KR102562000B1 - Sound absorbing panel for architecture - Google Patents

Abstract

It relates to a sound-absorbing laminated panel for construction, wherein the sound-absorbing laminated panel for construction includes a first perforated sound-absorbing layer formed with a plurality of resonance grooves recessed from one surface and a plurality of first through holes penetrating the one surface and the other surface, and the first perforated sound-absorbing layer. Disposed on the other surface of the layer, a plate sound-absorbing layer made of a porous structure, disposed between the first perforated sound-absorbing layer and the plate sound-absorbing layer, and having a plurality of second through holes penetrating both sides A second perforated sound-absorbing layer formed, And a temperature control member for controlling the temperature of the second perforated sound-absorbing layer, wherein the second perforated sound-absorbing layer is made of a material that contracts and expands in response to temperature changes, and the second perforated sound-absorbing layer in cross section according to the temperature change. As the length of the layer is changed, the overlapping degree of the first through hole and the second through hole in the thickness direction is adjusted, and the cross-sectional area of the sound absorbing hole passing through the sound absorbing layer is increased or decreased to increase or decrease the frequency of sound absorbed by the sound absorbing layer. Characterized in that the range changes.

Description

Sound-absorbing laminated panel for construction {SOUND ABSORBING PANEL FOR ARCHITECTURE}

The present invention relates to a sound-absorbing laminated panel for construction, which absorbs and reduces noise (sound) in various frequency bands by using both a resonance-type sound-absorbing method and a loss-type sound-absorbing method, and at the same time, the noise (sound) to be absorbed according to the use environment It relates to a building sound-absorbing laminated panel capable of variably adjusting the frequency of.

In general, sound-absorbing laminated panels are installed on the ceiling surface, floor surface, or wall surface of buildings such as apartments, multi-story houses, multi-storey shopping malls, etc. to block and absorb noise from adjacent spaces to create a more pleasant environment. , Until recently, various types of sound-absorbing laminated panels have been developed.

On the other hand, since the conventional sound-absorbing laminated panel uses only one of the resonance-type sound-absorbing method and the elimination-type sound absorption method, there is a problem in that noise of various frequency bands cannot be absorbed or reduced. In addition, even when both the resonance-type sound absorption method and the loss-type sound absorption method are adopted, there is a problem in that the size of the sound-absorbing hole is fixed in the loss-type sound absorption method and the frequency of the noise to be absorbed cannot be variably adjusted according to the use environment.

Registered Patent Publication No. 10-1830831 Registered Patent Publication No. 10-1715241

The present invention has been made to solve the above-described problems, and an object of the present invention is to absorb and reduce noise (sound) of various frequency bands by using both the resonance type sound absorption method and the elimination type sound absorption method according to the use environment and at the same time , To provide a sound-absorbing laminated panel for construction that can variably adjust the frequency of noise (sound) to be absorbed according to the usage environment.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve these problems, a sound-absorbing laminated panel for construction according to an embodiment of the present invention is a first perforated sound-absorbing layer formed with a plurality of resonance grooves recessed from one side and a plurality of first through holes penetrating the one side and the other side. , Disposed on the other surface of the first perforated sound-absorbing layer, a plate sound-absorbing layer made of a porous structure, disposed between the first perforated sound-absorbing layer and the plate sound-absorbing layer, a plurality of second through-holes penetrating both sides are formed A second perforated sound-absorbing layer, and a temperature control member for controlling the temperature of the second perforated sound-absorbing layer, wherein the second perforated sound-absorbing layer is made of a material that contracts and expands according to temperature changes, and according to the temperature change In cross-section, the length of the second perforated sound-absorbing layer is changed, the degree of overlap of the first through-hole and the second through-hole in the thickness direction is adjusted, and the cross-sectional area of the sound-absorbing hole passing through the plate sound-absorbing layer is increased or decreased to increase or decrease the plate sound-absorbing layer It is characterized in that the frequency band of the sound to be absorbed changes.

