KR20160019831A - Noise protection material for noise reduction of between floors and thereof construction method - Google Patents

Abstract

The present invention relates to a noise prevention member between floors and a construction method for preventing noise between floors. Specifically, the noise prevention member between floors includes: a lower sound absorbing insulation material of polyethylene terephthalate (PET) foamed in a thickness of 2 mm or greater; a sound absorbing material metalized or bonded onto the upper part of the lower sound absorbing insulation material and performing a sound absorbing action and a sound absorbing dispersion action by having multiple air cells in a height of at 2 mm or greater, wherein the sound absorbing material is composed of one among polyester (PE), polyvinyl chloride (PVC), and polypropylene; an upper sound absorbing insulation material of PET formed in a thickness of 2 mm or greater, which is metalized or bonded onto the upper part of the sound absorbing material; and a surface material in a separation paper form, which is formed in an aluminum material to perform a heat keeping action and thermal insulation action and is metalized or bonded onto the upper part of the upper sound absorbing insulation material. Therefore, the sound absorbed by the foamed PET lower sound absorbing insulation material is absorbed and dispersed through the air cell and an air path, and a function of the insulation material is also performed by the foamed PET and the air cell. Therefore, the noise prevention member between floors prevents the noise between floors and is used as construction materials with excellent thermal insulation features.

Description

TECHNICAL FIELD [0001] The present invention relates to a noise preventing material for a floor,

The present invention relates to an interlayer noise preventing material and a method for preventing interlayer noise by using the same. Particularly, the sound absorbed by the foamed poly (ethylene terephthalate) bracing insulator is absorbed and dispersed through the air cell and the vent path, The present invention also relates to an interlayer noise preventing material and a method for preventing interlayer noise by using the same as a building material having excellent heat insulating function as well as preventing interlayer noise because the function of the heat insulating material is also made parallel by the polyterephthalate.

Generally, floor impact sound in apartments, especially apartment buildings, is classified into two types, namely, weak impact sound and strong impact sound. Weak sound such as sound of falling light objects such as spoons and slipper sound can be absorbed by existing structure There is no problem, but the strong impact sound that occurs when the children are running is transmitted to the lower level as it is, so the residents frequently provide the cause of the dispute.

In order to prevent the interlayer noise of such a dwelling unit, it is conceivable to increase the thickness of the cement slab layer connected to the lower layer. However, when the thickness of the slab layer is increased, the load of the dwelling unit itself increases, The construction cost must be increased. As a result, there is a problem that the construction cost is increased.

Therefore, a method of using a sound insulating sheet made of synthetic resin or the like is proposed as a method for preventing the interlayer noise of the cement house while maintaining the thickness of the cement slab layer connected to the lower layer.

However, in the case of such a soundproof synthetic resin flooring material, if the thickness is thin, the desired purpose can not be achieved, and if the thickness of the flooring material is increased to such an extent that the desired purpose can be achieved, And the thickness of the flooring material is thinly pressed by the load of the furniture or the like located after a long period of time, so that the desired purpose can not be achieved.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a sound absorbing material using a synthetic resin material that maximizes the effect of absorbing and dispersing noise while sufficiently supporting the load of an object placed on the floor, The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an interlayer noise preventing material and a method for preventing interlayer noise by using the same.

The above-mentioned object is achieved by a lower sound-absorbing thermal insulator 102 made of polyethylene terephthalate (PET) foamed and molded to a thickness of at least 2 mm or more; A plurality of air cells 105 are formed at a height of at least 2 mm or more on the upper portion of the lower sound absorption heat insulating material 102 to have sound absorbing dispersion and buffering action, A cushioning material 104 made of one material selected from the group consisting of polyvinyl chloride (PVC) and polypropylene (PP); An upper sound absorbing thermal insulator 106 made of polyethylene terephthalate (PET) that is vapor-deposited or bonded to the upper portion of the cushioning material 104 and foam-molded to a thickness of at least 2 mm; And a surface material (108) in the form of a peeled sheet made of aluminum to be vapor-deposited or adhered to the upper portion of the upper sound insulating material (106) do.

