KR101824468B1 - A vibration absorbing member having a floor impact damper attached thereto and an interlayer noise preventing structure including the same - Google Patents

Abstract

The present invention relates to a vibration absorbing member attached with a bottom impact damper and a structure for preventing noise between floors, and specifically relates to a vibration absorbing member attached with a bottom impact damper and a structure for preventing noise between floors of a floating bottom structure including the same, which collects noise to a vibration absorbing section by using the bottom impact damper to prevent noise between floors and reduce sagging in the bottom at the same time. An object of the present invention is to collect vibration to the vibration absorbing section by using the bottom impact damper attached to the vibration absorbing member such that soundproofing function between floors can be stably maintained. In addition, the height difference between the bottom impact damper and the support portion maintained to be a predetermined distance such that a long-term sagging in the floating bottom structure can be reduced and failures can be reduced.

Description

An vibration absorbing member having a floor impact damper attached thereto and an interlayer noise preventing structure including the vibration absorbing member.

The present invention relates to a vibration absorbing member having a floor impact damper and an interlayer noise preventing structure including the vibration absorbing member. More particularly, the present invention relates to a floor impact damper, The present invention relates to a vibration absorbing member having a floor impact damper and a floor structure.

Since the introduction of apartments in Korea, the dispute over noise has been constantly raised. Recently, however, the intensity of the dispute has been worsening due to the fact that the neighboring households or their families . In order to solve these problems, the government has revised related laws and regulations and established regulatory standards to prevent noise generation. Article 3 Regulation on the Range and Criteria of Noise between Apartment Buildings (Environment Ordinance No. 559, Ministry of Land Transport and Communications No. 97, 2014.06.03.) Article 3 The equivalent noise level (Leq) 43dB during the day, 38dB at night, and the highest noise level (Lmax) at 57dB during the day and 52dB during the night. For air transmission sound, the 5-minute equivalent noise level (Leq) was defined as 45dB in the daytime and 40dB in the nighttime. The equivalent noise level is based on the high value during the 1 minute and 5 minute measurements, and the highest noise level is exceeded when the noise level exceeds 3 times per hour.

 However, the problem of conflict caused by this problem gradually increased rather than decreased, and the number of complaints received by the National Noise Information System increased by 13.3% to 129 cases in May from 1,097 cases (52.2 cases / day) in June 17, Leading to legal disputes or even serious social problems, even leading to murder.

 On the other hand, in the case of the interlayer sound insulating material, most of the materials have a large amount of pores due to the vibration absorption performance, and they are based on elastic materials. As a result, the pores are squeezed with time, In the case of a floating floor structure, various defects such as a reduction in sound insulation performance and sagging of the floor caused by a drop in floor space caused by deflection occur.

Therefore, it is required to develop a technology capable of maintaining stable interlayer sound insulation performance and reducing defective bottoms because it can reduce long-term deflection while having a floating floor structure excellent in sound insulation performance.

Korean Patent Registration No. 10-1348392 (December 30, 2013) Korean Patent Registration No. 10-1348392 (December 30, 2013)

An object of the present invention is to stably absorb sound insulation performance by absorbing vibrations in a vibration absorption section using a floor impact damper attached to the vibration absorption member. In addition, the height difference between the bottom impact damper and the support portion is set to be maintained at a predetermined interval, thereby reducing the defects by reducing the long-term deflection in the floored structure.

In order to solve the above problems, the present invention is formed between a floor slab (20) for partitioning a layer of a house and a floor finishing material (30) formed apart from the floor slab (20) A mesh portion 110 in which the mesh groove 111 is formed,