The second perforated sound-absorbing layer exposes a portion of the other surface of the first perforated sound-absorbing layer, and is disposed on one side of the first perforated sound-absorbing layer and the second perforated sound-absorbing layer, and one side wall of the first perforated sound-absorbing layer and A fixing member for fixing one side wall of the second perforated sound-absorbing layer to be aligned in parallel, and the other side opposite to one side of the second perforated sound-absorbing layer on the other surface of the first perforated sound-absorbing layer exposed by the second perforated sound-absorbing layer. Disposed on, may further include a stopper for limiting the expansion length of the second perforated sound-absorbing layer.

When the overlapping degree of the first through hole and the second through hole in the thickness direction increases, the cross-sectional area of the sound absorbing hole increases, and the frequency of sound absorbed by the plate sound absorbing layer may decrease.

When the second perforated sound-absorbing layer is expanded to a maximum length, the plurality of second through holes may completely overlap the plurality of first through holes.

A thermal expansion coefficient of the second perforated sound-absorbing layer may be greater than a thermal expansion coefficient of the first perforated sound-absorbing layer.

According to embodiments of the present invention, a sound-absorbing laminated panel for construction includes a plate sound-absorbing layer having a porous structure, a first perforated sound-absorbing layer in which a first through hole and a resonance groove are formed, and a plurality of sound-absorbing layers between the plate sound-absorbing layer and the first perforated sound-absorbing layer. By having a laminated structure in which a second perforated sound-absorbing layer including a second through hole is disposed, noise is reduced using both the resonance sound absorption method and the elimination type sound absorption method to absorb or reduce sound (noise) of various frequency bands. can

In addition, since the second perforated sound-absorbing layer is made of a material that contracts or expands according to temperature change, the first through-hole formed in the first perforated sound-absorbing layer and the second perforated sound-absorbing layer by adjusting the temperature of the second perforated sound-absorbing layer and the second perforated sound-absorbing layer 2 Use the frequency of sound to be absorbed through the plate sound-absorbing layer by adjusting the cross-sectional area of the sound-absorbing hole passing through the plate sound-absorbing layer from the outside by adjusting the overlapping degree of the through-holes (eg, completely overlapping, partially overlapping, or non-overlapping in the thickness direction) It can change depending on the environment.

The second perforated sound-absorbing layer may be made of a material whose length changes to 100% to 150% of the diameter of the first through hole in the range of 15°C to 25°C.

Effects according to the technical spirit of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is an exploded perspective view for explaining a laminated structure of a sound-absorbing laminated panel for construction according to an embodiment of the present invention.
2 to 4 are cross-sectional views for explaining a laminated structure of a sound-absorbing laminated panel for construction according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined.

Also, in this specification, the singular form may also include the plural form unless otherwise specified in the phrase. As used herein, "comprises" and/or "comprising" means that a stated component, step, operation, and/or element is present in the presence of one or more other components, steps, operations, and/or elements. or do not rule out additions.

1 is an exploded perspective view for explaining a laminated structure of a sound-absorbing laminated panel for construction according to an embodiment of the present invention, and FIGS. 2 to 4 are an exploded perspective view for explaining a laminated structure of a sound-absorbing laminated panel for construction according to an embodiment of the present invention. cross-sections for

1 and 2, the sound-absorbing laminated panel 10 for construction according to an embodiment includes a plate sound-absorbing layer 100, a first perforated sound-absorbing layer 200, a second perforated sound-absorbing layer 300, and a temperature control member. (500), a stopper (400) and a fixing member (600).

The plate sound-absorbing layer 100 is a layer made of a porous structure, and may serve to absorb sound (noise) incident from the outside into the plate sound-absorbing layer 100 through sound-absorbing holes to be described later. The plate sound-absorbing layer 100 is a porous material in which air can be contained, and if the material can reduce noise through a sound-absorbing method, fabric having porosity such as non-woven fabric, glass fiber, rock wool, felt, cork It can be made of various materials such as, soft fiberboard, ceramics.

