KR101953900B1 - Structure for preventing noise in floor - Google Patents

Abstract

The present invention provides a structure for preventing noise between floors in an apartment house. The structure for preventing noise between floors in an apartment house comprises: a slab layer forming a floor layer of each household of an apartment house; a pipe layer formed on the slab layer, wherein heating pipes in which heater water is circulated are installed; a shock absorbing layer arranged on the pipe layer, and having holes on a grid; and a noise removing layer arranged on the shock absorbing layer, and removing noise when the noise occurs in a plurality of places by an external shock.

Description

{Structure for preventing noise in floor}

More particularly, the present invention relates to an inter-apartment sound insulation structure for a building, which is capable of discharging noise caused by an impact generated in an indoor floor of each household of the apartment house to the outside.

Generally, when constructing a slab of a flat such as an apartment, it is necessary to horizontally form a mold, to place reinforcing bars thereon, to pour concrete, to place a foamed polystyrene, a floor cushioning member, a film, Mesh is laid on it, heating piping is installed on the top, and mortar is cemented to finish.

As such, the slab separating the layers and the layers of the multi-layered multi-layer buildings such as apartment buildings and high-rise buildings is constructed only by concrete, so that the vibration due to the noise and impact generated in the corresponding layer of the building is transmitted to the lower layer directly through the interlayer slab do.

The impact sound applied to the building structure of apartment houses and villas is transmitted to all directions due to the impact of the person's walking, opening and closing of the door, moving of the equipment, operation or stop of the equipments, This causes not only the surface of the building structure to be vibrated, but also to be perceived as noise when it is called by the air transmission sound and can be heard by people around the ear.

Particularly, in the case of a building to be constructed nowadays, the improvement of the sound insulation of the building is considered more than improvement of the heat insulation property. In the past, the goal was to construct buildings with heat insulation and heat resistance that would reduce the cost of warm and comfortable buildings, heating costs that occur naturally during the summer and winter, and so on. However, in the case of the Republic of Korea where collective residence is common, such as apartments, the number of residents suffering from the interstate noise is increasing.

When a large number of households maintain a collective or collective life within a building, each home can generate different types of noise. Households with elementary school children, residents with drummer occupations, and furniture with very noisy and crowded children have more noise than other households. The top, bottom, or side of the floor where these furniture and homes are located is exposed to loud noises, making it difficult to live comfortably and comfortably in practice. In order to solve this problem, a sound insulation facility for preventing the interlayer noise is installed, but the effect is insignificant.

Nowadays, this kind of interstory noise problem is seriously arising in a multi-family house, and the government announced that it will impose a penalty by applying the guilty of nearby disorder of the minor crime punishment act to the interstate noise induction act, and even the social noise problem , The regulations on housing construction standards, etc. have been strengthened and revised.

Conventional interlayer floor structures for minimizing the interlayer noise as described above are proposed. In the conventional interlayer floor structure, a lightweight foamed concrete layer is formed on the basis of a concrete slab, A piping and a mortar layer for finishing, and a floor decoration layer made of a decorative material such as monolith, wood, or tile.

However, the interlayer bottom structure has a function of attenuating the noise by the lightweight foamed concrete layer formed on the concrete slab, but it fails to properly absorb or block the noise such as the light impact sound and the heavy impact sound. Therefore, the noise and vibration caused by the impact applied to the floor are directly transmitted to the lower layer, resulting in a significant deterioration in the comfort of the building.

Especially, in today 's apartment building, the regulation is made to allow construction only if noise below a certain decibel is generated due to constant impact strength. In fact, when constructing a building these days, if there is no sound insulation facility, it will be regulated to such an extent that construction is impossible. Therefore, various ideas have conventionally been developed for the installation of such a sound insulation facility.

In the case of the above-mentioned prior art, a separate anti-vibration pad is laid out to develop a function of adding the sound absorption function, but this causes a problem because it has a high cost of installation as well as a sound insulation effect. The price of dustproof pad is expensive, and sand and aggregate to be laid up at the top are expensive, so construction cost is considerably high. Also, due to the high resilience of the anti-vibration pad, there is a possibility that the construction of the boiler piping facility, which will be seated on the upper side, becomes difficult.

In addition, conventionally, there is a problem that noise generated while water is circulated through the boiler pipe is propagated as it is to the lower floor as well as the room, thereby causing noise.

Conventionally, a plurality of dampers such as springs are installed in the floor of the room to prevent the impact from being transmitted to the lower layer. However, if damper is used for a long period of time, the original shock absorption function is lost, There is a problem that induces more.

In addition, there are many types of anti-noise materials currently used, but they are not so effective in blocking noise.

