KR20220058044A - Pair glass with improved insulation and a method of manufacturing the same - Google Patents

Abstract

The present invention relates to double-pane window with improved insulation, which can semi-permanently maintain a thermal management rate with a UV-blocking insulation film, and enables the UV-blocking insulation film to be installed taut, thereby preventing the beauty from being spoiled, and a method for manufacturing the same and, more specifically, to a method for manufacturing double-pane window with improved insulation, and double-pane window manufactured thereby. A first warm edge spacer which has the center penetrated therethrough, has a protrusion formed on one side of the edge thereof, and has an inner space corresponding to a thickness portion and filled with a moisture absorbent, a first UV-blocking insulation film, and a second warm edge spacer which has the center penetrated therethrough and has an inner space corresponding to a thickness portion and filled with a moisture absorbent, are provided. The second warm edge spacer presses the edge of the first UV-blocking insulation film to make the first UV-blocking insulation film taut while bringing the same into close contact with the first warm edge spacer and the protrusion. The edges of a double-pane window are respectively bonded to the outer surfaces of the first and second warm edge spacers not facing each other on both sides of the first UV-blocking insulation film through adhesive members. Silicon is applied to the outer space formed between the edges of the first and second warm edge spacers and the edges of the double-pane window to form a silicone finishing portion on the outer spacer.

Description

Pair glass with improved insulation and a method of manufacturing the same

The present invention relates to a multi-layer glass and a method for manufacturing the same, and in particular, a multi-layer with improved insulation function that allows the UV-blocking insulation film to be installed tautly so as not to impair the aesthetics while maintaining the thermal management rate semi-permanently with a UV-blocking insulating film It relates to glass and a method for manufacturing the same.

In general, double-glazed glass has a structure in which an air layer is provided between a pair of glass, and has superior thermal insulation function compared to single glass, thereby saving cooling and heating costs.

In recent years, by filling the air layer formed between a pair of glasses with argon, krypton gas, etc., the thermal insulation function has been further improved.

In this regard, Patent Document 1 discloses a first glass installed inside a building; a second glass forming the exterior wall of the building; a third glass positioned between the first glass and the second glass; a first non-metallic bar for maintaining a space between the first glass and the third glass located in the center; and a second non-metallic rod for maintaining a space between the second glass and a third glass located in the center, wherein the first non-metallic rod and the second non-metallic rod are located on the same straight line, and the first to third It is attached to the inner part 3 to 10 mm from the outermost part of the glass and is configured to further form a sealing part in a space extending to the outermost part of the first and second non-metallic rods and the first to third glass; the first non-metallic bar is an extrusion-molded product, and is composed of a first foamable resin inter-rod containing a desiccant, and the second non-metallic inter-rod is composed of a second insulating inter-rod wrapped with synthetic resin (PVC) on the outside of the aluminum reinforcement; The first foamable resin inter-rod has a thickness to separate the first and third glasses and is formed to form a loop of a size slightly smaller than the outermost circumference of the first and third glasses, and the first and third glasses a first bonding surface of both sides attached to the glass, a first inner surface facing the inner space between both glasses in a bonded state, and a first outer surface facing the outer space between both glasses; the second heat insulating rod includes a second reinforcing material made of a metal material such as aluminum, and a second PVC part surrounding the outside of the second reinforcing material, and is configured to be filled with a second moisture absorbent; The first space sealed by the first non-metallic rod to separate the first glass and the third glass, and the second space sealed by the second non-metallic rod to separate the second glass and the third glass are argon To provide a triple-layer glass using a non-metallic rod of the same type, characterized in that it is filled with gas (Ar) or krypton gas (Kr).

However, in the case of Patent Document 1, there was a risk of leakage of argon gas or krypton gas, which are insulating gases, and thus there was a fear that the thermal management rate could not be maintained.

That is, there was a fear that the thermal insulation function may be lowered.

And, as shown in FIG. 1 , in the prior art, a heat insulating film 3 was attached to the glass 2 into the inside of the multilayer glass 1 .

However, in the case of the prior art, there was a fear that the insulating film 3 was wrinkled when attached, which could impair the aesthetics.

Patent Document 1: Domestic Registered Patent No. 10-1021866 (Registered on March 7, 2011)

Accordingly, the present invention is a double-layer glass with an improved insulation function that allows the UV-blocking insulation film to be installed tautly unlike the prior art so as not to impair the aesthetics while maintaining the thermal management rate semi-permanently with a UV-blocking insulating film instead of a conventional insulating gas and to a manufacturing method thereof.

In order to achieve the above object, the present invention provides a method for manufacturing double-layer glass, comprising: a first insulating rod having a center penetrating through it, a protrusion formed on one side of the edge, and a moisture absorbent filling the inner space of the thick portion; A first UV-blocking insulating film; and a second insulating interstitial rod having a center penetrating through and filled with a moisture absorbent in the inner space of the thick portion, and pressing the edge of the first UV-blocking insulating film with the second insulating interfering rod to obtain the first A pair of glass edges is attached to the outer surfaces of the first and second heat insulating rods that do not face each other on both sides of the first UV blocking heat insulating film while closely adhering to the heat insulating rod and the protrusion. The heat insulation function is improved, characterized in that the silicone finish is formed in the external space by bonding through each, and applying silicone to the external space formed between the edge of the first and second insulating rods and the edge of a pair of glass. An object of the present invention is to provide a multilayer glass manufacturing method and a multilayer glass manufactured by the multilayer glass manufacturing method.

Since the present invention uses a UV-blocking insulating film instead of a conventional insulating gas, there is an effect that the insulating gas does not need to be leaked and additional insulating gas filling due to leakage is not required.

In other words, the UV-blocking insulating film has the effect of blocking external radiant heat in summer and preventing cold air from entering in winter.

In other words, it is possible to maintain the thermal management rate semi-permanently compared to the conventional double-layer glass using the insulating gas, and at the same time, there is an effect of improving the insulating function.

In the present invention, since the edge of the UV-blocking insulating film is pulled outward by the coupling between the insulating rods, the UV-blocking insulating film is not crumpled and has the effect of being installed taut.

That is, there is an effect that does not impair the aesthetics.

In the present invention, even if the glass is broken, since the UV-blocking insulating film does not leak like the conventional insulating gas, there is an effect that the insulating function can be maintained as much as possible.

The present invention is effective in preventing various diseases, such as skin cancer, because the present invention blocks ultraviolet rays harmful to the human body with a UV-blocking insulating film.

The present invention has an effect of maximally preventing the scattering of glass fragments with a UV-blocking insulating film and a safety net when glass is broken.

The present invention has an effect of preventing theft because the safety net prevents outsiders from entering the room even if the glass is broken.

In the present invention, since a plurality of through-holes of the safety net are formed in a polygonal shape, there is an effect that various performances can be made between the glass.

In other words, it has the effect of maximizing the interior effect.

In the present invention, since the safety net supports the UV-blocking insulating film, there is an effect of keeping the UV-blocking insulating film taut so as not to be crumpled.

Since the present invention is made of 3 or 4 multi-layer glass using a light-weight UV-blocking insulating film, the weight and thickness are reduced compared to the conventional multi-layer glass made of 3 or 4 layers of glass.

That is, there is an effect of easy transport and installation.

The present invention has the effect of further improving the heat insulating function because the UV-blocking heat insulating film is further adhered to the inside of the glass of the double-layer glass.

In addition, when the glass is broken, there is an effect of further preventing the scattering of glass fragments with an additionally attached UV-blocking insulating film.

