KR102412980B1 - Vibration Isolation Structure - Google Patents

Abstract

According to the present invention, in a vibration-proof structure for reducing noise between floors of a multi-layer structure including a floor slab (1) and a wall (2), the vibration-proof panel 100 installed on the floor slab (1); Cast-in-place concrete 200 to be poured in the field on the anti-vibration panel 100; and a finishing member 300 to be installed on the cast-in-place concrete 200, wherein a plurality of anti-vibration mounts 110 are attached to a predetermined area under the anti-vibration panel 100, and the anti-vibration panel 100 ) and the wall (2) is provided with a vibration-proof structure, characterized in that the ventilation space (4) is formed.
According to the present invention, there is an effect of securing a vibration-proof environment capable of maximizing the performance of the vibration-proof mount used for the vibration-proof structure.

Description

Anti-vibration structure for noise reduction between floors and method of construction {Vibration Isolation Structure}

The present invention relates to the field of vibration and sound insulation, and more particularly, to create an environment capable of maximizing the performance of the anti-vibration mount to increase the dust-proof efficiency, and to ensure the convenience of construction of the anti-vibration structure. It relates to a vibration-proof structure for reducing noise between floors and a method of constructing the same.

Due to the change in the architectural structure due to the increase in the high-rise of the apartment house, the noise between floors, such as the floor impact sound, is causing inconvenience to the residents. In particular, inter-floor noise generated in apartment houses acts as a social conflict factor that can lead to extreme behavior as well as conflicts between neighbors. Institutional and technical measures are urgently required.

The noise can be divided into a solid transmitted sound transmitted through a solid and an air transmitted sound transmitted through a space such as air according to a transmission path.

Inter-floor noise refers to the conversion of sound transmitted from solid materials such as floors and walls to sound transmitted from air in a space. In other words, in an apartment building structure, various living noises from the upper floor are transmitted to the lower floor through the wall connecting the upper floor and the lower floor.

The types of inter-floor noise can be divided into light impact sound and heavy impact sound.

The light impact sound is a floor impact sound generated by a relatively light and hard impact, such as when a small object is dropped or furniture is moved. The high-pitched sound transmitted to the lower layer by a light impact sound has a weak impact force and a short acoustic duration.

On the other hand, the heavy impact sound is a low-pitched sound transmitted to the lower floors by the sound of a heavy and soft impact being applied to the floor. Unlike the light impact sound, the impact force is large and the sound duration is long.

In order to disperse and absorb noise between floors, an interlayer sound insulation material (or a cushioning material or an interlayer sound insulation panel) is currently installed between the floor slab layer and the finishing mortar layer during the construction of an apartment house.

There are various types of such interlayer sound insulation materials according to materials, structures, physical properties, etc., and they are required to be effective not only for light impact sound but also for heavy impact sound. Accordingly, research and development to improve the interlayer sound insulation performance while reducing the manufacturing cost is continuously being carried out.

However, despite continuous technological development, the performance of sound insulating materials or vibration dampers has not been achieved, and the cause has not been identified.

1. Republic of Korea Patent Publication 10-2017-0024427 2. 20-0419652 for the Republic of Korea Registration Office 3. Republic of Korea Patent Publication 10-2010-0048740

The present invention has been devised to solve the problems of the above-mentioned vibration-proof structure, and an object of the present invention is a vibration-proof structure for reducing inter-floor noise that can secure a vibration-proof environment that can maximize the performance of the vibration-proof mount used for the vibration-proof structure And to provide a method for constructing the same.

Another object of the present invention is to provide a vibration-proof structure for reducing inter-floor noise, and a method for constructing the same, by lowering the difficulty of on-site construction of the vibration-proof structure to secure construction convenience.

According to one aspect of the present invention, in a vibration-proof structure for reducing noise between floors of a multi-layer structure including a floor slab (1) and a wall (2), a vibration-proof panel (100) installed on the floor slab (1); Cast-in-place concrete 200 to be poured in the field on the anti-vibration panel 100; and a finishing member 300 installed on the cast-in-place concrete 200, wherein a plurality of anti-vibration mounts 110 are attached to a predetermined area under the anti-vibration panel 100, and the anti-vibration panel 100 ) and the wall (2) is provided with a vibration-proof structure, characterized in that the ventilation space (4) is formed.