Therefore, there is a strong demand for a structure for preventing the interlayer noise transmitted from the apartment and the multi-story building to the interlayer slab and for absorbing the shock between the interlayer noise and absorbing the shock.

A prior art document related to the present invention is Korea Registered Patent Registration No. 10-066093 (registered on Dec. 15, 2006).

A first object of the present invention is to provide an inter-apartment sound insulation structure for a building capable of discharging noise due to an impact generated in an indoor floor of each household of the apartment house to the outside.

A second object of the present invention is to provide an inter-apartment sound insulation structure for a building, which absorbs noise generated in a pipe used for indoor floor heating, thereby reducing noises generated by heating water flow when heating is performed.

A third object of the present invention is to provide a sound insulation structure for a floor space of a building, which can measure noise generated in the floor in real time and provide a sound wave capable of canceling the noise, thereby canceling vibration due to noise.

In order to solve the above-mentioned problems, the present invention provides an inter-apartment floor-to-ceiling sound insulation structure.

Wherein the sound insulation structure of the apartment building comprises a slab layer constituting a bottom layer of each household of the apartment house; A pipe layer formed on the slab layer and provided with heating pipes through which heating water is circulated; An impact absorbing layer disposed on the pipe layer and formed with lattice holes; And a noise removing layer disposed on the impact absorbing layer and removing noise when noise is generated at a plurality of positions due to an external impact.

A sound absorbing layer formed of a sound absorbing material is disposed between the slab layer and the pipe layer,

The bottom surface of the scratch layer and the top surface of the slab layer are laminated to form a second contact surface in the form of a wave,

Wherein the upper surface of the sound-absorbing layer and the upper surface of the pipe layer are laminated in a wave-like second contact surface,

The wave-like valleys and the floor forming the first contact surface and the second contact surface are preferably arranged to intersect with each other along the upper and lower sides.

In addition, a vacuum layer is formed in the sound-absorbing layer and has a lattice shape and has a predetermined degree of vacuum,

The vacuum layer includes a plurality of first vacuum lines formed parallel to each other in the vertical direction in the damascene layer,

And a plurality of second vacuum lines connecting the plurality of vacuum lines vertically,

The plurality of second vacuum lines are preferably arranged to be offset from each other.

Further, a piping installation hole is formed in the piping layer,

Wherein a hollow conductive pipe is formed on the inner circumference of the pipe installation hole and formed of a conductive metal,

Wherein the heating pipe is disposed in the hollow of the conductive pipe,

A space is formed between the outer periphery of the heating pipe and the inner periphery of the conductive pipe,

In the spacing space, elastic members formed of a conductive metal are disposed,

Wherein the elastic members elastically support the heating pipe and the conductive pipe at a plurality of positions,

It is preferable that a rust preventive layer for preventing corrosion is coated on the outer periphery of the elastic members.

Particularly, the outer periphery of the conductive pipe and the pipe installation hole are contact-coupled with each other in a bent shape.

In addition, a lattice-shaped flow path is formed in the inside of the shock absorbing layer,

Wherein the flow path is exposed to the outside of a wall formed at an edge of the slab layer,

Wherein the wall is provided with an exposure hole for exposing the flow path to the outside of the wall,

Wherein the exposure hole is provided with a pressure sensor for measuring a pressure inside the flow passage and transmitting the measured pressure to the controller,

Wherein the exposure hole is provided with a valve that is electrically connected to the controller and opens the exposure hole when the measured pressure exceeds a predetermined reference pressure,

When the valve is opened, it is preferable that pressure air generated through a pressure higher than a reference pressure formed inside the flow path is discharged to the outside of the wall through the opening hole.

The noise canceling layer may be disposed on the noise canceling layer body so as to form a lattice-like position with respect to the noise canceling layer body. The noise eliminating layer may be provided on the noise canceling layer body to measure the sound waves generated at the corresponding position, And a plurality of sound wave generators installed in the noise canceling body to generate a predetermined sound wave,

Preferably, the controller generates a resonance sound wave capable of canceling the sound waves measured by using the plurality of sound wave generators, and controls the sound waves generated at the corresponding positions to be canceled.

The noise absorbing layer may be bonded to the impact absorbing layer,

A plurality of spacers are formed at the lower end of the noise removing layer,

Wherein a plurality of fixing grooves are formed at an upper end of the impact absorbing layer to fix the plurality of spacers,

A gap space is formed between the impact absorbing layer and the noise removing layer by the plurality of spacers,

The edges of the noise absorbing layer and the impact absorbing layer are air-tightly sealed by a hermetic member,

Wherein the noise removing layer includes a vacuum adjusting portion,

Wherein the vacuum regulator includes a vacuum sensor for measuring a degree of vacuum in the gap space and transmitting the measured degree of vacuum to the controller, a vacuum line, and a vacuum supplier driven by control of the controller,

Preferably, the controller generates a vacuum through the vacuum supplier so that the measured degree of vacuum reaches a reference degree of vacuum at which the measured degree of vacuum is variably set, and provides the generated vacuum in real time to the gap space through the vacuum line.