1 is an enlarged cross-sectional view of a conventional double-layer glass,
2 and 3 are front views of the first and second insulating interstitial bars of the multilayer glass according to the first embodiment of the present invention;
4 to 8 are diagrams of the manufacturing process of the multilayer glass according to the first embodiment of the present invention;
9 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the first embodiment of the present invention;
10 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the first embodiment of the present invention;
11 and 12 are front views of the first and second insulating interstitial bars of the double-layer glass according to the second embodiment of the present invention;
13 to 17 are diagrams of a manufacturing process of a multilayer glass according to a second embodiment of the present invention;
18 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the second embodiment of the present invention;
19 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the second embodiment of the present invention;
20 and 21 are front views of the first and second insulating interstitial bars of the multilayer glass according to the third embodiment of the present invention;
22 to 26 are diagrams of a manufacturing process of a multilayer glass according to a third embodiment of the present invention;
27 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the third embodiment of the present invention;
28 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the third embodiment of the present invention;
29 and 30 are front views of the first and second insulating interstitial bars of the multilayer glass according to the fourth embodiment of the present invention;
31 to 35 are diagrams of a manufacturing process of a multilayer glass according to a fourth embodiment of the present invention;
36 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the fourth embodiment of the present invention;
37 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the fourth embodiment of the present invention;
38 to 40 are front views of the first, second, and third heat-insulating bars of the multilayer glass according to the fifth embodiment of the present invention;
41 to 45 are diagrams of a manufacturing process of a multilayer glass according to a fifth embodiment of the present invention;
46 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the fifth embodiment of the present invention;
47 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the fifth embodiment of the present invention;
48 to 50 are front views of the first, second, and third heat-insulating bars of the multilayer glass according to the sixth embodiment of the present invention;
51 to 55 are diagrams of a manufacturing process of a multilayer glass according to a sixth embodiment of the present invention;
56 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the sixth embodiment of the present invention;
57 is an enlarged cross-sectional view of a laminated glass according to another embodiment of the sixth embodiment of the present invention.

Accordingly, various embodiments of the present invention as described above will be described in detail based on the accompanying drawings.

As shown in FIGS. 2 to 8, in the manufacture of the double-layer glass 1000 according to the first embodiment of the present invention included in the windows installed in buildings, the center is penetrated, and a protrusion 101 is formed on one side of the rim. is formed, and a first heat insulating rod 100 filled with a moisture absorbent 103 in the inner space 102 of the thick portion; and a first UV blocking heat insulating film 110; A second heat insulating rod 120 filled with a desiccant 122 is provided in the inner space 121 .

Here, the first and second heat insulating rods 100 and 120 are formed in the form of a square frame having a center penetrated therein, and are made of a non-ferrous metal material such as aluminum.

In addition, the protrusion 101 is formed to protrude long in the longitudinal direction from one side of the edge of the first insulating interstitial rod 100 .

In addition, the first UV-blocking insulating film 110 is manufactured by a sputtering method that continuously reflects heat.

And, by pressing the rim of the first UV-blocking insulating film 110 with the second insulating rod 120 to adhere to the first insulating insulating rod 100 and the protrusion 101, the first UV-blocking insulating film 110 to form a taut

That is, while in close contact with the first insulating insulating rod 100 and the protrusion 101 in a bent form of the edge of the first UV blocking insulating film 110 by the compression of the second insulating insulating rod 120, the first UV rays The edge of the blocking insulation film 110 is pulled outward, so that the first UV blocking insulation film 110 is formed taut.

In other words, as the second heat insulating bar 120 is inserted into the protrusion 101 of the first insulating bar 100 , the first UV blocking heat insulating film 110 is formed taut.

And, on the outer surfaces of the first and second heat insulating rods 100 and 120 that do not face each other on both sides of the first UV blocking heat insulating film 110, an adhesive member 131 is attached to the edge of a pair of glass 130 are attached to each other through

Here, an external space 141 is formed between the edges of the first and second heat insulating rods 100 and 120 and the edges of the pair of glasses 130 , and the adhesive member 131 is made of an adhesive or the like.

In addition, silicone is applied to the outer space 141 formed between the edges of the first and second insulating heat insulating rods 100 and 120 and the edges of the pair of glasses 130 , and the silicone is applied to the outer space 141 . A finishing part 140 is formed.

Then, the multilayer glass 1000 according to the first embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 103 and 122, and the first UV blocking insulating film 110 to block UV rays and heat inside and outside. inhibits movement.

And, in the manufacture of the multilayer glass 1000 according to another embodiment of the first embodiment of the present invention, as shown in FIG. 9, after further providing a second UV blocking insulating film 150, a pair of glass ( 130) to one of the adhesive members 151 through the adhesive.

Here, the second UV blocking insulating film 150 is adhered to one side of one glass 130 installed close to the outdoors through an adhesive member 151 .

In addition, the second UV blocking insulating film 150 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 151 is made of an adhesive or the like.

Then, a pair of glasses 130 are respectively positioned on both sides of the first and second heat insulating rods 100 and 120 that are first coupled to fix the first UV blocking heat insulating film 110 .

And, on the outer surfaces of the first and second heat insulating rods 100 and 120 that do not face each other on both sides of the first UV blocking heat insulating film 110, an adhesive member 131 is attached to the edge of a pair of glass 130 are attached to each other through

Here, the second UV-blocking insulating film 150 adhered to the single glass 130 is positioned between the pair of glasses 130 .

In addition, silicone is applied to the outer space 141 formed between the edges of the first and second insulating heat insulating rods 100 and 120 and the edges of the pair of glasses 130 , and the silicone is applied to the outer space 141 . A finishing part 140 is formed.

Then, the multilayer glass 1000 according to another embodiment of the first embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in buildings to further block UV rays with the first and second UV blocking insulating films 110 and 150, while further suppressing the movement of heat indoors and outdoors. .

And, as shown in FIG. 10, the manufacturing of the multilayer glass 1000 according to another embodiment of the first embodiment of the present invention further provides a safety net 160 having a plurality of through-holes 161 formed on the outer surface. After that, it is sandwiched between the first and second heat insulating rods 100 and 120 together with the first UV blocking heat insulating film 110 .

Here, the safety net 160 supports the first UV-blocking insulating film 110 .

Also, the through hole 161 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and second heat insulating rods 100 and 120 that do not face each other on both sides of the first UV blocking heat insulating film 110, an adhesive member 131 is attached to the edge of a pair of glass 130 are attached to each other through

Here, the second UV blocking insulating film 150 may be adhered to one of the pair of glasses 130 through an adhesive member 151 to be positioned between the pair of glasses 130 .

In addition, silicone is applied to the outer space 141 formed between the edges of the first and second insulating heat insulating rods 100 and 120 and the edges of the pair of glasses 130 , and the silicone is applied to the outer space 141 . A finishing part 140 is formed.

Then, the multilayer glass 1000 according to another embodiment of the first embodiment of the present invention is completed.

Thus, the double-glazed glass 1000 is included in the windows installed in the building, and when the glass 130 is damaged, the safety net 160 prevents an outsider from entering the room.

And, in the manufacture of the multilayer glass 1000 according to the second embodiment of the present invention, as shown in FIGS. 11 to 17, the center is penetrated, and a fitting groove 201 is formed on one side of the edge, A first heat insulating rod 200 filled with a moisture absorbent 203 in the inner space 202 of the thick portion; A first UV blocking heat insulating film 210; The center is penetrated, and a fitting part on one side of the edge A 221 is formed, and a second heat insulating rod 220 filled with a desiccant 223 is provided in the inner space 222 of the thick portion.

Here, the first and second heat insulating rods 200 and 220 are formed in the form of a square frame through which the center is penetrated, and are made of a non-ferrous metal material such as aluminum.