In this case, the ventilation space 30 is connected to the vibration-proof space 3 formed between the vibration-proof panel 100 and the floor slab 1, and a side finishing material 400 installed in the ventilation space 4; It may be a vibration-proof structure further comprising a.

In addition, the side finishing material 400 is a side panel 410 connected to the vibration-proof space (3); and a finishing panel 420 installed on the side panel 410 on an upper portion thereof.

In addition, a first ventilation hole 411 connecting the vibration-proof space 3 and the upper space 5 is formed in the side panel 410 , and the first ventilation hole 411 is formed in the finishing panel 420 . It may be a vibration-proof structure, characterized in that the second ventilation hole 421 for connecting the and the upper space (5) is formed.

In addition, the finishing panel 420 includes a front panel 422 mounted on the side panel 410; and a rear panel 423 formed behind the front panel 422 and having the second ventilation hole 421 formed thereon.

In addition, a plurality of the first vent holes 411 are formed along the longitudinal direction of the side panel 410 , and the lower end (b) of the rear panel 423 is located at the lower end of the front panel 422 (a). ) may be a vibration-proof structure, characterized in that it is formed to be spaced upward by a predetermined interval.

In addition, the vibration-proof structure further comprising a support member 120 attached to the lower portion of the vibration-proof panel 100, wherein the support member 120 is attached to an area to which the vibration-proof mount 110 is not attached. can be

In addition, the anti-vibration mount 110 is installed in contact with the floor slab 1, and the support member 120 is installed to be spaced apart from the floor slab 1 by a predetermined distance. can

In addition, the anti-vibration panel 100 is an extruded insulating material 120; A first polypropylene board 130 attached to the upper surface of the extrusion method heat insulating material (120); and a second polypropylene board 140 attached to the lower surface of the extruded heat insulating material 120 .

In addition, the vibration-proof mount 110 may be a vibration-proof structure, characterized in that the plate-shaped formed of a polyurethane material.

According to another aspect of the present invention, in the method of constructing a vibration-proof structure, the vibration-proof panel 100 is installed on the floor slab 1, and the side panel 410 is provided in the ventilation space 4 A first step of installing (S100); a second step (S200) of pouring the cast-in-place concrete 200 on the anti-vibration panel 100 and installing the finishing member 300 on the cast-in-place concrete 200; and a third step (S300) of installing the finishing panel 420 on the side panel 410 on the upper part (S300).

According to the present invention, there is an effect of securing a vibration-proof environment that can maximize the performance of the vibration-proof mount used in the vibration-proof structure.

According to the present invention, it is possible to secure the convenience of construction by lowering the difficulty of on-site construction of the vibration-proof structure.

1 is a cross-sectional view of a vibration-proof structure according to an embodiment of the present invention.
2 and 3 are perspective views of a vibration-proof structure according to an embodiment of the present invention.
Figure 4 is an enlarged view of the lower part of the vibration-proof structure according to an embodiment of the present invention.
5 is a view showing a finishing panel used in a vibration-proof structure according to an embodiment of the present invention.
6 is a view showing a state in which the finishing panel used for the vibration-proof structure according to an embodiment of the present invention is installed on the upper side of the side panel.
7 is experimental data comparing the effect of reducing vibrations between a case in which a vibration-proof panel is installed in a closed vibration-proof space and a case in which a vibration-proof panel is installed in an open vibration-proof space.

An embodiment of a vibration-proof structure for reducing noise between floors according to the present invention and a method of constructing the same will be described in detail with reference to the accompanying drawings. and a redundant description thereof will be omitted.

The embodiments described below are for explaining some of the various application cases of the present invention, so the spirit of the present invention is not limited to the configuration of the embodiments.

In addition, terms such as first, second, etc. used below are merely identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are limited by terms such as first and second not.

In addition, the term "coupling" does not mean only when there is direct physical contact between each component in the contact relationship between each component, but another component is interposed between each component, so that the component is in the other component. It should be used as a concept that encompasses even the cases in which each is in contact.