A bottom impact damper 120 placed on the lower surface of the mesh part 110 and filled with vibration absorbing aggregate to absorb interlayer vibration and a bottom impact damper 120 installed on the lower surface of the mesh part 110 to support the mesh part 110. [ The bottom shock damper 120 includes a predetermined number of support portions 130 formed along a vibration absorption section G for collecting vibrations in the vibration absorption section C, The vibration absorbing section G is formed at a position radially surrounding the vibration absorbing portion C and the bottom portion C of the floor impact damper 120 is located at the center of the body of the mesh portion 110, And the bottom surface of the mesh part 110 is formed to be lower than the bottom surface of the mesh part 110. The bottom surface of the mesh part 110 is formed with a bottom slab 20, The floor slab (20) according to claim 1, wherein the bottom slab A plurality of second mesh grooves 310 are formed on the styrofoam layer 200 to absorb vibration, a styrofoam layer 200 to be laminated on the vibration-absorbing member 100, The vibration absorbing member 100 includes a mesh portion 110 having a plurality of mesh grooves 111 formed on its surface and a mesh portion 110 located on a lower surface of the mesh portion 110 A bottom impact damper 120 filled with a vibration absorbing aggregate to absorb interlayer vibration and a predetermined number of supporting portions 130 formed on a lower surface of the mesh portion 110 to support the mesh portion 110, The bottom vibration dampers 120 are formed in a predetermined number along the vibration absorption section G in order to collect vibrations in the vibration absorption section C, And the vibration absorbing section G is formed at a position surrounding the vibration absorbing section C in a radial manner, The bottom surface of the shock absorber 120 is formed to be lower than the bottom surface of the mesh portion 110. The vibration absorber 3 is formed to have a BET specific surface area of 5 m 2 / The height difference h between the bottom surface of the support part 130 and the bottom surface of the floor impact damper 120 is less than 10 mm and the floor slab 20 dividing the floor of the multi- (100) formed on the floor slab (20) and absorbing vibrations. The vibration absorbing member (100) for absorbing vibrations is provided on the floor slab (20) , A styrofoam layer (200) stacked on the vibration absorbing member (100), and a mesh layer (300) having a plurality of second mesh grooves (310) formed on the styrofoam layer (200) The vibration absorbing member 100 includes a mesh portion 110 having a plurality of mesh grooves 111 formed on its surface, A bottom impact damper 120 placed on the lower surface of the mesh part 110 and filled with vibration absorbing aggregate to absorb interlayer vibration and a bottom impact damper 120 installed on the lower surface of the mesh part 110 to support the mesh part 110. [ Wherein the bottom shock damper 120 is formed along the vibration absorption section G to collect vibration by the vibration absorption section C and the vibration absorption section C Is positioned at the center of the body of the vibration absorbing member 100 and two or more vibration absorbing sections G are concentrically arranged in the radial direction around the vibration absorbing part C, A plurality of floor impact dampers 120 formed in a vibration absorbing section G disposed at a position on an arcuate surface at a farther radial distance from the vibration absorbing section C, The floor impact damper 120 may be formed to have a smaller width than the predetermined number of the floor impact dampers 120 formed in the section G, Wherein the floor impact damper (120) is formed to have a bottom surface that is lower than a bottom surface of the mesh portion (110). The floor impact damper (120) Thereby providing an anti-noise structure.

An object of the present invention is to stably absorb sound insulation performance by absorbing vibrations in a vibration absorption section using a floor impact damper attached to the vibration absorption member. In addition, the height difference between the bottom impact damper and the support portion is set to be maintained at a predetermined interval, thereby reducing the defects by reducing the long-term deflection in the floored structure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an overall structure of an interlayer-noise-reducing structure of the present invention. FIG.
2 is a view showing a front view of the components of the interlayer-noise-reducing structure of the present invention.
3 is a view showing an overall view of a vibration-absorbing member to which a bottom impact damper of the present invention is attached.
4 is a front view of the vibration-absorbing member with the bottom impact damper of the present invention.
5 is another embodiment of the vibration-absorbing member to which the floor impact damper of the present invention is attached.
6 is a top view of the vibration absorbing member with the bottom impact damper of the present invention attached thereto.
Fig. 7 is another embodiment of the vibration-absorbing member to which the bottom impact damper of the present invention is attached.
8 is an actual photograph of a vibration-absorbing member to which the floor impact damper of the present invention is attached.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

The present invention relates to a vibration absorbing member having a floor impact damper and an interlayer noise preventing structure including the same, wherein a floor impact damper (120) attached to the vibration absorbing member (100) So that vibrations can be absorbed around the vibration absorbing portion C, so that the interlayer sound insulation performance can be stably maintained.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a general view of a vibration absorbing member with a floor impact damper of the present invention and an interlayer noise barrier structure (hereinafter, referred to as an interlayer noise barrier structure) including the same.

