KR102626135B1 - Inter-floor floor impact sound blocking structure and inter-floor floor floor impact sound blocking structure construction method - Google Patents

Abstract

This invention relates to an inter-story floor impact sound blocking structure and an inter-story floor impact sound blocking structure construction method. In particular, a support panel is provided on an air mat covered with the top of a concrete slab, and a cushioning material, a hot water pipe, and a finishing mortar layer are provided on the top of the support panel. By ensuring that these are provided sequentially, cracks and local deformation occurring in the finishing mortar layer due to the self-load of the finishing mortar layer after construction, shock applied to the upper part of the finishing mortar layer, or furniture provided, etc. are prevented, thereby creating a slab structure. It relates to an inter-floor floor impact sound blocking structure and a method of constructing an inter-floor floor impact sound blocking structure that is stable and blocks impact noise and, unlike conventional slab structures, is simple to construct and can reduce construction costs.

Description

Inter-floor floor impact sound blocking structure and inter-floor floor impact sound blocking structure construction method {INTER-FLOOR FLOOR IMPACT SOUND BLOCKING STRUCTURE AND INTER-FLOOR FLOOR FLOOR IMPACT SOUND BLOCKING STRUCTURE CONSTRUCTION METHOD}

This invention relates to an inter-story floor impact sound blocking structure and an inter-story floor impact sound blocking structure construction method. In particular, a support panel is provided on an air mat covered with the top of a concrete slab, and a cushioning material, a hot water pipe, and a finishing mortar layer are provided on the top of the support panel. By being provided in this order, especially by inserting the support panel into the air mat, the self-load of the finishing mortar layer after construction, the impact applied to the upper part of the finishing mortar layer, or the furniture provided, etc., are prevented from occurring in the finishing mortar layer. By preventing cracks and local deformation, the slab structure is stable and impact noise can be blocked, and unlike conventional slab structures, construction is simple and construction costs can be reduced by constructing an inter-floor floor impact sound blocking structure and an inter-floor floor impact sound blocking structure. It's about method.

In general, when an impact such as a person walking or an object falling is applied to the upper floor of an apartment or other apartment complex, the noise radiated through the concrete slab into the lower floor unit is called floor impact sound.

The structural standard for floor impact sound blocking between floors for noise prevention refers to a floor structure approved by confirming the performance of the floor impact sound blocking structure, and the performance of the floor impact sound blocking structure is 49db or less for heavy impact sound (refers to floor impact noise due to heavy and soft impacts), light weight. It is a structure approved after confirming that the impact noise (refers to floor impact noise caused by a relatively light and hard impact) is below 49db.

As a prior art, Registered Patent Publication No. 10-114219 (April 25, 2012) installs a cushioning material on a concrete slab, pours lightweight foam concrete on top of it, and constructs a finishing mortar layer and floor finishing material on top of it to reduce noise between floors. However, the construction was complicated and took a lot of time, which resulted in increased costs.

As another conventional technology, Patent Publication No. 10-2007-0003729 (2007.01.05) not only allows expansion through a fitting structure but also improves the convenience of construction by ensuring a high degree of freedom in the piping line. However, concrete During the pouring process, voids were created in the lower part of the piping block, and due to this cause, there was a problem in that vibration or impact force was amplified by resonance phenomenon.

As another conventional technology, Registered Patent Publication No. 10-2403744 (2022.05.25), as shown in Figure 7, includes a floor slab, a buffer layer installed on the upper surface of the floor slab, and a finishing mortar layer installed on the upper surface of the buffer layer. It is a floor structure for reducing inter-floor noise that includes, and the buffer layer includes a coil mat placed on the upper surface of the floor slab and a cushioning material placed on the upper surface of the coil mat to reduce inter-floor noise, but after construction is completed, There was a problem in that cracks, deformation, and depression occurred in the part located on the coil mat due to local impact or load, and due to this problem, there was a problem that required re-construction.

