JP2003268907A - Fire-preventive glass panel structure and execution method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fire-preventive glass panel structure and an execution method therefor, which can enhance beauty and can maintain flame interruption performance of fire-preventive glass. <P>SOLUTION: This fire-preventive glass panel structure 100 is composed of a plurality of pieces of the fire-preventive glass 10, in which a side part is locally supported by a metallic material 12 and which are fixed in a grid pattern via joint parts 30. The joint part 30 is composed of a hollow gasket 51 which is formed in a grid pattern so as to fix the pieces of the glass 10; and the hollow gasket 51, which is made of silicon-based rubber excellent in fire resistance and adhesion to the glass 10, has a hollow part 52 whose inside is filled with a foamed material and paired fin parts 53 which are provided on both sides of the hollow part 52, so as to house an edge of the glass 10. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fireproof glass panel structure and its construction method.

[0002]

2. Description of the Related Art Fireproof glass includes a "heat-resistant plate glass" that prevents damage to the glass and prevents the entry of flames, and a metal mesh inserted inside the glass that holds glass fragments and prevents the entry of flames. There is such a "contained plate glass" and the like. Such a fireproof glass is regulated by the fireproof standard construction method so that it can be used as a fireproof facility having a fireproof performance of 20 minutes or more.

A fireproof glass panel structure composed of a plurality of fireproof glasses has a structure as shown in FIG.
In addition to fitting 0 into the grooves of the lattice-shaped sash frame 11,
As shown in FIG. 7, a non-combustible backup material 20 and a sealing material 21 are provided in the gap between the fireproof glass 10 and the sash frame 11 in order to prevent the burnout from occurring in the gap between the fireproof glass 10 and the sash frame 11. It is manufactured by filling.

On the other hand, a glass panel structure of high aesthetics in which the exposure of the sash frame 11 is suppressed as much as possible has become popular recently, and a fireproof glass panel structure of this type is desired.

[0005]

However, in the fireproof glass panel structure 100 in which the sash frame 11 is exposed as much as possible, the sealing material 21 is ignited during a fire or the sealing material 21 is deformed when the fireproof glass 10 is deformed. There was a problem that a gap was created due to the failure to follow and the flame shielding performance was impaired.

For example, when a heat-resistant glass plate is used as the fireproof glass 10 in the fireproof glass panel structure 100, the degree of thermal deformation of the adjacent fireproof glasses 10 is different, so that the joints between the fireproof glasses 10 are displaced to form a gap. The problem that the sealing material 21 burns out and impairs the flame-shielding performance, and when using a corrugated sheet glass as the fireproof glass 10 in the fireproof glass panel structure 100, the joints between the glasses shift due to the cracking of the glass at the time of fire and a gap is created. However, there is a problem that the flame shielding performance is impaired.

An object of the present invention is to provide a fireproof glass panel structure capable of enhancing the aesthetic appearance and maintaining the flameproof performance of the fireproof glass, and a method of constructing the same.

[0008]

In order to achieve the above-mentioned object, a fireproof glass panel structure according to claim 1 has a plurality of rectangular fireproof glasses, and a support means for supporting the plurality of fireproof glasses. In the fireproof glass panel structure including the above, the plurality of fireproof glasses are fixed in a lattice shape through joints, and the joints are made of predetermined joint members.

According to the fireproof glass panel structure of the first aspect, since the plurality of fireproof glasses are fixed in a grid pattern through the joints, and the joints are made of predetermined joint members,
It is possible to enhance the aesthetic appearance and maintain the flameproof performance of the fireproof glass.

The fireproof glass panel structure according to claim 2 is the fireproof glass panel structure according to claim 1,
The predetermined joint member is a hollow gasket having a foam material in a hollow portion.

According to the fireproof glass panel structure of the second aspect, since the predetermined joint member is the hollow gasket having the foamed material in the hollow portion, the flameproof performance of the fireproof glass can be reliably maintained.

The fireproof glass panel structure according to claim 3 is the fireproof glass panel structure according to claim 2, wherein
The hollow gasket is made of silicone rubber.

According to the fireproof glass panel structure of the third aspect, since the material of the hollow gasket is silicon rubber, it is possible to secure fire resistance and adhesiveness with the fireproof glass.

The fireproof glass panel structure according to claim 4 is the fireproof glass panel structure according to claim 2 or 3, characterized in that the foam is made of a carbon material.

According to the fireproof glass panel structure of the fourth aspect, since the foam material is a carbon-based material,
The influence on the glass member can be reduced.

A fireproof glass panel structure according to claim 5 is the fireproof glass panel structure according to any one of claims 2 to 4, wherein the foam material has a volume expansion ratio of 3
It is characterized by being more than double.

