KR20160062785A - Insulation and bearing panel and its manufacturing and installation method - Google Patents

Abstract

The purpose of the present invention is to provide an insulating bearing panel and manufacturing and constructing methods thereof enabling the construction of a wall of a structure by simply assembling and installing precast panels in a construction site by manufacturing the precast panels for exterior finishing and insulating at the same time in a factory. The insulating bearing panel according to the present invention to achieve the purpose includes: an outer plate composed of a plate body with a predetermined thickness and width, reinforcing ribs protruding from a surface of the plate body at constant intervals, protruding units protruding from the outer plate to the outer side of the reinforcing ribs, and insulating materials fixated between the reinforcing ribs; and an inner plate composed of a plate body with a predetermined thickness and width, reinforcing ribs protruding from a surface of the plate body at constant intervals, insertion grooves formed between the reinforcing ribs at constant intervals, and insulating materials fixated between the reinforcing ribs. The protruding units of the outer plate are inserted and coupled to the insertion grooves of the inner plate. In addition, the method for manufacturing the insulating bearing panel to achieve the purpose includes: a step of manufacturing the outer plate; a step of manufacturing the inner plate; and a step of coupling the inner and outer plates by inserting the outer plates into the inner plate. In addition, the method for constructing the insulating bearing panel to achieve the purpose includes: a step of transporting the insulating bearing panel; a step of installing the insulating bearing panel to a beam or a column by a medium of a coupler; and a step of filling the portion of the beam or the column where the insulating bearing panel is installed with mortar and finishing a bearing wall using a shear key.

Description

TECHNICAL FIELD The present invention relates to a heat insulating strength panel, a method of manufacturing the same,

The present invention relates to a heat insulating strength panel, and a method of making and installing the same.

Typically, precast outer wall panels include shear panels, span-crate panels, half-section panels, and double-sided coated precast panels.

Here, the above-mentioned front section concrete panel is made of a concrete plate as a whole, and the attachment of the front section concrete panel is installed on the outer side of the beam and column of the structure, so that a separate attachment device is necessary. It is uncertain, it is impossible to act as a bearing wall, and insulation work must be carried out separately after installing the outer wall.

In other words, the insulation between columns and beams should be separately insulated to prevent heat loss and condensation which may occur in the junction of beam or column due to insufficient insulation between shear walls and shear panel.

Here, if there is a separate finishing on the outer wall of the structure, there is no problem to insulate the outer wall, but there is a disadvantage that the finishing method which is an advantage of the shear section concrete panel can not be used.

In addition, since the weight of the front section concrete panel is heavy, it is required to be divided and manufactured for each segment as compared with other panel construction methods.

In addition, the above-mentioned shear concrete panel is mainly used where heat insulation is not needed because heat-insulating operation is troublesome.

Meanwhile, the span-crate panel has the advantage of making the inside of the panel hollow to reduce the weight of the concrete panel and making the length of the panel longer by making the pretension method using the tension of the steel wire.

However, since the span-crate panel is also attached to the outside of the structure, a separate attachment device is required, the binding force of the span is uncertain, and it can not serve as a proof wall.

In order to prevent heat loss and condensation which may occur at the junction of the beams or columns due to the poor insulation of the span-cleat panel and the beams or columns, it is necessary to insulate the columns and beams separately.

Here, the span-crate panel can be adiabatically heat-sealed if it is separately provided with a finish on the outer wall.

As described above, since the span-crate panel is manufactured by preparing and installing a long plate as described above, the plate can not be used in the envelope finishing method because it is much more deflected than the other panels. In addition, It is mainly used.

On the other hand, the half-section panel is manufactured by precast-casting the outer half-wall of the wall, installing the half-section panel on the site, installing reinforcing bars and formwork inside the half- .

The characteristics of the above-mentioned half-section panel construction method are advantageous in that they can act as a structure because they are composited with the structural part when the secondary concrete is poured, and the exterior finishing material can be installed on the wall outer precast plate.

However, the half-section panel must be subjected to a separate heat-insulating operation after the wall is completed.

Particularly, in order to prevent heat loss and condensation which may occur in the junction of the beam or column due to the poor insulation of the half-sectional panel and the portion joined to the beam or column, the column and the beam must be separately insulated.