The present invention has the effect of discharging the noise caused by the impact generated in the indoor floor of each household of the apartment house to the outside.

In addition, the present invention has the effect of reducing the noise generated by the heating water flow when the heating is performed by absorbing the noise generated in the piping used in the indoor floor heating.

In addition, the present invention has an effect of measuring noise generated in the floor in real time and providing a sound wave capable of canceling it, thereby canceling vibration due to noise.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing an interlayer sound insulation structure of a building according to the present invention. FIG.
2 is a view showing a configuration in which first and second contact surfaces according to the present invention are formed.
3 is a view showing an example in which a vacuum layer is further formed on a sound-absorbing layer according to the present invention.
4 is a view showing a pipe layer according to the present invention.
5 is a view showing an example in which a lattice-shaped flow path is formed inside the impact absorbing layer according to the present invention.
6 is a view illustrating a noise removing layer according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface .

Furthermore, the present invention is not limited to a configuration that does not include any other configuration between the substrate and any configuration provided or disposed on (or under) the substrate.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following description taken in conjunction with the accompanying drawings, in which: FIG.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing an interlayer sound insulation structure of a building according to the present invention. FIG.

Referring to FIG. 1, the soundproof structure of a multi-storey apartment building according to the present invention includes a slab layer 100 constituting a bottom layer of each house of a multi-family house, a plurality of heating pipes 120 formed on the slab layer 100, A shock absorbing layer 300 disposed on the piping layer 200 and having lattice-like holes formed thereon; a vibration damping layer 300 disposed on the shock absorbing layer 300, And a noise removing layer 400 for removing the noise when noise is generated at a plurality of positions due to the noise.

2 is a view showing a configuration in which first and second contact surfaces according to the present invention are formed.

Referring to FIG. 2, a sound-absorbing layer 500 formed of a sound-absorbing material is disposed between the slab layer 100 and the pipe layer 200 according to the present invention.

The lower surface of the scratch layer 500 and the upper surface of the slab layer 100 are laminated to form a first contact surface S1 having a wave shape.

The upper surface of the sound-absorbing layer 500 and the upper surface of the pipe layer 200 are laminated in a wave-like second contact surface S2.

The wave-like valleys and floors constituting the first contact surface S1 and the second contact surface S2 are preferably arranged to intersect with each other along the upper and lower sides.

3 is a view showing an example in which a vacuum layer is further formed on the sound-absorbing layer according to the present invention.

Referring to FIG. 3, a vacuum layer 510 is formed inside the sound-absorbing layer 500 and has a lattice shape and has a predetermined degree of vacuum.

The vacuum layer 510 includes a plurality of first vacuum lines 511 formed in parallel with each other in the upper and lower portions of the damascene layer 500 and a plurality of second vacuum lines 511 connecting the plurality of first vacuum lines 511 vertically And a plurality of second vacuum lines 512.

The plurality of second vacuum lines 512 are arranged to be offset from each other.

4 is a view showing a pipe layer according to the present invention.

Referring to FIG. 4, a pipe installation hole 210 is formed in the pipe layer 200.

In the inner circumference of the pipe installation hole 210, a hollow conductive pipe 220 is formed of a conductive metal.

In the hollow of the conductive pipe 220, the heating pipe 201 is disposed.

A space (a) is formed between the outer periphery of the heating pipe (201) and the inner periphery of the conductive pipe (220).

In the spacing space (a), elastic members (230) formed of a conductive metal are disposed.

The elastic members 230 elastically support the heating pipe 201 and the conductive pipe 220 at a plurality of positions.

A rust preventive layer (not shown) for preventing corrosion is coated on the outer circumference of the elastic members 230.

In particular, the outer circumference of the conductive pipe 220 and the pipe installation hole 210 may be in contact with each other in a bent shape. It is possible to improve the conductivity by the bending and to disperse the coupling force and the external vibration.

5 is a view showing an example in which a lattice-shaped flow path is formed inside the impact absorbing layer according to the present invention.

Referring to FIG. 5, a lattice-shaped flow path 310 is formed inside the shock absorbing layer 300 according to the present invention.

The flow path 310 is exposed to the outside of the wall 110 formed at the rim of the slab layer 100.

The wall 110 is formed with an exposure hole 111 through which the passage 310 is exposed to the outside of the wall 110.

