KR101994131B1 - Structure for reducing noise between floors in apartment house - 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: an upper structure (100); a lower structure (200) arranged on a lower portion of the upper structure; a vibration absorbing unit (300) forming a layer between the upper and the lower structure (100, 200) to form a bottom of the upper structure (100) and form a ceiling of the lower structure (200), and absorbing noise and vibration created in the upper structure (100); and a noise discharge unit (400) to guide residual noise and vibration which are not absorbed by the vibration absorbing unit (300) to pillars (500) formed on a plurality of positions to support the upper and the lower structure (100, 200) to discharge the residual noise and vibration to the outside.

Description

{Structure for reducing noise between floors in apartment house}

The present invention relates to a structure for preventing noise from being interposed between adjacent floors, and it is intended to absorb noise generated from the floor in multiple ways, and to induce noise or vibration of remaining unabsorbed by the pillars, And to a structure for preventing noise between adjacent houses.

Generally, the construction is completed according to the number of floors, and after completing the foundation work, the gravel and the cement mortar are constructed to have a predetermined thickness in a state where the heating pipes are arranged at regular intervals on the concrete slab.

In this way, slabs dividing layers and layers of multi-layered multi-storey buildings such as apartments are constructed with concrete only, so that vibration due to noise and impact generated in the corresponding layer of the building is transmitted to the lower layer directly through the interlayer slab do.

In general, the impact sound applied to the building structure of apartment houses, villas, and other apartment buildings is transmitted to all directions due to the impact of the person's walking, opening and closing of doors, movement of objects, Thereby causing the surface of the building structure to vibrate, as well as being converted into an air transmission sound, which is perceived as noise when it is heard by people around the ear.

For example, a sound such as a drop of an object, which is applied to the floor, or a sound of moving a chair, generates a solid sound, and the sound transmitted through the floor slab to the lower layer is referred to as an interlayer noise.

Especially, in apartment houses and similar houses, there are resilience walls for residential space in each household. The noise generated as described above is transmitted to the bearing wall formed on the lower layer through the bearing wall to cause noise or vibration to be spread to the corresponding generation to cause noise.

Conventional interlayer floor structures have been proposed in the prior art to minimize and minimize the interlayer noise which is seriously raised. Such a conventional conventional interlayer floor structure is constructed such that, as shown in Fig. 1, And a floor decoration layer 5 made of a decorative material such as monolith, wood, tile or the like is formed on the heating pipe 3 and the mortar layer 4 for finishing, .

However, the above-mentioned 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, when the building is constructed with such a conventional floor structure, for example, the noise and vibration caused by the impact applied to the floor by the children jumping upstairs are directly transmitted to the lower layer through the bearing walls as described above, There is a problem that can not be lost.

A prior art document related to the present invention is Korean Patent Registration No. 10-1492208.

An object of the present invention is to provide a noise preventing structure for a building structure capable of absorbing noise generated from the floor in multiple ways and inducing noise or vibration of the remaining unabsorbed noise to be discharged to the outside, .

In order to achieve the above object, the present invention provides a structure for preventing noise between apartment houses.

The structure for preventing noise between apartment houses includes an upper structure 100; A lower structure 200 disposed at a lower portion of the upper structure; A bottom of the upper structure 100 and a ceiling of the lower structure 200 form a layer between the upper structure 100 and the lower structure 200 and the noise generated in the upper structure 100 A vibration absorption part (300) for absorbing vibration; And residual noise vibrations that are not absorbed by the vibration absorbing part 300 are led to the columns 500 formed at a plurality of positions to support the upper structure 100 and the lower structure 200 and are discharged to the outside And includes a discharge portion 400.

The vibration absorbing part 300 includes a plurality of vibration absorbing layers 310,

A noise dispersing layer 320 disposed at a lower portion of the vibration absorbing layer 310 and having multiple holes 321 uniformly arranged therein,

A lower support plate 330 disposed at a lower end of the noise dispersing layer 320 and supporting the noise dispersing layer 320,

And noise measuring devices 340 installed on the lower support plate 330 for measuring noise values in the polygonal holes 321.

An upper support plate 350 is disposed between the vibration absorbing layer 310 and the noise dispersing layer 320 and has a vacuum layer 351 formed therein,

The bottom surface of the upper support plate 350 is formed in an embossed shape,

In the lower support plate 320,

The cylinders 360 having the lifting shaft 361 are disposed,

A throttle 362 is disposed on the shaft 361 of each of the lifting cylinders 360,

The cylinders (360)

(321) of the polygonal shape,

As the shaft 361 is lifted and lowered, the volume of the upper and lower spaces in the polygonal hole 321 is varied,

The controller 370,

(361) of each of the cylinders (360) so as to form a volume of the upper and lower spaces preset according to the noise values measured in each of the polygonal holes (321) from the noise measuring devices (340) .

