KR101022005B1 - Manufacturing process of triple multi-layer glass using space bar made up of different material - Google Patents

Abstract

PURPOSE: A method for manufacturing triple multi-layer glasses using space bars made of different materials is provided to improve the durability of triple multi-layer glasses used in a multistory building and reduce manpower and costs for formation of space bars. CONSTITUTION: A method for manufacturing triple multi-layer glasses using space bars made of different materials comprises following steps. A plate glass is cut into a fixed size and is cleaned(S10). A super spacer is molded to a fixed thickness(S20). The super spacer is attached to one side of a third glass(S30), and a first glass is attached. Aluminum or a stainless steel plate is bent, and a metal space bar is formed. A metal space bar is attached to one side of a second glass using adhesive or adhesive tape, and the other side of the third glass is pressed and attached. Thiokol is injected into the outer surface of the metal space bar and the super spacer.

Description

Manufacturing process of triple multi-layer glass using space bar made up of different material}

The present invention relates to a three-layered glass manufacturing method, and more particularly, in forming a liver rod spaced apart from the first to third glass by a certain distance, the first glass facing the inside of the building and the third glass located in the center A super spacer is formed therebetween, and an intermetallic rod is formed between the third glass and the second glass constituting the outer wall of the building, and the interlayers of the triple multilayer glass are formed of different heterogeneous materials, respectively. The excellent super spacer improves the heat insulation effect, and on the outside of the building, the present invention relates to a method for manufacturing triple-layered glass using heterogeneous rods that can improve resistance to wind pressure by means of metal rods with enhanced bearing capacity.

In general, a multi-layered glass installed in a window frame or a chassis partitioning the interior and exterior of a building is configured by installing a ganbong between the glass to maintain a distance and a certain distance between the plurality of glass.

Thus, by separating the plurality of glass with 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 caused by the condensation phenomenon by adding an absorbent to the liver bar.

Conventional multilayer glass is configured to include a first glass facing the inside of the building, a second glass constituting the outer wall of the building, and a ganbong to maintain a constant space between the first glass and the second glass.

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 rod is formed by bending the aluminum material along the outer shape of the glass, or by connecting a plurality of rods made of a straight line by the coupling portion made of a predetermined 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.

In addition, in order to form the liver rod from the aluminum material, the process of cutting the steel sheet for forming the liver rod to a certain size, the process of bending the cut steel sheet, the process of inserting the connection key to form a closed loop structure, The process of injecting the absorbent and the process of attaching the adhesive are constantly required, and the equipment for operating each process and the operator for operating the equipment are required. There was a problem.

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 moisture absorbent was filled and cured in the interior of the aluminum liver rod, but it was used after 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 the construction and installation problems such as difficulty in bending the aluminum liver rod when the edges of the laminated glass are curved. Synthetic resin rod using PVC is proposed.

However, the conventional synthetic resin liver rods had problems of work to be bonded to the glass surface with silicon and low mechanical properties, and synthetic resin liver rods with additional reinforcing materials have been proposed to supplement these problems.

However, as more and more high-rise buildings using double-layered glass have been recently demanded, the supporting capacity for long-term support for not only insulation effects but also high-level external wind pressures is required. There was a problem that can not implement sufficient bearing capacity.

As such, there is no clear standard for the material and structure of the rods used to maintain the space between them by keeping a certain distance from each other. Thus, they provide excellent insulation effect and provide sufficient support for external impact. There is still a need for cues that can simplify the manufacturing process.

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 In order to maintain the space between the third glass is located in the need for another bong, even in the case of the triple layer glass as described above, there is still a problem when using an aluminum ganbon and a synthetic gangan rod as described above. There is a need for a method of manufacturing liver rods that can simultaneously provide support and simplify the manufacturing process.

The problem to be solved by the present invention is to form a liver bar that is located inside the building from the triple-layered glass as a super spacer, an extruded product containing a moisture absorbent, and the liver bar that is located outside the building has a strong support for wind pressure, etc. It can be used to improve the insulation effect and to improve the bearing capacity against wind pressure on the outside of the building.The super spacer, which is easy to bend along the shape of the glass, facilitates the work, reducing manpower and equipment for the formation of liver rods. The present invention provides a method for manufacturing triple layered glass using heterogeneous liver rods that can improve the durability of the triple layered glass used in a high-rise building.

