KR20090097061A - Spacer of pair glass - Google Patents

Abstract

A spacer for a pair glass is provided to improve the insulating effect by intensifying the adhesive force and the unity force between an insulating member and a mirror. A spacer for a pair glass(100) is composed of an upper plane(120), both side planes(130), an incline plane(140), a bottom plane(150), a space unit(110), a plurality of through-holes(125) which is formed in the upper part at regular intervals, a plurality of binding holes(160) which is formed in the size of 1-5mm at the both side planes, and a heat insulating member having an extrusion ball. A cover layer made of synthetic resins is injection-molded at both sides of the spacer.

Description

Double layer glass liver {Spacer of pair glass}

The present invention relates to a multi-layered glass liver rod, and more particularly, the binding holes formed on both sides of the liver rod in the process of coating the insulating member on both sides of the liver rod to be bonded to both tempered glass installed on both sides of the liver rod. Extrusion ball is formed through the binding sphere through the heat insulating member through the binding hole to have a strong binding force, by forming a binding groove on the outer surface of the heat insulating member to improve the adhesive force by the adhesive layer between the heat insulating member outer surface and the glass surface A multi-layered glass stem provided to improve the binding force with the adhesive layer.

In general, the ganbong is bonded between the glass to maintain a predetermined distance between the multi-layer glass installed in the window frame, chassis, etc. that partitions the indoor and outdoor of the building. Such a multilayer glass is widely used for insulation or noise blocking, and a ganbong is installed between the laminar glass to maintain a stable air layer between the glass, and the ganbong is usually made of aluminum.

As such, most of the rods are made of aluminum having high thermal conductivity to allow thermal conduction between the multilayered glass, so that there is a problem that the heat insulation effect is lowered. have.

In view of these problems, the Korean Utility Model Application No. 1994-33373 (the name of the design: a double-layered glass liver bar, hereinafter referred to as “quoting design 1”) has been proposed, which is illustrated in FIG. 1.

As shown, Proposition 1 has a cutout portion 11 formed in a longitudinal direction at a central portion of the upper surface thereof, and in a multi-layered glass liver rod 10 having a space for filling a desiccant therein, which is extruded from a synthetic resin, and A plurality of striped protrusions are formed on the inclined portions 12 on both sides of the lower side so as to achieve stable adhesion, and an adhesive layer 14 is coated on both sides to form adhesion with both panes, and an adhesive paper ( 15) was attached.

Proposition 1 has the advantage of obtaining a thermal insulation effect with a low thermal conductivity, but since the material is a synthetic resin, it is unstable due to unstable shape due to easy bending when bonding the rod to the glass surface, resulting in poor workability. There is a problem that the work efficiency is lowered, and the labor cost burden increases because a number of workers must work together to hold the glass plate so that the shape of the liver is not deformed.

In addition, in order to solve the above-mentioned problems, the reinforcing member of aluminum or aluminum alloy in the inner layer of the liver rod 20a in Registered Room No.0402312 (name of the registration: double-glazed liver bar, hereinafter referred to as 'quoting design 2') ( 10a) is integrally molded, and the liver rod 20a is molded in a synthetic resin on the outer layer, and the upper surface of the liver rod 20a is proposed as a structure in which through holes 21a are formed at regular intervals, which is illustrated in FIG. 2. .

As shown in FIG. 2, the problem with Cited Proposition 2 is that the surface of the liver rod inserted into the double glass surface firstly has a moisture caused by the temperature difference between the inside and the outside of the glass surface. By absorbing moisture with the moisture absorbent provided inside the liver rod, you can see the transparent glass window without moisture and condensation.In this case, the surface with the through hole of the liver rod is made of synthetic resin, so that corrosion occurs due to contact with moisture for a long time. Whitening of ash occurs to increase the size of the through hole and the thickness of the surface with the through hole is gradually weakened.

Secondly, if the temperature difference between inside and outside is severe, such as winter, liver and condensation increases as the inside of the double glass surface increases, and the liver bar plays an important role. It is absorbed by the absorbent, but due to the nature of the synthetic resin, the water is attached to the surface of the synthetic resin and the water gathers to form large droplets.

Third, the outer layer of the liver is made of synthetic resin, and both sides and the rear side of the liver are opposite (the opposite side of the surface with holes), and both sides of the liver are bonded to the glass and support cases such as aluminum chassis supporting the glass. Adhesives such as sealants are used on the back of each adhesive. The adhesives have properties that are relative to synthetic resins, so that peeling phenomenon occurs and the adhesive is used to corrode the surface of the resinous resin. The sealant, which is mainly used as an adhesive, is not easily adhered to the synthetic resin, so that the bar is separated from the glass surface and the bar is separated from the support case.

