KR101892020B1 - Construction hypocaust slab structure having noise isolation structure for bulding and construction method thereof - Google Patents

Abstract

The present invention relates to a heating slab structure used to prevent building interlayer noise, and a construction method thereof. More specifically, the heating slab structure is capable of remarkably reducing vibration and noise as well as improving heating efficiency in configuring an interlayer slab of a building, and is capable of remarkably reducing construction costs by utilizing recycling resources. According to the present invention, the heating slab structure comprises: a buffer sound absorption layer provided on the upper surface of a floor slab; a heat shield and stress dispersion layer provided on the upper part of the buffer sound absorption layer to suppress heat generated in a heating pipe from being transferred to the lower part and to disperse a load applied from the upper part; the heating pipe provided on the upper part of the heat shield and stress dispersion layer; a heat loss suppressing filler filled in the heating pipe to be filled to the height of the heating pipe or to cover the heating pipe; and a cement mortar layer deposited and cured on the heating pipe to form a cement mortar layer.

Description

TECHNICAL FIELD [0001] The present invention relates to a heating slab structure for preventing noise between buildings, and a construction method of the slab structure.

The present invention relates to a structure for preventing noise between buildings and a heating slab structure and a construction method thereof, and more particularly, to an improvement of a heating efficiency and vibration and noise in constituting an interlaminar slab of a building, The present invention relates to a structure for preventing noise between buildings and a heating slab structure and a construction method thereof.

Generally, a multi-family multi-family building such as an apartment or a villa has a multi-layered structure with a single-story building in which a household resides, so that the lower- The slabs have been structurally characterized to cause a great deal of inconvenience to heating, insulation and insulation, as well as causing interlayer noise.

That is, in the case of a general multi-storey building, an interlayer wall is formed between a lower layer and a upper layer to form an ondol heating slab structure for heating on the upper surface of the interlayer wall. Then,

FIG. 1 is a cross-sectional exemplary view showing a conventional Ondol heating slab structure according to the prior art. In the conventional Ondol heating slab structure, as shown in FIG. 1, A pipe (B) is buried at regular intervals, a mortar (C) is installed to fix the heating pipe (B), and a floor finishing material (D) such as wood or a tile, Thereby completing the Ondol heating slab structure by adding the soundproofing material E to the upper and lower ends of the mortar layer for fixing the heating pipe B, if necessary.

However, in the conventional ondol heating slab structure as described above, since mortar is placed on the upper part of the interlayer wall of the building, the inserted mortar becomes integrated with the interlayer wall body, so that the interlayer wall body and the ondol heating slab form a single lump .

Therefore, when an impact is applied from the upper part of the ondol heating slab, the noise or vibration due to the impact is directly transmitted to the lower layer through the mortar constituting the ondol heating slab and transferred to the lower layer. The shocks, noise, and noise generated by sound devices such as television and audio are transmitted to the lower layer as they ride through the interstice walls, and the inconvenience caused by the noise is very serious. Recently, There is a considerable social problem such as frequent quarrels between the neighbors who reside on the upper floor.

In addition, in the Ondol heating slab structure, it takes a long time for the heat generated in the process of heating by the heating pipe fixed by the mortar to spread through the mortar so that it is difficult to heat quickly, and the mortar itself generates heat There is a problem that the heating efficiency is greatly lowered because the heat can not be stored for a long time and the heat is easily lost.

In addition, since the mortar structure, which is the main raw material of cement, is very heavy in weight, the mortar structure is added to the dry matter that forms the interlayer wall, The work process for installing mortar is also difficult, requires a professional workforce, has a high cost of construction, and has a drawback in that the construction time is prolonged due to the necessity of the curing process.

(Literature 0001) Korean Patent No. 10-0669818 (Date of Notification: 2007. 01. 16.) Korean Patent Laid-Open No. 10-2002-0013232 (published on Feb. 20, 2002) (Document 0003) Korean Utility Model Registration No. 20-0315831 (Date of Publication: 2003. 06. 11.) (Publication 0004) Korean Patent No. 10-1723976 (Publication Date: Apr. 26, 2017)

It is an object of the present invention to solve the above problems and to provide a slab of a multilevel multi-family residential building such as an apartment or a villa, which can improve heating efficiency and significantly reduce vibration and impact noise. A combined heating slab structure and a construction method thereof.