The present invention provides an interlaminar noise preventing structure formed between a floor slab 20 partitioning a floor of a building and a floor covering 30 spaced apart from the floor slab 20 based on the wall surface 10, 2, the vibration absorbing member 100, the styrofoam layer 200, and the mesh layer 300 are stacked in this order on the top of the bottom slab 20.

3 to 7 are views of the vibration-absorbing member 100 of the present invention, and the vibration-absorbing member 100 will be described in detail. 8 is an actual photograph of the vibration-absorbing member 100 of the present invention.

The vibration absorbing member 100 includes a mesh unit 110, a floor impact damper 120, and a support unit 130.

A plurality of first mesh grooves 111 are formed on the surface of the mesh portion 110. The mesh part 110 is preferably formed in a serpentine shape to reduce cracks due to sagging of the bottom, but is not limited thereto.

The bottom impact damper 120 is disposed on the lower surface of the mesh part 110 and is used to fill the vibration absorbing material 3 for absorbing the interlayer noise. The vibration absorbing material 3 is preferably a porous lightweight aggregate having a BET specific surface area of 5 m ² / g or more, and the vibration absorbing material 3 is filled in the bottom impact damper 120 as shown in FIG.

The bottom impact damper 120 is connected to the bottom impact damper connection groove 112 formed in the mesh portion 110 and the bottom surface of the bottom impact damper 120 is formed lower than the bottom surface of the mesh portion 110 do. The floor impact damper 120 may fill the vibration absorber 3 with the floor impact damper 120 through the floor impact damper connection groove 112 of the mesh part 110.

It should be noted that the bottom impact damper 120 may be formed to correspond to each position of the first mesh grooves 111.

5, the bottom impact damper 120 may be formed at a lower portion of the mesh portion 110 as shown in FIG.

In other words, the bottom shock damper 120 can be formed at the lower part of the mesh part 110 in a state of filling the vibration dampers with the vibration absorbing material. As shown in the figure, Noise can be reduced.

That is, when the bottom impact damper 120 is positioned below the mesh part 110 in a state in which the vibration absorbing material 3 is contained, the center of gravity is generally downwardly lowered to increase the stability of the bottom impact, Help to catch.

FIG. 6 is a view showing the vibration-absorbing member 100 of the present invention as viewed from above, and a description will be made of a state in which the floor impact damper 120 is disposed.

6, a predetermined number of bottom shock dampers 120 are formed along the vibration absorption section G in order to collect vibration around the vibration absorption section C. As shown in FIG. Preferably, four floor impact dampers 120 are formed along the vibration absorbing section G in the up, down, left, and right directions around the vibration absorbing part C.

FIG. 6 is a view showing a state where two vibration absorbing members 100 are combined, and two vibration absorbing parts C are shown. The vibration absorbing member 100 on the left side (a) is referred to as group 1, the vibration absorbing member 100 on the right side (b) is referred to as group 2, and one vibration absorbing part C per one group is formed do.

The vibration absorbing part C is located at the center of the body of the mesh part 110 of the vibration absorbing member 100 and the vibration absorbing part G is formed at a position surrounding the vibration absorbing part C in a radial manner .

That is, in general, when a shock occurs at a specific position, the vibration propagates in a radial direction. Thus, the present invention allows a predetermined number of the floor impact dampers 120 to be disposed in the vibration absorbing section G in a radial form.

Accordingly, when noise is generated in the cutter, the bottom shock damper 120 absorbs and attenuates the vibration around the vibration absorbing portion C, and the attenuated vibration is collected around the vibration absorbing portion C, So that vibration can be attenuated secondarily.

7 is a view showing another embodiment of the present invention in which a predetermined number of floor impact dampers 120 are formed along a vibration absorption section G having an arc shape centered on the vibration absorption portion C. Accordingly, the vibration can be absorbed by the vibration absorbing part (C) so that the vibration can be efficiently absorbed to attenuate the interlayer noise. Also, FIG. 7 shows a vibration absorbing member 100 which is a group different from FIG. 6, and a plurality of vibration absorbing members 100 may be installed to absorb vibrations.

The height difference h between the bottom surface of the supporting portion 130 and the bottom surface of the floor impact damper 120 is set so that the floor impact damper 120 can be supported by the floor slab 20 instead of the supporting portion 130 10 mm or less, preferably 5 mm or less.