According to the fireproof glass panel structure of claim 5, since the foam has a volume expansion multiple of 3 times or more,
Stable flame shielding performance can be obtained.

The fireproof glass panel structure according to claim 6 is the fireproof glass panel structure according to claim 5, wherein
The foam material has a volume expansion ratio of 6 to 8 times.

According to the fireproof glass panel structure of claim 6, since the foam has a volume expansion multiple of 6 to 8,
Further, stable flame shielding performance can be obtained.

The fireproof glass panel structure according to claim 7 is the fireproof glass panel structure according to any one of claims 2 to 6, wherein the foam has an expansion start temperature of 3 or less.
It is characterized by being 50 ° C. or lower.

According to the fireproof glass panel structure of the seventh aspect, since the expansion start temperature of the foam is 350 ° C. or lower, stable flame shielding performance can be obtained from the early stage of the fire.

The fireproof glass panel structure according to claim 8 is the fireproof glass panel structure according to claim 7, characterized in that the foam has an expansion start temperature of 200 ° C.

According to the fireproof glass panel structure of claim 8, since the expansion start temperature of the foam is 200 ° C.,
More stable flame shielding performance can be obtained from the early stage of the fire.

The fireproof glass panel structure according to claim 9 is the fireproof glass panel structure according to claim 1, wherein
The predetermined joint member is a sealing material.

According to the fireproof glass panel structure of the ninth aspect, since the predetermined joint member is the sealing material, the flameproof performance of the fireproof glass can be reliably maintained.

The fireproof glass panel structure according to claim 10 is the fireproof glass panel structure according to claim 9,
The sealing material has a thickness of 8 mm or more.

According to the fireproof glass panel structure of the tenth aspect, since the sealing material has a thickness of 8 mm or more, the ashing rate of the sealing material can be suppressed.

The fireproof glass panel structure according to claim 11 is the fireproof glass panel structure according to claim 9 or 10, characterized in that the sealing material has a width of 25 mm or less.

According to the fireproof glass panel structure of the eleventh aspect, since the width of the sealing material is 25 mm or less, it is possible to prevent the joint member from contracting in volume by the heat of the flame and falling from between the fireproof glasses. be able to.

A fireproof glass panel structure according to claim 12 is the fireproof glass panel structure according to any one of claims 9 to 11, wherein the sealing material has a length of 2.7 m or less. Characterize.

According to the fireproof glass panel structure of the twelfth aspect, since the length of the sealing material is 2.7 m or less, it is possible to more reliably maintain the flameproof performance of the fireproof glass.

A fireproof glass panel structure according to a thirteenth aspect is the fireproof glass panel structure according to any one of the ninth to twelfth aspects, characterized in that the sealing material is made of a silicon-based material.

According to the fireproof glass panel structure of the thirteenth aspect, since the sealing material is made of a silicon-based material, it is possible to secure followability to the fireproof glass, weather resistance, and waterproofness.

A fireproof glass panel structure according to a fourteenth aspect is the fireproof glass panel structure according to any one of the ninth to twelfth aspects, wherein the sealing material is an expansive sealing material in which a foam material is inserted. It is characterized by being formed.

According to the fireproof glass panel structure of the fourteenth aspect, since the sealing material is the expansive sealing material in which the foaming material is inserted, the flameproof performance of the fireproof glass can be more reliably maintained. .

A fireproof glass panel structure according to a fifteenth aspect is the fireproof glass panel structure according to the fourteenth aspect, wherein the expansive sealing material has a volume expansion ratio of 3 times or more.

According to the fireproof glass panel structure of the fifteenth aspect, since the foam has a volume expansion multiple of three or more, it is possible to obtain stable flame shielding performance.

A fireproof glass panel structure according to a sixteenth aspect is the fireproof glass panel structure according to the fifteenth aspect, wherein the volume expansion ratio is 5 to 8 times.

According to the fireproof glass panel structure of the sixteenth aspect, since the foam has a volume expansion multiple of 5 to 8 times, more stable flame shielding performance can be obtained.

A fireproof glass panel structure according to a seventeenth aspect is the fireproof glass panel structure according to any one of the first to sixteenth aspects, wherein the supporting means locally forms a side portion of the fireproof glass. The feature is that it is a metal object to support.

According to the fireproof glass panel structure of the seventeenth aspect, since the supporting means is a metal article that locally supports the sides of the fireproof glass, the aesthetic appearance can be further enhanced.

A fireproof glass panel structure according to an eighteenth aspect is the fireproof glass panel structure according to the seventeenth aspect, characterized in that the metal objects are arranged on four sides of the fireproof glass at regular intervals. .

