KR101483001B1 - Curtain wall with high insulation for easy separation - Google Patents

Abstract

The present invention relates to a high-air tightness curtain wall that can be easily separated. The curtain wall includes a frame having a first insertion portion on one side; an inner insulation member installed in the first insulation portion and having a second insulation portion; an inner connecting member installed in the second insulation portion; an insulation member engaged to the inner connecting member at one side and having a hollow portion; an outer connecting member engaged to the other side of the insulation member; a finishing member engaged to the outer connecting member; and a glass panel interposed between the frame and the finishing member. The frame, the inner insulation member and the inner connecting member can be separated from each other.

Description

[0001] CURTAIN WALL WITH HIGH INSULATION FOR EASY SEPARATION [0002]

The present invention relates to a highly airtight insulating curtain wall which is easy to separate.

More particularly, the present invention relates to a method of manufacturing a double or triple insulating curtain wall which is composed of individual unit assemblies and which is easy to combine and separate, optionally constitutes a double or triple insulating curtain wall, To an air tight insulation curtain wall.

Also, the present invention relates to a highly airtight, heat-insulating curtain wall having a plurality of indoor and outdoor heat transfer media, which is excellent in airtightness and heat insulation.

In general, a curtain wall installed on the outer wall of a building is an outer wall serving as a partition that does not support a load. The curtain wall is composed of vertical and horizontal frames constituting a skeleton and a glass panel installed on the frame .

Such a curtain wall is required to have heat insulation, water tightness, dew condensation prevention, strength, durability, airtightness, sound insulation and wind resistance. In this case, the glass panel in the curtain wall is not a material excellent in heat insulation, It is necessary to take measures to strengthen the heat insulating performance of the frame in the month.

That is, in order to improve the heat insulating performance of the curtain wall, it is necessary to improve the heat insulating structure of the frame that blocks the inflow and outflow of heat and air into and out of the room.

Accordingly, various techniques have been developed to overcome the problem of lowering the heat insulation of the curtain wall.

One of the structures capable of improving the heat insulating property of the curtain wall is disclosed in the registered patent publication No. 10-1202214 filed by the present applicant, and a high-tightness insulating curtain wall is described.

1 is a cross-sectional view of a conventional high-tightness heat-insulating curtain wall, which is composed of a frame 10, a connecting member 20 which is longitudinally provided at one end of the frame 10 and protrudes outwardly, A hermetic thermal insulating member 40 made of synthetic resin and fitted to the connecting member 20; a closure member 50 coupled to the hermetic thermal insulating member 40; And a glass panel (60) installed between the closure member (50) and the closure member (50).

The high airtightness insulating curtain wall is constructed by multiplexing indoor and outdoor heat transfer mediums such as the frame 10, the connecting member 20, the heat insulating material 30, the hermetic thermal insulating member 40 and the closing member 50, The heat insulating property can be improved and the transfer of heat energy can be minimized by the hermetic heat insulating member 40 made of synthetic resin.

Further, when the frame 10 is installed so as to face the portion where the glass panel 60 can not be installed, that is, the floor, the wall and the ceiling of the building, the cap 70 is further installed between the frame 10 and the closing member 50 do.

However, in the conventional curtain wall, the frame 10 and the connecting member 20 are filled with the heat insulating material 30 made of synthetic resin. The frame 10 and the connecting member 20 are formed by extrusion molding It is difficult to form the projecting connecting member 20 extending outwardly of the frame 10 and the durability between the frame 10 and the connecting member 20 is weak. The hermetic heat insulating member 40 and the closing member 50 may be installed outside to form a closed curtain wall. However, since the frame 10 must be separately manufactured in order to form the exposed curtain wall, the cost is increased There is a problem.

Further, the heat insulating material 30 is formed by extrusion molding the frame 10 and the connecting member 20, and then filling the connecting member 20 through curing, thereby increasing the construction period and complicating construction. That is, it is a matter of course that the heat insulating property can be improved by a multi-layer structure, but the cost and the construction period are increased.

In addition, since it can be applied only to the double insulation structure, there is a problem in that the usability is low.

A triple adiabatic frame for a window has been described in another Korean Utility Model Registration No. 20-0471671, which is another structure capable of improving the heat insulating property of a curtain wall.