In addition, if there is a separate finish on the outer wall of the half-section panel, there is no problem if the outer wall is insulated. However, in this case, there is a disadvantage in that it is not possible to use the finish method which is an advantage of the half-

In addition, since the half-section panel is manufactured and transported to the site after the half-section is manufactured at the time of factory production, there is a problem that the strength of the panel is weak and it is liable to cause damage during transportation and installation.

On the other hand, the double-sided coating precast panel is manufactured by panelizing the inside and outside walls of the wall, installing the double-coated pre-cast panel on the spot, installing a reinforcing bar at the center of the double- .

This double-sided coating precast panel method is generally used when a post-synthesis structure is needed, but since the double-sided panel causes an unnecessary section to become larger, the wall becomes thicker.

Particularly, in order to prevent heat loss and condensation which may occur in the joining portion of the beam or column due to the poor heat insulation at the portion where the double-side coated precast panel is joined to the beam or column, the column and the beam must be separately insulated.

In addition, if there is a separate finishing on the outer wall, there is no problem if the outer wall is insulated. However, in this case, there is a disadvantage that the envelope finishing method which is advantageous of the two-side coated precast panel can not be used.

Particularly, when the double-side coated precast panel is manufactured in a factory, only the coated precast panel covering portion is manufactured and transported to the site, so that the strength of the panel is weak, and consequently, there is a problem that corrugation tends to occur during transportation and installation.

The various precast outer wall panels as described above all have areas where the heat insulation and the sheath finish are in conflict with each other.

In addition, the precast outer wall panels have a disadvantage in that one of the heat insulation and the sheath finishing must be disposed on-site according to the importance of field installation, and there is an economic loss to install a separate work platform or mobilize equipment.

Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method of manufacturing a precast panel by manufacturing a precast panel at the same time in a factory, Panel and method of making and constructing the same.

According to an aspect of the present invention, there is provided a heat insulating and strength panel including a plate having a predetermined width and thickness, a plurality of reinforcing ribs protruding from a surface of the plate, An outer plate made of a heat insulating material fixedly disposed between the reinforcing ribs;

A plurality of reinforcing ribs formed on the surface of the plate body at predetermined intervals so as to protrude from the reinforcing ribs; an insertion groove recessed and formed at a predetermined interval between the reinforcing ribs; And a protruding portion of the outer plate is inserted into the insertion groove of the inner plate.

According to another aspect of the present invention, there is provided a method of manufacturing an insulating thermal power panel, including: fabricating an outer plate; Fabricating an inner plate; And inserting the outer plate into the inner plate and coupling the outer plate to the inner plate.

According to another aspect of the present invention, there is provided a method for constructing a heat insulating strength panel, including: conveying a heat insulating strength panel; Installing the heat-insulating strength panel through beams or fasteners in columns; Filling the mortar with the beam or column and the heat insulating strength panel mounting portion, and finishing the mortar with a load bearing wall using a shear key.

As described above, the heat-insulating strength panel according to the present invention and its manufacturing method and construction method are manufactured at the same time in the factory at the time of manufacturing the pre-cast insulation heat resistance panel and the finish of the building, have.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an assembled cross-sectional view showing an adiabatic strength panel according to the present invention,
2 is an exploded sectional view showing an adiabatic strength panel according to the present invention,
3 is a cross-sectional view showing an outer plate of the heat insulating power panel according to the present invention,
4 is a plan view showing an outer plate of an insulating thermal power panel according to the present invention,
5A to 5D are process drawings showing the procedure for manufacturing the outer plate of the heat insulating power panel according to the present invention,
6 is a cross-sectional view showing an inner plate of a heat insulating power panel according to the present invention,
7 is a plan view showing an inner plate of the heat insulating power panel according to the present invention,
8A to 8D are process drawings showing the procedure of manufacturing the inner plate of the heat insulating power panel according to the present invention,
9A and 9B are views showing a state in which the heat insulating power panel according to the present invention is mounted,
10 is an exemplary view showing a state in which the heat insulating power panel according to the present invention is firstly fastened after being mounted,
FIGS. 11A and 11B are views showing an engaging shear key of a heat insulating strength panel according to the present invention;
12 is an exemplary view showing a state in which a heat insulating material is installed in a heat insulating power panel according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an assembled cross-sectional view showing an adiabatic strength panel according to the present invention, and FIG. 2 is an exploded sectional view showing an adiabatic strength panel according to the present invention.