According to the fireproof glass panel structure of the eighteenth aspect, since the metal objects are arranged on the four sides of the fireproof glass at regular intervals, the fireproof glass can be stably supported.

A fireproof glass panel structure according to a nineteenth aspect is the fireproof glass panel structure according to the seventeenth aspect, characterized in that the metal objects are arranged on two sides of the fireproof glass at regular intervals. .

A fireproof glass panel structure according to a twentieth aspect is the fireproof glass panel structure according to the nineteenth aspect, characterized in that two sides of the side portion of the fireproof glass are an upper side and a lower side.

The fireproof glass panel structure according to claim 21 is the fireproof glass panel structure according to any one of claims 1 to 16, wherein the supporting means is provided on two sides of the side portion of the fireproof glass. It is characterized in that it comprises a metal piece arranged at a fixed interval and a sash frame arranged on the other two sides of the side portion.

A fireproof glass panel structure according to a twenty-second aspect is the fireproof glass panel structure according to any one of the eighteenth to twenty-first aspects, wherein the constant interval is 2 m or less.

According to the fireproof glass panel structure of the twenty-second aspect, since the constant interval is 2 m or less, the fireproof glass can be supported more stably.

A fireproof glass panel structure according to a twenty-third aspect is the fireproof glass panel structure according to the twenty-second aspect, characterized in that the constant interval is 1.6 m or less.

According to the fireproof glass panel structure of the twenty-third aspect, since the constant interval is 1.6 m or less, the fireproof glass can be supported more stably.

A fireproof glass panel structure according to a twenty-fourth aspect is the fireproof glass panel structure according to any one of the first to sixteenth aspects, wherein the supporting means is provided on two sides of the side portion of the fireproof glass. It is characterized by being a sash frame arranged.

A fireproof glass panel structure according to a twenty-fifth aspect is the fireproof glass panel structure according to the twenty-fourth aspect, wherein two sides of the fireproof glass are an upper side and a lower side.

In order to achieve the above-mentioned object, claim 26
The method for constructing a fireproof glass panel structure according to the invention has a plurality of rectangular fireproof glasses, and in a method for constructing a fireproof glass panel structure having a supporting means for supporting the plurality of fireproof glasses, the plurality of fireproof glasses is used. It is characterized in that it is fixed in a lattice shape through the joint portion and a predetermined joint member is used for the joint portion.

According to the construction method of the fireproof glass panel structure of the twenty-sixth aspect, since a plurality of fireproof glasses are fixed in a grid pattern through the joints and a predetermined joint member is used for the joints, the aesthetic appearance is improved. It is possible to maintain the flameproof performance of the fireproof glass while improving the

[0055]

BEST MODE FOR CARRYING OUT THE INVENTION The fireproof glass panel structure according to the embodiments of the present invention and the construction method thereof will be described in detail below.

FIG. 1 is a diagram showing a schematic structure of a fireproof glass panel structure according to an embodiment of the present invention.

In FIG. 1, a fireproof glass panel structure 1
00 has a side portion locally supported by a metal piece 12 shown in FIG. 5, which will be described later, and is composed of a plurality of fireproof glasses 10 fixed in a grid pattern through joint portions 30 shown in FIG. 2, which will be described later. It forms an opening with flame performance.

The fireproof glass 10 is a "heat-resistant plate glass" which prevents breakage of the glass and prevents the entry of flames, and a "netted plate glass which holds glass fragments by a metal net inserted inside the glass and prevents the entry of flames. , Etc.

The "heat-resistant plate glass" includes crystallized glass obtained by reheating lithium alumina silicate glass to uniformly deposit fine crystals throughout the glass, and glass obtained by heat-treating borosilicate glass after being cut to size. , Glass obtained by edge-polishing soda-lime glass and strengthening treatment.

FIG. 2 is a sectional view showing a schematic structure of an example of the joint portion 30 in FIG.

In FIG. 2, the joint portion 30 is a hollow gasket 5 having a lattice shape for fixing a plurality of fireproof glasses 10.
This hollow gasket 51 has a hollow portion 52 inside and a fin portion 53 of about 1 to 2 mm for accommodating the edge of the fireproof glass 10 on both sides thereof at least on one side. The hollow portion 52 is filled with a foam material inside.

The hollow gasket 51 is made of silicone rubber, and the silicone rubber has excellent fire resistance and adhesion to the fireproof glass 10. The foamed material of the hollow portion 52 is a carbon-based material, and the carbon-based material expands at around 200 ° C., and even after the expansion, the fireproof glass 10 is forced out or the fireproof glass 10 is deformed. It does not suppress the effect on the glass member.