In the method of manufacturing triple multilayer glass using heterogeneous rods for achieving the above object, the plate glass is cut to fit the sizes of the first to third glasses, and the foreign substances on the cut glass surface are washed, A plate glass processing step which is sufficiently dried to remove; A super spacer including a moisture absorbent is molded to have a thickness of a desired distance to separate the first glass and the third glass, and is bonded to the first joining surfaces of both sides attached to the first and third glasses, respectively. A super spacer forming step of forming a first inner surface facing an inner space between both glasses and a first outer surface facing an outer space between both glasses in a state; The super spacer is adhered to one surface of the third glass by an adhesive or adhesive tape applied to the first bonding surface, and the first glass, which is temporarily fixed, is placed on one surface of the super spacer and pressurized to attach it. Super spacer bonding step; An intermetallic rod forming step of bending an aluminum or stainless steel sheet to form an intermetallic rod; Bonding an intermetallic bar to one surface of the second glass using an adhesive or an adhesive tape, and attaching the other surface of the third glass to the other surface of the intermetallic rod; And a cheol call injection step of injecting a cheol call on the outer circumferential surface of the super spacer and the intermetallic rod.

The present invention is to form a super bar to be located inside the building from the triple-layered glass as a super spacer, and to form a liver bar to be located outside the building to a metal bar with strong bearing capacity against wind pressure, etc. to improve the insulation effect and outside the building Simultaneously improves the bearing capacity against wind pressure and facilitates work by super spacers that are easy to bend corners along the shape of glass, reducing manpower and equipment for the production of triple-layered glass. There is an advantage that can improve the durability of the laminated glass.

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

1 is a block diagram of a method for manufacturing triple multilayer glass using heterogeneous liver rods according to the present invention, and FIG. 2 is a partial perspective view of triple multilayer glass using heterogeneous liver rods according to the present invention.

Referring to Figure 1, the three-layer multilayer glass manufacturing method using a heterogeneous liver bar according to the present invention, the plate glass processing step (S10) for cutting and washing the plate glass to a certain size, and forming a super spacer to form a super spacer to a certain thickness Step S20, bonding the super spacer to one surface of the cut third glass and attaching the first glass (S30), and forming a metal rod by bending the aluminum or stainless steel sheet Step S50, using the adhesive or adhesive tape to bond the intermetallic rod to one surface of the second glass, and press the other surface of the third glass adhesion step (S60) and the super spacer and the metal It comprises a thiol call injection step (S70) for injecting the chicol call on the outer peripheral surface of the liver.

In this case, the triple multilayer glass using the heterogeneous ganbong is the first glass 110 facing the inside of the building, as shown in Figure 2, the second glass 120 forming the outer wall of the building, and the first glass and A third spacer 130 positioned between the second glass, a super spacer 210 that maintains a space between the first glass and the third glass positioned at the center, and a second positioned at the center of the second glass. It consists of a metal rod 220 to maintain the space between the three glass. Here, the super spacer refers to a liver rod made of a foamable resin containing a moisture absorbent as a silicone product, which is well known in the art, and in the present specification, the super spacer is made for convenience of understanding the liver rod made of a foamable resin. The spacer is used as a term referring to a liver rod made of a foamable resin.

As described above, the ganbong located inside the building is composed of a super spacer for improving the thermal insulation effect, and the ganbong located outside the building is sufficiently supported by external shocks such as wind blowing from the outside. It consists of intermetallic rods that can be made of different materials.

The plate glass processing step (S10) is to cut the plate glass to the size of the first to the third glass, and to clean the foreign matter on the surface of the cut glass to ensure a strong adhesion and perfect visibility, remaining in the cleaning And dry enough to remove moisture.

In this case, the plate glass forming the first to the third glass can reflect most of the infrared rays having a region of the wavelength related to the cooling and heating of the sunlight, so the low-emissive glass (Low) has a large difference from the ordinary glass in the infrared reflectance It is composed of Low-E glass which is -Emissivity.

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.

The super spacer forming step (S20) may be performed to form a super spacer, which is an extrusion-molded product including a moisture absorbent, to have a thickness equal to a desired distance to separate the first glass and the third glass, or to form a wide plate-shaped super spacer to have such a thickness. Form by cutting constantly.

At this time, the super spacer is bent to form a loop of a size slightly smaller than the outermost circumference of the first to the third glass, both ends of the super spacer forming a loop as described above is tightly connected and sealed therein It is configured to form a first space.

In addition, as shown in FIG. 2, the super spacer 210 has a first bonding surface 211 at both sides attached to and in contact with the first and third glasses, respectively, and an inner space between the two glasses in the bonded state. It is configured to form a facing first inner surface 212 and a first outer surface 213 facing the outer space between the two glasses.