The first perforated sound-absorbing layer 200 may be disposed on one surface (upper surface in the drawing) of the plate material sound-absorbing layer 100 . The first perforated sound-absorbing layer 200 has a plurality of resonance grooves (HM) recessed from one side of the first perforated sound-absorbing layer 200, and a plurality of first perforated sound-absorbing layers penetrating one side and the other side of the first perforated sound-absorbing layer 200. One through hole HA1 may be formed. (In other words, the plate material sound-absorbing layer 100 may be disposed on the other surface of the first perforated sound-absorbing layer 200.) The first perforated sound-absorbing layer 200 includes a plurality of resonance grooves HM and a plurality of first perforated sound-absorbing layers. Through the through-hole HA1, it may serve to absorb or reduce noise in a resonance manner, or to absorb sound by introducing noise into the plate sound-absorbing layer 100.

A plurality of resonance grooves (HM) formed in the first perforated sound-absorbing layer 200 may play a role in reducing noise by resonating noise in a specific frequency region incident to the plurality of resonance grooves (HM) among the noise.

The resonance groove (HM) may include an inlet and a resonance groove. The inlet may be connected to one surface of the first perforated sound-absorbing layer 200 as a passage structure through which noise is introduced. The inlet may have a cylindrical shape and have a structure in which both ends in the thickness direction DR3 are open. The resonance groove may be connected to the open portion of the inlet. The resonance groove may have a space having a circular or elliptical structure inside, and specifically may have a shape in which the cross-sectional area of the groove expands and then contracts in the thickness direction. Noise generated from the outside of the first perforated sound-absorbing layer 200 is introduced into the resonance groove through the inlet and can be offset by the resonance effect in the resonance groove.

The plurality of first through-holes HA1 formed in the first perforated sound-absorbing layer 200 form sound-absorbing holes advancing to the plate material sound-absorbing layer 100 according to the degree of overlap with the second through-holes HA2 described later, thereby reducing noise It may play a role in advancing (inflowing) to the plate material sound-absorbing layer 100. The cross-sectional area of the sound-absorbing hole passing through the plate sound-absorbing layer 100 may be adjusted according to the degree of overlap between the first through-hole HA1 and the second through-hole HA2, and the sound-absorbing plate material is absorbed through the sound-absorbing hole according to the cross-sectional area of the sound-absorbing hole. Among the noise introduced into the layer 100, the frequency range of the absorbed noise may be variable. A detailed description of this will be given later.

The plurality of resonance grooves HM and the plurality of first through holes HA1 may be spaced apart from each other. The plurality of resonance grooves HM and the plurality of first through holes HA1 may be alternately disposed along the width direction, which is the first direction DR1.

The second perforated sound-absorbing layer 300 may be disposed between the first perforated sound-absorbing layer 200 and the plate material sound-absorbing layer 100 . The second perforated sound-absorbing layer 300 may expose a portion of the other surface (lower surface in the drawing) of the first perforated sound-absorbing layer 200 facing the second perforated sound-absorbing layer 300 . That is, the cross-sectional size of the second perforated sound-absorbing layer 300 may be smaller than the cross-sectional size of the first perforated sound-absorbing layer 200 .

A plurality of second through-holes HA2 penetrating both sides of the second perforated sound-absorbing layer 300 may be formed in the second perforated sound-absorbing layer 300 . The second perforated sound-absorbing layer 300 may be made of a material that contracts and expands according to temperature changes. The second perforated sound-absorbing layer 300 may have a cross-sectional length that changes according to a change in temperature. Illustratively, the cross-sectional view of the second perforated sound-absorbing layer 300 may be made of a solid material that increases in length when heated and shortens in length when cooled.