The foam material of the hollow portion 52 needs to have a volume expansion ratio of at least 3 times or more at the time of fire, and in order to obtain more stable flame shielding performance, it is preferably 6 to 8 times. The expansion start temperature needs to be 350 ° C. or lower, and is preferably 200 ° C. in order to obtain more stable flame shielding performance from the early stage of the fire.

As the foam material of the hollow portion 52, any of carbon (graphite) type, vermiculite type and hydrous sodium silicate type materials can be used because they do not burn at the time of fire. It is most suitable from the viewpoint of weather resistance and volume expansion ratio.

FIG. 3 is a sectional view showing a schematic structure of another example of the joint portion 30 in FIG.

In FIG. 3, the joint portion 30 has a lattice-like sealing material 46 for fixing the plurality of fireproof glasses 10.
Consists of.

As the material of the sealing material 46, a flame-retardant silicon material described later or an expansive sealing material described later in which a foam material which expands by heat in a fire is inserted is used.

The case where a flame-retardant silicon material is used as the material of the sealing material 46 will be described below.

From the viewpoint of the ashing speed of the sealing material at the time of fire (the speed at which the combustible components of the sealing material 46 are oxidized to ash by the fire at the time of fire), the sealing material 46
Depth A, that is, the thickness of the fireproof glass 10 needs to be 8 mm or more, and is preferably 10 mm or more.
Further, the width B of the sealing material 46, that is, the fireproof glass 10
It is necessary that the width between them is 25 mm or less, preferably 20 mm or less, and more preferably 5 mm or more from the viewpoint of thermal expansion of the fireproof glass 10.

Further, the sealing material 46 has a length of 2.7.
m or less. Fire protection glass 1 for longer lengths
This is because the gap between 0 and the sealing material 46 is easily opened, and it becomes difficult to obtain the flame shielding performance, and a gap may be generated in the joint portion 30.

As the material of the sealing material 46, in addition to the flame-retardant silicon-based material, a paste-like ceramic bond or a fire-resistant adhesive having excellent flame-retardant performance and kneaded with a fire-resistant material such as silicon dioxide or alumina silicate. Although it can be used, a flame-retardant silicon-based material is most suitable from the viewpoints of following the deformation of the fireproof glass 10, weather resistance, and waterproofness.

The case where an expansive sealing material is used as the sealing material 46 will be described below.

The expansive sealing material was a paste-like material obtained by kneading chloroprene rubber with hydrous sodium silicate (water glass) as a foaming material together with a solvent, or a carbon-based foaming material mixed in a silicon-based sealing material. There are such things as those, and stable flame shielding performance is obtained, which is unlikely to be affected by the size of the joint portion 30.

The expandable sealing material needs to have a volume expansion ratio of at least 3 times or more in order to exhibit flame shielding performance, but in order to obtain stable flame shielding performance, the volume expansion ratio is 5-8.
Doubled and expanded from about 120 ℃ to about 200
It is desirable to expand significantly at ℃.

FIG. 4 shows the fireproof glass panel structure 1 of FIG.
It is a figure which shows the support structure of the fire prevention glass 10 in 00, (a) is (b) in the case of 4 side button metal fittings.
Is a two-sided sash fits, and two-sided button hardware fits,
(C) shows the case where the two-side button metal fittings are fitted and the two-side glass butt fitting is set, and (d) shows the two-side sash fitting and the two-side glass butt fitting is set.

In FIG. 4A, the fireproof glass structure 1
The four sides 13, 14, 15, of the fire protection glass 10 at 00,
Button-shaped metal pieces 12, which will be described later with reference to FIG. 5, are provided at 16 at a constant interval L of 1.6 m. The metal 12 supports the fireproof glass 10.

Further, in order to support the weight of the glass panel structure 100, it is necessary to connect the metal piece 12 arranged on two sides of the four sides of the fireproof glass, for example, the upper and lower two sides 13 and 14, to another structure. There is a hardware 12 on the other two sides
It suffices if the fireproof glass 10 is sandwiched.

In addition to the support means for supporting the fireproof glass 10 described above, the left and right sides of the fireproof glass 10 shown in FIG.
Supporting means composed of button-shaped metal pieces 12 arranged on the sides 15 and 16 at regular intervals L and a normal sash frame 11 fitted on the upper and lower sides 13 and 14, the fireproof glass 10 shown in FIG. Supporting means composed of button-shaped metal pieces 12 arranged on the upper and lower two sides 13, 14 at regular intervals L, and FIG.
It may be a supporting means or the like composed of an ordinary sash frame 11 fitted to the upper and lower two sides 13 and 14 of the fireproof glass 10 shown in (d).

