KR20100066168A - Noise blocking member of the story partitions forplural story buildings - Google Patents

Abstract

PURPOSE: A noise blocking structure with a hollow layer of a multilayer building is provided to securely block noise and vibration, and to prevent lightweight aerated concrete from being cracked. CONSTITUTION: A noise blocking structure with a hollow layer of a multilayer building comprises a plastic panel(30), an embossed shock absorbing pad(40), a plastic board(50), lightweight aerated concrete(70), finishing mortar(80), and a side shock absorbing member(90). Multiple fitting protrusions(31) are formed in the plastic panel to fit rubber shock absorbers(20). The embossed shock absorbing pad is installed on the top of the plastic panel. The plastic board is installed on the top of the embossed shock absorbing pad. The lightweight aerated concrete is placed on the top of the plastic board. The finishing mortar has hot water pipelines(75). The side shock absorbing member is installed between a wall and a structure.

Description

Noise Blocking Member of the Story Partitions Forplural Story Buildings

The present invention relates to an impact sound blocking structure having a hollow layer of a multi-storey building installed on the floor of each floor in order to block inter-floor noise, vibration, resonance sound, impact sound, etc., which is pointed out as a problem in a multi-storey building such as an apartment.

In order to maximize supply shortage and land use, the demand of houses and offices has increased in recent years, and most buildings such as apartments, officetels, or large office buildings have become high and dense.

Such a high-rise building is integrated with the building structure, so noise and vibration between the upper and lower floors are well communicated, which makes the living experience between residents in the upper floor and the lower floor feel uncomfortable. have.

In particular, in the case of apartment houses, the main living spaces, the walls and floors made of concrete must be shared with neighbors. In the case of such strong concrete, the sound of noises and doors generated in residential life is very strong because of the high vibration and noise transmission by impact. Living noises generated during opening and closing and use of various objects are conveyed to neighbors in an unpleasant manner. On June 30, 2005, the government announced regulations on housing construction standards, etc. To increase the height from 180mm to 210mm and install the cushion floor and the floor thickness of the foundation floor to 150mm or 180mm. Under 50dB of impact sound, floor impact sound is strongly regulated.

Therefore, a countermeasure for solving the noise problem between floors of a multi-storey building is required.

Conventionally, in order to reduce the interlayer noise of a multi-storey building, a sound insulation layer was formed by placing rubber, styrofoam or foamed urethane, etc., between the base bottom layer and the finishing concrete layer of each layer, and placing lightweight foam concrete thereon.

However, the method of the interlayer sound insulation layer as described above is accompanied by a lot of structural defects, such as cracks of the mortar, there was a problem in that the sound insulation effect is not good.

In order to improve this, the applicant has proposed a patent registration No. 10-0741757.

Patent registration No. 10-0741757 (name: interlayer structure of a multi-storey building) is installed between the bottom base layer of the lower layer and the finishing mortar layer of the upper, as shown in Figures 4 and 5 of the accompanying drawings, A heat insulation panel 300 having a predetermined thickness, a panel 100 and a plurality of support members 200 and a plurality of through holes 310 formed therein; It comprises a plurality of buffer members 400 to form a unit structure, the panel 100 is to have a predetermined thickness injection-molded into a rectangular panel shape in which a plurality of mesh holes 110 are punched at regular intervals.

The support member 200 is installed to protrude in the lower portion of the panel 100 to be screw-connected to the panel 100 or to a fixed type injection molded integrally with the panel 100, the heat insulation The panel 300 is installed below the panel 100, and a plurality of through holes 310 are perforated to be fitted to the plurality of support members 200 and to be coupled to each other, and the buffer member 400 is formed in the panel 100. It is preferable to be made of a dustproof rubber material having excellent vibration absorption by being coupled to the end of the support member 200 to be in direct contact with the base bottom layer to support the interlayer structure.

FIG. 5 is a cross-sectional view illustrating a state in which an interlayer structure of a multi-story building having a length adjusting function is applied, and the interlayer structure is constructed between a lower base bottom layer 500 and an upper finishing mortar layer 510.

The interlayer structure includes a panel (100) and a heat insulation panel (300) fitted to the plurality of support members (200) and the support member (200) under the panel (100); The lower side of the heat insulation panel 300 is composed of a buffer member 400 is fitted to be coupled to the end of each support member 200.

The panel 100 has semi-permanent durability and form stability as a resin body resistant to compressive strength and heat change, and has excellent structural stability, and strengthens structural strength by preventing cracks by performing mesh function at the time of finishing mortar. By omitting and constructing the bubble concrete process, it is possible to fundamentally eliminate the occurrence of the lower cracks and deflections of the bubble concrete.

Reference numeral 520 denotes a hot water pipe, and 530 corresponds to a floorboard or floorboard as a floor finishing material.