As shown in these figures, the heat insulating power panel (P) according to the present invention comprises a bottom plate (109) having a predetermined width and thickness, a plurality of reinforcing ribs An outer plate 100 formed of a rib 120, a protrusion 130 protruding outward from the reinforcing rib 120, and a heat insulating material 140 fixedly disposed between the reinforcing ribs 120; A bottom plate 209 having a predetermined width and thickness; a plurality of reinforcing ribs 220 protruding from the bottom plate 209 with a predetermined gap therebetween; And an inner plate 200 composed of a heat insulating material 240 fixed between the insertion rib 230 and the reinforcing rib 220. The protrusion 130 of the outer plate 100 is connected to the inner plate 200 are inserted into the insertion groove 230 of the body 200.

3 and 4, the outer plate 100 includes a bottom plate 109 having a predetermined width and a predetermined thickness, and a plurality of protrusions formed at a predetermined interval on the surface of the bottom plate 109 A protrusion 130 protruding to the outside of the reinforcing rib 120 and a heat insulating material 140 fixedly disposed between the reinforcing ribs 120. [

A high thermal insulating material 150 is fixed to the exposed surface of the reinforcing rib 120 of the outer plate 100 and the reinforcing rib 120 and a plurality of shearing projections 132 are formed on the outer surface of the protruding portion 130 Respectively.

A finishing material 160 is fixed to the surface of the bottom plate 109 of the outer plate 100.

The bottom plate 109 of the outer plate 100 is provided with a wire or a bar 170 in the form of a lattice and a reinforcing rib 120 of the outer plate 100 is provided with a wire or a wire rod 172.

6 and 7, the inner plate 200 includes a bottom plate 209 having a predetermined width and a predetermined thickness, and a plurality of protrusions formed at a predetermined interval on the surface of the bottom plate 209 An inner plate 200 consisting of a reinforcing rib 220 and an inserting groove 230 formed between the reinforcing rib 220 and the heat insulating material 240 fixedly disposed between the reinforcing rib 220, The protrusion 130 of the outer plate 100 has a structure in which the insertion groove 230 of the inner plate 200 is installed.

The bottom plate 209 of the inner plate 200 is provided with a wire or a reinforcing bar 250 in a lattice shape and the reinforcing rib 220 is provided with a wire or a wire rope 252.

A plurality of shear grooves 232 are formed on the inner side of the insertion groove 230 of the inner plate 200. The shear grooves 260 are formed on the outer side of the bottom plate 209 of the inner plate 200, do.

The combination of the heat insulating material 140 of the outer plate 100 and the heat insulating material 240 of the inner plate 200 is formed in a hexagonal shape.

That is, the heat insulating power panel P according to the present invention is a structure in which the outer plate 100 and the inner plate 200 are combined with each other.

1 and 2, the heat insulating power panel P according to the present invention comprises an outer plate 100 and an inner plate 200, and the outer plate 100, the inner plate 200, And a finishing material 160 is provided on the surface of the outer plate 100. The heat insulating material 140 is disposed between the outer plate 100 and the outer plate 100,

In this case, the bottom plate 109 of the outer plate 100 and the bottom plate 209 of the inner plate 200 are provided with reinforcing bars 170 and 250 in the form of a lattice to increase the thickness of the bottom plates 109 and 209 Minimize it.

At this time, in order to reinforce the thickness of the thin bottom plates 109 and 209, the reinforcing ribs 120 and 220 are provided in a lattice shape to reinforce the bottom plates 109 and 209.

The bottom plate 109 of the outer plate 100 and the bottom plate 209 of the inner plate 200 are provided with sealing ribs 120 and 220 spaced from each other at a predetermined interval.

The heat insulating material 140 and 240 are disposed in a wide space in the central space of the reinforcing ribs 120 and 220 that are sewn and installed and the high thermal insulating material 150 is disposed at a position where the mutually reinforcing ribs 120 and 220 are in contact with each other. To meet the heat conduction regulations.

