JPH07330386A - Multiple glass - Google Patents

Abstract

PURPOSE:To provide multiple glass which can develop high fireproof performance as it maintains conventional moistureproofness. CONSTITUTION:A plurality of glass plates 1, 2 are laminated in such a manner that they leave spaces between them through spacers 3 in the thickness direction and seal layers 4, 5 are placed between the glass plates 1, 2 and the spacer 3 to form a tightly closed space A between a plurality of the glass plates. Hereupon, at least one 5 of the glass plates 1, 2 is made of fireproof and fire- resistant glass, while the other glass plate are made of tempered one.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention laminates a plurality of plate glasses at intervals in the thickness direction via spacers, and a seal layer is interposed between the plate glasses and the spacers. The present invention relates to a multi-layer glass in which a hermetically sealed space is formed between the plurality of glass sheets and at least one of the glass sheets is made of fireproof and fireproof glass sheet.

[0002]

2. Description of the Related Art Conventionally, in this type of double glazing, at least one of the plurality of glass plates is made of a fireproof and fireproof glass plate in order to seal between the glass plates to form a closed space. The only thought was to improve performance.

[0003]

However, normally, in order to form a closed space by sealing between plate glasses, a seal layer is formed between the plate glasses by using butyl rubber or the like. Therefore, when exposed to high heat such as a fire occurring in the space on one side that is partitioned by the double glazing, flammable gas is generated from the sealing layer, and flammable gas is generated in the closed space. When the plate glass on the other side of the double-glazing is filled with cracks due to the high heat, a high concentration of combustible gas leaks from the cracks and flows into the space on the other side partitioned by the double-glazing. In addition, it may ignite in contact with a large amount of fresh air and cause the fire to spread to the space on the other side or spread to the seal layer to spread the fire. Because there is, much higher fire performance has been desired.

Therefore, it is conceivable to use a material that does not easily generate a flammable gas for the seal layer, but generally, when moisture penetrates between the plate glasses constituting the double glazing, dew condensation or clouding occurs inside the sealed space. Or inconvenience,
Since the double-layered glass has a drawback that its commercial value is extremely low, it is essential that the sealing layer has high waterproofness, while a material that does not easily generate flammable gas is Since the waterproof property is usually low, it is difficult to improve the fireproof property while maintaining the waterproof property.

In addition, when the plate glass on the fire occurrence side is broken, the plate glass fragments fall off, the sealing action in the peripheral portion of the double-glazed glass is lost, and a holding frame body is formed in the peripheral portion of the plate glass on the other side. A gap may be formed between the two, and the flame may infiltrate into the space on the other side to spread the fire and spread the fire.

Therefore, in view of the above situation, an object of the present invention is to provide a double glazing which exhibits high fireproof performance while maintaining the conventional moistureproof property.

[0007]

A feature of the present invention for achieving this object is that plate glass other than fireproof and fire resistant plate glass among a plurality of plate glasses is made of heat strengthened glass, The effects are as follows.

[0008]

In other words, since the plate glass other than the fireproof and fire resistant plate glass among the plurality of plate glasses is made of heat strengthened glass, even if the double glazing is heated by a fire or the like,
Since the heat-strengthened glass is interposed in the thickness direction, the heat-strengthened glass can block the flame without breaking, and the fireproof performance is improved. Further, even if the double glazing is heated by a plate glass other than the heat-strengthened glass, the following effects are exerted, so that it is possible to prevent the flammable gas from igniting and causing calcination.

The opposite side of the heat-strengthened glass on the side opposite to the side close to the source of the fire and likely to be heated to a high temperature (hereinafter, the surface exposed to the high temperature when the fire occurs is simply referred to as the heating surface side). (Hereinafter, simply referred to as the non-heated surface side), even if combustible gas is generated from the sealing layer due to high heat, even if the combustible gas is filled in the sealed space, The heat-strengthened glass withstands high heat, and makes it difficult for the combustible gas to flow out into the space on the other side different from the source of the fire. Further, even if it breaks without being able to endure high heat, normal heat-strengthened glass becomes fine fragments when it breaks, and falls, so that the enclosed space in the double-glazing glass is broken when the heat-strengthened glass breaks. At the same time, it is opened to the space on the other side, and the flammable gas filled in the closed space is released at one time and diluted to a low concentration that is difficult to ignite, so that the fire on the heating surface side is on the non-heating surface side. There is little danger of burning the fire.

Further, when the heat-strengthened glass is applied to the heating surface side, even if it breaks, it becomes a fine piece,
In the peripheral part of the double glazing, fine fragments are easily retained without falling off, and since it is difficult to create a gap between the peripheral part of the plate glass on the other side and the holding frame, the flame enters the space on the other side. It is unlikely that calcination will occur (for example, when the double glazing is fixed to the holding frame, and when the normal plate glass breaks and falls off on the heating surface side, the fragments are large, so gravity causes the frame to fall out of the frame. While slipping out, a gap is generated in the frame and the plate glass on the other side rattles, whereas when it becomes a thin piece as described above, the small piece is held without falling out of the frame, and between the holding frame There is no gap in the plate glass on the other side and it is difficult for it to rattle.

[0011]

Therefore, since the double glazing of the present invention has improved fireproof performance, it can be used as a window glass or a door that is unlikely to catch fire even if a fire occurs, and is useful in terms of disaster prevention.

