KR101465410B1 - Interfloor Soundproof Structure of Building and Mat with Air-filled Aircap for Interfloor Soundproof Structure - Google Patents

Abstract

The present invention relates to an interlayer soundproof structure of a building and a mat with gas-filled air caps for the same. The interlayer soundproof structure installed on a bottom slab of a building includes a soundproof layer using the air cap mat installed on the top surface of a bottom slab and consisting of at least one mat with gas-filled air caps closely protruding from the whole region of one surface, in which the air cap is filled with gas mixed with air and gas with the mass, which is higher than that of the air in a volume ratio of 50% or more to the air, and an upper mat protection layer disposed on the mat; a bottom finishing layer disposed on the soundproof layer using the air cap mat; and a support layer interposed between the soundproof layer using the air cap mat and the bottom finishing layer. Therefore, it is possible to increase the soundproof effect of the air cap mat.

Description

TECHNICAL FIELD [0001] The present invention relates to a structure for preventing an interlayer noise and an interlayer noise,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a structure for preventing noise between buildings and an air-filled air-cap mat for preventing noise between buildings, and more particularly to a structure for preventing noise from being transmitted between upper and lower layers, Preventing structure and a structure for filling the interstice noise.

In the case of a multi-storey building such as an apartment or a villa, noises are generated due to rumbling, falling objects, etc., and noise generated from the upper floor is transmitted to the lower floor through the floor slab and the wall.

It is known that most of the noise generated in the upper story (about 70%) is transmitted through the floor slab of the building.

There is a problem that the living environment of a lower-level resident is hindered when noise is transmitted between the upper and lower floors. Therefore, a method of preventing the noise from being transmitted between the upper and lower floors is a method of forming an inter- .

FIG. 6 is an exploded perspective view showing an interlayer noise preventing structure of a conventional building, and FIG. 7 is a cross-sectional view illustrating an interlayer noise preventing structure of a conventional building.

As shown in these figures, the conventional structure for preventing noise between buildings of a building includes an air cap mat-based noise barrier layer 110 installed on the upper surface of the floor slab 201, And a support layer 130 disposed between the air cap mat-based noise barrier layer 110 and the bottom finishing layer 121. [

The air cap mat-based noise preventing layer 110 includes a lower foamed resin layer 117 whose bottom surface is in contact with the upper surface of the bottom slab 201 and a lower air cap mat (not shown) provided to contact the upper surface of the lower foamed resin layer 117 A heat insulating material layer 118 provided so as to be in contact with the upper surface of the lower air cap mat 112; an upper air cap mat 113 provided to contact the upper surface of the heat insulating material layer 118; And an upper foamed resin layer 119 provided so as to be in contact with the upper surface of the upper foamed resin layer 119.

As is well known in the art, the lower air cap mat 112 is formed with a plurality of air caps 114 in a state where two polyethylene sheets are stacked, and the air cap 114 is filled with air.

The air cap 114 is closely protruded over the entire upper surface area of the lower air cap mat 112.

The heat insulating material layer 118 is formed using Expanded PolyPropylene (EPP), Expanded Poly Styrene (EPS), or the like.

The upper surface and the lower surface of the heat insulating material layer 118 are formed in a waffle structure so as to have a plurality of air cap seating grooves 118a.

The upper air cap mat 113 can be manufactured in the same manner as the lower air cap mat 112.

In the upper air cap mat 113, an air cap 114 is closely protruded over the entire area of the bottom surface.

The floor finishing material layer 121 may be formed using a floor or the like as is well known in the art.

The support layer 130 may be formed using a lightweight foamed concrete layer 131, a closed mortar layer 132 or the like as is well known in the art.

Hereinafter, a mechanism for preventing the interlayer noise by the interlayer noise prevention structure of the conventional structure having such a structure will be described.

First, the impact sound generated in the floor finish layer 121 passes through the support layer 130 and reaches the air barrier mat-based noise barrier layer 110.

The impact noise reaching the air barrier mat-based noise barrier layer 110 passes through the upper foamed resin layer 119, and the sound energy decreases.

The impact sound passing through the upper foamed resin layer 119 passes through the air cap 114 of the upper air cap mat 113.

