KR101542766B1 - Shock-absorbing unit for constructing floor of building and floor construction structure comprising the same - Google Patents

Abstract

The present invention relates to a shock-absorbing unit for an installation of a building floor, and a floor installation structure having the same. The shock-absorbing unit for the installation of a building floor comprises: a post fixated to a floor structure; an elastic shock-absorbing member inserted into the post; and a support plate installed in the shock-absorbing member. According to the present invention, the shock-absorbing unit for the installation of a building floor effectively absorbs, distributes, and eliminates vibration and noise to provide excellent soundproof and vibration proof performance between the floors of a building. In addition to this, the shock-absorbing unit for the installation of a building floor has excellent thermal conductivity through an improved heating structure; thereby reducing energy consumption.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a shock absorbing unit for floor construction of a building and a floor construction structure including the shock absorbing unit.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shock absorbing unit for floor construction of a building and a floor construction structure including the shock absorbing unit. More particularly, the present invention relates to a shock absorbing structure for effectively absorbing and vibrating noise and vibration, Units and floor construction structures comprising the same.

In building multi-storied buildings such as multi-family houses (villas, etc.) and apartments, it is common that almost all work is done at the construction site. However, in the case of an apartment or the like, a prefabricated method using a PC method may be used.

The construction method of general multi-story building will be briefly described as follows.

First, foundation work such as earthwork and earth compaction is going on. Then, a skeletal structure of the building is formed by using a steel frame such as an H-beam and an I-beam on the ground. Specifically, a plurality of steel frame frames are installed vertically and horizontally, and then steel frame frames are welded or brazed together to form a skeleton structure of the building.

Next, bricks are installed between the vertically installed steel frame frames or the formwork is installed to connect the reinforcing bars to each other. Then, the concrete is laid and cured to construct the wall. Then, a horizontally installed steel frame is laid out with a formwork (typically 'Euroform'), a reinforcing bar is connected to the frame, and concrete is laid and cured to construct a slab. In this way, after concrete pouring and curing, after a certain period of time, if the form is dismantled, one layer is constructed. Then, by repeatedly installing the formwork, pouring concrete, and curing work several times, we construct several layers. The building thus constructed is divided into walls and slabs so as to accommodate several generations, and has a multi-layered structure, and at the same time, is divided into several living spaces in one layer.

At this time, in constructing the slab floor of the building, it is important to block noise and vibration between the floor (lower and upper floors). The shocks from the upper floors, especially the shocks caused by the severe fluctuations of the children in the apartments, cause severe damage to residents living in the lower floors. Accordingly, the installation of a shock absorber for impact absorption and a sound insulating material for exhausting noise can be said to be essential for the floor construction work of the building.

In order to prevent noise and vibration between these layers, sound insulation / cushioning materials such as rubber material and synthetic resin foam are generally installed at the bottom of the slab. For example, in Korean Patent No. 10-0166993 (Patent Document 1), a rubber material is laid on a floor base slab, and a polyethylene (PE) foamed sponge is laid thereon to form a barrier layer. Then, A method of constructing a floor structure for preventing floor impact noise by adhering a floor layer (floor material) on a sponge is proposed.

Korean Patent Laid-Open No. 10-2006-0038862 (Patent Document 2) discloses a foamable material having a foam expansion ratio of 5 to 200 times and a foam having a diameter of 10 to 3,000 탆, which can be used as an anti- A thermoplastic flame retardant foam having a cell has been proposed.

However, the floor construction according to the related art disclosed in the above Patent Documents 1 and 2 has a problem in that it can not effectively block the noise and vibration applied in the upper layer even if the sound insulation / damping material is installed. As a result, residents living in the lower floors are severely damaged by noise and vibration.

Further, as disclosed by the present inventors, Korean Patent No. 10-0757011 (Patent Document 3) and Korean Patent Registration No. 10-0954827 (Patent Document 4) disclose a floor construction structure for providing soundproofness and dustproofness through a hollow portion . However, although it has a soundproof and dustproof property by the hollow portion, it is pointed out that the installation work is somewhat complicated.

On the other hand, the floor construction structure according to the prior art is intended to purchase heating pipes in the finished mortar in heating. However, this causes a problem of a large amount of energy consumption because the thermal conductivity is low.

Korean Patent No. 10-0166993 Korean Patent Publication No. 10-2006-0038862 Korean Patent No. 10-0757011 Korean Patent No. 10-0954827

Accordingly, the present invention has been made to solve the above-mentioned problems of the conventional art, and it is an object of the present invention to provide a building structure capable of effectively absorbing and extinguishing noise and vibration to provide excellent interlayer soundproofness, dustproofness, And an object of the present invention is to provide a floor construction structure including the same.

It is another object of the present invention to provide a bottom construction structure capable of reducing energy consumption by improving the heating structure, thereby achieving excellent thermal conductivity.

