KR20200063444A - Noise Absorption Structure Of Slab Concrete Using Impact Mitigating Part - Google Patents

Abstract

The present invention relates to an inter-floor noise prevention structure of a slab having an impact mitigation layer at the center and, more specifically, to an inter-floor noise prevention structure of a slab having an impact mitigation layer at the center, which forms an empty space at the center of a slab of an apartment house when constructing a buffer layer on an upper portion of the slab to transfer striking force in a detour to both sides without transferring the striking force directly downwards through the center of the slab when striking the center of the slab to reduce the vibratory response and impact sound of a floor slab. According to a proper embodiment of the present invention, the inter-floor noise prevention structure of a slab constructed on an upper portion of a floor slab of an apartment house comprises: a lower buffer material constructed on an upper portion of the floor slab; an upper buffer material having a space of a prescribed size formed at the center thereof; a sound-absorbing material constructed in the space of the upper buffer material; and a mortar layer formed by pouring mortar on an upper portion of the upper buffer material.

Description

Noise Absorption Structure Of Slab Concrete Using Impact Mitigating Part

The present invention relates to an inter-layer noise prevention structure of a slab having an impact-relieving layer in the center, and more specifically, an empty space is formed in the center of the slab when the buffer layer is formed on the top of the slab of the apartment house, so that the hitting force when hitting the center of the slab is the center of the slab. It relates to an interlayer noise prevention structure of a slab having an impact-relieving layer in the center to reduce vibration response and impact noise of the floor slab by allowing it to be bypassed directly to both sides without being transmitted directly through.

In general, the floor slab, as shown in Figure 4, in order to prevent noise on the upper side of the floor slab (1) to form a cushioning material (2), and in turn to finish with lightweight foam concrete (3) and finishing mortar (4) In the interior of the finishing mortar 4, a hot water pipe 41 and the like are configured. Such a buffer layer is manufactured in various forms as described above, and is installed to prevent noise generated during movement of people living in an apartment house from being transmitted from an upper layer to a lower layer.

However, the floor impact sound, which is the main cause of inter-floor noise, is divided into light weight impact sound and heavy impact sound, and the current social issue is that the heavy impact sound has the characteristics of spherical transmission sound generated by vibration of the air and the heavy shock sound. The height of the is closely related to the vibration of the sphere, especially the floor slab, and as confirmed in many field measurement results, the magnitude of the impact sound response in the center of the slab where the vibration response of the floor slab occurs most is shown to be the largest. With the structure of the buffer layer, there was a problem that it was difficult to prevent interlayer noise.

As a background technology of the present invention, there is a utility model registration No. 0376919 "A structure for preventing noise between floors of a floor slab in an apartment house" (Patent Document 1). In the background art,'In the upper part of the floor slab, there is a soundproofing and vibration absorbing member, a heating pipe and an air-to-floor noise prevention structure composed of a foam concrete layer, the sound insulating material installed on the entire upper area of the floor slab; A vibration absorber installed in the shape of a well well in consideration of copper wire on the upper part of the sound insulating material; A heating pipe support seated on an upper portion of the protrusion of the vibration absorbing material; A fastening pin fastened to a fastening hole of the vibration absorbing material and a fastening hole of a heating pipe support; And a grill network inserted into a square hole of the heating pipe support and installed to enhance adhesion during curing due to foam concrete pouring.

However, the background technique is also a structure that is difficult to reduce the impact sound in the central portion of the slab, and has a complicated configuration.

Utility Model Registration No. 0376919 "Structure to prevent noise between floor slabs in apartment houses"

The present invention is to solve the above problems, and by forming an empty space in the center of the slab during the construction of the buffer layer, so that the impact force when hitting the center of the slab is not directly transmitted down through the center of the slab, but is bypassed and transmitted to both sides. It is possible to reduce the vibration response and impact sound of the floor slab, and to place the sound absorbing material capable of absorbing the low frequency sound in the 63 Hz band, which is the most problematic in heavy shock sound, in the empty space in the center of the slab to absorb the impact sound secondarily. The object is to provide an inter-layer noise prevention structure of a slab having an impact-relieving layer in a central portion to reduce overall floor impact noise.

The present invention is an inter-layer noise prevention structure of a slab constructed on an upper part of a floor slab of an apartment house, comprising: a lower cushioning material configured on an upper portion of the floor slab; An upper cushioning material having a space portion of a predetermined size formed in a central portion; A sound absorbing material configured in a space portion of the upper cushioning material; A mortar layer formed by pouring mortar on top of the upper cushioning material; to provide an interlayer noise prevention structure of a slab having an impact-relieving layer in the center, which comprises a.