In this case, an adhesive is applied to the first bonding surface 211 provided on both sides of the super spacer, or an adhesive tape is attached, and the first inner surface 212 is spaced apart between the first glass and the third glass. The first outer surface 213 is preferably configured to have a narrower width than the first inner surface so as not to be in direct contact with the first and third glasses. However, of course, the first outer surface may be formed to have the same width as the first inner surface.

In this way, the first inner surface is in contact with both glass to determine the width of the spaced space between the glass, the first outer surface has a narrower width than the first inner surface has a direct effect on the width of the spaced space. Although not covered, it is wrapped by the first cheer call, which will be described later, so that the super spacer can be sealed while being more firmly fixed between the first glass and the third glass.

In the super spacer bonding step (S30), the super spacer is adhered to one surface of the third glass by an adhesive or adhesive tape applied to the first bonding surface, and the temporarily fixed first glass is positioned on one surface of the super spacer. After pressing, attach it by pressing.

At this time, the super spacer attached to the third glass is attached to the point 3 ~ 10 mm inward from the outermost of the third glass, the first glass attached to one surface of the super spacer is also 3 to 10 at the outermost It is advisable to adjust the position so that it is attached to the point that has entered inwardly.

In addition, while the first glass is positioned on one surface of the super spacer, before the complete adhesion is performed, the heat insulating effect can be improved in the sealed first space formed between the first glass and the third glass by the super spacer It is preferable that it further comprises a heat insulating gas injection step (S40) for injecting argon gas (Ar) or krypton gas (Kr) into the gas. 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.

The intermetallic bar forming step (S50) is made through an independent process, which is performed separately as in the forming of the super spacer, and cuts and bends aluminum or stainless steel sheet to be in contact with the second and third glass, respectively. The second inner surface 222 facing the inner space between the two glasses and the second outer surface 223 facing the outer space between the two glasses in the bonded state with the second bonding surface 221 and the closed loop Intermetallic bar cutting and bending process to be formed to form (S51), Straight key insertion process (S52) to form a closed loop by inserting a straight key to both ends of the bent intermetallic bar, and the joining surface and the inner surface And a hygroscopic agent injection process (S53) for filling a hygroscopic agent in the inner space of the outer surface, and a butyl adhesion process (S54) for attaching the adhesive tape to both of the bonding surfaces.

At this time, the intermetallic rod is also bent to form a loop having a size slightly smaller than the outermost circumference of the first to third glass like the super spacer, and thus both ends of the intermetallic rod forming the loop are firmly connected It is configured to form a sealed second space therein.

In the intermetallic bonding step (S60), the first glass formed by separating the first glass and the third glass by a predetermined distance from the super spacer is moved to a conveyor belt, and then the second glass is formed by using an adhesive or an adhesive tape. It is configured to adhere the second glass and the third glass by adhering the intermetallic rod to one side of the second glass and the other surface of the third glass constituting the first laminated glass to contact the second bonding surface of the intermetallic rod. Accordingly, the intermetallic rod is positioned between the second glass and the third glass to strengthen the overall supporting force of the triple glass.

In this case, the intermetallic rod bonding step (S60) is attached to the first surface of the second glass first, as described above, the first multilayer glass is located on one surface of the second glass and pressurized to the second glass And it may be configured to attach the third glass, of course, the first metal stick to the other surface of the third glass constituting the first layer glass, and then press the second glass toward the third glass It may also be configured to.

In this case, the intermetallic rod is attached to the same position as that of the super spacer, that is, on the same straight line, so that the support force generated by the super spacer and the intermetallic rod is not dispersed, and thus, a more enhanced effect can be realized. It is preferable.

In addition, a heat insulating gas injection step of injecting argon gas, krypton gas, etc. may be further included in the space spaced apart from the second glass and the third glass by the intermetallic rod in the same manner as the space formed by the super spacer. have.

The cheol call injection step (S70) is the super spacer and the intermetallic rod is attached to the inner portion, about 3 to 10 mm inwardly from the outermost portion of the first to the third glass, so that the super spacer and Into the space leading to the outer circumferential surface of the intermetallic rod and the first to the third glass, the chicol is injected as a sealing part for preventing the movement of the liver rod and the inflow of moisture.