The sound energy is reduced not only through the plurality of record labels generated on the inner surface of the air cap 114 while passing through the air cap 114 of the upper air cap mat 113, Energy is reduced.

The sound energy of the impact sound that has passed through the air cap 114 of the upper air cap mat 113 is reduced again as the acoustic energy passes through the heat insulating material layer 118.

The impact sound passes through the air cap 114 of the lower air cap mat 112 through the heat insulating material layer 118.

The sound energy is reduced not only through the plurality of record labels generated on the inner surface of the air cap 114 while passing through the air cap 114 of the lower air cap mat 112, Energy is reduced.

The sound energy of the impact sound passing through the air cap 114 of the lower air cap mat 112 decreases while passing through the lower foamed resin layer 117.

The structure preventing structure of a conventional structure having the above-described structure is disclosed in Japanese Patent Application No. 72807 (entitled " Interlayer sound insulating sheet having an air hole "

However, according to the structure preventing structure of a conventional structure, since the permeation loss due to the air existing in the air cap 114 of the upper air cap mat 113 and the lower air cap mat 112 is small, Is limited.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an interlayer noise preventing structure and a gas filled air cap mat for an interlaminar noise preventing structure which can increase a sound insulating effect of an air cap mat.

According to the present invention, an air cap is densely protruded over an entire area of one surface of the air cap. When the total volume of the air cap is 100%, the volume of gas having a mass larger than air is 50% And a top mat protective layer disposed on the upper side of the gas-filled air-cap mat, wherein at least one gas-filled air-cap mat is provided on the upper surface of the bottom slab A plurality of mat deformation preventing plates formed on the upper surface of the bottom slab so as to be arranged in a strip shape using the soundproofing layer or the sound insulating material, respectively; An air cap is densely protruded over the entire area of one surface of the air cap. When the total volume of the air cap is assumed to be 100%, a volume of gas having a larger mass than that of air is 50% At least one gas filled air cap mat which is filled in a space between the mat deformation preventing plates and the space between the mat deformation preventing plate and the wall of the building, An air cap mat-based noise barrier layer disposed on an upper surface of the bottom slab, the upper air barrier layer having an upper mat protective layer; A floor finish layer disposed above the air cap mat based noise barrier; And a support layer disposed between the air barrier mat-based noise barrier layer and the bottom finishing material layer.

In order to stably maintain a sound energy reduction effect generated in the air cap, it is preferable that the air cap has an airtight coating layer formed on the outer surface thereof.

In order to prevent damage to the gas-filled air-cap mat, the air-cap mat-based noise barrier further comprises a lower mat-protective layer coupled to the bottom of the gas-fired air-cap mat, And is provided so as to be in contact with the upper surface of the floor slab.

In addition, in order to obtain a sound effect for an impact sound of a wider frequency range, it is preferable that the gas-filled air-cap mats are constituted by a plurality of air cans of different sizes.

In addition, in order to prevent deformation of the lower gas-filled air-cap mat due to the load applied from the upper direction, the gas-filled air-cap mat is composed of a plurality of gaskets; Preferably, the air cap mat-based noise barrier layer further includes a mat support plate sandwiched between the gas-filled air cap mats.

Also, it is preferable that at least one of the gas-filled air-cap mats is installed so as to be folded up along the wall of the building so as to reduce the amount of impact transmitted along the wall of the building.

Therefore, according to the present invention, when the total volume of the inside of the air cap is assumed to be 100%, a gas mixed with air of a mass greater than that of air is filled so that the volume of gas having a mass larger than that of air is 50% It is possible to increase the sound insulation effect of the cap mat (the transmission loss of the sound wave energy increases).

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of a main part of a structure for preventing noise in a building according to an embodiment of the present invention;
2 is a perspective view of a lower gas-filled air cap mat according to an embodiment of the present invention,
3 is a view showing a state where a lower gas-filled air cap mat according to an embodiment of the present invention is installed,
4 is a cross-sectional view showing a main portion of a structure for preventing noise in a building according to another embodiment of the present invention,
5 is a view illustrating a state in which a lower gas-filled air cap mat according to another embodiment of the present invention is installed,
6 is an exploded perspective view showing an interlayer noise preventing structure of a conventional building,
FIG. 7 is a cross-sectional view illustrating a structure for preventing noise in a conventional building. FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a lower-gas-filled air-cap mat according to an embodiment of the present invention. FIG. 3 is a cross- 1 is a view showing a state in which a lower gas-filled air cap mat according to an embodiment is installed.