FIG. 2 is a cross-sectional view of a conventional three-piece heat insulating frame for a window, and is composed of an inner frame 20 including an inner fixing portion 22, a first outer frame 30 located at an outermost position of the frame, A second outer frame 40 connected to the outer frame 30, one end of which is provided with an outer fixing part and the other end of which is coupled with a screw, a second outer frame 40 positioned between the inner frame 20 and the second outer frame 40, A pair of heat insulating engagement portions 60 that are fitted and fixed between the inner stationary portion 22 and the central stationary portion and between the central stationary portion and the external stationary portion, And a heat insulating cover part (70) covering part of the outer frame (40) in a 'U' shape to block heat transfer between the first outer frame (30) and the second outer frame (40).

The triple heat insulating frame for windows includes an inner frame 20, a first outer frame 30, a second outer frame 40, a third outer frame 50, a pair of heat insulating joints 60, The portion 70 is configured to extend in the longitudinal direction, thereby minimizing the heat transfer between the room and the outside.

The pair of heat insulating joints 60 are formed by laminating liquid polyurethane between the second outer frame 40 and the third outer frame 50 and between the third outer frame 50 and the inner frame 20 The inner frame 20, the second outer frame 40, and the third outer frame 50 are not formed in a straight line and are hardened in a bent state during the filling and curing process. A case may arise.

In other words, since the inner frame 20, the second outer frame 40 and the third outer frame 50 are connected to each other by the pair of heat insulating couplings 60 in a state of being spaced apart from each other, The second outer frame 40 and the third outer frame 50 can be cured in a bent state from the inner frame 20 in the process of filling and curing.

As a result, it is a cause of nuisance construction, and the cost is increased, and there is also a risk of exposure to the risk of occurrence of a safety accident.

In addition, although the closed curtain wall can be formed by providing the heat insulating pipe 90 at the portion where the glass wall 8 is not installed, the heat insulating pipe 90 must be separately manufactured, which increases the cost.

Although it is positive that the heat insulating performance is improved by filling the heat insulating material with the frame on which the glass panel is installed, it is positive that the filling and curing process must be performed to form the heat insulating material, .

Also, since the frame and the heat insulating material are integrally formed by curing, separation between the frame and the heat insulating material is not easy and the utilization due to reuse is low. The double or triple insulating curtain wall There is a problem that can not be done.

That is, there is a problem that a double or triple insulation curtain wall can not be constructed depending on the surrounding environment such as the place where the curtain wall is installed and the climatic condition.

Patent Registration No. 10-1202214 (November 12, 2012) Registration Utility Model Bulletin No. 20-0471671 (Mar.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to solve the problems of the related art, and it is an object of the present invention to provide a multi- To provide an easily separable, highly airtight, insulating curtain wall which can constitute a closed or exposed curtain wall.

Another object of the present invention is to provide a highly airtight heat-insulating curtain wall having a plurality of indoor and outdoor heat transfer media, which are excellent in airtightness and heat insulation and easy to separate.

According to an aspect of the present invention, there is provided a high-tightness heat-insulating curtain wall having a frame, An inner heat insulating member provided on the first inserting portion and having a second inserting portion; An inner connecting member provided in the second insertion portion; A heat insulating member in which one side is fitted to the inner connecting member and which has a hollow portion therein; An outer connecting member to which the other side of the heat insulating member is fitted and joined; A closure member coupled to the outer connecting member; And a glass panel mounted between the frame and the closing member, wherein the frame, the inner heat insulating member and the inner connecting member are separable. , And to solve technical problems.

The present invention is made up of individual unit assemblies that are easy to assemble and separate, can optionally form double or triple insulating curtain walls, and can optionally also constitute a closed or exposed curtain wall, Effect.

In addition, the present invention can prevent the transmission of heat energy and improve the airtightness and the heat insulation by keeping the airtightness in the indoor and outdoor heat transfer vehicles. Therefore, it is possible to reduce the cost required for cooling and heating the building .

