KR20220013883A - Double insulation fireproof glass door - Google Patents

Abstract

The present invention relates to a dual insulation fireproof glass door capable of securing insulation through a multilevel structure of fireproof glass and insulation glass as well as preventing the spread of flames in case of a fire. In accordance with the present invention, the dual insulation fireproof glass door includes: a door frame (100) installed in a door frame (10) to be openable, and having an opening (110) formed inward, and having a slot groove (120) formed on an inner circumference surface of the opening (110); fireproof glass (200) finishing the opening (110), and inserted into the slot groove (120) to be confined by a heat-resistant filler (220); and insulation glass (300) installed in the opening (110) so as to be spaced apart from the fireproof glass (200) to form an insulation space part (320), and ruptured by an increase in internal pressure of the insulation space part (320) when exposed to heat from a fire, to be separated from the door frame (100). Through the dual insulation fireproof glass door, insulation performance can be highly improved, and moreover, the insulation glass is first broken when exposed to fire heat, which can lead to an advantage of preventing an increase in the internal pressure of the insulation space part and damage to the fireproof glass caused by insulation glass fragments.

Description

Double insulation fireproof glass door {Double insulation fireproof glass door}

The present invention relates to a double-insulated fire-proof glass door, which, when described in more detail, relates to a double-insulated fire-proof glass door that can block flame propagation in case of fire while ensuring thermal insulation by a multilayer structure of fire-resistant glass and heat-insulating glass.

In general, most buildings such as apartments, schools, libraries, and buildings are equipped with windows, and these windows decorate the exterior of the building and act as a passage for sunlight and wind to enter and exit, blocking heat and cold as well as preventing fire, It adds a pleasant environment to the residents with waterproofing, soundproofing, and a pipe network function that allows you to see the outdoor scenery.

For these windows, double-glazed windows are installed on the door frame to improve sound insulation and thermal insulation, and polyamide or polyurethane materials are used on the door frame and window frame to improve insulation in winter, especially when the temperature is low. of insulation frame to block heat conduction from the outside and prevent dew condensation.

Accordingly, in order to prevent dew condensation, as for windows and doors, in Patent Registration No. 10-1468678 disclosed in the prior art, an upper frame, a lower frame, a left frame, and a right frame are formed around a window frame made of synthetic resin; Miseogi single-pane windows made of synthetic resin installed on the outside of the window frame so that the double-layer glass is inserted into the first and second windows made of synthetic resin, respectively, and slid by rollers; Miseogi slim single-pane windows are installed indoors while being spaced apart from each other by a predetermined distance from the single-plate glass so that the lower parts are fitted in the first lower frame and the second lower frame made of aluminum and slide by the sliding member; It is formed on the upper and lower portions of the windbreak frame installed in the fastening part of each one end of the first and second changjak constituting the Miseogi single chandelier, respectively, to block the lateral air flow while buffering action when in contact with the left frame or the right frame. A configuration that includes a side wind chime plate has been previously registered.

In addition, in Patent Laid-Open Patent Publication No. 10-2005-0105103, which is another prior art, the outer window is composed of a window frame, a glass fixing frame, and glass, and the inner window has a structure of a sliding window using a packing for a glass guide is applied. By using the aluminum chassis or high chassis (PVC) structure as an integral part of the inside and outside, it provides a thinner window frame structure compared to the existing double-glazed window structure, as well as preventing noise through the window structure with no gaps inside with packing for glass guide. The purpose is to improve the effect of heating and cooling. The present invention configured for this purpose includes: a plurality of outer guide rails formed at regular intervals so that the upper and lower sides correspond to each other on the outside of the inner surface; a plurality of inner guide grooves formed by a plurality of inner guide rails formed at regular intervals so that the upper and lower sides correspond to each other on the inner side of the inner surface; and a glass guide packing that is fitted on the inner guide groove to prevent the flow of glass when the glass is slidably coupled to the window frame and prevents noise when the glass slides back and forth. A configuration in which the glass is slidably coupled to the outer guide rail and slidably coupled to the glass guide packing fitted in the inner guide groove on the inside to form a double-glazed window has been previously disclosed.

However, in the prior art, the double-layer glass is applied to prevent dew condensation due to the temperature difference between the inside and the outside and to improve the insulation performance, but in case of a fire, the glass bends or bursts due to the pressure increase in the sealed space between the double-layer glass. However, as the ruptured glass shards hit and damage the neighboring glass, the fire protection performance fell short of the standard.