As shown in these drawings, the structure for preventing noise between buildings of a building according to an embodiment of the present invention includes an air cap mat-based noise preventing layer 10 installed on an upper surface of a floor slab 201, And a support layer 30 disposed between the air cap mat-based noise barrier layer 10 and the bottom coat layer 21. The base coat layer 21 is formed on the top of the noise barrier layer 10,

The air cap mat-based noise preventing layer 10 includes a lower mat protective layer 11 provided so that its bottom surface is in contact with the upper surface of the bottom slab 201 and a lower mat protective layer 11 provided to contact the upper surface of the lower mat protective layer 11. A mat supporting plate 15 provided to be in contact with the upper surface of the lower gas filling air cap mat 12; an upper gas filling air cap mat 13 provided to be in contact with the upper surface of the mat supporting plate 15; And an upper mat protective layer 16 disposed on the upper side of the upper gas filled air cap mat 13. [

The lower mat protective layer 11 is damaged when the lower gas filled air cap mat 12 is damaged by protrusions present in the floor slab 201 when the lower gas filled air cap mat 12 contacts the floor slab 201 For example, polystyrene, nonwoven fabric, or the like.

The air cap 14 is tightly protruded over the entire surface of the lower gas-filled air cap mat 12 and the upper gas-filled air cap mat 13, respectively.

The upper gas-filled air-cap mat (13) is formed with an air cap (14) having a size larger than that of the lower gas-filled air-cap mat (12).

Each air cap 14 is filled with a gas (hereinafter referred to as a "high-mass mixed gas") in which air and a gas having a larger mass than air (hereinafter referred to as "high mass gas") are mixed. Here, when the total volume of the high-mass mixed gas is 100%, it is mixed so that the mass of the mass of the mass larger than air is 50% or more.

As the high-mass gas, carbon dioxide or the like can be used.

The filling of the high-mass mixed gas may be performed by supplying the previously produced high-mass mixed gas in place of the air when forming the air cap 14 as in the prior art (forming a suction groove for forming an air cap on the outer circumferential surface of the forming roller, And a high-mass mixed gas is supplied to the suction groove through a suction net in place of the air. A method for sealing an air cap mat with a high-mass mixed gas in an airtight space, A method of producing a cap mat, and the like.

The air cap 14 has an airtight coating layer formed on its outer surface.

The airtight coating layer can be formed by applying polylactic acid (PLA), polyvinyl chloride (PVC) coating, or the like after the air cap forming process by a jetting method, a dipping method or the like.

The mat support plate 15 is used to stably maintain the state where the lower gas-filled air-cap mat 12 and the upper gas-filled air-cap mat 13 are initially installed along the horizontal direction, and can be manufactured using polystyrene, have.

The upper matte protection layer 16 may be formed of polyurethane foam, PE foam, EVA foam, or the like.

The air barrier mat-based noise barrier layer 10 having such a configuration is provided so that the bottom surface of the lower mat protective layer 11 is in contact with the upper surface of the bottom slab 201. The air cap 14 can be directed downward or upward.

Here, the installation of the air cap mat-based noise barrier layer 10 is performed such that the lower mat protective layer 11 and the lower gas-filled air cap mat 12 are folded up along the wall of the building.

The floor finish layer 21 may be formed using a floor or the like as is well known in the art.

The support layer 30 may be formed using a lightweight foamed concrete layer 31, a finishing mortar layer 32 or the like as is well known in the art.

The mechanism for preventing the interlayer noise according to the interlayer noise prevention structure of a building according to an embodiment of the present invention having such a structure will now be described.

First, the impact sound generated in the floor finishing material layer 21 passes through the support layer 30 and reaches the air barrier mat-based sound barrier layer 10.

The impact sound reaching the air cap mat-based noise barrier layer 10 passes through the upper mat protective layer 16, and the sound wave energy is reduced.

The impact sound that has passed through the upper mat protective layer 16 passes through the air cap 14 of the upper gas filled air cap mat 13. [

Not only the sound energy is reduced through the plurality of record labels generated on the inner surface of the air cap 14 while passing through the air cap 14 of the upper gas-filled air cap mat 13, The air energy is reduced in the process of passing through the air cap 14 of the air bag.