In addition, a clear wall 600 is provided between the columns 500,

The upper end of the barrier wall 600 is elastically supported through the ceiling 20 and the first elastic part 610,

The lower end of the curled wall 600 is elastically supported through the bottom 10 and the second elastic part 620,

The first elastic portion 610 may be formed of,

Is fitted and fixed in a first elastic fitting groove (21) formed in the ceiling (20)

The second elastic portion 620 may be formed of,

Is fitted and fixed in the second elastic fitting groove (11) formed in the bottom (10).

Particularly, the noise discharging unit 400 includes:

A resonance plate 410 formed at the lower end of the lower support plate 320 and having hollows and spacers 411 supporting the upper and lower ends,

A meter 420 for measuring the noise in the hollow,

And a vibration supplier 430 for providing a vibration canceling the noise transmitted to the hollow by the control of the controller 370 that receives the measured noise.

Further, under the resonance plate 410,

A noise exhaust plate 700 in which lattice-shaped grooves 710 are formed is disposed,

Noise discharge pipes 510 are buried in the pillars 500 along the longitudinal direction of each of the pillars 500,

The grooves 710 are connected to the noise exhaust pipes 510 through the connection pipes 720,

The ends of each of the noise exhaust pipes 510 are exposed outdoors,

The noise transmitted to the grooves 710 is transmitted to the noise discharge pipe 510 through the connection pipes 720 and is delivered to the outside through the noise discharge pipes 510 to be lost.

Further, inside each of the columns,

A plurality of installation holes into which the noise discharge pipes are inserted are formed,

The inner circumference of each of the plurality of installation holes and each of the noise exhaust pipes are elastically supported by elastic springs.

In addition,

A pipe layer 800 in which the heating pipe 810 is embedded is formed,

In the pipe layer 800,

A pipe installation groove 820 in which the heating pipe 810 is disposed is formed,

The heating pipe 810

On the outside of the heating pipe 810,

A first magnet 830 having a first polarity is disposed so as to surround the first magnet 830,

On the inner circumference of the pipe installation groove 820,

A second magnet 840 having a second polarity that forms a repulsive force with the first polarity is provided,

The outer circumference of the heating pipe 810,

An air layer is formed on the inner circumference of the pipe installation groove 820 so as to be spaced apart from the inner circumference of the pipe installation groove 820 by a certain gap due to the repulsive force.

The heating pipe may be resiliently supported through a pipe installation groove and elastic springs.

According to the above-mentioned solution, the present invention absorbs the noise generated from the floor in multiple ways and at the same time has the effect of inducing noise or vibration of the remaining unabsorbed to the column, quickly discharging it to the outside and disappearing .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a conventional noise preventing structure between apartment houses. FIG.
FIG. 2 is a view showing a structure for preventing the noise between rooms of a building according to the present invention. FIG.
3 is a view showing a configuration of a vibration absorber according to the present invention.
4 is a view showing an installation state of a wall according to the present invention.
5 is a view showing a configuration of a noise discharge unit according to the present invention.
FIG. 6 is a view showing a configuration in which the small pores are removed through a column according to the present invention.
7 is a view showing an installation state of a heating pipe 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 objects, 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.

FIG. 2 is a view showing a structure for preventing the noise between rooms of a building according to the present invention. FIG. 3 is a view showing a configuration of a vibration absorber according to the present invention. 4 is a view showing an installation state of a wall according to the present invention. 5 is a view showing a configuration of a noise discharge unit according to the present invention. FIG. 6 is a view showing a configuration in which the small pores are removed through a column according to the present invention. 7 is a view showing an installation state of a heating pipe according to the present invention.

2 to 7, the structure for preventing noise between apartment houses according to the present invention includes an upper structure 100; A lower structure 200 disposed at a lower portion of the upper structure; A bottom of the upper structure 100 and a ceiling of the lower structure 200 form a layer between the upper structure 100 and the lower structure 200 and the noise generated in the upper structure 100 A vibration absorption part (300) for absorbing vibration; And residual noise vibrations that are not absorbed by the vibration absorbing part 300 are led to the columns 500 formed at a plurality of positions to support the upper structure 100 and the lower structure 200 and are discharged to the outside And includes a discharge portion 400.

The vibration absorbing part 300 includes a plurality of vibration absorbing layers 310,

A noise dispersing layer 320 disposed at a lower portion of the vibration absorbing layer 310 and having multiple holes 321 uniformly arranged therein,

A lower support plate 330 disposed at a lower end of the noise dispersing layer 320 and supporting the noise dispersing layer 320,

And noise measuring devices 340 installed on the lower support plate 330 for measuring noise values in the polygonal holes 321.

An upper support plate 350 is disposed between the vibration absorbing layer 310 and the noise dispersing layer 320 and has a vacuum layer 351 formed therein.