In addition, since the time for filling and curing the frame to form the heat insulating member in the frame can be minimized, the present invention can reduce the construction period and reduce the cost Effect.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a cross-sectional view of a conventional high airtight adiabatic curtain wall.
2 is a cross-sectional view of a conventional triple heat insulating frame for a window.
3 is a perspective view of a highly airtight insulating curtain wall that is easy to separate in accordance with one embodiment of the present invention.
4 is an exploded perspective view of a highly airtight adiabatic curtain wall that is easy to separate in accordance with one embodiment of the present invention.
5 is a cross-sectional view of a highly airtight insulating curtain wall that is easy to separate in accordance with one embodiment of the present invention.
6 is a cross-sectional view of a highly airtight adiabatic curtain wall easily separable according to another embodiment of the present invention.
7 is an exploded cross-sectional view of a highly airtight adiabatic curtain wall that is easy to separate in accordance with another embodiment of the present invention.
FIG. 8 is a cross-sectional view of a highly airtight adiabatic curtain wall that is easy to separate in accordance with another embodiment of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may properly define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents And variations are possible.

Before describing the present invention with reference to the accompanying drawings, it should be noted that the present invention is not described or specifically described with respect to a known configuration that can be easily added by a person skilled in the art, Let the sound be revealed.

In addition, another embodiment of the present invention to be described with reference to the drawings is a structure of a closed curtain wall, and another embodiment is a structure of an exposed curtain wall, and the present invention is not limited to the structure of a closed or exposed curtain wall The present invention is not limited to the form and contents.

The highly airtight insulating curtain wall according to the present invention, which is easily separable, is composed of individual unit assemblies which are easy to assemble and detach, and which can optionally constitute a double or triple insulating curtain wall, and optionally also a closed or exposed curtain wall Airtight insulating curtain wall which is easy to separate.

Also, the present invention relates to a highly airtight, heat-insulating curtain wall having a plurality of indoor and outdoor heat transfer media, which is excellent in airtightness and heat insulation.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a highly airtight insulating curtain wall according to the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a perspective view of a highly airtight adiabatic curtain wall which can be easily separated according to an embodiment of the present invention, FIG. 4 is an exploded perspective view of a highly airtight adiabatic curtain wall which can be easily separated according to an embodiment of the present invention, 5 is a cross-sectional view of a highly airtight adiabatic curtain wall that is easy to separate in accordance with one embodiment of the present invention.

The highly airtight insulating curtain wall according to an embodiment of the present invention includes a frame 100, an inner heat insulating member 200, an inner connecting member 300, a heat insulating member 400, an outer connecting member 500, A member 600 and a glass panel 10 as shown in FIG.

The frame 100 is formed by extrusion molding in the shape of a polygonal metal such as aluminum or the like and has a function of supporting the glass panel 10 to be described later and transmitting external force such as wind force to the glass panel 10 And comprises a vertical frame 101 vertically installed and a horizontal frame 102 installed parallel to the floor.

The vertical frame 101 is a frame vertically connected to the floor and ceiling or vertically installed and installed outside the building. The horizontal frame 102 may be installed parallel to the floor or ceiling of the building, ).

At this time, the vertical frame 101 and the horizontal frame 102 may be installed by omitting any one depending on the shape of the building or the construction environment of the curtain wall.

At one end of the frame 100, a first inserting portion 110 is formed to insert an inner insulating member 200 to be described later.

The inner heat insulating member 200 is inserted into the first insertion portion 110 formed at one end of the frame 100, and the material thereof is made of synthetic resin and can be manufactured by extrusion molding.

The inner side heat insulating member 200 has a cross section of a 'c' shape, and a flat cross section formed at one side thereof is inserted into the first inserting portion 110 and is seated, and the inner connecting member 300 The second inserting portion 210 is formed.

The inner connecting member 300 is formed by extrusion molding and performs a function of firmly coupling the frame 100 and the heat insulating member 400 by holding the heat insulating member 400 to be described later. A protruding jaw 320 and a support 330. [

The fitting portion 310 performs a function of fitting one end of a heat insulating member 400, which will be described later, into engagement, and has a cross section of 'E' shape, And has a shape protruding outwardly of the frame 100.

The protruding jaws 320 protrude from both sides of the fitting part 310 and protrude from both sides of the heat insulating member 400 when the heat insulating member 400 is inserted.

The support portion 330 is inserted into the second insertion portion 210 so that the inner connection member 300 is seated on the frame 100.

The inner side insulating member 200 is inserted into the first inserting portion 110 of the frame 100 and the inner connecting member 300 is inserted into the second inserting portion 210 of the inner side insulating member 200 To be inserted and mutually coupled.

At this time, the frame 100, the inner heat insulating member 200, and the inner connecting member 300 can be coupled by piece coupling.

