KR102187222B1 - Soundproof wallpaper - Google Patents

Abstract

The present invention relates to a soundproof wallpaper that is easy to manufacture, environmentally friendly, and can effectively reduce the transmission of sound wave energy, and a method of manufacturing the same. The soundproof wallpaper according to the present invention comprises a wallpaper layer including paper or fabric and a resonance layer, the resonance layer being disposed adjacent to the wallpaper layer and an upper layer in which two or more through holes are formed, and the In addition to being disposed under the upper layer, it is characterized in that it comprises a lower layer in which two or more grooves are formed.

Description

Soundproof wallpaper{SOUNDPROOF WALLPAPER}

The present outbreak relates to a soundproof wallpaper, and in particular, to a soundproof wallpaper that is easy to manufacture, is environmentally friendly, and can effectively reduce the transmission of sound wave energy.

Typically, wallpaper is attached to the inner wall of a building to provide an aesthetic environment to the interior space of the building. Mainly, various designs are printed on fibers such as paper or silk. However, as environmental noise and interfloor noise have recently emerged as a social problem, many attempts have been made to impart soundproofing functions to the wallpaper.

Practical Publication No. 20-005055, Patent Publication No. 2011-003745, Patent Registration No. 284917, and Patent Registration No. 523206 disclose soundproof wallpapers. All of these prior arts have formed a foam layer on the rear surface of the soundproof wallpaper or separately form a space in order to improve the soundproof function of the wallpaper.

In general, a foam layer or a porous layer having a plurality of pores is used as a sound insulation material to improve the sound insulation function. However, when these soundproofing materials are installed 30cm or more apart from the floor or wall, they have good sound absorption across the entire frequency band, whereas when they are installed at a distance of 10cm or less from the floor or wall, the sound absorption is greatly reduced. The deterioration of the sound occurs particularly in the low range. Interfloor noise, which is a major problem in buildings, is mainly low-pitched sounds. However, in the case of conventional wallpaper, since it is used in close contact with the inner wall of a building, the existing soundproof wallpaper has a disadvantage that it is insufficient in providing a soundproof function.

The present invention has been created in view of the above circumstances, and has a technical purpose for a soundproof wallpaper capable of effectively reducing interfloor noise of a building by improving a soundproof function.

The soundproof wallpaper according to the first aspect of the present invention for realizing the above object is composed of a wallpaper layer comprising paper or fabric, and a resonance layer, and the resonance layer is disposed adjacent to the wallpaper layer, and two It is characterized in that it comprises an upper layer in which the above through-holes are formed, and a lower layer in which two or more grooves are formed while being disposed under the upper layer.

The soundproof wallpaper according to the second aspect of the present invention is a soundproof wallpaper in which a building is attached to an inner wall surface, and includes a wallpaper layer including paper or fabric, and a resonance layer, and the resonance layer is on the inner wall surface. Consisting of a lower layer disposed adjacent and having two or more through holes formed therein, and a lower layer disposed between the wallpaper layer and the lower layer and having two or more grooves formed therein, and the through hole and the groove communicate with each other. It is characterized.

In addition, the upper layer is characterized in that it is composed of an organic material and a porous mineral material.

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In addition, the lower layer is characterized in that it is composed of an organic material and a porous mineral material.

In addition, the porous mineral material is characterized in that it comprises a porous ceramic or zeolite.

In addition, the upper layer or the lower layer is characterized in that it is configured to further include a ferroelectric material.

In addition, the ferroelectric material is characterized in that the polarization.

In addition, it is characterized in that the refractory material is additionally included in the resonance layer.

In addition, the groove is characterized in that the cross-sectional shape is square or rectangular or circular or elliptical.

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The soundproof wallpaper according to the third aspect of the present invention is a soundproof wallpaper attached to and used on the inner wall of a building, comprising a wallpaper layer including paper or fabric, and a resonance layer, wherein the resonance layer is at least two It characterized in that the Helmholtz resonator is provided.

According to the present invention having the above configuration, a Helmholtz resonator is installed on the wallpaper. This Helmholtz resonator provides an effect of reducing the inter-floor noise of the building by blocking the transmission of noise generated in the interior space of the building to the adjacent space.

1 is a cross-sectional view of a soundproof wallpaper according to an embodiment of the present invention.
2 is a conceptual diagram for explaining the concept of a soundproof wallpaper according to another embodiment of the present invention.
3 is a block diagram showing a cross-sectional configuration of a soundproof wallpaper according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiments described below exemplarily show one preferred embodiment of the present invention, and the examples of these embodiments are not intended to limit the scope of the present invention.

1 is a cross-sectional view showing the structure of a soundproof wallpaper according to a first embodiment of the present invention.

