KR101101879B1 - Soundproof structure - Google Patents

Abstract

The present invention plate 130 is installed between the lower slab 110 and the upper finishing layer; And a plurality of noise reduction protrusion members 140 installed on the bottom surface of the plate 130 so as to be in surface contact with the upper surface of the lower slab 110, wherein the plurality of noise reduction protrusion members 140 are fixed. By providing a noise reduction structure characterized in that the central distribution density between the points (F) is distributed higher than the edge distribution density, while preventing the increase of the weight of the structure and the increase of construction cost, It can be reduced efficiently.

Interlayer noise, impact noise reduction, protrusion, buffer, distribution density

Description

Noise Reduction Structures {SOUNDPROOF STRUCTURE}

The present invention relates to the field of construction, and more particularly, to a structure for noise reduction to reduce the inter-floor noise transmitted from the upper floor to the lower floor in a structure such as an apartment.

The noise transmitted from the upper floor to the lower floor is always an important problem in multi-unit buildings such as apartments, and the biggest problem among them is the floor impact sound transmitted from the ceiling of the lower floor. .

These floor impact sounds can be classified into light impact sounds (high frequency noise) generated by scratching the upper floor and the like, and heavy impact sounds (low frequency noise) generated by jumping on the upper floor.

Since floor impact sounds of MDUs cause significant noise pollution, in order to regulate them, the regulations for the recognition and management of floor shock sound insulation structures for MDUs are regulated, and for light impact sounds, KS F 2863- In 1, the details of heavy impact sound are prescribed in KS F 2863-2.

1 and 2 illustrate the structure of a conventional slab structure for noise reduction.

As shown, basically the noise reduction structure is installed between the lower slab 110 and the upper finishing layer (bottom layer such as ondol, heat insulation layer, etc.), which is a noise reduction projection member 40 on the bottom of the plate 130 ) It is about a structure with many installed.

The noise reduction protrusion member 40 is formed of an elastic material to absorb the low frequency noise described above.

However, structurally, as the distance away from the fixed end of the floor weakens, the noise reduction projection member 40 is uniformly distributed, so when the construction is far from the fixed end of the floor close to the fixed end of the floor In some places, it is pointed out that the cost wasted due to relatively excessive construction and increased self-weight of the structure, and it is pointed out as a problem in that it is not effective to reduce the transmission of impact sound when the construction is based near the fixed end of the floor. .

The present invention has been made to solve the above problems, and to provide a noise reduction structure that can effectively reduce the transmission of impact sound, while preventing the increase in the weight of the structure, the increase in construction costs for that purpose. do.

In order to achieve the object as described above, the present invention is a plate 130 is installed between the lower slab and the upper finishing layer 120; And a plurality of noise reduction protrusion members 140 installed on the bottom surface of the plate 130 so as to be in surface contact with the upper surface of the lower slab. The plurality of noise reduction protrusion members 140 may include noise reduction structures. It proposes a noise reduction structure characterized in that the central distribution density between the fixed point (F) of the distribution is higher than the edge distribution density.

The plurality of noise reduction protrusion members 140 may have different sizes depending on the distribution density of the noise reduction protrusion members 140.

The plurality of noise reduction protrusion members 140 may have different intervals L1 and L2 depending on the distribution density of the noise reduction protrusion members 140.

The plurality of noise reduction protrusion members 140 may have different shapes depending on the distribution density of the noise reduction protrusion members 140.

The plurality of noise reduction protrusion members 140 may be distributed such that the distribution density of the noise reduction protrusion member 140 gradually increases as the distance from the fixed point F increases.

According to the distribution density of the noise reduction protrusion member 140, a high density region A1 and a low density region A2 surrounding the high density region A1 may be formed.

The plate 130 may be divided according to the distribution density of the noise reducing protrusion member 140.

The noise reduction protrusion member 140 may be formed to have a smaller area of the lower longitudinal section than an area of the upper longitudinal section of the main body 150.

A plurality of support protrusions 160 may protrude downward from the bottom of the main body 150.

The plurality of support protrusions 160 may be formed around the edges of the main body 152, and an air layer forming groove 170 may be formed in an inner region of the plurality of support protrusions 160.

