KR102034489B1 - Low vacuum double layer glass and making method thereof - Google Patents

Abstract

The present invention includes: a plurality of panes which are formed in the same or similar size and shape and are arranged to maintain an interval; a bonding film which is attached to the edge of the pane and forms a low vacuum layer at an interval between the panes by bonding the edges of the panes to each other while melting by a heating process; and a spacer which maintains an interval between the panes by being interposed between the panes and is impregnated into the bonding film when the bonding film is melted as the heating process is carried out. The bonding film is formed including a synthetic resin material which is not deformed by the load of the spacer and the pane in order to maintain an interval between the bonding film and the pane by supporting the spacer when interposed between the panes with the spacer at a room temperature. At the beginning of the heating process, an air layer filled between the panes is heated and expanded to be discharged at an interval between the pane and the bonding film. A vacuum layer is formed at an interval between the panes as an interval between the panes is sealed by the bonding film while maintaining an interval between the panes by the spacer since the spacer is impregnated inside the bonding film when the heating process is carried out and the bonding film is melted. The present invention is provided to save time and money.

Description

LOW VACUUM DOUBLE LAYER GLASS AND MAKING METHOD THEREOF}

The present invention relates to a low-vacuum multilayer glass and a method for manufacturing the same, and more particularly, to manufacture a multilayer glass while joining a plurality of plate glass edges by a heating process to form a low vacuum state between the plate glass, the operation between the plate glass The present invention relates to a low-vacuum multilayer glass and a method of manufacturing the same, which can reduce the time and cost required to manufacture a multilayer glass having an air layer by omitting a fluid filling process.

In general, in order to mine or ventilate ground structures such as single-family houses, apartments, and buildings, window systems are required for the purpose of keeping warm, soundproofing, and viewing.

The windows used in window systems use double glazed windows laminated with two sheets of glass for insulation, and these double glazings come in many varieties depending on the spacing between the two glasses and the way in which the spacing between them is handled.

Double-glazed windows are simply joined together so that a certain gap is formed between opposite surfaces of the two glasses, called pair glass.

The pair glass maintains the air layer remaining in the space secured between the two glasses as it is, the heat insulating performance by the air layer is inferior, it is not possible to prevent heat transfer loss by the air layer.

In order to make up for the shortcomings of the double-glazed windows, a vacuum window glass has been developed in which a vacuum state having a very low thermal conductivity is formed in the space between the glasses.

At this time, the degree of vacuum formed is about 10 ^-5 Torr, which is a level capable of almost completely preventing heat loss caused by tropical flow and conduction of gas or air in the space between the glass of the double glazing.

This prior art vacuum window glass is sealed with a sealing material in order to vacuum the space where the spacers are disposed between the double panes, and exhausts the inner air through the exhaust tube formed in the pane of one side to be in a reduced pressure state. Are manufactured.

Such a glass window glass reduces the heat transfer loss of a conventional double glass window, but only serves to take heat out of the sun and flow it out, and there is no example of converting energy into electric power to increase energy efficiency of a building. .

In order to solve the above problems, a vacuum multilayer glass has been developed, and the vacuum multilayer glass according to the prior art, in a vacuum multilayer glass in which a plurality of plate glass is laminated to form an outer window and an inner window, an outer transparent substrate which is an outer window, It includes a working electrode substrate of the dye-sensitized solar cell module including the inner transparent substrate formed by the inner window of the outer transparent substrate, the outer transparent substrate and the inner transparent substrate is spaced at regular intervals, between the outer transparent substrate and the inner transparent substrate Sealed in a vacuum state.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-2014-0080568 (published on July 01, 2014, the name of the invention: vacuum multilayer glass and a method of manufacturing the same).

In the multilayer glass according to the prior art, a separate process for forming a vacuum layer is performed by injecting a dye and a working electrode at intervals between the plate glass, thereby reducing the time and cost required to manufacture the multilayer glass having a vacuum layer. There is a problem that is difficult to do.

Therefore, there is a need for improvement.

The present invention is to manufacture a multi-layer glass by joining a plurality of plate glass edges by heating process to form a low vacuum state between the plate glass, and to omit the step of filling the working fluid between the plate glass to produce a multilayer glass having an air layer It is an object of the present invention to provide a low-vacuum multilayer glass and a method of manufacturing the same that can reduce the time and cost required.

