KR20140002009U - Noise Absorbent Inner Wall in Buildings - Google Patents

Abstract

It is easy to install and can be installed at relatively low cost, and has excellent sound absorption and soundproofing performance, and can reduce the noise generated in the work space.
The building inner wall of the present invention has a wall panel constituting the wall surface, a stud having support for the wall panel while forming a skeleton of the inner wall of the building, and having slits for receiving side ends of the wall panel on both sides, and attached to the wall panel. A sound absorbing panel is provided. The side end of the wall panel is installed to be inserted into the slit of the stud through the sealing member. In a preferred embodiment, the pair of slits is formed on the side of the stud, so that the wall panels are installed in pairs between adjacent studs, thereby forming a double wall.
The sound absorbing and soundproofing performance can be improved by blocking and absorbing the noise transmitted and transmitted from the work space to the adjacent space. Therefore, there is an effect of maintaining privacy protection or work security at a high level.

Description

Noise Absorbent Inner Wall in Buildings

The present invention relates to a structure of a building, and more particularly, to an inner wall of a building for enhancing a sound absorbing function.

Generally, when partitioning a space in a large work space, partitions are used or inner walls are installed.

Partitions enhance the convenience of arranging furniture, making the space more efficient, blocking the spread of conversations and work noise directly to others, and effectively masking individual movements, thereby increasing work efficiency and privacy. However, there is a lack of complete privacy, business security, and sound insulation.

Therefore, in order to maintain privacy protection, work security, soundproofing, etc. at a high level, it is desirable to provide an inner wall. In order to construct a functionally perfect inner wall, concrete blocks must be used, but the construction is not only cumbersome, but there is a problem that it is not easy to dismantle when the inner wall becomes unnecessary. Considering the fact that in recent years, large buildings are not divided into small rooms when newly constructed, the entire floor is formed into a single space, and the method of installing and dismantling the inner wall as needed is common. It is unrealistic to construct the inner wall with blocks.

The existing widely used method of building the inner wall is to use wood and gypsum board, steel partition or lightweight partition. However, in the case of using wood and gypsum board, the construction is complicated and expensive, and it is impossible to apply because of the possibility of dust generation in the work space where high cleanliness is required, such as a semiconductor manufacturing line or precision equipment. There are disadvantages. On the other hand, in the case of using a steel partition or a lightweight partition, there is a problem in that the construction is simple, but the aesthetics are inferior and sound insulation is not sufficient.

The present invention is to solve the above problems, the construction is simple and can be installed at a relatively low cost, the sound absorption and soundproofing performance is excellent to provide a building inner wall that can reduce the noise generated in the work space Shall be.

The inner wall of the building of the present invention for achieving the above technical problem and the wall panel constituting the wall surface and the studs that support the wall panel while forming a skeleton of the building inner wall, the slits for receiving the side end of the wall panel on both sides is formed And a sound absorbing panel attached to the wall panel. The side end of the wall panel is installed to be inserted into the slit of the stud through the sealing member.

In a preferred embodiment, the pair of slits is formed on the side of the stud, so that the wall panels are installed in pairs between adjacent studs, thereby forming a double wall.

The sound absorbing panel preferably includes a sound absorbing material block and a carbon sheet bonded to the sound absorbing material block so as to surround the sound absorbing material block.

The building inner wall according to the present invention can increase the sound absorption and sound insulation performance by blocking and absorbing the noise propagated from the work space to the adjacent space, and thus has the effect of maintaining a high level of privacy protection or work security.

In addition, the aesthetics after construction is excellent, there is an advantage that the construction is not complicated and can be installed at a relatively low cost as well as easy disassembly.

In particular, since the inner wall of the building of the present invention does not cause any scattering dust problem, it can be installed without causing concern about air pollution even in a space where an invitation degree is required, such as a semiconductor manufacturing plant.

Furthermore, not only does not generate static electricity, but also micro-induced static electricity can be immediately released through the existing ground wire or newly installed ground wire, there is an advantage that the problem caused by the static electricity does not occur at all. Since the carbon sheet is a flame retardant material, there is an additional advantage of suppressing fire propagation in case of fire.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the figure,
1 is a perspective view of an embodiment of an inner wall of a building according to the present invention.
2 is a cross-sectional view of the inner wall of the building shown in FIG.
3 is a partially cutaway perspective view of the sound absorbing panel illustrated in FIG. 1.