Registered Patent Publication No. 10-114219 (2012.04.25) Public Patent Publication No. 10-2007-0003729 (2007.01.05) Registered Patent Publication No. 10-2403744 (2022.05.25)

This invention proposes an inter-floor floor impact sound blocking structure to prevent noise between households, households, etc. in accordance with related regulations such as the Building Act, and aims to prevent damage to life and property due to disputes related to inter-floor noise between neighbors in advance and create a pleasant living environment. will be. In addition, it is intended to prevent cracks and bending deformation occurring in the finishing mortar layer after construction.

This invention relates to an inter-floor impact sound blocking structure (A) for noise prevention provided on the top of the concrete slab (SB) of a building structure, wherein the inter-floor impact sound blocking structure (A) is an elastic sheet on the top of the concrete slab (SB). (10) is provided, and an air mat 20 is provided on the upper part of the elastic sheet 10, and a plurality of support panels 30 are provided on the entire upper surface of the air mat 20, A cushioning material 40 is provided on the entire upper part where a plurality of support panels 30 are provided, and a hot water pipe 50 is placed on the upper part of the cushioning material 40, and the cushioning material 40 on which the hot water pipe 50 is placed is provided. It is characterized in that the finishing mortar (M) is poured and hardened on the upper part to provide a finishing mortar layer (60).

In addition, an elastic sheet 10 is first provided on the upper part of the concrete slab SB, and an air mat 20 is provided on the upper part of the elastic sheet 10, so that the concrete slab is formed by the elastic sheet 10. It has the effect of flattening the upper surface of the (SB), and also has an elastic effect, which can add to the effect of blocking floor impact noise between floors. The thickness of the elastic sheet 10 is about 1 to 5 mm, and 2 mm is most preferable.

In addition, the air mat 20 is formed in a mat shape, and the yarns 210 are twisted irregularly to form air layers 220 of various shapes. The thickness of the air mat 20 is preferably 30 to 40 mm, but the thickness of the air mat 20 should be greater than the height of the support panel 30.

In addition, the air mat 20 is made of a synthetic resin composition and has a diameter of 0.5 to 1.5 mm (gray yarn) is twisted irregularly to form various air layers 210, thereby serving as a spring with elastic force. Preferred synthetic resin compositions in the form of yarn include POP (Polyolefin Plastomer), TPR (synthetic rubber), PU (Polyurethane), and EVA (Ethylene-Vinyl Acetatecopolymer).

In addition, the support panel 30 has a plurality of support legs 320 integrally formed on the bottom of a square support plate 310 with a height of 22 to 36 mm, and the support legs 320 are inserted into the air mat 20. It is characterized in that the lower part is formed in a sharp cone shape to be supported.

In addition, the size of the square support plate 310 of the support panel 30 is preferably 500 x 500 mm or 1000 x 1000 mm.

In addition, the support panel 30 is provided so that the support legs 320 of the support panel 30 are attached to the air mat 20 at the top of the air mat 20 with a thickness of 30 to 40 mm on which the air layer 220 is formed. By being inserted and supported on the large concrete slab (SB), the loads of the cushioning material 40, the hot water pipe 50, and the finishing mortar layer 60 provided on the upper part of the support panel 30 are supported.

If the support panel 30 is not present or the support force of the support panel 30 is weak, cracks and cracks may occur in the finishing mortar layer due to the self-load of the finishing mortar layer after construction, an impact applied to the upper part of the finishing mortar layer, or furniture provided. Local deformation occurs. Therefore, the organic combination of the support panel 30 and the air mat 20 can be said to be the most characteristic configuration in this invention.

In addition, the square support plate 310 of the support panel 30 is provided with a plurality of horizontal support pieces 312 and vertical support pieces 313 in a grid shape inside the edge support piece 311, and the support legs ( 320) is characterized in that the horizontal support pieces 312 and the vertical support pieces 313 of the square support plate 310 are provided at orthogonal positions.

Additionally, the square support plate 310 of the support panel 30 may be provided with reinforcing supports 314 in the diagonal direction.