The present invention relates to a vibration-proof structure for reducing noise between floors.

In general, the vibration-proof structure adopts a configuration for reducing vibration transmitted from the upper portion by installing an elastic member between the lower portion of the vibration-proof panel and the floor slab.

However, since the elastic member is placed between the vibration-proof panel and the floor slab, an empty space (hereinafter referred to as 'vibration-proof space') is formed in the area where the elastic member is not installed, and the movement of the elastic member is restricted due to the air pressure in the vibration-proof space. phenomenon has occurred.

According to the previous study, the reason for the reduction of the vibration-proof effect by the air in the vibration-proof space was identified as the resonance phenomenon, and a sound-absorbing material was inserted in the vibration-proof space to solve the problem of reducing the vibration-proof effect.

However, there is a problem in that the humidity of the vibration-proof space is increased by the sound-absorbing material inserted into the vibration-proof space, and the moisture in the vibration-proof space is transferred to the wallpaper to be installed later, and mold is generated on the wallpaper.

Moreover, inserting a sound-absorbing material into the vibration-proof space did not solve the problem of reducing the vibration-proof effect.

In the present invention, it was determined that the cause of the above-described problem is caused by air pressure in the dust-proof space, and an experiment was conducted to prove this.

That is, since the vibration-proof space is sealed by the cast-in-place concrete and upper finishing material poured on the upper part, the air in the vibration-proof space is in a state in which it cannot be discharged to the outside. In this case, there is a problem that the behavior of the anti-vibration mount due to the vibration transmitted from the upper part is limited by the air pressure in the dust-proof space, and accordingly, the vibration-proof efficiency due to the behavior of the anti-vibration mount is lowered.

The present invention proposes a vibration-proof structure having an open vibration-proof space in order to solve the problem that the vibration-proof space is closed and air pressure restricts the behavior of the vibration-proof mount as described above. In addition, a unique configuration is proposed to facilitate the construction of the vibration-proof structure proposed in the present invention.

The anti-vibration structure according to an embodiment of the present invention is formed in a multi-layer structure including a floor slab 1 and a wall 2, and is installed on the floor slab 1, the dust-proof panel 100, the dust-proof panel 100 It includes the cast-in-place concrete 200 and the cast-in-place concrete 200 to be poured on the upper part in the field, and the finishing member 300 to be installed on the upper part ( FIGS. 1 and 2 ).

In this case, a plurality of anti-vibration mounts 110 are attached to a predetermined area under the anti-vibration panel 100 ( FIG. 4 ).

The anti-vibration mount 110 is a plate-shaped elastic material and serves to reduce vibration transmitted from the upper part. According to an embodiment of the present invention, the anti-vibration mount 110 may be formed of a polyurethane material.

Since the anti-vibration mount 110 is not attached to the lower front surface of the anti-vibration panel 100 , a dust-proof space 3 is formed between the anti-vibration panel 100 and the lower slab 1 .

In this case, the ventilation space 4 is formed between the dustproof panel 100 and the wall 2 so that the air on the dustproof space 3 is not in a closed state (FIG. 4).

The ventilation space 30 is connected to the vibration-proof space 3 formed between the vibration-proof panel 100 and the floor slab 1 .

The anti-vibration structure according to an embodiment of the present invention may further include a side finishing material 400 installed in the ventilation space 4 to close the ventilation space 4 ( FIGS. 2 and 6 ).

The side finishing material 400 includes a side panel 410 connected to the vibration-proof space 3 and a finishing panel 420 installed on the side panel 410 ( FIG. 6 ).

The side panel 410 is installed on the side of the anti-vibration panel 100, the cast-in-place concrete 200 and the finishing member 300, and the side panel 410 is pre-installed, and the vibration-proof panel 100, the cast-in-place concrete 200 ) and the construction of the finishing member 300 is preferable in terms of convenience of construction.

After the finishing member 300 is constructed, the finishing panel 420 may be installed on the side panel 410 . It is also possible for the finishing panel 420 to serve as a so-called rail.