Reinforcement member 200 is installed on the upper surface of the plate member 130; The reinforcement member 200 further comprises an upper plate 210 and a lower plate 220 spaced apart in the vertical direction; And a lattice forming support member 230 disposed between the upper plate 210 and the lower plate 220.

The present invention proposes a noise reduction structure that can effectively reduce the transmission of noise and heavy impact sound, while preventing an increase in the weight of the structure and an increase in construction cost.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 3 below, the noise reduction structure according to the invention of the plate 130 is installed between the lower slab and the upper finishing layer 120, the surface of the plate 130 so as to be in surface contact with the upper surface of the lower slab Including a plurality of noise reduction protrusion member 140 is installed on the bottom surface, in particular, a plurality of noise reduction protrusion member 140 has a central distribution density between the fixed point (F) of the noise reduction structure is the edge distribution It is characterized in that the distribution is higher than the density.

That is, structurally, the more the distance away from the fixed point (F) of the noise reduction structure is sensitive to the impact sound, by increasing the distribution density of the plurality of noise reduction protrusion member 140, the cost due to excessive construction over the entire area The transmission of impact sound can be efficiently reduced while preventing an increase and an increase in self weight.

The distribution density of the plurality of noise reduction protrusion members 140 is changed by varying the size of the noise reduction protrusion member 140 according to the distribution density of the noise reduction protrusion member 140 as shown in FIG. 3. Can be given.

In other words, the distance between the plurality of noise reduction protrusion members 140 is uniform over the entire area, but the size of the noise reduction protrusion member 140 at the center portion (that is, the center portion of the noise reduction protrusion member 140A). The size is made larger than the size of the noise reduction protrusion member 140 at the edge portion (that is, the edge noise reduction protrusion member 140B).

At this time, the size of the noise reduction protrusion member 140 is largely affected by the cross-sectional area and height, since the interval between the plate 130 and the lower slab is uniform, it is more preferable that the cross-sectional area varies depending on the distribution density.

Alternatively, the distribution density of the plurality of noise reduction protrusion members 140 may be determined by the intervals L1 and L2 of the noise reduction protrusion members 140 according to the distribution density of the noise reduction protrusion members 140 as illustrated in FIG. 4. By changing), you can make changes.

In other words, the plurality of noise reduction protrusion members 140 are the same throughout the entire area, but the distance L1 of the noise reduction protrusion member 140 at the center portion thereof is smaller than the distance L2 at the edge portion thereof. do.

Alternatively, the distribution density of the plurality of noise reduction protrusion members 140 may vary in the shape of the noise reduction protrusion member 140 according to the distribution density of the noise reduction protrusion member 140 as illustrated in FIG. 5. Changes can be made by different polygons, etc.

For example, as shown in FIG. 5, the appearance of the plurality of noise reduction protrusions 140 is the same throughout the entire area, but the noise reduction at the central portion thereof, as indicated by the reference numeral '140-140C'. The protruding member 140 may have a shape without a groove, and as indicated by the reference numeral '140-140D', the noise reducing protrusion member 140 at the edge thereof may have a shape having a groove (H). have.

Alternatively, the distribution density of the plurality of noise reduction protrusion members 140 may be changed by changing two or more elements such as size, interval L1, L2, and shape according to the distribution density of the noise reduction protrusion member 140. Of course you can give.

In addition, as shown in Figures 3 and 4, the distribution density of the plurality of noise reduction protrusion member 140 may vary gradually depending on the area.

That is, the plurality of noise reduction protrusion members 140 may be distributed such that the distribution density of the plurality of noise reduction protrusion members 140 increases gradually as the distance from the fixed point F increases.

In other words, the size or spacing (L1, L2) of the plurality of noise reduction protrusion member 140 may be gradually changed.

Alternatively, as illustrated in FIG. 6, the sizes of the plurality of noise reduction protrusion members 140 may vary in stages. In other words, according to the distribution density of the noise reduction protrusion member 140, it may be divided into a high density region A1 and a low density region A2 surrounding the high density region A1. In other words, the central portion becomes the high density region A1 and the edge portion becomes the low density region.

On the other hand, the plate member 130 may be integrally formed or divided into a plurality.

