KR102119407B1 - Vibration dampener for reduction of crashing sound - Google Patents

Abstract

The present invention insulates and prevents vibrations caused by shocks or vibrations generated on ondol floors of various buildings, such as multi-family houses and apartments, and prevents noise generated from one floor from being transmitted to another floor through the lower part of the interlayer structure. It is intended to provide.
To this end, the present invention discloses a high-rigidity vibration isolation device for interlayer noise reduction, in which an inner surface having a hexagonal star-shaped truss structure is integrally formed by overlapping two triangular tubes in the hollow of the tubular outer surface.

Description

VIBRATION DAMPENER FOR REDUCTION OF CRASHING SOUND

In the present invention, when the floor structure of various buildings such as multi-family houses or apartments is formed, it is installed on the upper surface of the slab, which is an interlayer structure, to insulate and prevent waves caused by shock or vibration from the outside, so that noise generated in one layer lowers the lower part of the interlayer structure. It relates to an anti-vibration barrier that prevents it from being transmitted to other floors. More specifically, it is built between an ondol layer and a concrete floor slab for heating the indoor floor, effectively absorbing and alleviating the shock applied to the floor, and interlayering the apartment house. It is possible to significantly reduce the noise, and also has excellent strength, and relates to a vibration damping device for a dry ondol floor, which maintains a damping function and stability even when used for a long time.

In general, the wall-type concrete slab structure, which is a common characteristic of various multi-storey multi-family houses such as multi-family houses or apartments, exhibits high rigidity and tightness, and sufficiently blocks air propagation noise transmitted to the air, but walks or objects such as floor impact noise. When an impact or vibration caused by the dropping of the product is applied directly to the floor, it is transformed into a solid propagation sound and hardly attenuated, and the floor slab is bent and vibrated and the vibration is radiated into the air as sound and transmitted to the lower layer or adjacent generations.

The floor impact sound is a light impact sound that generates a lot of high-frequency components, such as the sound coming down from the floor due to the impact of the floor when a small object falls and the chair is moved, and occurs when a child runs or an adult walks. It is classified as a heavy impact sound that generates a lot of low-frequency components, such as a heavy impact coming from the lower floor.

Recently, the Ministry of Land, Infrastructure and Transport announced the performance level of floor impact noise including 5 types of standard floor structures in order to solve the floor noise problem of apartment houses as the dispute between neighbors due to floor noise in apartment houses became a serious social problem and the number of civil complaints increased rapidly. However, it is limited to apply only products with a certain quality or more specified in this standard at the construction site, but the consumer burden is increasing due to the increase in construction cost.

In addition, the floor of a residential building is regulated to compose a heat insulating material to increase its efficiency and prevent heat loss during cooling and heating in accordance with the "Rules for Building Standards". The floor slab of a multi-family house is subject to construction constraints that must simultaneously meet the insulation and interlayer noise blocking regulations to prevent heat from being transferred to the lower part of the interlayer structure.

On the other hand, the ondol floor structure of the building is largely divided into wet and dry, and the wet structure is an improvement of the traditional gould structure, which has good heat storage performance and is structurally robust, but has a construction period due to formwork, concrete pouring and curing. Due to problems such as delays and maintenance, dry structures have recently been replaced.

That is, since the dry ondol floor structure does not require concrete pouring and curing time, it is possible to shorten the air as much as possible, and, unlike the wet ondol floor structure, there is a difference in each site due to the change in volume according to the moisture content and temperature of the concrete. Since it is possible to secure a uniform and precise construction quality, it is possible to obtain the most important construction cost reduction, air shortening, and standardization of quality.

However, since the dustproof mouth used in the existing dry ondol floor structure transmits the solid radio wave generated from the heat storage top plate to the lower layer in the form of airflow through the space between the top plate and the floor slab, it is insufficient to meet the standards for preventing floor noise. There are limits.

In order to solve such a conventional problem, a dust-proofing device for blocking the floor impact sound of an apartment house developed and registered by Lee Geum-jae among the present inventors is disclosed in Korean Patent Registration No. 10-1322207. This is composed of a structure in which a resonance hole 35 is formed in the center as shown in FIG. 1, and a plurality of deformation-inducing grooves 37 are formed at regular intervals on the outer circumferential surface. There is a problem in that durability and structural stability are significantly deteriorated due to severe changes in physical properties such as fatigue resistance and durability due to aging due to load and displacement of the dustproof device.