In addition, the upper portion of the sound absorbing material is composed of a plate-shaped steel sheet having a size larger than the size of the space portion, and to provide an inter-layer noise prevention structure of a slab having an impact-relieving layer in the center, characterized in that mortar is placed on the upper portion.

In addition, to provide an interlayer noise prevention structure of a slab having an impact-relieving layer in the center, characterized in that a plurality of shear connecting materials are configured outside the space to connect the floor slab and mortar.

The inter-layer noise-prevention structure of a slab having an impact-relieving layer in the center of the present invention forms an empty space in the center of the slab when constructing the buffer layer, so that when the slab hits the center, the hitting force is not transmitted directly down through the center of the slab but bypasses both sides. It is possible to reduce the vibration response and impact sound of the floor slab, and secondarily by placing a sound absorbing material capable of absorbing the low frequency sound in the 63 Hz band, which is the most problematic in heavy impact sound, in the empty space in the center of the slab. By absorbing the impact sound, there is a very useful effect that can reduce the overall floor impact sound.

The following drawings attached in the present specification are intended to illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is only described in the accompanying drawings. It should not be interpreted as limited.
1 is a cross-sectional view and a plan view showing an inter-layer noise prevention structure of a slab having an impact-relieving layer in the center portion of the present invention.
FIG. 2 is a view illustrating a transmission path of the impact sound of FIG. 1.
3 is a cross-sectional view showing another embodiment of FIG. 1.
Figure 4 is a cross-sectional view showing an embodiment of a conventional floor slab floor noise prevention structure of a multi-family house.

The present invention will be described in detail below with reference to the embodiments presented in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention and the invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

1 is a cross-sectional view and a plan view showing an inter-layer noise preventing structure of a slab having an impact-relieving layer in the center portion of the present invention, and FIG. 2 is a view illustrating a transmission path of the impact sound of FIG. 1.

In the middle of the present invention, the inter-layer noise prevention structure of the slab having the shock-absorbing layer is, as shown in FIG. 1, the lower cushioning material 10 and the space 21 in the center in the upper part of the floor slab 1 of the apartment house. It comprises an upper buffer material 20 formed, a sound absorbing material 30 formed in the space portion 21, and a mortar layer 40 formed on the upper buffer material 20.

The feature of the present invention, as shown in Figure 2, when forming a buffer layer consisting of a lower buffer material 10 and the upper buffer material 20 for the reduction of the floor impact sound to form a space 21 in the center of the upper buffer material 20 When hitting the center portion of the floor slab 1, the impact force is not transmitted directly down through the center portion of the floor slab 1 but is bypassed to both sides so as to reduce vibration response and impact sound of the floor slab.

The lower cushioning material 10 and the upper cushioning material 20 are preferably dynamic in elasticity, which is a property that can insulate vibrations and absorb sound pressure, and is constant for a long time. Any member having a material can be used.

The lower cushioning material 10 and the upper cushioning material 20 may be made of the same material or may be made of different materials according to functions.

In particular, the upper cushioning material 20 is made to be formed of a material having a density greater than that of the lower cushioning material 10, so as to facilitate power transmission in the mortar layer 40 formed on the upper part. That is, when the density of the upper buffer material 20 formed on the lower portion of the mortar layer 40 is low, cracks may occur on the floor due to settlement, and the density of the lower buffer material 10 is the same as that of the upper buffer material 20. Since the interlayer noise cannot be reduced when it has a high density, the upper buffer material 20 is formed to have a high density, and the lower buffer material 10 is formed to have a low density, thereby effectively preventing the phenomenon such as settlement and effectively reducing the interlayer noise. To make it possible.

In general, floor impact sound, which is the main cause of inter-floor noise, is classified into light weight impact sound and heavy weight impact sound, and the current social issue is that the heavy impact sound has the characteristics of concrete transmission sound generated by vibration of the air, and heavy shock sound. The height of the is closely related to the vibration of the sphere, especially the floor slab, and as shown in many field measurements, the magnitude of the impact response in the center of the floor slab where the vibration response of the floor slab occurs most is the largest. .

Therefore, in the present invention, the space portion 21 is formed in the center portion of the upper cushioning material 20 corresponding to the center portion of the floor slab 1 for reducing the floor impact sound, and the impact force is lowered when hitting the center portion of the floor slab 1 It is to reduce the vibration response and the impact sound of the floor slab 1 by allowing it to be transmitted by bypassing both sides instead of directly down through the center portion of the slab 1.

