KR101481691B1 - Device for reducing noises through floor - Google Patents

Abstract

The present invention provides an apparatus for efficiently preventing interlayer noise of a building. The apparatus of the present invention includes a plurality of air pockets 12 formed concavely and consecutively in a reference plane 11, a space portion 14 formed on the back surface of the air pocket, and side surfaces 18 formed on the rim portion. (10); A sponge layer (20, 30) adhered to the upper surface of the reference surface of the air pocket structure (10) and the bottom surface of the bottom surface (16b) of the air pocket, respectively; And styrofoam layers (22, 32) adhered to the top and bottom of the sponge layer, respectively. A plurality of air holes 16a are formed in the side surface 16 of the air pocket 12 to connect the air pocket and the space portion. The sponge layer and the styrofoam layer are inserted into the side surface 18 while being closely contacted with each other. At least one side of the side wall 18 is in close contact with the side wall of the building. The air inside the air pocket 12 escapes to the space portion 14 through the vent hole and the vibration is attenuated by the structure of the air pocket at the back of the space portion. And the transmission of vibration through air by the side wall 18 is prevented as much as possible.

Description

[0001] The present invention relates to a device for reducing noise,

The present invention relates to an interlayer noise control apparatus, more particularly, to mitigate the transmission of impact generated from a floor through air and to minimize the transmission to the vertical wall, thereby effectively reducing interlayer noise The present invention relates to an interlayer noise preventing device configured to be capable of preventing noise from being interrupted.

Apartment houses, etc. have become widespread, and in recent years, inter-floor noise has become a social problem. In order to minimize such interlayer noise, various devices have been proposed. For example, in Korean Patent Publication No. 2010-40983, a technique has been proposed in which air pockets are used to minimize the transmission of interlayer noise. Korean Patent No. 10-0671455 proposes to minimize the interlaminar noise by forming a void space therebetween while using the structure formed on the floor.

As described above, the formation of the air pocket or the formation of the empty space in the interior of the floor forming the layers between the multi-family houses and the buildings is effective to some extent in terms of preventing noise transmission to be. However, as for the interlayer noise, the sound generated by the external force applied to the floor between the floors may be transmitted to the lower layer or the upper layer, but the vibration of the floor due to the external force applied to the floor is transmitted to the upper layer or the lower layer, It is a very big cause.

As described above, the formation of the air pocket or the empty space by the opened structure in the floor formed of the concrete separating the layers and the layers in the multi-family house or the building, It can be said that the effect is somewhat recognized in terms of preventing transmission to other layers. However, in such a conventional structure, in order to prevent the vibration generated in the floor from being transmitted to the wall surface or the lower portion by using the air between the air pocket and the empty space as a medium, there is a certain insufficient effect to prevent the interlayer noise.

SUMMARY OF THE INVENTION The present invention has been made to solve such conventional disadvantages and it is an object of the present invention to provide a vibration damping device capable of effectively preventing vibration generated by an external force applied to a floor from being transmitted to another layer, Which is capable of attenuating an interlayer noise.

According to the invention for achieving such an object, it is possible to say that the floor is designed to be prevented from being transmitted to a wall surface or another layer by attenuating vibrations caused by an impact generated by an external force therein.

An air pocket structure having a plurality of air pockets formed concavely and continuously on a reference plane, a space formed on a back surface of the air pocket, and a side surface formed on a rim portion; A sponge layer closely attached to the upper surface of the reference surface of the air pocket structure and the bottom surface of the bottom of the air pocket; And a styrofoam layer closely adhered to the top and bottom of the sponge layer, respectively. Wherein a plurality of ventilation holes are formed in the side portion of the air pocket for connecting the air pocket and the space portion, and the sponge layer and the styrofoam layer are inserted into the air pocket structure while being closely attached to the inside of the air pocket structure, And is brought into close contact with the side wall.

The air pocket structure may be formed of any one of a paper material, a synthetic resin material, and a metal material.

According to the present invention, it is understood that the vibration caused by the impact generated in the floor is attenuated due to the structure of the air pocket inside the air pocket moving to the space portion along the air hole and the air pocket in the space portion. Further, since the side surface formed at the rim portion of the air pocket structure is in close contact with the sidewall of the building, it is possible to minimize the transmission of the vibration due to the air as the medium in the air pocket or the space portion.

Accordingly, it can be seen that vibrations generated in the multi-generational buildings are most effectively prevented from being transmitted by the vibration by preventing the vibrations generated in the multi-generational buildings from being transmitted to the side walls of the building by being attenuated in the noise preventing device of the present invention . According to the present invention, by virtue of the constitution of the sponge layer and the styrofoam layer, it is expected that the advantage of being advantageous even in the absorption of vibration through air can be expected.

