KR101376566B1 - Apparatus for Suporting Glasses - Google Patents

Abstract

The present invention relates to a glass support device. An aspect of an embodiment of the present invention is a glass support apparatus for supporting a glass module including an outer glass and an inner glass, comprising: forming a cold rolled galvanized iron sheet by high-speed bending forming, and then cutting to a predetermined length, A curtain wall formed at a predetermined shape and both ends thereof are joined by welding, and an installation space is formed in which a joint part of both ends is formed; A supporter installed in the installation space to support the glass module and be molded of aluminum; An ionization preventing member positioned between the curtain wall and the supporter and preventing the supporter from being ionized with respect to the curtain wall; A fastener fastened to the curtain wall through the supporter and the ionization preventing member to fix the supporter to the curtain wall; An adhesive member attaching the glass module to the supporter; And a sealing member for shielding a gap between the supporter and the glass module. .

Description

Glass support device {Apparatus for Suporting Glasses}

The present invention relates to a glass support device.

Glass is widely used as an exterior finishing material of modern buildings. As a frame that structurally combines glass, conventional exterior walls use thick steel plates as curtain walls and use steel plates as exterior wall structures that can withstand wind pressure and seismic forces caused by external typhoons. It was.

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1 is a cross-sectional view showing a curtain wall according to the prior art.
Referring to Figure 1, the prior art Korean Patent Application No. 10-2008-0085947 is composed by welding the shape member 10 woven together in a T-shaped thick iron plate, and extruded aluminum in a method for fixing the glass module 900 The mold member 30 was configured by pushing the mold member 30 to the fixing bolt head 31 constituting the T-shaped member 10 sideways.

This shape configuration is made of a tab 11 to the thick steel plate in the process of forming the T-shaped member 10 as the main member of the iron plate, and then directly attached to the screw 20 is attached to the different iron plate was configured in the T shape.

In the prior art, oxidized rust of the steel joint connection part 12, which is the main material, was coated with a powder coating of 60 to 80 microns so that the external steel was not in contact with moisture, rain, and oxygen, but the rust prevention treatment of the steel was used as a finish coating. There is a problem that oxidative rust of the part may penetrate the painted surface and expose rust to the outside.

In addition, the structure in which the T-shaped steel plate 10 and the aluminum extruded shape member 30 are in direct contact with each other is due to the ionization tendency of the aluminum shape material 30 as the iron ionization energy is 7.9ev compared to the aluminum ionization energy of 5.98ev. There is a problem that 30) is a structure that is ionized corrosion in the long term.

In addition, in order to increase the heat insulation effect of the outer wall of the building, even though the heat insulating material 40 is used in the multi-layered glass module 50, only a part of the aluminum extruded shape member 30 is insulated so that the heat flow into the inside due to the heat conduction by the metal is caused. There is a problem in that the heat insulating performance due to the outer glass becomes poor structure.

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On the other hand, the T-shaped steel built-up shape member 10 has to increase the thickness of the steel plate member to maintain the thickness of the steel sheet can be welded. The shape of the T-shaped 10 increases the load of the building at the exterior curtain wall construction site because the weight per unit length is high. As a result, the T-shaped steel curtain wall requires a large size bracket fastener so that the bracket fastener can bear the weight when attached to the frame, thereby increasing the load of the building and the installation cost according to the weight.

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Korean Patent Application No. 10-2008-0085947 (20080901) A heterogeneous coupling structure using a connection adapter

The present invention is to solve the problems of the prior art as described above, it is an object of the present invention to provide a glass support device that prevents oxidation corrosion by producing an integrated curtain wall without the joining portion of the steel curtain wall.

It is still another object of the present invention to provide a glass support apparatus in which ionization corrosion of aluminum extrusion brothers in contact with steel curtain walls is prevented.

It is still another object of the present invention to provide a glass support apparatus which prevents the outside temperature from being thermally conducted through an iron curtain wall to lower the heat insulating performance.

It is still another object of the present invention to provide a glass support apparatus in which a slim steel curtain wall is used, in which the thickness of the steel curtain wall is reduced and the weight is significantly reduced.