The sound absorbing material 30 can be constructed by cutting a variety of known sound absorbing materials according to the size of the space part 21, and a heavy shock sound is generated in the space part 21 formed in the upper cushioning material 20 located at the center of the bottom slab 1 The sound absorbing material 30 capable of absorbing the low-frequency sound in the 63 Hz band, which is the most problematic problem, is disposed to absorb the impact sound secondarily, thereby reducing the overall floor impact sound.

In particular, the upper portion of the space portion 21 in which the sound absorbing material 30 is installed is configured such that a plate-shaped steel plate 50 having a size larger than the size of the space portion 21 is constructed and the mortar layer 40 is placed on the upper portion again. By doing so, after the mortar layer 40 is placed, the integrated mortar layer can bypass the impact to the side of the steel plate 50 upon impact.

At this time, the steel sheet 50 is formed to be larger than the size of the sound absorbing material 30 to prevent the steel sheet 50 from being introduced into the space portion 21 during an upper impact, and to be easily bypassed by side work. It can be constructed using a variety of known steel plates.

The steel plate 50 may also be formed in various thicknesses and sizes depending on the size of the space portion 21.

As described above, the mortar layer 40 is formed by pouring mortar to a certain thickness on the upper portion of the upper cushioning material 20 in which the suction material 30 is configured.

Piping such as a hot water pipe (not shown) is formed inside the mortar layer 40.

3 is a cross-sectional view showing another embodiment of FIG. 1.

In addition, as shown in FIG. 3, a plurality of shear connecting members 60 may be configured outside the space portion 21 to connect the floor slab 1 and the mortar layer 40.

After the mortar layer 40 is formed, a shear connecting material 60 connecting the mortar layer 40 and the floor slab 1 around the central space portion 21 to smoothly transmit the striking force hitting the central portion to the side. Arrangement can be induced to maximize the above effects.

At this time, the shear connecting material 60 is configured to protrude to the upper portion of the floor slab 1 by using a variety of well-known means, such as anchor bolts, rebars, and then the lower buffer material 10 in turn on the upper portion of the floor slab 1 And by constructing the upper cushioning material 20 so that a portion of the upper end of the shear connecting material 60 protrudes to the upper portion of the upper cushioning material 20, and after configuring the sound absorbing material 30 in the space portion 21 of the upper cushioning material 20 Mortar is placed on the upper portion of the upper buffer material 20 to be embedded in the floor slab 1 from the lower end of the shear connecting material 60 to a certain height from the lower end to the upper level and from the upper end to the lower level of the mortar layer 40. By connecting the mortar layer 40 and the floor slab 1, the hitting force hitting the central portion can be smoothly transmitted to the side of the space portion 21.

The interlayer noise prevention structure of the slab having the shock-relieving layer in the center of the present invention as described above forms an empty space in the center of the slab during the construction of the buffer layer, so that the impact force is not transmitted directly down through the center of the slab when hitting the center of the slab. By allowing it to be transferred to the side, it is possible to reduce vibration response and impact noise of the floor slab, and also, in an empty space in the center of the slab, a sound absorbing material capable of absorbing low-frequency sound in the 63 Hz band, which is the most problematic in weight impact sound, is disposed. Secondly, by absorbing the impact sound, there is a very useful effect that can reduce the overall floor impact sound.

The present invention has been described in detail with reference to the presented embodiments so far, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such modified and modified inventions, but is limited by the appended claims.

1: Floor slab
10: lower cushioning material
20: upper cushioning material
21: Space Department
30: sound absorbing material
40: mortar layer
50: steel plate
60: shear connector

Claims (4)

In the inter-layer noise prevention structure of the slab constituted on the upper floor slab (1) of the apartment,
A lower cushioning material 10 configured on an upper portion of the floor slab 1;
An upper cushioning material 20 in which a space portion 21 of a certain size is formed in the central portion;
A sound absorbing material 30 formed in the space portion 21 of the upper cushioning material 20;
Mortar layer 40 formed by pouring mortar on top of the upper cushioning material (20); Interlayer noise prevention structure of the slab having an impact-relieving layer in the center, characterized in that comprises a. The method according to claim 1,
A slab having an impact-relieving layer in the center of the sound absorbing material 30 is formed of a plate-shaped steel plate 50 having a size larger than the size of the space 21, and a mortar layer 40 is placed on the top. Interlayer noise prevention structure. The method according to claim 1,
Interlayer noise prevention structure of a slab having an impact-relieving layer in the center, characterized in that a plurality of shear connectors 60 are formed outside the space 21 to connect the floor slab 1 and the mortar layer 40. The method according to claim 1,
The upper cushioning material 20 is an interlayer noise-preventing structure of a slab having an impact-relieving layer in the center, characterized in that the lower cushioning material 10 is formed of a material having a density greater than a certain size.

Images