The floor impact damper 120 replaces the support portion 130. As a result, the support portion 130 is turned off as time elapses due to the nature of the floored structure, and the vibration absorbing member 100 is entirely stuck Can be prevented. The height difference h between the bottom surface of the support part 130 and the bottom surface of the floor impact damper 120 is formed at an interval of 5 mm so that the floor impact damper 120 serves as a structural support, It is possible to have a long-term and stable interlayer sound insulation effect by reducing the cracks and blocking the penetrating sound due to the cracks.

The supporting part 130 serves as a column of the floated structure, and a predetermined number is formed on the lower surface of the mesh part 110 to support the mesh part 110. The supporting part is formed of an elastic material so as to have an elastic force. Preferably, the supporting part is made of a material such as PVC or EVA which is resistant to internal impact and is easy to absorb shock.

The styrofoam layer 200 is laminated on the vibration absorbing member 100 and is preferably formed of a material having an elastic force so as to be formed in order to isolate the continuity of sound with heat insulation performance. The styrofoam layer 200 may be formed of a material different from the vibration absorbing member 100 and the mesh layer 300 for negative segmentation and the styrofoam layer 200 may be deformed in height depending on the thickness of the bottom structure. Of course.

The mesh layer 300 is laminated on the styrofoam layer 200 to form a plurality of second mesh grooves 310. The mesh layer 300 is laminated on the upper part of the styrofoam layer 200. It is preferable that a mesh network is formed in an oblique direction so that adhesion performance and deflection deviation with the floor mortar positioned on the upper part of the mesh layer (Bottom mortar not shown). Further, the mesh layer 300 is preferably made of a PVC material, and the vibration absorbing member 100 is also preferably made of a PVC material.

Since the mesh layer 300 is formed in a diagonal direction, it is formed in a structure that is easy to be coupled with the styrofoam layer 200. The cracks of the bottom mortar to be applied to the upper part of the mesh layer 300 are sine- The mesh layer 300 may be formed in an oblique direction to reduce the cracks.

Fig. 9 relates to another embodiment of the present invention, and another embodiment will be described with reference to the same. 9 is a schematic drawing showing the mesh portion 110 roughly.

The present invention is characterized in that two or more vibration absorbing sections G are arranged in a radial pattern around a vibration absorbing part C and arranged at a position on a circular arc with a larger radius around the vibration absorbing part C A plurality of floor impact dampers 120 formed in the vibration absorbing section G are formed in a predetermined number of the bottom impact dampers 120 formed in the vibration absorbing section G arranged at a circular arc position near the center of the vibration absorbing part C, (120).

9 shows two vibration absorbing sections and a vibration absorbing section arranged radially near the vibration absorbing section C as a first vibration absorbing section G1, And the vibration absorption region arranged in a radial pattern is indicated by a second vibration absorption period (G2).

 The amount of the vibration absorbing aggregate filled in the predetermined number of the bottom impact dampers 120 disposed in the first vibration absorbing section G1 is set to be greater than the amount of the vibration loaded in the bottom impact damper 120 formed in the second vibration absorbing section G2 More than the amount of absorbent aggregate is filled.

The size of the floor impact damper 120 is set so that the size of the floor impact damper 120 is different from that of the vibration absorbing portion C when the shock is generated in the water, The floor impact damper 120 may be formed to be smaller than the floor impact damper 120 in the vicinity of the vibration absorbing portion C. That is, as the size of the bottom impact damper 120 becomes smaller, the vibration can be sufficiently absorbed even if the amount of the vibration absorbing material is reduced.

Also, although two vibration absorption sections are shown in the drawing, it is needless to say that the number of vibration absorption sections may be increased to three or more.

As described above, according to the present invention, the vibration absorbing member 100, the styrofoam layer 200, and the mesh layer 300 are laminated one after another between the bottom slab 20 and the bottom flooring 30, The floor impact damper 120 absorbs and attenuates vibrations, so that the interlayer noise can be effectively reduced.

Although the present invention has been described with reference to the preferred embodiments thereof with reference to the accompanying drawings, it will be apparent to those skilled in the art that many other obvious modifications can be made therein without departing from the scope of the invention. Accordingly, the scope of the present invention should be interpreted by the appended claims to cover many such variations.

