KR101482434B1 - Floor structure for reducing floor noise with resonance avoidance system - Google Patents

Abstract

The present invention relates to a floor structure with a resonance avoidance system to reduce interlayer noise. The floor structure includes a first resonance avoidance unit having a floor panel spaced apart from a floor slab, and a vibration-proof member interposed between the floor slab and the floor panel to resiliently support the vibration-proof member so that natural frequencies of the floor slab and the floor panel are set to be different to avoid the resonance; and a second resonance avoidance unit having a finishing panel placed on the floor panel to structurally separate the floor panel and the finish panel so that natural frequencies of the floor panel and the finish panel are set to be different to avoid the resonance. Therefore, the vibration from the finishing panel to the floor slab is reduced, and the interlayer noise is decreased. The floor structure may further include a third resonance avoidance unit having a buffer member placed on the floor slab and made of a material to absorb impact transferred to the floor slab, and a support plate interposed between the buffer member and the vibration-proof member to support the vibration-proof member, so that natural frequencies of the floor slab and the support plate are set to be different to avoid the resonance.

Description

TECHNICAL FIELD [0001] The present invention relates to a floor structure for reducing floor noise with a resonance avoiding system,

The present invention relates to an interlayer noise reducing floor structure having a resonance avoiding system, and more particularly, to an interlayer noise reducing floor structure having a resonance avoiding system for reducing a floor impact sound of a building.

Recently, the building type has been concentrated in multi-storey apartment buildings such as apartments and villas. Since the conflict between the residents due to the noise generated in the floor in the apartment building is becoming a major social problem, the floor impact sound blocking performance for ensuring a quiet living environment is more important than anything else.

Such a floor impact sound is classified into a heavy impact sound such as a beeping sound of children and a light impact sound such as a sound of pulling a chair. Here, it is recognized that reinforcing the structure such as increasing the thickness of the floor slab of a building as a heavy impact sound is the most likely solution to the interlayer noise conflict.

However, if the thickness of the floor slab of the building is increased, not only the quantity of the floor slab but also the weight of the building increases, and the dimensions of the main structural members such as columns, bases, and the like also increase. Therefore, it is necessary to increase the construction cost of the building and the construction cost, and the floor height of the building is also increased, which lowers the economical efficiency of the building.

The floor structure of the conventional apartment house is mainly composed of a wet method. The floor structure of the wet type method is, as shown in FIG. 1, a heat insulation material 11 installed on the floor slab 10 A lightweight foamed concrete 12, a closed mortar 13, a finishing material 14, and a pipe 15.

However, in the floor structure according to the conventional wet method, there is no heat insulating material for reducing the floor impact sound, and even if the heat insulating material is replaced with a cushioning material, there is no great effect in reducing the heavy impact sound. The deterioration of the foamed concrete may cause a problem of corrosion of the heat insulating material or the cushioning material.

It is an object of the present invention to provide an interlayer noise reduction floor structure having a resonance avoidance system that greatly reduces a transmission rate of vibration due to a floor impact sound applied to a finishing panel There is.

Another aspect of the present invention is to provide an interlayer noise reducing floor structure including a resonance avoiding system that significantly reduces the absolute amount of vibration energy reaching the bottom slab by dissipating vibration energy sequentially transmitted to each vibration system in multiple stages The purpose.

Technical Solution In order to achieve the above object, the present invention provides a floor panel comprising a bottom panel spaced apart from a floor slab, and an anti-vibration member provided between the bottom panel and the bottom panel to elastically support the bottom panel A first resonant frequency skin which avoids resonance by making the natural frequencies of the floor slab and the floor panel different from each other; And a second resonant frequency skin disposed on the floor panel and having a finishing panel structurally separated from the floor panel to avoid resonance by differentiating the natural frequency of the floor panel and the finishing panel A cushioning member made of a material for reducing noise transmitted to the floor slab from the finishing panel to reduce noise between the flooring slabs and absorbing impact transmitted to the floor slab, And a third resonant circuit skin which is provided between the anti-vibration members and has a support plate for supporting the anti-vibration member and avoids resonance by changing the natural frequency of the bottom slab and the support plate. The present invention provides an interlayer noise reduction floor structure having a floor structure.

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Preferably, the floor panel may be made of a vibration-proof alloy that damps vibration and noise.

Preferably, the second resonator skin may include a waterproof sheet installed between the finish panel and the floor panel such that the finish panel and the floor panel are structurally separated from each other.

Preferably, the second resonant veneer skin is constructed of a prefabricated panel so that the finish panel and the floor panel are structurally separated.

Preferably, the anti-vibration member is formed of a soft steel material and may include a bent portion that is deformed by bending when the load is transmitted to dissipate energy.