12, in order to ensure a heat insulating effect, a portion of the high thermal insulating material 150 at the corner of the heat insulating material 140 is covered with a heat insulating material 150 having a high thermal conductivity, So as to satisfy the heat conduction regulations.

The bottom plates 109 and 209 are thinned to reduce the weight of the heat insulating power panel P according to the present invention and the reinforcing ribs 120 and 220 are installed to reinforce the bottom plates 109 and 209, The weight of the member, which is an important factor, was reduced.

The heat insulating materials 140 and 240 to be installed at this time will be described in detail in a method of manufacturing a heat insulating strength panel to be described later.

9A and 9B, a portion of the outer plate 100 and the inner plate 200, which are in contact with the beam or the column S, is formed by widening the outer plate 100, So that there is a step.

A portion of the reinforcing rib 120 is provided with a high thermal insulating material 150 inside the outer plate 100 having the stepped portion and a heat insulating material 140 is installed inside the bottom plate 109 of the outer plate 100 So that the beam or the column (S) is adiabatically heated during the field installation of the heat insulating strength panel (P).

As shown in FIGS. 1 and 2, the outer plate 100 and the inner plate 200 are connected to each other by providing a protrusion 132 on the protrusion 130 of the outer plate 100, The protrusions 130 of the outer plate 100 are coupled to the inner plate 200 when the outer plate 100 is coupled to the inner plate 200. [ And the gap between the protrusion 130 and the insertion groove 230 is filled with grout material so as to fill the gap between the front end protrusion 132 and the front end groove 232 to be mechanically engaged And is bound to the insertion groove 230 of the inner side plate 200 by the shearing force of the protrusion 130 of the outer side plate 100. [

A method of attaching a heat insulating material separately to the portions where the heat insulating and heat resistant panels P are brought into contact with each other, or a method of attaching a foam insulating material at the time of installation.

As shown in FIG. 10, a fastener F is installed in the heat insulating strength panel P so as to be able to be primarily fastened to the beam or column S, and when the heat insulating strength panel P is installed in the field, The fastening tool F is fastened to the column S with bolts or the like.

The inner side plate 200 is stably sandwiched between the beams or pillars S so that the entire heat insulating and strength panel P is stably installed and the outer side plate 100 is covered with the inner side plate 200 ) And the outer plate (100) meet at a position where the beam or the column (S) meets.

At this time, the connecting portion between the heat insulating and strength panel P and the beam or column S or between the heat insulating and strength panel P and the heat insulating strength panel P forms the shear key groove 260 in which the shear key 280 can be installed, The shear key groove 260 can be formed by installing the heat insulating power panel P according to the present invention. When the shear key groove 260 is grouted with the mortar, the shear key 280 is installed, (S).

Hereinafter, the manufacturing of the heat insulating resistant panel according to the present invention having the above-described structure will be described.

FIGS. 5A to 5D are process charts showing the procedure for manufacturing the outer plate of the heat insulating power panel according to the present invention, and FIGS. 8A to 8D are process drawings showing the procedure for manufacturing the inner plate of the heat insulating power panel according to the present invention.

As shown in these drawings, the method for manufacturing an insulating thermal power panel according to the present invention includes the steps of: installing a bottom plate 109; Installing a high thermal insulator (150) at a predetermined position of the bottom plate (109); Installing a heat insulating material (140) between the high thermal insulating materials (150); Providing a protrusion (130) at a predetermined lower position of the bottom plate (109); Placing a grid-like reinforcing bar (170) or a wire at a predetermined position on the bottom plate (109); Disposing the iron wire (172) or the iron wire between the heat insulating material (140) on the bottom plate (109); Installing side molds (180) on both sides of the bottom plate (109); Placing and curing concrete on the bottom plate 109; Removing the side molds (180); preparing an outer plate (100) comprising the step of removing the side molds (180);

Installing the bottom plate (209); Installing a heat insulating material (240) at a predetermined position of the bottom plate (209); Installing an inserting groove (230) on the outer side of the heat insulating material (240); Placing a grid-like reinforcing bar (250) or a wire at a predetermined position on the bottom plate (209); Placing a thunderstall 252 or a wire at a predetermined position on the bottom plate 209; Installing side molds (270) with ridges (272) on opposite sides of the bottom plate (209); Placing and curing concrete on the bottom plate 209; Removing the side mold (270); fabricating an inner plate (200) having a step of removing the side mold (270); And inserting and joining the outer plate 100 into the inner plate 200.