In addition, the support leg 320 is provided below at a position where the horizontal support beam 312 and the vertical support beam 313 of the square support plate 310 are orthogonal, and is inserted into the air mat 20 to be supported. The lower end of the support leg 320 is formed as a pointed block support part 321 having a block shape, and the upper part of the support leg 320 is connected to the square support plate 310 and has a circular opening at the top. A portion 322 is formed, and the inside of the body of the support leg 320 is formed as a conical space 323 to be connected to the circular opening 322, and the body of the support leg 320 is formed. The side is characterized in that a plurality of vertically elongated grooves 324 are provided to be connected to the conical space 322.

In addition, the height of the support panel 30 is smaller than the thickness of the air mat 20, so that the support legs 320 of the support panel 30 are inserted into the air mat 20 to support the concrete slab SB. Alternatively, the upper surface of the elastic sheet 10 may be lifted by approximately 4 to 8 mm. Therefore, the support panel 30 and the air mat 20 make the air mat 20 elastic like a spring. That is, as the support plate 310 connected to the support leg 320 of the support panel 30 is supported by the air mat 20, the air mat 20 adds elastic force like a spring, and the support panel 30 ) The square support plate 310 also has the effect of receiving elasticity due to the elastic force of the air mat 20 below the support panel 30.

Therefore, when the height of the finishing mortar layer 60 is 40 mm and the specific gravity of 1 m2 mortar is calculated as 2.5, the load of the finishing mortar layer 60 is about 100 kg. At this time, the support legs 320 of the support panel 30 When the upper surface of the concrete slab (SB) or the elastic sheet 10 is lifted by about 4 to 8 mm, the air mat 20 acts as a spring, and the load of the finishing mortar layer 60 increases by 10 to 8 mm. The effect is reduced by 20%.

In addition, the cushioning material 40 is made of any one of EPS (Expanded Polystyrene), EPP (Expanded Polypropylene), and EVA (Ethylene Vinyl Acetate), and the hot water pipe 50 is attached to a plurality of ∩-shaped fixing pins 510. It is placed on the cushioning material 40, and a fishhook-shaped locking portion 510b is provided at the lower part of the leg portion 510a of the ∩-shaped fixing pin 510 to secure the locking portion (510b) of the ∩-shaped fixing pin 510. 510b) is inserted into and fixed to the cushioning material 40.

In addition, the cushioning material 40 is a cushioning material made of one of EPS (Expanded Polystyrene), EPP (Expanded Polypropylene), EVA (Ethylene Vinyl Acetate), non-woven fabric, glass wool in the form of glass fiber, or sponge. The thickness of the cushioning material 40 is preferably 20 to 40 mm, and its size is preferably 900Х1000mm, 900Х1800mm, 1000Х1000mm, or 1000Х2000mm.

In addition, the hot water pipe 50 is placed on the cushioning material 40 by a plurality of ∩-shaped fixing pins 510, and the bottom of the leg portion 510a of the ∩-shaped fixing pin 510 has a fishhook shape. A locking portion 510b is provided to prevent the locking portion 510b of the ∩-shaped fixing pin 510 from being separated in the reverse direction at the same time as it is inserted into the cushioning material 40, so that it is fixed even if the worker steps on the hot water pipe 50. The pin 510 is pulled out to prevent the hot water pipe 50 from flowing.

In addition, the thickness of the finishing mortar layer 60 is 40 mm or more, preferably 60 mm or more, and the finishing mortar (M) forming the finishing mortar layer 60 is generally made by mixing only cement and sand as a binder. For floors, a cement to sand ratio of about 1:3 is desirable.

In addition, on the inside of the corner side wall surface (SW) between the concrete slab (SB) and the side wall surface (SW), the top is open " It is characterized in that it is provided with a floor impact sound discharge gap 70 in the shape of ".

The floor impact sound discharge gap 70 is provided from the upper part of the support panel 30, and is formed by the side wall surface (SW) on one side and the cushioning material 40 and finishing mortar layer 60 on the other side. “It is characterized by being formed in a shape.

In addition, it is characterized in that a floor finishing material (80) is provided on the top of the finishing mortar layer (60).