That is, a fixing piece (not shown in the drawing) passing through the first insertion portion 110, the second insertion portion 210, and the support portion 330, or the like.

Accordingly, the frame 100, the inner heat insulating member 200, and the inner connecting member 300 are firmly coupled to each other by piece coupling, and are separated from each other by releasing the piece coupling.

Therefore, it is easy to replace and install the frame 100, the inner heat insulating member 200, and the inner connecting member 300.

One end of the heat insulating member 400 is fitted to the inner connecting member 300 and is made of synthetic resin. The cross-sectional shape of the heat insulating member 400 is 'H'. The heat insulating member 400 is manufactured by extrusion molding. And includes a locking part 420 and a protrusion 430.

The body portion 410 may be formed with a hollow portion 411 in which the interior of the body portion 410 is hollow so that an air layer is formed therein. And the heat insulating property is increased by the air filled in the hollow portion 411.

According to the design conditions, the hollow portion 411 can be filled with the heat insulating material 440.

Accordingly, the thermal energy transfer between the frame 100 and the heat insulating member 400 is minimized by the heat insulating material 440 filled in the hollow portion 411.

That is, the heat insulating material 440 is installed inside the hollow portion 411 formed in the heat insulating member 400 to prevent the transfer of heat energy, and the material thereof is made of synthetic resin.

The latching part 420 is formed on each side of the body part 410 and is coupled to the inner connecting member 300 and the outer connecting member 500 to be described later.

The engaging portion 420 is recessed inward from the outer side of the body portion 410 and includes a fitting portion 310 formed on the inner connecting member 300 and a fitting portion 510 formed on the outer connecting member 500 Respectively.

The protrusion 430 is formed in the hollow portion 411 formed inside the body portion 410 and protrudes to the inside of the body portion 410 to improve the bending strength and durability of the heat insulating member 400.

At this time, the protrusions 430 may be spaced apart from each other as shown in the accompanying drawings, but may be integrally formed.

The inner heat insulating member 200 and the heat insulating member 400 may be made of an acrylic resin, a methyl methacrylate resin, a polyethylene resin, a polyamide resin, a polystyrene resin, a polyurethane resin, a celluloid resin, or the like.

At this time, a typical synthetic resin may be a polyamide resin. The polyamide resin is classified into an aliphatic polyamide, an aromatic polyamide, and an aliphatic cyclic polyamide. Representative examples of aliphatic polyamides include nylon 6,6, which is produced by condensation polymerization of hexamethylenediamine having 6 carbon atoms and adipic acid having 6 carbon atoms. Aromatic polyamides have introduced an aromatic skeleton to further improve heat resistance and are known as aramid. The polyamide is excellent in heat resistance, mechanical properties, electrical characteristics, and chemical resistance, and is a synthetic resin capable of replacing metals such as polyacetal, and is suitable as a material for the inner heat insulating member 200 and the heat insulating member 400.

Accordingly, since the inner heat insulating member 200 and the heat insulating member 400 are formed by using a polyamide resin that minimizes thermal energy transfer and is excellent in durability and heat resistance, it is possible to prevent loss of indoor and outdoor heat energy of the building, The heat insulating property can be improved.

The outer connecting member 500 is formed by extrusion molding and performs a function of bending the heat insulating member 400 to firmly couple the heat insulating member 400 and a closing member 600 described later. A protruding jaw 520, and a support portion 530. As shown in Fig.

According to the design conditions, the outer connecting member 500 may be formed in the same shape as the inner connecting member 300.

The fitting portion 510 is coupled with the other end of the heat insulating member 400 and the supporting portion 530 performs a function of coupling the closing member 600 described later.

At this time, the support portion 530 may be configured to correspond to the inner surface of the closure member 600 coupled with the outer connection member 500.

Here, the joining process of the inner connecting member 300, the heat insulating member 400, and the outer connecting member 500 will be described.

The protrusions 320 protrude outwardly from the fitting members 310 and 510 formed on the inner connecting member 300 and the outer connecting member 500, And 520 are pushed from the outside to the inside so that a part of the protruding protrusions 320 and 520 is located at the depressed portion of the latching portion 420 so that the inner connecting member 300, the heat insulating member 400, 500 are firmly coupled.