In addition, the fitting groove 201 is formed elongated in the longitudinal direction on one side of the edge of the first insulating interbar 200, and the fitting part 221 has a length from one side of the edge of the second insulating interbar 220. It is formed to protrude long along the direction.

In addition, the first UV-blocking insulating film 210 is manufactured by a sputtering method that continuously reflects heat.

Then, by pressing the edge of the first UV-blocking insulating film 210 with the fitting portion 221 of the second heat insulating rod 220 and inserting it into the fitting groove 201, it is closely attached to the first heat insulating bar 200 and the The first UV blocking heat insulating film 210 is tightly formed.

That is, by pressing the fitting portion 221 of the second heat-insulating bar 220, the edge of the first UV-blocking heat-insulating film 210 is inserted into the fitting groove 201 in a bent form while the first heat-insulating bar 200 is pressed. is in close contact with, and the edge of the first UV-blocking insulating film 210 is pulled outward, so that the first UV-blocking insulating film 210 is taut.

In other words, the first UV-blocking insulating film 210 is formed taut as the inclined portion 221 of the second insulating interlayer 220 is fitted into the fitting groove 201 of the first insulating interlocking rod 200 .

And, on the outer surfaces of the first and second heat insulating rods 200 and 220 that do not face each other on both sides of the first UV blocking heat insulating film 210, an adhesive member 231 is attached to the edge of a pair of glass 230. are attached to each other through

Here, an external space 241 is formed between the edges of the first and second heat insulating rods 200 and 220 and the edges of the pair of glasses 230 , and the adhesive member 231 is made of an adhesive or the like.

Then, silicone is applied to the outer space 241 formed between the edges of the first and second insulating interstitial rods 200 and 220 and the edges of the pair of glasses 230, and the silicone is applied to the outer space 241. A finish portion 240 is formed.

Then, the multilayer glass 1000 according to the second embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 203 and 223, and the first UV blocking insulating film 210 to block UV rays and heat inside and outside. inhibits movement.

And, in the manufacture of the multilayer glass 1000 according to another embodiment of the second embodiment of the present invention, as shown in FIG. 18, after further providing a second UV blocking insulating film 250, a pair of glass ( 230) is adhered to one of the adhesive members 251.

Here, the second UV-blocking insulating film 250 is adhered to one side of a single glass 230 installed close to the outdoors through an adhesive member 251 .

In addition, the second UV blocking insulating film 250 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 251 is made of an adhesive or the like.

Then, a pair of glasses 230 are respectively positioned on both sides of the first and second heat insulating rods 200 and 220 that are first coupled to fix the first UV blocking insulating film 210 .

And, on the outer surfaces of the first and second heat insulating rods 200 and 220 that do not face each other on both sides of the first UV blocking heat insulating film 210, an adhesive member 231 is attached to the edge of a pair of glass 230. are attached to each other through

Here, the second UV-blocking insulating film 250 adhered to the single glass 230 is positioned between the pair of glasses 230 .

Then, silicone is applied to the outer space 241 formed between the edges of the first and second insulating interstitial rods 200 and 220 and the edges of the pair of glasses 230, and the silicone is applied to the outer space 241. A finish portion 240 is formed.

Then, the multilayer glass 1000 according to another embodiment of the second embodiment of the present invention is completed.

Therefore, the double-layer glass 1000 is included in the windows installed in the building to further block UV rays with the first and second UV blocking insulating films 210 and 250, and further suppress the movement of heat indoors and outdoors. .

And, as shown in FIG. 19, the manufacturing of the double-layer glass 1000 according to another embodiment of the second embodiment of the present invention further provides a safety net 260 having a plurality of through-holes 261 formed on the outer surface. After that, it is sandwiched between the first and second heat insulating rods 200 and 220 together with the first UV blocking heat insulating film 210 .

Here, the safety net 260 supports the first UV-blocking insulating film 210 .

In addition, the through hole 261 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and second heat insulating rods 200 and 220 that do not face each other on both sides of the first UV blocking heat insulating film 210, an adhesive member 231 is attached to the edge of a pair of glass 230. are attached to each other through

Here, the second UV blocking insulating film 250 may be adhered to one of the pair of glasses 230 through an adhesive member 251 so as to be positioned between the pair of glasses 230 .

Then, silicone is applied to the outer space 241 formed between the edges of the first and second insulating interstitial rods 200 and 220 and the edges of the pair of glasses 230, and the silicone is applied to the outer space 241. A finish portion 240 is formed.

Then, the multilayer glass 1000 according to another embodiment of the second embodiment of the present invention is completed.

Therefore, the double-layer glass 1000 is included in the windows installed in the building, and when the glass 230 is damaged, the safety net 260 prevents an outsider from entering the room.

And, the manufacturing of the multilayer glass 100 according to the third embodiment of the present invention, as shown in Figs. 20 to 26, the center is penetrated, the first and second internal spaces 301 divided into the thickness portion. As the 302 is formed, one side of the second inner space 302 is opened, and the first heat insulating rod 300 filled with a desiccant 303 in the first inner space 301; (310) and;, the center is penetrated, the fitting part 321 is formed on one side of the edge, and the second insulating interstitial rod 320 filled with the desiccant 323 in the inner space 322 of the thick part is provided. do.

Here, the first and second heat insulating rods 300 and 320 are formed in the form of a square frame through which the center is penetrated, and are made of a non-ferrous metal material such as aluminum.

In addition, as one side of the second inner space 302 is opened, a long hole is formed in one side of the edge of the first insulating interleaving rod 300 in the longitudinal direction, and the fitting portion 321 is the second insulating interleaving rod 320 . ) is formed to protrude long along the longitudinal direction from one side of the edge.

In addition, the first UV blocking insulating film 310 is manufactured by a sputtering method that continuously reflects heat.

Then, the first insulating interlocking rod ( 300) and a portion of the inner surface of the second inner space 302 to form the first UV blocking heat insulating film 310 taut.

That is, by pressing the fitting portion 321 of the second heat-insulating rod 320, the edge of the first UV-blocking heat-insulating film 310 is bent in the form of being inserted into the open side of the second inner space 302, and The first heat insulating rod 300 and a part of the inner surface of the second inner space 302 are in close contact, and the rim of the first UV blocking insulating film 310 is pulled outward, and the first UV blocking insulating film 310 . is tightly formed.

In other words, as the fitting portion 321 of the second heat-insulating bar 320 is fitted into the open side of the second inner space 302 of the first heat-insulating bar 300, the first UV-blocking insulating film 310 is formed. formed taut.

And, on the outer surfaces of the first and second heat insulating rods 300 and 320 that do not face each other on both sides of the first UV blocking insulating film 310, an adhesive member 331 is attached to the edge of a pair of glass 330. are attached to each other through

Here, an external space 341 is formed between the edges of the first and second heat insulating rods 300 and 320 and the edges of the pair of glasses 330 , and the adhesive member 331 is made of an adhesive or the like.

Then, silicone is applied to the outer space 341 formed between the edges of the first and second heat insulating rods 300 and 320 and the edges of the pair of glasses 330, so that the outer space 341 is filled with silicone. A finishing part 340 is formed.

Then, the multilayer glass 1000 according to the third embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 303 and 323, and the first UV blocking insulating film 310 to block UV rays and heat inside and outside. inhibits movement.

And, in the manufacture of the multilayer glass 1000 according to another embodiment of the third embodiment of the present invention, as shown in FIG. 27, after further providing a second UV blocking insulating film 350, a pair of glass ( 330) is adhered to one of the adhesive members 351 through the adhesive member 351.

