KR101207288B1 - Isolating structure for floor to floor impact sound of apartment buildings and construction method - Google Patents

Abstract

The present invention forms an air layer on the floor between floors to block noises, vibrations, resonance sounds, impact sounds, etc., which are transmitted between floors when building a wet floor structure such as an apartment. It relates to the blocking structure and its construction method, which has the effect of cushioning by the air layer formed by the EPE mesh net and the elastic foam polystyrene buffer board to minimize the impact noise of the multi-storey building, and to shorten the construction air and reduce the cost. have.

Multi-storey building, noise between floors, EPE mesh, elastic foam polystyrene buffer board, lightweight foam concrete, finishing mortar

Description

Structure of floor impact sound interception of apartment building and its construction method {ISOLATING STRUCTURE FOR FLOOR TO FLOOR IMPACT SOUND OF APARTMENT BUILDINGS AND CONSTRUCTION METHOD}

The present invention relates to blocking the floor impact sound of a multi-family house such as an apartment, and more particularly, an interlayer floor to block noises, vibrations, resonance sounds, impact sounds, etc., which are transmitted between floors of a multi-family house constructed with a wet floor structure. The present invention relates to an interlayer floor impact sound blocking structure of a multi-family house in which an air layer is formed on a surface to absorb and block impact sounds, and a construction method thereof.

The urban buildings are becoming higher and denser in order to solve the housing shortage caused by the concentration of the population and to make efficient use of the land.

In other words, in order to maximize supply shortage of land and land use, as the demand of houses and offices has recently increased, most buildings such as apartments, officetels, or large office buildings, such as apartment houses, are becoming higher and denser.

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, due to the uniqueness of apartments that share walls and floors, various noises from neighbors, especially children's thumping and dropping objects, and the noise of floor shocks, such as the noise of walking, are causing great damage to residents. .

In particular, in the case of apartment houses, the main living spaces, the walls and floors made of concrete must be shared with the neighbors. In the case of the strong concrete, the vibration and noise transmission by the impact is very strong, so children play in the residential life. Sounds, dropping objects, walking sounds, and living noises generated when opening and closing doors and various objects are transmitted to neighbors, giving them unpleasant feelings, and sound insulation has now emerged as an important factor in determining residential performance.

For this reason and background, the government enacted the performance standard for the floor impact sound of MDU by revising the regulations on the housing construction standard in April 2003, and from April 23, 2004, the floor construction of the floor impact sound reduction structure for the MDU This is mandatory.

However, despite these regulations and enforcement, their effectiveness is insignificant due to the problems of interlayer noise technology and economic efficiency compared to the effect of multi-story buildings.

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 floor layer and the finished concrete layer of each layer, and placing lightweight foam concrete thereon.

However, the method of the interlayer sound insulation layer as described above has a problem that is not good in sound insulation effect.

Patent registration No. 10-0629249 has been disclosed as a pre-registered technology related to the impact sound block structure of a multi-family house.

Patent Registration No. 10-0629249 (name: inter-floor impact sound blocking structure of the multi-family house) is to support the load of the multi-layer multi-family house through the structural wall 10 and the slab 20, as shown in FIG. Applied to the floor of the multi-family house designed in a wall structure, and positioned between the plurality of mass blocks 30 and parallel to the upper surface of the slab 20 at a predetermined interval, and the mass blocks 30 The multi-resonance panel 40 of the rigid material is installed on the slab 20 and has a unit resonance chamber (s) divided into the front, rear, left and right and up and down, the mass block 30 and the multi resonance panel 40 It is composed of a sound insulating sheet 50 of the flexible material to be laid on the top, the finishing layer is installed on the upper surface of the sound insulating sheet 50.

Since the pre-registered technology needs to install the multi-resonance panel 40 and the sound insulation sheet 50 and a plurality of mass blocks 30 separately, the construction cost is increased due to the increase of the component cost, thereby substantially increasing the construction cost. This situation is not widely used.

In particular, the mass block 30 is a concrete block having a strength greater than slab strength and a long lengthwise arrangement as a means for increasing the mass and reducing the rigidity of the floor structure while maintaining the existing framework system and the finishing system. In addition, the sound insulation function is reduced due to the transmission phenomenon of noise and vibration through the intensity of the above, there was a problem that the impact sound is transmitted to the lower layer.

In the present invention for improving the above problems, the construction work is very easy, with a relatively low cost to block various inter-layer noise and vibration transmitted between the floors, and prevent the formation of cracks of lightweight foam concrete, good floor finishing construction The purpose of the present invention is to provide an interlayer floor impact sound blocking structure and a construction method thereof for enabling this.