Referring to Figure 1, the building inner wall according to an embodiment of the present invention is the wall panel (100a ~ 100f), and the stud (110a ~ 110d) for supporting the wall panel (100a ~ 100f) while forming a vertical skeleton of the building inner wall and And a sound absorbing panel 200 attached to the wall panels 100a to 100f.

In a preferred embodiment, an acrylic plate having a thickness of 3 to 10 millimeters (mm) is used as the wall panels 100a to 100f. In particular, according to the present invention, as the wall panel (100a ~ 100f) is installed as described later and the airtightness is maintained as the support rigidity is increased, even if using a thin acrylic plate of 5 mm or 3 mm The functionality of the inner wall can be maintained.

As the studs 110a to 110d, a metal material such as aluminum may be used, and the metal material may be prepared by extrusion processing of the metal material. As shown in FIG. 2, a pair of slits 112 are formed at both sides of each stud 110a-110d to accommodate side end portions of the two wall panels 100a-100f.

For example, one end of the first wall panel 100a and one end of the second wall panel 100b are inserted into the slit pair formed on one side of the first stud 110a. Meanwhile, the other end of the first wall panel 100a and the other end of the second wall panel 100b are inserted into the slit pair formed on one side of the second stud 110b and the other side of the second stud 110b. One end of the third wall panel 100c and one end of the fourth wall panel 100d are inserted into the slit pair formed in the slit pair. By configuring in this way, the double wall using an acryl plate is comprised.

At this time, when inserting the end of the wall panel (100a ~ 100f) into the slit of the stud (110a ~ 110d), as shown in Figure 2, the wall panel (100a ~ 100f) through the gasket 114 is stud It is preferable to make it fully sealed by connecting to 110a-110d. The gasket 114 not only prevents air circulation but also increases a sound insulation effect.

3 illustrates the sound absorbing panel 200 shown in FIG. 1 in detail.

In a preferred embodiment, the sound absorbing panel 200 is composed of a cuboidal to plate-shaped melamine foam (202) provided inside, and a carbon sheet (204) surrounding the melamine foam (202). It is a panel of the form.

The melamine foam 202 is a synthetic foam of melamine resin, which is a collection of fine pores made of an open cell structure, which has excellent sound absorption and non-flammability in case of fire, and in particular, light weight. It is known.

In one embodiment, the carbon sheet 204 has a form in which a nonwoven fabric is laminated, and a back surface is coated with an adhesive layer.

In the sound absorbing panel 200 of FIG. 3, the carbon sheet 204 is made of melamine such that the melamine foam 202 therein is not exposed to the outside and the powder that can be separated from the melamine foam 202 does not spill out. The foam 202 is completely wrapped and adhered to the outer circumferential surface of the melamine foam 202 by an adhesive layer.

In manufacturing the sound absorbing panel 200, first, the melamine foam 202 is cut into a rectangular parallelepiped shape, and the carbon sheet 204 is cut to completely wrap the melamine foam 202. After the cutting is completed, the protective sheet is removed from the carbon sheet 204, and then the melamine foam 202 is placed on the adhesive layer adhered to the nonwoven fabric of the carbon sheet 204, and then the melamine foam 202 is applied to the carbon sheet 204. It will be attached around it.

At this time, the sound absorbing panel 200 attached to each wall panel (100a ~ 100f) may be processed into a single panel, but as shown in Figure 1 by dividing the production into a plurality of panels to enhance the aesthetics and increase the convenience of production It is preferable. In addition, the overall aesthetics may be further increased by changing the color of the sound absorbing panels 200 or partially changing the color of each sound absorbing panel 200.

The building wall of Figure 1 can be constructed as follows.

First, the wall panels 100a to 100f, the studs 110a to 110d, and the wall panels 100a to 100f are designed and processed according to the height of the room and the length of the wall surface.

Subsequently, after installing the studs at the far end, for example, the first stud 110a, the pair of slits formed on one side of the first stud 110a may have one end of the first wall panel 100a and the second wall panel ( One end of 100b) is inserted through the gasket 114. In this case, the operation of inserting the other end of the first wall panel 100a and the other end of the second wall panel 100b into a pair of slits formed on one side of the second stud 110b may be performed at substantially the same time. Whenever the end portions of the wall panels 100a to 100f are inserted into and installed on the studs 110a to 110d, a force is applied in the lateral direction so that the connection between the studs 110a to 110d and the wall panels 100a to 100f is in close contact. It is desirable to increase the airtightness. This process is repeated until all assembly is complete.