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One aspect of an embodiment of a glass support device according to the present invention for achieving the above object is a glass support device for supporting a glass module comprising an outer glass and an inner glass: high speed bending a cold rolled galvanized iron sheet A curtain wall which is formed after forming and cutting into a predetermined length, formed into a predetermined shape, and both ends thereof are joined by welding, and an installation space is formed in which joint portions of both ends are formed; A supporter installed in the installation space to support the glass module and be molded of aluminum; An ionization preventing member positioned between the curtain wall and the supporter and preventing the supporter from being ionized with respect to the curtain wall; A fastener fastened to the curtain wall through the supporter and the ionization preventing member to fix the supporter to the curtain wall; An adhesive member attaching the glass module to the supporter; And a sealing member for shielding a gap between the supporter and the glass module. The supporter includes: a first supporter installed in the installation space and having a flange portion on which an inner surface of the inner glass is supported; And a second supporter installed in the first supporter and having a support protrusion extending outwardly of the first supporter to support end portions of the inner glass and the outer glass. .

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According to the Example of the glass support apparatus by this invention, the following effects can be anticipated.

First, in the embodiment of the present invention, the cold-rolled galvanized steel sheet is formed by high-speed bending forming, there is no need to manufacture along the T-shaped steel curtain wall, there is no joint in the steel curtain wall configuration, the weight is significantly reduced slim Integral steel curtain wall is manufactured. Therefore, the man-hour of T-shaped steel curtain wall is reduced, and the oxidation and corrosion of the joints are fundamentally prevented in the steel curtain wall configuration, and the installation cost of the glass support device can be significantly reduced.
In addition, since the ionization corrosion prevention member is inserted between the aluminum extrusion brothers in contact with the steel curtain wall so that there is no direct contact between the steel curtain wall and the aluminum extrusion brothers, ionization corrosion is prevented and the durability of the glass support device is increased.
In addition, by forming a heat insulating material for blocking the external temperature in the support protrusion for supporting the glass module and the support protrusion of the curtain wall, the external temperature is prevented from being conducted through the aluminum extrusion material. Therefore, the heat insulating performance of the glass support device is improved to reduce the heat insulating cost.

In another embodiment of the present invention, the cold-rolled galvanized steel sheet is formed by high-speed bending forming, so that a slim, integral steel curtain wall is produced in which the joint part is eliminated and the weight is significantly reduced in the steel curtain wall configuration. Thus, in the steel curtain wall configuration, the oxidation of the joint is fundamentally prevented and the installation cost of the glass support device can be significantly reduced.
In addition, by forming a heat insulating material for blocking the external temperature in the support protrusion for supporting the glass module and the support protrusion of the curtain wall, the external temperature is prevented from being conducted through the aluminum extrusion material. Therefore, the heat insulating performance of the glass support device is improved to reduce the heat insulating cost.

In still another embodiment of the present invention, the cold-rolled steel sheet is formed by high-speed bending forming, whereby a slim-integral steel curtain wall is produced in which the joint is eliminated in the steel curtain wall configuration and the weight is significantly reduced. Thus, in the steel curtain wall configuration, the oxidation of the joint is fundamentally prevented and the installation cost of the glass support device can be significantly reduced.
In addition, by forming a heat insulating material for blocking the external temperature in the support protrusion for supporting the glass module and the support protrusion of the curtain wall, the external temperature is prevented from being conducted through the aluminum extrusion material. Therefore, the heat insulating performance of the glass support device is improved to reduce the heat insulating cost.

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1 is a cross-sectional view showing a curtain wall according to the prior art.
2 is a conceptual diagram showing a roll forming process of a cold rolled galvanized iron sheet.
Figure 3 is a cross-sectional view showing a disassembled state of the first embodiment of the glass support apparatus according to the present invention.
Figure 4 is a cross-sectional view showing a state in which the glass module is supported by the first embodiment of the glass support device according to the present invention.
Figure 5 is a cross-sectional view showing an exploded state of a second embodiment of the glass support apparatus according to the present invention.
Figure 6 is a cross-sectional view showing a state in which the glass module is supported by the second embodiment of the glass support device according to the present invention.
Figure 7 is a cross-sectional view showing a disassembled state of a third embodiment of the glass support apparatus according to the present invention.
Figure 8 is a cross-sectional view showing a state in which the glass module is supported by the third embodiment of the glass support device according to the present invention.

