RU179829U1 - SOUND-ABSORBING CELL PANEL - Google Patents

Abstract

The utility model relates to multilayer sound-absorbing panels with a resonant type honeycomb core, damping sound vibrations (noise) created by gas flows and their superchargers, intended for use in aerospace engineering, transport (automotive, shipbuilding, railway, oil and gas pumping, etc.), radio engineering, construction and other industries, and can be used, for example, as sound-absorbing panels in the manufacture of flow paths of modern aviation turbojet engines. The objective of the utility model is to increase the efficiency of reducing the noise generated by a gas or air stream when it passes through the gas paths of a vehicle’s engine. A sound-absorbing honeycomb panel consists of two bearing layers (casing): an internal sound-absorbing perforated layer 1 and an outer 2; cells 3 and 4 with the reciprocal orientation “top-base”; the inner layer 1 is made with through perforation 5. In the transverse or inclined sections of the cells 3 and 4 of the honeycomb core, permeable elastic membranes can be located 6. One, two or more membranes can be located in each cell. The voids between the cells can be filled with a binder 7. Cells of the honeycomb core can be made in the form of truncated and un-truncated pyramids and cones. The perforation holes of the skin can be either cylindrical or conical-cylindrical in shape, when the outline of the larger base of the truncated cone is located on the outer surface of the sound-absorbing layer of the skin, the smaller base is contoured along the side surface of the cylindrical part of the perforation. Various types of cell piling are allowed, in particular: tetragonal and hexagonal close-packed piling.

Description

The utility model relates to multilayer sound-absorbing panels with a resonant type honeycomb core, damping sound vibrations (noise) created by gas flows and their superchargers, intended for use in aerospace engineering, transport (automotive, shipbuilding, railway, oil and gas pumping, etc.), radio engineering, construction and other industries, and can be used, for example, as sound-absorbing panels in the manufacture of flow paths of modern aviation turbojet engines.

Known multilayer cell panel containing the outer and inner perforated sheathing and honeycomb in the form of truncated pyramids and (or) cones (patent RU No. 2247878 from 03/10/2005).

A disadvantage of the known design is the insufficient effect of sound attenuation, due to the fact that:

- the truncated pyramidal or conical shape of the cells with a diameter of the upper base exceeding the diameter of the cell neck does not allow to efficiently convert the potential energy of air compression inside the cells into the kinetic energy of air movement in the cell neck;

- the presence between the carrier layers of the skin of the system of acoustically interconnected regions of complex shape around the system of isolated unidirectional pyramidal or conical cells makes it difficult for active resonance phenomena to occur in these areas and in the corresponding perforations in the carrier layer of the skin of the skin.

Closest to the claimed design of the panel is a multilayer panel containing plating and honeycomb in the form of perforated polyhedral alternating between themselves "top - base" truncated pyramids with a taper angle of 5 ÷ 50 ° (patent RU No. 2290312 from 12.27.2006).

The known design has an insufficient noise suppression effect due to the fact that acoustic waves are suppressed inside the cells, and not in the channel (gas path of the engine), in which the most active interaction of the resonant radiation of the cells with the main noise stream occurs. In this design, the side surfaces of the honeycomb core cells have through perforations, which allows compressed air to pass from one cell to another, which interferes with active resonant processes and reduces the amplitudes of the acoustic air pressure in the cell necks and reduces the power of the acoustic screen in the channel cross section, reducing the coefficient sound absorption.

Signs of the prototype, which coincides with the essential features of the claimed utility model, a sound-absorbing panel containing inner perforated and outer skin layers and honeycomb between them with cells in the form of multifaceted alternating “top - base” volumetric geometric shapes.

The objective of the utility model is to increase the efficiency of reducing the noise generated by a gas or air stream when it passes through the gas paths of a vehicle’s engine.

The technical result of the utility model is to increase the sound absorption coefficient.

The problem was solved due to the fact that in the well-known sound-absorbing honeycomb panel containing the inner perforated and outer skin layers and the honeycomb between them with cells in the form of alternating top-to-base volumetric hollow geometric bodies, the side surfaces of the honeycomb cells are made solid.

Cell honeycomb cells can be made in the form of truncated pyramids and cones. To enhance the sound absorption effect, the cells of the honeycomb core can be made in the form of unbroken pyramids and cones, and the holes of the perforation of the noise-absorbing layer of the skin should be made directly or near the junction of the vertices of the pyramids or cones and in the areas where their bases adjoin the noise-absorbing layer.

To enhance the sound absorption effect of the perforation holes in the sound-absorbing layer of the casing, a conical-cylindrical shape can be made when the outline of the larger base of the truncated cone is located on the outer surface of the sound-absorbing layer of the casing, and the smaller base is mated along the contour with the side surface of the cylindrical part of the perforation.

To enhance the effect of sound absorption in transverse or inclined sections of the cells of the honeycomb core, additionally permeable elastic membranes can be placed. Each cell may contain 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.

Signs of the proposed technical solution, distinctive from the prototype, - the side surfaces of the cells of the honeycomb core are solid (there is no through perforation). Cells of the honeycomb core can be made in the form of pyramids, cones, or truncated pyramids and cones. Holes of through perforation (cell neck) in the sound-absorbing layer of the skin can be conical-cylindrical: the outline of the larger base of the truncated cone is located on the outer surface of the sound-absorbing layer of the skin, the smaller base is contoured with the side surface of the cylindrical part of the perforation. Permeable resilient membranes can be placed in the cross or inclined sections of the honeycomb core cells.

The implementation of cells with impermeable (without perforation) side surfaces leads to an increase in the amplitudes of the acoustic air pressure inside and in the necks of the cells, which 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 noise-absorbing layer of the casing and to increase the power of the acoustic screen in the cross section of the channel, increasing the sound absorption coefficient.