Next, the operation of the inner wall of the building of FIG. 1 will be described.

In the state in which the inner wall of the building is constructed, not only the wall panels 100a to 100f are installed in the double wall form, but also the connection area between the studs 110a to 110d and the wall panels 100a to 100f is kept in close contact and the airtightness is maintained. Only the panels 100a to 100f exhibit significant sound insulation effects.

Furthermore, according to the present invention, the sound absorbing panel 200 exhibits an additional sound absorbing function. In particular, the melamine foam 202 in the sound absorbing panel 200 serves to absorb the noise generated in the work space. In addition, the melamine foam 202 has a flame retardancy that does not burn in the fire to perform a function that partially prevents the propagation of the flame in the event of a fire.

On the other hand, in general, the surface resistance of the carbon sheet 204 is known to be 10 ³ ~ 10 ¹⁴ Ω / ㎠ according to the product, it is known to be effective in preventing static electricity. Therefore, when the wall surface is grounded or the sound absorbing panel 200 is grounded by a separate ground line, extremely small amounts of electrostatic inductive charges may be rapidly released to the ground.

In addition to the antistatic action, the carbon sheet 204 hardly generates dust from itself and thus does not pollute the surroundings, and the powder generated during the deterioration of the melamine foam 202 is transferred to the outside of the sound absorbing panel 200. This prevents the departure.

Accordingly, when the sound absorbing panel 200 as described above is installed in the work space, it is possible to absorb the noise in the room without contaminating the air in the work space. In particular, when installed in a facility requiring ultra-correction conditions such as a semiconductor manufacturing line, the partition device can absorb the noise generated in the semiconductor manufacturing apparatus without contaminating the air of the manufacturing line.

Although the preferred embodiments of the present invention have been described above, the present invention can be modified in various ways without departing from the technical idea or essential features, and can be embodied in other specific forms.

For example, the above description will be mainly focused on the embodiment of using melamine foam as the sound absorbing material, but the sound absorbing material is not limited thereto, and synthetic rubber such as polyurethane, styrene butadiene rubber, polychloroprene rubber, nitrile rubber, silicone rubber, etc. May be used.

On the other hand, while the above has been described an embodiment using a carbon sheet as the outer member of the sound absorbing panel device, a sheet containing a metal or coated with a metal may be used instead.

The static electricity may be discharged by connecting the ground wire to the sound absorbing panel 200 and the ground terminal of the building or the mechanical device.

On the other hand, the above has been described an embodiment for forming a vertical skeleton of the inner wall of the building by installing the studs (110a ~ 110d) supporting the wall panels (100a ~ 100f) at regular distances, but similar horizontal skeleton members are used together The wall panels 100a to 100f may be arranged like a tile by using a connection port at a position where each skeleton member meets. Such embodiments will be omitted by those skilled in the art based on the present specification.

Therefore, it should be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the claims of utility model registration described below rather than the above detailed description, and all modifications or variations derived from the meaning and scope of the utility model registration claims and equivalents thereof are included in the scope of the present invention Should be interpreted as being.

100a ~ 100f: wall panel
110a-110d: stud, 112: slit, 114: gasket
200: sound absorption panel
202: melamine foam, 204: carbon sheet

Claims (3)

Wall panels 100a to 100f constituting the wall surface;
Studs 110a to 110d supporting the wall panels 100a to 100f and forming slits for receiving side ends of the wall panels 100a to 100f on both sides thereof; And
Sound absorbing panel 200 attached to the wall panel (100a ~ 100f);
And,
The inner wall of the building panel is installed so that the side end portions of the wall panels (100a to 100f) are inserted into the slits of the studs (110a to 110d) through a sealing member. The method according to claim 1,
The slits are formed in pairs on the side surfaces of the studs 110a to 110d,
An inner wall of a building in which double wall surfaces are formed by installing the wall panels 100a to 100f in pairs between adjacent studs 110a to 110d. The method according to claim 1 or 2, wherein the sound absorbing panel 200
Sound-absorbing material block,
A carbon sheet bonded to the sound absorbing material block to surround the sound absorbing material block;
Building inner wall provided with.

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