The closing member 600 is coupled to the outside of the outer connecting member 500 and is exposed to the outside of the building, and may be made of synthetic resin, aluminum, or the like.

The inner side of the closing member 600 may have a shape corresponding to the outer surface of the outer connecting member 500 to be in contact.

According to the design conditions, the finishing member 600 is shown in a combined form as shown in the accompanying drawings, but it is needless to say that the finishing member 600 can be manufactured as an integral unit of a rectangular shape.

The glass panel 10 may be at least two glass plates 11, 12 spaced apart by a spacer 13 and sealed. That is, the spacing of the glass plates 11 and 12 is maintained by the spacer 13, and an air layer is formed between the glass plates 11 and 12, thereby improving the heat insulating property.

A spacer 13 and a back-up agent 14 are provided between the frame 100 and the glass panel 10 and between the closing member 600 and the glass panel 10 and a sealant 15).

According to this configuration, the high-tightness heat-insulating curtain wall according to the present invention can be easily separated from the frame 100, the inner heat insulating member 200, and the outer heat insulating member 700 by being engaged with each other by piece- Do.

In addition, indoor and outdoor heat conduction mediums can be configured in multiple ways to prevent heat energy transfer and to maintain airtightness to improve airtightness and heat insulation, thereby reducing the cost of cooling and heating the building.

Further, in order to fill the heat insulating material in the frame in the conventional curtain wall (see FIGS. 1 and 2), it is not necessary to extrude the connecting member or the heat insulating member to be filled with the heat insulating material so as to protrude outwardly of the frame. The frame 100 is extruded and the inner connecting member 300 and the inner heat insulating member 200 are coupled to each other to facilitate stacking of the frame 100 during transportation and storage, It is possible to easily manufacture a mold (mold) for molding, which is advantageous in minimizing the construction period and cost.

FIG. 6 is a cross-sectional view of a highly airtight adiabatic curtain wall easy to separate according to another embodiment of the present invention, and FIG. 7 is an exploded sectional view of a highly airtight adiabatic curtain wall easy to separate according to another embodiment of the present invention.

The highly airtight heat-insulating curtain wall according to another embodiment of the present invention includes a frame 100, an inner heat insulating member 200, an inner connecting member 300, a heat insulating member 400, an outer connecting member 500, An outer heat insulating member 700, a closure member 600, and a glass panel 10.

6, one side end of the outer connecting member 500, the outer insulating member 700, and the closing member 600, which are coupled to the outside of the insulating member 400, And is configured to correspond to the first insertion portion 110 formed at one end of the connecting member 300 and the frame 100. [

At this time, the outer connecting member 500, the outer heat insulating member 700, and the closure member 600 can be coupled by the piece coupling.

According to the design conditions, the outer heat insulating member 700 is made of a synthetic resin, and may be made of one material selected from acrylic resin, methyl methacrylic resin, polyethylene resin, polyamide resin, polystyrene resin, polyurethane resin and celluloid resin. have.

Accordingly, the inner heat insulating member 200, the heat insulating member 400, and the outer heat insulating member 700 are constructed so that the heat insulation is made of triple layers, thereby preventing the transmission of heat energy and maintaining the airtightness, Can be improved.

According to this configuration, there is an advantage in that, when the curtain wall is constructed, the outer heat insulating member 700 is additionally provided between the outer connecting member 500 and the closing member 600, thereby selectively configuring the double or triple insulating curtain wall .

FIG. 8 is a cross-sectional view of a highly airtight adiabatic curtain wall that is easy to separate in accordance with another embodiment of the present invention.

According to another embodiment of the present invention, a high-tightness heat-insulating curtain wall which can be easily separated according to another embodiment of the present invention means an exposed curtain wall. The frame 100, the inner heat insulating member 200, the cap member 800, 900, and a glass panel 10.

The cap member 800 functions to securely couple the frame 100 and the cap insulating member 900 to each other by sandwiching the cap insulating member 900 to be described later. The fitting protrusion 810 and the supporting portion 820 are formed, .

The fitting protrusion 810 protrudes outward from the frame 100 and is fitted with a cap insulating member 900 to be described later.

The support portion 820 is inserted into the second insertion portion 210 formed on the inner heat insulating member 200 so that the cap member 800 is seated on the frame 100.

