KR20100068696A - Floor structure for reducing floor impact sound and execution methods of the same - Google Patents

Abstract

PURPOSE: A floor structure for reducing floor impact sound and a construction method thereof are provided to effectively absorb floor impact sound, and to reduce construction time. CONSTITUTION: A floor structure for reducing floor impact sound comprises a floor slab layer(12), a floor reduction material, a wall insulation material(13), an autoclaved lightweight concrete layer(15), and a finishing mortar layer(16). The floor slab layer is integrally formed in a wall(11) which has vertical surfaces. The floor reduction material is loaded on the top of the floor slab layer. The wall insulation material is installed between the wall and the floor reduction material. The autoclaved lightweight concrete layer and the finishing mortar layer are installed on the top of the floor reduction material.

Description

Floor structure for reducing floor impact sound and execution methods of the same}

The present invention relates to a floor structure for floor impact noise reduction and a construction method thereof, and more particularly to a floor impact sound reduction floor structure capable of shortening the floor impact sound and shortening the air of watertight construction of the floor reduction material. It is about a method.

In general, floor impact sound reduction floor structure is used to reduce the impact sound delivered to the neighboring generation or the lower floor by absorbing and consuming the energy of the impact sound applied to the floor.

The floor impact sound reducing floor structure may be classified into a wet type and a semi-dry type. Wet floor impact sound reduction floor structure is used when the floor of the apartment house is constructed by the wet construction method, semi-dry floor impact sound reduction floor structure is used when the floor of the apartment house is constructed by the semi-dry construction method. The semi-dry construction method refers to a construction method in which a mortar having a thick viscosity is installed directly on a buffer layer on a bottom slab layer. In addition, the wet construction method refers to a construction method of installing light foam concrete having a very thin viscosity on the bottom slab layer, and then constructing a mortar having a high viscosity after the lightweight foam concrete is hardened.

According to the semi-dry construction method, since the finishing mortar layer is formed directly on the buffer layer, there is an advantage in that construction is easier than the wet construction method, and according to the wet construction method, since the lightweight foam concrete is constructed on the buffer layer, the thermal insulation performance is improved and the flatness of the floor is improved. There is an advantage to improve. At present, each construction company is properly selected and used one of the semi-dry construction method and the wet construction method in consideration of the environmental conditions and the advantages of the above construction methods.

As shown in FIG. 1, the bottom impact sound reducing floor structure 10 includes a buffer layer 14 provided on the top surface of the bottom slab layer 12, and a wall surface insulating material provided between the buffer layer 14 and the wall 11. (13), the lightweight foamed concrete layer 15 for thermal insulation stacked on top of the buffer layer 14, and the finishing mortar layer 16 laminated on the lightweight foamed concrete layer 15 and provided with a heating pipe 17. ). The floor impact sound reducing floor structure 10 described above is wet, and the finishing mortar layer 16 is stacked on the buffer layer 14 to be used for semi-drying. That is, the moisture (hereinafter referred to as 'water') generated by the lightweight foam concrete layer 15 and the finishing mortar layer 16 or the finishing mortar layer 16 that is poured and stacked on the buffer layer 14 is a buffer layer ( Watertight construction is carried out at the contact portion between the buffer layer 14 and the wall insulation material 13 so as not to flow into the inside of the 14). In such watertight construction, the adhesive tape 18 is used. The watertight construction is a very important process because water enters the buffer layer 14 to reduce the floor impact noise reduction performance.

However, the part where the wall insulation material 13 and the buffer layer 14 meet is a concave corner part, and there is a problem that it is very difficult to construct with the adhesive tape 18. That is, if the watertight construction of the corner portion using the adhesive tape 18 is not properly made as described above, the watertight failure fails when water is poured into the buffer layer 14 when pouring lightweight foam concrete or mortar. That is, if care is not taken due to the nature of the watertight construction of the corner portion, the construction of the adhesive tape 18 is not performed properly, so the watertightness fails, and in order to prevent such cases, taping the corner portion several times, or the construction of the worker during the taping construction By delaying the time, the karate is excessively increased. As a result, there is a problem that the air and the construction cost of the floor structure increase.

Meanwhile, since the buffer layer 14 has a structure in which a plurality of divided modules having a predetermined area are assembled, the adhesive tape 18 is attached to the assembled portion of the buffer layer 14 in addition to the contact portion between the buffer material 14 and the wall insulation material 13. Attach). Since the assembled parts are made to be horizontal to each other, the watertight construction is simple and easy, and there is no problem that water is introduced.