KR 10-1468678 B1 (2014.11.27.) KR 10-2005-0105103 A (2005.11.03.)

In the present invention, a new technology was created to solve the problems of the prior art, and although it is a double glass door, it can satisfy the performance standards as a fire door installed to prevent the flame from spreading outside when a fire breaks out in a building. It is an object of the present invention to provide a double insulation fire protection glass door with an improved structure so that the distortion of the door is suppressed as much as possible in case of a fire and the fire glass does not easily collapse.

Furthermore, since the insulating glass is adhered to the inner circumferential surface of the door frame to form a double-layered insulating space with the fire protection glass, the insulating performance is highly improved and the insulating glass is destroyed first when exposed to fire heat, increasing the internal pressure of the insulating space and the insulating glass An object of the present invention is to provide a double insulated fire glass door that prevents damage to the fire glass due to fragments.

As a specific means for solving the problems of the present invention, the present invention constitutes a double insulated fireproof glass door that satisfies the fire protection performance, but consists of a pair of vertical frames and a pair of horizontal frames so that the door frame 10 can be opened and closed. The door frame 100 is installed, the opening 110 is formed inside, the slot groove 120 is formed on the inner peripheral surface of the opening 110; a fire-resistant glass 200 that closes the opening 110 and is inserted into the slot groove 120 and is provided to be constrained by the heat-resistant insulating filler 220; And it is installed in the opening 110 so as to be spaced apart from the fire glass 200 to form an insulating space 320, and when exposed to fire heat, is destroyed due to an increase in internal pressure of the insulating space 320 and the door frame 100. It is characterized in that it comprises a; insulating glass 300 provided to be separated from the phase.

At this time, the door frame 100 includes an outer frame part 130 in which an outdoor side plate 132 and an outer peripheral plate 134 forming an outer peripheral surface of the door frame 100 are bent, and an indoor side plate 142 and a door frame. (10) An inner frame part 140 in which an inner peripheral plate 144 forming an inner peripheral surface is bent at a right angle, and a locking plate 146 bent inwardly in parallel to the indoor side plate 142 is provided at an end of the inner peripheral plate 144 ) and the engaging plate 146 of the inner frame part 140 is in close contact with the outdoor side plate 132 of the outer frame part 130, the end of the outdoor side plate 132 is bent into a 'C' shape to the engaging plate and an overlap (150) formed to constrain (146).

On the inside of the door frame 100, an inner reinforcing frame 170A mounted at a position closest to the glass 200 and 300, and an inner reinforcing frame 170B mounted on the outer circumferential plate 134 from the opposite side are formed. , The inner reinforcing frame 170A is formed by bending a base plate 172 mounted on the inner circumferential plate 144 of the inner frame part 140 and at both ends of the base plate 172 at right angles to form an indoor side plate 132 and an outdoor It includes a pair of extension plates 174 mounted on the side plate 142, and is installed between the locking plate 146 of the inner frame part 140 and the outdoor side plate 132 of the outer frame part 130. It is characterized in that a heat-resistant insulating sheet 180 is provided between the outer frame parts 130 and 140 to block heat conduction.

The slot groove 120 includes an overlapping portion 150 for supporting and constraining the fire protection glass 200 from the outdoor direction by overlapping the locking plate 146 and the outdoor side plate 132, and the inner frame part 140 ) is installed on the inner circumferential plate 144 and is formed between the finishing bars 124 that restrain the fire glass 200 in the interior direction, from the outer end of the door frame 100 to the end of the second overlapping part 160 The height (H) of the insulating glass 300 is characterized in that it is configured to be higher than the height (h) of the finishing bar 124 is seated.

In addition, the finishing bar 124 is fastened by a fixing piece 126 together with the inner reinforcing frame 170A formed on the opposite side in a state of being seated on the inner circumferential plate 144, and the fixing piece 126 is insulating glass. It is characterized in that it is configured to be closed by a heat-resistant sealant 190 applied between the 300 and the finishing bar 124,

The insulating glass 300 is formed in a smaller size than the fire protection glass 200, and the fire protection glass 200 is formed of heat-resistant glass and is constrained by the closing bar 124 while being inserted into the slot groove 120. , characterized in that the insulating glass 300 and the spacing block 240 are configured to be adhesively fixed while seated on the inner circumferential surface of the finishing bar 124 .