Another object of the present invention is to provide a slab structure capable of reducing the construction cost by utilizing the recycled resources and reducing the weight of the slab structure to greatly reduce the total load, thereby improving the durability and the longevity of the building And a method of constructing the same.

According to an aspect of the present invention, there is provided a building heating slab structure comprising: a buffer absorbing layer provided on an upper surface of a bottom slab layer; A heat and stress dispersion layer provided on the buffering and sound absorbing layer to suppress heat transferring from the lower heat generating pipe to the lower portion and to disperse a load acting from the upper portion; A heating pipe provided on the upper portion of the heat-generating and stress-dispersing layer; A heat loss suppressing filler filled to fill the space between the heating pipes to a height of the heating pipe or to cover the heating pipe; And a cement mortar layer cured on the heating fin to form a cement mortar layer.

The buffer absorbing layer may include corrugated cardboard corrugated on the upper surface of the bottom slab layer and an air mat provided on the upper surface of the corrugated cardboard and having an air space of a predetermined size defined and continuously arranged, The heat-shielding and stress-dispersing layer comprises a resin panel in which a plurality of perforated unit panels are connected to each other, and the heat-loss-suppressing filler may be formed into a ball shape comprising glass grains and pulp.

In addition, it may further comprise a mesh network member having a predetermined mesh size provided on the ball-shaped heat loss-suppressing filler.

As a method of constructing a floor slab of a building, a corrugated cardboard installation step of installing corrugated cardboard on the upper surface of the bottom slab layer; An air mat installation step of installing an air mat on the corrugated board, the air mat being formed by successively arranging a predetermined size of air space; Installing a resin panel on an upper portion of the air mat; A heating pipe exerting step of installing a heating pipe on an upper portion of the resin panel; A ball filling step of filling a ball formed by mixing pulp-glass particles between the heating pipes; And forming a cement mortar layer by curing and curing a cement mortar on the heating pipe.

The method may further include installing a mesh network having a predetermined mesh size on the heating pipe before the finishing layer is formed after the heating pipe is discharged.

As can be clearly understood from the above description, the structure-to-building noise-preventing double-layered heating slab structure and its construction method of the present invention are characterized in that components constituting the interlayer floor slab structure quickly propagate heat across the entire heat generated in the heating pipe So that the heating efficiency can be remarkably improved.

Further, the heat generated from the heating pipe can be rapidly propagated, and the heat can be maintained, and the noise due to vibration and impact can be remarkably reduced.

In addition, it is possible to reduce the construction cost by utilizing the recycled resources, and the weight of the slab structure can be reduced to greatly reduce the total load, thereby greatly contributing to improvement in durability and extension of the life of the building .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing a conventional Ondol heating slab structure. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a floor slab,
3 is a flow chart showing a construction process of a heating slab for preventing building-to-building noise noise according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 2 is a view showing a structure of a heating slab for preventing building-to-building noise between buildings according to the present invention.

As shown in FIG. 2, the building-to-building noise-preventing heating slab structure according to the present invention includes: a buffering sound-absorbing layer 100 provided on an upper surface of a bottom slab layer S; A heat and stress dispersion layer 200 provided on the buffering / sound absorbing layer 100 to suppress heat conduction to the lower portion and to disperse stress acting from the upper portion; A heating pipe 300 provided at an upper portion of the heat and stress dispersion layer 200 and configured to provide heating heat through a heating medium to be supplied; The heat pipe 300 is filled up to the height of the heating pipe 300 or the heating pipe 300 while being filled between the heating pipes 300. The heat pipe 300 maintains heat generated by the heating pipe 300, Filler (400); And a cement mortar layer 500 cured on the heating fin 300 to form a cement mortar layer.

The top floor of the cement mortar layer 500 is provided with a flooring or a wood flooring.

The buffering and sound absorbing layer 100 comprises a corrugated cardboard 110 formed of a pulp material and formed in a corrugated shape and provided on the upper surface of the bottom slab layer S and a corrugated cardboard 110 provided on an upper surface of the corrugated cardboard 110, And an air mat (120) having a space defined and continuously arranged.

The corrugated cardboard 110 may be made of recycled corrugated paper formed by dissolving recycled pulp such as waste newspaper, waste magazine, high paper, old paper, and corrugated cardboard into water, vacuum dewatering, and drying through hot pressing. In addition, the corrugated cardboard 110 made of such recycled corrugated cardboard can be recycled because it uses recyclable pulp such as waste paper as its raw material.

