned to the same frequency, which leads to the mutual influence of the resonators, and as a result to a decrease in their joint work . Also, the disadvantages of the known design are the insufficiently strong fastening of the noise insulation part to the bearing part, the presence of defects and messages between adjacent cells, due to the complex gluing process, significant weight, cumbersome, because the design is multilayer.

The objective of the invention is the creation of a sound-absorbing panel, which allows to increase the efficiency of reducing noise generated by a gas or air stream, having a lower weight with a sufficiently wide spectrum of frequencies of absorbed sound, a reliable connection of noise-protective and carrier parts.

The problem was solved due to the fact that in the known composite sound-absorbing panel, consisting of several interconnected sections, made with the possibility of disconnecting from each other, each of the sections contains an inner perforated and outer bearing layers of the lining and placed between the layers made in in the form of separate cells of various shapes and / or volumes, according to the invention, the carrier layers of the skin and the filler between them are made as a single unit in the form of a single-layer structure, while adjacent cells have different shapes and / or volumes.

Cells of various shapes or volumes can be installed alternating along the length and width of the panel in a different order, which determines the modal composition of the noise.

To enhance the effect of sound absorption in transverse or inclined sections of the cells, additionally permeable and / or elastic membranes can be placed, and at least one membrane is located in each cell.

To enhance the sound absorption effect in the transverse or inclined sections of the cells, porous fibrous materials can additionally be placed.

Signs of the proposed technical solution, distinctive from the prototype, the supporting layers of the skin and the filler between them are made as a single unit in the form of a single-layer structure; adjacent cells have different shapes and / or volumes; cells of various shapes and / or volumes are installed alternating along the length and / or width of the panel in a different order, which determines the modal composition of the noise; permeable elastic membranes are additionally placed in the transverse or inclined sections of the cells; each cell has at least one membrane; in transverse or inclined sections of the cells are additionally placed porous fibrous materials.

The implementation of the noise insulation part together with the carrier in the form of separate cells will eliminate defects that violate the continuity between the noise insulation and the power part of the structure and the orientation of the perforation relative to the cell axis, ensuring a reliable connection of the noise protection and carrier parts. The result is increased rigidity and reliability.

The execution of each section in the form of cells of various shapes and / or volumes and the possibility of placing adjacent cells of different shapes and / or volumes helps to eliminate interference, which, on the one hand, increases the broadband system, on the other hand, allows to achieve the maximum sound absorption effect. This design feature leads to a more active interaction of the resonant radiation of the cells with the main noise stream in the flow path (channel) in front of the sound-absorbing layer of the casing and to increase the power of the acoustic screen in the channel cross section, increasing the sound absorption coefficient.

The execution of sections with the ability to disconnect from each other allows you to create a sound-absorbing panel with a different set of cells. Due to the use of combined forms and layouts of resonators, the mutual influence of the cells is significantly reduced and the efficiency of collaboration over a wide frequency band is increased.

The presence in the cells of permeable elastic membranes located in the transverse or inclined sections of the cells leads to an increase in resonance phenomena in the cell chambers due to the conversion of the energy of elastic deformation of the membranes into the kinetic energy of air movement in the cylindrical necks of the cells, an increase in the amplitudes of the acoustic pressure of air in the necks of the cells, and an increase acoustic screen power in the channel cross section for a wider frequency range of noise, increasing the sound absorption coefficient of noise in a wide frequency range.

The design of a single-layer broadband (instead of two-, three-layer) can reduce the weight of the structure and its cost.

The inventive design of the sound-absorbing panel has a large number of degrees of freedom, which will provide a discrete and fairly dense series of resonant frequencies, which will allow to increase the efficiency of reducing noise generated by a gas or air stream, as well as a reliable connection of noise-protective and carrier parts.

The proposed composite sound absorbing panel is illustrated by the drawings shown in FIG. 1-4.