Further, a step of installing a finishing material 160 on the surface of the outer plate 100 is added.

That is, the method for manufacturing a heat insulating resistant panel according to the present invention includes the steps of: fabricating the outer plate 100; Fabricating the inner plate (200); And inserting and joining the outer plate 100 into the inner plate 200.

5A to 5D, a bottom plate 109 is provided and a high thermal insulation material 150 is first placed on the bottom plate 109 at a position corresponding to the reinforcing rib 120 And the heat insulating material 140 is installed on the side surface of the reinforcing rib 120 so as to overlap with the high thermal insulating material 150.

As shown in FIG. 12, the overlapping length of the heat insulating material 140 and the high thermal insulating material 150 is the same as the thickness of the heat insulating material 140 corresponding to a wide width, So that the corners of the high thermal insulating material 150 come into contact with the dividing line.

5 (b), when the same heat insulating material 140 is used for the bottom plate 109 and the reinforcing rib 120 to satisfy the heat insulation requirement according to the average heat flow rate area weighting method, the reinforcing rib 120 The heat insulating material 150 installed on the bottom plate 109 may be installed on the entire bottom plate 109 and the heat insulating material 140 having a wide width may be provided on the upper part.

At this time, the high thermal insulating material 150 and the heat insulating material 140 simultaneously perform the role of the form of the bottom plate 109, and the economical efficiency is improved.

After the heat insulating material 140 and the high thermal insulating material 150 are installed on the bottom plate 109 as described above, the protruding portion 130 having the shear protrusions 132 formed on the outside is installed as shown in 5c A grid wire reinforcing bar 170 or a wire is disposed on the bottom plate 109 and a reinforcing rib 120 is provided with a wire rod 172 or a wire.

At the same time, after the side mold 180 is installed on the side surface of the bottom plate 109, the concrete is placed and cured in the bottom plate 109, and then the side molds 180 are removed, The protrusions 130 of the plurality of outer plates 100 necessary for coupling the plate 200 are formed and the outer plate 100 provided with the heat insulating material 140 and the high thermal insulating material 150 is manufactured.

In order to put a special pattern on the surface of the outer side plate 100, the outer side plate 100 is firstly fabricated on the bottom of the bottom plate and the reinforcement 170 or wire The reinforcing rib 120 or the iron wire is installed and the primary concrete is poured and cured in the bottom plate 109. Then the heat insulating material 140 is installed on the bottom plate 109, The outer plate 100 may be manufactured in the order of completing the reinforcing rib 120 by placing and curing the secondary concrete in the reinforcing ribs 140 and installing the high thermal insulating material 150 on the reinforcing ribs 120.

It should be noted that the method of manufacturing the outer side plate 100 is inconvenient except for a special case because it is troublesome to place and cure the concrete in two divided cycles.

Accordingly, the outer plate 100 is completed as shown in FIGS.

8A to 8D, the inner plate 200 is manufactured by providing a bottom plate 209 and a heat insulating material 240 on the bottom plate 209.

At this time, the heat insulating material 240 simultaneously acts as a mold for the bottom plate 209, thereby improving the economical efficiency.

8C, a plurality of insertion grooves 230 may be formed in the bottom plate 209 so that the front end groove 232 may be formed in the bottom plate 209, A reinforcing rib 250 or a wire is inserted into the reinforcing rib 209 and a reinforcing rib 220 or a reinforcing rib 252 is inserted into the reinforcing rib 220.

At the same time, a side mold 270 having a boom 272 is installed to form a shear key groove 260 in which the beam or column S and the shear key 280 can be installed, The shear grooves 260 for forming the shear keys 280 are formed and the plurality of insertion grooves 260 necessary for joining the inner plate 200 and the outer plate 100 are formed 230 are formed, and the inner plate 200 provided with the heat insulating material 240 is manufactured.

At this time, the reinforcing ribs 220 of the manufactured inner plate 200 are arranged in various ways in a lattice form so that the bottom plate 209 is structurally safe.