The length of the second perforated sound-absorbing layer 300 is changed according to the temperature change, so that the cross-sectional position of the plurality of second through holes HA2 formed in the second perforated sound-absorbing layer 300 may move. Accordingly, when the length of the second perforated sound-absorbing layer 300 changes, the second through-hole HA2 overlaps the plurality of first through-holes HA1 formed in the first perforated sound-absorbing layer 200 in the thickness direction. may change. That is, the second perforated sound-absorbing layer 300 may serve to change the relative arrangement relationship between the first through hole HA1 and the second through hole HA2 while the length is changed according to the temperature change. The first through hole HA1 and the second through hole HA2 constitute a sound absorbing hole for guiding noise to flow into the plate sound absorbing layer 100, and the first through hole HA1 and the second through hole ( HA2), the cross-sectional area of the sound-absorbing hole increases or decreases according to the degree of overlapping, so that the frequency band of noise (sound) absorbed by the plate sound-absorbing layer 100 may be varied.

The temperature control member 500 may control the temperature of the second perforated sound-absorbing layer 300 . The temperature control member 500 adjusts the temperature of the second perforated sound-absorbing layer 300 to change the length of the second perforated sound-absorbing layer 300 to correspond to the frequency region of the noise to be absorbed through the first through hole ( HA1) and the second through hole HA2, that is, the degree of overlap in the thickness direction DR3 may be adjusted. That is, the temperature control member 500 may serve to adjust the cross-sectional area of the sound-absorbing hole to correspond to the frequency region of the noise to be absorbed by changing the length of the second perforated sound-absorbing layer 300 through temperature control. Accordingly, it is possible to variably adjust the frequency of noise (sound) to be absorbed in response to the use environment.

Fixing member 600 is disposed on one side of each of the first direction (DR1) and the second direction (DR2) of the first perforated sound-absorbing layer 200 and the second perforated sound-absorbing layer 300, the first perforated sound-absorbing layer It may serve to fix one side wall of 200 and one side wall of the second perforated sound-absorbing layer 300 so as to be aligned side by side with each other. As one side wall of the first perforated sound-absorbing layer 200 and one side wall of the second perforated sound-absorbing layer 300 are fixed to each other by the fixing member 600, the length of the second perforated sound-absorbing layer 300 is heated or cooled. Even when is changed, the length of the second perforated sound-absorbing layer 300 is increased or decreased only to the other side, so that it is easy to adjust the relative positional relationship (overlapping degree) between the first through hole HA1 and the second through hole HA2 can For example, the fixing member 600 may be disposed on the left and upper edges of the first perforated sound-absorbing layer 200 and the second perforated sound-absorbing layer 300 on a plane.

The stopper 400 may be disposed on the other side of the second perforated sound-absorbing layer 300 on the other surface of the first perforated sound-absorbing layer 200 exposed, on the other side opposite to the one side on which the fixing member 600 is disposed. That is, the stopper 400 may be disposed on a side opposite to the side on which the fixing member 600 is disposed. Stopper 400 may serve to limit the expansion length of the second perforated sound-absorbing layer (300).

On the other hand, as the temperature of the second perforated sound-absorbing layer 300 is changed by the temperature control member 500, the first perforated sound-absorbing layer 200 in contact with the second perforated sound-absorbing layer 300 is the second perforated sound-absorbing layer 300 When the thermal energy of ) is conducted and the length expands and contracts together, it may be difficult to adjust the relative positional relationship between the first through hole HA1 and the second through hole HA2. Therefore, the thermal expansion coefficient of the second perforated sound-absorbing layer 300 may be greater than the thermal expansion coefficient of the first perforated sound-absorbing layer 200 . That is, by being made of a material whose thermal expansion coefficient of the first perforated sound-absorbing layer 200 is smaller than the thermal expansion coefficient of the second perforated sound-absorbing layer 300, despite the change in temperature, the first penetration of the first perforated sound-absorbing layer 200 The hole HA1 is fixed and can move only the second through hole HA2 of the second perforated sound absorbing layer 300 . Accordingly, it may be easy to adjust the relative positional relationship between the first through hole HA1 and the second through hole HA2.

