KR101381867B1 - A construction method for reducing noise between floors - Google Patents

Abstract

The present invention relates to a method for constructing a floor for preventing an inter-floor noise and cracking in an apartment building. Specifically, the method for constructing a floor for preventing inter-floor noise and cracking in apartment buildings can prevent the cracking of buildings occurred by a huge impact of a weight and prevent a shaking noise by constructing an upper slab capable of being moved to an underlying floor slab.

Description

Floor construction method to prevent floor noise and cracks in multi-family houses {A CONSTRUCTION METHOD FOR REDUCING NOISE BETWEEN FLOORS}

The present invention relates to a floor construction method for preventing floor noise and cracking of multi-unit houses, and in particular, by constructing the upper slab in a microfluidic manner with respect to the foundation floor slab to prevent cracking of the building due to heavy impact and vibration noise. It relates to a floor construction method for preventing noise and cracks between floors of a multi-family house to prevent the damage.

Recently, noise transmission between households such as apartments has become a big problem. There are many causes of noise transmitted from generation to generation in apartments, but floor shocks are the most important.

Floor impact sound is a structure born noise generated when the structure of the building vibrates when an impact is applied to one part of the building, and the air adjacent to the structure vibrates when the building structure vibrates. Therefore, in order to block the floor shock sound, the path through which vibration propagates should be blocked.

In addition, the floor shock sound is directly transmitted sound because the noise generated from the upper floor of the building occupies a considerable proportion of the direct transmission sound transmitted through the floor slab in addition to the structure transmission sound as described above depending on the structure of the building. A countermeasure is also needed.

Conventionally, in order to reduce the interlayer noise of a multi-story building, a sound insulation layer was formed by placing rubber, styrofoam or foamed urethane, etc., between the floor slab 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 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. 1 and 2, the slab 20 is disposed between the mass blocks 30 arranged parallel to the upper surface of the slab 20 at predetermined intervals and between the mass blocks 30. The multi-resonance panel 40 of the rigid material is installed on the upper and left, right and left and vertically divided unit resonant chamber (s), and the flexible material to be laid on the mass block 30 and the multi-resonance panel 40 It is composed of a sound insulating sheet 50 and the finishing layer is installed on the upper surface of the sound insulating sheet 50.

Such a pre-registration technique has a problem that the mass block 30 has a strength greater than the slab strength and has a concrete block or greater strength that is disposed in the longitudinal direction, and thus vibration noise is transmitted to the lower layer.

In addition, since the large impact due to the heavy weight through the mass block 30 is directly transmitted to the slab 20 and the wall 10 there is a problem that causes the crack of the building.

Patent Registration No. 10-0629249

The present invention was created in order to solve the above problems, to prevent the occurrence of cracks in buildings caused by heavy impacts of heavy materials and to improve the transmission of the upper floor vibration to the lower floor than in the conventional inter-floor The purpose is to provide a floor construction method for preventing noise and cracks.

In the present invention to achieve the above object in the floor construction method for preventing floor noise and cracking of the apartment house on the foundation floor slab integrally formed on the wall,

An oil-filled cylinder body, a piston having a through hole through which the oil passes, coupled to the cylinder body in a vertical reciprocating manner, one end integrally connected to the piston, and the other end protruding outside the cylinder body, and a support plate A plurality of damping cylinders having a rod provided and a spring accommodated in the cylinder body and interlocked with the piston to compress or expand;

a) forming an installation groove at a boundary between the wall and the base floor slab;

b) applying an adhesive to the upper surface of the foundation floor slab and installing a dustproof sheet formed of EVA resin;

c) attaching a release sheet to the wall of the installation groove;

d) securing each damping cylinder to the antivibration sheet with the support plates facing upward and the support plates positioned on the same plane;

e) attaching a cushion mat to the upper surfaces of the respective support plates and seating a metal plate on each cushion mat to cover an upper portion of the foundation floor slab;

f) securing a boiler pipe to said metal plate;

g) pouring concrete to the metal plate to form the upper slab by embedding the boiler pipe; and characterized in that it comprises a.

In addition, in the construction method of the present invention, after the step g) characterized in that it further comprises the step of attaching a stretchable border mat to the boundary between the upper slab and the wall.

First, since the upper slab 130 is constructed to be separated from the wall 200 and be movable up and down, even when a large load of impact is applied to the upper slab 130, the impact force is attenuated by the damping cylinder 300, so that the wall 200 ) And the shock vibration to the foundation floor slab 100 can be blocked to minimize the occurrence of cracks.

Secondly, the upper slab 130 is constructed to be separated from the wall 200 and the upper slab 130 is constructed to be supported by the base bottom slab 100 by the damping cylinder 300, thereby being applied to the upper slab 130. Since the shock vibration is blocked from being transmitted through the wall 200 and the foundation floor slab 100, the noise caused by the shock vibration is minimized from being transmitted to the lower floor.

1 and 2 is a schematic diagram illustrating a conventional construction method,
3a to 3d is a flow chart illustrating a construction method of an embodiment of the present invention,
4 is a cross-sectional view illustrating a behavior state when an impact is applied to the upper slab;
5A and 5B are cross-sectional views of an operating state of the damping cylinder.

The construction method of the embodiment of the present invention by constructing the upper slab with respect to the foundation floor slab so as to flow finely to prevent the crack of the building due to the heavy impact of the heavy weight and to minimize the transmission of vibration noise of everyday life to the lower floor.

The construction method of this invention is demonstrated, referring FIG. 3A-FIG. 3D.

Referring to FIG. 3A, first, the installation groove 210 is formed at the boundary between the wall 200 and the foundation floor slab 100. The installation groove 210 is preferably formed at the time of construction of the wall 200 and the foundation floor slab 100.