Thus, the inner plate 200 is completed as shown in Figs.

As shown in FIG. 2, the step of inserting and connecting the outer plate 100 into the inner plate 200 is performed as follows. First, the manufactured inner plate 200 is inserted into the insertion groove of the inner plate 200 The protrusion 130 of the outer plate 100 is inserted into the grooves 230 of the inner plate 200 and the grooves 230 of the inner plate 200 are filled with an appropriate amount of grout material, The protrusion 130 of the plate 100 is inserted to join the outer plate 100 and the inner plate 200 together.

The length of the protrusion 130 of the outer plate 100 and the depth of the insertion groove 230 of the inner plate 200 are made to coincide with each other so that the sectional shape of the high temperature insulating material 150 is maintained, And the reinforcing ribs 220 of the inner plate 200 are formed to be in contact with each other.

When the grout material filled in the insertion groove 230 of the inner plate 200 is cured after the outer plate 100 and the inner plate 200 are coupled to each other, the protrusions 130 of the outer plate 100 and the inner plate And the shearing protrusions 132 and the shearing grooves 232 provided in the insertion grooves 230 of the first and second housing parts 200, 200 are completely engaged with each other.

The protruding portion 130 on the end surface of the outer plate 100 coupled with the insertion groove 230 of the inner plate 200 has a protruding portion 130 on the heat insulating proof panel P So that the inner plate 200 is sandwiched by the beam or column S and the outer plate 100 is installed so as to cover the outer surface so that shear resistance capable of withstanding the weight of the outer plate 100 do.

The heat insulating strength panel P thus combined is completed by covering the surface of the outer side plate 100 with a finishing material 160 such as tiles.

Hereinafter, the construction of the heat insulating strength panel according to the present invention having the above-described construction and manufacturing will be described.

9A and 9B are views showing a state in which the heat insulating strength panel according to the present invention is mounted, FIG. 10 is an exemplary view showing a state in which the heat insulating strength panel according to the present invention is first fastened after being mounted, 11a and 11b are views showing binding tacking keys 280 of the heat insulating power panel according to the present invention, and Fig. 12 is an exemplary view showing the heat insulating panel of the heat insulating power panel according to the present invention.

As shown in these drawings, the method for constructing an insulating strength panel according to the present invention comprises the steps of: carrying an insulation strength panel (P); Installing the heat insulating strength panel (P) on a beam or column (S) through a primary fastening (F); And filling the mortar M with the beam or column S and the heat insulating strength panel P mounting portion.

The heat insulating power panel P includes a bottom plate 109 having a predetermined width and thickness, a plurality of reinforcing ribs 120 protruding from the bottom surface of the bottom plate 109 at regular intervals, An outer plate 100 composed of a protrusion 130 protruding to the outside of the rib 120 and a high thermal insulator 150 fixedly disposed between the reinforcing ribs 120; A bottom plate 209 having a predetermined width and thickness; a plurality of reinforcing ribs 220 protruding from the inner surface of the bottom plate 209 at regular intervals; And an inner plate 200 composed of a heat insulating material 240 fixedly disposed between the reinforcing ribs 220. The protrusions 130 of the outer plate 100 are located on the inner side And inserted into the insertion groove 230 of the plate 200.

A high thermal insulating material 150 is fixed to the surface of the reinforcing rib 120 of the outer plate 100.

A plurality of shear projections 132 protrude from the outer surface of the protrusion 130.

A finishing material 160 is fixed to the surface of the bottom plate 109 of the outer plate 100.

The bottom plate 109 of the outer plate 100 is provided with a reinforcing bar 170 or a wire in a lattice shape.

A reinforcing rib 120 of the outer plate 100 is provided with a thunderstall 172 or a wire.

The bottom plate 209 of the inner plate 200 is provided with a reinforcing bar 250 or a wire in a lattice shape.

The reinforcing rib 220 of the inner plate 200 is provided with a thunderstall 252 or a wire.

A shear key groove 260 is formed on the outer side of the bottom plate 209 of the inner plate 200.

A plurality of front end recesses (232) are formed on the inner side of the insertion groove (230) of the inner plate (200).

