KR200279176Y1 - Insulating glass for window - Google Patents

Abstract

The present invention relates to a multilayer glass for windows used in a window of a building or a general house, and comprises a spacer 120 is bonded to the periphery between the glass pane 110 to enable the multilayer structure of the glass pane 110. In the multilayer glass 100 for a window, an electrode layer 122 is coated on the surface of the spacer 120 and a lead wire 140 for conducting electricity is connected to form an electrode on the spacer 120. Since the heating wire 140 is installed on the inner surface of the 110, but the heat wire 140 is configured to form a solar dust collecting layer, the condensation generated on the inner surface and the peripheral portion of the plate glass can be effectively prevented as well as thermal insulation. The effect can be improved, and by enabling heat dissipation using solar heat, it has a useful effect of improving energy efficiency.

Description

Double glazing for window {INSULATING GLASS FOR WINDOW}

The present invention relates to a multilayer glass for windows that can be used in windows of buildings or houses, and more particularly, to a multilayer glass for windows that can effectively prevent dew condensation, improve insulation effects, and improve energy efficiency. will be.

In general, double-layered glass is made of double or triple sealed glass of the same size at regular intervals, and then sealed by putting a constant air pressure in the space between the glass and the plate glass. It is used in various fields, such as buildings, recording rooms, etc., where noise isolation is required, and where temperature and humidity control is required.

1 is a partial cutaway perspective view schematically showing a multilayer glass for windows according to the prior art, showing an example of a double structure, the laminated glass for windows (1) according to the prior art is two sheets of glass 10 having the same specification And a spacer 20 installed as a periphery between the plate glass 10 and a corner connector 30 for fixing and fixing the spacer 20.

Here, the spacer 20 is generally rectangular in the form of an inner hollow shape formed of a metal material such as aluminum or iron, and filled with an absorbent 21 such as silica gel. The moisture absorbent 21 serves to prevent moisture from condensation on the inner surface of the pane 10 by removing moisture between the panes 10.

Looking briefly at the manufacturing process of the multilayer glass 1 according to the prior art made of such a configuration as follows.

First, the plate glass 10 is cut to meet the standard, but if necessary to perform the reinforcement and bonding process and performs the marking after cleaning / drying.

The spacer 20 is formed into an internal hollow shape through automatic bending / welding / cutting, and then filled with a moisture absorbent 21 made of silica gel to prevent condensation. The spacer 20 is first sealed (butyl sealant). . Then, these spacers 20 are assembled. Here, the spacer 20 is assembled in a rectangular frame shape, and the spacers 20 are connected and fixed to each other through the corner connector 30.

The spacers 20 assembled between the two panes 10 are positioned to bond them together, and after the secondary sealing (thiokol sealant) through the sealing material 40, the cured is completed to complete the multilayer glass 1. . At this time, the spacer 20 is disposed around the inner surface of the plate glass 10 to form a bonding with the plate glass 10 by an adhesive such as double-sided tape, and into the space between the plate glass 10 before the secondary sealing Air pressure is injected to form an air layer. Here, the air layer exhibits a heat insulating and noise blocking effect.

However, in the conventional multilayer glass as described above, condensation occurs first on the periphery of the plate glass due to temperature difference between indoor and outdoor and thermal conductivity of the spacer, and condensation occurs on the inner surface of the plate glass due to the transition effect into the inside of the plate glass. There was a problem, and accordingly there was a problem that the thermal insulation performance of the laminated glass is also reduced.

Accordingly, the present invention has been made to solve the problems described above, the purpose is to form an electrode layer on the surface of the spacer bonded to the periphery between the plate glass and to form a lead wire for energization to the spacer It is to provide a double-glazed glass for the window to prevent the formation of condensation on the peripheral portion of the plate glass and to improve the insulation effect by allowing the electrode to be formed.

Another object of the present invention is to install a heating wire on the inner surface of the pane to improve the effect of preventing condensation on the inner surface of the pane and to enable self-heat dissipation using solar heat to improve energy efficiency. To provide a laminated glass for.

1 is a partial cutaway perspective view schematically showing a laminated glass for a window according to the prior art.

Figure 2 is a partial cutaway perspective view schematically showing a window glass according to the present invention.

Figure 3 is a block diagram showing to explain the laminated glass for windows according to the present invention.

Explanation of symbols on the main parts of the drawings

100: multilayer glass 110: plate glass

120: spacer 121: moisture absorbent

122: electrode layer 130: corner connector

140: lead wire 150: hot wire

The present invention for achieving the above object is a laminated glass for a window comprising a spacer bonded to the periphery between the plate glass to enable a multi-layer structure of the plate glass, the coating of the electrode layer on the surface of the spacer, It is characterized by the technical configuration that the lead wires for the connection is formed so that the electrode is formed on the spacer.