Such pre-registration technology requires a lot of construction cost due to the increase of the cost for the processing of each part, and it takes a lot of time because it is difficult for the horizontal adjustment as a whole, and consequently, the construction time increases. There was a problem that the shock sound is delivered to the lower layer because the buffer function is not enough.

In the present invention devised to improve the above problems, the construction work is easy, and the buffer layer including various floor impact sounds transmitted between layers with relatively low cost, so as to more reliably block interlayer noise and vibration as a multilayer structure. It is an object of the present invention to provide an impact sound blocking structure having a hollow layer of a multi-layered building to prevent crack formation of lightweight foamed concrete to enable good floor finishing.

In the present invention for achieving the above object is an interlayer structure installed between the base floor layer of the multi-storey building and the finishing mortar layer of the upper, is installed on the upper surface of the base floor layer, rubber at a predetermined interval on the lower side to absorb shock A plastic panel in which a plurality of fitting protrusions for inserting the cushioning material are uniformly arranged and integrally formed; An embossing buffer pad formed on an upper portion of the plastic panel and made of an elastic material so as to have sound absorption and cushioning effects; Is installed on the upper side of the embossed buffer pad, the synthetic resin board to have a heat insulation and sound insulation function; Lightweight foam concrete is poured into a predetermined thickness on the upper surface of the synthetic resin board; Hot water heating pipes are arranged on the upper side of the lightweight foam concrete, the finishing mortar to finish flat including the hot water heating pipes; And a side buffer member installed between the interlayer structure and the wall surface.

In the present invention, between the upper surface of the synthetic resin board and the lightweight foam concrete is characterized in that the coating material to further strengthen the durability of the synthetic resin board is installed.

In the present invention, the rubber cushioning material fitted to the fitting protrusion of the plastic panel is formed so that the fitting hole penetrates the center portion, the edge portion forming a concentric circle around the center portion is formed at a predetermined interval by the space portion, the edge portion It is characterized in that it is formed higher at a constant height than the central portion.

In the present invention, the rubber buffer is a fitting hole and the center and the space portion and the rim portion is provided with the same upper / lower sides are symmetrical structure, characterized in that the buffer groove is formed around the side.

In the present invention, the rubber buffer is durable ethylene propylene rubber (Ethylene Propylene Diene M-class Rubber): 70 to 90 parts by weight; Excellent chloroprene rubber (Chloroprene rubber): characterized by molding by mixing 10 to 30 parts by weight.

In the present invention, the embossed buffer pad is formed on the upper surface of the upper embossing portion of a relatively large standard to form a hollow layer between the synthetic resin board, the lower side resonance sound generated between the base layer and the plastic panel It is characterized in that the lower embossing portion of a relatively small size is formed to absorb and prevent the amplification of the sound.

The present invention is to reduce the material cost by simply reducing the specifications of the plastic panel and the rubber buffer material, and to form the rubber buffer material bonded to the plastic panel in the same shape up and down to facilitate the coupling and field construction work, the rubber The buffering effect is maximized by the space portions formed on the upper and lower portions of the cushioning material, and the shock absorbing effect of the multi-storey building is minimized by the multi-layered structure including the hollow layer.

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

1 is a partial cross-sectional perspective view showing a construction state of the embodiment of the present invention, Figure 2 is a cross-sectional view of the construction state in the embodiment of the present invention.

As shown, in the embodiment of the present invention as an interlayer structure installed between the base bottom layer of the multi-storey building and the finishing mortar layer of the upper layer, the rubber buffer 20, the plastic panel 30, the embossed buffer pad 40 and the synthetic resin The board 50, the covering material 60, the lightweight foam concrete 70, the finishing mortar 80 and the side buffer 90 is composed of.

The plastic panel 30 is installed on the upper surface of the base bottom layer 10, and a plurality of fitting protrusions 31 for uniformly arranging the rubber buffers 20 at a predetermined interval on the lower side to absorb shocks are arranged uniformly. Formed.

The plastic panel 30 forms a plurality of frames in a square or at regular intervals and shapes, forms a circular plate at regular intervals at the intersections of the frames, and has a grid shape having protrusions having a predetermined size at the center of the circular plate.

The fitting protrusion 31 is formed at the lower end of the center of the circular support plate so that the rubber buffer 20 is installed therein so that the load and impact vibration transmitted from the upper part are evenly distributed and transmitted to the adjacent rubber buffer 20. It was.

In addition, the lattice frame structure in which a hole is formed between the frame and the frame has fewer waves due to vibration than the flat panel, and in particular, resonance sound generated by resonance in the space portion between the base bottom layer and the plastic panel 30 is produced by the plastic. Induced by the lower embossing portion 42 formed on the lower side of the embossed buffer pad 40 is installed on the top of the panel 30 to be extinguished so as to block the transmission of the impact sound.