Meanwhile, this invention relates to a method of constructing an inter-floor floor impact sound blocking structure for noise prevention provided on the top of the concrete slab (SB) of a building structure, in which an elastic sheet 10 is installed on the top of the concrete slab (SB). Sheet installation step (S100); An air mat installation step (S200) in which an air mat 20 having a predetermined thickness is installed on the elastic sheet 10; A support panel installation step (S300) in which a support panel 30 is installed on the air mat 20; A cushioning material installation step (S400) in which a cushioning material 40 is installed on the upper part of the support panel 30; A hot water pipe placing step (S500) in which the hot water pipe 50 is placed on the upper part of the cushioning material 40 by a ∩-shaped fixing pin 510; It is characterized in that it includes a finishing mortar layer installation step (S600) in which the finishing mortar (M) is poured and hardened on the upper part of the cushioning material (40) where the hot water pipe (50) is placed and the finishing mortar layer (60) is installed.

In addition, in order to provide a U-shaped floor impact sound discharge gap 70 on the inside of the side wall SW before the elastic sheet installation step (S100), a gap creation hole G is installed from the bottom of the concrete slab SB. It is characterized by further including a gap creation hole installation step (S50) installed on the side wall (SW) having a certain height.

In addition, after the finishing mortar layer installation step (S600), a floor finishing material installation step (S700) is further included in which the floor finishing material 80 is installed on the upper part of the finishing mortar layer 60.

This invention has the effect of preventing damage to life and property due to noise-related disputes between neighbors and creating a pleasant living environment.

In addition, the support panel provided on the upper part of the air mat allows sufficient resistance to the self-load of the finishing mortar layer after construction, the impact applied from the upper part of the finishing mortar layer, or the load of furniture provided, etc., so that it can be finished after construction. Cracks and bending deformation occurring in the mortar layer are prevented, resulting in an extended lifespan.

In addition, the effect of floor impact noise generated by an impact acting from the top is blocked between floors by the organic combination of the support panel, air mat, cushioning material, and finishing mortar layer.

In addition, the floor impact sound between floors is discharged to the upper part of the space through the floor impact sound discharge gap provided on the inside of the corner side wall between the concrete slab and the side wall, thereby achieving the effect of reliably blocking the floor impact sound.

In addition, by additionally providing an elastic sheet on the upper part of the concrete slab, not only has the effect of flattening the upper surface of the concrete slab, but also has an elastic effect, so that the effect of blocking floor impact sound between floors can be added.

Figure 1 is a longitudinal cross-sectional view showing an inter-floor floor impact sound blocking structure according to this invention.
Figure 2 is a longitudinal cross-sectional view showing another embodiment of the inter-floor floor impact sound blocking structure according to this invention.
Figure 3 is an enlarged illustration of only the air mat in the inter-floor floor impact sound blocking structure according to this invention.
Figure 4a is a perspective view showing a support panel in the inter-floor impact sound blocking structure according to this invention, Figure 4b is a plan view showing the support panel, and Figure 4c is a longitudinal cross-sectional view showing the support panel.
Figure 5 is an enlarged longitudinal cross-sectional view showing before and after a load is applied by a hot water pipe and a finishing mortar layer to the top of the cushioning material placed on the support panel in the inter-floor floor impact sound blocking structure according to this invention.
Figure 6 is a flowchart showing the construction state of the inter-floor floor impact sound blocking structure according to this invention.
Figure 7 is a longitudinal cross-sectional view showing an inter-floor impact sound isolation slab according to the prior art.

An embodiment of this invention will be described with reference to the accompanying drawings as follows.

Figure 1 is a longitudinal cross-sectional view showing an inter-floor floor impact sound blocking structure according to this invention, Figure 2 is a longitudinal cross-sectional view showing another embodiment of an inter-floor floor impact sound blocking structure according to this invention, and Figure 3 is an inter-floor impact sound blocking structure according to this invention. It is an enlarged illustration of only the air mat in the floor impact sound blocking structure, Figure 4a is a perspective view showing the support panel in the floor impact sound blocking structure between floors according to this invention, Figure 4b is a plan view showing the support panel, Figure 4 4c is a longitudinal cross-sectional view showing the support panel, and Figure 5 is an enlarged view of before and after the load is applied by the hot water pipe and the finishing mortar layer to the top of the cushioning material placed on the support panel in the inter-floor floor impact sound blocking structure according to this invention. This is a vertical cross-sectional view.