In the drawing, the soundproof wallpaper includes a wallpaper layer 10 and a resonance layer 20. The wallpaper layer 10 is composed of paper or fabric, like a conventional wallpaper. The resonance layer 20 includes an upper layer 21 disposed adjacent to the wallpaper layer 10 and a lower layer 22 coupled to the upper layer 21. The resonance layer 20, that is, the upper layer 21 and the lower layer 22, includes, for example, PVC, nylon, polyester, and organic materials such as aqueous acrylic, ethyl vinyl acetate (EVA), and polyvinyl alcohol (PVA).

A plurality, that is, at least two or more through holes 211 are formed in the upper layer 21, and grooves 221 are formed in the lower layer 22 to correspond to the through holes 211. The number of through holes 211 corresponding to the grooves 221 is not limited to one and may be set arbitrarily. In addition, although the groove 221 is shown to have a square or rectangular shape in the drawings, the groove 221 may be preferably configured to have an elliptical or hemispherical cross-sectional shape.

The through hole 211 and the groove 221 constitute a Helmholtz resonator. A Helmholtz resonator having a closed space constituted by a groove 221 and an inlet portion formed by a through hole 211 causes a phase shift when a sound wave of a specific frequency band is introduced through the inlet, so that the sound wave in the opposite phase Is released to the outside through. In addition, as the generated sound wave of the reverse phase is phased out from the original sound wave, an effect of removing the original sound wave is created. At this time, the sound range in which resonance occurs by the Helmholtz resonator may be appropriately set by adjusting the sizes of the through holes 211 and the grooves 221. For example, the smaller the size of the through hole 211 and the groove 221, the lower the resonance frequency.

When sound wave energy is applied to a medium, the sound wave energy is divided into reflected sound wave energy reflected by the medium, absorbed sound wave energy absorbed by the medium, and passing sound wave energy passing through the medium. The frequency band and magnitude of each of these sound wave energy are related to the type or shape of the medium, or the natural vibration frequency of the medium.

In Figure 1, assuming that the soundproof wallpaper according to the present embodiment is attached to the inner wall surface, when an arbitrary sound wave is generated in the interior space of the building, a part of the generated sound wave energy is the wallpaper layer 10 and the resonance layer 20 And reflected and absorbed by the inner wall surface, and the remaining sound wave energy passes through these media and is transferred to another adjacent space. And the sound wave energy transmitted to the outside in this way is the cause of the interlayer noise. At this time, the size or main sound range of the sound wave transmitted to the outside varies depending on the material or thickness of the inner wall surface and the wallpaper layer 10 and the resonance layer 20.

In FIG. 1, the sizes of the through-holes 211 and the grooves 221 installed in the resonance layer 20 are preferably set so as to reduce the sound waves in the band transmitted to the outside as much as possible. In addition, by setting the sizes of the through holes 211 and the grooves 221 not all the same, but various types, a method of expanding the sound bandwidth of the sound wave removed by the resonant layer 20 may also be preferably employed. .

On the other hand, according to the research of the present inventors, when pores having different sizes are formed in a material, the sound absorption and sound insulation functions are improved. 2 is a diagram for explaining the sound absorption and sound insulation functions.

In FIG. 2, reference numeral 30 denotes a medium to which sound wave energy is applied. Assuming that the first pores 31 having a relatively large diameter and the second pores 32 having a small diameter exist in this medium, when a sound wave A is introduced from the outside, the sound wave A is It is propagated through the first and second pores 31 and 32. However, when the sound wave A that has passed through the first pore 31 enters the second pore 32, the sound wave A reflects or refracts as indicated by a and b. And this phenomenon similarly occurs even when the sound wave (b) passing through the second pore 32 enters the first pore 31. It is believed that this is caused by varying the resonance frequency of the pores according to the size of the pores.

In general, the sound insulation function of a material is determined by how much sound waves applied from the outside pass through, and the sound absorption function is determined by how much sound waves applied from the outside are absorbed. All substances vibrate when they are stimulated by external sound waves, and at this time, the frequency sound that affects the vibration is absorbed through the process of converting it into vibration energy.

As described above, when pores having different sizes are formed in a medium, the sound wave is reflected and refracted while passing through the pores, thereby remarkably reducing the straightness of the sound wave. That is, the sound insulation function is improved. In addition, sound waves resonate as they pass through pores of different sizes. That is, sound wave energy in various frequency bands is converted into vibration energy in the pores, thereby improving the sound absorption function.

In another embodiment of the present invention, the upper layer 21 or the upper layer 21 and the lower layer 22 constituting the resonance layer 20 in FIG. 1 are formed of a mixture of an organic material and a porous mineral material.

Porous ceramic or zeolite is preferably employed as the porous mineral material, and vermiculite or tourmaline powder can be effectively employed. Of course, mixing an organic material and at least two or more types of porous minerals may be preferably employed, and the upper layer 21 and the lower layer 22 may contain different minerals. As is well known, porous ceramics usually have pores in the unit of µm, and in the case of zeolite, pores in the unit of nm.