In addition, the external reinforcing frame 170B installed in the horizontal frame extends to the outer circumferential surface of the vertical frame, penetrates through the external reinforcing frame 170B at the center of the vertical frame on the hinge side, and is coupled with one end exposed to the outside. A pin 160 is formed, and a coupling hole 12 for accommodating the exposed binding pin 160 is formed in the door frame 10 at a position corresponding to the binding pin 160 .

According to the specific means for solving the above problems, in the present invention, the insulating glass is adhered to the inner circumferential surface of the door frame to form an insulating space of a multi-layer structure together with the fire protection glass, so the thermal conductivity is very low, so the thermal insulation performance is excellent, and therefore, when a fire occurs It has very good fire and heat protection.

Moreover, when exposed to fire heat, the insulating glass is destroyed first, thereby preventing the increase in internal pressure of the insulating space and damage to the fire protection glass due to the fragments of the insulating glass.

1 is a front view showing a state in which the double insulation fire protection glass door provided in the present invention is constructed.
Fig. 2 is a longitudinal cross-sectional view taken along line AA' of Fig. 1;
Fig. 3 is a cross-sectional view taken along line BB' of Fig. 1;
4 is a block diagram showing an exploded state of the door frame of the double-insulated fire protection glass door according to an embodiment of the present invention.
5 is a longitudinal cross-sectional view showing an example of a state in which the double-insulated fire protection glass door of the present invention is exposed to fire.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, when it is determined that the subject matter of the present invention may be unnecessarily obscured as it is obvious to those skilled in the art with respect to related known functions, the detailed description thereof will be omitted.

1 is a configuration diagram showing a construction state of a double insulated fire protection glass door according to an embodiment of the present invention, FIG. 2 is a longitudinal cross-sectional view taken along line AA' of FIG. 1, and FIG. 3 is BB' of FIG. It is a cross-sectional view showing a cut line.

The present invention relates to a double-insulated fire-resistant glass door, in which the insulating glass is adhered to the inner circumferential surface of the door frame to form a multi-layered insulating space with the fire-proof glass, so that the insulating performance is highly improved and the insulating glass is destroyed first when exposed to fire heat The main components of the door frame 100 , the fire glass 200 , and the insulating glass 300 as a whole are to prevent damage to the fire glass due to the increase in internal pressure of the insulating space and the fragments of the insulating glass.

The door frame 100 according to the present invention is composed of a pair of vertical frames and a pair of horizontal frames and is installed to be able to open and close to the door frame 10, and as the opening 110 is formed inside, the opening ( 110) A slot groove 120 is formed on the inner circumferential surface. At this time, the door frame 100 is assembled in the form of a square frame, and an opening 110 for installing a fire protection glass 200 and an insulating glass 300 to be described later is formed in the center.

The door frame 100 is formed by bending a plate-shaped material or by extrusion molding. It is preferable that each corner of the door frame 100 is rounded and bent while rounding, that is, omitting the v-groove extraction operation for ease of bending, or each corner is molded into a rounded shape by injection molding. This is to prevent the door frame 10 from easily bursting or breaking due to the weak durability of each corner when exposed to the environment of the design for the purpose of use of fireproof glass for a long time and thermal expansion.

4 is a block diagram showing an exploded state of a door frame of a double-insulated fire protection glass door according to an embodiment of the present invention, wherein the door frame 100 includes an outer frame part 130, an inner frame part 140, and an overlapping part ( 150) and a reinforcing frame 170.

The outer frame part 130 is formed by bending the outer side plate 132 and the outer peripheral plate 134 forming the outer peripheral surface of the door frame 100 at an angle of 90°.

The inner frame part 140 is formed by bending the interior side plate 142 and the outer peripheral plate 148 forming the outer peripheral surface of the door frame 100 at an angle of 90°, and the interior peripheral surface of the indoor side plate 142 and the door frame 10 . The inner circumferential plate 144 is formed by bending at a right angle, and an end of the inner circumferential plate 144 is composed of a locking plate 146 bent inwardly in parallel to the indoor side plate 142 .