The inter-floor impact sound blocking structure (A) according to this invention is provided on the upper part of the concrete slab (SB) of a building structure. As shown in Figures 1 to 5, the floor finishing material is damaged due to local impact or load after construction. It is provided to extend the lifespan by preventing cracks and local deformation occurring in the finishing mortar layer containing.

Here, the thickness of the concrete slab (SB) is preferably 210 mm or more (150 mm for the ramen structure, 180 mm for the flat plate structure).

For this purpose, the inter-floor impact sound blocking structure (A) is provided to include an air mat 20, a support panel 30, a cushioning material 40, a hot water pipe 50, and a finishing mortar layer 60. An air mat 20 is provided on the top of the concrete slab SB, a support panel 30 is provided on the top of the air mat 20, and a cushioning material 40 is provided on the top of the support panel 30.

A hot water pipe 50 is placed on the top of the cushioning material 40, and finishing mortar M is poured and hardened on the top of the cushioning material 40 on which the hot water pipe 50 is placed to form a finishing mortar layer 60.

As shown in FIG. 2, an elastic sheet 10 may be provided on the top of the concrete slab SB, and an air mat 20 may be provided on the top of the elastic sheet 10.

This has the effect of leveling the upper surface of the concrete slab (SB) by removing foreign substances and covering the bottom of the concrete slab (SB), and also has an elastic effect due to the elastic sheet 10. The effect of blocking floor impact noise between floors can be achieved.

The thickness of the elastic sheet 10 is preferably about 1 to 5 mm, and it is desirable to have a thickness of 2 mm. This means that if the thickness of the elastic sheet 10 is less than 1 mm, the elastic effect is minimal, and if it is more than 5 mm, the elastic effect is good, but the space utilization ratio decreases and the floor height increases due to the increase in the thickness of the floor slab.

The air mat 20 is provided to have a mat shape with a thickness of 30 to 40 mm, and the yarns 210 are twisted irregularly to form air layers 220 of various shapes.

For this purpose, the air mat 20 is formed by irregularly twisting gray yarn 210 with a diameter of 0.5 to 1.5 mm made of a synthetic resin composition to form various air layers 210, and the synthesis of the yarn is performed. The resin composition is preferably TPR (synthetic rubber), PU (Polyurethane), POP (Polyolefin Plastomer), or EVA (Ethylene-Vinyl Acetatecop olymer).

A predetermined elastic force is provided by the twisted yarn 210 in the air mat 20 and has a shape that supports the support panel 30, which will be described later, so that the finishing mortar layer 60 provided at the top has sufficient elastic force or not. Elastic support can be provided. This prevents cracks or local deformation from occurring in the finishing mortar layer 60, thereby extending its lifespan.

Therefore, the thickness of the air mat 20 must be greater than the height of the support panel 30.

In addition to the yarns 210 twisted in the air mat 20, the interlayer floor impact sound generated in the finishing mortar layer 60 moves laterally due to the air layer 220 provided in the space between the yarns 210. As it is discharged to the outside through the floor impact sound discharge gap 70, which will be described later, the floor impact sound between floors can be reduced by that much.

The support panel 30 is placed on the top of the air mat 20 to sufficiently support the load acting from the top to the bottom, and floor impact sound is also transmitted to the outside through the edge of the air mat 20 located at the bottom. In order to be discharged, a plurality of support legs 320 are integrally formed on the bottom of the square support plate 310.

It is preferable that the lower end of the support leg 320 is formed in a sharp cone shape so that it can be inserted into and supported by the air mat 20.