Since the above-mentioned "netted plate glass" and "heat-resistant plate glass" have different properties in the event of a fire, the fireproof glass structure 100 suitable for each property is selected.

When the "netted plate glass" which is highly likely to be broken during a fire is used as the fireproof glass 10, at least two sides (upper and lower sides) are used as shown in FIGS. 4 (b) and 4 (d). By fitting 13 or 14 or the left and right sides 15 and 16) to the ordinary sash frame 11, the fireproof glass 10 can be held even if the glass is broken.

When the "heat-resistant glass plate" is used as the fire-proof glass plate 10, the fire-proof glass plate 10 does not crack at the time of a fire unlike the "net-cored plate glass plate". It suffices if the portion 30 is interposed, and it is not necessary to fit the fireproof glass 10 to the sash frame 11 or the like.

Any fireproof glass panel structure 1
In No. 00 as well, it is desirable that the width of the joint portion 30 is 5 mm or more in order to prevent the fireproof glasses 10 from coming into contact with each other and being damaged by thermal expansion of the fireproof glasses 10 at the time of fire.

In the present embodiment, the metal 12 is arranged at an interval of 1.6 m, but the interval is not limited to this and may be 2 m or less.

FIG. 5 is a sectional view showing a schematic structure of the metal piece 12 in FIG.

In FIG. 5, the metal piece 12 has a pair of thicknesses of 2
It is composed of metal plates 41 and 42 of mm. One end of a bolt 43 is fixed to the metal plate 42, and a hole for the bolt 43 to penetrate is provided in the metal plate 41. The pair of metal plates 41 and 42 sandwich the pair of fireproof glasses 10 with the sheet-shaped silicone rubber 45 interposed therebetween, and the pair of fireproof glasses 10 are fixed by the bolts 43 and the nuts 44.

The metal plates 41, 42, the bolts 43, and the nuts 44 may be made of metal such as aluminum, iron, and stainless steel, but stainless steel from the viewpoint of melting temperature, durability and rust prevention. Is preferred.

Further, the silicon rubber 45 can prevent the fireproof glass 10 and the metal article 12 from coming into direct contact with each other.

A non-combustible ceramic backup material may be used in place of the silicone rubber 45. In this case, a flame-retardant silicone sealing material 46 is filled in the gap between the pair of fireproof glasses 10 to prevent water leakage. Need to keep.

In the present embodiment, the thickness of the metal plates 41, 42 is 2 mm, but the thickness is not limited to this and may be 1.5 mm or more. Here, if the thickness of the metal plates 41 and 42 is 1 mm or less, the rigidity is lost due to the heat at the time of fire, and it does not play a role of suppressing the deformation of the adjacent glass.

Further, in the present embodiment, the metal piece 12 is a square having one side of 30 mm, but the size is not limited to this, and may be 30 mm or more.

Further, in the present embodiment, the metal piece 12 has a square shape, but the shape is not limited to this, and the hanging portion to the fireproof glass 10 for suppressing the movement of adjacent fireproof glasses is not limited to this. Any shape may be used as long as it is 10 mm or more, and for example, a circular shape having a diameter of 30 mm may be used.

[0092]

EXAMPLES Next, examples of the present invention will be specifically described.

First Example The present inventor firstly prepared two sheets having a thickness of 8 mm and a size of 1 m ×
In the fireproof glass structure 100, which is made of 2.4 m of fireproof glass 10 and has the joint portion 30 in the center, one side is 4
Two 0 mm square metal pieces 12 were arranged at 1.8 m intervals, and a flame-retardant silicon-based sealing material SE5007 (manufactured by Toray Dow Corning) was used for the joint portion 30 having a width of 20 mm.

Here, as the fireproof glass 10, a heat-resistant plate glass obtained by edge-polishing soda-lime glass and thermally strengthened was used.

A fireproof test of the fireproof glass structure 100 was conducted using a wall heating furnace defined in JIS A 1311.

The results of the above fire protection test will be described in detail below.

After 5 minutes from the start of heating, the fireproof glass 10 is deformed by heat in the furnace, but the joint portion 30 is made of metal 12
Since the deformation of the fireproof glass structure 100 was suppressed by the above, no flame was ejected from the joint portion 30.

Even after 5 to 20 minutes have passed since the start of heating,
As in the above case, no flame was ejected from the joint portion 30.

After 30 minutes from the start of heating, a partial gap was formed in the joint portion 30 due to the ashing of the flame-retardant silicon-based sealing material. However, this gap did not impair the basic fire spread prevention property.

Further, as a result of continuing the fireproof test, the heat deformation of the fireproof glass 10 increased 40 minutes after the start of heating and the gap of the joint portion 30 expanded, and the flame shielding performance was impaired 45 minutes after the start of heating. A gap penetrating portion was formed.

