KR100949782B1 - Sound insulation member and structure for reducing noise using the same - Google Patents

Abstract

The present invention includes a plurality of protrusions 110 protruding from the lower surface of the main body; Grooves 120 formed on the upper surface of the forming position of the projection (110); By presenting a shock absorbing member 100 comprising a; reinforcing ribs 130 protruding on the lower surface of the main body to connect and reinforce the plurality of protrusions 110, while preventing the increase of the weight of the structure, the increase in construction cost, Efficiently reduce the transmission of noise and heavy impact sound.

Noise reduction, buffer

Description

SOUND INSULATION MEMBER AND STRUCTURE FOR REDUCING NOISE USING THE SAME}

The present invention relates to the field of construction, and more particularly, to a structure for noise reduction to reduce the 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 is a cross-sectional view showing the structure of a conventional general slab structure.

As shown, it basically takes a structure in which the bottom layer 2, such as ondol, is formed on the top of the concrete slab 1, in order to absorb the above-mentioned floor impact sound, the styrofoam between the slab 1 and the bottom layer 2; Shock-absorbing layer 3 made of a cushioning material such as EVA or the like is further formed.

However, such a buffer material is pointed out as a problem in that it has excellent buffering performance against high frequency noise but cannot exhibit its performance against low frequency noise.

In other words, the structure of forming the impact sound buffer layer 3 by the buffer material prevents the transmission of the light impact sound, which is 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 slab 1 must be thickened, but in this case, since the weight of the structure increases, efficient design cannot be achieved and construction cost increases. It cannot be a fundamental solution.

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

The present invention, in order to achieve the object as described above, a plurality of protrusions 110 formed on the lower surface of the main body; Grooves 120 formed on the upper surface of the formation position of the protrusion 110; Presenting a shock absorbing member 100 comprising a; reinforcing ribs 130 protruding on the lower surface of the body to connect and reinforce between the plurality of protrusions 110.

The plurality of protrusions 110 and the reinforcing ribs 130 are preferably formed to have a lattice structure.

It is preferable to further include; auxiliary ribs 140 protruding from the lower surface of the main body so as to connect and reinforce between the core portions of the reinforcing rib 130.

The plurality of protrusions 110, the reinforcing ribs 130, and the auxiliary ribs 140 may be formed to have a lattice structure.

The degree of protrusion of the auxiliary ribs 140 is preferably smaller than the amount of protrusion of the reinforcing ribs 130.

Preferably, through holes 150 are formed in the inner region formed by the plurality of protrusions 110 and the reinforcing ribs 130.

The buffer member 100 is preferably formed of a rubber material.

The rubber material is preferably formed by mixing at least one material selected from waste tire chips, rubber chips, ethylene vinyl acetate chips, and expanded polystyrene with an inorganic or organic binder.

The present invention is another means for achieving the above object, the slab (10); The buffer member 100 installed on the upper portion of the slab 10; An air layer 20 formed by a space between the slab 10 and the buffer member 100; It proposes a noise reduction structure comprising a; finishing layer 30 installed on the upper portion of the buffer member (100).

The upper surface of the slab 10, it is preferable that the elastic support layer 200 for elastically supporting the lower end of the projection 110 of the buffer member 100 to the upper side.

The buffer member 100 is preferably installed such that a portion of the lower end of the protrusion 110 is inserted into an upper surface of the elastic support layer 200.

The elastic support layer 200 is preferably formed so that the lower surface is coincident with the upper surface of the slab 10, the upper surface is flat.

The elastic support layer 200 is preferably formed of a porous material.

It is preferable that the heat insulation layer 300 is formed between the buffer member 100 and the finishing layer 30.

It is preferable that the insulating layer 400 is formed in the transverse direction between the side wall of the buffer member 100 and the finishing layer 30 and the wall 11.

It is preferable that the insulating layer 400 is formed in the transverse direction between the side wall of the buffer member 100, the finishing layer 30, and the elastic support layer 300 and the wall 11.

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 Figures 3 and 4, the buffer member 100 according to the present invention, basically, a plurality of projections 110 formed on the lower surface of the main body; Grooves 120 formed on the upper surface of the forming position of the projection (110); And a reinforcing rib 130 protruding from the lower surface of the main body so as to connect and reinforce between the plurality of protrusions 110.

As shown in FIG. 2, the shock absorbing member 100 is installed between the slab 10 and the finishing layer 30. The protrusion 110 protruding from the lower surface of the shock absorbing member 100 is the slab 10. It serves to form the air layer 20 in the space between the, and by the cushion role of the air layer 20 can be reduced as well as the transmission of the heavy impact sound as well as the light impact sound.

Grooves 120 are formed on the upper surface of the formation position of the projections 110, and the grooves 120 not only exhibit sound absorption effects, but also increase the density of the projections 110, thereby increasing the load and impact distribution. Make a big difference.

