KR20050118524A - Soundproof and vibration-proof floor structure of building using constrained layer damping - Google Patents

Abstract

The present invention relates to a soundproofing and a dustproof floor structure of a building using a damping layer, which is installed on the upper surface of the lower slab and the lower slab by means of an adhesive and is formed by the upper surface of the damping layer and the damping layer formed of plastics. It is composed of slab, and the damping layer is bonded to the lower slab and the upper slab, respectively, by providing the bonding means and the activity preventing means of the damping layer so as to act integrally with each other to prevent the plastic deformation of the damping layer. By absorbing through excellent soundproofing, dustproof function.

Description

Soundproof and vibration-proof floor structure of building using constrained layer damping}

The present invention relates to a soundproofing and dustproof floor structure of a building using a damping layer, and more particularly, it is located between a lower slab and an upper slab, and integrally acts with both plates to provide a damping layer formed of a plastic body, thereby being applied from the outside. The present invention relates to a soundproofing and dustproof floor structure of a building using a damping layer capable of exhibiting excellent soundproofing and dustproofing functions by absorbing impact energy through a damping layer.

The soundproofing and dustproof floor structure of a conventional building cushions vibration by using the elasticity of a member by installing a soundproofing and a dustproof layer formed of an elastic body, or by blocking the progress of vibration by installing an air layer by a structure containing air. Most of them were soundproof and dustproof.

Hereinafter, with reference to the accompanying drawings will be described in detail a soundproof, dustproof floor structure of a conventional building.

1 is a cross-sectional view showing a soundproof, dustproof floor structure of a building using a conventional elastic body. As shown, between the lower slab 10 and the upper slab 20 by installing a soundproof, vibration-proof layer 3 formed of an elastic body to the sound applied to the floor finishing layer (not shown) soundproof, the dustproof layer (3) By cushioning by the provided elasticity and transmitting it to the lower slab 10, a soundproof and dustproof function is exhibited.

2 is a cross-sectional view showing a soundproofed and dustproof floor structure of a building using a conventional air layer. As shown, the impact applied to the bottom finishing layer (not shown) by installing a soundproof, dustproof layer 4 having a structure for accommodating the air layer 4a between the lower slab 10 and the upper slab 20. By blocking the transmission to the slab 10, it exhibits a soundproof, dustproof function.

An object of the present invention is to provide a new soundproofing, soundproofing technology based on the principle of absorbing the vibration energy transmitted from the outside to the lower slab or upper slab by plastic deformation of the damping layer, soundproof, dustproof To provide a floor structure.

Another object of the present invention is to lower the slab and the damping layer so that the lower slab and the damping layer and the upper slab and the damping layer are integral with each other without mutual action, so that the damping layer can effectively absorb vibration energy through plastic deformation. It is to provide an adhesive structure of the upper slab and the damping layer.

In order to achieve the above object, the present invention,

The upper slab and the upper slab, which are located on the upper surface of the lower slab and are installed to be inoperative with the lower slab by the bonding means, and are positioned on the damping layer and the damping layer formed of the plastic body, and are installed to be inoperative with the damping layer by the activity preventing means. It provides a soundproof, dustproof floor structure of the building comprising a.

The damping layer is composed of a plastic body having the property of not returning the input energy to the outside by exhausting the energy of the pressure to deform its shape by receiving the pressure applied from the outside and plastically deforming it.

As a means for adhering the lower slab and the damping layer, the damping layer has its own adhesive force such that the lower slab and the damping layer do not interact with each other and act integrally. When the damping layer is laid after the lower slab is placed, the damping layer is bonded to the lower slab by its own adhesive force to be integrated. Alternatively, when the damping layer is installed after the lower slab is placed by attaching an adhesive layer having an adhesive force to the bottom of the damping layer, the damping layer is adhered to the lower slab by the adhesive force of the adhesive layer to be integrated.

As means for preventing the activity of the upper slab and the damping layer, the present invention provides a method different from the method of bonding the lower slab and the damping layer. The problem of deterioration of adhesive strength with the passage of time for placing slabs after the damping layer is installed, and the problem of deterioration of adhesive strength due to contact with moisture, which is indispensable in the process of pouring the slabs after installation of the damping layer. In the same manner as the adhesive method with the slab, the damping layer itself has an adhesive force or by attaching an adhesive layer on the upper surface of the damping layer, the desired purpose cannot be achieved.