That is, in order to increase the effect of reducing the floor impact sound, a flexible material having a suitable loss factor should be used to reduce the spring constant, and consider the opposite characteristics of satisfying vibration isolation and durability at the same time. If the durability is improved by improving the dynamic multiplication factor, especially the vibration constant (vibration damping effect) decreases due to the problem of an increase in the spring constant, on the contrary, if the dynamic magnification is improved and the second moment of section is reduced, the vertical strain increases and the durability decreases. Due to the difficulty in securing stability due to the lack of practicality.

Here, the above-mentioned background technology or the prior art is only for helping the inventor to understand the technical significance of the present invention as information possessed by the inventor or acquired in the process of deriving the present invention, and the technology to which the present invention belongs before filing of the present invention It is said that this does not mean a technique widely known in the field.

KR 101322207 B1 (2013.10.21) KR 1020090076747 A (2009.07.13) KR 101559955 B1 (2015.10.06) KR 200378945 Y1 (2005.03.07) KR 200406999 Y1(2006.01.17)

Won-taek Kim and 1 other, research on the design of a butyl elastic compound and vibration control system to improve noise isolation performance. Elastomer and Composite Vol. 49, No. 2 (2014) pp.95-102.

Accordingly, the present inventor puts emphasis on solving the limitations and problems of the existing anti-vibration systems by comprehensively considering the above-mentioned matters, and minimizes the vertical strain by increasing the strength, without compromising the structural and design stability of the apartment. In terms of material use, it is economical and has excellent soundproofing and dustproofing properties, such as absorbing and damping solid transmission sound, so that efforts are being made to develop a new structured anti-vibration device that can simultaneously achieve the effect of meeting the interlayer noise blocking regulations. While inclined and constantly researching, as a result, the present invention was invented.

Therefore, the technical problem and the object to be solved by the present invention is to provide a high-rigidity vibration isolation device for interlayer noise reduction to improve durability and structural stability by having excellent sound insulation performance of a floor impact sound and having excellent strength.

Here, the technical problems and objects to be solved by the present invention are not limited to the technical problems and objectives mentioned above, and other technical problems and objectives not mentioned will be clearly understood by those skilled in the art from the following description.

A specific means according to an embodiment of the present invention for achieving the above-described object and solving the technical problem is a two-sided triangular tube in the hollow of the tubular outer surface is a hexagonal star-shaped truss structure (Truss structure) A high-rigidity dustproof device for reducing inter-layer noise is proposed, wherein the inner surface is integrally formed.

Thus, the present invention can effectively attenuate low-frequency vibration and solid transmission sound by minimizing the cross-sectional area while increasing the compressive strength and securing stability against vertical deformation by increasing the cross-sectional secondary moment for the same cross-sectional area.

In a preferred embodiment of the present invention, the pipe wall thickness of the outer surface body and the pipe wall thickness of the inner surface body are formed in a ratio of 2:1 to 3:2, thereby improving rigidity and flexibility due to vibration.

In a preferred embodiment of the present invention, the inner surface is formed to be symmetrical every 30 degrees relative to the center of the outer surface, thereby minimizing stress due to tension and compression.

In a preferred embodiment of the present invention, the outer surface has a diameter of 40 mm, a height of 50 mm, a cross-section of a hexagonal hole is formed in the center of the inner surface, and the six vertex portions are the inner circumference of the outer surface. By forming integrally with the surface, it is possible to more effectively increase the cross-sectional secondary moment for the same cross-sectional area.

An embodiment of the present invention equipped with means and a configuration for achieving the above object and solving a technical problem, a truss structure having a hexagonal cross-section by overlapping two triangular tubes in the hollow of the tubular outer surface In combination, it is possible to increase the compressive strength and secure the stability against vertical deformation by increasing the cross-sectional secondary moment for the same cross-sectional area. In addition, due to the morphological characteristics of the cross-section, it can effectively attenuate low-frequency vibration and solid transmission sound. Can be.

In addition, since the dynamic magnification, durability and aging characteristics are improved and strengthened, and deformation such as volume due to temperature changes is minimized, the ondol floor can be supported and supported firmly and stably by maintaining the intrinsic elasticity and maintaining the inherent elasticity even when used for a long time. Not only can it improve the structural stability of the soundproofing and dustproof performance, it can greatly reduce the floor impact noise, thereby significantly reducing the floor noise.