In addition, the outer frame part 130 and the inner frame part 140 are coupled by a press-compression method by the overlapping portion 150 . Specifically, the overlapping part 150 attaches the locking plate 146 of the inner frame part 140 to the outdoor plate 132 of the outer frame part 130 and attaches the end of the outdoor plate 132 to a 'c'. It is formed to restrain the locking plate 146 by bending it into a shape.

The double insulated fire protection glass door of the present invention is configured to suppress distortion due to high heat by forming a reinforcing frame 170 having a roughly C shape on the door frame 100 in order to satisfy the standard of fire protection performance.

Specifically, on the inside of the door frame 100, the inner reinforcing frame 170A mounted at the position closest to the glass 200 and 300, and the inner reinforcing frame 170B mounted on the outer circumferential plate 134 from the opposite side thereof. is formed

The inner reinforcing frame 170A includes a base plate 172 mounted on the inner circumferential plate 144 of the inner frame part 140, and a base plate 172 bent at both ends at right angles to form an indoor and an outer plate 132 ( It is composed of a pair of extension plates 174 mounted on the 142 and inwardly bent plates 176 bent at both ends of the extension plate 174 .

In addition, between the engaging plate 146 of the inner frame part 140 and the outer side plate 132 of the outer frame part 130, and between the inner reinforcing frame 170B and the outer frame part 130, a heat-resistant insulating sheet (180) is provided.

As such, as the inner and outer frame parts 130 and 140 are bound in a non-contact state by the heat-resistant insulating sheet 180, cooling and heating efficiency to block heat conduction between the inner and outer frame parts 130 and 140 is improved and When a fire occurs, the overheating phenomenon of the outer frame part 130 is prevented by internal heat.

In addition, the external reinforcement frame 170B installed in the horizontal frame is configured to extend to the outer circumferential surface of the vertical frame and constrain, as shown in FIG. 1 , to suppress distortion due to high heat.

Additionally, in the center of the vertical frame on the hinge side, as shown in FIG. 3 , a binding pin 160 that penetrates through the external reinforcement frame 170B and is coupled with one end exposed to the outside is formed, and the binding pin 160 . A coupling hole 12 for accommodating the exposed binding pin 160 is formed in the door frame 10 at a position corresponding to .

Therefore, even when exposed to high heat for a long time, the binding pin 160 restrains the door frame 10 and the vertical frame of the door, so that the door frame 100 is bent alone to ensure durability that can suppress the leakage of flames through the gap. can

2 and 4 , the slot groove 120 formed on the inner circumferential surface of the opening 110 is coupled to overlap the locking plate 146 and the outdoor side plate 132 to install the fireproof glass 200 outdoors. Between the overlapping portion 150 for supporting and restraining in the lateral direction, and the finishing bar 124 detachably installed on the inner circumferential plate 144 of the inner frame part 140 to restrain the fire glass 200 in the indoor direction. is formed in

The overlapping portion 150 has a double plate structure in which the locking plate 146 and the outdoor side plate 132 are combined through the heat-resistant insulating sheet 180 to form an integral body, so that in case of a fire, the fire protection glass 200 has a binding force. This can be firmly maintained, and by the detachable structure of the finishing bar 124, the installation and replacement of the fire glass 200 can be conveniently performed.

The fire protection glass 200 according to the present invention inserted into the slot groove 120 to close the opening 110 is provided to be constrained by the heat-resistant insulating filler 220 in the slot groove 120 . The fire-resistant glass 200 is formed of heat-resistant glass with a thickness of 6 to 10 mm, and the edge portion is inserted into the slot groove 120 of the door frame 100 and is formed of a heat-resistant insulation material containing glass wool. ) is bound by

Then, the heat-resistant insulating filler 220 is installed between the slot groove 120 and the fire glass 200 in a compressed state, and then firmly restrains the fire glass 200 by the expansion and restoring force.

In the event of a fire, when the fire protection glass 11 is exposed to high temperature for a certain period of time, the physical properties of the glass, which is in a hard solid state, become brittle and deformation occurs in the direction of gravity. Since the four corners of the front and rear are pressed and fixed, the fire protection glass 11 is suppressed as much as possible from sagging or deforming, thereby improving the flame blocking durability.

The insulating glass 300 according to the present invention is installed in the opening 110 so as to be spaced apart from the fireproof glass 200 to form the insulating space 320, and when exposed to fire heat, the internal pressure of the insulating space 320 rises. Due to the destruction, it is provided to be separated on the door frame 100 .