In the present invention for achieving the above object is to be installed on the upper surface of the base floor layer of the multi-storey building, having a uniform network structure to absorb the shock and noise transmitted from the top to uniformly distribute the air layer of a certain thickness EPE mesh network; An elastic foamed polystyrene buffer board having a nonwoven fabric attached integrally to an upper surface thereof and installed on an upper portion of the EPE mesh net; Lightweight foam concrete is poured into a predetermined thickness on the upper surface of the elastic foam polystyrene buffer 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; The EPE mesh net, elastic foam polystyrene buffer board, lightweight foam concrete, and includes a side buffer material installed between the finishing mortar and the wall surface.

In the present invention, the non-woven fabric attached to the elastic foam polystyrene buffer board is characterized in that the polypropylene non-woven fabric (Polypropylene non-woven fabric) having a waterproof coating layer on one side.

In the present invention, the EPE mesh network is characterized in that the construction to absorb the impact and noise transmitted from the upper by stacking two layers of EPE mesh sheet having a net structure of a certain standard.

The construction process of the present invention includes a side buffer installation step of attaching the EPE side buffer material with one side adhesive bonding treatment in accordance with the height of the finishing mortar height of the wall portion adjacent to the foundation floor layer of the multi-storey building; An EPE mesh network installation process having a net structure of a predetermined standard so as to absorb shocks and noises transmitted from the upper part by uniformly distributing an air layer having a predetermined thickness on the upper surface of the base bottom layer of the multi-story building after installing the side buffer member; An elastic foamed polystyrene buffer board installation step of installing an elastic foamed polystyrene buffer board on the EPE mesh network sheet by the mesh network layer installation process; A lightweight foam concrete placing step of pouring lightweight foam concrete to a predetermined thickness on an upper surface of the elastic foam polystyrene buffer board; Hot water heating pipes are arranged on the upper side of the light-weight foam concrete, and includes a finishing mortar placing process for finishing the finishing mortar flat including the hot water heating pipes.

The elastic foamed polystyrene buffer board applied to the present invention is a foam polystyrene (EPS) bead method of the excellent thermal insulation grade, there is no degradation of the thermal insulation performance over time, the EPE mesh network applied with this facilitates the construction In addition to shortening the construction air, it also significantly reduces the cost, and has a relatively good cushioning effect to reduce the noise between the floors of the apartment house.

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

1 is a construction process diagram of the floor impact sound interception structure according to an embodiment of the present invention can be divided into a side buffer installation process and EPE mesh network installation process and elastic foam polystyrene buffer board installation process and lightweight foam concrete pouring process and finishing mortar casting process. .

The side buffer installation process is to block the impact and noise transmitted through the wall surface 110, one side of the adhesive bond treatment in accordance with the construction mortar construction height line of the wall surface 110 adjacent to the base floor layer 100 of the duplex building. The side buffer material 170 made of expanded polyethylene (EPE) is to be attached to a certain height.

EPE mesh network installation process is a part that is in direct contact with the base floor layer 100 and is a very important part for the function of blocking the impact noise, which requires attention to be uniformly installed evenly. The air layer of a predetermined thickness is uniformly distributed on the top surface of the bottom layer 100 to install an EPE mesh network 120 having a net structure of a predetermined size so as to absorb the shock and noise transmitted from the top.

The EPE mesh network installation process is to install the mesh sheet 5mm in close contact with the bottom surface, and the joint area between the sheets to prevent the occurrence of gaps by using a tape, etc., and then stacked by installing the same mesh sheet 5mm in different directions The gap between the sheets should be avoided by using a tape or the like.

That is, it is more preferable to laminate | stack and install a mesh type sheet in double.

The elastic foam polystyrene buffer board installation process is to install the elastic foam polystyrene buffer board 130 on the EPE mesh net sheet 120 by the mesh network layer installation process, so that the gap is not necessarily generated by using an OPP tape. shall.

The OPP tape should be in close contact with the waterproof layer of the nonwoven fabric 131 attached to the upper surface of the elastic foam polystyrene buffer board 130 to prevent the foam concrete from penetrating during the pouring of the lightweight foam concrete 140 which is the next process. do.

In addition, the gap between the wall 110 and the OPP tape should be used to prevent the occurrence of airborne concrete when penetrating the lightweight foam concrete 140.

The lightweight foam concrete placing process is a process of pouring the lightweight foam concrete 140 to a predetermined thickness on the upper surface of the elastic foam polystyrene buffer board 130.

In the finishing mortar placing process, the hot water heating pipe 150 is arranged on the upper side of the light-weight foam concrete 140, and includes a hot water heating pipe 150 to finish the finishing mortar 160 flat. Finishing process.

Figure 2 is a partial cross-sectional perspective view showing a construction state of the embodiment of the present invention, Figure 3 is a front sectional view of the construction state in the embodiment of the present invention, Figure 4 is an embodiment of the present invention Partial perspective view of an EPE mesh network with applied mesh structure.

Embodiment of the present invention is to be installed on the upper surface of the base floor layer 100 of the multi-storey building, the embodiment of the present invention is EPE mesh net 120 and elastic foam polystyrene buffer board 130 and lightweight foam concrete 140 and Finish mortar 160 and the side buffer 170 as a component.