The present invention comprises a plurality of plate glass which is formed in the same or similar size and shape to each other, and is spaced apart from each other; Bonding film is bonded to the edge of the glass plate, the bonding film to form a low vacuum layer in the interval between the glass plate by bonding the edge of the glass plate while melting by heating process; And a spacer interposed between the panes to maintain a gap between the panes, the spacer being impregnated into the bonding film when the heating process is performed and the bonding film is melted. And a synthetic resin material which is not deformed by the load of the spacer and the plate glass so as to support the spacer when interposed between the plate glass and maintain the gap between the plate glass and the laminated film. In this initial stage, the air layer filled between the plate glass is heated and expanded, and the air layer is discharged at an interval between the laminated film and the plate glass. When the heating process is performed, the laminated film is melted. Impregnated inside so that While maintaining a distance between the flat glass is a distance between the glass plates sealed by the adhesive film is characterized in that a vacuum layer is formed in the gap between the glass plates.

In addition, the spacer of the present invention, characterized in that it comprises a ball member which is interposed in the gap between the plate glass, the bonding film is characterized in that the insertion groove is formed on which the ball member is seated.

In addition, the spacer of the present invention, characterized in that it comprises a wire rod interposed in the gap between the pane, the wire rod is characterized in that interposed between the laminated film and the plate glass.

In addition, the spacer of the present invention is characterized in that it further comprises a reinforcing spacer made of a wire rod disposed through the vacuum layer formed between the plate glass.

In addition, the present invention, (a) seating the laminated film on the plate glass rim, the mounting step of seating the spacer on the upper surface of the laminated film; (b) a laminating step of seating the other pane of the same or similar size as the pane so as to be supported by the spacer; And (c) a heating step of supplying thermal energy to the plate glass and the bonding film to seal the edge of the plate glass while the bonding film is melted. In the initial stage of the heating step, an air layer filled between the plate glass is provided. The air layer is discharged at the interval between the laminated film and the plate while being heated and expanded, and the spacer is impregnated in the laminated film when the laminated film is melted by the heating step, so that the gap between the plate glass is caused by the spacer. It is characterized in that the gap between the plate glass is sealed by the bonding film while maintaining the vacuum layer is formed in the gap between the plate glass.

The low-vacuum multilayer glass according to the present invention and a method for manufacturing the same, omitting operations such as the step of injecting the working fluid in the gap between the plate glass and the process of coating the plate glass, and only bonded the edge of the plate glass by the heating step between the glass Since the multilayer glass is manufactured while forming the low vacuum layer at intervals, the time and cost required to manufacture the multilayer glass are reduced.

In addition, the low-vacuum multilayer glass according to the present invention and a method for manufacturing the same are bonded to the laminated film between the plurality of plate glass edges, the spacer is placed on the laminated film and then the heating step is carried out to bond the plate glass, the initial heating process proceeds The spacer maintains a gap between the adhesive film and the plate glass so that the air filled between the pair of plate glass expands and is discharged at the interval between the plate glass and the adhesive film, and when the heating process continues, the adhesive film melts and the spacer is bonded. Impregnated into the film there is an advantage that can be easily produced a low-vacuum multilayer glass that is sealed with an adhesive film while the gap between the plate glass is maintained by the spacer.

1 is an exploded perspective view showing a low-vacuum multilayer glass according to a first embodiment of the present invention.
Figure 2 is a perspective view showing a seating state of the laminated film of the low vacuum multilayer glass according to the first embodiment of the present invention.
3 is a cross-sectional view showing an adhesive state of the low-vacuum multilayer glass according to the first embodiment of the present invention.
Figure 4 is an enlarged view showing the insertion groove of the low vacuum multilayer glass according to the first embodiment of the present invention.
5 is a perspective view showing a laminated film and a spacer of a low vacuum multilayer glass according to a second embodiment of the present invention.
6 is a perspective view illustrating a laminated film and a spacer of a low vacuum multilayer glass according to a third embodiment of the present invention.

Hereinafter, an embodiment of a low vacuum multilayer glass and a method of manufacturing the same according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom.

Therefore, the definitions of these terms should be made based on the contents throughout the specification.

1 is an exploded perspective view showing a low-vacuum multilayer glass according to a first embodiment of the present invention, Figure 2 is a perspective view showing a seating state of the laminated film of a low-vacuum multilayer glass according to a first embodiment of the present invention 3 is a cross-sectional view illustrating an adhesive state of the low vacuum multilayer glass according to the first embodiment of the present invention, and FIG. 4 is an enlarged view illustrating an insertion groove of the low vacuum multilayer glass according to the first embodiment of the present invention. to be.

1 to 4, the low-vacuum multilayer glass according to an embodiment of the present invention is formed of the same or similar size and shape to each other, a plurality of plate glass 10 and the interval spaced apart, the plate glass ( 10) between the laminated film 20 and the plate glass 10, which is bonded to the edge, and the edge of the plate glass 10 is bonded to each other while being melted by the heating process to form a low vacuum layer in the interval between the plate glass 10 Interposed to maintain the gap between the plate glass 10, the heating process is progressed to include a spacer 30 that is impregnated into the laminated film 20 when the laminated film 20 is melted.