Accordingly, the present invention provides an activity preventing means for preventing the activity of the upper slab on the upper surface of the damping layer in the manner of preventing the activity of the upper slab and the damping layer so as to be integrated with the upper slab.

Through the preferred embodiments of the accompanying drawings, looks at in detail the configuration and operation of the soundproof, vibration-proof floor structure of the building according to the invention.

3 is a cross-sectional view of the first embodiment according to the present invention. As shown, the first embodiment according to the present invention is located on the lower slab 10 and the lower slab 10, the damping is formed in the plastic body and is installed so as not to work with the lower slab 10 by the adhesive means Soundproof and dustproof floor structure of the building, characterized in that it comprises a top slab 20 located on the upper surface of the floor 30 and the damping layer 30 and is installed to be inactive with the damping layer 30 by an activity preventing means. to provide.

As the bonding means of the lower slab 10 and the damping layer 30, as shown in (a) is formed of a material having an adhesive force by the damping layer 30 itself, the damping layer 30 to the lower slab 10 Or the damping layer 30 adheres to the lower slab 10 by an adhesive layer 40 having an adhesive force between the lower slab 10 and the damping layer 30 as shown in (b). To be integrated with the lower slab (10).

As the means for preventing the activity of the upper slab 20 and the damping layer 30, the damping layer 30 and the upper plate during curing of the upper slab 20 by fixing the activity preventing pin 100 on the upper surface of the damping layer 30. The adhesion of the slab 20 is firm so that the damping layer 30 and the upper slab 20 are integrally behaved. Preferably, the activity preventing pin 100 includes a plurality of resinous resin pins 110.

4 is a cross-sectional view of a second embodiment according to the present invention. Components overlapping with the first embodiment according to the present invention will be omitted for convenience. As shown, the second embodiment according to the present invention is a soundproof, dustproof floor structure of the building to prevent the upper slab 20 and the damping layer 30 to be prevented by the shear key 200.

As a means for preventing the activity of the upper slab 20 and the damping layer 30, the upper surface of the damping layer 30 has a sufficient height to prevent the activity of the upper slab 20 and a width capable of resisting shear force. By installing the shear key 200, the upper slab 20 and the damping layer 30 are integrally operated.

5 is a sectional view of a third embodiment according to the present invention. Components overlapping with the first embodiment according to the present invention will be omitted for convenience. As shown, the third embodiment according to the present invention is a soundproof, dustproof floor structure of the building to prevent the upper slab 20 and the damping layer 30 by the pleats 300.

As a means for preventing the activity of the upper slab 20 and the damping layer 30, the upper slab slab is formed on the upper surface of the damping layer 30 by forming a wrinkle portion 300 having a sufficient height to prevent the upper slab 20 from acting. 20 and the damping layer 30 to be integrated.

6 is a sectional view of a fourth embodiment according to the present invention. Components overlapping with the first embodiment according to the present invention will be omitted for convenience. As shown, the fourth embodiment according to the present invention is a soundproof, dustproof floor structure of the building to prevent the upper slab 20 and the damping layer 30 by the uneven portion 400.

By providing the activity preventing means of the upper slab 20 and the damping layer 30, by providing an uneven portion 400 having a sufficient height on the upper surface of the damping layer 30 to prevent the activity of the upper slab 20 The upper slab 20 and the damping layer 30 to be integrally behaved.

7 is an installation state diagram in which an embodiment of the present invention is installed in a building. As shown, the bottom slab 12 and the damping layer 30 is installed by installing the adhesive layer 40 on the top surface of the bottom slab 12 and the damping layer 30 on the top surface of the adhesive layer 40 and by the adhesive force of the adhesive layer 40. ) And bond together. A plurality of anti-activity pins 100 having pin branches 110 are fixedly installed on the upper surface of the damping layer 30, and the lightweight foamed concrete 22 is poured to cure the damping layer 30 and the lightweight foamed concrete 22. Move it all together. Thereafter, an upper structure such as a heating piping layer 50 and a finishing mortar layer 60 is installed on the upper surface of the lightweight foam concrete 22.

Hereinafter, the working principle of the soundproofing and the dustproofing effect by the configuration of the present invention will be described in detail with reference to the accompanying drawings.