Here, the effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is an exemplary view showing an anti-vibration device according to the prior art.
2 is a perspective view showing an anti-vibration hole according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a dustproof according to an embodiment of the present invention.
4 is a cross-sectional view showing a local part of an ondol floor to which a dustproof mouth is applied according to an embodiment of the present invention.
5 is a standard test report of the floor impact sound blocking performance of an ondol floor to which a dust isolation device is applied according to an embodiment of the present invention.
6 is a standard test report of the floor impact sound blocking performance of an ondol floor to which a dust isolator according to the prior art is applied.

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

Prior to this, the terms to be described later are defined in consideration of functions in the present invention, which clearly indicates that the concept conforms to the technical spirit of the present invention and should be interpreted as meaning commonly used or commonly recognized in the art.

In addition, if it is determined that a detailed description of known functions or configurations related to the present invention may obscure the subject matter of the present invention, the detailed description will be omitted.

Here, the attached drawings are exaggerated or simplified for a convenience and clarity of description and understanding of the structure and operation of the technology, and it is revealed that each component does not exactly match the actual size and shape.

In addition, when a part includes a certain component, this means that other components may be further included instead of excluding other components unless otherwise specified.

As shown in Figures 2 to 4, the dustproof sphere (D) according to an embodiment of the present invention is a truss structure having a hexagonal cross-section by overlapping two triangular tubes in the hollow of the tubular outer surface 10 The phosphor inner surface 20 is integrally formed.

That is, six vertices of the inner surface 20 are formed on the inner circumferential surface of the outer surface 10 in a unitary shape.

And in the center of the inner surface 20 is guided for easy installation using a separate installation guide, and at the same time, a hexagonal-shaped hole 21 is formed to induce resonance.

Here, the diameter of the outer surface 10 can be made of a tubular having a diameter of 40mm and a height of 50mm, and the inner surface 20 is formed into a tubular shape having two regular triangular tubes overlapped in the hollow of the outer surface 10 with a cross section of a regular hexagonal shape. It can be done.

In addition, the tube wall thickness of the outer surface 10 and the tube wall thickness of the inner surface 20 is preferably formed in a ratio of 2:1 to 3:2, the inner surface 20 is the center of the outer surface 10 It is preferably formed to be symmetrical every 30 degrees as a reference.

For example, the tube wall thickness of the outer surface 10 may be made of 3 mm, and the tube wall thickness of the inner surface 20 may be 2 mm.

The outer surface 10 and the inner surface 20 may be integrally molded by extrusion molding using a plastic-based material such as SEBS or a rubber-based material such as EPDM and SBS (Styrene-Butadiene-Styrene).

That is, since the inner surface 20 is integrally formed in the hollow of the tubular outer surface 10, it can be mass-produced by the extrusion molding method, so productivity is higher than that of the injection molding method, and uniformity of quality can be achieved, and particularly vertical load When deformed, it naturally deforms and induces dispersion and change to the horizontal load, so it can absorb and buffer the impact force applied to the floor more effectively.

In addition, only the edge portion of the lower portion is directly contacted with the bottom slab (S) or the polyethylene foam (B1) placed thereon by the hexagonal hole (21) formed to communicate up and down in the center of the inner surface (20). It can effectively disperse and attenuate the light and heavy impact sound transmitted from the upper layer.

The dustproof sphere (D) according to the embodiment of the present invention configured as described above has excellent compressive strength and can obtain a low-frequency attenuation effect due to a truss-like branch.

That is, the secondary moment of cross-section is increased by the inner surface 20 of the truss structure when applied to the anti-vibration hole (D) by placing it at a distance of 60 cm×30 cm from other adjacent anti-vibration holes on the dry floor of the floating floor structure. The stability of the ondol can be maintained by minimizing the vertical deformation compared to the same load, and the low-frequency solid transmission sound transmitted to the top is diffused in all directions by the inner surface 20 of the truss structure, and then divided into three branches, absorbing sound. Characteristics and damping characteristics can be increased.

According to the analysis of Cremer and Heckl, when the number of branches is α and the ratio of the cross-sectional area before and after the branch is σ, the attenuation amount R of the longitudinal wave at the branch point is expressed by the following equation (1).