In addition, the heating wire is provided on the inner surface of the plate glass.

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

Figure 2 is a partial cutaway perspective view schematically showing the multilayer glass for a window according to the present invention, Figure 3 is a configuration diagram shown to explain the laminated glass for a window according to the present invention.

2 and 3 show an embodiment of a multilayer glass having a dual structure according to the present invention, the laminated glass 100 for a window according to the present invention is two sheets of glass 110 made of the same standard and the Spacer 120 is installed as a periphery between the plate glass 110 to enable a multi-layered structure of the plate glass 110, and corner connectors for connecting and fixing the corner portion of the spacer 120 to be assembled in a rectangular frame shape It consists of 130.

Here, the spacer 120 is filled with an absorbent (121) such as silica gel inside the substantially rectangular shape having an internal hollow shape, the electrode layer 122 is coated on the surface of the lead wire (for conduction) It is preferable to connect the 140 to form an electrode in the spacer 120.

The plate glass 110 can be used in a variety of selection, such as transparent and translucent glass or color coated glass.

In addition, by installing a heating wire 150 on the inner surface of the plate glass 110 may be configured to improve the efficiency of preventing condensation on the inner surface of the plate glass 110, the lead wire for power supply is connected to the spacer 120 The power supply may be made through the lead wire 140 connected to form an electrode.

At this time, the heating wire 150 is preferably configured to have a moisture-proof function to be resistant to moisture and to have an excellent visible light transmittance, and the heat radiation 150 is additionally formed with a solar dust collecting layer to heat through power supply It can also be configured to make its own heat dissipation using solar heat rather than divergence.

Accordingly, heat is formed around the plate glass 110 by forming an electrode layer 122 on the surface of the spacer 120 and forming an electrode in the spacer 120 itself through a configuration in which the lead wire 140 is electrically connected. It is possible to effectively remove moisture present in the surroundings, as well as to prevent cold air transfer to the spacer 120 due to the temperature difference between the indoor and outdoor sides of the corner connector 130 side in the spacer 120 It is possible to effectively prevent the occurrence of condensation, which often occurs, thereby resulting in prevention of condensation diffusion and improvement of adiabatic effect.

In addition, by dissipating heat to the inner surface of the plate glass 110 through the configuration in which the heating wire 150 is installed on the inner surface of the plate glass 110, condensation that may occur on the inner surface of the plate glass 110 can be effectively prevented and the spacer 120 In addition to the moisture absorbent 121 is filled in) to double the moisture removal effect can improve the effect of preventing dew condensation, which can also lead to an improvement in the thermal insulation effect.

In addition, the heat ray 150 may have a solar dust collecting function according to the addition of the solar dust collecting layer, thereby achieving self heat dissipation according to the solar dust collecting, thereby improving energy efficiency.

In conclusion, the conventional double layer for windows is made possible by removing moisture throughout the plate glass 110 through the electrode layer 122 formed on the surface of the spacer 120 and the heating wire 150 provided on the inner surface of the plate glass 110. Not only can it compensate for the weaknesses of glass, but it also has a better effect to prevent condensation.

On the other hand, the manufacturing process of the multi-layered glass 100 for the window according to the present invention corresponds to a known technique, so a detailed description of the manufacturing process will be omitted.

As described above, the multilayer glass for windows 100 according to the present invention has been described with reference to specific embodiments of the accompanying drawings, but the present invention is not limited to the specific embodiments of the detailed description and the accompanying drawings. Various modifications can be made within the scope of the technical idea of the invention.

As described above, according to the multilayer glass for windows according to the present invention, the electrode layer is formed on the surface of the spacer bonded to the periphery between the plate glass, and the lead wire for conduction is connected so that the electrode is formed on the spacer. It is possible to prevent the occurrence of condensation on the part, there is an excellent effect that can improve the effect of preventing condensation on the inner surface of the plate glass by installing a heating wire to the inner surface of the plate glass.

In addition, heat dissipation is achieved at the periphery and the inner surface of the plate glass, which leads to an increase in heat insulation effect, and has a very useful effect of improving energy efficiency by having a solar dust collecting function on the heating wire.

Claims (3)

In the laminated glass 100 for a window comprising a spacer 120 bonded to the periphery between the plate glass 110 to enable a multi-layer structure of the plate glass 110, A multilayer glass for windows, characterized in that the electrode layer 122 is formed on the surface of the spacer 120 to form a coating, and lead wires 140 are connected to each other so that an electrode is formed on the spacer 120. The method of claim 1, Laminated glass for a window, characterized in that the heating wire 150 is installed on the inner surface of the plate glass (110). The method of claim 2, The double layer glass for the window, characterized in that the heating wire 150 is formed to form a solar dust collecting layer, the heat dissipation using its own heat.