The lower surface of the buffer material 104 has a planar base film 104a and the lower surface of the intermediate film 104c having a plurality of cylindrical air pipes 104b formed on the upper surface of the base film 104a is adhered or deposited The lower surface of the flat finish film 104d is adhered or deposited on the upper portion of the air pipe 104b to form the air cell 105 and the air passage 105e is formed between the air cell 105 and the air cell 105, ) Is preferably formed.

Meanwhile, the above-mentioned object is achieved by a method of manufacturing an electronic device, comprising the steps of: attaching an interlayer insulating material 110 to an upper portion of a slab 202; A plurality of piping slots 204 and a plurality of structural reinforcement grooves 206 for reinforcing the structure are installed on the upper part of the inter-layer noise preventing member 110 so as to pipe a heating pipe (not shown) A step of attaching and fixing the heat block 208 formed with the heat block 208; A groove 210a is formed to be convex downward to be inserted into the pipe slot 204 of the heat block 208 and a pipe to be inserted into the upper portion of the heat block 208. A heat conductive plate 210 having a plate material integrally formed to increase the thermal conductivity ; ≪ / RTI > Piping the pipe to the desired structure using the groove 210 of the heat conduction plate 210 or the pipe slot 204 along the shape of the pipe slot 204 of the heat block 208; Installing an iron plate (212) on the upper part of the heat block (208) piped by the pipe to increase the thermal conductivity; And installing a floor material (214) on the upper portion of the steel plate (212) to finish the finishing work.

Here, it is preferable that at least one of the loess and the elbow is filled in the structural reinforcing groove 206 of the insulating block 208.

The present invention adopts a noise preventive material made of a synthetic resin without forming a thick slab structure, and the weight of the weight body can be supported by a plurality of air cells, so that the thickness of the flooring material is thinly pressed by the load of furniture, To ensure the reliability of the interlayer noise-proofing material and to enable long-term use, and to improve sound insulation and dispersion effect of the surface material of aluminum material and the upper and lower sound-absorbing insulation material of air cell and PET material, It is possible to prevent the interlayer noise while improving the heat insulation effect.

1 is an exploded perspective view showing a structure of an interlaminar soundproofing material according to the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for preventing an interlaminar noise by using an interlaminar soundproofing material according to the present invention.

The structure of the present invention will be described with reference to FIGS. 1 and 2. FIG.

As shown in FIG. 1, an interlayer-noise-insulating material 110 according to the present invention includes a lower bump insulating material, a buffer material 104, an upper sound absorbing thermal insulator 106, and a surface material 108, .

The lower sound absorption heat insulating material 102 is formed by foaming polyethylene terephthalate (PET). In the present invention, it is required to foam at least a thickness of 2 mm or more to have sound absorption and heat insulation effect, The lower sound absorption heat insulating material 102 in the present invention is preferably formed to have a thickness of at least 2 mm or more.

The cushioning material 104 made of any one of polyester (PE), polyvinyl chloride (PVC), and polypropylene (PP) is adhered or deposited on the upper surface of the lower bump insulating material At this time, a plurality of air cells 105 are formed at a height of at least 2 mm or more so that the sound absorbing dispersion and the buffering action can be smoothly performed.

Here, the structure of the cushioning material 104 will be described. The lower surface of the cushioning material 104 is composed of a flat base film 104a. On the upper surface of the base film 104a, a cylindrical or dome- the lower surface of the intermediate film 104c having a plurality of air pipes 104b having a structure of a plurality of air pipes 104b is attached or deposited.

The lower surface of the flat finish film 104d is attached or deposited on the upper portion of the air pipe 104b so that the air pipe 104b can be formed into the air cell 105. [

At this time, a ventilation passage 104e communicating with the air cell 105 is formed between the air cell 105 and the air cell 105 so that the noise is dispersed along the ventilation path 104e, The external air or cool air passes through the medium of the air filled in the air cell 105, and the temperature of the air The conduction time can be delayed.

Accordingly, the interlaminum silencer 110 according to the present invention absorbs noise, disperses and eliminates noise, and delays the conduction time of heat or cold depending on the external environment, thereby improving the function as a heat insulator.

Here, the air cell 105 of the cushioning member 104 must be formed at a height of at least 2 mm or more to be able to support the weight of the cushioning member 104 while being compressed and resiliently compressed when the weight is placed on the upper part.

If the air cell 105 is formed with a height of less than 2 mm, the decompression ability of the air cell 105 after being compressed by the upper load is lowered. In this case, the base film 104a and the finish film 104d are in contact with each other.