As shown in FIG. 1, the plate glass 10 includes a plurality of plates to be positioned to face each other in order to make a vacuum glass, and it is preferable to use a plate glass molded in a rectangular plate shape.

At this time, the plate glass 10 can be used by applying a variety of thickness, but to prevent damage even in the heat fusion process of the bonding film 20, even if installed in the building 4 ~ 10mm to achieve the original function of the vacuum glass It is preferable to form the plate glass 20 to form a thickness within.

In addition, the laminated film 20 is to use a PVB (Polyvinyl Butyral) film that is used as a sealing material, in the present invention, when bonding a plurality of glass plates 10 facing each other, the laminated glass is made It is used for the use of the adhesive agent which arrange | positions as shown in FIG. 1 between (10), and joins the plate glass 10. As shown in FIG.

For example, the bonding film 20 is to be thermally fused between the plate glass 10 to be bonded by using a melting property when heat is applied, and although not described in detail in the present invention, a conventional polybutyral film, Polyvinyl Butyral Film A film called as can be used.

In particular, the bonding film 20 is formed to form a border shape formed along the outer edge of the plate glass 10, as shown in FIG. ) To form a junction.

In addition, the bonding film 20 may use a variety of thickness of the bonding film 20, but is formed to form a thickness within 1 ~ 5mm does not lead to a problem that does not excessively open or open between the plate glass 10 is laminated. It is to be prevented, and to facilitate the heat fusion process by the heat transferred.

On the other hand, the spacer 30 is to be placed in close contact with one side of the bonding film 20 so that the bonding film 20 can be supported while wrapping the outside of the spacer 30 in the thermal fusion process of the bonding film 20, It is comprised so that it may be located along the edge length direction of the plate glass 10 by which bonding is performed.

Spacer 30 is, as shown in FIG. 1, when the bonding film 20 is positioned between the plate glass 10 facing each other, the heat transfer transfer the bonding film 20 through the process of fusion, In order to prevent the inner surface of the plate glass 10 to be bonded in the process of melting the bonding film 20, a plurality of spacers 30 are arranged at intervals along the edge length direction of the bonding film 20 is In the bonding process of the plate glass 10 through thermal fusion of the bonding film 20 is to prevent the contact of the edge of the plate glass 10 to be bonded to prevent the defect due to the adhesion of the plate glass 10.

For example, as shown in FIG. 3, when the plate glass 10 to be laminated is disposed to face each other, and the laminated film 20 and the spacer 30 are positioned between the plate glass 10 to face the vacuum glass. Air between the panes 20 expands in volume due to the heat transferred, thereby naturally being discharged to the outside of the glass through the gap between the laminated film 20 formed by the spacer 30 and the pane 10. , The laminated film 20 positioned between the plate glass 20 is fused by the heat transmitted and firmly bonds the plate glass 10 made contact with each other, in this process is located on one surface of the laminated film 20 When the spacer 30 is impregnated into the molten laminated film 20, the spacer 30 is fixed, thereby maintaining the gap between the plate glass 10 where the bonding is performed.

When the laminated film 20 is interposed between the plate glass 10 with the spacer 30 at room temperature, the laminated film 20 supports the spacer 30 to maintain a gap between the plate glass 10 and the laminated film 20. 30) and synthetic resin material that is not deformed by the load of the plate glass 10.

Therefore, at the initial stage of the heating process, the air layer filled between the plate glass 10 is heated and expanded, and the air layer is discharged at an interval between the laminated film 20 formed by the spacer 30 and the plate glass 10, and heated. When the process proceeds and the laminated film 20 is melted, the spacer 30 is impregnated into the laminated film, so that the gap between the glass panes 10 is maintained by the spacer 30 and the plate glass 10 is held by the laminated film 20. The gap between them is sealed so that a vacuum layer is formed in the gap between the panes 10.

The spacer 30 of the present embodiment includes a ball member interposed at the interval between the plate glass 10, the bonding film 20 is formed with the insertion groove 21, the ball member is seated.

In addition, in the present embodiment, the spacer 30 is made of a metal material, thereby preventing the spacer 30 from being easily damaged by external pressure even when the spacer 30 is positioned between the plate glass 10 to be joined.

After the spacers 30 are arranged at intervals along the edge length direction of the bonding film 20, when the bonding film 20 is heat-sealed, the bonding film 20 easily wraps the outside of the spacer 30. It is possible to prevent the external exposure of the spacer 30, and to facilitate the formation of the vacuum layer 10 of the manufactured vacuum glass.