According to an aspect of the present invention,

A post fixed on the bottom structure;

A resilient buffer member inserted into the post; And

And a supporting plate provided on the buffer member.

According to a preferred embodiment, it is preferable that the buffer member is constituted by a dish spring in which a plurality of dish members are stacked. At this time, a buffer hole is formed at the center of the plate member to insert the post.

The support plate may include an insertion hole into which the upper end of the post is inserted and a guide portion that guides the upper end of the post from the insertion hole. At this time, the upper end of the post may be inserted into the insertion hole of the support plate, but may be positioned at a predetermined distance from the distal end of the insertion hole.

Further, according to the present invention,

Bottom structure;

A buffer unit provided on the bottom structure;

A thermally conductive metal plate mounted on the buffer unit;

A heat insulating material provided on the bottom structure around the buffer unit; And

And a heating pipe installed between the heat insulating material and the thermally conductive metal plate.

At this time, a buffer pad may be provided at a contact interface between the buffer unit and the thermally conductive metal plate.

INDUSTRIAL APPLICABILITY According to the present invention, sound absorption and vibration are effectively absorbed and exhausted (dispersed), so that interlaminar soundproofness and dustproofness are excellent. In addition, the improved heating structure makes it possible to reduce energy consumption because of its excellent thermal conductivity.

1 is a perspective view of a concrete panel for floor construction of a building according to a first embodiment of the present invention.
2 is a cross-sectional view of a concrete panel for floor construction of a building according to a first embodiment of the present invention, and is a sectional view taken along the line AA in Fig.
3 is a cross-sectional view of a concrete panel for floor construction of a building according to a first embodiment of the present invention, and is a sectional view taken along line BB of Fig.
4 is a perspective view of a concrete panel for floor construction of a building according to a second embodiment of the present invention.
5A to 5E show various embodiments of the truss girder used in the present invention.
6 is a process diagram for explaining a method of manufacturing a concrete panel for floor construction of a building according to the present invention.
7 is a perspective view showing an embodiment of a forming mold for forming a charging cell.
8 is a perspective view showing another embodiment of the mold.
9 is a cross-sectional view illustrating a process of installing a concrete panel for floor construction of a building according to the present invention.
10 is a cross-sectional structural view of a floor construction structure according to an exemplary embodiment of the present invention.
11 is an exploded perspective view showing an embodiment of a shock absorber unit used in the present invention.
12 is a perspective view of a plate member constituting a shock absorber unit used in the present invention.
13 is a sectional view of a plate member constituting a shock absorber unit used in the present invention.
14 is a cross-sectional view showing another embodiment of the shock absorber unit used in the present invention.
15 is a rear perspective view of a support plate constituting a shock absorber unit used in the present invention.
16 is a perspective view showing a part of a floor construction structure according to another embodiment of the present invention.
17 is a cross-sectional view showing a floor construction structure according to another embodiment of the present invention.

In this specification, 'and / or' are used to mean at least one of the elements listed before and after.

The terms "first", "second", "third", "one side", and "other side" are used herein to distinguish one element from another, But is not limited by the terms.

In this specification, the terms "forming on the top, forming on the upper side ", and" forming on the lower side "and the like do not mean only that the constituent elements are laminated in direct contact with each other, Quot; includes the meaning that another element is further formed between the elements. For example, "formed on the surface" means that, in addition to the meaning that the second component is formed directly on the first component, a third component is added between the first component and the second component And includes meaning that can be formed.

As used herein, the terms "connection", "installation", "coupling", and "fastening" mean not only that the two members are capable of being detached (combined and separated), but also include the meaning of an integral structure. Specifically, the terms 'connection', 'installation', 'coupling', and 'engagement' used in the present specification include, for example, a force fitting method (force fitting method); A fitting method using a groove and a projection; And a fastening method using screws, bolts, pieces, rivets, or the like, the two members are combined so as to be capable of being engaged and disengaged, as well as being welded or bonded with adhesives, cement or mortar, And the two members are combined through the through-hole. Also, in the case of the 'installation,' it also includes the meaning that two members are stacked (seated) without a separate coupling force.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings illustrate exemplary embodiments of the invention and are provided to aid in the understanding of the invention only. In the accompanying drawings, the thickness may be enlarged to clearly show each layer and the area, and the scope of the present invention is not limited by the thickness, size and ratio shown in the drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted.

The present invention provides a shock absorber that can be installed on the floor of a building to effectively absorb and consume impact applied in the upper layer. Further, the present invention provides a bottom construction structure including the buffer unit. Hereinafter, in explaining the present invention, the buffer unit will be described together with the explanation of the floor construction structure.

The bottom construction structure according to the present invention includes a bottom structure and a plurality of buffer units provided on the bottom structure.