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Hereinafter, a first embodiment of a glass support apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

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FIG. 2 is a conceptual view showing a roll forming process of a cold rolled galvanized iron plate, and FIG. 3 is a cross-sectional view showing a disassembled state of a first embodiment of a glass support apparatus according to the present invention, and FIG. Is a cross-sectional view showing a state in which the glass module is supported by the first embodiment of the glass support device.
First, referring to FIG. 2, the galvanized cold rolled steel sheet is bent in a straight line into a high-speed molding die, and then molded in the form of a curtain wall 100. Preventive treatment Finally, the curtain wall 100 may be formed into a polyhedral pillar shape having a predetermined length by roll forming, for example, a rectangular pillar shape.

Next, referring to FIG. 3 and FIG. 4, in the present embodiment, the glass support apparatus includes the curtain wall 100, the supporters 300 and 310, the ionization prevention member 200, the fastener 500, and the adhesive member. 700, a heat insulating member 600, a backup member 820, and a sealing member 800, 810. And the glass module 900 is supported by the glass support device.
In more detail, the glass module 900 has a gap between the outer glass 920 and the inner glass 910, the outer glass 920, and the inner glass 910 that are spaced apart in parallel to each other. And a caulking member 940 that shields the gap between the outer glass 920 and the inner glass 910. The outer glass 920 and the inner glass 910 are supported by the glass support apparatus in the form of a module in which the spacer 930 and the caulking member 940 are assembled, that is, the glass module 900.

The curtain wall 100 is molded into a hollow having a substantially rectangular cross section. The curtain wall 100, as described above, after forming the cold-rolled galvanized iron sheet by high-speed bending forming, cut to a predetermined length, and welded to both ends of the curtain wall 100 formed again Is formed.
In addition, a predetermined installation space 110 is defined by a portion where both ends of the curtain wall 100 continue, that is, one surface of the curtain wall 100 where the joint 111 of the curtain wall 100 is located. . Such installation space 110 is a place where various configurations for supporting the glass module 900 are installed.
Substantially, the installation space 110 is bent in a direction in which a part of one surface of the curtain wall 100 where the joint portion 111 of the curtain wall 100 is located is recessed into the curtain wall 100. It is formed. An anti-separation protrusion 112 is provided on one surface of the curtain wall 100 corresponding to the entrance of the installation space 110. The separation preventing protrusion 112 is formed by protruding a portion of the curtain wall 100 corresponding to the entrance of the installation space 120 to face each other. Substantially, the separation preventing protrusion 112 may be simultaneously formed in the process of bending a part of the curtain wall 100 to form the installation space 110.

The supporters 300 and 310 include first and second supporters 300 and 310. The first supporter 300 is installed inside the installation space 110. In addition, the second supporter 310 is protruded to the outside of the first supporter 300 in a state where the second supporter 310 is installed inside the first supporter 300.
The first supporter 300 is a place where one surface of the glass module 900 and the inner glass 910 is substantially supported. To this end, the first supporter 300 has a cross section that is joined to a cross section of the first installation space 110. In the first supporter 300, a flange 303, a seating groove 302, and a guide protrusion 301 are formed.
The flange 303 is a portion where one surface of the inner glass 910 is substantially supported. The flange 303 is in contact with one surface of the curtain wall 100 adjacent to the inlet of the installation space 110 while the first supporter 300 is installed in the installation space 110. . Substantially the other glass modules 900 which are adjacent to each other are supported by the flange 303.
The seating groove 302 is a portion into which the release preventing protrusion 112 is fitted while the first supporter 300 is installed in the installation space 110. To this end, the seating groove 302 is formed in a shape that matches the departure-avoidance protrusion 112.
The guide protrusion 301 is located at one side of the first supporter 300 corresponding to the base of the flange 303. The guide protrusion 301 protrudes from one surface of the flange 303 and serves to guide the position of the adhesive member 700.

In the present embodiment, the first supporter 300 is fixed to the curtain wall 100 by the fastener 500 in a state where the first supporter 300 is installed in the installation space 110. In this case, the fastener 500 is fastened to the joint 111 of the curtain wall 100 by passing through one side of the first supporter 300.
The second supporter 310 is provided with a support protrusion 313. The support protrusion 313 substantially extends to the outside of the first supporter 300 in a state where the second supporter 310 is installed inside the first supporter 300. Is defined as part of The support protrusion 313 is for supporting the glass module 900.
In addition, the second supporter 310 is provided with a seating slot 312 and the separation preventing protrusion 311. The seating slot 312 is formed by recessing a portion of the second supporter 310 adjacent to the support protrusion 313. The departure preventing protrusion 311 may protrude from one or both surfaces of the support protrusion 313. The seating slot 312 and the separation preventing protrusion 311 are for fixing the heat insulating member 600.