In FIG. 1 shows a General view of the composite ZPK

In FIG. 2 - variant of the castle connection, section with trapezoidal grooves.

In FIG. 3 - variant of the castle connection, section with square grooves.

In FIG. 4 - version of the castle connection, section with triangular grooves.

The composite sound-absorbing panel consists of several identical sections 1, interconnected. Each section 1 contains an inner perforated and an outer supporting layer of skin, and a filler placed between them. In each section 1, the supporting layers of the casing and the filler between them are made as a single unit in the form of separate cells of various shapes and / or volumes. Standing cells have different shapes and / or volumes. The composite sound-absorbing panel is single-layer.

Sections can be interconnected in various ways, for example, by means of a lock connection (Fig. 1). The sections are made with grooves for connection with neighboring sections in the form of a castle connection with trapezoidal grooves (Fig. 2), square grooves (Fig. 3) and triangular grooves (Fig. 4). Sections are configured to disconnect from each other.

Cells of various shapes and / or volumes can be installed alternating along the length and / or width of the panel in a different order. Various layout schemes are possible, determined by the modal composition of the noise. In transverse or inclined sections of the cells, additionally permeable elastic membranes can be placed. Each cell may have one, two or more membranes. The number of membrane layers and their orientation (angle of inclination to the cell axis) in the cell volume are determined by the characteristics of the noise spectrum and design. Membranes can be made of fabrics, nets, as well as porous-fibrous materials. In transverse or inclined sections of the cells, porous-fibrous materials can additionally be placed.

The diameters of the perforation and its orientation relative to the axis of the resonator, the volume and shape of the resonators, the number, properties (stiffness, thickness, permeability) of the membranes and their orientation (angle of inclination to the axis of the cell) in the volume of each cell are selected from the condition of resonant operation of the cell at a given noise frequency. The resonant frequency of the cell depends on the volume and shape, the thickness of the perforated wall, the number, properties, location (along the height of the cell) and the orientation of the membranes and the stiffness of the material of the cells and the carrier layer (near the perforations).

Cells can be placed in different layouts on a plane or curved surface. The inventive design can be installed in any plane.

Cells of a composite sound-absorbing panel can be produced by all known methods of manufacturing such products, including 3D printing methods. Panel sizes may vary.

A composite sound-absorbing panel works as follows: noise reduction in the channels lined with resonant ZPKs occurs due to the fact that the wave, passing through the perforation, changes the propagation direction, forming an acoustic screen that prevents the further propagation of the longitudinal wave. Due to the use of combined forms and layouts of resonators, the mutual influence of the cells is significantly reduced and the efficiency of collaboration over a wide frequency band is increased.

The proposed design of the panel allows to increase the sound absorption coefficient of noise generated by a gas or air stream by an average of 15% in a wide frequency range of acoustic noise, in comparison with the prototype. This technical result was established when testing a prototype panel.

The advantage of the claimed composite sound-absorbing panel is that it has higher sound-absorbing properties in comparison with the prototype, has less weight, reliable

connection of noise and bearing parts, low cost and simple construction.

Claims (4)

1. Composite sound-absorbing panel, consisting of several interconnected sections, made with the possibility of detachment from each other, each of the sections contains an inner perforated and outer bearing layers of the skin and placed between the layers of filler, made in the form of separate cells of various shapes and / or volumes , characterized in that the supporting layers of the casing and the filler between them are made as a single unit in the form of a single-layer structure, while the adjacent cells have different shapes and / or volumes. 2. The sound-absorbing panel according to claim 1, characterized in that the cells of various shapes or volumes are installed alternating along the length and width of the panel in a different order determined by the modal composition of the noise. 3. The sound-absorbing panel according to claim 1, characterized in that permeable and / or elastic membranes are additionally placed in the transverse or inclined sections of the cells, and at least one membrane is located in each cell. 4. The sound-absorbing panel according to claim 1, characterized in that porous-fibrous materials are additionally placed in the transverse or inclined sections of the cells.

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