The combination of the heat insulating material 140 of the outer plate 100 and the heat insulating material 240 of the inner plate 200 is formed in a hexagonal shape.

That is, the method of constructing a heat insulating strength panel according to the present invention is mounted in various forms, as shown in FIGS. 9a and 9b, on a completed beam or column S on site when the heat insulating strength panel P is transported to the site.

The heat-insulating strength panel P is divided and manufactured so as to facilitate transportation and the like, and the heat-insulating and strength panel P is installed at a required position divided in the field.

At this time, the heat insulating force panel P is installed on the inner side plate 200 as a structural member by sandwiching the side plate 200 with the beam or column S, and the outer side plate 100 is covered with the outer side.

The heat insulating strength panel P is placed in contact with the beam or column S such that the shear key groove 260 formed at the time of manufacturing the inner plate 200 and the shear key groove 260 formed at the beam or column S face each other So that the shear key 280 can be installed.

First, the heat insulating proof panel P is mounted at a required position and the first fixing boss F is attached to the post S or the first fixing boss F as shown in Fig. 10, Thereby securing safety according to the installation of the heat insulating strength panel (P).

When the wall is completed, the connection between the heat insulating strength panel P and the beam or column S and the connection of the heat insulating strength panel P and the heat insulating strength panel P are shown in FIGS. 11A and 11B The backing material 290 is connected to the heat insulating strength panel P and the beam or column S or to the shear key groove 260 where the heat insulating strength panel P and the heat insulating strength panel P are connected. And the mortar grout material is filled to complete the shear key 280, the shear resistance of the shear key 280 makes the beam or column S and the heat insulating strength panel P an integral structure.

As shown in FIG. 11B, the contact portion where the heat insulating and strength panel P and the heat insulating and strength panel P are in contact is provided with a separate heat insulating material at the contact portion.

And the outer side is processed by caulking (300) so as to adapt to the waterproofing and heat insulating strength panel (P) stretching.

The connecting portion of the outer plate 100 which is in contact with the beam or the column S may be treated in the same manner.

100: outer plate 109: bottom plate
120: reinforcing rib 130:
132: Shear protrusion 140: Insulation
150: high thermal insulation material 160: finishing material
170: Rebar 172:
180: side mold 200: inner plate
209: bottom plate 220: reinforcing rib
230: insertion groove 232: shear groove
240: Insulation material 250: Reinforcing material
252: Steam iron 260: Shear key groove
270: side mold 272: raised
280: Flyer 290: Backup agent
300: caulking F: primary fastening
P: Insulating strength panel S: Beam or column

Claims (27)