3 Vibration absorber
10 Wall
20 floor slab
30 floor finish
100 vibration absorbing member
110 mesh portion
111 1st mesh groove
112 Floor Impact Damper Connection Groove
120 Floor Impact Damper
130 support
200 styrofoam layer
300 mesh layer
310 2nd Mesh Home

Claims (4)

A floor slab (20) defining a floor of the apartment house and a floor covering (30) spaced apart from the floor slab (20)
A mesh portion 110 having a plurality of mesh grooves 111 formed on its surface,
A floor impact damper 120 placed on the lower surface of the mesh part 110 and filled with vibration absorbing aggregate to absorb interlayer vibration,
And a predetermined number of supports 130 formed on a lower surface of the mesh unit 110 to support the mesh unit 110,
The bottom shock damper 120 is formed in a predetermined number along the vibration absorption section G so as to collect vibration by the vibration absorption section C,
The vibration absorbing portion C is positioned at the center of the body of the mesh portion 110 and the vibration absorbing portion G is formed at a position surrounding the vibration absorbing portion C in a radial manner,
Wherein a bottom surface of the bottom impact damper (120) is formed lower than a bottom surface of the mesh portion (110).
An interlayer-type noise preventing structure formed between a floor slab (20) for partitioning a floor of a house and a floor finishing material (30) formed apart from the floor slab (20)
A vibration absorbing member 100 formed on the bottom slab 20 for absorbing vibration,
A styrofoam layer (200) laminated on the vibration absorbing member (100)
A plurality of second mesh grooves 310 are formed and a mesh layer 300 is stacked on the styrofoam layer 200,

The vibration absorbing member (100)
A mesh portion 110 having a plurality of mesh grooves 111 formed on its surface,
A floor impact damper 120 placed on the lower surface of the mesh part 110 and filled with vibration absorbing aggregate to absorb interlayer vibration,
And a predetermined number of supports 130 formed on a lower surface of the mesh unit 110 to support the mesh unit 110,
The bottom shock damper 120 is formed in a predetermined number along the vibration absorption section G so as to collect vibration by the vibration absorption section C,
The vibration absorbing portion C is located at the center of the body of the vibration absorbing member 100 and the vibration absorbing portion G is formed at a position surrounding the vibration absorbing portion C in a radial manner,
Wherein a floor surface of the floor impact damper (120) is formed lower than a bottom surface of the mesh part (110).
3. The method of claim 2,
The vibration absorbing aggregate is formed to have a BET specific surface area of 5 m ² / g or more,
Wherein the vibration absorbing member 100 is formed such that a height difference h between the bottom surface of the supporting portion 130 and the bottom surface of the floor impact damper 120 is less than 10 mm. Lt; RTI ID = 0.0 > 1, < / RTI >
An interlayer-type noise preventing structure formed between a floor slab (20) for partitioning a floor of a house and a floor finishing material (30) formed apart from the floor slab (20)
A vibration absorbing member 100 formed on the bottom slab 20 for absorbing vibration,
A styrofoam layer (200) laminated on the vibration absorbing member (100)
A plurality of second mesh grooves 310 are formed and a mesh layer 300 is stacked on the styrofoam layer 200,

The vibration absorbing member (100)
A mesh portion 110 having a plurality of mesh grooves 111 formed on its surface,
A floor impact damper 120 placed on the lower surface of the mesh part 110 and filled with vibration absorbing aggregate to absorb interlayer vibration,
And a predetermined number of supports 130 formed on a lower surface of the mesh unit 110 to support the mesh unit 110,
The floor impact damper 120 is formed along the vibration absorption section G to collect vibration by the vibration absorption section C,

The vibration absorbing portion C is located at the center of the body of the vibration absorbing member 100 and two or more vibration absorbing portions G are disposed radially in a concentric circle around the vibration absorbing portion C,
The plurality of floor impact dampers 120 formed in the vibration absorbing section G disposed at the position of the arc on the farther radial side with respect to the vibration absorbing part C are arranged in the vicinity of the vibration absorbing part C, Is formed to have a smaller size than a predetermined number of the bottom impact dampers (120) formed in the vibration absorbing section (G) disposed at a circular arc position,

Wherein a floor surface of the floor impact damper (120) is formed lower than a bottom surface of the mesh part (110).

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