Preferably, the bent portion may be bent to have a U-shaped cross section.

Preferably, the first resonator skin may be provided to include an air layer between the bottom panel and the bottom slab.

In accordance with the present invention, a plurality of resonance avoidance systems including a first resonance cavity skin, a second resonance cavity skin, and a third resonance cavity skin are formed on the bottom slab, And the dynamic characteristics of the vibration system constituted by the respective systems are made different from each other, it is possible to provide an effect of greatly reducing the transmission rate of the vibration caused by the floor impact sound applied to the finish panel.

According to an embodiment of the present invention, the attenuation of each vibration system is superimposed due to the first resonance circuit skin, the second resonance circuit skin, and the third resonance circuit skin, and the vibration energy sequentially transmitted to each vibration system is dissipated in multiple stages, It is possible to provide an excellent effect of greatly reducing the absolute amount of vibration energy reaching the bottom slab.

According to an embodiment of the present invention, vibration transmitted to the floor slab is reduced by the multiple resonance avoidance system and the multi-stage vibration energy dissipating system, and noise and vibration radiated to the lower floor room through the floor slab are reduced The interlayer noise of the entire building can be reduced.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a cross-sectional view showing a bottom structure according to a conventional wet process.
2 is a cross-sectional view illustrating an interlayer noise reduction floor structure having a resonance avoidance system according to an embodiment of the present invention.
3 shows a vibration model of an entire floor structure including an interlayer noise reduction floor structure including a floor slab and a resonance avoidance system.

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

First, the embodiments described below are embodiments suitable for understanding the technical characteristics of the interlayer noise reduction floor structure having the resonance avoidance system of the present invention. However, the technical features of the present invention are not limited by the embodiments to which the present invention is applied or explained in the following embodiments, and various modifications are possible within the technical scope of the present invention.

An interlayer noise reduction floor structure having a resonance avoidance system according to an embodiment of the present invention is based on reducing the transmission rate of vibration due to an impact sound applied to the floor of a building by a multi-resonance avoidance system.

The noise reduction floor structure 100 having the resonance avoidance system according to an embodiment of the present invention may include a first resonance cavity skin 110 and a second resonance cavity skin 130 as in the embodiment shown in FIG. Lt; / RTI >

The first resonance circuit skin 110 includes a floor panel 111 provided so as to be spaced apart from the floor slab and a vibration isolator 110 installed between the floor slab and the floor panel 111 to elastically support the floor panel 111. [ Member 113 so as to avoid resonance by making the natural frequency of the floor slab and the floor panel 111 different.

At this time, the floor panel 111 may be installed at a lower portion of a finishing panel 131, which will be described later, to form a floor surface.

Preferably, the bottom panel 111 may be made of a vibration-proof alloy that attenuates vibration and noise.

For example, the anti-vibration alloy may be a Fe-Mn alloy, a Mn-Cu alloy (Sonoston), or the like, for example, by converting vibration and noise generated by a walking load, an impact load, , A Cr-Al-Fe alloy (sementaloy), an Fe-Cr-Al alloy, or the like.

However, the type of the anti-vibration alloy constituting the bottom panel 111 is not limited to the above-described one, and various modifications may be made if the vibration and noise transmitted to the panel member are attenuated. In addition, the bottom panel 111 is not limited to the one made of the anti-vibration alloy but can be modified by various materials.

In addition, the anti-vibration member 113 may be installed between the floor slab and the floor panel 111 to elastically support the floor panel 111.

The anti-vibration member 113 can be applied to any shape as long as the bottom panel 111 can elastically support the bottom panel 111.

For example, as in the embodiment shown in FIG. 2, the anti-vibration member 113 may be formed of a soft steel material and include a bent portion 113a that is deformed by flexural deformation when the load is transmitted to dissipate energy.

At this time, the bent portion 113a may be bent to have a U-shaped cross section. However, the cross-sectional shape of the bent portion 113a is not limited to the illustrated embodiment, and various modifications can be made if the deformation can be concentrated by bending.

The upper surface of the anti-vibration member 113 may be joined to the lower surface of the floor panel 111, and a plurality of anti-vibration members 113 may be provided at appropriate positions. At this time, the U-shaped bent portion 113a functions as an elastic spring to absorb and mitigate the shock transmitted from the floor panel 111. [ That is, when the dynamic load is transmitted from the upper portion of the bent portion 113a, the bent portion 113a is configured to absorb the shock by the bending deformation and to recover the impact, thereby preventing the load transmitted to the floor panel 111 from being directly transmitted to the bottom slab .

In addition, since the anti-vibration member 113 is made of a vibration-proof alloy, it can dissipate dynamic energy and prevent vibration and noise, thereby maximizing vibration reduction effect.