Assuming that the vibration isolator D according to an embodiment of the present invention has a branch number of 3 at all branch points and the cross-sectional area before and after the branch is the same, a low frequency attenuation of 9 dB is generated every time a solid transmission sound passes through the branch point. This occurs, indicating that the power level of the solid transmission sound is attenuated to 1/7.9.

In addition, the anti-vibration hole (D) according to an embodiment of the present invention has the same load and the vertical strain compared to the same cross-sectional area due to the inner surface 20 having a hexagonal star-shaped truss structure by overlapping two triangular tubes. It is reduced to about 1/2 and has very stable physical and mechanical properties.

<Test Example 1>

Compressive strength (stress) for each strain of the dust proofing device according to the prior art made of the same material (Fig. 1) and the dustproofing device (D) according to the embodiment of the present invention was commissioned by the Korea Institute for Chemical Convergence Testing, an accredited certification organization, KS It was measured according to the test method prescribed in B 5541, and the results are shown in Table 1 below.

Here, in order to secure the stability of the ondol floor, the dustproof mouth used for the ondol of an apartment house should generally use a maximum vertical strain of 10% or less, and the normal use range is 5% or less.

division Conventional anti-vibration device (cross-section: 8.22cm ² ) Anti-vibration sphere of the embodiment (cross-section: 7.02cm ² ) Strain 2% 8 N/cm ² 16 N/cm ² Strain 4% 16 N/cm ² 31 N/cm ² Strain 6% 23 N/cm ² 44 N/cm ² Strain 8% 29 N/cm ² 56 N/cm ² Strain 10% 36 N/cm ² 65 N/cm ²

As a result of comparing and testing the compressive strength by strain of the conventional anti-vibration ball and the anti-vibration ball (D) according to the embodiment of the present invention, the anti-vibration ball (D) according to the embodiment of the present invention is compared with the conventional anti-vibration ball (FIG. 1). It was found that the strain had a strength of 1.9 times at 4% and a strength of 1.8 times at 10% of strain.

Therefore, in the vibration isolator according to the embodiment of the present invention, the strain is reduced to 1/2 or less with respect to the same load to secure and maintain the stability of the ondol floor.

<Test Example 2>

After constructing the dustproof opening (D) prepared according to the embodiment of the present invention on a dry ondol floor having a floating floor structure as shown in FIG. 4, a standard laboratory measurement of the floor impact sound blocking performance of the ondol floor was performed.

Here, the dry ondol floor of the floating floor structure can be constructed in the following order, method and structure.

First, after attaching a 10 mm thick side buffer (A1) and a 5 mm thick silver foil coated polyethylene foam (A2) along the edge wall surface of the floor slab (S), a 5 mm thick silver foil is attached to the top surface of the floor slab (S). The coated polyethylene foam (B1) is laid and adhered. At this time, in order to maintain the flatness of the floor and to prevent moisture from penetrating, one polyethylene foam and the other polyethylene foam adjacent to each other are attached with an adhesive tape and connected to each other without a gap.

Subsequently, a 30 mm thick rubber sponge (B2) is placed on the polyethylene foam (B1) in close contact with each other so that a gap does not occur with the side buffer (A1) and the polyethylene foam (A2) on the wall, and the rubber sponge (B2) ) Insert the anti-vibration hole (D) into the hole formed at regular intervals, and arrange it so that it is not separated from the polyethylene foam (B1) on the floor slab (S) by using a separate installation guide.

Subsequently, a 12 mm thick magnesium board (B3) is placed on the rubber sponge (B2) and a dustproof opening (D), and another 12 mm thick magnesium board (B4) and a 10 mm thick rubber sponge (B5) are sequentially placed thereon. Laying is laid so as to be horizontal, and then a 30 mm thick piping panel (B6) is placed on the rubber sponge (B5) in the same direction as the other adjacent panels, and 0.3 mm thick on the panel (B6). After placing the heat-conducting plate (B7), the heating pipe (P) is fitted into the groove of the heat-conducting plate (B7).

At this time, in order to maintain the flatness of the floor and prevent moisture from penetrating, one member and another member adjacent to each other are attached with an adhesive tape or the like to connect to each other without gaps, and the pipe panel (B6) is a rubber sponge (B5). When gaps and gaps may occur, a lingering phenomenon may occur, so it is installed in close contact with the floor surface, and the heating pipe (P) is completely buried so as not to be exposed to the top of the panel (B6).