From the above, it was revealed that the fireproof glass panel structure 100 used in this example has a flameproof performance of 20 minutes required as fireproof equipment in the Building Standards Act.

Further, although the fireproof glass panel structure 100 using the heat-resistant glass obtained by strengthening the soda-lime glass having a relatively low softening point in this example has a flame shielding performance of about 45 minutes, If heat-resistant glass or the like that has been crystallized with a high softening point is used, thermal deformation due to softening of the glass can be suppressed, and thus higher flame shielding performance can be secured.

Second Embodiment Next, the inventor of the present invention has two sheets having a thickness of 10 mm and a size of 1 m ×
In a fireproof glass structure 100, which is made of 2.4 m of fireproof glass 10 and has a joint portion 30 in the center,
2 is not arranged, and the joint portion 30 having a width of 15 mm has a flame-retardant silicone-based sealing material SE5 as the sealing material 46.
007 (manufactured by Toray Dow Corning) was used.

Here, as the fireproof glass 10, a heat-resistant plate glass obtained by edge-polishing soda-lime glass and further heat-strengthened was used.

A fireproof test of the fireproof glass structure 100 was conducted using a wall heating furnace defined in JIS A 1311.

After 5 minutes from the start of heating, the fireproof glass 10 is deformed by heat in the furnace, and some deviations between the fireproof glasses 10 can be seen. However, since it is within the depth of the joint portion 30, the joint No eruption of flame was seen from the part 30.

Even after 5 to 20 minutes have passed since the start of heating,
As in the above case, no flame was ejected from the joint portion 30.

At 25 minutes after the start of heating, a partial gap was formed in the joint portion 30 due to the ashing of the flame-retardant silicon-based sealing material. However, this gap did not impair the basic flame shielding performance.

Further, as a result of continuing the fire prevention test, a large number of gaps were formed in the joint portion 30 30 minutes after the start of heating, and a gap penetrating portion which impairs the flame shielding performance was formed 35 minutes after the start of heating.

From the above, it was revealed that the fireproof glass panel structure 100 used in this example has the flameproof performance of 20 minutes required as fireproof equipment in the Building Standards Act.

Further, the fireproof glass panel structure 100 using the heat-resistant glass obtained by strengthening the soda-lime glass having a relatively low softening point in this example has a flame barrier performance of about 35 minutes, but has a softening point. If a crystallized heat-resistant glass or the like is used, it is possible to suppress thermal deformation due to softening of the glass, and thus it is possible to secure higher flame shielding performance.

Third Embodiment Next, the inventor of the present invention has two sheets of thickness 8 mm and size 1 m ×
In a fireproof glass structure 100, which is made of 2.4 m of fireproof glass 10 and has a joint portion 30 in the center,
The hollow gasket 51 made of silicon rubber having a carbon-based foam material in the hollow portion was used for the joint portion 30 having a width of 15 mm without arranging 2.

Here, the hollow gasket 51 has a width of 20.
mm, depth 8 mm, thickness 1.5 mm, and a carbon foam material having a 4 mm square and a foaming ratio of about 6 was inserted into the hollow portion.

Also, the hollow gasket 51 and the fireproof glass 1
Between 0 and 0, a silicon-based sealing material for adhesively fixing the hollow gasket 51 was thinly filled and adhered.

Further, as the fireproof glass 10, a heat-resistant plate glass obtained by edge-polishing soda-lime glass and further heat-strengthened was used.

A fireproof test of the fireproof glass structure 100 was conducted using a wall heating furnace defined in JIS A 1311.

After 3 minutes from the start of heating, the carbon-based foaming material swelled so as to cover the entire joint portion 30, and was stable until 40 minutes of heating without being affected by the deformation of the fireproof glass 10. Exhibited flameproof performance.

From the above, it was found that the fireproof glass panel structure 100 used in this example has the flameproof performance of 20 minutes required as fireproof equipment in the Building Standards Act, and the sealing material. Fireproof glass panel structure 1 using a flame-retardant silicon-based sealing material as 46
It was found that it has a stable and high flame-shielding performance as compared with No. 00.

Further, the fireproof glass panel structure 100 using the heat-resistant glass obtained by strengthening the soda lime glass having a relatively low softening point used in this example had a flame shielding performance of about 40 minutes, If heat-resistant glass or the like that has been crystallized with a high softening point is used, thermal deformation due to softening of the glass can be suppressed, and thus higher flame shielding performance can be secured.