In the present invention, the bottom structure is not particularly limited as long as it can support the buffer unit. The bottom structure may be any one capable of providing a surface on which a buffer unit can be arranged and installed. The floor structure may be, for example, a conventional concrete slab. In addition, the bottom structure may include a concrete panel as described below. Hereinafter, the present invention will be described by taking an embodiment in which the floor structure is realized by a concrete panel.

1 to 3 show a concrete panel for floor construction (hereinafter abbreviated as 'concrete panel') of a building according to a first embodiment of the present invention. 4 shows a concrete panel for floor construction of a building according to a second embodiment of the present invention.

The concrete panel 100 forms the floor (bottom structure) of the building. In the present invention, the size (length, width, thickness, etc.) of the concrete panel 100 is not limited. One or more of the concrete panels 100 may be fastened and assembled to form the floor of the building depending on the size (scale) of the building and / or the size of the concrete panel 100 itself. The concrete panel 100 may have a size to form a floor by two or more fastenings in consideration of the transportation and installation work according to one embodiment.

1 to 4, the concrete panel 100 has, for example, a rectangular parallelepiped shape and a plate shape. The concrete panel 100 includes a base plate 10, an isolation wall 20 protruding from the top of the base plate 10, a plurality of charging cells 30 formed by the isolation wall 20, .

The base plate 10 is, for example, in the shape of a rectangular parallelepiped. An isolation wall 20 is formed integrally with the base plate 10 so as to protrude therefrom. The isolation wall 20 has a lattice structure or a honeycomb structure (honeycomb structure). In the present invention, the lattice structure has a grid structure in which the isolation walls 20 are arranged in a rectangular shape with the longitudinal direction (lateral direction) and the lateral direction (longitudinal direction) And a waffle structure formed in a rhombic (or parallelogram) shape or the like. Further, in the present invention, the honeycomb structure (honeycomb structure) includes honeycomb shapes such as pentagonal, hexagonal, and octagonal shapes. In the drawing, the isolation wall 20 is formed in a lattice structure. More specifically, the isolation wall 20 includes a plurality of lateral walls 22 protruding in the longitudinal direction (lateral direction) of the base plate 10 as shown in the figure, And the vertical wall 24 and the vertical wall 24 may have a square-shaped lattice structure at right angles to each other.

The charging cell 30 has a groove shape formed on the base plate 10 as shown in the figure, and is formed by the isolation wall 20. The plurality of charging cells 30 is a space partitioned by the plurality of lateral walls 22 and the plurality of vertical walls 24 in detail. A filling material 150 (see Fig. 10) of a pore structure is embedded in the filling cell 30.

In the present invention, the packing 150 of the pore structure is not limited as long as it has a plurality of pores. The pore structure filler 150 may be selected, for example, from foamed concrete and / or synthetic foam foam. More specifically, the filling material 150 of the pore structure is formed by pouring the cured concrete material (sand and cement paste) to form bubbles by physical manipulation (for example, air injection) Or a synthetic resin foam foam formed by foaming a synthetic resin composition (a mixture of a synthetic resin and a foaming agent), and the like. The synthetic resin foam foam may be, for example, a polystyrene foam, a polyurethane foam, a polyethylene foam, or a polypropylene foam. By the packing 150 having such a pore structure, noise and vibration applied to the upper layer can be absorbed and shielded, and lightness can be imparted. The filling material 150 of the pore structure may be selected from glass wool, mineral wool, rock wool, fiber aggregate (cotton, etc.), and in some cases, synthetic resin foam chip, sand (sandpaper) And may be composed of at least one member selected from the group consisting of clay minerals, clay minerals, perlite rocks, foamed perlite rocks, vermiculite, foamed vermiculite, wood chips (sawdust etc.), rice husks and rice straw crushed products (finely crushed)

The number of the charging cells 30 is not limited. The charging cells 30 may be arranged in, for example, three to twenty columns in the lateral direction (longitudinal direction) and two to fifteen columns in the longitudinal direction (width direction). In the figure, the charging cells 30 are arranged in four rows in the horizontal direction (longitudinal direction) and eight columns in the vertical direction (width direction), and a total of 32 charging cells 30 are formed.

Further, according to an exemplary embodiment of the present invention, the concrete panel 100 may include a through hole 40. [ A plurality of through holes 40 may be formed in at least one direction selected from the horizontal direction (longitudinal direction) and the longitudinal direction (width direction) of the concrete panel 100. It is preferable that the through hole 40 is formed at least in the longitudinal direction (width direction) of the concrete panel 100. In the drawing, a through hole 40 is formed in the longitudinal direction (width direction) of the concrete panel 100, and is formed on the base plate 10. In constructing the floor, the through-hole 40 is usefully used when a plurality of concrete panels 100 are fastened. Specifically, a tensile line 181 (see FIG. 9) for fastening to the adjacent concrete panel is inserted into the through hole 40.