Particularly, the spacer 30 is formed of a ball member to keep the surface in contact with the inner surface of the plate glass 10 to be bonded to a minimum to prevent damage to the plate glass 10 to be bonded due to contact with the spacer 30. It is to.

In addition, the spacer 30 is configured to be coupled to the insertion groove 21 formed in the rim longitudinal direction of the bonding film 20, the diameter of the insertion groove 21 is formed smaller than the diameter of the ball member ball When the member is seated in the insertion groove 21, the ball member can maintain the state protruding toward the bonding film 20 to maintain the gap between the plate glass 10 and the bonding film 20.

Such a configuration is intended to facilitate the bonding of the bonding film 20 and the spacer 30 even when the plurality of spacers 30 are to be joined in the edge length direction of the bonding film 20, and the present invention In the bonding film 20 to form a circular or cylindrical insertion groove 21.

In addition, although illustrated and described to be inserted into the spacer 30 made of a ball member, the present invention is not limited thereto, but the plate glass 10 which is positioned and bonded to one surface of the bonding film 20 while preventing the plate glass 10 from which the bonding is performed is damaged. If the configuration can be easily spaced between the configuration of the insertion groove 21 and the spacer 30 and its coupling form can be applied in a variety of changes.

Looking at the low vacuum multilayer glass manufacturing method according to an embodiment of the present invention configured as described above are as follows.

The low vacuum multilayer glass manufacturing method according to the first embodiment of the present invention, the seating step of seating the bonding film 20 on the edge of the plate glass 10, and seating the spacer 30 on the upper surface of the bonding film 20, A lamination step of seating another plate glass 10 having the same or similar size as that of the plate glass 10 so as to be supported by the spacer 30, and supplying thermal energy to the plate glass 10 and the bonding film 20 to the bonding film 20. The melting step includes a heating step of closing the rim of the plate glass 10.

In the initial stage of the heating step of the present embodiment, the air layer filled between the plate glass 10 is heated and expanded, and the air layer is discharged at an interval between the laminated film 20 formed by the spacer 30 and the plate glass 10. .

Thereafter, when the heating step is further progressed and the bonding film 20 is melted, the spacer 30 is impregnated into the bonding film 20, and thus the space between the glass panes 10 is maintained by the spacer 30. The gap between the panes 10 is sealed by 20 to form a vacuum layer at the gap between the panes 10.

As described above, in the present embodiment, since the heating process is performed while the gap between the panes 10 is opened to some extent, the air layer provided between the panes 10 is expanded at the initial stage of the heating process, and the spacer 30 is expanded. Is discharged at intervals between the plate glass 10 and the laminated film 20 formed by the), and when the heating process is further progressed, as the laminated film 20 is melted, the spacer 30 is impregnated into the laminated film 20. , While the bonding film 20 is fused to the edge of the pair of plate glass 10 facing each other to close the gap between the plate glass 10.

Therefore, as in the prior art, a separate process of discharging the air layer between the plate glass 10 while closing the gap between the plate glass 10 is omitted, and the process of filling the gap between the plate glass 10 other than the working fluid other than air Since it is omitted, the time and cost required to manufacture the multilayer glass forming the vacuum layer can be significantly reduced.

5 is a perspective view illustrating a laminated film and a spacer of a low vacuum multilayer glass according to a second embodiment of the present invention, and FIG. 6 is a bonded film and a spacer of a low vacuum multilayer glass according to a third embodiment of the present invention. Perspective view.

5 and 6, the spacer 30 of the low-vacuum multilayer glass according to the second embodiment of the present invention includes a first wire rod interposed between the panes 10, and the first wire rod It is interposed between the laminated film 20 and the plate glass 10.

Therefore, since the spacer 30 made of the first wire is placed in the longitudinal direction on the upper surface of the bonding film 20 bonded in a band shape along the edge of the plate glass 10, the gap between the plate glass 10 is more firmly supported. You can do it.

In addition, the spacer 30 of the low-vacuum multilayer glass according to the third embodiment of the present invention further includes a reinforcing spacer 32 made of a second wire disposed through the vacuum layer formed between the plate glass 10. Therefore, a plurality of seating grooves 22 are formed on the inner edge of the bonding film 20 so as to face each other in the horizontal or vertical direction, and the seating grooves 22 are formed in the horizontal or vertical direction of the plate glass 10 to be laminated. The reinforcing spacers 32 are arranged to be installed further.