The present invention has been made to solve the above problems, it is possible to shorten the air of the water-tight construction to prevent water from flowing into the interior of the floor reducing material, it is possible to effectively reduce the floor impact sound energy floor impact sound reduction It is an object of the present invention to provide a floor structure and a construction method thereof.

Still another object of the present invention is to provide a floor structure for reducing impact noise and a method of construction thereof, which can be used in a wet construction method and a semi-dry construction method.

In order to achieve the above object, the present invention provides a floor structure in which a lightweight foamed concrete layer and a finishing mortar layer are stacked on an upper portion of a floor slab layer, stacked on an upper portion of a floor slab layer, and a lightweight foamed concrete layer on an upper surface thereof. A floor reducing material having a laminated mortar layer is provided, and the floor reducing material is bent upwards so as to contact the side of the light foam concrete layer and the finishing mortar layer, the bottom reducing material being in contact with the side of the light foam concrete layer and the finishing mortar layer. The height of the contact portion is the same as the upper surface of the finishing mortar layer or higher than the height of the finishing mortar layer, characterized in that made in contact with the wall insulation.

Another floor structure according to the present invention is a floor structure in which a finish mortar layer is stacked on top of a floor slab layer, the bottom structure of which is laminated on top of a floor slab layer, and a finish mortar layer is stacked on a top surface thereof. The floor reducer is bent upward to contact the side of the finishing mortar layer, the height of the contact portion in contact with the side of the finishing mortar layer is the same as the upper surface of the finishing mortar layer or higher than the height of the finishing mortar layer wall surface Characterized in that the contact made with the insulating material.

Preferably, the bottom reducing material, the buffer layer laminated on the top of the bottom slab; And a contact layer stacked to cover an upper portion of the buffer layer, and having a contact portion contacting the light foamed concrete layer and the side surface of the finishing mortar layer or the side surface of the finishing mortar layer.

Preferably, the contact layer is any one of rubber, foamed polyethylene, foamed polypropylene, polyethylene processed into sheet shape, and polypropylene processed into sheet shape to prevent water from entering the buffer layer. Is done.

In order to achieve the object of the present invention, a method of constructing a floor structure for reducing floor impact sound includes (a) stacking a buffer layer on an upper portion of a floor slab layer, wherein the edge of the contact layer has a larger area than that of the buffer layer. Forming a floor reducing material by being folded up into contact with the wall insulation provided between the wall and the buffer layer and stacking the contact layer on top of the buffer layer; (b) placing light foamed concrete on top of the floor reducing material to form a lightweight foamed concrete layer; And (c) installing a heating pipe on the upper portion of the lightweight foam concrete layer and pouring mortar to form a finishing mortar layer, wherein the height of the contact portion folded in contact with the wall insulation material is the same as the upper surface of the finishing mortar layer. Or higher than the height of the finished mortar layer.

According to another aspect of the present invention, there is provided a method of constructing a floor structure for reducing floor impact sounds, wherein (a ') a buffer layer is stacked on top of a bottom slab layer and has a larger area than that of the buffer layer. Forming a floor reducing material by folding the upright in a vertical direction to make contact with the wall insulation provided between the wall and the buffer layer and stacking the contact layer on top of the buffer layer; And (b ') installing a heating pipe on top of the floor reducing material and pouring mortar to form a finishing mortar layer, wherein the height of the contact portion folded in contact with the wall insulation material is the same as the top surface of the finishing mortar layer or Characterized by being made higher than the height of the finished mortar layer.

In the step of forming the floor reducing material, the buffer layer and the contact layer is made of a plurality of modules each having a predetermined area is assembled, the contact module of the contact layer contacting the wall insulation material of the module of the contact layer one side or two sides in the vertical direction It is preferably formed long to be folded up.

In addition, it is preferable to further include the step of attaching the adhesive tape to the interface between each module contact.

Preferably, the contact layer is any one of rubber, foamed polyethylene, foamed polypropylene, polyethylene processed into sheet shape, and polypropylene processed into sheet shape to prevent water from entering the buffer layer. Is done.

The floor structure for reducing the impact sound and the construction method according to the present invention has the following effects.

First, since the edge of the contact layer of the floor reducing material made of waterproof material is the same or higher than the height of the upper surface of the finishing mortar layer, it is not necessary to apply the adhesive tape to the contact portion of the corner where watertight construction is difficult. Can be saved.

Second, the bottom impact sound performance can be expected to be improved by eliminating the fear of watertightness of the contact portion of the wall, which has a high risk of poor watertight construction.

Third, as the air of watertight construction is shortened, the construction cost can be reduced.