A pressure sensor 320 is installed in the exposure hole 111 to measure the pressure inside the flow path 310 and transmit the measured pressure to the controller 330.

A valve 340 is provided in the exposure hole 111 to electrically open the exposure hole 111 when the measured pressure is greater than a predetermined reference pressure.

When the valve 340 is opened, pressure air generated through a pressure higher than a reference pressure formed in the passage 310 is discharged to the outside of the wall 110 through the exposed hole 111 .

6 is a view illustrating a noise removing layer according to the present invention.

Referring to FIG. 6, the noise removing layer 400 according to the present invention is disposed on the noise removing layer body 410 in a lattice-like position with the noise removing layer body 410, A plurality of sound wave measuring devices 420 for measuring the sound waves generated in the sound removing layer body 410 and transmitting the sound waves to the controller 330, And a sound wave generator 430 of FIG.

The controller 330 may generate a resonance sound wave that can cancel the sound waves measured by using the plurality of sound wave generators 430 and may control to cancel the sound waves generated at the corresponding positions.

It is preferable that resonance sound waves corresponding to a certain range of sound waves are set in the controller so as to cancel certain sound waves.

In addition, although not shown in the drawings, the noise removing layer 400 is combined with the shock absorbing layer 300.

At the lower end of the noise removing layer 400, a plurality of spacers are formed.

At the upper end of the shock absorbing layer 300, a plurality of fixing grooves are formed in which the plurality of spacers are inserted and fixed.

A gap space is formed between the impact absorbing layer 300 and the noise removing layer 400 by the plurality of spacers.

The edges of the noise absorbing layer 400 and the impact absorbing layer 300 are air-tightly sealed by a hermetic member.

The noise removing layer 400 includes a vacuum regulator.

The vacuum regulator includes a vacuum sensor for measuring a degree of vacuum in the gap space and transmitting the measured degree of vacuum to the controller, a vacuum line, and a vacuum supplier driven by the control of the controller.

The controller may generate a vacuum through the vacuum provider so that the measured degree of vacuum reaches a reference degree of vacuum at which the measured degree of vacuum is variably set and provide the generated vacuum in real time to the gap space through the vacuum line.

According to the structure and the operation described above, the present invention has the effect of discharging the noise caused by the impact generated in the indoor floor of each household of the apartment house to the outside of the house.

In addition, the present invention has the effect of reducing the noise generated by the heating water flow when the heating is performed by absorbing the noise generated in the piping used in the indoor floor heating.

In addition, the present invention has an effect of measuring noise generated in the floor in real time and providing a sound wave capable of canceling it, thereby canceling vibration due to noise.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. The present invention is not limited to the drawings.

100: slab layer
200: Piping layer
300: shock absorbing layer
400: Noise reduction layer

Claims (4)

A slab layer constituting the bottom layer of each household of the apartment house;
A pipe layer formed on the slab layer and having heating pipes through which heating water is circulated;
An impact absorbing layer disposed on the pipe layer and formed with lattice holes;
A noise removing layer disposed on the impact absorbing layer and removing the noise when noise is generated at a plurality of positions due to an external impact;
≪ / RTI >
A sound absorbing layer formed of a sound absorbing material is disposed between the slab layer and the pipe layer,
The lower surface of the sound-absorbing layer and the upper surface of the slab layer are laminated in a wave-like first contact surface,
Wherein the upper surface of the sound-absorbing layer and the upper surface of the pipe layer are laminated in a wave-like second contact surface,
Wherein a wave-like valley and a floor forming the first contact surface and the second contact surface are arranged so as to intersect with each other along the upper and lower sides,
Inside the sound-absorbing layer,
A vacuum layer having a lattice shape and forming a predetermined degree of vacuum is further formed,
Wherein the vacuum layer
A plurality of first vacuum lines formed in parallel along the upper and lower sides in the sound-absorbing layer,
And a plurality of second vacuum lines connecting the plurality of vacuum lines vertically,
Wherein the plurality of second vacuum lines comprise:
Are arranged to be staggered from each other.
Sound insulation structure of apartment house interlayer.
delete delete The method according to claim 1,
In the piping layer,
A pipe installation hole is formed,
On the inner circumference of the pipe installation hole,
A conductive tube formed of a conductive metal and having a hollow shape,
Wherein the heating pipe is disposed in the hollow of the conductive pipe,
A space is formed between the outer periphery of the heating pipe and the inner periphery of the conductive pipe,
In the spacing space, elastic members formed of a conductive metal are disposed,
The elastic members
The heating pipe and the conductive pipe are elastically supported to each other at a plurality of positions,
In the outer periphery of the elastic members,
The anti-rusting layer for corrosion protection is coated,
Sound insulation structure of apartment house interlayer.

Images