On the other hand, the second perforated sound-absorbing layer 300 is preferably made of a material whose length changes by at least 100% to 150% of the diameter of the first through hole HA1 in the range of 15 ° C to 25 ° C maintained in an indoor environment. can do. When the length of the second perforated sound-absorbing layer 300 is changed outside the temperature range maintained indoors, the length of the second perforated sound-absorbing layer 300 is heated to an excessively high temperature or cooled to an excessively low temperature to increase or decrease the indoor temperature can affect In addition, the second perforated sound-absorbing layer 300 is made of a material whose length is changed by at least 100% to 150% of the diameter of the first through hole HA1 in the range of 15 ° C to 25 ° C maintained in an indoor environment. The positional relationship may be easily changed so that the first through hole HA1 and the second through hole HA2 overlap each other, partially overlap each other, or do not overlap each other within room temperature.

Hereinafter, a method for varying the frequency of noise absorbed by the sound-absorbing laminated panel for construction according to the present invention according to the relative position between the first through hole HA1 and the second through hole HA2 will be described.

2 shows that the second perforated sound-absorbing layer 300 is heated by the temperature control member 500 and expanded to the maximum length.

Referring to Figure 2, when the second perforated sound-absorbing layer 300 is heated by the temperature control member 500, the second perforated sound-absorbing layer 300 has a length to the other side opposite to one side where the fixing member 600 is disposed. can be inflated. The second perforated sound-absorbing layer 300 may have a maximum length limited by the stopper 400, the second perforated sound-absorbing layer 300 is expanded to a maximum length, and a plurality of first through holes HA1 and a plurality of first The two through holes HA2 may completely overlap each other in the thickness direction DR3.

The first through-hole HA1 and the second through-hole HA2 may constitute a sound-absorbing hole through which noise passes through the sound-absorbing plate material 100 . When the first through hole HA1 and the second through hole HA2 completely overlap each other, the cross-sectional area (effective area) of the sound absorbing hole may be maximized. On the other hand, the frequency of the sound that is introduced into the plate sound-absorbing layer 100 and absorbed through the sound-absorbing hole composed of the first through hole HA1 and the second through hole HA2 is the first through hole HA1 and the second through hole HA1. It can be determined by the cross-sectional area (effective area) of the sound-absorbing hole composed of the hole HA2. Specifically, as the cross-sectional area of the sound-absorbing hole increases, noise in a low-frequency band is absorbed, and as the cross-sectional area of the sound-absorbing hole decreases, noise in a high-frequency band may be absorbed.

Therefore, when the second perforated sound-absorbing layer 300 is expanded to the maximum length and the first through hole HA1 and the second through hole HA2 completely overlap, the first through hole HA1 and the second through hole HA1 overlap each other. Noise introduced into the plate sound-absorbing layer 100 through the sound-absorbing hole formed of (HA2) and absorbed may be noise in a low frequency band.

3 shows that the second perforated sound-absorbing layer 300 is cooled and contracted by the temperature control member 500 .

Referring to FIG. 3, when the second perforated sound-absorbing layer 300 is contracted by the temperature control member 500, the second perforated sound-absorbing layer 300 is contracted to form a plurality of first through holes HA1 and a plurality of second perforated sound absorbing layers. The two through holes HA2 may completely non-overlap in the thickness direction DR3. (That is, it can be out of sync.)

When the first through hole HA1 and the second through hole HA2 do not overlap in the thickness direction, the sound absorbing function may be generally performed by the first perforated sound absorbing layer 200 . Specifically, some of the noise in a specific frequency region among noises traveling to the first perforated sound-absorbing layer 200 may be reduced by a plurality of resonance grooves HM formed in the first perforated sound-absorbing layer 200 . In addition, among the noise propagating to the first perforated sound-absorbing layer 200, the thickness of the first through hole HA1 formed in the first perforated sound-absorbing layer 200 corresponds to an odd multiple of A/4 (A: the wavelength of sound waves). Noise having a frequency that corresponds to the frequency may be reduced by the first through hole HA1. On the other hand, the first through-hole HA1 is covered by one side of the second perforated sound-absorbing layer 300, so noise introduced into the first through-hole HA1 may not generally flow into the plate sound-absorbing layer 100.