In addition, the applicant has a patent registration No. 074391, as shown in Figure 3, the upper surface 120, both side surfaces 130, the inclined surface 140 and the bottom surface 150 is provided with a space portion 110 in the cross section, the inclined surface 140 is bent at a portion where both sides and the bottom is connected, the reinforcing member 145 protruding from both ends of the inclined surface 140 is formed, the upper surface 120, a plurality of through-holes 125 at regular intervals In the conventional multilayer glass liver bar 100 is provided, the insulating cap 200 is provided with an integral cap covering both side surfaces 130, the inclined surface 140 and the bottom surface 150, except for the upper surface (120). In the binding force with the inner surface of the insulating cap 200 in contact with both sides of the liver in the multilayer glass liver bar, as shown in Figure 3 by binding to form the stepped end of the insulation cap 200 to surround the edge of the upper surface of the liver bar Moisture due to lack of adhesive principle or adhesive layer There is a problem that the inflow of the finite air is open, and also caused the interview site of the liver rod 100 and the insulation cap 200 to be opened by the external shock to further bond the liver rod 100 and the insulation cap 200. I have a challenge to improve.

The present invention has been made in order to solve the above-mentioned conventional problems, by forming a binding port on both sides of the liver rod to strengthen the binding force of the heat insulating member is coated on both sides of the multilayer glass liver rod strong binding force between the liver rod and the insulation member. Another object of the present invention is to provide a multi-layered glass liver rod having a strong binding force of the adhesive layer by forming a binding groove on the outer surface of the heat insulating member for the purpose of improving the adhesion between the heat insulating member outer surface and the glass surface. .

In the conventional multi-layer glass liver bar which consists of an upper surface, both sides, an inclined surface and a bottom surface, and has a space inside the cross section, and the plurality of through holes are provided on the upper surface at regular intervals.

A plurality of binding holes penetrating a circular diameter of 1 to 5 mm in size on both sides are formed, and the coating layer made of synthetic resin is extruded on both sides of the liver rod in which the binding holes are formed. It provides a multilayer glass liver bar which is made.

In addition, to provide a multi-layered glass liver bar, characterized in that to form a binding groove having a cross-section "단면" shape in the longitudinal direction perpendicular to the heat insulating member outer surface.

As described above, the present invention is to coat the heat insulating member on both sides of the liver bar to enhance the adhesive strength with the tempered glass connected to both sides of the multilayer glass liver rod made of aluminum or aluminum alloy and improve the heat insulation effect By forming a binding groove in the glass to improve the adhesion to the glass surface and to improve the stronger adhesion and bonding strength with the glass surface has a useful effect of enhancing the adhesive force between the liver and the glass surface to enhance the insulation and heat insulation effect.

4 and 5, the present invention includes an upper surface 120, both side surfaces 130, an inclined surface 140, and a bottom surface 150, and includes a space 110 inside the cross section. In the multilayer glass liver rod 100 having a plurality of through holes 125 provided at regular intervals on the upper surface 120, a plurality of circular diameters 1 to 5 mm are penetrated to both side surfaces 130. Two binding holes 160 are formed, and the insulating layer 200a having the extrusion ball 210 formed inside the binding hole 160 by extrusion molding the coating layers made of synthetic resin on both sides of the liver rod 100 on which the binding holes 160 are formed. It provides a multi-layer glass liver bar (hereinafter referred to as 'ganbong') characterized in that consisting of).

In addition, as shown in Figure 8 to provide a multi-layer glass liver bar, characterized in that to form a binding groove 220 having a cross-section "∨" shape in the longitudinal direction perpendicular to the outer surface of the heat insulating member (200a) have.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention.

As shown in FIG. 5, both side surfaces 130 of the liver rod 100 are formed on both side surfaces 130 of the liver rod 100 with a plurality of binding holes 160 having a circular diameter of 1 to 5 mm. The coating layer of the synthetic resin is extruded in the extrusion molding in the extrusion molding while pushing the liver rod by an extruder using an extrusion method (extrusion) while applying the coating layer of synthetic resin on both sides of the liver rod (100) Refers to stacking the insulating member (200a) through the process.

Accordingly, the synthetic resin agent penetrates the coating layer, which is a synthetic resin, and passes through the binding hole 160 through the binding holes 160 formed on both side surfaces 130 of the liver rod 100. Extruded ball 210 made of a synthetic resin of a mass larger than the hole size of the.

Thus, by strengthening the coupling force between the liver rod 100 and the heat insulation member 200a, the insulation member 200a may be prevented from being separated from the side surface of the liver rod 100.

As a result, as shown in FIGS. 6 and 7, the heat insulating member 200a coated on both side surfaces 130 of the liver rod 100 has a strong binding with the extrusion ball 210 introduced into the binding hole 160. Due to this, the binding with the liver rod 100 is improved, and the insulation member 200a is coated on both sides of the liver rod 100 so as to prevent the penetration of moisture generated in the glass due to the temperature difference between the inside and the outside. Will bring.

That is, while a moisture absorbent (not shown) such as silica gel absorbs moisture generated on the double glass 300 surface in the space portion 110 of the liver rod 100 made of aluminum or aluminum alloy, the temperature difference of the liver rod according to the moisture is increased. Fine moisture is adhered to the upper surface 120 of the liver rod 100 by the heat insulating member that covers both side surfaces 130 of the liver rod 100 to prevent it from being removed by an absorbent (not shown) ( 200a) may prevent the moisture absorbed by the moisture absorbent (not shown) provided in the space portion 110 of the liver rod 100 to be discharged to the outside again.