This cheol call injection step (S70) is a step (S71) of contacting the outlet of the cheol call supply device to the outer surface of the first to third glass, and supplying the cheol call along the outer surface of the first to third glass Moving the outlet of the device and supplying the cheol (S72), and the edge treatment process for adhering the flow preventing means to the glass by recognizing the edge of the first to third glass and supplying more cheolol (S73) It is configured to include.

In this way, the first call 310 is formed on the first sealing portion formed on the outer circumferential surface of the super spacer by the supply of the first call, and the second call 320 is formed on the second sealing portion formed on the outer circumferential surface of the intermetallic rod. Is formed. As described above, the first to third glasses are filled between the first and third glasses and the second and third glasses while covering the outer circumferential surfaces of the super spacer and the intermetallic rod, respectively. As a result, the bonding force between the super spacer and the intermetallic rod can be prevented from being directly exposed to external moisture or foreign substances.

In addition, the path from the outer space to the space between the first and third glass is extended by the first and second chocolate, so that external moisture or the like passes through the first and second chocolate. The total diffusion distance diffused into the super spacer and the metal rod increases, and the adsorption time in the rod increases, thereby significantly reducing condensation caused by external moisture.

When the thiol is hardened after the filling of the thiol is completed, the rods for separating the first to third glasses constituting the triple multilayer glass by a predetermined distance are different from the super spacer inside the building and the metal rods outside the building. In addition, it improves the insulation effect of the building and at the same time maintains sufficient bearing capacity against wind pressure continuously applied even in high-rise buildings, which not only increases the durability of the triple-glazed glass but also increases the durability of the building itself. .

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 block diagram of a method for manufacturing triple multilayer glass using heterogeneous liver rods according to the present invention.

2 is a partial perspective view of a triple multilayer glass using heterogeneous liver rods according to the present invention.

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

100-First Glass 120-Second Glass

130-3rd Glass 210-Super Spacer

220-Metal Rod 310-First Cheol

320-2nd Fuck

Claims (4)

A plate glass processing step of cutting the plate glass to the size of the first to third glass, washing the foreign substances on the cut glass surface, and then drying the plate glass sufficiently to remove water remaining during the washing; A foamable resin intercalator containing a moisture absorbent is molded to have a thickness equal to a desired distance to separate the first glass and the third glass, and is bonded to the first joining surfaces of both sides attached to the first and third glasses, respectively. Forming a first inner surface facing the inner space between the two glasses and a first outer surface facing the outer space between the two glasses in a closed state; Bonding the foamed resin interrod to one surface of the third glass by using an adhesive or adhesive tape applied to the first bonding surface, and placing the temporarily fixed first glass on one surface of the foamed resin interrod, pressurized Foaming resin rod sticking step; An intermetallic rod forming step of bending an aluminum or stainless steel sheet to form an intermetallic rod; Bonding an intermetallic bar to one surface of the second glass using an adhesive or an adhesive tape, and attaching the other surface of the third glass to the other surface of the intermetallic rod; And It comprises a cheol call injection step of injecting the cheol call on the outer circumferential surface of the effervescent resin rod and the metal rod; The step of adhering the expandable resin rod is an insulating gas injection step of automatically injecting argon gas (Ar) or krypton gas (Kr) into the sealed space formed by the expandable resin rod in the press for pressing the first glass. Further comprises; The intermetallic rod forming step, An aluminum or stainless steel sheet is cut and bent by an auto bending machine to be joined to both side surfaces of the second and third glasses, respectively, and the inner surface facing the inner space between the two glasses in the bonded state, and both glasses. An intermetallic bar cutting and bending process to form an outer surface facing an outer space therebetween and bend to form a closed loop; A straight key insertion process of inserting straight keys at both ends of the bent metal rods to form a closed loop; An absorbent injecting process for filling an absorbent into an inner space consisting of both of the bonding surface, the inner surface, and the outer surface; And Method for producing a triple layer glass using a heterogeneous liver rod, characterized in that comprising a butyl bonding process for attaching the adhesive tape to both bonding surfaces. delete delete The method of claim 1, The cheol call injection step, An outer surface contacting process of contacting an outlet of the cheocol supply device to an outer surface of the first to third glasses; Moving the discharge port of the thicol supply device along the outer surfaces of the first to third glass and supplying the chicol; And Recognize the edges of the first to third glass, the flow preventing means is in close contact with the glass, and until it is filled in the space from the outer surface of the expandable resin or metal rod to the outer edge of the corner of the first to third glass Method for manufacturing triple multilayer glass using heterogeneous liver bar, characterized in that it comprises a corner treatment process for supplying a cheocol.

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