The EPE mesh network 120 is a mesh sheet having a mesh structure of a predetermined size to absorb a shock and noise transmitted from the top to uniformly distribute the air layer of a predetermined thickness.

The EPE mesh network 120 is constructed so as to absorb the impact and noise transmitted from the top by stacking the EPE mesh sheet having a net structure of a predetermined standard in two layers in different directions.

That is, the EPE mesh net 120 is preferably stacked in two layers so that the mesh nets overlap each other to have a more uniform and stable buffering effect.

The elastic foam polystyrene buffer board 130 is to be placed on the upper surface of the light foam aerated concrete 140, and installed on top of the EPE mesh net 120 to evenly distribute the impact, the non-woven fabric on the upper surface 131 is integrally attached.

The non-woven fabric 131 attached to the elastic foam polystyrene buffer board 130 is a polypropylene non-woven fabric having a waterproof coating layer on one side thereof, which prevents the penetration of moisture to the lower side during the construction of wet concrete. It has a shock absorbing function.

The lightweight foam concrete 140 is to be poured in a predetermined thickness on the upper surface of the elastic foam polystyrene buffer board 130.

The finishing mortar 160 is to arrange the hot water heating pipes 150 at regular intervals on the upper side of the light-weight foam concrete 140 and cast them thereon, including the hot water heating pipes 150 to finish flat will be.

The side buffer material 170 is installed between the interlayer structure and the wall surface 110 to block the shock vibration through the wall surface.

As described above, the present invention expands and installs the EPE mesh net 120 on the upper surface of the base bottom layer 100, and then installs the elastic foam polystyrene buffer board 130 thereon, but the upper surface of the elastic foam polystyrene buffer board 130 is A polypropylene non-woven fabric having a waterproof coating layer is attached to the upper side, and the foamed concrete is formed when the lightweight foamed concrete 140 is poured by preventing the gap from occurring using the OPP tape. By preventing the penetrating phenomenon to prevent the penetration of water to the lower side will have a more clear shock absorbing function.

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 construction process diagram of the interlayer floor impact sound blocking structure according to an embodiment of the present invention.

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

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

4 is a partial perspective view of an EPE mesh network having a network structure applied to an embodiment of the present invention.

5 is a cross-sectional view of a construction state of a conventional multi-story interlayer structure.

Figure 6 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

100: foundation bottom layer

110: wall 120: EPE mesh

130: elastic foam polystyrene buffer board 131: nonwoven fabric

140: lightweight foam concrete 150: hot water heating piping

160: finish mortar 170: side buffer

Claims (4)

To be installed on the upper surface of the base bottom layer 100 of the multi-storey building, An EPE mesh network 120 having two layers of an EPE mesh sheet having a net structure of a predetermined size so as to uniformly distribute an air layer having a predetermined thickness to absorb shocks and noises transmitted from the top; It is installed on top of the EPE mesh net 120, the elastic foamed polystyrene buffer board 130, the polypropylene non-woven fabric (131) having a waterproof coating layer on one side is integrally attached to the upper surface Wow; After the OPP tape is attached to the connection portion of the elastic foam polystyrene buffer board 130, the lightweight foam concrete 140 is cast in a predetermined thickness on the upper surface of the elastic foam polystyrene buffer board 130; Hot water heating pipe 150 is arranged on the upper side of the lightweight foam concrete 140, the finishing mortar 160 including the hot water heating pipe 150 to finish flat; The EPE mesh net 120, the elastic foam polystyrene buffer board 130, lightweight foam concrete 140 and the finishing mortar 160 and the side cushioning material 170 is installed between the wall surface 110 of the apartment house Interlayer floor impact sound blocking structure. delete delete A side cushioning material installation process of attaching a side buffer material 170, one side of which is adhesive bonded, to the finishing mortar construction height line of the wall surface 110 adjacent to the foundation floor layer 100 of the multi-story building; After installing the side cushioning material, the air layer of a certain thickness is uniformly distributed on the upper surface of the base bottom layer 100 of the multi-storey building to double the EPE mesh sheet having a mesh structure of a certain standard so as to absorb the shock and noise transmitted from the top. An EPE mesh network installation process of installing the cross-laminated EPE mesh network 120; On the EPE mesh network 120 by the mesh network installation process, an elastic foamed polystyrene buffer board 130 in which a polypropylene non-woven fabric 131 having a waterproof coating layer on one side is integrally attached to the upper surface. Elastic foam polystyrene buffer board installation step of installing; After the OPP tape is attached to the connection portion of the elastic foam polystyrene buffer board 130, the lightweight foam concrete pouring process of pouring the lightweight foam concrete 140 to a predetermined thickness on the upper surface of the elastic foam polystyrene buffer board 130; ; Hot water heating pipe 150 is arranged on the upper side of the lightweight foam concrete 140, including the hot water heating pipe 150, including a finishing mortar pouring process to finish the finishing mortar 160 flat Construction method of interlayer floor impact sound insulation

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