Ventilation holes are formed in the side panel 410 and the finish panel 420 so that the dust-proof space 3 and the upper space 5 can communicate with each other despite the installation of the side panel 410 and the finishing panel 420 .

Specifically, the side panel 410 has a first vent hole 411 connecting the vibration-proof space 3 and the upper space 5 is formed, and the finish panel 420 has a first vent hole 411 and an upper space ( 5) The second vent 421 for connecting is formed.

In this case, since the air on the anti-vibration space 3 can be moved to the upper space 5, the problem of generating air pressure that limits the behavior of the anti-vibration mount 110 can be solved.

These results can be confirmed through the experimental data attached to FIG. Referring to the experimental data, it can be seen that the impact sound is much lower in the floor structure having the open state (the vent structure according to the present invention) than in the conventional floor structure formed in the closed state (conventional structure).

A plurality of first vent holes 411 are formed along the longitudinal direction of the side panel 410 , and a plurality of second vent holes 421 are formed along the longitudinal direction of the finishing panel 420 .

The finishing panel 420 may include a front panel 422 mounted on the side panel 410 and a rear panel 423 formed behind the front panel 422 and having a second ventilation hole 421 ( 5, 6).

In this case, in order to prevent the upper end of the first vent 411 from being closed by the lower end (b) of the rear panel 423, the lower end (b) of the rear panel 423 is located at the lower end of the front panel 422 ( In a), it is preferable to be formed spaced apart upward by a predetermined interval (FIG. 6).

Accordingly, even if the first ventilation holes 411 and the second ventilation holes 421 are not vertically arranged, the vibration-proof space 3 and the upper space 5 can be connected, so that the convenience of construction can be secured.

According to an embodiment of the present invention, a support member 120 attached to the lower portion of the anti-vibration panel 100 may be further included ( FIGS. 3 and 4 ).

Since the vibration-proof panel 100 is generally installed on the front surface of the lower slab 1 , a subsequent construction operation is performed by a worker positioned above the vibration-proof panel 100 . In this case, the anti-vibration panel 100 may be drooping, which may cause damage to the anti-vibration panel 100 or damage to the anti-vibration mount 110 under the anti-vibration panel 100 . Accordingly, the support member 120 is attached to the lower portion of the vibration-proof panel 100 to support the vibration-proof panel 100 when the vibration-proof panel 100 is deflected.

The support member 120 is attached to an area to which the anti-vibration mount 110 is not attached.

However, when the support member 120 is always in contact with the floor slab 1, the ratio of the noise load transmitted to the vibration-proof mount 110 is reduced, or the behavior of the vibration-proof mount 110 is limited, and the vibration-proof is substantially The same problem as the increase in the number of mounts 110 may occur. The anti-vibration effect is because a better effect is exhibited as the number of installations of the anti-vibration mount 110 is small.

Accordingly, as shown in FIG. 3 , the anti-vibration mount 110 should be installed to be in contact with the floor slab 1 , and the support member 120 should be installed to be spaced apart from the floor slab 1 by a predetermined distance.

Accordingly, the support member 120 serves to support the anti-vibration panel 100 only when the anti-vibration panel 100 is drooped, and is installed spaced apart from the floor slab 1 after construction is completed. It does not limit the behavior of the mount 110 .
Also, referring to FIG. 3 , it can be seen that the anti-vibration mount 110 and the support member 120 are installed to be spaced apart from each other.

The anti-vibration panel 100 is a second polypropylene board ( 140).

The cast-in-place concrete 200 may include a lightweight foam concrete layer 210 formed on the anti-vibration panel 100 and a mortar layer 220 formed on the lightweight foam concrete layer.

Hereinafter, a method of constructing a vibration-proof structure according to an embodiment of the present invention will be described.

In the construction method of the vibration-proof structure according to the present invention, the first step (S100) of installing the vibration-proof panel 100 on the upper part of the floor slab 1 and the side panel 410 in the ventilation space 4 (S100), the vibration-proof panel (100) The second step (S200) of pouring cast-in-place concrete 200 on the upper part and installing the finishing member 300 on the upper part of the cast-in-place concrete 200 (S200) and the side panel 410 on the upper part of the finishing panel 420 It may include a third step (S300) of installing the.