According to the present invention, one air cell 105 can elastically support a weight of about 5 kg, and as shown in FIG. 1, since a plurality of such air cells 105 are repeatedly formed at regular intervals, The load of most equipment or furniture is elastically supported by the plurality of air cells 105, so that the conventional problem that the interlayer noise-reducing member 110 is entirely compressed and thus the function is not performed can be solved will be

After the cushioning material 104 is deposited or adhered to the lower sound insulating heat insulating material 102 as described above, the upper sound absorbing thermal insulating material 106 having the same molding conditions as the lower sound absorbing thermal insulating material 102 is formed on the upper surface of the cushioning material 104, The upper surface of the upper sound absorbing and thermal insulating material 106 is deposited or adhered to the upper surface of the upper sound absorbing and thermal insulating material 106 by evaporating or adhering the surface material 108 in the form of a ridged sheet made of aluminum so as to maintain the heat insulation effect and the heat insulating effect as shown in FIG. It is one structure.

That is, after the above-described interlaminar noise preventing member 110 is attached to the upper part of the slab 202, a wire mesh is installed, and a heating pipe is piped to the upper part of the slab 202, The noise generated from the upper and lower portions of the interlaminus noise insulating material 110 is primarily absorbed by the lower sound absorbing thermal insulating material 102 and the upper and lower sound absorbing thermal insulating materials 102 After passing through the base film 104a or the finish film 104d of the cushioning material 104 and passing the noise through the air cell 105, The noise canceling effect can be maximized.

Since the surface material 108 of the interlaminsof noise preventing member 110 is made of an aluminum material, when the heat generated in the heating pipe is to be conducted to the lower portion of the slab 202, a primary heat insulating function is exhibited, The heat of the upper and lower sound-absorbing and thermal insulating materials 102 is formed by foaming the PET, so that the sound absorbing and heat transfer of the cold air of the slab 202 to the upper portion is exerted. Thereby preventing the heat of the heating-use heat from being offset from the cooling air of the slab 202, thereby maximizing the heating efficiency.

The method for preventing noise between layers using the interlaminsof noise preventing member 110 according to the present invention will be described with reference to FIG.

As shown in FIG. 2, the step of attaching the interlaminar noise preventing member 110 shown in FIG. 1 to the upper part of the slab 202 is performed, so that the cold or heat transmitted from the lower part of the slab 202 is delayed as much as possible So that an insulation effect can be obtained.

As described above, since the interlayer-noise-reducing material 110 has the function of absorbing and dispersing noise as described above, noise transmitted from the lower portion of the slab 202 to the upper portion and noise transmitted from the upper portion of the slab 202 to the lower portion So that noise generated between the layers can be dispersed or erased.

A plurality of piping slots 204 and a plurality of piping slots 204 for reinforcing the structure are installed on the upper part of the inter-layer noise preventing member 110 attached to the slabs 202 so as to pipe the heating pipes in a U- A step of attaching and fixing the heat insulating block 208 in which the reinforcing groove 206 is formed is performed.

The plurality of pipe slots 204 are formed in a straight or bent shape in various shapes by protruding upward in a quadrilateral arc shape, a semicircle, and an ellipse in the insulating block 208, 204 is such that the installer can freely pipe the pipe as shown in Fig.

In this case, it is preferable that the structure reinforcing groove 206 of the heat block 208 is filled with a material for generating far-infrared rays, which is beneficial to the human body, such as yellow clay or elvan, so that the heat efficiency can be increased while being eco-friendly.

As shown in FIG. 2, the preheating operation of inserting a pipe into the pipe slot 204 of the heat block 208 is performed by providing a heat conduction path 210 having a groove 210a which is convex downward and can be inserted into a pipe, The heat conduction plate 210 for inserting the plate 210 is installed so that the heat of the heating medium passing through the pipe can be spread rapidly to the periphery of the pipe and can be rapidly conducted.

As shown in FIG. 2, the heat conduction plates 210 may be provided on the entire upper portion of the heat block 208, but they may be spaced apart from each other at regular intervals. Therefore, the present invention is not limited thereto. Adoption may be changed.