The bottom surface of the upper support plate 350 is formed in an embossed shape.

Cylinders 360 having a shaft 361 to be lifted are disposed on the lower support plate 320.

A throttle 362 is disposed on the shaft 361 of each of the lifting cylinders 360.

The cylinder 360 is disposed in each of the polygonal holes 321 and the volume of the upper and lower spaces in the polygonal hole 321 varies as the shaft 361 is raised and lowered.

The controller 370 is configured to determine the volume of the upper and lower spaces preset according to the noise values measured in each of the polygonal holes 321 from the noise meters 340, The shaft 361 is moved up and down.

In addition, a curtain wall 600 is provided between the columns 500.

The upper end of the barrier wall 600 is elastically supported through the ceiling 20 and the first elastic part 610.

The lower end of the barrier wall 600 is elastically supported through the bottom 10 and the second elastic part 620.

The first elastic part 610 is fixed to the first elastic fitting groove 21 formed in the ceiling 20 and the second elastic part 620 is fixed to the bottom part 10 2 resilient fitting groove 11 and is fixed.

Particularly, the noise discharge unit 400 includes a resonance plate 410 formed at the lower end of the lower support plate 320 and having spacers 411 for supporting the upper and lower parts, And a vibration providing unit 430 for providing vibration to cancel the noise transmitted to the hollow by the control of the controller 370 that receives the measured noise desirable.

Further, below the resonance plate 410, a noise exhaust plate 700 in which lattice-shaped grooves 710 are formed is disposed.

The noise exhaust pipes 510 are buried in the pillars 500 along the longitudinal direction of each of the pillars 500.

The grooves 710 are connected to the noise exhaust pipes 510 through the connection pipes 720, respectively.

The ends of each of the noise exhaust pipes 510 are exposed to the outside and the noise transmitted to the grooves 710 is transmitted to the noise exhaust pipe 510 through the connection pipes 720, 510) and is lost.

In addition, in each of the pillars, a plurality of installation holes into which the noise discharge pipes are inserted are formed.

The inner circumference of each of the plurality of installation holes and each of the noise exhaust pipes are elastically supported by elastic springs.

Further, a piping layer 800 in which a heating pipe 810 is embedded is formed on the bottom,

A pipe installation groove 820 in which the heating pipe 810 is disposed is formed in the pipe layer 800.

The heating pipe 810 is disposed outside the heating pipe 810 so as to surround the first magnet 830 having the first polarity.

A second magnet 840 having a second polarity that forms a repulsive force with the first polarity is provided on the inner circumference of the pipe installation groove 820.

The outer circumference of the heating pipe 810 is spaced apart from the inner circumference of the pipe installation groove 820 so as to have a constant gap due to the repulsive force to form an air layer.

The heating pipe may be resiliently supported through a pipe installation groove and elastic springs.

According to the present invention, it is possible to absorb noise generated from the floor in multiple ways, and to induce noise or vibration of residual noise that has not been absorbed, .

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: superstructure
200: Substructure
300: vibration absorption portion
400:
500: Column

Claims (4)

Superstructure;
A lower structure disposed at a lower portion of the upper structure;
A vibration absorber forming a layer between the upper structure and the lower structure and absorbing noise and vibration generated in the upper structure and a ceiling of the lower structure; And
And a noise discharging portion for guiding the residual noise vibration not absorbed by the vibration absorbing portion to the columns formed at a plurality of positions to support the upper structure and the lower structure,
Wherein the vibration absorber comprises: a plurality of vibration absorbing layers which are concavo-convexly coupled to each other; a noise dispersing layer which is disposed below the vibration absorbing layer and in which holes of a polygonal shape are uniformly arranged; A lower support plate for supporting the dispersion layer; and a noise measuring device installed on the lower support plate for measuring a noise value in the polygonal hole,
An upper support plate disposed between the vibration absorbing layer and the noise dispersing layer and having a vacuum layer formed therein,
The bottom surface of the upper support plate is formed in an embossed shape,
In the lower support plate,
Cylinders having axes to be lifted are arranged,
A throttle plate is disposed on the axis of each of the lifting cylinders,
The cylinders,
A plurality of holes arranged in each of the polygonal holes,
As the shaft is lifted and lowered, the volume of the upper and lower spaces in the polygonal hole is varied,
The controller,
Wherein the axis of each of the cylinders is elevated so as to form a volume of the upper and lower spaces preset according to the noise values measured in each of the polygonal holes from the noise measuring devices .
delete delete The method according to claim 1,
A wall is provided between the columns,
The upper end of the wall is elastically supported through the ceiling and the first elastic portion,
The lower end of the wall is elastically supported through the bottom and the second elastic portion,
The first elastic portion
A first elastic fitting groove formed in the ceiling,
The second elastic portion
And a second resilient fitting groove formed on the bottom of the second resilient fitting groove.

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