The ionization preventing member 200 serves to prevent ionization of the first supporter 300. In particular, when the curtain wall 100 is formed of a steel material, and the first supporter 300 is formed of an aluminum material having a relatively high ionization tendency, the first supporter by the ionization preventing member 200 Ionization of 300 can be prevented. For example, the ionization preventing member 300 may be formed of a polyamide material.
The ionization prevention member 200 is located between the curtain wall 100 and the first supporter 300. Substantially, the ionization preventing member 200 may be said to be located inside the installation space 110. Therefore, the ionization prevention member 200 has an open loop cross section corresponding to the space between the installation space 110 and the first supporter 300. The ionization prevention member 200 may be installed in the installation space 110 at the same time as the first supporter 300 or before the first supporter 300 is installed in the installation space 110. have.

The heat insulating member 600 is provided on the second supporter 310 and the support protrusion 313. To this end, the heat insulating member 600 is provided with an internal space that is joined to the cross section of the support protrusion 313. Substantially, the heat insulation member 600 is provided to surround the support protrusion 313. The heat insulation member 600 may be installed in a sliding manner before or after the second supporter 310 is installed on the first supporter 300. The heat insulating member 600 also serves to prevent ionization of the second supporter 310.

In the heat insulating member 600, seating protrusions 603, release preventing grooves 601, and stopping protrusions 602 are formed. The mounting protrusion 603 is provided at the tip of the heat insulating member 600. The separation preventing groove 601 is located in the inner space of the heat insulating member 600. The mounting protrusion 603 and the separation prevention groove 601 serve to prevent the heat insulating member 600 from being detached from the second supporter 310. In the process in which the heat insulating member 600 is slid with respect to the second supporter 310, the seating protrusion 603 slides in a state located inside the seating slot 312, and prevents the release groove. 601 may slide in a state where the departure preventing protrusion 311 is positioned therein. The stopping protrusion 602 protrudes from an outer surface of the heat insulating member 600. The stopping protrusion 602 serves to guide the position of the backup member 820 which will be described later.

The adhesive member 700 serves to attach one surface of the glass module 900 and the inner glass 910 to the first supporter 300. As the adhesive member 700, a double-sided tape attached between the flange 303 and the inner glass 910 may be used.
The backup member 820 is positioned between the second supporter 310 and the caulking member 940. The backup member 820 regulates the filling amount and the filling position of the second sealing member 810 which will be described later. The backup member 820 may be installed before the inner glass 910 is attached to the first supporter 300 by the adhesive member 700 or at the same time as the backup member 820 is attached to the first supporter 300. . Since the heat insulating member 600 is positioned in the second supporter 310, the backup member 820 is located between the heat insulating member 600, the caulking member 940, and the outer glass 920. Can be.

The sealing members 800 and 810 serve to shield a gap between the supporters 300 and 310 and the glass module 900. In the present embodiment, the sealing members 800 and 810 include first and second sealing members 800 and 810.
The first sealing member 800 is positioned between the first supporter 300 and the inner glass 910. Substantially, the first sealing member 800 may be located between the first supporter 300 and the inner glass 910 corresponding to the outside of the adhesive member 700. The first sealing member 800 has the first supporter 300 and the inner glass 910 in a state where the inner glass 910 is attached to the first supporter 300 by the adhesive member 700. It can be filled in the gap between).

The second sealing member 810 is positioned between the second supporter 310 and the outer glass 920. However, since the heat insulating member 600 is positioned in the second supporter 310, the second sealing member 810 is substantially the heat insulating member 600 and the same as the backup member 820. It will be located between the caulking member 940 and the outer glass 920. In addition, the second sealing member 810 may be filled after the inner glass 910 is supported by the first supporter 300 by the adhesive member 700.
Hereinafter, a process of supporting the glass module according to the first embodiment of the glass support apparatus according to the present invention will be described in more detail.

First, the first supporter 300 and the ionization preventing member 200 are installed in the installation space 110 of the curtain wall 100. In this case, the first supporter 300 and the ionization prevention member 200 are installed in the installation space 110 by sliding in a direction orthogonal to the surface of the drawing. In addition, the first supporter 300 and the ionization preventing member 200 may be installed in the installation space 110 by sliding at the same time, or may be installed in the installation space 110 by sliding sequentially. . And the description of the manufacturing process of the curtain wall 100, as described above, will be omitted.