Therefore, by improving the fireproof performance, it becomes easy to apply the double glazing not only as the type-II fire door but also as the type-A fire door.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIGS. 1 and 2, the double glazing of the present invention is
Heat-strengthened glass 1 and wire-reinforced glass 2 with wire net inside
And are arranged in parallel with each other with the spacer 3 interposed therebetween, and the first sealing material 4 is interposed between the spacer 3 and the heat-strengthened glass 1 and the mesh-filled glass 2, and the heat-strengthened glass 1 and the mesh-filled glass 2 are provided. In between, a second sealing material 5 is interposed outside the first sealing material 4, and a hermetically sealed space A is formed between the heat-strengthened glass 1 and the wire-reinforced glass 2 to form a multi-layer glass. At the same time, the sash frame 7 built in the structure is fitted and fixed.

The first seal material 4 is made of polyisobutylene, and the second seal material 5 is made of polysulfide material. The heat-strengthened glass has a thickness of 3.2.
About 1000kg by heat treatment of plate glass of mm or more
f / cm ^{2 to} 2000 kgf / cm ² (100 MN / m ²
A surface compressive force of about 200 MN / m ² ) is applied.

The spacer 3 is made of aluminum and is formed into a ring shape around the entire periphery of the heat-strengthened glass 1. The cross-sections show both lateral surfaces (the heat-strengthened glass 1 and the meshed glass 2). It is O-shaped with a constriction 8 formed on the opposing surface), an opening 9 is formed on the closed space A side, and a desiccant 10 is filled inside the opening 9.
Thereby, the first seal member 4 is easily held in the constriction 8.

[Other Embodiment] Another embodiment will be described below.
In the previous embodiment, it was fitted into the built-up sash, but FIG.
As shown in FIG. 7, while the double-layer glass is fitted and attached to one of the concave portions of the frame body 17 having an H-shaped cross section,
If the insert member 18 having a tapered surface is fitted into the other concave portion of the above and the double glazing is attached, the frame body 17 is expanded and deformed as the insert member 18 is fitted, and the double glazing is placed on the opposite side. By using the effect of deforming by tightening, it is possible to form a strong sealing property and firmly, and further improve the fire prevention performance.

Further, as shown in FIG. 4, heat-strengthened glass 1a
And the reticulated glass 2 and the heat-strengthened glass 1b are arranged in parallel via the spacers 3 and 3, and the spacer 3 and the heat-strengthened glass 1a and 1b and the spacer 3 are placed between the reticulated glass 2 and One sealing member 4 is interposed, and a second sealing member 5 is interposed between the heat-strengthened glass 1a, 1b and the mesh-filled glass 2 outside the first sealing member 4 so that A closed space A may be formed between the glass 2 and the meshed glass to form a double glazing.

In such a case, first, until the heat-strengthened glass 1a (1b) on the heating surface side is broken by heat,
Since heat is less likely to be transmitted to the heat-strengthened glass 1b (1a) on the non-heating surface side, there is an advantage that the structure has a higher fireproof property.

The spacer 3 is not necessarily made of aluminum and may be made of iron. In such a case, the spacer 3 has a large weight, but has a structure more rich in fire resistance. Further, the shape is not limited to the above-mentioned embodiment, and may be a quadrangular cross section. Also, the value of the surface compressive stress of the heat strengthened glass,
The materials of the first and second sealing materials 4 and 5 are not limited to those in the previous embodiment, and the value of the surface compressive stress is about 7
00-1000 kgf / cm ² (70-100 MN /
A heat-strengthened glass having a surface compressive stress of about m ² ) may be used, and a flame-retardant silicone sealing material is used as the second sealing material 5, and deformation such as further improvement of fireproof performance can be performed. In the embodiment, the first and second sealing materials 4 and 5 are referred to as a sealing layer.

Further, in the above-mentioned embodiments, the net-cored glass having the wire net inside is used, but the present invention is not limited to this, and the wire-containing glass in which the wires are arranged in parallel, the low expansion crystallized glass, Reinforced borosilicate glass or the like can be used, and in short, any material can be used as long as it can be prevented from falling down by the heat of a fire or the like, and these are collectively referred to as fire and fire resistant plate glass.

It should be noted that reference numerals are added to the claims for convenience of comparison with the drawings, but the present invention is not limited to the configurations of the accompanying drawings by the entry.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional view showing a mounting structure for double glazing of the present invention.

FIG. 2 is a vertical cross-sectional view of the main part of the double glazing of the present invention.

FIG. 3 is a vertical cross-sectional view of the main part of the double-glazing unit in another embodiment.

FIG. 4 is a vertical cross-sectional view of the main part of the double-glazing unit in another embodiment.

[Explanation of symbols]

 1, 2 Plate glass 3 Spacer 4, 5 Seal layer A Sealed space

Claims (3)

[Claims] 1. A plurality of plate glasses (1), (2) are laminated at intervals in the thickness direction through spacers (3) over the entire circumference thereof to form the plate glasses (1), (2). Sealing layers (4) and (5) are interposed between the spacers (3) to form a closed space (A) between the plurality of plate glasses (1) and (2), and the plurality of plate glasses ( A multilayer glass in which at least one plate glass (2) of (1) and (2) is composed of a fireproof and fireproof plate glass, and a plate glass other than the fireproof and fireproof plate glass among the plurality of plate glasses (1 ) Is a double glazing composed of heat strengthened glass. 2. The double glazing according to claim 1, wherein the sealing layer is made of a butyl rubber sealing material. 3. The double glazing according to claim 1 or 2, wherein the fireproof and fireproof plate glass is made of any one of wire-containing glass, low expansion crystallized glass and tempered borosilicate glass.