1 is an exemplary perspective view of an apparatus for preventing noise according to the present invention;
2 is a cross-sectional exemplary view of an apparatus for preventing noise according to the present invention;
3 is a cross-sectional view of an example of a floor of a building in which the noise prevention device of the present invention is implemented.

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the drawings. FIG. 1 shows a structure for preventing interlayer noise according to the present invention. As shown, the present inventive interlayer-type noise preventing structure includes an air pocket structure 10 having a reference surface 11 on which a plurality of air pockets 12 are formed and a side surface 18 surrounding all the edges of the reference surface, .

The reference surface 11 of the air pocket structure 10 is formed at the center portion with respect to the side wall 18 and is formed into a plate shape having a constant thickness. Therefore, when the air pocket 12 is recessed downward in the reference plane 11, the space portion 14 having a shape corresponding to the upper air pocket 12 is formed on the lower portion of the reference plane 11 as shown in FIG. Is formed. A plurality of through holes 16a connecting the air pocket 12 and the space portion 14 are formed in the side portion 16 of the air pocket 12. [

It is more preferable that the side portion 16 is formed in an inclined plane as shown in the structural strength. That is, by shaping the side surface portion 16 into an inclined surface, the load applied to the floor as in the case of the thrust structure can be dispersed, thereby improving the overall structural strength.

The side surface 18 is formed so as to have a predetermined length in the vertical direction (vertical direction) on all outer sides of the reference surface 11, and is preferably formed integrally with the reference surface 11. The side 18 is a portion that contacts the side 18 of the air pocket structure in contact with or adjacent to the sidewall of the multi-family house or building and through the air in the air pocket 12 and space 14, So that the vibration caused by the impact in the building can be prevented from being transmitted to the side wall of the building.

The air pocket structure 10 having such a basic configuration can be formed of various materials such as a metal material, a synthetic resin material, or a paper material. For example, a thin metal plate may be molded as described above, or may be formed of a synthetic resin material or a reinforced synthetic resin material containing fibers or the like. Alternatively, the air pocket structure 10 may be formed of paper having a predetermined thickness, such as corrugated cardboard, or paper, such as a laminate of multiple piles. Among these materials, it is desirable that the vibration generated in the floor can be absorbed and, if possible, be selected from a lightweight material.

In the illustrated embodiment, it can be seen that the air pocket 12 has a rectangular shape when viewed in plan view. However, such an air pocket 12 may not be limited by its shape. For example, it may be formed into a polygonal shape, a circular shape, an elliptical shape, etc. including a triangular shape as well as a square shape when viewed on a plan view as shown Of course it is.

A plurality of ventilation holes 16a are formed in the side surface portion 16 of the air pocket 12. The ventilation hole 16a is formed such that the air in the air pocket 12 can be moved to the space portion 14 on the backside thereof by an impact applied to the floor. Generally, when an impact occurs in the floor of a building, it is natural that the vibration due to such impact is transmitted to the other part through the air layer inside the air pocket 12. [

For example, if the air inside the air pocket 12 is clogged (i.e., the air vents are not formed), the air inside the air pocket 12 will not have a travel path, 12 to the bottom surface 16b. However, when a plurality of ventilation holes 16a are present as in the present invention, the air in the air pocket 12 is moved to the space portion 14 on the back side through the ventilation holes 16a by the impact of the floor .

And the space portion 14 has a plurality of shapes substantially corresponding to the back surface of the air pocket 12. [ Therefore, it is natural that the air that has moved to the space portion 14 through the vent hole 16a is attenuated by the back surface structure of the plurality of air pockets 12. [ Since the air pocket 12 and the space portion 14 on the back surface thereof are formed substantially continuously with respect to the entire floor (x-axis and y-axis directions). It is a matter of course that the vibration caused by the air moved to the space portion 14 on the back surface through the vent hole 16a will be attenuated in all directions by the back surface structure of the air pocket 12. [

According to the present invention, since the side surfaces 18 are formed on all the outer surfaces of the reference surface 11, the waves of the air passing through the air holes 16a are mostly blocked by the side surfaces 18, The vibration can be prevented from being transmitted to the side wall of the housing. That is, according to the present invention, when an impact is applied to the floor, the air in the air pocket 12 escapes into the space portion 14 through the air vent hole 16a, The shape of the back surface of the air bag 12 is gradually attenuated, and the attenuated air waves are blocked by the side surface 18. Therefore, it can be seen that the vibration generated by the impact is substantially prevented from being transmitted to the side wall of the building.