The reinforcing rib 130 is formed to protrude on the lower surface of the main body to connect and reinforce between the plurality of protrusions 110, so that the plurality of protrusions 110 to maintain a certain position in spite of the impact, the weight of the impact sound Ensure efficient transmission.

It is preferable in view of structural stability that the plurality of protrusions 110 and the reinforcing ribs 130 have a lattice structure, as shown in FIG. 4.

3 and 4 illustrate a structure further including an auxiliary rib 140 protruding from a lower surface of the main body to connect and reinforce core portions of the reinforcing rib 130 as a first embodiment of the buffer member 100. will be.

The auxiliary ribs 140 allow the projections 110 and the reinforcing ribs 130 to maintain a predetermined position despite the impact, thereby efficiently reducing the transmission of the heavy shock sound.

Even when the auxiliary ribs 140 are formed as described above, it is preferable that the plurality of protrusions 110, the reinforcing ribs 130, and the auxiliary ribs 140 take a lattice structure together in view of structural stability.

The degree of protruding from the lower surface of the main body is preferably formed in the order of the projection 110, the reinforcing rib 130, the auxiliary rib 140, which reduces the contact area between the buffer member 100 and the slab 10 air layer This is because it is possible to secure enough (20).

5 and 6 illustrate a structure in which a through hole 150 is formed in an inner region formed by a plurality of protrusions 110 and reinforcing ribs 130 as a second embodiment of the buffer member 100.

This has the advantage of being able to efficiently perform the role of absorbing and shock-absorbing for the heavy impact sound while saving the material of the buffer member 100.

In order for the shock absorbing member 100 to perform a better shock absorbing function, it is preferable that the shock absorbing member 100 is formed of a rubber material having excellent elasticity, and as a result of experiments, waste tire chips, rubber chips, ethylene vinyl acetate chips, foamed polystyrene, etc. It was shown that the use of the mixture formed by mixing the inorganic or organic binders was excellent in noise reduction effect.

Here, the inorganic or organic binder is preferably used to be 5 to 20% (volume) of the entire composition of the buffer member 100.

Hereinafter, with reference to FIGS. 7 to 10, an embodiment of the noise reduction structure to which the shock absorbing member 100 is applied will be described.

Noise reduction structure according to the present invention is basically, slab (10); The buffer member 100 is installed on the top of the slab (10); An air layer 20 formed by a space between the slab 10 and the buffer member 100; It is configured to include; a finishing layer 30 installed on the upper portion of the buffer member (100).

The lower end of the projection 110 of the buffer member 100 may take a configuration in direct contact with the upper surface of the slab 10, as shown in Figure 7, the elastic support layer 200 on the upper surface of the slab 10 It is more preferable to take the structure of elastically supporting the lower end of the projection 110 of the buffer member 100 upward by the elastic support layer 200.

In this case, the upper shock is first buffered by the protrusions 110 and the air layer 20 of the buffer member 100, and the shock transmitted to the protrusions 110 is again restored by the elastic support layer 200. This is because a double buffering effect can be obtained.

This effect is stronger when the lower end portion of the protrusion 110 of the buffer member 100 has a structure inserted into the upper surface of the elastic support layer 200 to some extent.

The elastic support layer 200 is provided on the upper surface of the slab 10, when the upper surface of the slab 10 is not flat, the lower surface coincides with the upper surface of the slab 10, by forming the upper surface flat, The upper surface of the slab structure as a whole to achieve the effect of enabling a stable construction of the buffer member (100).

In order for the elastic support layer 200 to perform the function well, it is preferable that the elastic support layer 200 is formed of a porous material. As a result of the experiment, materials such as polyester, polystyrene, polypropylene, glass wool, rock wool, urethane sponge, and fiber material are used. The noise reduction effect was found to be excellent.

As shown in FIG. 8, when the heat insulation layer 300 is formed between the buffer member 100 and the finishing layer 30, the noise and impact reduction effects are not only better than the heat insulation effect.

The heat insulating layer 300 is preferably formed of a polyolefin material. Experimental results show that the use of a material such as expanded polystyrene, expanded polyethylene, expanded polypropylene, etc. is excellent.

As shown in FIG. 9, in the case where the insulating layer 400 is formed in the transverse direction between the buffer member 100, the finishing layer 30, and the side surface of the elastic support layer 300 and the wall 11, the wall is formed. Since the transmission of the shock through (11) is prevented, more excellent noise and impact reduction effect can be obtained.

When the material of the insulating layer 400 is the same as the above insulating layer 300, the effect was found to be excellent.

Hereinafter, with reference to FIG. 10 will be described an embodiment of an experiment for determining the effect of the structure for noise reduction according to the present invention.

100 parts of waste tire chips having a size of 0.1 to 2 mm and 5 to 20 parts of a urethane binder are mixed as a molding material by mixing using a mixing device, and the shock absorbing member 100 is formed by heat press molding using steam or electricity in a molding machine. Was molded.