8 is a cross-sectional view illustrating the effect of the configuration of the present invention. As shown, the lower slab 10, the lower slab 10, the upper slab 10 and the upper slab 20, both ends of which are constrained to be integrally installed, the damping layer 30 formed of a plastic body and the upper slab on which both ends are restrained ( Assume a floor structure consisting of 20). When an impact is applied to the upper slab 20, the upper slab 10 and the lower slab 20 are convexly deformed downwardly, as shown in (a), and immediately due to the characteristics of the positive plate (b). As shown, the upper slab 10 and the upper slab 20 are vibrated by convex upward deformation. That is, the energy of the impact is converted and accumulated into the vibration energy of the lower slab 10 and the upper slab 20.

Here, the damping layer 30 which is integral with the lower slab 10 and the upper slab 20 without being active is deformed as the lower slab 10 and the upper slab 20 are deformed. However, unlike the positive plate, the damping layer 30 is formed of a plastic body and thus cannot vibrate itself and does not accumulate vibration energy. It only consumes energy in deforming its shape. Therefore, the damping layer 30 absorbs the vibration energy held by the two plates when the lower slab 10 and the upper slab 20 vibrate and exhausts its shape.

The soundproof and dustproof floor structure of the building according to the present invention uses this principle, and the damping layer 30 deforms its vibration shape while deforming its shape until the vibration generated by the impact applied to the upper slab 20 is extinguished. As it absorbs and burns out, it exhibits excellent dustproof function.

Since the noise is also transmitted by the fine vibration of the member, the soundproofing, dustproof floor structure of the building according to the present invention exhibits an excellent soundproofing function by the same working principle as dustproofing.

The soundproof and dustproof floor structure of the building according to the present invention exhibits excellent soundproofing and dustproofing effect by rapidly extinguishing vibration generated by the impact applied to the floor of the building, and ultimately provides a comfortable indoor environment.

1 is a cross-sectional view showing a soundproof, dustproof floor structure of a building using a conventional elastic body.

2 is a cross-sectional view showing a soundproofed and dustproof floor structure of a building using a conventional air layer.

3 is a cross-sectional view of the first embodiment according to the present invention.

4 is a cross-sectional view of a second embodiment according to the present invention.

5 is a sectional view of a third embodiment according to the present invention.

6 is a sectional view of a fourth embodiment according to the present invention.

7 is an installation state diagram in which an embodiment of the present invention is installed in a building.

8 is a cross-sectional view illustrating the effect of the configuration of the present invention.

* Explanation of symbols for main parts of the drawings

10: lower slab slab 12: floor slab

20: slab slab 22: lightweight foam concrete

30 damping layer 40 adhesive layer

50: heating piping layer 60: finishing mortar layer

100: activity prevention pin 110: pin branch

200: shear key 300: wrinkles

400: uneven portion

Claims (7)

Lower slab; A damping layer disposed on an upper surface of the lower slab and installed to be inoperative with the lower slab by an adhesive means and formed of a plastic body; And Soundproofing and dustproof floor structure of the building, characterized in that it comprises a top slab located on the damping layer upper surface and is installed to be inactive with the damping layer by the activity preventing means. The method of claim 1, Soundproofing and dustproof floor structure of the building, characterized in that the bonding means is formed of a material having an adhesive force as the damping layer itself. The method of claim 1, The adhesive means is a soundproof, dustproof floor structure of a building, characterized in that consisting of an adhesive layer having an adhesive force between the lower slab and the damping layer. The method according to any one of claims 1 to 3, Soundproofing and dustproof floor structure of the building, characterized in that the activity preventing means is composed of activity preventing pins installed on the upper surface of the damping layer. The method according to any one of claims 1 to 3, Soundproofing and dustproof floor structure of the building, characterized in that the activity preventing means is composed of a shear key installed on the upper surface of the damping layer. The method according to any one of claims 1 to 3, Soundproofing and dustproof floor structure of the building, characterized in that the activity preventing means is composed of a wrinkle portion installed on the upper surface of the damping layer. The method according to any one of claims 1 to 3, Soundproofing and dustproof floor structure of the building, characterized in that the activity preventing means is composed of an uneven portion provided on the upper surface of the damping layer.