More specifically, the insulating glass 300 is spaced apart from the fire protection glass 200 by the spacing block 240, and the insulating space 320 is formed between the fire protection glass 200 and the insulating glass 300, , the inside of the heat insulating space 320 is formed of a vacuum state or an air layer or a heat insulating gas layer to form a heat insulating layer that blocks heat flow due to a temperature difference between the inside and outside.

And the insulating glass 300 is formed of a 4 ~ 6mm thick general low-e glass (low-e glass), that is, the insulating glass 300 is formed with a thinner thickness than the fire protection glass 200, exposed to flame It is applied as a specification that is easily damaged by high heat rather than fireproof glass.

Referring to FIGS. 2 and 3 , the insulating glass 300 is installed so that the edge surface thereof is seated on the finishing bar 124 , and the four corners seated therein are adhesively fixed to each other by an adhesive including a heat-resistant sealant 190 . provided In addition, the spacing block 240 is also installed on the finishing bar 124 so that only the four corners of the fire glass 200 are inserted into the slot groove 120 .

In addition, the finishing bar 124 is fastened by a fixing piece 126 together with the inner reinforcing frame 170A formed on the opposite side in a state of being seated on the inner circumferential plate 144 . That is, the fixing piece 126 is sequentially coupled through the inner circumferential surface plate 144 and the inner reinforcing frame 170A from the inner circumferential surface of the finishing bar 124 .

At this time, the fixing piece 126 is closed by the heat-resistant sealant 190 applied between the insulating glass 300 and the finishing bar 124 .

As a result, the fixing piece 126 is not loosened or released by an external impact, but also has a solid coupling state with the door frame, so as to firmly clamp the fire glass at the scene of a fire or a fire prevention performance test. can be maintained for a long time, thus ensuring excellent fire protection performance.

On the other hand, the height (H) from the outer end of the door frame 100 to the end of the second overlapping part 160 should be higher than the height (h) of the finishing bar 124 on which the insulating glass 300 is seated, preferably To have a position equal to or higher than the upper end of the spacing block 240 . This is to prevent the gap block 240 from being exposed when viewed from the outside and impair the aesthetics, and to maximize the bonding force of the fire protection glass 200 in case of fire by expanding the contact area with the fire protection glass 200 .

5 is a longitudinal cross-sectional view showing an example of a state in which the double-insulated fireproof glass door of the present invention is exposed to fire. Since it is installed to be seated on the inner circumferential surface, when exposed to fire heat, the insulating glass 300 cannot withstand high temperature and is first independently destroyed so that it can be easily separated and removed. If the insulating glass 300 cannot be initially removed during a fire, the internal pressure of the insulating space unit 300 may rise and an explosion may occur. As a result, it will not be able to perform its functions properly.

Even after the insulating glass 300 is removed due to the heat of fire, the fire glass 200 remains firmly restrained in the slot groove 120 and the slot groove 120 and the fire glass 200 by the insulating filler 220. All the gaps in between are firmly filled, so that the breakage and separation of the fire glass due to the internal heat pressure and high temperature of the fire space are suppressed as much as possible, and the function as a fire door that blocks the leakage of flames and fire gases is strengthened. It can be carried out, and due to the nature of the glass, the situation on the opposite side can be observed with the naked eye, so fire reporting and rescue operations can be made more effectively.

As such, the double insulation fire protection glass door provided in the present invention can not only firmly clamp the fire glass for a long time in case of fire by means of the slot groove 120 structure, but also include the reinforcement frames 170A and 170B installed in the door frame 100 and Since the door frame 100 is not easily twisted with the binding pin 160 structure, durability as a fire door can be guaranteed.

As described above, in the detailed description of the present invention, the most preferred embodiment of the present invention has been described, but various modifications are possible within the scope not departing from the technical scope of the present invention. Therefore, the protection scope of the present invention is not limited to the above embodiments, but the protection scope should be recognized from the techniques of the claims to be described later and equivalent technical means from these techniques.