4 shows a concrete panel 100 according to a second embodiment of the present invention. Referring to FIG. 4, according to another exemplary embodiment of the present invention, the concrete panel 100 may include an insert 50. As shown in FIG. 4, one side of the insert 50 is embedded in the side surface of the concrete panel 100, and the other side is exposed to the outside. Further, according to another exemplary embodiment of the present invention, the concrete panel 100 may include an annular member 60. One side of the ring member (60) is embedded in the side surface of the concrete panel (100), and the other side is exposed to the outside.

The insert 50 is used to connect with the reinforcing bars F installed in the wall W of the building (see Fig. 9). With the insert 40, the concrete panel 100 can have a firm bonding force with the wall W of the building. At this time, one side of the insert 50 is embedded in the side surface of the concrete panel 100, and the other side is exposed to the outside. The ring member 60 is used for conveying or installing the concrete panel 100. Concretely, at the time of conveyance or installation of the concrete panel 100, it is possible to hold the ring member 60 or connect a conveying device such as a crane to the ring member 60. [ Therefore, the ring member 60 can facilitate the conveyance or installation work of the concrete panel 100.

Also, the concrete panel 100 includes a reinforcing core. The reinforcing core material may be one that can improve the strength of the concrete panel 100 and is embedded in the concrete panel 100. The reinforcing core material can be selected from, for example, a metal mesh, a metal porous plate, a reinforcing bar, a truss girder and / or a fiber sheet. The reinforcing core material can be embedded in the base plate 10 and / or the isolation wall 20 of the concrete panel 100.

Fig. 2 is a sectional view taken along the line A-A in Fig. 1, and Fig. 3 is a sectional view taken along the line B-B in Fig. According to an exemplary embodiment of the present invention, as shown in FIGS. 2 and 3, at least one selected from the metal mesh 70 and the metal porous plate as the reinforcing core material may be embedded in the base plate 10.

2 and 3, at least one selected from the reinforcing bars 80 and the truss girder 90 may be embedded in the interior of the isolation wall 20. [ More specifically, for example, a reinforcing bar 80 (FIG. 2) may be embedded in the vertical wall 24 of the isolation wall 20, and a truss girder 90 may be embedded in the interior of the horizontal wall 22. The truss girder 90 has a three-dimensional structure in which three or more main bars are connected, which is advantageous for strength reinforcement.

5A to 5E show various embodiments of the truss girder 90 that can be usefully used in the present invention as a reinforcing core. 5A to 5E, the truss girder 90 has a three-dimensional structure including at least three main bars 92 and a steel wire 94 connecting the main bars 92. As shown in FIG. The main bar 92 and the steel wire 94 may be used as steel pipes, reinforcing bars and wires. The steel wire 94 may have a smaller diameter than the main bar 92. And a variety of three-dimensional structures depending on the number and position of the main bars 92. [ 5A and 5B show a triangular truss girder 90 having three main bars 92 and FIG. 5C shows four main bars 92, in which the steel wire 94 is formed in an X- It shows the connected structure. FIG. 5D illustrates a truss girder 90 having a rectangular shape and FIG. 5E shows a trapezoidal cross-sectional view. The truss girder 90 having such a three-dimensional structure is effective to reinforce the support strength and the tensile strength of the concrete panel 100.

According to a preferred form, the truss girder 90 can be selected from a triangular structure as shown in Fig. 5A. 5A, the truss girder 90 includes a plurality of main bars 92 and a plurality of steel bars 94 connecting the plurality of main bars 92. The steel bars 94 are continuous And may have a structure in which a plurality of main bars 92 are connected while bent as a structure. The truss girder 90 having such a structure is very effective in reinforcing the support strength and the tensile strength of the concrete panel 100. 5A, a truss girder 90 including three main bars 92 and two steel wires 94 is illustrated.

The above-described concrete panel 100 can be simply constructed with a rigid structure at the bottom of a building. Specifically, the concrete panel 100 is robust in its structural aspects. That is, it includes a base plate 10, and has a rigid supporting force by a lattice structure or a honeycomb-shaped isolation wall 20 formed on the base plate 10. In addition, it is lightweight while providing soundproofness and dustproofness. That is, a plurality of charging cells 30 are formed between the isolation walls 20 to secure lightness, and a filling material 30 having a pore structure for absorbing and exhausting (noise) (150) can be embedded, thereby achieving soundproofing and dustproofing. The packing 150 is lightweight due to its low density due to its pore structure. Further, in the construction of the floor of the building, the bottom is constructed by fastening the concrete panel 100 through the tension line 181, without the work of installing the formwork and pouring concrete, Do.