Subsequently, the air mat 120 is formed, for example, by vertically and horizontally connecting a plurality of airbags made by blow molding polyethylene.

Here, the heating slab structure for preventing building-to-building noise between buildings in the present invention is characterized in that, in the space portion formed by the air mat (120) having the corrugated cardboard (110) A member (not shown) may be filled. As the sound absorbing member, a glass fiber sound absorbing material, a polyester sound absorbing material, a polyestrene sound absorbing material, a melanin sound absorbing material, a sponge type sound absorbing material, and the like can be variously applied.

Next, the heat-shielding and stress-dispersing layer 200 is formed of a panel in which unitary panels made of polyethylene are adhesively connected to each other, and a plurality of holes may be formed in the unit panel.

The panel made of the resin material (for example, polyethylene) constituting the heat-shielding and stress-dispersive layer 200 can disperse loads acting on the upper part, remove stress and noise, and cut off radiant heat.

A unit panel constituting the panel 200 may be formed by recycling waste plastics. In other words, the unit panel can be formed by washing, crushing, melting and injection molding the waste plastics.

Specifically, the unit panel is made of a plastic material, has a plurality of through holes, and is formed into a rectangular box shape opened on one side. The unit panel is bonded by using an adhesive or the like to form a panel having a size corresponding to the construction surface.

Since the heating pipe 300 can employ a conventional heating pipe such as a copper pipe capable of generating heating heat while passing a heat fluid, a detailed description thereof will be omitted.

Next, the heat-loss-suppressing filler 400 may be made of glass particles having a predetermined particle size and a ball shape including pulp. Herein, the glass grains constituting the ball-shaped heat-loss-suppressing filler (400) can be recycled from waste glass bottles or the like.

For example, the ball-shaped heat-loss-suppressing filler 400 made of glass grains and pulp may be obtained by molding a mixture obtained by mixing inorganic particles of glass particles and fibers of pulp or pulp together with a predetermined amount of water in a squeeze machine (Foam glass artificial material).

As described above, the ball-shaped heat-loss-suppressing filler 400 made of glass grains and pulp can recycle resources by using a waste glass bottle. Such a heat-loss-suppressing filler 400 constitutes a bottom- And the stress acting from the upper part can be dispersed. Microvoids are formed therebetween, and sound absorption can be performed by the gap.

The structure of the present invention may further include a mesh network member 410 having a predetermined mesh size, which is provided on the ball-shaped heat-loss-suppressing filler 400.

In the heating slab structure for preventing building-to-building noise in the present invention, the mesh net member 410 is formed on the ball-shaped heat-loss-suppressing filler 400, and the ball- It is possible to prevent the ball-shaped heat-damage-suppressing filler 400 from buoyancy when the cement mortar is poured thereon.

Next, a method of constructing a heating slab for preventing building-to-building noise from occurring according to the present invention will be described with reference to FIG. FIG. 3 is a flow chart illustrating a construction process of a heating slab for preventing building-to-building noise from noise according to the present invention. In the following description of the method for constructing a building-to-building noise-free heating slab according to the present invention, a description of the elements described in the construction-to-building-to-building sound-insulating slab construction method according to the present invention will be simplified or omitted.

As shown in FIG. 3, the method for constructing a building-to-building noise prevention slab according to the present invention includes a corrugated board installation step (S100) of installing corrugated cardboard on the upper surface of a bottom slab layer (S); (S200) of installing an air mat on which the air space is divided by the corrugated board and continuously arranged; A panel installing step (S300) of installing a flat resin panel on the air mat; A heating pipe discharging step (S400) of installing a heating pipe on the resin panel; A ball filling step (S500) of filling ball containing pulp-glass particles between the heating pipes; And forming a cement mortar layer by curing and curing the mortar on the heating pipe (S600). On the upper surface of the cement mortar layer, a final floor covering material or a wooden floor covering is laid.

In addition, the method may further include a mesh network installing step (S700) of installing a mesh mesh having a predetermined mesh size on the heating pipe before the finishing layer forming step (S600) after the heating pipe is discharged.