Next, after the first supporter 300 and the ionization prevention member 200 are installed in the installation space 110, the first supporter 300 and the ionization prevention member 200 are fastened using the fastener 500. It is fixed to the curtain wall (100). At this time, as described above, the fastener 500 is fastened to the joint welding portion 111 of the curtain wall (100).

In addition, a second supporter 310 is installed in the first supporter 300, and a heat insulating member 600 is installed in the second supporter 310. Similarly to the first supporter 300 installed in the installation space 110, the second supporter 310 also slides in a direction orthogonal to the ground in FIG. 3 of the first supporter 300. It is installed inside. The heat insulation member 600 may be installed before the second supporter 310 is installed inside the first supporter 300 or after the second supporter 310 is installed inside the first supporter 300. In FIG. 3, the second supporter 310 may be installed in the second supporter 310 by sliding in a direction perpendicular to the ground.
In this state, the glass module 900 is fixed to the first and second supporters 300 and 310. Inner glass 910 constituting substantially the glass module 900 is attached to the first supporter 300, substantially the flange 303 by an adhesive member 700.
Finally, the sealing members 800, 810 and the backup member 820 are formed in the gap between the first supporter 300 and the glass module 900 and the gap between the second supporter 310 and the glass module 900. Locate it. More specifically, the first sealing member 800 may be filled in the gap between the first supporter 300 and the inner glass 910. In addition, a backup member 820 is positioned in the gap between the heat insulating member 600 and the caulking member 940 installed in the second supporter 310, and substantially in the second supporter 310. In this case, the backup member 820 may be fixed to the heat insulating member 310 or the glass module 900 before the glass module 900 is supported by the first supporter 300. In addition, the second sealing member 810 may be filled in the gap between the second supporter 310 and the heat insulating member 600 and the outer glass 920.

Hereinafter, a second embodiment of a glass support apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.
Figure 5 is a cross-sectional view showing a second embodiment of the glass support device according to the present invention in an exploded state, Figure 6 is a cross-sectional view showing a glass module supported state by a second embodiment of the glass support device according to the present invention. . For the same components as those of the first embodiment of the present invention described above among the components of the present embodiment, reference numerals of FIGS. 3 and 4 are used, and detailed description thereof will be omitted.

In the present embodiment, the support protrusion 120 provided in the curtain wall 100 performs the function of the supporter. The support protrusions 120 are formed to protrude outwards in a state where both end portions of the curtain wall 100 which are welded to each other are in contact with each other. In addition, the ends of the glass modules 900 adjacent to each other are substantially supported by the support protrusions 120.

The support protrusion part 120 is provided with a departure prevention protrusion 121. The departure preventing protrusion 121 may be formed on one surface or both surfaces of the support protrusion 120. Substantially, the separation preventing protrusion 121 is formed by protruding a portion of the support protrusion 120.

The heat insulating member 610 is installed to surround the support protrusion 120. The separation preventing groove 611 is formed in the heat insulating member 610. The departure prevention protrusion 121 is fitted into the departure prevention groove 611. In addition, a stopping protrusion 612 is formed on the heat insulating member 610. The stopping protrusion 612 serves to guide the position of the backup member 820 inserted between the glass module 900 and the support protrusion 120. Substantially, the separation preventing groove 611 and the stopping protrusion 612 may be formed on the inner and outer sides of the heat insulating member 610 facing each other.

Hereinafter, a third embodiment of a glass support apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

7 is a cross-sectional view showing a disassembled state of the third embodiment of the glass support apparatus according to the present invention, Figure 8 is a cross-sectional view showing a glass module supported state by the third embodiment of the glass support apparatus according to the present invention. . For the same components as those of the first embodiment of the present invention described above among the components of the present embodiment, reference numerals of FIGS. 3 and 4 are used, and detailed description thereof will be omitted.

7 and 8, the present embodiment includes a curtain wall 100, supporters 400 and 410, a heat insulating member 600, an adhesive member 700, a fastener 510, and a backup member 820. ) And sealing members 800 and 810. A support protrusion 130 is formed on the curtain wall 100, and the supporters 400 and 410 include first and second members 400 and 410.

In more detail, the support protrusion 130 performs the same function as the above-described support protrusion 120 of the second embodiment of the present invention. However, in this embodiment, the support protrusion 130 has a polygonal cross section, for example, a rectangle.