Fourth, the floor impact sound can be efficiently reduced by configuring the floor reducing material for reducing the floor impact sound in a multilayer structure.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be substituted for them at the time of the present application It should be understood that there may be equivalents and variations.

2 is a perspective view schematically illustrating a floor structure for reducing floor impact sound according to a preferred embodiment of the present invention, and FIG. 3 is a cross-sectional view taken along line III-III 'of FIG. 2. The present invention can shorten the air of watertight construction to prevent water from flowing into the floor reducing material by lightweight foamed concrete or mortar, and is characterized by effectively absorbing floor impact sound energy. It is also characterized by its ability to be used in wet or semi-dry construction.

Referring to the drawings, the floor impact sound reduction floor structure 200, the floor slab layer 12, the floor reduction layer laminated on top of the bottom slab layer 12 formed integrally facing the wall 11 having a vertical plane. Wall insulation material 13 provided between the ash 100, the wall 11, and the floor reducing material 100, and the lightweight foamed concrete layer 15 and the finishing mortar layer 16 provided on the floor reducing material 100. Or finish mortar layer 16. Here, the light-bubble concrete layer 15 and the finishing mortar layer 16 are laminated in the upper portion of the floor reducing material 100 is a wet structure, the finishing mortar layer 16 on the floor reducing material 100 is The laminate is a semi-dry structure. That is, as described above, the present invention is applicable to both the wet structure and the semi-dry structure, and will be described below as a structure for the wet structure.

On the other hand, since the wall insulation material 13, lightweight foam concrete layer 15, and the finishing mortar layer 16 is commonly used in the floor structure for reducing the floor impact sound, a detailed description thereof will be omitted.

The floor reducing material 100 is laminated on the bottom slab layer 12 and is installed to reduce the floor impact sound. In addition, the floor reducing material 100 according to the present invention serves to shorten the floor impact sound, as well as to shorten the air (water) of the water-tight construction of the contact area where the floor reducing material 100 and the wall insulation material 13 is in contact. It is installed to perform.

In order to achieve the purpose of the floor reducing material 100 to shorten the air of the watertight construction, the floor reducing material 100 is the edge of the lightweight foam concrete layer 15 and the finishing mortar layer 16 It is formed to be bent upward in the vertical direction to contact the side and wall insulation material (13). Here, the height of the contact portion 122 in contact with the side of the light-weight foam concrete layer 15 and the finishing mortar layer 16 is the same as the upper surface of the finishing mortar layer 16 or higher than the height of the upper surface of the finishing mortar layer 16. Is done. Therefore, the water generated during the pouring of the lightweight foam concrete and the finishing mortar is prevented from flowing between the floor reducing material 100 and the wall insulation material 13.

More specifically, the floor reducing material 100 is laminated to cover the upper portion of the buffer layer 110 and the buffer layer 110, the upper layer of the slab layer 12, lightweight foam concrete layer 15 and the finishing mortar And a contact layer 120 having a contact portion 122 in contact with the side of the layer 16.

The buffer layer 110 is provided on the bottom slab layer 12 to reduce the floor impact sound. In this case, the buffer layer 110 is shown as being made of a single layer, but is not limited to this, it may be made of a multilayer structure. In addition, when the buffer layer 110 has a multi-layered structure, it is apparent that the buffer layer may be formed to have different materials and different thicknesses.

The contact layer 120 may be formed of rubber, foamed polyethylene, foamed polypropylene, polyethylene processed into a sheet shape, and polypropylene processed into a sheet shape to prevent water from entering the buffer layer 110. It is made of either. The contact layer 120 is formed to have an area larger than that of the buffer layer 110. Accordingly, the edge of the contact layer 120 is folded in the vertical direction to contact the side and wall insulation material 13 of the light-weight foam concrete layer 15 and the finishing mortar layer 16. The contact portion 122 is a part in contact with the side surface of the wall insulation material 13 and the lightweight foamed concrete layer 15 and the finishing mortar layer 16.

The contact portion 122 has a height that is the same as the top surface of the finishing mortar layer 16 located on the top layer of the bottom structure 200 or higher than the height of the finishing mortar layer 16. Thus, water generated when pouring lightweight foamed concrete and mortar is blocked from flowing into the buffer layer 110 through the wall insulating material 13 and the contact layer 120.

As described above, the contact layer 120 serves to reduce the impact of the floor with the buffer layer 110 as well as the waterproof function to prevent water from flowing into the buffer layer 110 as described above.