FIG. 4 shows that the first through hole HA1 and the second through hole HA2 are partially overlapped. Referring to FIG. 3, when the second perforated sound-absorbing layer 300 is contracted or expanded by the temperature control member 500, the plurality of first through holes HA1 and the plurality of second through holes HA2 are formed in the thickness direction. (DR3) can partially overlap.

When the first through hole HA1 and the second through hole HA2 partially overlap, the cross-sectional area (effective cross section) of the sound absorbing hole composed of the first through hole HA1 and the second through hole HA2 decreases, The noise introduced into the plate sound-absorbing layer 100 through the sound-absorbing hole and absorbed may be noise of a high frequency band compared to the case of completely overlapping.

Those skilled in the art related to the present embodiment will be able to understand that it may be implemented in a modified form within a range that does not deviate from the essential characteristics of the above description. Therefore, the disclosed methods are to be considered in an illustrative rather than a limiting sense. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the equivalent scope will be construed as being included in the present invention.

10: sound-absorbing laminated panel for construction
100: plate sound-absorbing layer
200: first perforated sound-absorbing layer
300: second perforated sound-absorbing layer
400: stopper
500: temperature control member
600: fixing member

Claims (5)

A first perforated sound-absorbing layer formed with a plurality of resonance grooves recessed from one side and a plurality of first through holes penetrating the one side and the other side;
a plate sound-absorbing layer disposed on the other surface of the first perforated sound-absorbing layer and having a porous structure;
a second perforated sound-absorbing layer disposed between the first perforated sound-absorbing layer and the plate material sound-absorbing layer and having a plurality of second through-holes passing through both sides; and
Including a temperature control member for adjusting the temperature of the second perforated sound-absorbing layer,
The second perforated sound-absorbing layer is made of a material that contracts and expands according to temperature changes,
The length of the second perforated sound-absorbing layer is changed in cross section according to the temperature change, and the overlapping degree of the first through-hole and the second through-hole in the thickness direction is adjusted while the cross-sectional area of the sound-absorbing hole passing through the plate material sound-absorbing layer increases or decreases. It is characterized in that the frequency band of the sound absorbed by the plate sound-absorbing layer is changed,
The second perforated sound-absorbing layer exposes a portion of the other surface of the first perforated sound-absorbing layer,
A fixing member disposed on one side of the first perforated sound-absorbing layer and the second perforated sound-absorbing layer and fixing one side wall of the first perforated sound-absorbing layer and one side wall of the second perforated sound-absorbing layer to be aligned side by side; and
Disposed on the other side opposite to one side of the second perforated sound-absorbing layer on the other side of the first perforated sound-absorbing layer exposed by the second perforated sound-absorbing layer, and further comprising a stopper for limiting the expansion length of the second perforated sound-absorbing layer Sound-absorbing laminated panel for construction.
delete According to claim 1,
When the overlapping degree of the first through hole and the second through hole in the thickness direction increases, the cross-sectional area of the sound-absorbing hole increases, and the plate material sound-absorbing layer decreases the frequency of sound absorbed as the cross-sectional area of the sound-absorbing hole increases. , sound-absorbing laminated panels for construction.
According to claim 3,
When the second perforated sound-absorbing layer is expanded to its maximum length, the plurality of second through-holes completely overlap the plurality of first through-holes, the architectural sound-absorbing laminated panel.
According to claim 4,
The thermal expansion coefficient of the second perforated sound-absorbing layer is greater than the thermal expansion coefficient of the first perforated sound-absorbing layer, sound-absorbing laminated panel for construction.