Sponge layer layers 20 and 30 are respectively provided on the upper portion of the reference surface 11 of the air pocket structure 10 and the lower portion of the bottom surface 16b. The sponge layer layers 20 and 30 are configured to be inserted into the inner side surface of the side surface 18 of the air pocket structure 10 while being closely attached thereto. Styrofoam layers 22 and 32 are provided on the upper and lower portions of the sponge layers 20 and 30, respectively. The styrofoam layers 22 and 32 are also inserted into the air pocket structure 10 while being in close contact with the inner surface of the side surface 18 thereof.

The sponge layers 20 and 30 function to absorb vibration. By installing the sponge layers 20 and 30 in contact with the upper and lower surfaces of the air pocket structure 10, it is possible to absorb not only the vibration generated by the impact but also the shock generated by the impact It will also function to absorb the wave of air inside the air pocket 12. Further, it is natural that the sponge layers 20 and 30 also function to absorb the impact generated in the floor.

The styrofoam layers 22 and 32 provided on the upper and lower surfaces of the sponge layers 20 and 30 respectively absorb the vibration generated in the floor as well as the sponge layer as well as the function of insulation, Of the sponge layer 20 and 30 is prevented from being further transmitted to the outside after the sponge layer 20 and 30 pass through the medium. The sponge layers 20 and 30 and the styrofoam layers 22 and 32 may have a function of absorbing noise itself.

The sponge layers 20 and 30 have a soft ductility compared to the styrofoam layers 22 and 32. The vibration caused by the impact generated in the floor is transmitted to the air pocket 12 through the styrofoam layers 22 and 32. Styrofoam layers 22 and 32 having stronger rigidity at this time are not affected by the impact generated in the floor The sponge layers 20 and 30 can be uniformly dispersed as a whole while preventing the sponge layers 20 and 30 from concentrating on a part thereof.

The vibration of the air generated by the vibration transmitted to the inside of the air pocket 12 is attenuated while being escaped to the space portion 14 of the back surface through the vent hole 16a as described above, , 30). Further, it is judged that the entire vibration can be absorbed by the styrofoam layers 22 and 32 provided outside the sponge layers 20 and 30.

Next, an example in which the above-described interlayer noise preventing device is actually applied will be described with reference to FIG. As shown in the figure, the interlayer noise preventing device composed of the air pocket structure 10, the sponge layers 20 and 30, and the styrofoam layers 22 and 32 is installed on the slabs 100 forming the interstices of the building do. The foamed concrete layer 110 is formed to have a predetermined thickness on the upper part of the interlayer noise abatement device and the finished molten metal layer 120 in which the pipe 122 is installed in the upper part of the foamed concrete layer 110 Can be installed. A bottom material 130 is disposed on the top of the finished mortar layer 120.

It can be seen that the side 18 of the air pocket structure 10 described above is in close contact with the side wall 140 of the building. That is, as described above, the side 18 is in close contact with the side wall 140 of the building to prevent the vibration through the air in the air pocket 12 from being transmitted to the side wall 140. A plurality of such air pouch structures 10 are installed in a single layer wherein each side 18 is in close contact with the side 18 of the adjacent structure 10 or as shown in the side wall 140 of the building, Respectively. Accordingly, it is possible to minimize the transmission of the vibration generated by the impact to the side wall 140 through the air layer in the air pocket 12. [

As described above, according to the present invention, it can be seen that the vibration caused by the impact generated in the floor is prevented from being transmitted to the side wall 140 of the building as much as possible. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. will be.

10 ..... air pocket structure
12 ..... air pocket
14 ..... space portion
16 ..... side portion
16a.
16b ..... bottom
18 ..... side
20, 30 ..... sponge layer
22, 32 ..... Styrofoam layer

Claims (2)

A plurality of air pockets 12 formed concavely and continuously in the reference plane 11, a space 14 formed in the back surface of the air pocket, and side surfaces 18 formed on at least one side of the rim An air pocket structure (10);
A sponge layer (20, 30) adhered to the upper surface of the reference surface of the air pocket structure (10) and the bottom surface of the bottom surface (16b) of the air pocket, respectively; And
And a styrofoam layer (22, 32) adhered to the upper and lower portions of the sponge layer, respectively;
A plurality of air holes 16a are formed in the side portion 16 of the air pocket 12 to connect the air pocket and the space portion. The sponge layer and the styrofoam layer are inserted into the side surface 18 while being closely attached to each other. Wherein at least one side of the side surface (18) is in close contact with the side wall of the building or the side surface of the adjacent air pocket structure.
The interlaminar noise preventing device according to claim 1, wherein the air pocket structure (10) is formed of any one of a paper material, a synthetic resin material, and a metal material.

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