In the latter case, the plate 130 may be divided into a number of regardless of the distribution density of the noise reduction projection member 140, as shown in Figure 6 according to the distribution density of the noise reduction projection member 140 Since the plate 130 may be uniformly manufactured according to the distribution density of the noise reducing protrusion member 140, the plate 130 may be advantageous in terms of ease of manufacture and ease of construction of the plate 130.

On the other hand, the noise reduction projection member 140 may be formed in various ways, including a cylindrical shape with a constant longitudinal cross-sectional area, as shown in Figures 3 to 6, but as shown in Figure 7 or less of the body 150 It is more preferable that the area of the lower longitudinal section is formed smaller than the area of the upper longitudinal section, as will be described later.

That is, the transmission rate of the heavy shock sound is inversely proportional to the dynamic elastic modulus of the object to be a medium, where the dynamic elastic modulus refers to the dynamic elastic properties of the object. Is to minimize.

In more detail, the upper part of the main body 150 to which the impact is applied is resistant to the impact by high density, and the lower part of the main body 150 to which the shock is transmitted is absorbed by the low density. Depending on the material, it is possible to obtain the effect of noise reduction by the composite material.

The structure in which the longitudinal cross-sectional area decreases from the top to the bottom of the main body 150 may be a hemispherical shape and various other examples. As shown in FIG. 7 and 8, the main body 150 is stepped downward. In the case of taking a structure, it is preferable in terms of easy manufacturing and a simple structure and clearly obtaining the noise reduction effect.

Although the stepped structure may have a two-layered structure, a three-layered structure, or a multilayered structure, there is a limit in the space in which the noise reduction structure may be installed in relation to the height of the building. As you can see, taking a two-layer structure is actually the most efficient.

In this case, the main body 150 includes an upper main body 151 in contact with the bottom surface of the plate member 130; And a lower main body 152 formed at a lower core portion of the upper main body 151 so as to have an area narrower than that of the upper main body 151.

As illustrated in FIGS. 9 and 10, the bottom surface of the lower main body 152 may have a structure in which a plurality of support protrusions 160 protrude downward.

In this structure, the contact area between the noise reduction protrusion member 140 and the lower slab can be reduced, and the damping and spring functions can be performed at the same time, resulting in a better noise reduction effect. Because you can get.

In order to achieve a stable installation structure while minimizing a contact area with the lower slab, it is preferable that the upper support protrusion 160 has a hemispherical shape.

11 to 14, the plurality of support protrusions 160 are formed around the edges of the lower main body 152, and the air layer forming grooves 170 are formed in the inner region of the plurality of support protrusions 160. In this case, since the air in the inner region of the upper air layer forming groove 170 serves as a cushion during elastic driving of the noise reducing protrusion member 140 due to vibration, a more effective low frequency noise reduction effect can be obtained. .

The noise reducing protrusion member 140 may have a structure bonded to the bottom surface of the plate member 130 or may have a structure inserted into the insertion groove 131 formed on the bottom surface of the plate member 130.

In the latter case, it is preferable that the insertion protrusion 180 protrudes from the upper surface of the main body 150 so as to be inserted into the insertion groove 131.

The insertion protrusion 180 is preferably formed at the center of the upper surface of the main body 150, so that the insertion protrusion 180 is located vertically above the upper air layer forming groove 170.

When the up and down elastic driving of the noise reducing protrusion member 140 due to vibration, it is preferable that the air in the inner region of the air layer forming groove 170 is more preferably so that the noise reducing protrusion member 140 is elastically driven in the vertical direction. This is because it can be clearly cushioned.

Of course, the noise reduction protrusion member 140 may simply take a cylindrical structure. However, this structure prevents the transmission of the light impact sound, which is a high frequency noise, but hardly affects the transmission of the heavy impact sound in the low frequency region. Therefore, in order to reduce the weight impact sound, the thickness of the lower slab has to be thickened, but even in this case, since the weight of the structure increases, efficient design cannot be achieved and construction cost increases. There can be no solution.

15 and 16 illustrate embodiments of the noise reduction structure to which the noise reduction protrusion member 140 according to the present invention is applied.

The structure is a plate 130 installed on top of the lower slab; Noise reduction protrusion member (140) installed on the bottom surface of the plate member 130 so as to be in surface contact with the upper surface of the lower slab; It is configured to include; a reinforcing member 200 installed on the upper surface of the plate material (130).