According to the present invention, the air in the anti-vibration space 3 can be ejected to the outside, thereby maximizing the anti-vibration effect according to the behavior of the anti-vibration mount 110 .

In addition, it is possible to form the ventilation space 4 through which the air of the vibration-proof space 3 can be discharged to the outside only by installing the side finishing material 400, so that construction is convenient.

In addition, even without using a thick anti-vibration mount, dust-proof efficiency can be sufficiently achieved, thereby securing space and ensuring convenience of construction.

Since the above has only been described with respect to some of the preferred embodiments that can be implemented by the present invention, as noted, the scope of the present invention should not be construed as being limited to the above embodiments, and It will be said that the technical idea and the technical idea having its roots are all included in the scope of the present invention.

1: floor slab
2: wall
3: ventilation space
4: Dust-proof space
5: upper space
100: dustproof panel
200: cast-in-place concrete
300: finishing member
400: side finish

Claims (11)

In the vibration-proof structure for reducing noise between floors of a multi-layer structure including a floor slab (1) and a wall (2),
a dustproof panel 100 installed on the floor slab 1;
Cast-in-place concrete 200 to be poured in the field on the anti-vibration panel 100; and
A finishing member 300 to be installed on the cast-in-place concrete 200, but including,
A plurality of anti-vibration mounts 110 are attached to a predetermined area under the anti-vibration panel 100,
A ventilation space (4) is formed between the dustproof panel (100) and the wall (2),
The ventilation space (4) is connected to the vibration-proof space (3) formed between the vibration-proof panel (100) and the floor slab (1),
It further includes; the side finishing material 400 installed in the ventilation space (4);
The side finishing material 400 is
a side panel 410 connected to the vibration-proof space 3; and
Including; and a finishing panel 420 installed on the side panel 410,
A first ventilation hole 411 connecting the vibration-proof space 3 and the upper space 5 is formed in the side panel 410,
A second vent 421 connecting the first vent 411 and the upper space 5 is formed in the closing panel 420,
The finishing panel 420 is
a front panel 422 mounted on the side panel 410; and
It is formed behind the front panel 422, the second vent hole 421 is formed on the rear panel 423; includes;
The first ventilation holes 411 are formed in plurality along the longitudinal direction of the side panel 410,
The lower end (a) of the front panel 422 is mounted on the upper side of the side panel 410,
The lower end (b) of the rear panel 423 is formed spaced apart from the lower end (a) of the front panel 422 upward by a predetermined interval,
It further includes; a support member 120 attached to the lower part of the anti-vibration panel 100,
The support member 120 is attached to the area to which the anti-vibration mount 110 is not attached,
The anti-vibration mount 110 is installed in contact with the floor slab 1,
The support member 120 is in contact with the floor slab 1 when the vibration-proof panel 100 is drooping downward to support the vibration-proof panel 100,
The support member 120 is installed to be spaced apart from the floor slab 1 by a predetermined distance in a state in which the anti-vibration panel 100 is not tilted downward,
The anti-vibration mount 110 and the support member 120 are installed to be spaced apart from each other.
delete delete delete delete delete delete delete According to claim 1,
The anti-vibration panel 100 is
Extrusion method insulation 120;
A first polypropylene board 130 attached to the upper surface of the extrusion method heat insulating material (120); and
A second polypropylene board 140 attached to the lower surface of the extrusion method heat insulating material 120;
Vibration-proof structure, characterized in that it includes.
10. The method of claim 9,
The vibration-proof mount 110 is a vibration-proof structure, characterized in that the plate-shaped formed of a polyurethane material.
In the method of constructing the vibration-proof structure of claim 9,
The anti-vibration panel 100 and the anti-vibration mount 110 to which the support member 120 is attached are installed on the floor slab 1, and the side panel 410 is installed in the ventilation space 4 A first step of installing (S100);
a second step (S200) of pouring the cast-in-place concrete 200 on the anti-vibration panel 100 and installing the finishing member 300 on the cast-in-place concrete 200; and
The third step (S300) of installing the finishing panel 420 on the side panel 410;
A method of constructing a vibration-proof structure comprising:

Images