Meanwhile, the concrete panel 100 may be manufactured by various methods, but it may be manufactured by the following method. 6 is a process diagram for explaining a method of manufacturing the concrete panel 100. As shown in FIG. And FIG. 7 illustrates a forming mold 120 for forming the charging cell 30. As shown in FIG.

6 and 7, the concrete panel 100 includes a first step of installing a reinforcing core material inside the mold 110; A second step of providing a forming mold 120 for forming the charging cell 30 on the reinforcing core material; And a third step of pouring and curing concrete inside the mold 110.

The first step of installing the reinforcing core material may include one or more reinforcing core materials selected from metal mesh, metal porous plates, reinforcing bars, truss girders and fiber sheets as described above. A metal mesh 70 may be installed in the mold 110 and a reinforcing bar 80 and a truss girder 90 may be provided on the metal mesh 70 according to a more specific embodiment. The reinforcing bars 80 are installed in the vertical direction so as to be embedded in the vertical walls 24 and the truss girders 90 are arranged in the horizontal direction 22 ). The reinforcing core material, that is, the metal mesh 70, the reinforcing bar 80 and the truss girder 90 can be connected to each other.

The manufacturing of the concrete panel 100 further includes a fourth step of installing a hollow pipe 140 inside the mold 110. The hollow tube 140 is for forming a through hole 40, which is removed after concrete curing. The hollow tube 140 is not particularly limited as long as it is hollow, and can be selected from, for example, a metal tube or a synthetic resin tube. The fourth step of installing the hollow tube 140 may be performed between the first step and the second step, or between the second step and the third step.

The mold 110 includes a bottom plate 112 and four wall portions 113 formed on side surfaces of the bottom plate 112. At this time, it is preferable that at least one of the four wall portions 113 can be separated so that the concrete panel 100 can be easily removed. A through hole 114 through which the hollow tube 140 passes may be formed in the wall portion 113 of the mold 110. In addition, an insert hole (not shown) for inserting the insert 50 and the ring member 60 may be formed in the wall portion 113 of the mold 110.

The forming mold 120 is for forming the charging cell 30 and includes at least a cell forming mold 123 having a shape corresponding to the charging cell 30. [ At this time, the cell forming mold 123 has a shape corresponding to the charging cell 30 and may have various shapes. The cell forming mold 123 may have various shapes, for example, triangular, rectangular, pentagonal, hexagonal, and rhombic. By the provision of the cell forming mold 123, the charging cell 30 is formed and the isolation wall 20 having the lattice structure or honeycomb structure as described above is formed.

The forming mold 120 includes a plurality of cell forming molds 123 that correspond to the charging cells 30 according to one embodiment and form the charging cells 30; And a connection frame 125 connecting the plurality of cell forming frames 123. As shown in FIG. 7, fastening holes 125a for fastening fasteners such as bolts may be formed at both ends of the connection frame 125. As shown in FIG. Therefore, when the mold frame 120 is installed in the mold 110, both ends of the connection frame 125 are placed on the wall portion 113 of the mold 110, The mold 110 can be firmly fixed to the mold 110 by fastening the mold 110 to the fastener such as the mold 110.

Fig. 8 shows another embodiment of the mold 110. Fig. Referring to FIG. 8, the concrete panel 100 may include the steps of installing a forming mold 120 on a bottom plate 112 of a mold 110 according to another embodiment; Providing a reinforcing core material on the forming die 120; And pouring and curing the concrete in the mold 110. That is, the concrete panel 100 shown in FIG. 1 can be manufactured in an inverted form. At this time, the forming mold 120 includes a plurality of cell forming molds 123 having a shape corresponding to at least the charging cells 30. [ Specifically, a plurality of cell forming molds 123 are arranged as a forming mold 120 on the bottom plate 112 of the mold 110 at a predetermined interval, and then the installation of the reinforcing core material, the pouring and curing of the concrete can proceed have.

Hereinafter, a concrete embodiment of the floor construction according to the present invention will be described.

The floor construction structure according to the present invention may include one or more concrete panels 100 as described above. 9 and 10 illustrate a bottom construction structure according to the present invention. FIG. 9 illustrates a process of installing the concrete panel 100, and FIG. 10 illustrates a floor construction structure according to an exemplary embodiment of the present invention. As shown in FIG.

First, referring to FIG. 9, the wall W of a building can be built through a mold C as usual. Specifically, an inner mold C and an outer mold C are provided for the construction of the wall W. A plurality of reinforcing bars (F) are connected between the inner mold (C) and the outer mold (C). When the concrete is poured and cured between the inner and outer formwork (C), the wall (W) is applied. At this time, a concrete panel 100 for installing a floor is installed between the left side wall W and the right side wall W. For example, a plurality of two or more concrete panels 100 are installed so as to be horizontal. A horizontal support plate 191 and a support frame 192 may be installed to support the plurality of concrete panels 100 in a horizontal direction. 9, the horizontal holding plate 191 is installed at a lower portion of the concrete panel 100, and the supporting frame 192 is installed at a lower side of the horizontal holding plate 191, have.