The reduction amount of the sound wave energy generated when the sound wave energy passes through the air cap 14 of the upper gas filled air cap mat 13 is smaller than the amount of the sound air existing in the air cap 14 of the upper gas filled air cap mat 13 (In the conventional case) due to the air having a larger mass of gas than in the air cap 14 (in the conventional case), thereby increasing the transmission loss of the sound wave energy and increasing the sound insulation effect.

The sonic energy of the impact sound that has passed through the air cap 14 of the upper gas-filled air cap mat 13 passes through the mat support plate 15, and the sound energy is reduced again.

The impact sound that has passed through the mat support plate 15 passes through the air cap 14 of the lower gas filled air cap mat 12 and passes through the air cap 14 of the upper gas filled air cap mat 13, The sound energy is reduced.

The sound energy of the impact sound that has passed through the air cap 14 of the lower gas-filled air cap mat 12 is reduced while passing through the mat support layer 30.

In the above-described embodiment, the gas-filled air cap mats (the upper gas-filled air-cap mats and the lower-gas-filled air-cap mats) are provided so as to be continuous over the entire area of the floor slab 201 of the building, Likewise, the present invention can be implemented by a method of dividing the floor slab 201 of a building into a plurality of mat mounting areas and installing a gas filling air cap mat in each mat mounting area.

FIG. 4 is a cross-sectional view of a main portion of a structure preventing noise between buildings of a building according to another embodiment of the present invention, and FIG. 5 is a view illustrating a state in which a lower gas-filled air cap mat according to another embodiment of the present invention is installed.

As shown in these drawings, the structure for preventing noise between buildings of a building according to another embodiment of the present invention includes a plurality of mat deformation preventing plates 40 provided on the upper surface of the bottom slab 201, A floor finishing material layer 21 and a supporting layer 30 having the same structure as the interlayer noise preventing structure of the building according to the embodiment of the present invention described above.

Each of the mat deformation preventing plates 40 is formed in a strip shape using a sound insulating material.

The mat deformation preventing plate 40 is made of a material capable of supporting the load applied from the upward direction. Accordingly, it is possible to prevent the upper gas filled air cap mat 13 and the lower gas filled air cap mat 12 from being deformed by the load applied from the upward direction.

As a material for manufacturing the mat deformation preventing plate 40, a polyurethane foam, a PE foam, an EVA foam, a vibration proof rubber, or the like can be used.

The mat deformation preventing plates 40 having such a configuration are provided on the upper surface of the floor slab 201 so as to be arranged side by side.

The fact that the mat deformation preventing plates 40 are arranged side by side means that when the mat deformation preventing plates 40 are arranged side by side and the section between the mat deformation preventing plates 40 is again divided into a plurality of areas When the plates are arranged in a lattice form).

The air cap mat-based noise preventing layer 10 is provided in a space between the mat deformation preventing plates 40 and between the mat deformation preventing plate 40 and the wall 202 of the building so as to be in contact with the upper surface of the bottom slab 201, An upper gas filled air cap mat 13 and a lower gas filled air cap 13 which are installed in the space between the floor 11 and the mat anti-dripping plate 40 and between the mat anti-dripping plate 40 and the wall 202 of the building, A mat 12 and a mat support plate 15 provided so as to be in contact with the upper surface of the lower gas-filled air-cap mat 12.

The air barrier mat-based noise barrier layer 10 having such a configuration is provided so that the bottom surface of the lower mat protective layer 11 is in contact with the upper surface of the bottom slab 201.

The upper gas-filled air-cap mat (13) and the lower gas-filled air-cap mat (12) are prevented from being deformed by the load applied from the upper direction through the mat deformation preventing plate 13 and the lower gas-filled air cap mat 12 can be stably maintained.

As described above, according to the embodiment of the present invention, when the total volume of the inside of the air cap 14 is assumed to be 100%, the volume of the gas of mass greater than air is 50% The sound absorbing effect of the air cap mat can be increased (the transmission loss of the sound wave energy is increased).