In the fireproof glass panel structure 100 used in this embodiment, the hollow gasket 51 has a thickness of 1.5 m.
m. This is because the thickness of the hollow gasket 51 is 2 mm.
When it is above, there is a case where the foam material expands and lacks uniformity when breaking through the hollow gasket 51, partially expands and stable flame shielding performance cannot be obtained, and the thickness is 1 mm.
If the following is satisfied, the hollow gasket 5 is allowed to expand before the foam material expands.
This is because 1 may be burned out, and the foam material may fall from the joint portion 30 and a predetermined flame shielding performance may not be obtained.

From the above, the thickness of the hollow gasket 51 is
1 mm to 2 mm is suitable.

[0122]

As described in detail above, according to the fireproof glass panel structure of the first aspect, a plurality of fireproof glasses are fixed in a grid pattern through the joints, and the joints have predetermined joints. Since it is made of a member, it is possible to enhance the aesthetic appearance and to maintain the flameproof performance of the fireproof glass.

According to the fireproof glass panel structure of the second aspect, since the predetermined joint member is the hollow gasket having the foamed material in the hollow portion, the flameproof performance of the fireproof glass can be reliably maintained.

According to the fireproof glass panel structure of the third aspect, since the material of the hollow gasket is silicon rubber, it is possible to secure fire resistance and adhesiveness with the fireproof glass.

According to the fireproof glass panel structure of the fourth aspect, since the foam is made of a carbon material,
The influence on the glass member can be reduced.

According to the fireproof glass panel structure of the fifth aspect, since the foam has a volume expansion multiple of 3 times or more,
Stable flame shielding performance can be obtained.

According to the fireproof glass panel structure of claim 6, since the foam has a volume expansion multiple of 6 to 8,
Further, stable flame shielding performance can be obtained.

According to the fireproof glass panel structure of the seventh aspect, since the expansion start temperature of the foam is 350 ° C. or less, stable flame shielding performance can be obtained from the early stage of the fire.

According to the fireproof glass panel structure of the eighth aspect, since the expansion start temperature of the foam is 200 ° C.,
More stable flame shielding performance can be obtained from the early stage of the fire.

According to the fireproof glass panel structure of the ninth aspect, since the predetermined joint member is the sealing material, the flameproof performance of the fireproof glass can be reliably maintained.

According to the fireproof glass panel structure of the tenth aspect, since the sealing material has a thickness of 8 mm or more, the ashing rate of the sealing material can be suppressed.

According to the fireproof glass panel structure of the eleventh aspect, since the sealing material has a width of 25 mm or less, it is possible to prevent the joint member from contracting in volume by the heat of the flame and falling from between the fireproof glasses. be able to.

According to the fireproof glass panel structure of the twelfth aspect, since the length of the sealing material is 2.7 m or less, the flameproof performance of the fireproof glass can be more reliably maintained.

According to the fireproof glass panel structure of the thirteenth aspect, since the sealing material is made of a silicon-based material, it is possible to secure followability with respect to the fireproof glass, weather resistance, and waterproofness.

According to the fireproof glass panel structure of the fourteenth aspect, since the sealing material is the expansive sealing material in which the foam material is inserted, the flameproof performance of the fireproof glass can be more reliably maintained. .

According to the fireproof glass panel structure of the fifteenth aspect, since the foam has a volume expansion multiple of three or more, stable flame shielding performance can be obtained.

According to the fireproof glass panel structure of the sixteenth aspect, since the foam has a volume expansion multiple of 5 to 8 times, more stable flame shielding performance can be obtained.

According to the fireproof glass panel structure of the seventeenth aspect, since the supporting means is a metal article that locally supports the sides of the fireproof glass, the aesthetic appearance can be further enhanced.

According to the fireproof glass panel structure of the eighteenth aspect, since the metal objects are arranged on the four sides of the fireproof glass at regular intervals, the fireproof glass can be stably supported.

According to the fireproof glass panel structure of the twenty-second aspect, since the constant interval is 2 m or less, the fireproof glass can be supported more stably.

According to the fireproof glass panel structure of the twenty-third aspect, since the constant interval is 1.6 m or less, the fireproof glass can be supported more stably.

According to the construction method of the fireproof glass panel structure of the twenty-sixth aspect, since a plurality of fireproof glasses are fixed in a grid pattern through the joints and a predetermined joint member is used for the joints, the aesthetic appearance is improved. It is possible to maintain the flameproof performance of the fireproof glass while improving the

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of a fireproof glass panel structure according to an embodiment of the present invention.

FIG. 2 is a sectional view showing a schematic configuration of an example of a joint portion 30 in FIG.

3 is a cross-sectional view showing a schematic configuration of another example of the joint portion 30 in FIG.