The reinforcement spacer 32 is configured to prevent the inner surface of the plate glass 10 to be joined between the glass panes 10 to be bonded, and to facilitate the coupling process of the reinforcement space 32. As described above, the inner edge of the bonding film 20 is formed by forming a plurality of seating grooves 22.

Since the seating groove 22 restrains both ends of the reinforcing spacer 32 so that the seating groove 22 is seated at the correct position, the reinforcing spacer 32 installed at the gap between the pair of the panes 10 protrudes outward from the end of the pane 10. It is possible to prevent the malfunction of the installation.

Thus, a plurality of plate glass edges are joined by a heating process to form a low vacuum state between the plate glass to produce a multilayer glass, and to omit the step of filling the working fluid between the plate glass is required to produce a multilayer glass having an air layer. It is possible to provide a low-vacuum multilayer glass and a method for manufacturing the same, which can reduce the time and cost.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Will understand.

In addition, the low-vacuum multilayer glass and its manufacturing method have been described as an example, but this is merely exemplary, and the glass of the present invention and the method of manufacturing the same may be used for other products other than the low-vacuum multilayer glass and its manufacturing method.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: plate glass 20: laminated film
21: insertion groove 22: seating groove
30 spacer 32 reinforcement spacer

Claims (5)

A plurality of panes formed in the same or similar size and shape to each other and disposed at intervals;
Bonding film is bonded to the edge of the glass plate, the bonding film to form a low vacuum layer in the gap between the glass plate by bonding the edge of the glass plate while melting by heating process; And
Interposed between the panes to maintain a gap between the panes, and including a spacer which is impregnated into the laminated film when the heating process is performed to melt the laminated film,
The laminated film is a synthetic resin material that is not deformed by the load of the spacer and the plate glass so as to maintain the gap between the plate glass and the laminated film to support the spacer when interposed between the plate glass and the spacer at room temperature It is made, including
In the initial stage of the heating process, the air layer filled between the plate glass is heated and expanded to discharge the air layer at an interval between the laminated film and the plate glass,
When the heating process is performed and the laminated film is melted, the spacer is impregnated in the laminated film, so that the gap between the plate glass is sealed by the laminated film while the gap between the plate glass is maintained by the spacer. At the interval of the vacuum layer is formed,
The spacer includes a reinforcing spacer comprising a first wire interposed in the gap between the plate glass so as to be interposed between the laminated film and the plate glass, and a second wire disposed through a vacuum layer formed between the plate glass. ,
Since the first wire is seated long in the longitudinal direction on the upper surface of the bonding film bonded in a band shape along the edge of the plate glass to support the gap between the plate glass,
A plurality of seating grooves are formed on the inner edge of the bonding film so as to face each other in a horizontal or vertical direction, and the seating grooves are provided with the reinforcing spacers transverse to the horizontal or vertical direction of the plate glass to be laminated.
Since the seating recess restrains both ends of the reinforcing spacer to be seated at the correct position, the reinforcing spacer installed in the gap between the pair of the panes may prevent misoperation to be protruded to the outside of the pane end. Low vacuum multilayer glass, characterized in that.
delete delete delete (A) a seating step of seating the laminated film on the plate glass rim, the seating spacer on the upper surface of the laminated film;
(b) a laminating step of seating the other pane of the same or similar size as the pane so as to be supported by the spacer; And
(c) a heating step of supplying thermal energy to the plate glass and the bonding film to seal the edge of the plate glass while melting the bonding film,
In the initial stage of the heating step, the air layer filled between the plate glass is heated and expanded to discharge the air layer at an interval between the laminated film and the plate glass,
When the laminated film is melted by the heating step, the spacer is impregnated in the laminated film, and thus the gap between the plate glass is sealed by the laminated film while the gap between the plate glass is maintained by the spacer. At the interval of the vacuum layer is formed,
The spacer includes a reinforcing spacer comprising a first wire interposed in the gap between the plate glass so as to be interposed between the laminated film and the plate glass, and a second wire disposed through a vacuum layer formed between the plate glass. ,
Since the first wire is seated long in the longitudinal direction on the upper surface of the bonding film bonded in a band shape along the edge of the plate glass to support the gap between the plate glass,
A plurality of seating grooves are formed on the inner edge of the bonding film so as to face each other in a horizontal or vertical direction, and the seating grooves are provided with the reinforcing spacers transverse to the horizontal or vertical direction of the plate glass to be laminated.
Since the seating recess restrains both ends of the reinforcing spacer to be seated at the correct position, the reinforcing spacer installed in the gap between the pair of the panes may prevent misoperation to be protruded to the outside of the pane end. Low-vacuum multilayer glass manufacturing method, characterized in that.

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