The plurality of concrete panels 100 are fastened through a tension line 181. Specifically, as described above, the concrete panel 100 is provided with the through-hole 40. After the tension line 181 is inserted into the through-hole 40, tension is applied to the through- do. 9, one end of the tension line 181 is fixed to one side (left side of the drawing) of the left concrete panel 100 by a fixing member 182 such as a tension cone. When the other end of the tension line 181 is tensioned by using the tensioner 185 at one side (right side of the drawing) of the right concrete panel 100 and then fixed to the reinforcing bar F, The concrete panel 100 can be firmly fastened. At this time, the tensioner 185 is connected to a hydraulic unit, so that a strong tension may be applied. In the present invention, the tensile wire 181 is not limited as long as it has an appropriate strength, and for example, reinforcing steel may be used, or preferably a plurality of twisted steel wires may be used. The distal end of the tension line 181 can be firmly fastened to the reinforcing bar F welded to the inside of the wall body W by welding or the like.

After the plurality of concrete panels 100 are fastened through the tension lines 181 as described above, the insert 50 provided on the side of the concrete panel 100 is welded to the reinforcing bars F of the wall W Or it can be fastened with a separate fastener so as to have a stronger bonding force.

The above-described installation process of the concrete panel 100 is described by taking as an example the case of constructing two or more floors of a building. In the case of the bottom layer of the building (for example, a floor-contacting one layer), the installation structure of the horizontal holding plate 191 and the support frame 192 may be omitted.

Referring to FIG. 10, the bottom construction structure according to the present invention includes a concrete panel 100 installed as described above, and a thermally conductive metal plate 500 spaced on the concrete panel 100. At this time, the concrete panel 100 and the thermally conductive metal plate 500 are separated by the buffer unit 200 according to the present invention. Between the concrete panel 100 and the thermally conductive metal plate 500, a heat insulating material 300 and a heating pipe 400 are installed in this order from the bottom.

More specifically, the bottom construction structure according to the present invention includes a concrete panel 100, a plurality of cushioning units 200 provided on the concrete panel 100, a thermally conductive metal plate (not shown) provided on the cushioning unit 200, A heat insulating material 300 provided on the concrete panel 100 around the buffer unit 200 and a heating pipe 400 installed between the heat insulating material 300 and the heat conductive metal plate 500, .

At this time, the concrete panel 100 has a filling cell 30 formed therein. The filling cell 30 is filled with the filling material 150 having the pore structure as described above. According to another embodiment of the present invention, the filling material 150 of the pore structure is embedded in at least the filling cell 30, and between the insulating wall 20 and the heat insulating material 300, The filling material 150 may be formed as a layer.

The buffer unit 200 is installed between the concrete panel 100 and the thermally conductive metal plate 500 and separates them from each other to a predetermined space. Further, the buffer unit 200 has a buffering force together with a supporting force. The buffer unit 200 may be fixed on the isolation wall 20 of the concrete panel 100. Hereinafter, a shock absorbing unit 200 according to the present invention will be described with reference to FIGS. 11 to 15. FIG.

11 to 15 show an embodiment of the shock absorber unit 200 according to the present invention.

11, the shock absorber unit 200 includes a post 210 fixed on the concrete panel 100, a resilient buffer member 220 inserted into the post 210, And a support plate 230 provided on the buffer member 220.

The posts 210 have, for example, a rod shape. One side (lower side in the drawing) of the posts 210 can be fixed in a structure embedded in the isolation wall 20 of the concrete panel 100. The other side (upper side in the figure) of the post 210 is exposed to the outside, and the buffer member 220 is inserted and installed in the outside.

The buffer member 220 has elasticity, which is inserted into the post 210 to provide a buffering force. The buffer member 220 is not limited as long as it has elasticity. The buffer member 220 can be, for example, a coil spring (a normal spring structure), but is selected from a disc spring according to a preferred embodiment of the present invention. In the figure, a dish spring is shown as a preferred embodiment of the cushioning member (220).

The buffer member 220 is preferably formed of a dish spring in which a plurality of dish members 222 are stacked. The plate member 222 is an elastic metal member, and it may be made of a material such as carbon steel, stainless steel (SUS), aluminum alloy steel, and steel. At this time, a buffer hole 220a is formed at the center of the plate member 222, and the post 210 is inserted into the buffer hole 220a. Referring to FIG. 11, two dish members 222 are stacked in opposite directions to form one spring set, and one or more such spring sets may be stacked.

Fig. 11 illustrates a cushioning member 220 composed of three spring sets. Specifically, FIG. 11 shows a state in which six dish members 222 are used, and two dish members 222 stacked in opposite directions form one spring set. .