The support panel 30 is the most important element in this invention. The support legs 320 of the support panel 30 are attached to the air mat 20 at the top of the air mat 20 where the air layer 220 is formed. By being inserted and supported on the large concrete slab (SB), the loads of the cushioning material 40, the hot water pipe 50, and the finishing mortar layer 60 provided on the upper part of the support panel 30 can be stably supported.

If the support panel 30 is not present or the support force of the support panel 30 is weak, cracks and local deformation will occur in the finishing mortar layer 60, and the bottom layer will settle due to the load of the finishing mortar layer 60. phenomenon occurs.

The square support plate 310 of the support panel 30 is provided with a plurality of horizontal supports 312 and vertical supports 313 in a lattice shape inside the edge support 311 to strengthen the support force, The support leg 320 is provided at a position where the horizontal support pieces 312 and the vertical support pieces 313 of the square support plate 310 are perpendicular to each other.

The square support plate 310 of the support panel 30 is provided with reinforcing supports 314 diagonally to prevent deformation and ensure sufficient support force, and is provided at the top of the square support plate 310. Floor impact sound can be transmitted to the lower part.

The support leg 320 of the support panel 30 is formed in a cone shape with a sharp lower end so that it can be inserted into and supported by the air mat 20. The lower part of the support leg 320 has a pointed shape with a closed shape. A blocking support 321 is formed, and a circular opening 322 with an open top is formed at the top, and a conical space 323 is formed inside to be connected to the circular opening 322.

A plurality of vertically elongated grooves 324 are formed on the side of the support leg 320 to be connected to the conical space 322, thereby enhancing strength while reducing the amount of material used, and also reducing part of the floor impact sound. It is transmitted to the lower part through the groove 324 to prevent it from moving around inside.

The height of the support panel 30 is smaller than the thickness of the air mat 20, so that the support legs 320 of the support panel 30 are inserted into the air mat 20 to support the concrete slab SB. Alternatively, it is preferable that the upper surface of the elastic sheet 10 be lifted by about 4 to 8 mm.

As shown in Figure 5, when the hot water pipe 50, the finishing mortar layer 60, and the floor finishing material 80 are provided on the upper part of the buffer part 40, the support leg 320 is pressed downward by its weight. By maintaining the lower end of the concrete slab (SB) or the elastic sheet 10, the overall load does not act directly on the concrete slab (SB), but rather acts on the support panel 30 and the air mat (which acts as a spring) As it is dispersed by 20), the finishing mortar layer 60 can be further stably supported.

The cushioning material 40 is made of any one of EPS (Expanded Polystyrene), EPP (Expanded Polypropylene), and EVA (Ethylene Vinyl Acetate) to ensure that the hot water pipe 50 is stably supported and to obtain a further cushioning effect. It becomes possible.

The cushioning material 40 refers to a material installed on the floor structure to absorb impact sound. The cushioning material 40 and the cushioning material 40 are installed in close contact so as not to create a gap between them, and the joint area is finished with a joint tape, etc. It is desirable.

The thickness of the cushioning material (40) is preferably 20 to 40 mm depending on the building, and the cushioning material (40) must comply with the insulation standards according to Article 2 of the energy-saving design standards for buildings, and the dynamic elastic coefficient is 40MN/m ^3. Hereinafter, the loss coefficient should be in the range from 01 to 03.

The cushioning material 40 is a cushioning material made of one of EPS (Expanded Polystyrene), EPP (Expanded Polypropylene), and EVA (Ethylene Vinyl Acetate). However, in addition to these types, it can be made of non-woven fabric, glass wool in the form of glass fiber, or sponge. It can be provided with any one of the following. At this time, the size of the cushioning material 40 is preferably 900Х1000mm, 900Х1800mm, 1000Х1000mm, or 1000Х2000mm.

The hot water pipe 50 is placed on the cushioning material 40 by a plurality of ∩-shaped fixing pins 510, and a fishhook-shaped hook is provided at the bottom of the leg portion 510a of the ∩-shaped fixing pins 510. (510b) is provided to prevent the locking portion 510b of the ∩-shaped fixing pin 510 from being separated in the reverse direction at the same time as it is inserted into the cushioning material 40, so that even if the worker steps on the hot water pipe 50, the fixing pin (510b) is provided. 510) is pulled out to prevent the hot water pipe 50 from flowing.