On the other hand, the buffer layer 110 and the contact layer 120 as described above is formed by assembling a plurality of modules having a predetermined area. In this case, the buffer layer 110 is composed of a plurality of modules having the same area with each other, the contact layer 120 is made of a module having a different area according to the stacking position. That is, as shown in FIG. 4, the contact layer 120 contacts the wall insulation material 13 among the plurality of modules 120a, 120b, and 120c. It is elongated to be folded to protrude in the vertical direction. For example, one side of the contact module 120b in contact with one wall insulation material 13 is formed long, and the contact module 120c in contact with the corner portion where two wall insulation materials 13 meet is formed in two long sides. . In addition, the module 120a that is not in contact with the wall insulation material 13 is formed to have the same area as the module of the buffer layer 110. Accordingly, a long formed portion of the contact modules 120b and 120c in contact with the wall insulation material 13 is folded so that one surface thereof comes into contact with the wall insulation material 13, and the opposite surface is a light-bubble concrete layer 15 and a finishing mortar. In contact with layer 16.

As a result, the contact layer 120 of the floor reducer 100 covers the edge where the wall insulation material 13 and the buffer layer 110 contact and is located at the same or higher level than the top surface of the finishing mortar layer 16. By forming so as to reduce the taping work time of watertight construction and to prevent the inflow of water can be expected to improve the floor impact sound performance.

Meanwhile, reference numeral '17', which is not described, is a heating pipe installed inside the finishing mortar layer 16.

Next, the construction method of the floor structure 200 having the above structure will be described. At this time, the construction method to be described below will be described with respect to the wet construction method. In the meantime, the semi-dry construction method according to the present invention can be easily inferred from the wet construction method by those skilled in the art, and thus detailed description thereof will be omitted.

First, the floor reducing material 100 is laminated on the top of the floor slab layer 12 that forms the interlayer floor of the multi-family house to be constructed with the floor structure 200. At this time, the wall surface insulating material 13 is already installed in the wall 11 of the apartment house. More specifically, the floor reducing material 100 includes a buffer layer 110 stacked on the bottom slab layer 12 and a contact layer 120 stacked on the buffer layer 110. The buffer layer 110 and the contact layer 120 are divided into a plurality of modules to have a predetermined area. For example, the buffer layer 110 is divided into modules having an area of 700 mm by 700 mm and a thickness of 18 mm and stacked on the bottom slab layer 12. In addition, the contact layer 120 has an area of 800 mm × 700 mm in which one side of the module 120a having the area of 700 mm × 700 mm and the module contacting with one wall insulating material 13 is increased, similar to the buffer layer 110. It consists of a contact module 120b and a contact module 120c having an area of 800 mm × 800 mm in which two surfaces are extended in contact with the corner portions of the two wall insulating materials 13. At this time, the contact layer 120 has a thickness of 7mm.

The one side and two sides of the contact module (120b, 120c) is stretched is made to be in contact with the wall insulation material 13 is folded up in the vertical direction. Therefore, the height of the contact portion 122 of the contact layer 120 folded in the vertical direction is 100mm.

Meanwhile, as the contact layer 120 is divided, watertight construction is performed using an adhesive tape (not shown) at a connection portion to which each module 120a, 120b, 120c is connected. That is, as the contact layer 120 is formed to cover the edge portion of the wall insulation material 13, the conventional taping work time can be reduced to 30% to 60% as a whole.

Subsequently, light-weight foamed concrete is poured into the upper portion of the floor reducing material 100 to cure, and the finishing mortar is cured by pouring the upper portion of the light-weight foamed concrete layer 15 to be cured. The lightweight foamed concrete layer 15 and the finishing mortar layer 16 has a thickness of 40mm to 50mm. Accordingly, the contact portion 122 of the contact layer 120 in contact with the side surface of the lightweight foamed concrete layer 15 and the finishing mortar layer 16 has the same height or higher than the upper surface of the finishing mortar layer 16. It is made to have a height to prevent water from flowing into the buffer layer (110).

In addition, the wall insulation material 13 is manufactured to have a thickness of 20 mm and a height of 160 mm. The height of the wall insulation material 13 is typically formed higher than the height of the top surface of the finishing mortar layer 16, and after the finishing mortar layer 16 is formed, the altar is made equal to the height of the finishing mortar layer 16.

The thickness and the folded height of the contact layer 120 of the floor reducing material 100 are described as an embodiment, and may be made to have various thicknesses and heights according to the construction situation of the floor structure 200. That is, the contact portion 122 of the contact layer 120 in contact with the sides of the lightweight foamed concrete layer 15 and the finishing mortar layer 16 is the same height or higher than the top surface of the layer located on the top layer of the floor structure. If made to have, any structure can be employed.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Various modifications and variations are possible, of course, within the scope of equivalents of the claims to be described.