At this time, the frame 100, the inner heat insulating member 200, and the cap thermal insulating member 900 can be coupled by the piece coupling. That is, the first insertion portion 110, the second insertion portion 210, and the support portion 820, thereby facilitating replacement and separation.

As shown in FIG. 7, the cap insulating member 900 has an inner surface corresponding to the outer surface of the fitting protrusion 810, and the outer surface of the cap insulating member 900 is provided with one end of the glass panel 10 A backup agent 14 is provided therebetween and sealed using a sealant 15 or the like.

According to the design conditions, the cap insulating member 900 is made of a synthetic resin and may be made of one material selected from acrylic resin, methyl methacrylic resin, polyethylene resin, polyamide resin, polystyrene resin, polyurethane resin and celluloid resin. have.

According to this configuration, it is not necessary to manufacture each of the frames 100 for constituting the closed curtain wall or the exposed curtain wall, since they are composed of individual unit assemblies and are easy to be combined and separated. That is, the exposed frame or the closed curtain wall can be selectively installed in the same frame 100, which is advantageous in terms of usability.

In addition, indoor and outdoor heat transfer media can be constructed in multiple ways to prevent the transmission of heat energy and to maintain airtightness, thereby improving airtightness and heat insulation, thereby reducing the cost of cooling and heating the building.

In addition, since the structure for joining the heat insulating member formed in the frame can minimize the time for filling and curing to form the heat insulating member in the frame, the construction period can be shortened and the cost can be reduced.

3 to 8 illustrate only the main points of the present invention. As various designs can be made within the technical scope of the present invention, the present invention is limited to the configurations of Figs. 3 to 8 It is self-evident.

10: glass panel 11, 12: glass plate
13: Spacer 14: Backup agent
15: sealant 100: frame
101: vertical frame 102: horizontal frame
110: first insertion portion 200: inner side heat insulating member
210: second insertion portion 300: inner connecting member
310, 510: fitting portion 320, 520: projecting jaw
330, 530, 820: Support part 400: Heat insulating member
410: Body part 411: Hollow part
420: fastening part 430:
440: Insulation material 500: Outer connection member
600: finishing member 700: outer heat insulating member
800: cap member 810: fitting projection
900: a cap insulating member

Claims (6)

A frame 100 having a first insertion portion 110 formed on one side thereof;
An inner heat insulating member 200 installed in the first inserting portion 110 and having a second inserting portion 210 formed therein;
An inner connecting member 300 installed at the second inserting portion 210;
A heat insulating member 400 having one side inserted into the inner connecting member 300 and having a hollow portion 411 formed therein;
An outer connecting member 500 to which the other end of the heat insulating member 400 is fitted;
A closure member 600 coupled to the outer connection member 500; And
And a glass panel 10 installed between the frame 100 and the closure member 600,
The frame 100, the inner heat insulating member 200, and the inner connecting member 300 are detachable,
The frame 100, the inner heat insulating member 200 and the inner connecting member 300 are coupled by piece coupling,
The inner connecting member 300
A fitting portion 310 to which one end of the heat insulating member 400 is fitted;
A protruding protrusion 320 protruding outward from the fitting portion 310; And
And a support part 330 inserted into the first insertion part 110,
An outer heat insulating member 700 is further coupled between the outer connecting member 500 and the closure member 600,
The inner heat insulating member 200, the heat insulating member 400 and the outer heat insulating member 700 are made of a synthetic resin such as acrylic resin, methyl methacrylate resin, polyethylene resin, polyamide resin, polystyrene resin, polyurethane resin and celluloid resin And a material selected from the group consisting of:
The heat insulating member (400)
A body 410 having a hollow portion 411 formed therein to form an air layer therein;
The inner connecting member 300 and the outer connecting member 500 are formed on both sides of the body portion 410 and are fitted into the outer connecting member 500 and are recessed inward from the outer side of the body portion 410, (420) inserted into the fitting part (310) formed on the outer connecting member (300) and the fitting part (510) formed on the outer connecting member (500), respectively. And
And a protrusion 430 formed on the hollow portion 411 formed in the body portion 410 and configured to protrude inward from the body portion 410 and configured to be spaced apart from each other,
Wherein the outer connecting member (500), the outer heat insulating member (700), and the closing member (600) are coupled by piece coupling.
delete delete The method according to claim 1,
Wherein the hollow portion (411) is filled with a heat insulating material (440).
delete delete

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