FIG. 4 is a diagram showing a support structure of the fireproof glass 10 in the fireproof glass panel structure 100 of FIG. 1, where (a) is
In the case of 4 side button hardware, (b) is 2 side sash fit, 2 side button hardware is fit, (c) is 2 side button hardware fit, 2 side glass butt fit,
(D) shows the case of two-side sash fitting and two-side glass butt fitting.

5 is a cross-sectional view showing a schematic configuration of a metal piece 12 in FIG.

FIG. 6 is a diagram showing a schematic configuration of a conventional fireproof glass panel structure.

FIG. 7 is a cross-sectional view showing a schematic configuration of a glass butting construction of a conventional fireproof glass panel structure.

[Explanation of symbols]

10 fire protection glass 12 hardware 30 joints 51 hollow gasket 52 hollow 53 Fins 100 Fireproof glass panel structure

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 2E001 DA01 DE04 FA09 FA51 HA11                       HF02 HF12 LA06 MA02 MA04                       MA08                 2E002 NB02 UA01 UA02 UB04 UB07                       WA06 WA17                 4H017 AA39 AB15 AC01 AC13 AD01                       AD05 AE03

Claims (26)

[Claims] 1. A fireproof glass panel structure having a plurality of rectangular fireproof glasses and comprising support means for supporting the plurality of fireproof glasses, wherein the plurality of fireproof glasses are fixed in a grid pattern through joints. In addition, the joint portion is made of a predetermined joint member, which is a fireproof glass panel structure. 2. The fireproof glass panel structure according to claim 1, wherein the predetermined joint member is a hollow gasket having a foam material in a hollow portion. 3. The fireproof glass panel structure according to claim 2, wherein the hollow gasket is made of silicon rubber. 4. The fireproof glass panel structure according to claim 2, wherein the foam is a carbon-based material. 5. The fireproof glass panel structure according to claim 2, wherein the foaming material has a volume expansion ratio of 3 or more. 6. The fireproof glass panel structure according to claim 5, wherein the foam material has a volume expansion ratio of 6 to 8 times. 7. The expansion start temperature of the foam is 350 ° C. or lower, wherein
Fireproof glass panel structure according to item. 8. The fireproof glass panel structure according to claim 7, wherein the foam has an expansion start temperature of 200 ° C. 9. The fireproof glass panel structure according to claim 1, wherein the predetermined joint member is a sealing material. 10. The fireproof glass panel structure according to claim 9, wherein the sealing material has a thickness of 8 mm or more. 11. The fireproof glass panel structure according to claim 9, wherein the sealing material has a width of 25 mm or less. 12. The fireproof glass panel structure according to claim 9, wherein the sealing material has a length of 2.7 m or less. 13. The sealing material according to claim 9, wherein the sealing material is made of a silicon material.
Fireproof glass panel structure according to item. 14. The fireproof glass panel structure according to claim 9, wherein the sealing material is an expansive sealing material having a foam material inserted therein. 15. The fireproof glass panel structure according to claim 14, wherein the expansive sealing material has a volume expansion ratio of 3 or more. 16. The fireproof glass panel structure according to claim 15, wherein the volume expansion ratio is 5 to 8 times. 17. The fireproof glass panel structure according to claim 1, wherein the supporting means is a metal member that locally supports a side portion of the fireproof glass. 18. The metal piece is attached to a side portion of the fireproof glass.
18. The fireproof glass panel structure according to claim 17, wherein the fireproof glass panel structure is arranged along the sides at regular intervals. 19. The metal fitting is attached to the side of the fire protection glass.
18. The fireproof glass panel structure according to claim 17, wherein the fireproof glass panel structure is arranged along the sides at regular intervals. 20. The fireproof glass panel structure according to claim 19, wherein two sides of the fireproof glass are an upper side and a lower side. 21. The supporting means comprises a metal object arranged on two sides of the fire protection glass at regular intervals and a sash frame arranged on the other two sides of the side part. Item 17. A fireproof glass panel structure according to any one of items 1 to 16. 22. The fireproof glass panel structure according to claim 18, wherein the predetermined interval is 2 m or less. 23. The fireproof glass panel structure according to claim 22, wherein the predetermined interval is 1.6 m or less. 24. The fireproof glass panel structure according to claim 1, wherein the support means is a sash frame arranged on two sides of the fireproof glass. . 25. The fireproof glass panel structure according to claim 24, wherein two sides of the fireproof glass are an upper side and a lower side. 26. A method of constructing a fireproof glass panel structure having a plurality of rectangular fireproof glasses, comprising support means for supporting the plurality of fireproof glasses, wherein the plurality of fireproof glasses are lattice-shaped through joints. A method for constructing a fireproof glass panel structure, characterized in that it is fixed to the joint and a predetermined joint member is used for the joint.