Subsequently, referring to FIG. 3B, an adhesive is applied to the upper surface of the foundation floor slab 100 and the dustproof sheet 110 formed of EVA resin is attached, and the release sheet 170 is attached to the wall surface of the installation groove 210. Let's do it.

The release sheet 170 may be a styrofoam of about 10mm.

Referring to FIG. 3C, a plurality of damping cylinders 300 are fixed to the dustproof sheet 110 at predetermined intervals.

5A and 5B, the damping cylinder 300 is coupled to the cylinder body 310 filled with the oil 350, and is vertically reciprocated in the cylinder body 310 so that the oil 350 is coupled to the damping cylinder 300. A piston 320 having a through hole 321 formed therethrough, and a rod 330 having one end integrally connected to the piston 320 and the other end protruding outside the cylinder body 310, and having a supporting plate 331. And a spring 340 accommodated in the cylinder body 210 and interlocked with the piston 320 to compress or expand.

The piston 320 is slowed in operation speed by the oil 350 and the spring 340 filled in the cylinder body 310, and the self vibration generated when the spring 340 is contracted and expanded, the oil ( Attenuation).

The cushion mat 360 is attached to the upper surfaces of the support plates 331, and the metal plate 120 is seated on the cushion mat 360 to cover the upper portion of the foundation bottom slab 100.

The metal plate 120 is fixed by installing the boiler pipe 140 in a zigzag. The boiler pipe 140 is used as a flexible material in the part away from the metal plate 120. This is to prevent damage to the metal plate 120 when the microfluidic flow up and down.

Subsequently, referring to FIG. 3D, concrete is poured into the metal plate 120 to form the upper slab 130 while the boiler pipe 140 is embedded.

In this case, the upper slab 130 is separated from the wall 200 by the release sheet 170 in the installation groove 210, and the upper slab 130 is broken of the release sheet 170 formed of a styrofoam material when the upper slab 130 moves up and down. It is possible to behave without friction with the wall 200 due to the like.

After the concrete of the upper slab 130 is cured, the flexible frame mat 160 is attached to the boundary between the upper slab 130 and the wall 200, and the wall 200 and the upper slab 130. Construct a interior finish (not shown).

When the structure constructed as described above is subjected to a large impact load on the upper slab 130, the piston 320 of the upper slab 130, the metal plate 120 and the damping cylinder 300 is lowered, wherein the spring ( The impact is attenuated by the repulsive force of 340 and the resistance of the oil 350 to minimize the transfer to the foundation floor slab 100.

When the upper slab 130 moves up and down, the edge mat 160 is stretched.

4 and 5B, when the piston 320 is lowered in the cylinder body 310, the oil 350 moves to the upper space of the piston body 310 through the through hole 321 of a narrow diameter. The oil height of the lower space in the piston body 310 is gradually lowered and the piston 320 is supported by the repulsive force of the spring 340, thereby making it possible to dampen the impact.

Since the upper slab 130 is constructed so as to be separated from the wall 200 and move up and down, the impact force is attenuated by the damping cylinder 300 even when a large load of impact is applied to the upper slab 130. 200) and the impact vibration to the foundation floor slab 100 can be blocked to minimize the occurrence of cracks.

In addition, the upper slab 130 is constructed to be separated from the wall 200 and the upper slab 130 is constructed to be supported by the base bottom slab 100 by the damping cylinder 300, so that the upper slab 130 Since the applied shock vibration is prevented from being transmitted through the wall 200 and the foundation floor slab 100, the transmission of the shock vibration noise to the lower floor is minimized.

On the other hand, since the boiler pipe 140 is constructed to be fixed to the metal plate 120 having high thermal conductivity, the heating efficiency is improved over the entire upper slab 120.

100 ... Foundation Floor Slab 110 ... Dustproof Sheet
120 ... metal plate 130 ... upper slab
140 Boiler pipe 200 Wall
300 ... attenuation cylinder

Claims (2)

In the floor construction method for preventing floor noise and cracks in a multi-family house on the foundation floor slab integrally formed on the wall,
A cylinder 320 filled with an oil 350, a piston 320 having a through hole 321 coupled to the cylinder body 310 so as to be reciprocated vertically, and having the oil 350 passed therethrough; The piston 320 is integrally connected to the piston 320 and the other end is protruded out of the cylinder body 310 and accommodated in the cylinder body 210 with the rod 330 provided with the support plate 331. A plurality of damping cylinders (300) having springs (340) interlocked with and compressed to;
a) forming an installation groove 210 at a boundary between the wall 200 and the foundation floor slab 100;
b) applying an adhesive to the upper surface of the foundation floor slab 100 and installing a dustproof sheet 110 formed of EVA resin;
c) attaching the release sheet 170 to the wall surface of the installation groove 210;
d) fixing each damping cylinder (300) to the dustproof sheet (110) with the support plates (331) facing upwards and the support plates (331) positioned on the same plane;
e) attaching a cushion mat (360) to the upper surfaces of the support plates (331) and seating a metal plate (120) on each cushion mat (360) to cover an upper portion of the foundation bottom slab (100);
f) fixing the boiler pipe 140 to the metal plate 120;
g) forming concrete on the metal plate 120 to form the upper slab 130 by embedding the boiler pipe 140 to prevent inter-floor noise and cracks in the multi-family house. Floor construction method. The method of claim 1, wherein after the step g) further comprising the step of attaching the flexible frame mat 160 to the boundary between the upper slab 130 and the wall 200 between the floors of the apartment house Floor construction method for noise and crack prevention.

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