The first resonance circuit skin 110 may include an air layer 114 between the bottom panel 111 and the bottom slab.

That is, as in the illustrated embodiment, the space in which the anti-vibration member 113 is not provided between the floor panel 111 and the floor slab forms the air layer 114.

Accordingly, the air layer 114 prevents resonance due to the floor impact sound of the floor panel 111, thereby reducing vibration.

As described above, the first resonating cavity skin 110 provides the effect that vibration is attenuated by the air layer 114 and the vibration-proof member 113.

The first resonant cavity skin 110 may be formed in such a manner that the bottom slab and the bottom panel 111 are made of a material different from the material of the vibration preventing member 113 and the air layer 114 and the bottom slab and the bottom panel 111 And the resonance can be avoided by changing the natural frequency by the configuration. A detailed description thereof will be described later.

The second resonant frequency skin 130 includes a finishing panel 131 disposed on the floor panel 111 and structurally separated from the floor panel 111 so that the floor panel 111 And the finishing panel 131 are made different from each other, thereby avoiding resonance.

That is, the finish panel 131 may be structurally separated from the bottom panel 111.

At this time, a method for structurally separating the finish panel 131 and the floor panel 111 is applicable without limitation.

For example, as in the embodiment shown in FIG. 2, the second resonating cavity skin 130 may be formed by the finishing panel 131 and the bottom panel 111 such that the finishing panel 131 and the bottom panel 111 are structurally separated from each other. And a waterproof sheet 133 installed between the floor panels 111. [

Accordingly, the finishing panel 131 and the bottom panel 111 are laminated between the waterproof sheet 133, so that they can not be joined and can be structurally separated. Also, even when the finishing panel 131 is made of concrete, the finishing panel 131 and the bottom panel 111 can be separated from each other by preventing leakage of concrete by the waterproof sheet 133.

However, the second resonator skin 130 may be formed by attaching the finishing panel 131 and the bottom panel 111 to the bottom panel 111, 111 may be structurally separated from the finished panel 131 by a prefabricated panel.

For example, the finishing panel 131 may be made of precast concrete and assembled in the field so that the finishing panel 131 and the floor panel 111 are not joined together. Accordingly, due to the material and the structure, the finish panel 131 and the floor panel 111 can be structurally separated.

The finish panel 131 and the bottom panel 111 are structurally separated from each other so that the finish panel 131 and the bottom panel 111 are stacked, Can be supported by the flexural stiffness of the flange 111.

In addition, the second resonator skin 130 may be made of a vibration-proof alloy and may be configured to reduce vibration by the bottom panel 111 having a plate shape.

The second resonance circuit skin 130 generates bending stiffness and vibration reduction effect by the floor panel 111 in a state where the finish panel 131 and the floor panel 111 are structurally separated from each other, The natural frequency of the finishing panel 131 and the floor panel 111 may be different. The resonance avoidance system will be described later.

Meanwhile, the interlayer noise reduction floor structure 100 having a resonance avoidance system according to an embodiment of the present invention may further include a third resonator skin 150.

The third resonance circuit skin 150 includes a cushioning member 151 formed on the bottom slab and made of a material absorbing an impact transmitted to the bottom slab and a cushioning member 151 disposed between the cushioning member 151 and the vibration- And a support plate 153 for supporting the anti-vibration member 113. The resonance can be avoided by making the natural frequencies of the bottom slab and the support plate 153 different from each other.

The material of the cushioning member 151 can be applied without limitation to materials and types as long as it can absorb impact. For example, the cushioning member 151 may be formed of a glass surface or foamed rubber, but is not limited thereto.

The support plate 153 may be installed on the upper surface of the buffer member 151 and may support the vibration-preventive member 113 from below. Also, the support plate 153 is made of a steel material having high rigidity, so that the buffer plate 151 can be prevented from being deformed locally.

Here, the vibration of the third resonator-touch skin 150 may be reduced by the buffer member 151.

Since the support plate 153 is structurally separated from the bottom slab by the buffer member 151 and vibration is reduced and the material of the bottom slab is different from that of the bottom slab, the natural frequency of the support plate 153 and the bottom slab is Can be configured differently. The resulting resonance avoidance system will be described later.

Hereinafter, the vibration reduction structure of the multiple resonance avoidance system shown in FIG. 2 will be described with reference to the dynamic model shown in FIG. 3 shows a vibration model of the entire floor structure including the floor slab and the interlayer noise reduction floor structure 100 having the resonance avoidance system.

Referring to FIG. 3, an interlayer noise reduction floor structure 100 having a resonance avoidance system according to an embodiment of the present invention may include first to fourth vibration systems.