By forming the airtight coating layer on the outer surface of the air cap 14, gas having a mass larger than that of the air existing in the air cap 14 is prevented from leaking to the outside of the air cap 14, ) Can be stably maintained. As the initial shape of the air cap 14 can be stably maintained as described above, it is possible to reduce the sound energy reduction effect through the plurality of record labels generated on the inner surface of the air cap 14, The sound wave energy reduction effect can be stably maintained.

In addition, the bottom mat protective air layer mat (12), that is, the bottom mat protective mat layer (11) is bonded to the bottom surface of the gas filled air cap mat to prevent damage to the gas filled air cap mat.

In addition, by providing a plurality of gas filled air cap mats having different sizes of the air caps, it is possible to obtain a sound effect for impact sound of a wider frequency range (the frequency of the decreasing sound wave energy in each air cap varies).

In addition, by providing the mat support plate 15 between the air filling mats, it is possible to prevent the lower air filling mats 12 from being deformed by the load applied from the upward direction.

Also, at least one of the gas-filled air cap mats may be folded up along the wall of the building to reduce the amount of impact transmitted along the wall of the building.

Further, by adding the mat deformation preventing plate 40, it is possible to stably maintain the sound insulation effect of the upper gas-filled air-cap mat 13 and the lower gas-filled air-cap mat 12.

10, 110: an air cap mat-based noise preventing layer 11: a lower mat protective layer
12: Lower gas filling air cap mat 13: Upper gas filling air cap mat
14, 114: air cap 15: mat support plate
21, 121: floor finish layer
30, 130: support layer 40: mat anti-flow plate
112: lower air cap mat 113: upper air cap mat

Claims (10)

An interlayer noise preventing structure for a building installed on a floor slab of a building,
An air cap is densely protruded over the entire area of one surface of the air cap, and when the total volume of the air cap is 100%, the volume of the air having a larger mass than that of the air is 50% And an upper mat protective layer disposed on the upper side of the gas-filled air-cap mat, wherein the air-mat mat-based noise barrier layer provided on the upper surface of the bottom slab and the at least one gas- ;
A floor finish layer disposed above the air cap mat based noise barrier;
And a support layer disposed between the air barrier mat-based noise barrier layer and the bottom finishing material layer. The method according to claim 1,
Wherein an airtight coating layer is formed on an outer surface of the air cap. 3. The method according to claim 1 or 2,
Wherein the air cap mat-based noise barrier layer further comprises a lower mat protective layer coupled to a bottom surface of the gas-filled air cap mat, wherein a bottom surface of the lower mat protective layer contacts the upper surface of the bottom slab. Structural Noise Suppression Structure. 3. The method according to claim 1 or 2,
Wherein the gas-filled air-cap mats have a plurality of air-cap sizes different from each other. 3. The method according to claim 1 or 2,
Wherein the gas-filled air-cap mat is composed of a plurality of gas-filled air-cap mats;
Wherein the air cap mat-based noise barrier layer further comprises a mat support plate sandwiched between the gas-filled air cap mats. 3. The method according to claim 1 or 2,
Wherein at least one of the gas-filled air-cap mats is folded up along a wall of the building. An interlayer noise preventing structure for a building installed on a floor slab of a building,
A plurality of mat deformation preventing plates formed on the upper surface of the floor slab so as to be formed in a strip shape using sound insulating materials and arranged side by side;
An air cap is densely protruded over the entire area of one surface of the air cap. When the total volume of the air cap is assumed to be 100%, a volume of gas having a larger mass than that of air is 50% At least one gas filled air cap mat which is filled in a space between the mat deformation preventing plates and the space between the mat deformation preventing plate and the wall of the building, An air cap mat-based noise barrier layer disposed on an upper surface of the bottom slab, the upper air barrier layer having an upper mat protective layer;
A floor finish layer disposed above the air cap mat based noise barrier;
And a support layer disposed between the air barrier mat-based noise barrier layer and the bottom finishing material layer. 8. The method of claim 7,
Wherein an airtight coating layer is formed on an outer surface of the air cap. The air cap is densely formed over the whole area of the one surface, and when the total volume of the air cap is 100%, a mass of gas larger than air and air is supplied so that the volume of gas having mass larger than air is 50% Wherein the gas filled with the mixed gas is filled with air. 10. The method of claim 9,
Wherein the air cap has an airtight coating layer formed on an outer surface thereof.

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