Here, the second UV-blocking insulating film 350 is adhered to one side of a single glass 330 installed close to the outdoors through an adhesive member 351 .

In addition, the second UV blocking insulating film 350 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 351 is made of an adhesive or the like.

Then, a pair of glasses 330 are respectively positioned on both sides of the first and second heat insulating rods 300 and 320 that are first coupled to fix the first UV blocking insulating film 310 .

And, on the outer surfaces of the first and second heat insulating rods 300 and 320 that do not face each other on both sides of the first UV blocking insulating film 310, an adhesive member 331 is attached to the edge of a pair of glass 330. are attached to each other through

Here, the second UV-blocking insulating film 350 adhered to the single glass 330 is positioned between the pair of glasses 330 .

Then, silicone is applied to the outer space 341 formed between the edges of the first and second heat insulating rods 300 and 320 and the edges of the pair of glasses 330, so that the outer space 341 is filled with silicone. A finishing part 340 is formed.

Then, the multilayer glass 1000 according to another embodiment of the third embodiment of the present invention is completed.

Therefore, the double-layer glass 1000 is included in the windows installed in the building to further block UV rays with the first and second UV blocking insulating films 310 and 350, and further suppress the movement of heat indoors and outdoors. .

And, as shown in FIG. 28, the manufacturing of the multilayer glass 1000 according to another embodiment of the third embodiment of the present invention further provides a safety net 360 having a plurality of through holes 361 formed on the outer surface. After that, it is sandwiched between the first and second heat insulating rods 300 and 320 together with the first UV blocking heat insulating film 310 .

Here, the safety net 360 supports the first UV-blocking insulating film 310 .

Also, the through hole 361 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and second heat insulating rods 300 and 320 that do not face each other on both sides of the first UV blocking insulating film 310, an adhesive member 331 is attached to the edge of a pair of glass 330. are attached to each other through

Here, the second UV blocking insulating film 350 may be adhered to one of the pair of glasses 330 through an adhesive member 351 so as to be positioned between the pair of glasses 330 .

Then, silicone is applied to the outer space 341 formed between the edges of the first and second heat insulating rods 300 and 320 and the edges of the pair of glasses 330, so that the outer space 341 is filled with silicone. A finishing part 340 is formed.

Then, the multilayer glass 1000 according to another embodiment of the third embodiment of the present invention is completed.

Therefore, the double-glazed glass 1000 is included in the windows installed in the building, and when the glass 330 is damaged, the safety net 360 prevents outsiders from entering the room.

And, in the manufacture of the multilayer glass 1000 according to the fourth embodiment of the present invention, as shown in FIGS. 29 to 35, the center is penetrated, and a protrusion 401 is formed on one side of the rim, and the thickness A pair of first heat-insulating rods 400 filled with a desiccant 403 in the inner space 402 of the portion; and the center is penetrated and the inner space 411 of the thick portion is filled with the desiccant 412 Two heat insulating rods 410 and; and a pair of first UV blocking insulating films 420 are provided.

Here, the first and second heat insulating rods 400 and 410 are formed in the form of a square frame through which the center is penetrated, and are made of a non-ferrous metal material such as aluminum.

In addition, the protrusion 401 is formed to protrude long in the longitudinal direction from one side of the edge of the first insulating interlocking rod 400 .

In addition, the first UV-blocking insulating film 420 is manufactured by a sputtering method that continuously reflects heat.

And, by pressing the edge of one first UV-blocking insulating film 420 with one of the first insulating rods 400 and adhering to the remaining first insulating insulating rods 400 and the protrusion 401, the first UV-blocking The heat insulating film 420 is formed taut, and the edge of the remaining first UV blocking heat insulating film 420 is pressed with the second heat insulating bar 410 to be adjacent to the first heat insulating bar 400 and the protrusion 401. While closely adhering, the first UV blocking heat insulating film 420 is taut.

That is, the edge of the first UV blocking insulating film 420 is bent by the compression of the one first insulating rod 400 while in close contact with the remaining first insulating insulating rod 400 and the protrusion 401 . , the edge of the first UV blocking insulating film 420 is pulled outward, so that the first UV blocking insulating film 420 is formed taut.

In addition, by pressing the second heat insulating rod 410, the edge of the remaining first UV blocking insulating film 420 is in close contact with the adjacent first heat insulating rod 400 and the protrusion 401 in a bent form, the The edge of the first UV blocking heat insulating film 420 is pulled outward, so that the first UV blocking heat insulating film 420 is formed taut.

In other words, the remaining first insulated rod 400 is fitted inside the protrusion 401 of the one first insulated rod 400 , and the second insulated protrusion 401 of the remaining first insulated rod 400 is inserted into the inside of the protrusion 401 . As the heat insulating rod 410 is fitted, a pair of first UV blocking heat insulating films 420 are tightly formed.

And, on the outer surfaces of the first and second heat insulating rods 400 and 410 that do not face each other on both sides of the pair of the first UV blocking insulating film 420, the edges of the pair of glass 430 are attached to the adhesive member ( 431), respectively.

Here, an external space 441 is formed between the rims of the pair of first and second insulating insulating rods 400 and 410 and the rims of the pair of glass 430 , and an adhesive member 431 . is made of an adhesive or the like.

In addition, silicone is applied to the outer space 441 formed between the rim of the pair of first and second insulating insulating rods 400 and 410 and the rim of the pair of glass 430, so that the outside A silicone finish 440 is formed in the space 441 .

Then, the multilayer glass 1000 according to the fourth embodiment of the present invention is completed.

So, the double-glazed glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 403 and 412, and the first UV blocking insulation film 420 to block UV rays and heat indoors and out. inhibits movement.

And, as shown in FIG. 36, in the manufacture of the multilayer glass 1000 according to another embodiment of the fourth embodiment of the present invention, after further providing a second UV blocking heat insulating film 450, a pair of glass ( 430) is adhered to one of the adhesive members 451.

Here, the second UV-blocking insulating film 450 is adhered to one side of a single glass 430 installed close to the outdoors through an adhesive member 451 .

In addition, the second UV blocking insulating film 450 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 451 is made of an adhesive or the like.

Then, a pair of glasses 430 are respectively positioned on both sides of the first and second heat insulating rods 400 and 410 that are first coupled to fix the pair of first UV blocking insulating films 420 .

And, on the outer surfaces of the first and second heat insulating rods 400 and 410 that do not face each other on both sides of the pair of the first UV blocking insulating film 420, the edges of the pair of glass 430 are attached to the adhesive member ( 431), respectively.

Here, the second UV-blocking insulating film 450 adhered to the single glass 430 is positioned between the pair of glasses 430 .

In addition, silicone is applied to the outer space 441 formed between the rim of the pair of first insulating insulating rods 400 and the second insulating insulating rod 410 and the rim of the pair of glass 430, A silicone finish 440 is formed in the space 441 .

Then, the multilayer glass 1000 according to another embodiment of the fourth embodiment of the present invention is completed.

Therefore, the double-layer glass 1000 is included in the windows installed in the building to further block UV rays with the first and second UV blocking insulating films 420 and 450, and further inhibit the movement of heat indoors and outdoors. .

And, as shown in FIG. 37 , in the manufacture of the multilayer glass 1000 according to another embodiment of the fourth embodiment of the present invention, a pair of safety nets 460 having a plurality of through holes 461 formed on the outer surface thereof. After providing more, between the pair of the first insulating interlocking rod 400, and between the second insulating interstitial rod 410 and the first insulating interfering rod 400 adjacent to the second insulating interstitial rod 410, a pair Inserted together with the first UV-blocking insulating film 420 of the.

Here, the safety net 460 supports the first UV-blocking insulating film 420 .

Also, the through hole 461 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and second heat insulating rods 400 and 410 that do not face each other on both sides of the pair of the first UV blocking insulating film 420, the edges of the pair of glass 430 are attached to the adhesive member ( 431), respectively.

Here, the second UV blocking insulating film 450 may be adhered to one of the pair of glasses 430 through an adhesive member 451 so as to be positioned between the pair of glasses 430 .

In addition, silicone is applied to the outer space 441 formed between the rim of the pair of first insulating insulating rods 400 and the second insulating insulating rod 410 and the rim of the pair of glass 430, A silicone finish 440 is formed in the space 441 .

Then, the multilayer glass 1000 according to another embodiment of the fourth embodiment of the present invention is completed.

Therefore, the double-glazed glass 1000 is included in the windows installed in the building, and when the glass 430 is damaged, the safety net 460 prevents outsiders from entering the room.

And, in the manufacture of the multilayer glass 1000 according to the fifth embodiment of the present invention, as shown in FIGS. 38 to 45, the center is penetrated, and a fitting groove 501 is formed on one side of the edge, A first heat insulating rod 500 filled with a moisture absorbent 503 in the inner space 502 of the thick portion; the center is penetrated and a fitting portion 511 is formed on one side of the rim, the other side of the rim A fitting groove 512 is formed on the surface, and a second heat insulating interstitial rod 510 filled with a moisture absorbent 514 in the inner space 513 of the thick portion; and the center is penetrated and the fitting portion is on one side of the edge ( 521) is formed, and a third heat insulating rod 520 filled with a moisture absorbent 523 in the inner space 522 of the thick portion; and a pair of first UV blocking heat insulating films 530 are provided.

Here, the first, second, and third insulated rods 500, 510, and 520 are formed in the form of a square frame having a center penetrated therein, and are made of a non-ferrous metal material such as aluminum.

In addition, the fitting groove 501 is formed to be long in the longitudinal direction on one side of the edge of the first insulating inter-bar (500).

In addition, the fitting portion 511 is formed to protrude long along the longitudinal direction from one side of the edge of the second heat insulating rod 510 , and the fitting groove 512 is opposite to the edge of the second heat insulating bar 510 . It is formed long in the longitudinal direction on the surface.

In addition, the fitting portion 521 is formed to protrude long along the longitudinal direction from one side of the edge of the third heat insulating rod 520 .

In addition, the first UV-blocking insulating film 530 is manufactured by a sputtering method that continuously reflects heat.

Then, by pressing the edge of the first UV-blocking insulating film 530 with the fitting part 511 of the second heat insulating rod 510 and inserting it into the fitting groove 501, it is in close contact with the first heat insulating bar 500 . to form the first UV-blocking insulating film 530 taut, and pressing the edge of the remaining first UV-blocking insulating film 530 with the fitting part 521 of the third heat-insulating rod 520 to form a fitting groove ( 512) while being in close contact with the second heat insulating rod 510 to form the first UV blocking heat insulating film 530 taut.

That is, by pressing the fitting portion 511 of the second heat insulating rod 510, the edge of one first UV blocking heat insulating film 530 is inserted into the fitting groove 501 in a bent form, and the first heat insulation bar ( 500), and the edge of the first UV-blocking insulating film 530 is pulled outward, so that the first UV-blocking insulating film 530 is taut.

In addition, by pressing the fitting portion 521 of the third heat insulating rod 520, the edge of the remaining first UV blocking heat insulating film 530 is inserted into the fitting groove 512 in a bent form, while the second heat insulating bar 510 is pressed. ), and the edge of the first UV-blocking insulating film 530 is pulled outward, so that the first UV-blocking insulating film 530 is taut.

In other words, the inclined portion 511 of the second insulating interlocking rod 510 is fitted into the fitting groove 501 of the first insulating interlocking rod 500 , and the fitting groove 512 of the second insulating interleaving rod 510 is inserted As the fitting portion 521 of the third heat insulating rod 520 is fitted, a pair of first UV blocking heat insulating films 530 are tightly formed.

And, on the outer surfaces of the first and third heat insulating rods 500 and 520 that do not face each other on both sides of the pair of first UV blocking insulating films 530, the edges of the pair of glasses 540 are attached to the adhesive member ( 541), respectively.

Here, an external space 551 is formed between the edges of the first, second, and third heat insulating rods 500 , 510 and 520 and the edges of the pair of glasses 540 , and the adhesive member 541 is made of adhesives, etc.

In addition, silicone is applied to the outer space 551 formed between the edges of the first, second, and third insulating rods 500 , 510 , and 520 and the edges of a pair of glass 540 , and the external space A silicone finish 550 is formed at 551 .

Then, the multilayer glass 1000 according to the fifth embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 503, 514, 523, and the first UV blocking insulating film 530 to block UV rays and indoor, It inhibits heat transfer to the outside.

And, in the manufacture of the multilayer glass 1000 according to another embodiment of the fifth embodiment of the present invention, as shown in FIG. 46, after further providing a second UV blocking insulating film 560, a pair of glass ( 540) is adhered to one of the adhesive members 561.

Here, the second UV blocking heat insulating film 560 is adhered to one side of one glass 540 installed close to the outdoors through an adhesive member 561 .

In addition, the second UV-blocking insulating film 560 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 561 is made of an adhesive or the like.

Then, a pair of glasses 540 on both sides of the first, first, and third heat insulating rods 500, 510 and 520 that are first coupled to fix the pair of the first UV blocking insulating films 530, respectively place it

And, on the outer surfaces of the first and third heat insulating rods 500 and 520 that do not face each other on both sides of the pair of first UV blocking insulating films 530, the edges of the pair of glasses 540 are attached to the adhesive member ( 541), respectively.

Here, the second UV-blocking insulating film 560 adhered to the single glass 540 is positioned between the pair of glasses 540 .

In addition, silicone is applied to the outer space 551 formed between the edges of the first, second, and third insulating rods 500 , 510 , and 520 and the edges of a pair of glass 540 , and the external space A silicone finish 550 is formed at 551 .

Then, the multilayer glass 1000 according to another embodiment of the fifth embodiment of the present invention is completed.

Therefore, the double-layer glass 1000 is included in the windows installed in the building to further block UV rays with the first and second UV blocking heat insulating films 530 and 560, while further suppressing the movement of heat indoors and outdoors. .

And, as shown in FIG. 47, in the manufacture of the multilayer glass 1000 according to another embodiment of the fifth embodiment of the present invention, a pair of safety nets 570 having a plurality of through holes 571 formed on the outer surface thereof. After providing more, between the first and second heat insulating rods 500 and 510, and between the second and third insulating rods 510 and 520 together with a pair of first UV-blocking insulating films 530, respectively insert

Here, the safety net 570 supports the first UV-blocking insulating film 530 .

In addition, the through hole 571 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and third heat insulating rods 500 and 520 that do not face each other on both sides of the pair of first UV blocking insulating films 530, the edges of the pair of glasses 540 are attached to the adhesive member ( 541), respectively.

Here, the second UV blocking insulating film 560 may be adhered to one of the pair of glasses 540 through an adhesive member 561 so as to be positioned between the pair of glasses 540 .

In addition, silicone is applied to the outer space 551 formed between the edges of the first, second, and third insulating rods 500 , 510 , and 520 and the edges of a pair of glass 540 , and the external space A silicone finish 550 is formed at 551 .

Then, the multilayer glass 1000 according to another embodiment of the fifth embodiment of the present invention is completed.

Therefore, the double-glazed glass 1000 is included in the windows installed in the building, and when the glass 540 is damaged, the safety net 570 prevents outsiders from entering the room.

And, the manufacturing of the multilayer glass 1000 according to the sixth embodiment of the present invention, as shown in FIGS. 48 to 55, the center is penetrated, the first and second internal spaces 601 divided into the thickness portion. As the 602 is formed, one side of the second inner space 602 is opened, and the first heat insulating rod 600 filled with a desiccant 603 in the first inner space 601; As the first and second internal spaces 611 and 612 divided into the parts are formed, one side of the second internal space 612 is opened, and the first internal space 611 is filled with a desiccant 613, and A second heat-insulating rod 610 having a fitting portion 614 formed on one side thereof; a center is penetrated, a fitting portion 621 is formed on one side of the edge, and a desiccant ( 623) is filled with a third heat insulating rod 620; and; and a pair of first UV blocking heat insulating films 630 are provided.

Here, the first, second, and third insulating interstitial rods 600, 610, and 620 are formed in the form of a square frame having a center penetrated therein, and are made of a non-ferrous metal material such as aluminum.

In addition, as one side of the second internal space 602 is opened, a hole having a length in the longitudinal direction is formed on one side of the edge of the first insulating interlocking rod 600 .

In addition, the fitting portion 614 is formed to protrude long along the longitudinal direction from one side of the edge of the second insulating interlocking rod 610, and one side of the second internal space 612 is opened while the second insulating interstitial rod ( 610), a long hole in the longitudinal direction is formed on one side opposite to the edge.

In addition, the fitting portion 621 is formed to protrude long along the longitudinal direction from one side of the edge of the third heat insulating rod 620 .

In addition, the first UV-blocking insulating film 630 is manufactured by a sputtering method that continuously reflects heat.

Then, by pressing the edge of one first UV blocking heat insulating film 630 with the fitting portion 614 of the second heat insulating rod 610, the first heat insulating The first UV-blocking insulating film 630 is tightly formed by closely adhering to the inner surface of the interstitial rod 600 and the second inner space 602, and the fitting portion 621 of the third insulating interstitial rod 620 is used. By pressing the edge of the remaining first UV-blocking insulating film 630 and sandwiching it in the open side of the second inner space 612, the second heat insulating rod 610 and the inner portion of the second inner space 612 are in close contact with each other. to form the first UV-blocking insulating film 630 taut.

That is, by pressing the fitting portion 614 of the second heat insulating rod 610, the edge of the first UV blocking heat insulating film 630 is bent in the form of being inserted into the open side of the second inner space 602. While being in close contact with a portion of the inner surface of the first heat insulating rod 600 and the second inner space 602, the edge of the first UV blocking insulating film 630 is pulled outward, so that the first UV blocking insulating film ( 630) is formed taut.

In addition, by pressing the fitting portion 621 of the third heat-insulating rod 620, the edge of the remaining first UV-blocking heat-insulating film 630 is bent in a bent form while being inserted into the open side of the second inner space 612. The second heat insulating rod 610 and a portion of the inner surface of the second inner space 612 are closely attached, and the edge of the first UV blocking heat insulating film 630 is pulled outward, and the first UV blocking heat insulating film 630 is ) is tightly formed.

In other words, the fitting portion 614 of the second heat insulating interrode 610 is fitted to one open side of the second inner space 602 of the first insulating interlocking rod 600 , and the As the fitting portion 621 of the third heat insulating rod 620 is fitted to one open side of the second inner space 612, a pair of first UV blocking heat insulating films 630 are formed taut.

And, on the outer surfaces of the first and third heat insulating rods 600 and 620 that do not face each other on both sides of the pair of the first UV blocking insulating film 630, the edges of the pair of glass 640 are attached to the adhesive member ( 641), respectively.

Here, an external space 651 is formed between the edges of the first, second, and third heat insulating rods 600, 610 and 620 and the edges of the pair of glass 640, and the adhesive member 641 is made of adhesives, etc.

In addition, silicone is applied to the outer space 651 formed between the edges of the first, second, and third insulating rods 600 , 610 , and 620 and the edges of a pair of glass 640 , and the external space A silicone finish 650 is formed at 651 .

Then, the multilayer glass 1000 according to the sixth embodiment of the present invention is completed.

So, the double-layer glass 1000 is included in the windows installed in the building to block the inflow of moisture with the desiccant 603, 613, 623, and the first UV blocking insulation film 630 to block UV rays and indoor, It inhibits heat transfer to the outside.

And, in the manufacture of the multilayer glass 1000 according to another embodiment of the sixth embodiment of the present invention, as shown in FIG. 56, after further providing a second UV blocking insulating film 660, a pair of glass ( 640) is adhered to one of the adhesive members 661.

Here, the second UV-blocking insulating film 660 is adhered to one side of one glass 640 installed close to the outdoors through an adhesive member 661 .

In addition, the second UV blocking insulating film 660 is manufactured by a sputtering method that continuously reflects heat, and the adhesive member 661 is made of an adhesive or the like.

Then, a pair of glass 640 on both sides of the first, first, second, and third heat insulating rods 600, 610 and 620 that are first coupled to fix the first UV blocking insulating film 630, respectively. place it

And, on the outer surfaces of the first and third heat insulating rods 600 and 620 that do not face each other on both sides of the pair of the first UV blocking insulating film 630, the edges of the pair of glass 640 are attached to the adhesive member ( 641), respectively.

Here, the second UV-blocking insulating film 660 adhered to the single glass 640 is positioned between the pair of glasses 640 .

In addition, silicone is applied to the outer space 651 formed between the edges of the first, second, and third insulating rods 600 , 610 , and 620 and the edges of a pair of glass 640 , and the external space A silicone finish 650 is formed at 651 .

Then, the multilayer glass 1000 according to another embodiment of the sixth embodiment of the present invention is completed.

Thus, the double-glazed glass 1000 is included in the windows installed in buildings to further block UV rays with the first and second UV blocking insulating films 630 and 660, while further suppressing the movement of heat indoors and outdoors. .

And, as shown in FIG. 57, in the manufacture of the multilayer glass 1000 according to another embodiment of the sixth embodiment of the present invention, a pair of safety nets 670 having a plurality of through holes 671 formed on the outer surface thereof. After further providing, between the first and second heat insulating rods 600 and 610, and between the second and third heat insulating rods 610 and 620, respectively, together with a pair of first UV blocking insulating films 630 insert

Here, the safety net 670 supports the first UV-blocking insulating film 630 .

Also, the through hole 671 is formed in a polygonal shape such as a triangle, a square, or a hexagon.

And, on the outer surfaces of the first and third heat insulating rods 600 and 620 that do not face each other on both sides of the pair of the first UV blocking insulating film 630, the edges of the pair of glass 640 are attached to the adhesive member ( 641), respectively.

Here, the second UV blocking insulating film 660 may be adhered to one of the pair of glasses 640 through an adhesive member 661 to be positioned between the pair of glasses 640 .

In addition, silicone is applied to the outer space 651 formed between the edges of the first, second, and third insulating rods 600 , 610 , and 620 and the edges of a pair of glass 640 , and the external space A silicone finish 650 is formed at 651 .

Then, the multilayer glass 1000 according to another embodiment of the sixth embodiment of the present invention is completed.

Therefore, the double-glazed glass 1000 is included in the windows installed in the building, and when the glass 640 is damaged, the safety net 670 prevents outsiders from entering the room.

In the above, the present invention has been illustrated and described with reference to specific preferred embodiments, but the present invention is not limited to the above-described embodiments, and common knowledge in the technical field to which the invention pertains within the scope not departing from the spirit of the present invention Various changes and modifications will be possible by the possessor.

100: first insulating interstitial rod 101: protrusion
102: interior space 103: desiccant
110: first UV-blocking insulating film 120: second insulating rod
121: interior space 122: desiccant
130: glass 131: adhesive member
140: silicone finish 141: external space
150: second UV-blocking insulating film 151: adhesive member
160: safety net 161: through hole
200: first insulating interlocking rod 201: fitting groove
202: interior space 203: desiccant
210: first UV-blocking insulating film 220: second insulating rod
221: fitting part 222: internal space
223: desiccant 230: glass
231: adhesive member 240: silicone finish
241: external space 250: second UV-blocking insulating film
251: adhesive member 260: safety net
261: through hole 300: first heat insulating rod
301: first internal space 302: second internal space
303: moisture absorbent 310: first UV-blocking insulating film
320: second insulating interstitial bar 321: fitting part
322: interior space 323: desiccant
330: glass 331: adhesive member
340: silicone finish 341: external space
350: second UV-blocking insulating film 351: adhesive member
360: safety net 361: through hole
400: first heat insulating rod 401: protrusion
402: interior space 403: desiccant
410: second insulating interstitial rod 411: internal space
412: moisture absorbent 420: first UV-blocking insulating film
430: glass 431: adhesive member
440: silicone finish 441: external space
450: second UV-blocking insulating film 451: adhesive member
460: safety net 461: through hole
500: first insulating interbar 501: fitting groove
502: interior space 503: desiccant
510: second insulating interbar 511: fitting part
512: fitting groove 513: internal space
514: desiccant 520: third heat insulating rod
521: fitting part 522: internal space
523: moisture absorbent 530: first UV-blocking insulating film
540: glass 541: adhesive member
550: silicone finish 551: external space
560: second UV-blocking insulating film 561: adhesive member
570: safety net 571: through hole
600: first insulating interstitial rod 601: first internal space
602: second inner space 603: moisture absorbent
610: second insulating interstitial rod 611: first internal space
612: second inner space 613: desiccant
614: fitting part 620: third heat insulating rod
621: fitting part 622: internal space
623: moisture absorbent 630: first UV-blocking insulating film
640: glass 641: adhesive member
650: silicone finish 651: external space
660: second UV-blocking insulating film 661: adhesive member
670: safety net 671: through hole
1000: double-layer glass

Claims (30)

In the method for manufacturing double-layer glass,
The center is penetrated, the protrusion 101 is formed on one side of the edge, and the first heat insulating rod 100 filled with the moisture absorbent 103 in the inner space 102 of the thick portion; and the first UV blocking heat insulating film (110) and;, a second heat insulating rod 120 through which the center is penetrated and filled with a desiccant 122 in the inner space 121 of the thick portion,
By pressing the edge of the first UV-blocking insulating film 110 with the second insulating rod 120 to adhere to the first insulating insulating rod 100 and the protrusion 101, the first UV-blocking insulating film 110 is taut to form,
The edges of the pair of glass 130 on the outer surfaces of the first and second heat insulating rods 100 and 120 that do not face each other on both sides of the first UV blocking heat insulating film 110 are respectively attached through the adhesive member 131 . glued,
Silicone is applied to the outer space 141 formed between the edges of the first and second heat insulating rods 100 and 120 and the edges of the pair of glasses 130, so that the silicone finish part in the outer space 141 (140) A method of manufacturing double-layer glass with improved heat insulation, characterized in that it forms. According to claim 1,
A heat insulating function characterized in that the second UV blocking insulating film 150 is attached to one of the pair of glasses 130 through an adhesive member 151 so as to be positioned between the pair of glasses 130 . An improved method for manufacturing double-layer glass. According to claim 1,
A method of manufacturing double-layer glass with improved heat insulation function, characterized in that a safety net (160) having a plurality of through-holes (161) formed on the outer surface is sandwiched between the first and second heat insulating rods (100) (120). 4. The method of claim 3,
The through-hole 161 is a method of manufacturing double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. [Claim 5] Multi-layer glass with improved thermal insulation function manufactured by the method for manufacturing the multi-layer glass of any one of claims 1 to 4. In the method for manufacturing double-layer glass,
The center is penetrated, the fitting groove 201 is formed on one side of the edge, and the first heat insulating rod 200 filled with the moisture absorbent 203 in the inner space 202 of the thick part; The film 210 and;, the second insulating interstitial rod 220, the center is penetrated, the fitting portion 221 is formed on one side of the edge, and the moisture absorbent 223 is filled in the inner space 222 of the thick portion. prepare,
By pressing the edge of the first UV-blocking insulating film 210 with the fitting portion 221 of the second heat insulating rod 220 and inserting it into the fitting groove 201, it is closely attached to the first heat insulating bar 200 to make the first Forming the UV-blocking insulating film 210 taut,
On the outer surfaces of the first and second heat insulating rods 200 and 220 that do not face each other on both sides of the first UV blocking heat insulating film 210, the edges of a pair of glass 230 are attached to each other through an adhesive member 231. glued,
Silicone is applied to the outer space 241 formed between the rims of the first and second heat insulating rods 200 and 220 and the rims of the pair of glasses 230 to provide a silicone finish to the outer space 241. (240) A method of manufacturing double-layer glass with improved heat insulation, characterized in that it forms. 7. The method of claim 6,
Insulation function characterized in that the second UV blocking heat insulating film 250 is attached to one of the pair of glasses 230 through an adhesive member 251 so as to be positioned between the pair of glasses 230 . An improved method for manufacturing double-layer glass. 7. The method of claim 6
A method of manufacturing double-layer glass with improved heat insulation function, characterized in that a safety net (260) having a plurality of through-holes (261) formed on the outer surface is sandwiched between the first and second heat insulating rods (200, 220). 9. The method of claim 8,
The through-hole 261 is a method of manufacturing double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. [10] The laminated glass with improved heat insulation function manufactured by the method for manufacturing the laminated glass according to any one of claims 6 to 9. In the method for manufacturing double-layer glass,
One side of the second internal space 302 is opened as the center is penetrated, and the first and second internal spaces 301 and 302 divided in the thickness portion are formed, and a desiccant 303 is formed in the first internal space 301 . A first insulating rod 300 filled with; and a first UV blocking insulating film 310; and the center is penetrated, and a fitting part 321 is formed on one side of the rim, and the inner space of the thick part ( A second heat insulating rod 320 filled with a desiccant 323 is provided in 322,
The first insulating insulating rod 300 while pressing the edge of the first UV-blocking insulating film 310 with the fitting part 321 of the second insulating insulating rod 320 and inserting it into the open side of the second internal space 302 . and forming the first UV blocking heat insulating film 310 in close contact with a part of the inner surface of the second inner space 302,
The edges of the pair of glasses 330 on the outer surfaces of the first and second heat insulating rods 300 and 320 that do not face each other on both sides of the first UV blocking insulating film 310 are respectively attached through the adhesive member 331 . glued,
Silicone is applied to the outer space 341 formed between the edges of the first and second heat insulating rods 300 and 320 and the edges of the pair of glasses 330, and a silicone finish is formed in the outer space 341. (340) A method of manufacturing double-layer glass with improved heat insulation, characterized in that it forms. 12. The method of claim 11,
A heat insulating function characterized in that the second UV blocking heat insulating film 350 is attached to one of the pair of glasses 330 through an adhesive member 351 so as to be positioned between the pair of glasses 330 . An improved method for manufacturing double-layer glass. 12. The method of claim 11
A method of manufacturing double-layer glass with improved heat insulation function, characterized in that a safety net (360) having a plurality of through holes (361) formed on the outer surface is sandwiched between the first and second heat insulating rods (300, 320). 14. The method of claim 13,
The through hole 361 is a method of manufacturing a double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. The multilayer glass with improved heat insulation function manufactured by the method for manufacturing the multilayer glass of any one of claims 11 to 14. In the method for manufacturing double-layer glass,
A pair of first heat insulating rods 400 having a center penetrating, a protrusion 401 formed on one side of the edge, and a moisture absorbent 403 filled in the inner space 402 of the thick portion; and the center penetrating and a second heat insulating rod 410 filled with a moisture absorbent 412 in the inner space 411 of the thick portion; and a pair of first UV blocking heat insulating films 420 are provided,
The first UV-blocking insulating film while pressing the edge of the first UV-blocking insulating film 420 with one of the first insulating insulating rods 400 and adhering to the remaining first insulating insulating rods 400 and the protrusion 401 . Forming 420 taut, pressing the edge of the remaining first UV-blocking insulating film 420 with the second insulating interlocking rod 410 and adhering to the adjacent first insulating intermittent rod 400 and the protrusion 401 while in close contact Forming the first UV-blocking insulating film 420 taut,
On the outer surfaces of the first and second heat insulating rods 400 and 410 that do not face each other on both sides of the pair of the first UV blocking insulating film 420, the edges of the pair of glass 430 are attached to the adhesive member 431. Each is attached through
Silicone is applied to the outer space 441 formed between the rims of the pair of first and second insulating insulating rods 400 and 410 and the rims of the pair of glass 430, the outer space ( 441), a method for manufacturing double-layer glass with improved heat insulation, characterized in that the silicon finish 440 is formed. 17. The method of claim 16,
A heat insulating function characterized in that the second UV blocking heat insulating film 450 is attached to one of the pair of glasses 430 through an adhesive member 451 so as to be positioned between the pair of glasses 430. An improved method for manufacturing double-layer glass. 17. The method of claim 16,
A plurality of through-holes 461 between a pair of the first heat-insulating bars 400 and between the second heat-insulating bars 410 and the first heat-insulating bars 400 adjacent to the second heat-insulating bars 410 A method of manufacturing double-layered glass with improved thermal insulation function, characterized in that sandwiching the safety net 460 formed on the outer surface. 19. The method of claim 18,
The through-hole 461 is a method of manufacturing double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. [Claim 20] The multi-layer glass with improved heat insulation function manufactured by the method for manufacturing the multi-layer glass according to any one of claims 16 to 19. In the method for manufacturing double-layer glass,
The center is penetrated, the fitting groove 501 is formed on one side of the rim, and the first insulating rod 500 filled with the moisture absorbent 503 in the inner space 502 of the thick portion; the center is penetrated, A fitting portion 511 is formed on one side of the edge, a fitting groove 512 is formed on one side opposite to the edge, and a moisture absorbent 514 is filled in the inner space 513 of the thick portion. (510) and; A third heat insulating rod 520 through which the center is penetrated, a fitting portion 521 is formed on one side of the edge, and a moisture absorbent 523 is filled in the inner space 522 of the thick portion; , to provide a pair of first UV-blocking insulating films 530,
By pressing the edge of one first UV-blocking insulating film 530 with the fitting part 511 of the second heat insulating rod 510 and inserting it into the fitting groove 501, it is closely attached to the first heat insulating bar 500 and the The first UV blocking heat insulating film 530 is tightly formed, and the edge of the remaining first UV blocking heat insulating film 530 is pressed with the fitting portion 521 of the third heat insulating rod 520 to fit into the fitting groove 512 . The first UV-blocking insulating film 530 is tightly formed by being in close contact with the second heat insulating rod 510 while being inserted into the
Adhesive member 541 with the edge of a pair of glass 540 on the outer surfaces of the first and third heat insulating rods 500 and 520 that do not face each other on both sides of the pair of the first UV blocking insulating film 530 Each is attached through
Silicone is applied to the outer space 551 formed between the rims of the first, second, and third heat insulating rods 500 , 510 and 520 and the rims of a pair of glass 540 , and the external space 551 is ), a method of manufacturing double-layer glass with improved heat insulation, characterized in that the silicon finish 550 is formed. 22. The method of claim 21,
A heat insulating function characterized in that the second UV blocking heat insulating film 560 is attached to one of the pair of glasses 540 through an adhesive member 561 so as to be positioned between the pair of glasses 540 . An improved method for manufacturing double-layer glass. 22. The method of claim 21
A safety net 570 having a plurality of through-holes 571 formed on the outer surface is sandwiched between the first and second heat insulating bars 500 and 510 and between the second and third heat insulating bars 510 and 520 A method of manufacturing double-layered glass with improved thermal insulation function. 24. The method of claim 23,
The through-hole 571 is a method of manufacturing double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. Claims 21 to 24 of any one of the laminated glass manufacturing method of any one of the improved heat insulation function of the laminated glass. In the method for manufacturing double-layer glass,
One side of the second internal space 602 is opened while the center is penetrated, and the first and second internal spaces 601 and 602 divided in the thickness portion are formed, and a desiccant 603 is formed in the first internal space 601 . One side of the second internal space 612 is opened while forming the first and second insulating interstitial rods 600 filled with; , The first internal space 611 is filled with a desiccant 613, and the second insulating interstitial rod 610 having a fitting portion 614 formed on one side of the edge, and the center is penetrated and fitted on one side of the edge A portion 621 is formed, and a third heat insulating rod 620 filled with a moisture absorbent 623 in the inner space 622 of the thick portion; and a pair of first UV blocking heat insulating films 630 are provided,
By pressing the edge of one first UV-blocking insulating film 630 with the fitting portion 614 of the second heat insulating rod 610 and sandwiching it in the open side of the second internal space 602, the first insulating interleaving rod ( 600) and a portion of the inner surface of the second inner space 602 to form the first UV blocking heat insulating film 630 taut, and use the fitting part 621 of the third heat insulating rod 620 to insert the remaining second 1 By pressing the edge of the UV-blocking insulating film 630 and inserting it into the open side of the second internal space 612, the second insulating rod 610 and a part of the inner surface of the second internal space 612 are pressed in close contact with the above. Forming a first UV-blocking insulating film 630 taut,
On the outer surfaces of the first and third heat insulating rods 600 and 620 that do not face each other on both sides of the pair of the first UV blocking heat insulating film 630, the edge of the pair of glass 640 is attached to the adhesive member 641. Each is attached through
Silicone is applied to the outer space 651 formed between the edges of the first, second, and third heat insulating rods 600 , 610 , and 620 and the edges of a pair of glass 640 , and the external space 651 . ), a method for manufacturing double-layer glass with improved heat insulation, characterized in that the silicone finish 650 is formed on the surface. 27. The method of claim 26,
An insulating function characterized in that the second UV blocking heat insulating film 660 is attached to one of the pair of glasses 640 through an adhesive member 661 so as to be positioned between the pair of glasses 640 . An improved method for manufacturing double-layer glass. 27. The method of claim 26
A safety net 670 having a plurality of through-holes 671 formed on the outer surface is sandwiched between the first and second heat insulating bars 600 and 610 and between the second and third heat insulating bars 610 and 620 A method of manufacturing double-layered glass with improved thermal insulation function. 29. The method of claim 28,
The through-hole 671 is a method of manufacturing double-layer glass with improved heat insulation, characterized in that it is formed in a polygonal shape. The multilayer glass with improved heat insulation function manufactured by the method for manufacturing the multilayer glass of any one of claims 26 to 29.

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