The thickness of the finishing mortar layer 60 is 40 mm or more, preferably 60 mm or more, and the finishing mortar (M) forming the finishing mortar layer 60 is generally made by mixing only cement and sand as a binder, For flooring, a cement to sand ratio of about 1:3 is desirable.

In addition, inside the corner side wall surface (SW) between the concrete slab (SB) and the side wall surface (SW), the top is open " "A shaped floor impact sound discharge gap 70 is provided so that the floor impact sound generated from the finishing mortar layer 60 is transmitted through the cushioning material 40, the support panel 30, and the air mat 20. By being discharged to the outside through the floor impact sound discharge gap 70 located above the edge of the floor impact sound, a corresponding amount of floor impact sound can be blocked.

A more preferable floor impact sound discharge gap 70 is provided from the upper part of the support panel 30, and is provided on the side wall surface (SW) on one side and the laminated cushioning material 40 and finishing mortar layer 60 on the other side. This has a more impact sound blocking effect.

In this invention, the floor finishing material 80 refers to a material (foamed vinyl flooring, wood flooring, etc.) that is finally finished on the upper surface of the finishing mortar layer 60.

In this invention, an air mat 20 having a large air layer 220 is provided on the upper surface of a concrete slab (SB), a support panel 30 is provided on the upper surface of the air mat 20, and the support panel ( By providing the cushioning material 40 at the top of 30), there is an effect of lowering the dynamic modulus of elasticity to increase the sound insulation effect, as well as lowering the residual strain to minimize the risk of floor subsidence due to the load of the finishing mortar layer 60. .

Figure 6 is a flowchart showing the construction state of the inter-floor floor impact sound blocking structure according to this invention.

Construction of the inter-floor impact sound blocking structure provided on the concrete slab (SB) of the building structure according to this invention first involves removing foreign substances on the top of the concrete slab (SB) of the building structure and installing the elastic sheet (10). In the elastic sheet installation step (S100), an air mat 20 having a predetermined thickness is installed to cover the upper part of the elastic sheet 10 (air mat installation step (S200)). At this time, before the elastic sheet installation step (S100), the inside of the concrete slab (SB) and the side wall (SW) is " Creation of a gap so that the gap creation hole (G) is installed on the side wall (SW) at a certain height from the top or bottom of the concrete slab (SB) in order to provide a "shaped floor impact sound discharge gap (70). The old installation step (S50) can be further included.

This discharge gap 70 is constructed by providing a hot water pipe 50 and a finishing mortar layer 60 on the top of the cushioning material 40 and then separating them by pulling out the gap creation port (G).

Next, in the support panel installation step (S300), the support panel 30 is installed to rest on the top of the air mat 20, and then the cushioning material 40 is installed to cover the top of the support panel 30. (Buffer installation step (S400)).

Next, in the hot water pipe placing step (S500), the hot water pipe 50 is placed on the upper part of the cushioning material 40 by the ∩-shaped fixing pin 510, and then the cushioning material 40 on which the hot water pipe 50 is placed is placed. ) is constructed by pouring and curing the finishing mortar (M) on the upper part of the mortar layer so that the finishing mortar layer 60 is installed (finishing mortar layer installation step (S600)).

Subsequently, after the finishing mortar layer installation step (S600), it is preferable to further include a floor finishing material installation step (S700) in which the floor finishing material 80 is installed on the upper part of the finishing mortar layer 60.