12 and Fig. 13 show one dish member 222. Fig. As shown in Figs. 12 and 13, the plate member 222 has a buffer hole 220a formed at the center thereof, and a plate 222a in the shape of a cap in the circumferential direction with respect to the buffer hole 220a, Is formed at a predetermined angle. Therefore, when receiving an external force such as an impact applied from the outside, the freshly shaped dish 222a spreads at a predetermined angle to buffer the external force, which also has a sense of stability. Two of these plate members 222 are stacked in a direction opposite to each other by a single spring set, and have an effective buffering force. That is, such a diaphragm spring implements a more stable buffering force than a coiled spring, which is also structurally robust and preferred for the floor construction of the present invention. Fig. 14 is an assembled cross-sectional view of the shock absorber unit 200. Fig. 14 shows a state in which two dish members 222 are stacked in the opposite direction as a buffer member 220, that is, a dish spring composed of one spring set.

The support plate 230 is installed on the cushioning member 220 to support the thermally conductive metal plate 500. At this time, the support plate 230 is formed with an insertion hole 230a through which the upper end 210a of the post 210 is inserted. 15 is a rear perspective view of the support plate 230. FIG.

As shown in FIG. 15, a guide part 232 may be provided on the back surface of the support plate 230. The guide part 232 may be formed integrally with the support plate 230 or may be installed as a separate member on the support plate 230 through welding or the like. The guide part 232 guides the upper end 210a of the post 210 so as not to be separated from the insertion hole 230a of the support plate 230. [ Therefore, the insertion hole 230a of the support plate 230 extends to the guide part 232, and the guide part 232 may have a cylindrical shape.

14, it is preferable that the upper end 210a of the post 210 is inserted into the insertion hole 230a of the support plate 230 so as to have a step difference d. Specifically, it is preferable that the upper end 210a of the post 210 is positioned at a predetermined distance d from the distal end 230a-1 of the insertion hole 230a. For example, when a strong impact is applied to the upper portion of the support plate 230, the upper end 210a of the post 210 is detached from the insertion hole 230a by the contraction of the cushioning member 220, And can be pressed onto the metal plate 500. The step (d) can prevent such a phenomenon. That is, when a strong impact is applied to the support plate 230, the step (d) forms an extra exit / exit path of the end 210a so that the upper end 210a of the post 210 and the thermally conductive metal plate 500 So that compression bonding can be prevented. The step (d) may be formed at a distance of, for example, 0.2 to 3 mm. The step (d) may be formed at a distance of 0.5 to 2 mm for another example. Specifically, when an impact is applied, the upper end 210a of the post 210 may flow in the range of 0.2 to 3 mm (or a range of 0.5 to 2 mm) inside the insertion hole 230a).

Referring to FIG. 14, a stopper 240 may be formed on the post 210. The stopper 240 protrudes at right angles from the post 210 as shown in Fig. 14, and is closely attached to the lower end of the buffer member 220. [ The stopper 240 supports the buffer member 220.

Meanwhile, in the present invention, the heat insulating material 300 is not particularly limited as long as it has a heat insulating property, and the material commonly used in the art can be used. Further, the heat insulating material 300 may have a sound insulation property as well as a sound insulation property. The heat insulating material 300 may be made of, for example, synthetic resin foam (polystyrene foam, polyurethane foam, polyethylene foam, polypropylene foam, etc.), isoprene (compressed synthetic resin foam, isoprene is compressed polyethylene foam, But are not limited to, gypsum board, glass wool, mineral wool, rock wool, and fiber aggregates (such as cotton).

Further, the thermally conductive metal plate 500 is not particularly limited as long as it is a metal plate having thermal conductivity. The thermally conductive metal plate 500 may be composed of a single metal selected from, for example, iron (Fe), copper (Cu), and aluminum (Al), or an alloy thereof. The thermally conductive metal plate 500 may be selected from an iron plate in consideration of price, or may be selected from an aluminum plate or an iron-aluminum alloy plate in consideration of thermal conductivity together with weight.

In addition, as described above, the heating pipe 400 is installed between the heat insulating material 300 and the thermally conductive metal plate 500 according to the present invention. At this time, the heating pipe 400 may be installed as close as possible to the lower surface of the thermally conductive metal plate 500. The heat generated from the heating pipe 400 rises and is conducted to the thermally conductive metal plate 500.

At this time, according to the present invention, an effective heating effect can be realized in comparison with the conventional one. That is, when the heating pipe is installed in the finished mortar as in the prior art, the finishing mortar has a low thermal conductivity due to a low thermal conductivity, so that the heating effect is low compared to the energy consumption. However, the thermal conductive metal plate 500 is provided according to the present invention, When the heating pipe 400 is provided on the lower side of the conductive metal plate 500, the thermal conductivity is effectively improved. More specifically, the metal plate 500, which has a higher thermal conductivity than the conventional finishing mortar, can effectively conduct and discharge heat, thereby achieving a high heating effect even with a low energy consumption amount. Further, a heat insulating material 300 is provided on the lower side of the heating pipe 400, so that the heat of the heating pipe 400 can be transferred only to the upper part by heat insulation.