Here, the reinforcing member 200 is the upper plate 210 and the lower plate 220 provided at intervals in the vertical direction; And a lattice forming support member 230 disposed between the upper plate 210 and the lower plate 220.

Since the reinforcing member 200 having such a structure has a low self-weight and excellent resistance to bending load, when the composite structure is formed with the noise reducing protrusion member 140 as described above, an excellent noise reduction effect can be obtained.

The grid forming support member 230 may take various configurations. In general, the grid forming support member 230 may be installed to form a rectangular grid in view of the rectangular shape of the structure.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 is a cross-sectional view of a conventional noise reduction structure.

Figure 2 is a partial perspective view of a conventional noise reduction structure.

3 or less shows an embodiment of the noise reduction projection member according to the present invention,

3 is a plan view of the first embodiment;

4 is a plan view of a second embodiment;

5 is a plan view of a third embodiment;

6 is a plan view of a fourth embodiment;

7 is a sectional view of a fifth embodiment.

8 is a perspective view of a fifth embodiment;

9 is a sectional view of a sixth embodiment;

10 is a perspective view of a sixth embodiment;

11 is a sectional view of a seventh embodiment.

12 is a perspective view of a seventh embodiment.

Fig. 13 is a bottom view of the seventh embodiment.

14 is a use state diagram of the seventh embodiment.

Figure 15 is an exploded perspective view of one embodiment of the structure for reducing noise according to the present invention.

Figure 16 is a cross-sectional view of one embodiment of the structure for noise reduction according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

130: plate 140: noise reduction projection member

151: upper body 152: lower body

160: base protrusion 170: groove for forming the air layer

180: insertion protrusion 200: reinforcing member

210: upper plate 220: lower plate

230: lattice forming support member

Claims (11)

Plate 130 is installed between the lower slab and the upper finishing layer 120; A plurality of noise reducing protrusion members (140) installed on the bottom surface of the plate member (130) to be in surface contact with the upper surface of the lower slab; Including, The plurality of noise reducing protrusion members 140 is characterized in that the central distribution density between the fixed point (F) of the noise reduction structure is distributed so as to be higher than the edge distribution density. The method of claim 1, The plurality of noise reduction protrusion members 140 may have different sizes depending on the distribution density of the noise reduction protrusion members 140. The method of claim 1, The plurality of noise reduction protrusion members 140 are noise reduction structures, characterized in that the interval (L1, L2) different from each other according to the distribution density of the noise reduction protrusion member 140. The method of claim 1, The plurality of noise reduction protrusion members 140 may have different shapes depending on the distribution density of the noise reduction protrusion members 140. The method according to any one of claims 1 to 4, The plurality of noise reduction protrusion members 140 are noise reduction structures, characterized in that the distribution density of the noise reduction protrusion member 140 is distributed so as to gradually increase away from the fixed point (F). The method according to any one of claims 1 to 4, Noise reduction structure comprising a high density area (A1) and a low density area (A2) surrounding the high density area (A1) according to the distribution density of the noise reduction projection member (140). The method according to any one of claims 1 to 4, The plate member 130 is a noise reduction structure, characterized in that formed in accordance with the distribution density of the noise reduction projection member 140. The method according to any one of claims 1 to 4, The noise reduction protrusion member 140 includes a main body 150 in contact with the bottom surface of the plate 130, wherein the main body 150 is formed such that the area of the lower longitudinal section is smaller than the area of the upper longitudinal section. Noise reduction structure characterized in that. The method of claim 8, Noise reduction structure, characterized in that the bottom of the main body 150 has a plurality of supporting protrusions 160 protruding downward. The method of claim 8, The plurality of support protrusions 160 are formed around the edges of the main body 150, and the noise reduction structure, characterized in that the air layer forming grooves 170 are formed in the inner region of the plurality of support protrusions 160. . The method according to any one of claims 1 to 4, Further comprising; reinforcing member 200 installed on the upper surface of the plate 130, The reinforcement member 200 An upper plate 210 and a lower plate 220 installed at intervals in the vertical direction; A lattice forming support member 230 disposed between the upper plate 210 and the lower plate 220; Noise reduction structure, characterized in that it comprises.

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