1 is a cross-sectional view showing a conventional floor impact sound reduction structure.

Figure 2 is a perspective view schematically showing a floor structure for reducing floor impact sound according to a preferred embodiment of the present invention.

3 is a cross-sectional view taken along line III-III 'of FIG. 2;

Figure 4 is a plan view showing a contact layer of the floor structure for reducing the impact impact floor according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: floor reducing material 110: buffer layer

120 contact layer 122 contact portion

Claims (10)

In the floor structure in which the lightweight foamed concrete layer and the finishing mortar layer is laminated on the floor slab layer, A floor reducing material laminated on top of the floor slab layer and having a light foamed concrete layer and a finishing mortar layer laminated on the upper surface thereof; The floor reducer is bent upward to contact the sides of the lightweight foam concrete layer and the finishing mortar layer, the height of the contact portion in contact with the side of the lightweight foam concrete layer and the finishing mortar layer is the same as the top surface of the finishing mortar layer or finish Floor structure for reducing the impact impact floor, characterized in that made higher than the height of the mortar layer made in contact with the wall insulation. The method of claim 1, The floor reducing material, A buffer layer stacked on top of the bottom slab layer; And Floor structure for reducing the impact impact floor, characterized in that it comprises a; contact layer formed to cover the upper portion of the buffer layer, the contact portion in contact with the side of the light-weight foam concrete layer and the finishing mortar layer. In the floor structure in which the finishing mortar layer is laminated on top of the floor slab layer, A floor reducing material laminated on top of the bottom slab layer and having a finishing mortar layer laminated on the top surface thereof; The floor reducer is bent upward to contact the side of the finishing mortar layer, the height of the contact portion in contact with the side of the finishing mortar layer is the same as the upper surface of the finishing mortar layer or higher than the height of the finishing mortar layer and the wall insulation material Floor structure for reducing the impact impact floor, characterized in that made to contact. The method of claim 3, The floor reducing material, A buffer layer stacked on top of the bottom slab layer; And Floor structure for reducing the impact impact floor, comprising: a contact layer laminated to cover the top of the buffer layer, the contact portion is formed in contact with the side of the finish mortar layer. The method according to claim 2 or 4, The contact layer is made of any one of rubber, foamed polyethylene, foamed polypropylene, polyethylene processed into sheet shape, and polypropylene processed into sheet shape to prevent water from entering the buffer layer. Floor structure for floor impact sound reduction to be made. (a) Laminating a buffer layer on top of the bottom slab layer, the edge of the contact layer configured to have a larger area than the area of the buffer layer is folded up in the vertical direction to be brought into contact with the wall insulation provided between the wall and the buffer layer and the contact layer is the buffer layer. Forming a floor reducing material by laminating on top of the; (b) placing light foamed concrete on top of the floor reducing material to form a lightweight foamed concrete layer; And (c) installing a heating pipe on top of the lightweight foam concrete layer and pouring mortar to form a finished mortar layer; The height of the contact portion folded in contact with the wall insulation material is the same as the upper surface of the finishing mortar layer or higher than the height of the finishing mortar layer construction method of the floor impact sound reduction floor structure. (a ') A buffer layer is laminated on top of the bottom slab layer, and the edge of the contact layer configured to have an area larger than the area of the buffer layer is folded upward in the vertical direction to be brought into contact with the wall insulation provided between the wall and the buffer layer and the contact layer is Forming a bottom reducing material by laminating on top of the buffer layer; And (b ') installing a heating pipe on top of the floor reducing material and pouring mortar to form a finished mortar layer; and The height of the contact portion folded in contact with the wall insulation material is the same as the upper surface of the finishing mortar layer or higher than the height of the finishing mortar layer construction method of the floor impact sound reduction floor structure. The method according to claim 6 or 7, In the step of forming the floor reducing material, Each of the buffer layer and the contact layer is formed by assembling a plurality of modules each having a predetermined area, and the contact module contacting the wall insulation material among the modules of the contact layer is long so that one side or two sides are folded upward in the vertical direction. Construction method of floor structure for reducing floor impact sound. The method of claim 8, And attaching an adhesive tape to the interface where each module is in contact with each other. The method according to claim 6 or 7, The contact layer is made of any one of rubber, foamed polyethylene, foamed polypropylene, polyethylene processed into sheet shape, and polypropylene processed into sheet shape to prevent water from entering the buffer layer. The construction method of the floor impact sound reduction floor made into.

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