10:Elastic sheet 20:Air mat
30: Support panel 40: Buffer material
50: Hot water pipe 60: Finishing mortar layer
70: Floor impact sound discharge gap 210: Yarn
220: Air layer 310: Square support plate
320: Support leg 510: ∩-shaped fixing pin
510a: Leg portion 510b: Locking portion
A: Floor impact sound blocking structure between floors M: Finishing mortar
SB: Concrete slab SW: Side wall
S100: Elastic sheet installation step S200: Air mat installation step
S300: Support panel installation step S400: Buffer installation step
S500: Hot water pipe placement step S600: Finishing mortar layer installation step

Claims (7)

In the inter-floor impact sound blocking structure (A) for noise prevention provided on the top of the concrete slab (SB) of a building structure,
The inter-floor impact sound blocking structure (A) includes an elastic sheet 10 on an upper part of a concrete slab (SB), an air mat 20 on an upper part of the elastic sheet 10, and the air mat 20. A plurality of support panels 30 are provided in contact with each other on the entire upper surface, a cushioning material 40 is provided on the entire upper part of the plurality of support panels 30, and a hot water pipe ( 50) is placed, and finishing mortar (M) is poured and hardened on the top of the cushioning material 40 on which the hot water pipe 50 is placed to provide a finishing mortar layer 60, and the support panel 30 is a square support plate. (310) A plurality of support legs 320 are integrally provided on the bottom, and the square support plate 310 of the support panel 30 has a plurality of horizontal supports 312 and a plurality of horizontal supports 312 inside the edge support 311. Vertical support beams 313 are provided in a grid shape, the square support plate 310 of the support panel 30 is provided with reinforcing support bars 314 in the diagonal direction, and the support legs 320 are provided with the square support plate ( The horizontal abutment 312 and the vertical abutment 313 of 310 are provided at the lower part at a position orthogonal, and the lower end of the support leg 320 has a closed shape so that it is inserted into and supported by the air mat 20. It is formed of a pointed block support portion 321, and the upper part of the support leg 320 is connected to the square support plate 310 to form a circular opening portion 322 with an open top, and the support leg 320 ) The interior of the body is formed as a conical space 323 to be connected to the circular opening 322, and a plurality of vertically elongated grooves 324 are formed on the side of the body of the support leg 320. An inter-floor floor impact sound blocking structure, characterized in that it is provided to be connected to the conical space 323.
According to paragraph 1,
The air mat 20 is formed in a mat shape, and the yarns 210 are twisted irregularly to form air layers 220 of various shapes. An interlayer floor impact sound blocking structure.
delete According to paragraph 1,
The cushioning material 40 is made of any one of EPS (Expanded Polystyrene), EPP (Expanded Polypropylene), and EVA (Ethylene Vinyl Acetate), and the hot water pipe 50 is provided with a plurality of ∩-shaped fixing pins 510. An inter-floor floor impact sound blocking structure placed on a cushioning material (40), wherein the leg portion (510a) of the ∩-shaped fixing pin (510) is inserted into and fixed to the cushioning material (40).
According to paragraph 1,
An inter-floor floor impact sound blocking structure, characterized in that the thickness of the air mat (20) is greater than the height of the support panel (30).
According to paragraph 1,
On the inside of the corner side wall (SW) between the concrete slab (SB) and the side wall (SW), the upper part is open. "An inter-floor floor impact sound blocking structure characterized by having a shaped floor impact sound discharge gap (70).
In the construction method of an inter-floor floor impact sound blocking structure for noise prevention according to the invention of claim 1, which is provided on the top of the concrete slab (SB) of a building structure,
An elastic sheet installation step (S100) in which the elastic sheet 10 is installed on the upper part of the concrete slab (SB);
An air mat installation step (S200) in which an air mat 20 having a predetermined thickness is installed on the elastic sheet 10;
A support panel installation step (S300) in which a support panel 30 is installed on the air mat 20;
A cushioning material installation step (S400) in which a cushioning material 40 is installed on the upper part of the support panel 30;
A hot water pipe placing step (S500) in which the hot water pipe 50 is placed on the upper part of the cushioning material 40 by a ∩-shaped fixing pin 510; and
A finishing mortar layer installation step (S600) in which the finishing mortar (M) is poured and hardened onto the top of the cushioning material (40) on which the hot water pipe (50) is placed and the finishing mortar layer (60) is installed; A method of constructing an inter-floor floor impact sound blocking structure comprising: