KR101037409B1 - Triple multi-layer glass easy to diversify of the space of glasses - Google Patents

Abstract

PURPOSE: A triple multi-layer glass easy to diversify of the space of glasses is provided to have the diversified spaces of glasses according to the kind of building. CONSTITUTION: A triple multi-layer glass easy to diversify of the space of glasses comprises a first TPS space bar(210), a second TPS space bar(220), an insulation plastic spacer and a low-E glass. The first TPS space bar maintains the space of a third glass(130). The third glass locates between the first glass and a center area. The second TPS space bar maintains the space between the third glass and the second glass(120). The insulation plastic spacer comprises a hygroscopic agent. The through-hole is formed inside the first or third glass.

Description

Triple multi-layer glass easy to diversify of the space of glasses}

The present invention relates to triple-layered glass, and more particularly, a first TPS ganbong that maintains a space between a first glass facing the inside of the building and a third glass located in the center, and the outer wall of the building and the third glass. It is possible to vary the thickness of the entire multilayer glass by installing a second TPS liver rod that maintains the space between the second glasses forming the same line on the same straight line, and varying the widths of the first TPS liver rod and the second TPS liver rod. The present invention relates to triple glass that can minimize the leakage of gas.

In general, the multilayer glass installed in a window frame or a chassis that partitions the interior and exterior of a building is configured by installing a ganbong between the glass to maintain a distance from a plurality of glass spaced apart from each other.

In this way, by separating the plurality of glass between each other by the liver bar, it is possible to increase the heat insulation and sound insulation effect, it is possible to prevent the moisture generated by the condensation phenomenon by adding a moisture absorbent and the like to the liver bar.

1 is a partial perspective view showing the structure of a conventional multilayer glass.

Referring to FIG. 1, the conventional multi-layered glass has a first glass 10 facing the inside of a building, a second glass 20 forming an outer wall of the building, and the first glass and the second glass are spaced apart from each other. It was configured to include a liver bar 30 to maintain the space.

The rod is usually made of an aluminum material so as to firmly support the spaced glass. In addition, the ganbong made of aluminum material in this way is bent the aluminum plate to the contact surface of the both sides contacting the first and second glass, the inner surface facing the inner space between the two glass, and the outer space between the two glass It was constructed by forming an outer surface facing toward.

In addition, the liver rod is formed by bending an aluminum material along the outer shape of the glass, or by connecting a plurality of liver rods made of straight lines by the coupling portion of the bent shape.

However, as described above, the liver rod made of aluminum has a high thermal conductivity, which significantly reduces the thermal insulation effect, and thus the visual field is greatly disturbed by the dew condensation caused by the temperature difference between the inner and outer surfaces of the glass. there was.

Accordingly, in order to prevent the reduction of the thermal insulation effect due to the thermal conductivity of the aluminum liver rod, the urethane resin or the hygroscopic agent is injected into the interior of the aluminum liver rod and cured. However, the increase in work process and work required for such injection and curing There is a problem that the manufacturing cost is increased due to the increase in time.

In addition, it is cumbersome to reduce the thermal insulation effect and to form a through hole for absorbing moisture after bending the aluminum plate separately, and when the edge portion of the laminated glass is curved, it is difficult to bend the aluminum trunk rod. Due to installation problems, synthetic resin liver rods have been proposed using PVC.

Thus, the thickness of the whole multilayer glass formed using the aluminum liver rod or PVC liver rod is determined by the width of the spaced glass and the liver rod bonded between them, especially the width of the liver rod that separates the glass from each other. It is common to become dependent.

However, in the case of the conventional aluminum liver rod or PVC liver rod, a liver rod having a predetermined size and shape is separately manufactured, and then bonded to the glass by means of a separate adhesive or silicone to form a multilayer glass. Since the length was generally standardized, there was a problem that it was difficult to produce multilayer glass having various thicknesses.

In addition, in the case of the aluminum liver rod, there was a limit in reducing the length of the width due to the constraint of forming an inner space for inserting the moisture absorbent and the constraint of having support for external force applied on both sides of the glass.

In addition, in the case of the conventional aluminum liver rod or PVC liver rod, since the adhesive surface of the liver rod is not completely adhered to the glass surface by a separate adhesive or silicone, a considerable amount of gas filled in the inner space surrounded by the liver rod with time passes There was a problem leaking.

In addition, in order to seal the inner space enclosed by the liver rod to prevent leakage of the filled gas, the beginning and end portions of the liver rod should be in close contact with each other. There is a problem that the work process, such as attaching or gluing with an adhesive, and a problem that the adhesion by the additional adhesive means is not made precisely after forming the liver rod.

In addition, in the case of the recently proposed triple-layered glass, a gap between the first glass facing the inside of the building and the third glass located in the center, and the second glass and the center forming the outer wall of the building Another inter-bar is required to maintain the space between the third glass to be located in the case of the triple glass, as described above, there was a problem that it is difficult to control the overall thickness, the adhesion to the glass surface and the sealed space There was still a problem that it is difficult to completely adhere the ends of the liver bar to form a.

The problem to be solved by the present invention is to form a wide width of the first TPS liver rod and the second TPS liver rod constituting the triple multilayer glass to vary the thickness of the entire triple layer glass by an easy process, between the glass The present invention provides a triple multilayer glass that is easy to diversify the gap between the glass to minimize the leakage of gas and the like filled in.

Triple multilayer glass that is easy to diversify the gap between the glass for achieving the above object, the first glass provided inside the building; A second glass constituting the outer wall of the building; A third glass positioned between the first glass and the second glass; A first TPS liver rod for maintaining a space between the first glass and a third glass centrally located; And a second TPS interleave retaining a space between the second glass and a third glass positioned at the center, and attached to be located on the same straight line as the first TPS interleaved, wherein the first TPS interleaved and the second TPS interleaved are absorbents. It consists of a TPS material consisting of a thermal insulating plastic spacer (Thermo Plastic Spacer) comprising a non-solidified TPS material is directly bonded to one surface of the glass while being supplied through the TPS supply device, the first TPS and the second TPS rod Formation of and adhesion to one side of the glass is characterized in that it is configured to proceed simultaneously.

At this time, the first and the second TPS liver rod is a portion which is initially attached to one side of the glass is formed in an oblique shape gradually increasing inclination, the closing portion of the first and second TPS liver rod is a portion which is finished on one surface of the glass It is formed in an oblique shape corresponding to the shape of the starting portion, characterized in that configured to form a closed space in close contact with each starting portion and the closing portion of the first TPS liver rod and the second TPS liver rod.

The present invention forms various widths of the first TPS liver rod and the second TPS liver rod constituting the triple multilayer glass, and can be manufactured in various thicknesses according to the type and the number of floors in which the triple multilayer glass is installed. There is an advantage that can increase the durability of the triple-layer glass while minimizing leakage to enhance the insulation effect of the building.

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

FIG. 2 is a partial perspective view of the triple multilayer glass which is easy to vary the spacing between the glass according to the present invention, FIG. 3 is a sectional view taken along line AA of FIG. 2, FIG. 4 is a sectional view taken along line BB of FIG. 2, and FIG. Fig. 6 is a schematic view showing the opening portion and the closing portion of the first and second TPS rods, and Fig. 6 is a partial perspective view showing another embodiment of the triple multilayer glass that is easy to vary the gap between the glass according to the present invention.

Referring to FIGS. 2 and 3, the three-layered glass having a wide variety of gaps between the glass according to the present invention may include the first glass 110 facing the inside of the building and the second glass 120 forming the outer wall of the building. And, the first glass TPS 130 is located between the first glass and the second glass 130, and the first TPS intermittent 210 to maintain a space between the third glass located in the center, and the first And a second TPS rod rod 220 for maintaining a space between the second glass and the third glass located in the center.

The first to third glass (110, 120, 130) can reflect most of the infrared rays having a region of the wavelength related to cooling and heating of the wavelength of the solar light low-emissivity glass having a great difference from the ordinary glass in the infrared reflectance (Low-Emissivity) It is preferred to be composed of Low-E glass. In this way, the first to the third glass is made of low-rise glass reflects the infrared rays generated by the heating mechanism inside the building back in the building in winter, and radiant heat generated by the solar heat applied from the outside of the building in the summer. By reflecting back to the outside it is possible to implement a good thermal insulation effect.

Thus, the first to third glass (110, 120, 130) composed of a Roy glass is cut to the size of the glass to the size suitable for the purpose to install the triple-layer glass, foreign matter on the surface of the cut glass to ensure solid adhesion and perfect visibility After washing, it is configured to dry sufficiently to remove the water remaining during the washing.

The first TPS liver rod 210 and the second TPS liver rod 220 are heat insulating plastic spacers containing a moisture absorbent as a TPS material, that is, a one-component polyisobutylene (Polyisobutylen) that can improve the thermal insulation effect (Thermo Plastic Spacer) It is composed. In this case, the TPS material is preferably composed of a TPS material provided by Cummeling, Germany.

In this case, the second TPS liver rod 220 is attached to the same position as the position where the first TPS liver rod 210 is attached, that is, located on the same straight line, and the first TPS liver rod in response to an external shock or wind pressure caused by wind. It is desirable to be able to implement a more enhanced effect without the dispersion of the bearing capacity generated by the second TPS liver rod.

The first TPS liver rod 210 and the second TPS liver rod 220 are uniformly formed to be directly bonded to the glass surface while the TPS material is not solidified in a specific form while being supplied through the TPS supply device. In this case, the fact that the TPS material supplied through the TPS supply device is not solidified may be agglomerated into a shape that may take various shapes according to the shape of the viscous particles being discharged, rather than the viscous object being completely solidified. It means that there is.

The TPS material supplied through the TPS supply device has an adhesive force between the particles to maintain the bar shape of a bar shape discharged from the TPS supply device, and thus to the outermost part of the adhesive liver bar. Particles are attached directly to one side of the second glass or the third glass to form the second TPS liver rod or the first TPS liver rod and adhere to the glass surface at the same time to improve the work efficiency.

In addition, the first and second TPS liver rod 210 has an adhesive force between the particles, but since the shape is not solidified, by moving the outlet of the TPS supply device along the outer shape of the glass surface, not only straight but also bent shape and curve It is possible to easily form a liver bar of various shapes, such as.

Accordingly, the first or second TPS liver rods 210 and 220 are different from the metal liver rods having a regular size, and thus, the first glass and the third glass or the second glass may be adjusted by adjusting the outlet size of the TPS supply device. The thickness of the first and second TPS interleaving spaces that separate the third glass, that is, the length of the width may be variously configured to reach 1 to 20 mm.

Therefore, as shown in FIG. 2, the thickness of the first TPS liver rod may be formed to be about 12 to 16 mm, such as a conventional metal rod, and of course, the second TPS liver rod 220 as shown in FIG. 6. ), The thickness of the first TPS liver rod 210 can be configured to be thinly formed while maintaining the thickness thereof. In this case, the thicknesses of the first and second TPS liver rods refer to the widths of the first and second TPS liver rods shown in FIGS. 2 and 6.

That is, as shown in FIGS. 2 and 3, the first TPS ganbong 210 has a wide width between the upper and lower surfaces spaced apart from the first glass 110 and the third glass 130. The joining surfaces of both sides of the first glass 110 and the third glass 130 that are in contact with each other may be configured to have a narrow plate shape, as shown in FIG. 6. The width of the upper and lower surfaces spaced apart from the third glass 130 may be formed to be narrower than the width of the second TPS liver rod 220.

In addition, the thickness of the second TPS liver rod may be configured to be formed thin in the state in which the thickness of the first TPS liver rod is maintained, and the thickness of the first and second TPS liver rods is triple including the corresponding liver rod. It can be variously selected according to the type of building and the number of floors in which the multilayer glass is installed.

As such, the thicknesses of the spaces spaced between the first and third glasses can be varied by adjusting the thicknesses of the first and second TPS liver rods, that is, the widths thereof, and as a result, various thicknesses of the entire triple multilayer glass are formed. You can do it.

In addition, the first and second TPS liver rods do not add a separate absorbent because the moisture absorbent is uniformly contained, and thus the inner surface of the first and second TPS liver rods including the absorbent uniformly is the first glass and the first Since it is open toward the space between the three glass and the space between the second glass and the third glass, it is possible to smoothly absorb the water causing condensation without forming a separate through hole for the absorption of water.

The space spaced apart from the first glass and the third glass by the first TPS interleaved bar is an argon gas (Ar) or krypton gas (A), which is an insulating gas capable of improving an insulating effect in order to prevent heat transfer by air. It may be configured by injecting Kr). At this time, the space that is sealed by the second TPS interleaved spaced apart from the second glass and the third glass may be configured by injecting argon gas (Ar) or krypton gas (Kr).

In addition, the first TPS liver rod may be formed by placing the TPS supply apparatus on one surface of the third glass, moving the third glass, and sequentially placing the position where the first TPS liver rod is attached to the outlet of the TPS supply apparatus. Of course, according to the size of the third glass is set in advance, the TPS supply device may move around the third glass to form the first TPS ganbong directly on the third glass.

And, the second TPS liver rod may be formed by placing the TPS supply apparatus on one surface of the second glass, moving the second glass and the position where the second TPS liver rod is attached to the outlet of the TPS supply apparatus sequentially Of course, according to the size of the second predetermined glass, the TPS supply device may move around the second glass to directly form the second TPS ganbong on one surface of the second glass.

In this case, the TPS supply device may be configured by setting the position to be attached to the first and second TPS interstitial with the size of the glass in advance, but a sensor that can recognize the presence of the glass plate on one side of the outlet of the TPS supply device It is preferable that the first and second TPS liver rods are automatically formed regardless of the size of the glass to be supplied and configured to proceed with the process.

In this case, the TPS supply device is preferably configured to recognize the outermost portion of the glass by the sensor and to form the first and second TPS interleaved at a position of approximately 3 to 10 mm inside from the outer portion.

In addition, in order to minimize and automate the production process of the triple layered glass and to completely adhere the first and second TPS interleaves, first, a second TPS interleaver 220 is formed on one surface of the second glass 120. And attaching and pressing the third glass 130 to the other surface of the second TPS liver rod 220, and after forming the first TPS liver rod 210 on the other surface of the third glass 130, the first TPS liver rod While attaching and pressing the first glass 110 to the other side of 210, it is preferable to sequentially form the second TPS liver rod and the first TPS liver rod.

Accordingly, after attaching the second TPS liver rod 220 or the first TPS liver rod 210 to one surface of the second glass 120 or the third glass 130, the third glass 130 or the first glass 110. ) Is placed on the other side of the second TPS liver rod 220 or the first TPS liver rod 210, and at a constant pressure such that the shape of the second TPS liver rod 220 or the first TPS liver rod 210 does not change in the press. By pressing, the third glass 130 or the first glass 110 is attached to the second TPS liver rod or the first TPS liver rod.

In this case, as shown in FIG. 5, the first part of the first TPS ganbong 210 is first attached to one surface of the third glass is the first glass is located on one surface of the third glass It is preferably formed in an oblique shape that gradually increases in the direction, the closing portion 212, which is a portion of the first glass is finished on the first TPS bar is formed in a diagonal shape corresponding to the shape of the starting portion. In addition, the starting portion of the second TPS liver rod is formed in a diagonal shape that gradually increases in the direction in which the third glass is located on one surface of the second glass, the closing portion of the second TPS liver rod is formed in a diagonal shape corresponding to the shape of the opening portion. Of course.

As described above, since the starting part 211 and the closing part 212 of the first TPS liver rod are formed to face each other by diagonal lines corresponding to each other, the first TPS liver rod is attached to one surface of the third glass 130. By simply pressing the glass 110 on the upper portion of the first TPS interleaved 210, the first glass is attached to the other side of the first TPS interleaved, and at the same time, the start portion 211 and the closed portion 212 of the first TPS interleaved It is possible to form a closed space by closely contacting the. Similarly, the opening and closing portions of the second TPS liver rods are also formed to face each other by corresponding diagonal lines, and after attaching the second TPS liver rods to one side of the second glass, the third glass is simply placed on the upper portion of the second TPS liver rods. Just by pressing, the third glass is attached to the other side of the second TPS liver rod and at the same time, the initiation portion and the closing portion of the second TPS liver rod can be completely adhered to form a closed space.

At this time, argon gas or krypton in a press for pressing the first glass or the third glass before the first glass or the third glass is pressed on the other side of the first TPS liver rod or the second TPS liver rod to achieve complete adhesion. The gas may be configured to automatically inject gas into an enclosed space formed by the first TPS interleaving or the second TPS interleaving.

Accordingly, heat transfer between the first glass and the third glass is suppressed by the argon gas or the krypton gas, thereby realizing a better heat insulating effect. In addition, argon gas or the like injected into the space formed by the first and second TPS interleaves is injected through a separate through space and the holes are not artificially blocked, but one side of the first and second TPS interleaves Argon gas is automatically injected before the first glass and the third glass are attached to the glass, and the gas is completely sealed by the same pressure, thereby significantly reducing the leakage of gas.

Conventionally, in the case of a metal rod such as an argon gas, which has been conventionally injected and additionally sealed such an injection hole, a gas leak of about 1% occurs annually, but argon gas, etc. is automatically generated in a press before the glass is attached and pressed as in the present invention. And pressurize the entirety of the first and second TPS rods to a uniform pressure, and in particular, the starting and closing portions of the first and second TPS rods are formed in a diagonal line corresponding to each other, and are uniformly pressurized in a press and adhered to the glass. The degree of leakage is reduced to less than 0.1% per year, allowing for longer periods of use and maintaining adiabatic effects.

In addition, the first TPS liver rod 210 and the second TPS liver rod 220, as shown in Figure 4, the position slightly entered inward from the outermost portion of the first to third glass (110, 120, 130), approximately 3 ~ 10mm It is preferably configured to attach to the inner portion. Accordingly, the sealing portion for preventing the movement of the liver rod and the inflow of water is further formed in the space leading to the first and second TPS liver rods and the outer circumferential surfaces of the first to third glasses.

At this time, the first thiol 310 is injected into the first sealing portion formed on the outer circumferential surface of the first TPS liver rod, and the second thiol call 320 is injected into the second sealing portion formed on the outer circumferential surface of the second TPS liver rod.

As such, while covering the outer circumferential surfaces of the first TPS liver rod and the second TPS liver rod, the first thiol 310 and the second thiol 320 are respectively disposed between the first glass, the third glass, and the second glass and the third glass. By being filled, the bonding force between the first to the third glass can be further strengthened, and the first TPS liver rod and the second TPS liver rod can be prevented from being directly exposed to external moisture or foreign matter.

In addition, the path from the outer space to the space between the first and third glasses is lengthened by the first and second fucks 310 and 320, and accordingly, the first moisture and the like are the first and second fucks. The total diffusion distance that is diffused through the first TPS liver rod and the second TPS liver rod increases, and the adsorption time in the liver rod also increases, thereby significantly reducing condensation caused by external moisture. .

In addition, according to the present invention, when configured to support the spaced space between the first glass and the third glass by the first TPS rod and the second TPS rod, the restriction on the outer shape and size of the glass is reduced as well as the pattern on the surface. Structural glass with or through the center can be made of triple glass.

Figure 7 is an exemplary view of a triple layer glass using a patterned glass according to the present invention, Figure 8 is an exemplary view of a triple layer glass using a glass with a through hole according to the present invention.

Referring to FIG. 7, the first to third glasses 110, 120, and 130 are made of glass having a pattern on the surface thereof, and the first TPS liver rod 210 and the second TPS liver rod 220 are formed on the surface of the glass in which the pattern is formed. To form triple-layer glass.

In this case, the first glass to the third glass may be configured in a form that is simply printed on the glass surface, of course, the pattern may be formed in the intaglio or embossed form on the glass surface.

Conventional liver rods are solidified in shape and adhered to the glass surface by an adhesive, so that when the adhesive surface of the liver rods is uneven due to a pattern formed on the glass surface, it is impossible to maintain a firm adhesive state. However, since the first TPS liver rod 210 and the second TPS liver rod 220 are not solidified in shape, the first TPS liver rod 210 and the second TPS liver rod 220 are discharged from the TPS supply device. A small amount of TPS material is emitted from the embossed portion along the silver glass surface, and a little more TPS material is emitted from the embossed portion, so that the outermost portions of the first and second TPS rods are not affected by the pattern formed on the glass surface. The surface and glass surface can be brought into close contact with each other. It is also possible to fully adhere the TPS material that is not solidified to the glass surface that is pressed from the other side of the first and second TPS interleaves to form a closed space.

In addition, the first and second TPS interbars are firmly adhered to the patterned glass surface by the adhesion between the TPS particles that are completely in close contact with the glass surface, in particular, the adhesion of the TPS particles located at the outermost surface.

In addition, referring to Figure 8, the first glass to the third glass (110, 120, 130) is composed of a glass having a structural through-hole for the connection of pipes or other devices in a portion, the first TPS interstitial ( 210 and the second TPS interceptor 220 are attached to form triple glass.

At this time, in order to form a sealed space between the first glass and the third glass and to fill the argon gas, the TPS liver rod is formed along the circumference of the structural through hole, and the first or second TPS liver rod is formed along the entire circumference of the glass. By doing so, it is possible to block the gas leak through the structural through-holes. That is, between the first glass and the third glass is formed a first TPS liver rod that surrounds the entire glass and a third TPS liver rod surrounding the periphery of the structural through-holes, and the entire glass between the second glass and the third glass A second TPS liver rod is formed surrounding the circumference of the fourth TPS liver rod surrounding the circumference of the structural through hole formed therein.

As such, by forming the TPS liver rod and moving the outlet of the TPS supply device along the shape of the portion to be sealed, it is possible to easily form the liver rods of various shapes such as curved lines as well as bent shapes. Accordingly, it is possible to produce and use a solid triple-layer glass even where structural through-holes are required.

Next will be described the operation of the triple multilayer glass that is easy to diversify the interval between the glass according to the present invention configured as described above.

The third glass is positioned between the first glass facing the inside of the building and the second glass constituting the outer wall of the building, and the third glass is formed of a TPS material along an outer portion of one surface of the third glass located in the middle of the first glass. 1TPS ganbong is bonded to separate the first glass and the third glass by a certain distance, and the second TPS ganbong made of TPS material is bonded along the outer surface of the other surface of the third glass in the middle of the second glass is bonded to the second glass Separate the third glass by a certain distance.

At this time, the argon gas is filled in the closed space formed between the first glass and the third glass by the first TPS interrod, and the closed space formed between the second and third glass by the second TPS interrod. .

Accordingly, the first and second TPS interstitials and the argon gas block heat conduction between the first glass representing the temperature inside the building and the second glass representing the temperature outside the building, thereby improving the thermal insulation effect. In addition, since the first and second TPS interstitials and argon gas exhibit an even temperature distribution over the entire first glass, condensation may be prevented from occurring.

As such, the heat transfer between the first glass and the second glass is blocked by the argon gas filled in the space formed by the first and second TPS rods made of TPS material and the first and second TPS rods, and thus the first glass side. The temperature difference between and the temperature of the second glass side is to maintain a large state. Therefore, as a thermal insulation performance evaluation index indicating the amount of heat transfer due to the temperature difference of the indoor air in the unit area of the building, the heat permeability calculated by the amount of heat lost per square meter when there is a 1 degree temperature difference between the hot and cold parts of the material at the unit time In this case, it becomes clear that the thermal insulation performance is improved. In this case, the lower the heat permeability, the less heat is lost, which means that the heat insulating performance is excellent. On the contrary, the higher the heat permeation rate, the higher the heat transfer, that is, the greater the heat loss.

In the case of using the conventional general multilayer glass and the general metal liver rod, the heat transmission rate is about 3.0 W / m 2 K, whereas the first TPS liver rod made of the general multilayer glass and TPS material and the sealed space formed by the first TPS liver rod When the argon gas is filled, the heat permeation rate is approximately 1.2 W / m 2 K, which saves 420 liters of oil per year per 20 m 2 of glass area. In addition, this value is simply compared to the case of the multilayer glass, the third glass is additionally provided between the second glass forming the outer wall of the building and the first glass forming the inner side of the building, accordingly, the first glass and the first glass It is possible to realize a significantly increased thermal insulation performance than in the case of triple glass having a greater distance between the two glasses.

In addition, the TPS material constituting the first and second TPS rods is evenly distributed in the moisture absorbent, does not have a large thermal conductivity in the TPS material itself, and does not depend on a separate adhesive when adhering to the first to third glass Since the viscous TPS material, which is not solidified, hardens and adheres to the surfaces of the first to third glasses in the microparticle unit, the thermal conductivity between one side of the glass and one side of the liver is not as large as that of the case of forcibly bonding using a separate adhesive. Will not.

In addition, the first and second TPS liver rods are directly supplied in the shape of the liver rods in a uniformly blended state without being solidified and attached to the first glass to the third glass, so that the first and second TPS rods are formed along the bent portion of the glass. Even in the corner portion of the 2TPS liver rod, the TPS material and the moisture absorbent are uniformly distributed, thereby significantly reducing condensation. As a result, the degree of decrease in the heat transmission rate at the bent corners or the edges of the glass is even greater.

In the above description, the technical idea of the present invention has been described with the accompanying drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

1 is a partial perspective view showing a structure of a conventional multilayer glass.

Figure 2 is a partial perspective view of the triple layered glass easy to diversify the gap between the glass according to the present invention.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along line B-B in FIG.

Figure 5 is a block diagram showing the opening and closing portion of the first TPS liver rod and the second TPS liver rod according to the present invention.

Figure 6 is a partial perspective view showing another embodiment of the triple layered glass that is easy to vary the gap between the glass according to the present invention.

Figure 7 is an exemplary embodiment of triple glass using a patterned glass according to the present invention.

Figure 8 is an exemplary embodiment of a triple multilayer glass using a glass with a through hole formed in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

100-First Glass 120-Second Glass

130-3rd Glass 210-1TPS Ganbong

220-2nd TPS Ganbong 230-3rd TPS Ganbong

240-4th TPS Soybean 310-1st Chocolate

320-2nd Fuck

Claims (9)

delete delete Between the first glass installed inside the building, the second glass forming the outer wall of the building, the third glass located between the first glass and the second glass, and the first glass and the third glass located in the center A first TPS liver rod for maintaining a space of the first TPS liver rod, and a second TPS liver rod for maintaining a space between the second glass and a third glass centrally located, the second TPS liver rod being attached to the same straight line as the first TPS liver rod; The 1TPS liver rod and the 2TPS liver rod are made of a TPS material made of a heat insulating plastic spacer (Thermo Plastic Spacer) containing a moisture absorbent, and the non-solidified TPS material is directly attached to one surface of the glass while being supplied through the TPS supply device. And the formation of the first TPS liver rod and the second TPS liver rod and attachment to one surface of the glass simultaneously; The first glass or the third glass is composed of Roy glass, and a pattern is formed on a surface of the first glass to the third glass; The first glass to the third glass is composed of a Roy glass having a structural through-hole formed therein, the third TPS between the first glass and the third glass wrapped around the periphery of the structural through-holes located inside the first TPS liver rod It is formed, and between the second glass and the third glass triple TPS glass that is easy to vary the gap between the glass, characterized in that further formed a fourth TPS liver rod surrounding the circumference of the structural through-hole located inside the second TPS liver rod . The method of claim 3, The TPS material is a triple multilayer glass that is easy to vary the gap between the glass, characterized in that consisting of one component polyisobutylene (Polyisobutylen). The method of claim 3, The first TPS liver rod is a portion where the first portion is first attached to one surface of the third glass is formed in an oblique shape gradually increasing in the direction in which the first glass is located on one surface of the third glass, the first TPS liver rod is the first The closed portion, which is a portion finished on one glass surface, is formed in a diagonal shape corresponding to the shape of the opening portion; The starting portion, wherein the second TPS liver rod is a portion that is first attached to one surface of the second glass, is formed in a diagonal shape that gradually increases in a direction in which the third glass is positioned on one surface of the second glass, and the second TPS liver rod is the first A closing portion, which is a portion finished on one glass surface, is formed in an oblique shape corresponding to the shape of the opening portion; The multiple-layered glass of which the diversification of the spaces between the glasses is characterized in that the opening portions and the closing portions of the first TPS liver rod and the second TPS liver rod are in close contact with each other to form a closed space. The method of claim 5, The width of each of the first TPS interleaving spaced apart from the first glass and the third glass and the second TPS interleaving spaced apart from the second glass and the third glass is 1 ~ 20㎜ Easy triple glass. The method of claim 6, At least one of the space sealed by the first TPS interleaved spaced apart from the first glass and the third glass and the space sealed by the second TPS interleaved spaced apart from the second glass and the third glass is argon gas. The triple multilayer glass which is easy to diversify the space | interval between glass characterized by being filled with (Ar) and krypton gas (Kr). The method of claim 7, wherein The first TPS liver rod and the second TPS liver rod is configured to recognize the outermost portion of the glass in the sensor provided in the TPS supply device and is formed to form in the position 3 ~ 10mm from the outer portion of the gap between the various Triple glazed glass that is easy to paint. The method of claim 8, A sealing part is further formed in a space extending from the outer circumferential surface of the first TPS liver rod and the second TPS liver rod and the outermost portions of the first to third glasses, and a first thiol is injected into the first sealing portion formed on the outer circumferential surface of the first TPS liver rod. The second sealing portion formed on the outer circumferential surface of the second TPS liver rod is a second multi-layer glass, it is easy to diversify the gap between the glass, characterized in that the injection.

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