The heat insulating member 620 is installed to surround the support protrusion 130. The heat insulating member 620 may be formed of a polyamide material. In addition, the insulating member 620 is provided with a plurality of gasket members 622. The gasket member 622 serves to shield a gap between the heat insulating member 620, the support protrusion 130, and the supporters 400 and 410. For example, the gasket member 622 may be positioned at ends of the heat insulating member 620 in contact with the support protrusion 130 and the supporters 400 and 410, respectively. To this end, an insertion groove 621 into which the gasket member 622 is inserted may be formed in the heat insulating member 620.

The supporters 400 and 410 include first and second members 400 and 410. The first member 400 is fixed to the support protrusion 130, and the second member 410 is coupled to the first member 400. The first member 400 is fixed by the fastener 510 to the support protrusion 130 in a state where the heat insulating member 620 is installed. The fastener 510 is substantially fastened to the support protrusion 130 after sequentially passing through the first member 400 and the heat insulating member 620. The first member 400 is a place where one surface of the glass module 900 and the outer glass 610 is supported. The second member 410 is coupled to the first member 400 while the first member 400 is fixed to the support protrusion 130 by the fastener 510. Accordingly, the fastener 510 may be shielded from the outside by the second member 410. The first member 400 is fixed to the curtain wall 100 and the heat insulating member 620 by a fastener 510.

On the other hand, the first member 400 is provided with a stopping protrusion 402. The stopping protrusion 402 serves to regulate the position of the backup member 820 inserted into the space between the first member 400 and the glass module 900.

In addition, in the present embodiment, the sealing members 800 and 810 and substantially the second sealing member 810 are positioned between the first member 400 and the glass module 900. More specifically, the second sealing member 810 is positioned between the first member 400 and the outer glass 920 corresponding to the outside of the backup member 820.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. .

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Claims (19)

In a glass support apparatus for supporting a glass module comprising an outer glass and an inner glass:
Cold-rolled galvanized iron sheet is formed by high-speed bending forming and then cut into a predetermined length, and formed into a predetermined shape, and then both ends are joined by welding, and an installation space is formed in which joints of both ends are located. Curtain wall;
A supporter installed in the installation space to support the glass module and be molded of aluminum;
An ionization preventing member positioned between the curtain wall and the supporter and preventing the supporter from being ionized with respect to the curtain wall;
A fastener fastened to the curtain wall through the supporter and the ionization preventing member to fix the supporter to the curtain wall;
An adhesive member attaching the glass module to the supporter; And
A sealing member for shielding a gap between the supporter and the glass module; Lt; / RTI >
The supporter includes:
A first supporter installed in the installation space and having a flange portion on which an inner surface of the inner glass is supported; And
A second supporter installed in the first supporter and having a support protrusion extending outwardly of the first supporter to support end portions of the inner glass and the outer glass; Glass support device comprising a.
delete The method of claim 1,
And a heat insulating member provided to surround the supporting protrusion.
The method of claim 3, wherein
The support protrusion is provided with a departure prevention protrusion,
The glass support device is formed in the heat insulating member is a separation prevention groove in which the separation preventing projection is seated.
delete The method of claim 3, wherein
A seating slot is formed in any one of the second supporter and the heat insulating member.
The other one of the said 2nd supporter and a heat insulating member is a glass support apparatus provided with the mounting protrusion which mounts in the said mounting slot.
The method according to claim 6,
The seating slot and the seating protrusion are formed long in the longitudinal direction of the second supporter and the heat insulating member,
And the seating protrusion is seated in the seating slot when the heat insulating member slides in the longitudinal direction with respect to the extension protrusion.
The method of claim 1,
The second supporter is a glass support device that is provided in the sliding manner on the first supporter.
The method of claim 1,
The adhesive member attaches the inner glass to the first supporter,
The first supporter is provided with a glass guide device for guiding the position of the adhesive member.
The method according to any one of claims 1, 3, 4, 6 to 9,
Wherein the sealing member comprises:
A first sealing member for shielding a gap between the first supporter and the inner glass constituting the glass module;
A backup member for shielding a gap between the heat insulating member including the second supporter and the outer glass constituting the glass module; And
A second sealing member for shielding a gap between the heat insulating member including the second supporter corresponding to the outside of the backup member and the outer glass constituting the glass module; Glass support device comprising a. delete delete delete delete delete delete delete delete delete

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