The implementation of honeycomb cells in the form of truncated pyramids or cones with impermeable (without perforation) side surfaces leads to an increase in the amplitudes of the acoustic air pressure inside and in the necks of the cells, which 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 cross section of the channel, increasing the sound absorption coefficient.

The implementation of the cells of the honeycomb core in the form of unbroken pyramids or cones with impermeable (without perforation) side surfaces provides unhindered exit of compressed air from the cells through the mouths to the channel, which leads to an increase in the amplitudes of the acoustic pressure of air in the neck of the cells and to an increase in the power of the acoustic screen in the cross section channel, increasing sound absorption.

The implementation of through holes of perforation (cell necks) in the noise-absorbing layer of the conical-cylindrical shell directly at or near the junction of the vertices of the pyramids or cones and in the areas adjacent to their bases to the noise-absorbing layer of the skin provides better transmission of acoustic noise waves from the flow path into the cell chambers.

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 the power of the acoustic screen in the channel cross section for a wider range of noise, increasing the sound absorption coefficient of noise in a wide range ONET frequencies.

The location in the cells of permeable elastic membranes makes it possible to intensify active resonant phenomena in all cells and in perforations (cell necks) of the lining sheathing layer, minimize acoustic losses and make the process of converting the potential energy of compressed air and the elastic deformation of the membranes inside the cells into kinetic energy of air movement as complete as possible in the necks of the cells and in creating an acoustic screen in the cross section of the channel, increasing the sound absorption coefficient of noise in a wide range no frequencies.

The diameters, heights and cone angle of the conical-cylindrical neck, the number, properties (stiffness, thickness, permeability) of the membranes and their orientation (angle of inclination to the cell axis) in the cell volume are selected from the condition of the resonant operation of the cell at a given noise frequency; the resonant frequency of the cell depends on the volume and angle of taper of the cell chamber, diameters, heights and the angle of taper of the conical-cylindrical neck (thickness of the perforated layer), the number, properties, location (height of the cell) and the orientation of the membranes and the stiffness of the material of the cells and the carrier layer ( near perforations).

Cell honeycomb cells can be arranged with tetragonal or hexagonal stacks on a plane or curved surface.

When tetragonal laying, the axis of the cells pass through the nodes of the tetragonal lattice on a plane or curved surface:

- in each odd row, all cells have one orientation, in an even row - cells with a reverse orientation;

- in each row, neighboring cells have a different orientation and in each even row, the cells are shifted by one relative to the cells of the odd rows;

- in all nodes of the lattice pass the axis of the cells of the same orientation, in the centers of the interstitial lattice - the axis of the cells of the opposite direction.

With hexagonal laying, in all nodes of the triangular lattice on the plane or curved surface, the axes of the cells of the same direction pass, in the centers of the internodes with the periodicity of the lattice - the axis of the cells of the opposite direction.

To ensure the rigidity of the panel structure, voids between cells can be filled with a binder.

In FIG. 1 shows elements of a sound-absorbing honeycomb panel with conical resonant cells; in FIG. 2 - diagrams of particular cases of laying conical cells in a honeycomb core: tetragonal laying pattern (Fig. 2 a-c) and hexagonal (Fig. 2d) (view from the working perforated inner lining) with holes in the vertices and bases. In FIG. Figure 3 shows sound-absorbing panels with conical-cylindrical perforation of the upper bearing layer: without a membrane (Fig. 3a), with one (Fig. 3b, d) or two (Fig. 3c, d) transverse (Fig. 3b, c) in the cell ) or inclined (Fig. 3d, d) membranes.

The sound-absorbing honeycomb panel consists of two bearing layers (casing): an internal sound-absorbing perforated layer 1 and an outer 2; cells 3 and 4 with the reciprocal orientation “top-base”; the inner layer 1 is made with through perforation 5. In the transverse or inclined sections of the cells 3 and 4 of the honeycomb core, permeable elastic membranes are placed 6. The voids between the cells are filled with a binder 7.

Performing perforation of the carrier layer of the casing ensures the passage of acoustic noise waves from the flow path into the conical cells of the cells through their peaks and bases. For unhindered exit of compressed air from the cells through the perforations (necks) into the channel, it is necessary to strive for alignment and contiguity of the cylindrical perforation surfaces in the layer and the corresponding internal surfaces of the pyramidal or conical cells. The conical (non-truncated) shape of the chambers of the resonant reflecting cells is preferable to the pyramidal shape, since the conical shape allows you to more significantly minimize acoustic losses and make the conversion of the potential energy of air compression inside the cells into kinetic energy of air movement in (cylindrical or conical-cylindrical) necks more complete. perforation of the sound-absorbing carrier layer of the panel.

Elements of a sound-absorbing panel with a biconical honeycomb core can be produced by all known methods of manufacturing products from polymer composite materials (autoclave molding from prepregs, vacuum infusion, pressure impregnation method RTM, direct pressing, pultruded method).

The proposed sound-absorbing honeycomb panel has higher sound-absorbing properties in comparison with the prototype.

Claims (3)

1. A sound-absorbing honeycomb panel containing inner perforated and outer skin layers and a honeycomb between them with cells in the form of alternating top-to-bottom volume hollow geometric bodies, characterized in that the honeycomb cells are made in the form of pyramids or cones with solid side surfaces. 2. The sound-absorbing panel according to claim 1, characterized in that the perforation holes of the inner skin layer are conical-cylindrical in shape: the contour of the larger base of the truncated cone is located on the outer surface of the inner skin layer, the smaller base is contoured with the side surface of the cylindrical perforation. 3. The sound-absorbing panel according to claim 1, characterized in that permeable elastic membranes are located in transverse or inclined sections of the honeycomb core cells.

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