That is, as moisture is absorbed into the moisture absorbent (not shown) accommodated in the space portion 110 of the liver rod 100, a temperature difference occurs in the space portion 110 so that the material of the liver rod 100 is made of the metal rod 100. Moisture is adhered to both side surfaces 130, in order to prevent such moisture from adhering to both sides 130 of the liver rod 100 to reduce the sudden temperature difference generated in the space portion 110 of the liver rod (100) By coating 200a) on both sides 130 of the liver rod 100, this can be prevented.

In addition, as shown in FIGS. 8 to 12, a plurality of binding grooves having a “∨” shape in the longitudinal direction perpendicular to the outer surface of the heat insulating member 200a coated on both side surfaces 130 of the liver rod 100 ( By forming 220, the adhesive layer 400 on the outer surface of the heat insulating member 200a to adhere to the glass 300 surface on the outer surface of the heat insulating member 200a on which the binding groove 220 having the “∨” shape is formed. In this case, the adhesive liquid of the adhesive layer 400 flows into the binding groove 220 formed in the heat insulating member 200a to have a strong binding force between the heat insulating member 200a and the glass 300 surface.

As shown in FIG. 10, each of the liver rods 100 is formed at four corner portions forming the vertices of the rectangles in the liver rod 100 installed in a quadrangular band shape between the two edges of the glass 200. Instead of installing the connector to connect / bind the present invention will be self-evident in installing the square bar-shaped liver rod 100 of the integral by connecting each of the liver rods 100, welding the side parts of the joint portion. Since the insulation is coated on the side of the rod 100, the connector is fastened, there is no characteristic that can prevent the temperature difference between the connector and the glass surface, so in the present invention, the welded integral square strip made without the connector. It will provide a shape bar.

The material of the heat insulating member 200a coated on both sides of the liver rod 100 may be used as an insulating member material by selecting one of epoxy resin and Teflon resin without thermal deformation, which is the adhesion between the liver rod 100 and the glass 300. Due to the use of silicone-based sealant, such as the sealant of the adhesive layer used in the film, micro-gaps occur between the liver and the adhesive layer due to shrinkage and expansion due to temperature / indoor / outdoor temperature differences. The phenomenon occurs.

For this reason, the above problems can be solved by using an epoxy resin and a teflon resin alternatively to the material used for the insulating member 200a.

As described through the above embodiments, the multilayer glass liver rod may be manufactured by various design changes, and the principle is limited to the configuration of the present invention through the constant embodiment, but the mechanism through the principle has general knowledge. It can be easily manufactured by changing the design.

1 is a perspective view (1) of a conventional multilayer glass liver rod.

2 is a perspective view (2) of a conventional multilayer glass liver rod.

3 is a perspective view 3 of a conventional multilayer glass liver rod.

Figure 4 is a multi-layer glass liver bar state in accordance with the present invention.

5 is a process chart of the process of coating the heat insulating member on the multi-layered glass stem in accordance with the present invention.

Figure 6 is an exploded perspective view of the laminated glass rod in accordance with the present invention before installing the glass window.

7 is a cross-sectional view taken along line A-A` after installing the multilayer glass stem in accordance with the present invention shown in FIG.

8 is a state in which a binding groove is formed on the outer surface of the heat insulating member of the multilayer glass liver rod according to the present invention.

9 is a plan view in which a binding groove is formed on the outer surface of the heat insulating member of the multilayer glass liver rod of FIG. 8.

10 is an assembled and exploded perspective view of the multilayer glass liver rod having a binding groove formed on the outer surface of the heat insulating member according to the present invention before being installed in the glass window;

Figure 11 is a structural diagram for bonding the adhesive layer between the multi-layer glass liver bar and the glass window formed with a binding groove on the outer surface of the heat insulating member according to the present invention.

FIG. 12 is a cross-sectional view taken along line B-B 'of a multi-layered glass liver formed of a window-adhesive layer-insulating member according to the present invention of FIG. 11;

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

Ganbong 100 Space section 110 Top 120 Through hole 125 Both sides 130 Slope 140 Bottom 150 Binding hole 160 Insulation member 200a Extruded ball 210 Binding groove 220 Glass 300 Adhesive layer 400

Claims (2)

The upper surface 120, both sides 130, the inclined surface 140 and the bottom surface 150 is provided with a space portion 110 in the cross section inside, the upper surface 120 is provided with a plurality of through holes 125 at regular intervals In the normal multilayer glass liver rod 100 which there is,  A plurality of binding holes 160 having a circular diameter of 1 to 5 mm are formed on both side surfaces 130, and the coating layer of synthetic resin is extruded on both sides of the liver rod 100 in which the binding holes 160 are formed. Laminated glass liver bar, characterized in that consisting of a heat insulating member (200a) is formed with an extrusion ball 210 inside the binding sphere (160). The multi-layer glass liver bar according to claim 1, wherein a binding groove (220) having a cross-sectional shape in the longitudinal direction perpendicular to the outer side surface of the heat insulating member (200a) is formed.

Images