Afterwards, a 12 mm thick magnesium board (B8) was stacked on the heat conduction plate (B7), and then flooring, such as a floorboard, was applied to finish, to significantly reduce the floor noise of the apartment house, while creating an environmentally friendly dry floor. Can be completed.

The standard laboratory test of the floor impact sound blocking performance of the constructed ondol floor was commissioned by Korea Noise & Vibration Co., Ltd., an accredited certification institution, and measured according to the test methods specified in KS F 2810-1 and KS F 2810-2. It was evaluated by the inverse A characteristic curve of 2863-1 and KS F 2863-2.

In addition, the light shock sound according to the test results was measured at the octave band center frequency of 125 kHz to 2 kHz, and the weight shock sound was measured at 63 kHz to 500 kHz.

As a result of the evaluation, as shown in the test report of FIG. 5, the performance level of the lightweight shock sound is a normalized floor shock sound level calculated from the reverberation time measurement result measured in the sound collection room on the first floor, and is calculated by the inverse A characteristic reference curve. The inverted A characteristic weighted normalized floor impact sound level L'n,AW, which was the single value evaluation amount, was evaluated to be 35 dB.

And, as shown in the test report of the heavy shock sound performance level, the measured value is the floor impact sound level measured in the sound collection room on the first floor, and the inverse A characteristic weighted floor impact sound level L _i calculated by the inverse A characteristic reference curve _{, Fmax,AW} Was rated at 47dB.

<Example of comparison test>

Floor Impact Sound Blocking Performance Standard Laboratory for Comparative Test Examples with Conventional Vibration Isolation in order to confirm and prove that the ondol floor structure to which the vibration isolation device (D) according to an embodiment of the present invention exhibits the optimum effect and performance The measurement was carried out in the same manner as in the above-described example.

As a result of the evaluation, as shown in the test report of FIG. 6, the performance level of the lightweight shock sound is a normalized floor shock sound level calculated from the reverberation time measurement result measured in the first floor sound collection room, and is calculated by the inverse A characteristic reference curve. The inverted A characteristic weighted normalized floor impact sound level L'n,AW, which was the single-value evaluation amount, was evaluated to be 37 dB.

And, as shown in the test report of FIG. 6, the performance level of the heavy impact sound is the floor impact sound level measured in the sound collection room on the first floor, and the inverse A characteristic weighted floor impact sound level L _i calculated by the inverse A characteristic reference curve _{, Fmax,AW} Was rated at 49dB.

Therefore, when the vibration isolator (D) according to an embodiment of the present invention is applied to a dry ondol floor structure, the weight impact sound is reduced by 1.4dB at 63Hz (power level is reduced to 72%) and reduced by 5.5dB at 125Hz (power level is 28 %) to show an excellent low-frequency attenuation effect, and as a result, it can be seen that the dry shock impact performance of the dry ondol was improved to 3rd grade.

On the other hand, the present invention is not limited by the above-described embodiments and the accompanying drawings, and various modifications and applications that are not exemplified within the scope of the technical spirit of the present invention, as well as substitution and equality of each component It is apparent to those of ordinary skill in the art to which the present invention pertains that the present invention can be widely applied by changing to another embodiment.

Therefore, the contents related to modifying and applying the technical features of the present invention should be interpreted as being included within the technical spirit and scope of the present invention.

10: outer surface 20: inner surface
21: hole

Claims (4)

Inside the hollow of a tubular outer body having an outer diameter of 40 mm and a height of 50 mm, two inner triangular tubes are overlapped to form an inner body having a hexagonal star-shaped truss structure integrally, and a cross section is regular in the center of the inner body. A high-rigidity vibration isolation device for reducing inter-layer noise, in which a hole in the shape is formed, and the six vertex portions are formed integrally with the inner circumferential surface of the outer surface.
According to claim 1,
The tube wall thickness of the outer surface and the tube wall thickness of the inner surface, 2:1 to 3:2 formed of a high-strength anti-vibration damper for reducing the interlayer noise.
The method according to claim 1 or 2,
The inner surface is a high-rigidity dustproof device for reducing inter-layer noise formed to be symmetrical every 30 degrees relative to the center of the outer surface.
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