Formation of the projections 110 and the grooves 120 used a mold rather than a perforation.

The structure of the buffer member 100 obtained by the above embodiment, the elastic support layer 200 made of polyester material, the heat insulating material 300, and the like were constructed as shown in FIG. 10.

Subsequently, the floor shock sound level was measured according to KS F 2810. Measured.

That is, the test structure 40 was constructed so that the sound receiving chamber 42 was formed therein, and the structures of the upper buffer member 100, the elastic support layer 200, the heat insulating material 300, etc. were installed on the structure 40. , The finishing layer 30 was constructed thereon, and the impact sound generator 41 was installed.

Impact sound generator 41 was installed in a total of five points, such as the center and the edge of the finishing layer 30, the sound receiving chamber 42 was provided with five microphones 43 for measuring the average sound pressure level.

The following table shows the floor impact sound level measured in this way.

Example 1 is a case where the first embodiment (Figs. 3, 4) of the buffer member according to the present invention is applied, Example 2 is a case when the second embodiment (Figs. 5, 6) of the buffer member according to the present invention is applied Comparative Example 1 relates to a case in which polyethylene foam and lightweight foamed concrete are applied, and Comparative Example 2 relates to a case in which no sound insulating material is applied.

Table 1 shows the experimental results divided into the case of light impact sound and heavy impact sound, it can be seen that the case according to the embodiment of the present invention has excellent sound insulation effect compared to the comparative examples.

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.

2 to 10 show an embodiment of the present invention,

2 is a sectional view of a first embodiment of a noise reduction structure.

3 is a sectional view of a first embodiment of a cushioning member.

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a sectional view of a second embodiment of a cushioning member.

6 is a cross-sectional view taken along line B-B in FIG.

7 is a sectional view of a second embodiment of a noise reduction structure.

8 is a sectional view of a third embodiment of a noise reduction structure.

9 is a sectional view of a fourth embodiment of a noise reduction structure.

10 is a sectional view of an experimental example.

** Description of the symbols for the main parts of the drawings **

10: slab 11: wall

20: air layer 30: finishing layer

100: buffer member 110: protrusion

120: groove 130: reinforcement rib

140: auxiliary rib 150: through hole

200: elastic support layer 300: heat insulation layer

400: insulation layer

Claims (16)

A plurality of protrusions 110 protruding from the lower surface of the main body; Grooves 120 formed on the upper surface of the formation position of the protrusion 110; A reinforcing rib 130 protruding from a lower surface of the main body so as to connect and reinforce between the plurality of protrusions 110; And auxiliary ribs 140 protruding from a lower surface of the main body so as to connect and reinforce core portions of the reinforcing ribs 130. The plurality of protrusions 110, the reinforcing ribs 130, and the auxiliary ribs 140 are formed to have a lattice structure. The degree of protrusion of the auxiliary ribs 140 is less than the degree of protrusion of the reinforcing ribs 130, characterized in that the buffer member (100). delete delete delete delete The method of claim 1, Shock absorbing member (100), characterized in that through holes (150) are formed in the inner region formed by the plurality of protrusions (110) and reinforcing ribs (130). The method of claim 1, The buffer member 100 is a buffer member 100, characterized in that formed by a rubber material. The method of claim 7, wherein The rubber material is A buffer member (100), characterized in that formed by mixing at least one material selected from waste tire chips, rubber chips, ethylene vinyl acetate chips, expanded polystyrene, and inorganic or organic binders. Slab 10; The buffer member of any one of claims 1 or 6 to 8 installed on the top of the slab (10); An air layer 20 formed by a space between the slab 10 and the buffer member 100; Finishing layer 30 installed on the buffer member 100; Noise reduction structure comprising. 10. The method of claim 9, On the upper surface of the slab 10, Noise reduction structure, characterized in that the elastic support layer 200 is formed to elastically support the lower end of the protrusion 110 of the buffer member 100 to the upper side. The method of claim 10, The buffer member 100 is A noise reduction structure, characterized in that the lower portion of the protrusion 110 is installed to be inserted into the upper surface of the elastic support layer (200). The method of claim 10, The elastic support layer 200 Noise reduction structure, characterized in that the lower surface coincides with the upper surface of the slab, the upper surface is formed to be flat. The method of claim 10, The elastic support layer 200 Noise reduction structure, characterized in that formed by a porous material. 10. The method of claim 9, Between the buffer member 100 and the finishing layer 30 Noise reduction structure, characterized in that the insulating layer 300 is formed. 10. The method of claim 9, Noise reduction structure, characterized in that the insulating layer 400 is formed in the transverse direction between the side wall and the wall 11 of the buffer member 100 and the finishing layer 30. 10. The method of claim 9, Noise reduction structure, characterized in that the insulating layer 400 is formed in the transverse direction between the side wall of the buffer member 100, the finishing layer 30 and the elastic support layer 300 and the wall (11).

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