After the heat conduction plate 210 is installed as described above, a step of piping the heating pipe to the groove 210a or the pipe slot 204 of the heat conduction plate 210 to a desired structure is performed.

The iron plate 212 shown in FIG. 2 is disposed at the upper part of the heat block 208 to which the pipe is piped, in order to raise the thermal conductivity. It is proper that a plurality of iron plates 212 are installed substantially and a floor material 214 such as wood and stone is also applied to the upper portion of the iron plate 212 However, it is proper that a plurality of flooring members 214 are practically installed, which is usually constructed, so that the present invention is simplified.

As a result, the present invention accomplishes the interlayer noise prevention construction method by performing the step of constructing and finishing the block member 214.

Therefore, when the above-mentioned interlaminsof noise preventing member 110 is attached to the upper portion of the slab 202, the noise generated in the upper and lower portions of the interlaminumon noise preventing member 110 is higher And the noise passed through the upper and lower sound absorption heat insulating materials 102 is again passed through the base film 104a or the finish film 104d of the cushioning material 104 and then to the air The sound transmission is delayed secondarily, and is dispersed and erased along the air passage 104e, thereby maximizing the noise shielding effect.

Since the surface material 108 of the interlaminsof noise preventing member 110 is made of aluminum, when heat generated in the heating pipe is to be conducted from the lower portion of the heat insulating block 208 to the lower portion of the slab 202, Since most of the heat is transferred to the upper part to increase the heating efficiency and the upper and lower sound absorption heat insulating materials 102 are formed by foaming PET, the cooling air of the slab 202 is not only absorbed, The heating efficiency of the heating-use five can be maximized by preventing the heat of the heating-use heat from being offset from the cooling air of the slab 202. [

102: lower bump insulating material 104: buffer material
105: air cell 106: upper bump insulator
108: surface member 110: interlayer noise preventing member
202: Slab 204: Plumbing slot
206 Structural reinforcement groove 208: Insulation block
210: heat conduction plate 212: iron plate

Claims (4)

A lower sound-absorbing thermal insulator 102 made of polyethylene terephthalate (PET) foamed to a thickness of at least 2 mm;
A plurality of air cells 105 are formed at a height of at least 2 mm or more on the upper portion of the lower sound absorption heat insulating material 102 to have a sound absorbing dispersion and a buffering action and are made of polyester A cushioning material 104 made of one material selected from the group consisting of polyvinyl chloride (PVC) and polypropylene (PP);
An upper sound absorbing thermal insulator 106 made of polyethylene terephthalate (PET) that is vapor-deposited or bonded to the upper portion of the cushioning material 104 and foam-molded to a thickness of at least 2 mm;
(108) in the form of a ridged leaf made of an aluminum material to be deposited or adhered to the upper part of the upper sound absorbing thermal insulating material (106) so as to perform thermal insulation and thermal insulation action. The method according to claim 1,
The lower surface of the cushioning material 104 is formed with a planar base film 104a and a lower surface of the intermediate film 104c having a plurality of cylindrical air pipes 104b formed on the upper surface of the base film 104a is adhered or deposited A lower surface of the flat finish film 104d is attached or vapor deposited on the upper portion of the air pipe 104b to form an air cell 105. An air passage 104e communicating with the air cell 105 and the air cell 105 (110). ≪ / RTI > (110) according to claim 1 to the upper portion of the slab (202);
A plurality of piping slots 204 and a plurality of structural reinforcement grooves 206 for reinforcement of structure are formed on the upper part of the interlayer noise attenuating material 110 so as to pipe the heating pipe in a U shape or a shape like "(208);
A groove 210a is formed to be convex downward to be inserted into the pipe slot 204 of the heat block 208 and a pipe to be inserted into the upper portion of the heat block 208. A heat conductive plate 210 having a plate material integrally formed to increase the thermal conductivity ; ≪ / RTI >
Piping the pipe to the desired structure using the groove 210 of the heat conduction plate 210 or the pipe slot 204 along the shape of the pipe slot 204 of the heat block 208;
Installing an iron plate (212) on the upper part of the heat block (208) piped by the pipe to increase the thermal conductivity;
And a floor material (214) is installed on the upper part of the steel plate (212). The method of claim 3,
Wherein the structure reinforcing groove (206) of the heat insulating block (208) is filled with at least one of a loess and a quartz stone.

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