The embossing buffer pad 40 is installed on the upper portion of the plastic panel 30, and made of an elastic material to have a buffering effect, and the synthetic resin board 50, which is weak to local loads and has no buffer restoring force installed on the upper side, has a hard bottom portion. When directly in contact with the plastic panel 30 is to prevent the depression and damage caused by the load of concern, and to reinforce the buffer function.

The embossing buffer pad 40 is formed with a relatively large upper embossing portion 41 on the upper surface so as to form a hollow layer 45 between the synthetic resin board 50, the lower side and the base bottom layer 10 and A relatively small lower embossing portion 42 is formed so as to absorb resonance sound generated between the plastic panels 30 and prevent attenuation of sound.

The embossed buffer pad 40 is preferably made of a synthetic resin such as EPP (Expandable Polypropylene), EPE (Expandable Polyethylene), EVA (Ethylene Vinylacetate), Urethane, etc., which are foamed at a relatively low density so as to have appropriate sound absorption and elasticity.

The synthetic resin board 50 is installed on the upper side of the embossed buffer pad 40, to have a heat insulation and sound insulation.

The synthetic resin board 50 is a board in which polystyrene, (Polystyrene), urethane (Urethane), etc. are foamed at a high density so as to have a high compressive strength, and there is no deformation in load and impact delivered from the top, and excellent insulation and sound insulation.

Between the upper surface of the synthetic resin board 50 and the lightweight foam concrete 70 is provided with a coating material 60 to enhance the durability of the synthetic resin board 50.

The coating material 60 is a non-woven fabric having a rough surface and many pores, and is attached to the upper surface of the synthetic resin board 50 to prevent breakage of the synthetic resin board 50 and in particular, foam concrete that is poured on the upper surface thereof. Prevents cracks during dry curing by increasing the sludge into the pore gaps, and improves the adhesive force between the synthetic resin board 50 and the foamed concrete, thereby providing a sense of unity without peeling and peeling by eliminating heterogeneity between organic and inorganic materials. It is effective to increase warmth and sound absorption.

The lightweight foam concrete 70 is to be poured in a predetermined thickness on the upper surface of the synthetic resin board (50).

The finishing mortar 80 is a hot water heating pipe 75 is arranged on the upper side of the lightweight foam concrete 70, the hot water heating pipe 75 is fixed to a suitable position by the pipe fixing hole 76 and then flat To finish.

Since the finishing mortar 80 can be constructed in a wet manner, it is possible to form a smoother surface finish, and minimize cracking.

In addition, the side buffer material 90 is installed between the interlayer structure and the wall surface 11 to prevent the vibration noise of the bottom surface to be transmitted to the wall surface (11).

3 is a partial cross-sectional perspective view of a rubber buffer applied to an embodiment of the present invention.

The rubber buffer 20 is to be fitted to the fitting protrusion 31 formed on the bottom surface of the plastic panel 30 to prevent direct contact between the base bottom layer 10 and the plastic panel 30 to have a cushioning function. The thickness of the top and bottom is small and the level can be easily adjusted.

The rubber buffer 20 is formed so that the fitting hole 21 penetrates the central portion 22, and the edge portion 24 forming a concentric circle around the central portion 22 is spaced by the space portion 23. To form a floating but the edge portion 24 is formed to be higher than the central portion 22 at a constant height.

In addition, the rubber buffer 20 has a fitting hole 21 and the center portion 22 and the space portion 23 and the edge portion 24 having the same upper and lower sides are the upper and lower symmetrical structure, the side circumference The buffer groove 25 is formed in the.

The reason why it is manufactured with symmetrical structure is to consider the convenience and speed and to attenuate the transmission sound once more in the rubber so that the work can be performed without any distinction between the upper and lower sides when the rubber buffer is inserted into the worker or machine. There is.

The rubber buffer 20 is a durable ethylene propylene propylene (Ethylene Propylene Diene M-class Rubber): 70 ~ 90 parts by weight and excellent dustproof performance Chloroprene rubber (Chloroprene Rubber): molded by mixing 10 ~ 30 parts by weight do.

The rubber buffer 20 is to minimize the height of the upper / lower to reduce the construction cost by saving the use of the rubber raw material as a processing material, and the height is low so that the height of the bottom surface is minimized by the present invention The ceiling height of the room is to be formed so high.

The space portion 23 and the edge portion 24 formed on the upper and lower portions of the rubber buffer 20 and the buffer groove 25 formed around the side were absorbed more easily to double the buffer function.

That is, by allowing the load to be supported only by the edge portion 24 formed higher than the center portion 22, the elastic action of the rubber itself and the shock absorbing by the buffer groove 25 formed around the edge portion 24 are flexible. Is to have elasticity.