A reinforcing rib 120 protruding and extending outward from the reinforcing rib 120 and having a plurality of protrusions formed at a predetermined interval on the surface of the bottom plate 109; (130), and a heat insulating material (140) fixedly disposed between the reinforcing ribs (120);
A bottom plate 209 having a predetermined width and thickness; a plurality of reinforcing ribs 220 protruding from the bottom plate 209 with a predetermined gap therebetween; And an inner plate 200 composed of a heat insulating material 240 fixedly disposed between the reinforcing ribs 220,
Wherein protrusions (130) of the outer plate (100) are inserted into the insertion grooves (230) of the inner plate (200). The method according to claim 1,
Wherein a high thermal insulating material (150) is fixedly installed between the reinforcing rib (120) of the outer plate (100) and the protruding portion (130). The method according to claim 1,
And a plurality of shear projections (132) protruding from the outer surface of the protrusion (130). The method according to claim 1,
Wherein a finishing material (160) is fixed to the surface of a bottom plate (109) of the outer plate (100). The method according to claim 1,
Wherein the bottom plate (109) of the outer plate (100) is provided with a wire or a reinforcing bar (170) in a lattice shape. The method according to claim 1,
Wherein an iron wire (172) or a wire is installed on the bottom plate (109) of the outer plate (100). The method according to claim 1,
Wherein the bottom plate (209) of the inner plate (200) is provided with a wire or a reinforcing bar (250) in a lattice shape. The method according to claim 1,
Wherein the bottom plate (209) of the inner plate (200) is provided with a thunderstall (252) or a wire. The method according to claim 1,
And a shear key groove (260) is formed outside the bottom plate (209) of the inner plate (200). The method according to claim 1,
Wherein a plurality of front end recesses (232) are formed on the inner side of the insertion recess (230) of the inner side plate (200). The method according to claim 1,
Wherein a combined shape of the heat insulating material (140) of the outer side plate (100) and the heat insulating material (240) of the inner side plate (200) is formed in a hexagonal shape. Fabricating the outer plate (100);
Fabricating the inner plate (200);
And inserting the outer plate (100) into the inner plate (200) and joining the inner plate (200). 13. The method of claim 12,
The outer plate 100 is manufactured by the steps of: installing a bottom plate 109; Installing a high thermal insulator (150) at a predetermined position of the bottom plate (109); Installing a heat insulating material (140) between the high thermal insulating materials (150); Providing a protrusion (130) at a predetermined lower position of the bottom plate (109); Placing a grid-like reinforcing bar (170) at a predetermined position on the bottom plate (109); Disposing a coils (172) between the heat insulating material (140) on the bottom plate (109); Installing side molds (180) on both sides of the bottom plate (109); Placing and curing concrete on the bottom plate 109; And removing the side molds (180). 14. The method of claim 13,
Wherein a step of installing a finishing material (160) on the surface of the outer plate (100) is added. 13. The method of claim 12,
The inner plate 200 is manufactured by the steps of: installing a bottom plate 209; Installing a heat insulating material (240) at a predetermined position of the bottom plate (209); Installing an inserting groove (230) on the outer side of the heat insulating material (240); Placing a grid-like reinforcing bar (250) at a predetermined position on the bottom plate (209); Disposing a thimble 252 at a predetermined position on the bottom plate 209; Installing side molds (270) with ridges (272) on opposite sides of the bottom plate (209); Placing and curing concrete on the bottom plate 209; And demolding the side molds (270). Conveying the heat insulating strength panel (P);
Installing the heat insulating strength panel (P) on a beam or column (S) through a primary fastening (F);
Filling the mortar (M) with a portion where the beam or column (S) and the heat-insulating strength panel (P) are installed, and finishing the mortar (M) using a shear force. 17. The method of claim 16,
The heat insulating power panel P comprises a bottom plate 109 having a predetermined width and thickness, a plurality of reinforcing ribs 120 protruding from the bottom plate 109 at regular intervals, And a heat insulating material 140 fixedly disposed between the reinforcing ribs 120. The outer plate 100 may be made of a synthetic resin, A bottom plate 209 having a predetermined width and thickness; a plurality of reinforcing ribs 220 protruding from the bottom plate 209 with a predetermined gap therebetween; And an inner plate 200 composed of a heat insulating material 240 fixed between the insertion rib 230 and the reinforcing rib 220. The protrusion 130 of the outer plate 100 is connected to the inner plate 200). ≪ / RTI > 18. The method of claim 17,
Wherein a high thermal insulating material (150) is fixedly installed between the reinforcing rib (120) of the outer plate (100) and the protruding portion (130). 18. The method of claim 17,
Wherein a plurality of shear projections (132) are protruded from the outer surface of the protrusion (130). 18. The method of claim 17,
Wherein a finishing material (160) is fixed on a surface of a bottom plate (109) of the outer plate (100). 18. The method of claim 17,
Wherein the bottom plate (109) of the outer plate (100) is provided with a wire or a reinforcing bar (170) in a lattice shape. 18. The method of claim 17,
Wherein the bottom plate (109) of the outer plate (100) is provided with a thunderstall (172) or a wire. 18. The method of claim 17,
Wherein the bottom plate (209) of the inner plate (200) is provided with a grid of wire or steel bars (250). 18. The method of claim 17,
Wherein the bottom plate (209) of the inner plate (200) is provided with a thunderbolt (252) or a wire. 18. The method of claim 17,
And a shear key groove (260) is formed on the outer side of the bottom plate (209) of the inner plate (200). 18. The method of claim 17,
Wherein a plurality of shear grooves (232) are formed on the inner side of the insertion groove (230) of the inner plate (200). 18. The method of claim 17,
Wherein a combined shape of the heat insulating material (140) of the outer side plate (100) and the heat insulating material (240) of the inner side plate (200) is formed in a hexagonal shape.

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