In the case of paper or fabric constituting the wallpaper layer 10 in this embodiment, pores of approximately tens of µm are formed, and pores of several µm to several nm are formed in the resonance layer 20 by a porous mineral material. When sound waves from the outside enter the pores of the resonant layer 20 through the pores of the wallpaper layer 10, reflection and refraction of the sound waves occur as described in FIG. 2 and proceed to the inner wall surface through the resonant layer 20 The amount of sound waves produced is significantly reduced.

In particular, as described above, the resonance frequency of the pores varies according to the size of the pores, so that the smaller the pore size, the better the sound absorption function for the low frequency range. The zeolite included in the resonant layer 20 has pores in the unit of nm, and the size of these pores provides a desirable effect in removing the low-frequency sound range, which is a problem in interlayer noise.

In the case of producing the soundproof wallpaper according to the present embodiment, the wallpaper layer 10 is formed through a conventional process, and then the upper layer 21 and the lower layer constituting the resonance layer 20 by extruding a mixture of an organic material and a porous mineral material. (22) will be formed. Then, the wallpaper layer 10, the upper layer 21, and the lower layer 22 are bonded to each other through an adhesive or thermal bonding method to form a soundproof wallpaper.

3 is a cross-sectional view showing the structure of a soundproof wallpaper according to another embodiment of the present invention.

In this embodiment, a lower layer 42 having at least two or more through holes 421 is formed on the lower side of the resonance layer 40, that is, on a side surface disposed adjacent to the inner wall surface when attaching the soundproof wallpaper to the inner wall surface, An upper layer 42 is formed between the lower layer 42 and the wallpaper layer 10. In addition, a groove 411 communicating with the through hole 40 is formed in the upper layer 41. Also in the present embodiment, the groove 411 may be formed of a square or rectangular shape, or a shape having an elliptical or hemispherical cross-sectional shape.

Also in this embodiment, the resonance layer 40 may preferably include an organic material and a porous mineral material.

The embodiment shown in FIG. 1 is configured to sound-absorb and absorb noise generated in the inner space made by the inner wall surface to the outside through the inner wall surface, whereas in this embodiment, It is configured to sound and absorb external noise. In addition, since other configurations and operations are substantially the same as those of the above-described embodiment, detailed descriptions are omitted.

The embodiments according to the present invention have been described above. The soundproof wallpaper according to the present invention is provided with a plurality of Helmholtz resonators on the soundproof wallpaper, so that the sound wave energy propagating outside or inside through the soundproof wallpaper is reduced.

In addition, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the technical spirit of the present invention.

For example, in the case where the resonance layers 20 and 40 are formed in the above-described embodiment, a heat-resistant material or a fire-resistant material may be additionally included in addition to the porous mineral material. And as such a heat-resistant or fire-resistant material, volcanic ash can be preferably employed.

In addition, in the above-described embodiment, when forming the resonance layers 20 and 40, a ferroelectric material may be additionally mixed.

According to the research of the present inventors, when a ferroelectric material is mixed with an organic material, it is possible to control the resonance frequency of the organic material layer. That is, in forming the resonance layer, an organic material or a mixture of an organic material and a porous mineral material is mixed with a ferroelectric material to form the upper layer (21, 41) or the lower layer (22, 42), and a predetermined voltage is applied thereto to polarize the ferroelectric material. If so, the resonant frequencies of the upper layers 21 and 41 or the lower layers 22 and 42 are changed. At this time, the resonance frequency can be appropriately adjusted according to the particle size or amount of the ferroelectric material mixed with the organic material or the type of the ferroelectric material.

In this case, the ferroelectric material may be an inorganic material such as PZT, an organic material such as PVDF, or a mixture of an inorganic ferroelectric material and an organic material or organic ferroelectric material.

10: wallpaper layer, 20: resonance layer,
21: upper layer, 22: lower layer,
211: through hole, 221: groove.

Claims (21)

A wallpaper layer comprising paper or fabric,
It is configured with a resonance layer,
The resonance layer includes an upper layer disposed adjacent to the wallpaper layer and having two or more through holes, and a lower layer disposed under the upper layer and having two or more grooves,
Soundproof wallpaper, characterized in that the upper layer or the lower layer comprises a ferroelectric material. The method of claim 1,
Soundproof wallpaper, characterized in that the upper layer is composed of an organic material and a porous mineral material. delete The method of claim 1,
Soundproof wallpaper, characterized in that the lower layer is composed of an organic material and a porous mineral material. The method according to claim 2 or 4,
Soundproof wallpaper, characterized in that the porous mineral material comprises a porous ceramic or zeolite. delete The method of claim 1,
Soundproof wallpaper, characterized in that the ferroelectric material is polarized. The method of claim 1,
Soundproof wallpaper, characterized in that the refractory material is additionally included in the resonance layer. The method of claim 1,
The groove is a soundproof wallpaper, characterized in that the cross-sectional shape is square or rectangular or circular or oval. delete delete delete delete delete delete delete delete delete delete delete delete

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