In other words, it is constituted by one vibration system (first vibration system) due to the mass M1 of the bottom slab, the flexural stiffness S1 and the damping D1 of the bottom slab, and the structural member restricting the boundary condition such as a column or a wall .

One vibration system (second vibration system) can be constituted by the dynamic rigidity S2 of the buffer member 151, the attenuation D2 of the buffer member 151 and the mass M2 of the support plate 153 .

At this time, the second vibration system may have a dynamic characteristic different from that of the first vibration system by the bottom slab. Particularly, the second vibration system significantly reduces natural frequency as compared with the first vibration system, and the vibration transmitted from the floor impact sound to the floor slab can be greatly reduced.

On the other hand, one vibration system (third vibration system) can be used as the dynamic rigidity S2, damping force D3, damping force of the air layer 114 and mass M3 of the bottom panel 111 of the anti- Can be configured.

At this time, the third vibration system may have different dynamic characteristics due to the difference between the first vibration system and the second vibration system and the elements constituting the vibration system. In particular, the natural frequency of the third vibration system is lower than the natural frequency of the first vibration system, and is higher than the natural frequency of the second vibration system, so that the transmission rate of vibration can be greatly reduced.

On the other hand, one vibration system (fourth vibration system) can be constituted by the flexural rigidity S4 of the anti-vibration member 113, the attenuation D4, and the mass M4 of the finish panel 131. The fourth vibration system may have a dynamic characteristic different from that of another vibration system. Particularly, the natural frequency of the fourth vibration system is lower than the natural frequency of the first vibration system and relatively higher than the natural frequency of the second and third vibration systems, so that the transmission rate of the vibration due to the floor impact sound can be further reduced.

As described above, the interlayer noise reduction floor structure having the resonance avoidance system according to the embodiment of the present invention is characterized in that a plurality of resonance avoidance systems consisting of a first resonance skin, a second resonance skin and a third resonance skin And the dynamic characteristics of the vibration system constituted by the respective systems are different from each other, it is possible to provide an effect of greatly reducing the transmission rate of vibration due to the floor impact sound applied to the finish panel.

In addition, due to the first resonator skin, the second resonator skin, and the third resonator skin, the attenuation of each vibration system is superimposed, and the vibration energy sequentially transmitted to each vibration system is dissipated in multiple stages, It is possible to provide an excellent effect of greatly reducing the absolute amount of the magnetic field.

Therefore, the floor noise reduction floor structure having the resonance avoidance system according to an embodiment of the present invention reduces vibration transmitted to the floor slab by the multiple resonance avoidance system and the multi-stage vibration energy dissipating system, It is possible to reduce noise and vibration radiated to the lower room through the floor slab, thereby reducing the interlayer noise of the entire building.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention, It will be appreciated that those skilled in the art will readily understand the present invention.

100: Interlayer noise reduction floor structure with resonance avoidance system
110: first resonance circuit skin 111: floor panel
113: anti-vibration member 113a:
114: air layer 130: second resonance skin
131: Finishing panel 133: Waterproof sheet
150: third resonance circuit skin 151: buffer member
153: Support plate

Claims (8)

delete And a vibration preventing member provided between the floor slab and the floor panel to elastically support the floor panel. The floor slab and the floor panel have different natural frequencies, A first resonant frequency skin avoiding the first resonant frequency; And
A second resonant frequency skin disposed above the floor panel and having a finishing panel structurally separated from the bottom panel to avoid resonance by differentiating the natural frequency of the floor panel and the finishing panel;
To reduce the transmission of vibration from the finishing panel to the floor slab, thereby reducing interlayer noise,
A buffer member formed on the bottom slab and made of a material absorbing shock transmitted to the bottom slab and a support plate provided between the buffer member and the dustproof member to support the dustproof member, And a third resonant frequency skin which avoids resonance by making the natural frequency of the support plate different from the resonant frequency of the resonant frequency.
3. The method of claim 2,
Wherein the floor panel is made of a vibration-proof alloy for damping vibrations and noises.
3. The method of claim 2,
Wherein the second resonant circuit skin comprises a waterproof sheet installed between the finish panel and the floor panel to structurally separate the finish panel and the floor panel. rescue.
3. The method of claim 2,
Wherein the second resonant frequency skin is constructed of a prefabricated panel so that the finishing panel and the floor panel are structurally separated from each other.
3. The method of claim 2,
Wherein the anti-vibration member is made of a soft steel material and has a bent portion that is bent and deformed when the load is transmitted to dissipate energy.
The method according to claim 6,
Wherein the bent portion is bent to have a U-shaped cross section.
3. The method of claim 2,
Wherein the first resonant frequency skin comprises an air layer between the floor panel and the floor slab.

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