In addition, a glass fiber sound absorbing material, a polyester sound absorbing material, a polyurethane sound absorbing material, a melanin sound absorbing material, and a melamine sound absorbing material are adhered to the space portion formed by the air mat having the corrugated cardboard and the corrugated portion of corrugations after the air mat installation and before the panel installing step (S300) , And a sound absorbing material filling step (S800) for filling one sound absorbing material selected from spongy sound absorbing materials.

The corrugated cardboard and the air mat installed in the corrugated cardboard installation step (S100) and the air mat installation step (S200) form a buffering sound-absorbing layer.

The corrugated board provided in the corrugated cardboard installation step (S100) is made of recycled corrugated paper formed by dissolving recycled pulp such as waste newspaper, waste magazine, high paper, old paper, and corrugated cardboard into water, vacuum dewatering, . The corrugated board made of such recycled corrugated cardboard can be recycled because the recycled pulp such as waste paper is used as the raw material.

Further, the air mat provided in the air mat installing step (S200) is formed by vertically and horizontally connecting a plurality of air bags made, for example, by blowing polyethylene.

The panel provided in the panel installation step S300 is provided with the unit panel as described above, so that the load acting on the upper panel can be dispersed, stress and noise can be removed, and heat radiated from the heating pipe can be blocked.

The ball provided in the ball filling step S500 is formed into a ball shape (a foamed glass artificial material) by including glass grains having a predetermined particle size and pulp. For example, the inorganic particles of the glass grains, Of water mixed with water can be molded into a sphere in a compression machine. The glass grains can be recycled by crushing a waste glass bottle or the like.

As described above, the ball-filled portion formed by the balls made of glass grains and pulp has microvoids formed thereon, so that it is possible to absorb sound by the voids, and it is possible to increase the heating efficiency by providing heat insulation to the lower portion.

Next, the mesh network installed in the mesh network installation step (S700) is configured on a heating pipe filled with balls, and the ball positioned below the mesh network is interrupted while locating, and when the cement mortar is poured, It is possible to prevent buoyancy from floating.

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 and scope of the invention as defined by the appended claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the claims should be construed as being included in the scope of the present invention.

100: buffer absorbing layer, 110: corrugated cardboard
120: air mat, 200: shear and stress dispersion layer
300: Heating pipe 400: Heat loss-inhibiting filler
410 mesh network member 500 cement mortar layer
S100: Corrugated board installation step S200: Air mat mounting step
S300: panel mounting step S400: heating pipe discharging step
S500: Ball filling step S600: Finishing layer forming step
S700: Mesh network installation step S800: Sound absorption material charging step

Claims (5)

delete As a building heating slab structure,
A buffer absorbing layer provided on an upper surface of the bottom slab layer;
A heat and stress dispersion layer provided on the buffering and sound absorbing layer to suppress heat transferring from the lower heat generating pipe to the lower portion and to disperse a load acting from the upper portion;
A heating pipe provided on the upper portion of the heat-generating and stress-dispersing layer;
A heat loss suppressing filler filled to fill the space between the heating pipes to a height of the heating pipe or to cover the heating pipe; And
And a cement mortar layer cast on the heating float to form a cement mortar layer,
Wherein the buffer absorbing layer comprises corrugated cardboard corrugated on a top surface of the bottom slab layer and an air mat provided on an upper surface of the corrugated cardboard and having an air space of a predetermined size defined and continuously arranged,
Wherein the heat-shielding and stress-dispersing layer comprises a resin panel in which unit panels having a plurality of holes are connected to each other,
Wherein the heat loss suppressing filler is formed in a ball shape comprising glass grains and pulp.
3. The method of claim 2,
Further comprising a mesh net member having a predetermined mesh size provided on the ball shaped heat loss suppressing filler.
A method of constructing a floor slab of a building,
A corrugated cardboard forming step of providing corrugated cardboard on the upper surface of the bottom slab layer;
An air mat installation step of installing an air mat on the corrugated board, the air mat being formed by successively arranging a predetermined size of air space;
Installing a resin panel on an upper portion of the air mat;
A heating pipe exerting step of installing a heating pipe on an upper portion of the resin panel;
A ball filling step of filling a ball formed by mixing pulp-glass particles between the heating pipes; And
And forming a cement mortar layer by curing and cementing a mortar on the top of the heating pipe.
5. The method of claim 4,
And installing a mesh network having a predetermined size of mesh on the heating pipe before the finishing layer forming step after the heating pipe is discharged.

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