10: door frame
100: door frame
110: opening 120: sullot groove 124: closing bar 124a: through hole 126: fixing piece
130: outer frame part 132: outdoor side plate 134: outer peripheral plate
140: inner frame part 142: interior side plate 144: inner peripheral plate 146: catch plate
150: overlap
160: binding pin
170A: Internal reinforcement frame 170B: External reinforcement frame
172: base plate 174: extended plate 176: inward bending plate
180: heat-resistant insulating sheet 190: heat-resistant sealant
200: fire glass
220: insulating filler 240: gap block
300: insulating glass 320: insulating space part

Claims (7)

It is composed of a pair of vertical frames and a pair of horizontal frames and is installed so as to be able to open and close in the door frame 10, and as the opening 110 is formed inside, the slot groove 120 is formed on the inner circumferential surface of the opening 110. The door frame 100 is formed;
a fire-proof glass 200 that closes the opening 110 and is inserted into the slot groove 120 and is provided to be constrained by the heat-resistant insulating filler 220; and
It is installed in the opening 110 to be spaced apart from the fire glass 200 to form the insulating space 320, and when exposed to fire heat, the insulating space 320 is destroyed due to an increase in internal pressure on the door frame 100. A double-insulated fire-proof glass door comprising a; heat-insulating glass 300 that is provided to be separated.
The method of claim 1,
The door frame 100 is
an outer frame part 130 in which an outer peripheral plate 134 forming an outer peripheral surface of the outdoor side plate 132 and the door frame 100 is bent;
The indoor side plate 142 and the inner peripheral plate 144 forming the inner peripheral surface of the door frame 10 are bent at right angles, and at the end of the inner peripheral plate 144, a locking plate 146 bent inward in parallel to the indoor side plate 142 The inner frame part 140 provided with this, and
In a state in which the engaging plate 146 of the inner frame part 140 is in close contact with the outdoor side plate 132 of the outer frame part 130, the end of the outdoor side plate 132 is bent in a 'C' shape to form the engaging plate 146. Double insulated fire glass door, characterized in that it comprises an overlap portion 150 is formed to constrain the.
3. The method of claim 2,
Inside the door frame 100, an inner reinforcing frame 170A mounted at a position closest to the glass 200 and 300, and an inner reinforcing frame 170B mounted on the outer circumferential plate 134 from the opposite side are formed. ,
The inner reinforcing frame 170A includes a base plate 172 mounted on the inner circumferential plate 144 of the inner frame part 140 and bent at both ends of the base plate 172 at right angles to form an indoor side plate 132 and an outdoor side plate a pair of extension plates 174 mounted on 142;
A heat-resistant insulating sheet ( 180) double insulation fire protection glass door, characterized in that it is provided.
3. The method of claim 2,
The slot groove 120 includes an overlapping portion 150 for supporting and constraining the fire protection glass 200 from the outdoor direction by overlapping the locking plate 146 and the outdoor side plate 132, and the inner frame part 140 ) is installed on the inner circumferential plate 144 and is formed between the finishing bars 124 that restrain the fire glass 200 in the indoor direction,
The height (H) from the outer end of the door frame (100) to the end of the second overlapping part (160) is higher than the height (h) of the finishing bar (124) on which the insulating glass (300) is seated. Double insulated fireproof glass door.
5. The method of claim 4,
The finishing bar 124 is fastened by a fixing piece 126 together with the inner reinforcing frame 170A formed on the opposite side in a state of being seated on the inner circumferential plate 144,
The fixing piece (126) is a double insulated fire-proof glass door, characterized in that it is configured to be closed by a heat-resistant sealant (190) applied between the insulating glass (300) and the finishing bar (124).
5. The method of claim 4,
The insulating glass 300 is formed in a smaller size than the fire protection glass 200, and the fire protection glass 200 is formed of heat-resistant glass and is constrained by the closing bar 124 while being inserted into the slot groove 120. , The insulating glass (300) and the spacing block (240) is a double-insulated fire-proof glass door, characterized in that it is configured to be adhesively fixed in a state seated on the inner peripheral surface of the finish bar (124).
4. The method of claim 3,
The external reinforcement frame 170B installed on the horizontal frame extends to the outer peripheral surface of the vertical frame,
In the center of the vertical frame on the hinge side, a binding pin 160 that penetrates through the external reinforcement frame 170B and is coupled with one end exposed to the outside is formed,
Double insulated fire protection glass door, characterized in that the coupling hole (12) for accommodating the exposed binding pin (160) is formed in the door frame (10) at a position corresponding to the binding pin (160).

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