The cushioning groove 25 is formed by the elastic action of the rubber buffer 20 has the effect of absorbing shock absorbing step by step as the principle of the spring, the results of the test about 3 ~ 4dB light weight, weight compared to the previous technology Impact sound blocking effect was shown.

Since the fitting holes 21 formed on the upper / lower sides of the rubber buffer 20 are identical to each other without the upper / lower division, the worker is inserted into the fitting protrusion 31 of the plastic panel 30 during the construction work. Make it easier for the user.

As described above, the present invention is the same shape of the rubber buffer material up and down, easy construction work as well as maximize the buffering effect by the space portion formed in the upper and lower, respectively, in particular the portion having a buffer function is made of a multi-layer structure It is to minimize the impact noise of the multi-story building.

As described above, the present invention is a technology for blocking the noise between floors of a multi-storey building, and a multi-storey building is built due to the change of residential culture. It is a technology that is highly applicable to the industry as a technology that makes the living life more quiet and comfortable by minimizing the transmission of impact sound.

1 is a partial cross-sectional perspective view showing a construction state of the embodiment of the present invention.

2 is a cross-sectional view of the construction state in the embodiment of the present invention.

Figure 3 is a partial cross-sectional perspective view of the rubber buffer applied to an embodiment of the present invention.

Figure 4 is a cross-sectional view of the construction state of a conventional multi-story interlayer structure.

Figure 5 is a perspective view of the separated state of the unit panel applied to a conventional multi-story interlayer structure.

* Explanation of symbols for main parts

10: foundation bottom layer 11: wall panel

20: rubber buffer 21: fitting hole

22: center portion 23: space portion

24: edge portion 25: buffer groove

30: plastic panel 31: fitting

40: embossed buffer pad 41: upper embossed portion

42: lower embossed portion 45: hollow layer

50: resin board 60; clothing material

70: lightweight foam concrete 75: hot water heating piping

76: piping fixture 80: finishing mortar

90: side buffer

Claims (6)

An interlayer structure provided between the base bottom layer of a multi-story building and the finishing mortar layer at the top, It is installed on the upper surface of the base bottom layer 10, the plastic panel formed integrally with a plurality of fitting protrusions 31 for uniformly arranged to install the rubber buffer material 20 at a predetermined interval on the lower side to absorb shock ( 30); An embossed buffer pad 40 formed on an upper portion of the plastic panel 30 and made of an elastic material so as to have a sound absorbing and buffering effect; Is installed on the upper side of the embossed buffer pad 40, the synthetic resin board 50 to have a heat insulation and sound insulation function; Lightweight foam concrete 70 is poured into a predetermined thickness on the upper surface of the synthetic resin board (50); Hot water heating pipe (75) is arranged on the upper side of the lightweight foam concrete (70), the finishing mortar (80) including the hot water heating pipe (75) to finish flat; Impact sound blocking structure having a hollow layer of a multi-story building comprising a side buffer (90) installed between the interlayer structure and the wall surface (11). The method of claim 1 Impact sound having a hollow layer of a multi-storey building, characterized in that between the upper surface of the synthetic resin board 50 and the lightweight foam concrete 70 is provided with a coating material 60 to enhance the durability of the synthetic resin board 50 Blocking structure. The method of claim 1, The rubber buffer 20 to be fitted to the fitting protrusion 31 of the plastic panel 30 is The fitting hole 21 is formed to penetrate the central portion 22, and the edge portion 24 forming a concentric circle around the central portion 22 is formed at a predetermined interval by the space portion 23, but the edge portion is formed. 24 is an impact sound block structure having a hollow layer of a multi-story building, characterized in that formed in a higher height than the central portion (22). The method according to claim 1 or 3, The rubber buffer 20 is The upper and lower sides of the fitting hole 21, the center portion 22, the space portion 23 and the edge portion 24 is the upper / lower symmetrical structure, the buffer groove 25 is formed around the side Impact sound blocking structure having a hollow layer of a multi-story building. The method according to claim 1 or 3, The rubber buffer 20 is Durable ethylene propylene rubber (Ethylene Propylene Diene M-class Rubber): 70 to 90 parts by weight; Chloroprene rubber with excellent dustproof performance: Impact sound blocking structure having a hollow layer of a multi-story building, characterized in that molded by mixing 10 to 30 parts by weight. The method of claim 1, The embossing buffer pad 40 is formed with a relatively large upper embossing portion 41 on the upper surface to form a hollow layer 45 between the synthetic resin board 50, The lower side of the multi-storey building, characterized in that the lower embossing portion 42 of a relatively small size is formed to absorb and attenuate the resonance sound generated between the base floor layer 10 and the plastic panel 30 to prevent amplification of sound. Impact sound blocking structure having a hollow layer.

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