Further, according to another embodiment of the present invention, the bottom construction structure according to the present invention may further include a cushioning pad 450. Specifically, as shown in FIG. 10, a buffer pad 450 may be provided at a contact interface between the buffer unit 200 and the thermally conductive metal plate 500. The buffer pad 450 is for buffering between the buffer unit 200 and the thermally conductive metal plate 500 and may be composed of, for example, a rubber material, a synthetic resin material, a fiber material, or the like.

16 and 17 show a bottom construction according to another embodiment of the present invention.

In the present invention, the floor structure may be an assembled assembly of a plurality of concrete panels 100 as described above, or may be selected from existing concrete slabs S as mentioned above. 16 shows a conventional concrete slab S as a floor structure. Such a concrete slab S can be constructed through the formwork.

At this time, the buffer unit 200 is fixed on the concrete slab S. According to an exemplary embodiment, the support portion Sa may be formed on the concrete slab S and the post 210 of the shock absorber 200 may be fixedly mounted on the support portion Sa. The support portion Sa may be formed on the concrete slab S at a predetermined interval in a straight line or a lattice structure, and may be made of, for example, a concrete material, an iron material, or a wood material.

17, a bottom construction structure according to the present invention includes a concrete slab S, a plurality of cushioning units 200 provided on the concrete slab S, A heat insulating material 300 provided on the concrete slab S around the buffer unit 200 and a heat insulating material 300 disposed on the heat insulating metal plate 500, And a heating pipe (400) installed between the heating pipe (400). At this time, as described above, the support portion Sa is formed on the upper portion of the concrete slab S, and the post 210 of the shock absorber 200 may be embedded and fixed to the support portion Sa. The buffer pads 450 may be provided at the contact interface between the support plate 230 of the buffer unit 200 and the thermally conductive metal plate 500.

In addition, the floor construction structure according to the present invention may further include other components in addition to the above-described components. For example, a finishing material may be provided on top of the thermally conductive metal plate 500. Such a finish can be selected from commonly used floor finishes. The finishing material may be selected from, for example, a printing decorative sheet, a mat, a tile, a natural stone (such as marble), an artificial marble (such as a marble-patterned synthetic resin sheet) and /

In addition, the floor construction structure according to the present invention may further include various functional layers in addition to the finishing material. For example, a soil layer, a deodorization layer, a sterilizing layer, a far-infrared radiation layer and / or a separate sound insulating material layer may be optionally formed.

The floor construction structure according to the present invention may be, for example, a multi-family house or a tenement-house type building; A building with many rental offices inside; And collective type of apartment, school, hospital, dormitory etc; The present invention can be applied to remodeling existing buildings as described above. In addition, the building includes a prefabricated building constructed by a precast method (PC method) applied to an apartment or the like.

As described above, according to the present invention, the noise and vibration are effectively absorbed and exhausted (dispersed) as described above, so that the interlayer soundproofing and dustproofing are excellent, and the floor of the building can be firmly and simply installed. Further, as described above, the improved heating structure is excellent in thermal conductivity, and energy consumption can be reduced.

Concretely, it is a multi-family house or a multi-family house-type villa-type building; A building with many rental offices inside; And collective type of apartment, school, hospital, dormitory etc; The present invention can be applied to remodeling existing buildings as described above. In addition, the building includes a prefabricated building constructed by a precast method (PC method) applied to an apartment or the like.

10: base plate 20: isolation wall
30: Charging cell 40: Through hole
50: insert 60: ring member
70: metal mesh 80: reinforcing bar
90: Truss girder 100: Concrete panel
110: Mold 120: Molding frame
200: buffer unit 210: post
220: buffer member 230: support plate
240: Stopper 300: Insulation
400: heating pipe 500: thermally conductive metal plate

Claims (8)

delete delete delete delete delete Bottom structure;
A buffer unit mounted on the bottom structure;
A thermally conductive metal plate mounted on the buffer unit;
A heat insulating material provided on the bottom structure around the buffer unit; And
And a heating pipe disposed between the heat insulating material and the thermally conductive metal plate,
The buffer unit includes:
A post fixed on the bottom structure;
A resilient buffer member inserted into the post; And
And a support plate provided on the buffer member.
The method according to claim 6,
Wherein a buffer pad is provided at a contact interface between the buffer unit and the thermally conductive metal plate.
The method according to claim 6,
Wherein the floor structure is a floor slab of a building or an assembly of a plurality of concrete panels fastened to each other.

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