JP2005146777A - Fire resistive panel for glass curtain wall - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fire resistive panel for a spandrel wall of a curtain wall which has dimensional stability under change in temperature, electric wave non-reflectivity, fire-resistance, lightweightness and large bending strength, and which is easy to manufacture. <P>SOLUTION: The fire resistive panel for the spandrel wall of the curtain wall comprises magnesia cement based boards containing 75 to 94.5 weight percent of a magnesia cement, 0.5 to 5 weight percent of a reinforcing fibrous material, and 5 to 20 weight percent of a lightweight aggregate as main materials, and a phenol foam plate. The magnesia cement based boards are glued onto both faces of the phenol foam plate. Preferably, the reinforcing fibrous material is in a mesh-state and is embedded in both sides of the magnesia cement based boards. Further, the reinforcing fibrous material preferably comprises short fibers which are dispersed in the magnesia cement based boards substantially evenly. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to a fireproof panel for a curtain wall used for a waist wall of a glass curtain wall.

Since the phenol resin foam (phenol resin foam) is excellent in heat insulation and flame retardancy, a fireproof panel for construction made of a phenol resin foam and a nonflammable hard material is used.

JP 53-109584 (Claims) JP 62-071636 (Claims, lower left column on page 2)

For example, Patent Document 1 discloses a panel made of a phenol resin foam and a glass fiber reinforced cement molded body (GRC).
Discloses a panel made of a phenol resin foam, a metal face material, a gypsum board, and a calcium silicate plate.

In recent years, glass curtain walls have been used frequently, and calcium silicate plates are mainly used for the waist of this glass curtain wall, but because it is heavy and lacks heat insulation, a panel with rock wool or phenol foam as the core is used. Has been developed.

When used as a fireproof panel for a glass curtain wall, the fireproof panel is exposed to direct sunlight through the glass. For this reason, especially the center part of a panel becomes high temperature, and the dimension of a fireproof panel may become unstable,
In some cases, there is a risk of heat splitting of the glass (the surface temperature of the refractory panel becomes high, and the glass is abnormally expanded due to the radiant heat and cracks). Therefore, (1) dimensional stability due to temperature change is required for the fireproof panel of the glass curtain wall.

At present, there is a problem of reflection (ghost, etc.) of TV radio waves, and the fireproof panel of the glass curtain wall is also required to (2) not reflect radio waves (radio wave non-reflectivity).

Of course, the fireproof panel of the glass curtain wall has (3) fire resistance,
4) is preferably a 12 kg / m ³ has a light weight, (5) bending when strength to carry the easily handled it (the hand of man in large construction sites, etc., without being thereby broken deflected, transportation Etc.), and (6) easy manufacturing is also required.

None of the fireproof panels of the prior art satisfy all the above characteristics (1) to (6).
Therefore, this invention is providing the fireproof panel for glass curtain walls which satisfy | fills all the characteristics of said (1)-(6).

According to invention of Claim 1, the magnesia cement type | system | group which uses as a main material the magnesia cement 75-94.5 weight%, the reinforcing fiber material 0.5-5 weight%, and the lightweight aggregate 5-20 weight%. A fireproof panel for a glass curtain wall waist wall is provided, characterized in that the board is bonded to both sides of a phenol foam board.
Preferably, the reinforcing fiber material has a mesh shape and is embedded on both surfaces of the magnesia cement-based board (the invention according to claim 2). Also preferably,
The reinforcing fiber material is a short fiber and is dispersed substantially uniformly in the magnesia cement-based board (the invention according to claim 3).

According to the invention of claim 1, since the magnesia cement-based board whose main material is magnesia cement with good dimensional stability due to temperature change is used,
When used as a fireproof panel for a curtain wall, even if it is exposed to direct sunlight, a fireproof panel having a stable dimension can be obtained. In addition, since a magnesia cement-based board mainly composed of magnesia cement having good radio wave non-reflectivity is used, there is no radio wave interference such as ghost even if it is used for a fireproof panel of a curtain wall. Moreover, since the reinforcing fiber material is included, the bending strength is high, and the weight is light because it is made of a magnesia cement-based board and a lightweight aggregate. Furthermore,
Since the magnesia cement board is used, it has fire resistance.
According to the invention described in claim 2, since the reinforcing fiber material is in a mesh shape, a fireproof panel having a high bending strength can be obtained.
According to the invention described in claim 3, since the reinforcing fiber material is dispersed substantially uniformly in the magnesia cement-based board, a fireproof panel having a high bending strength can be obtained.

The fireproof panel of the present invention comprises a phenol foam board as a core material and a magnesia cement-based board as an outer shell material bonded to both surfaces of the phenol foam board.
The main material is 4.5% by weight, reinforcing fiber material 0.5 to 5% by weight, and lightweight aggregate 5 to 20% by weight.

The phenol foam board is lightweight and has excellent fire resistance and heat insulation. Therefore,
This was used as a core material having heat insulating properties, and magnesia cement-based boards described later were arranged on both sides. A well-known thing can be used for a phenol foam board.

As described above, the magnesia cement-based board is made of magnesia cement 75-
94.5 wt%, reinforcing fiber material 0.5-5 wt%, lightweight aggregate 5-20 wt%
And the main material.

In the present invention, a board mainly composed of magnesia cement is used in view of good dimensional stability due to temperature change, good radio wave non-reflectivity, and fire resistance.
The magnesia cement is 75 to 94 in the magnesia cement board.
. 5% by weight is included. If it is less than 75% by weight, the strength of the magnesia cement-based board will be insufficient. If it exceeds 94.5% by weight, the magnesia-cement board (and hence the fireproof panel) will become heavy. This is because it becomes difficult to impregnate the reinforcing fiber material with the slurry of magnesia cement and lightweight aggregate during production.

In the magnesia cement-based board, a reinforcing fiber material is included. By including the reinforcing fiber material, the bending strength is improved.
As the reinforcing fiber material, inorganic fibers such as glass fibers (particularly alkali-resistant glass fibers) are preferable, but organic fibers can also be used. In addition, it is also preferable to process the inorganic fiber with a resin coating or the like. For example, it is possible to use a glass fiber with a resin coating.
The reinforcing fiber material is contained in an amount of 0.5 to 5% by weight in the magnesia cement-based board. This is because if it is less than 0.5% by weight, the bending strength is insufficient, and if it exceeds 5% by weight, the magnesia-cement board is poor in moldability.

The reinforcing fiber material is preferably mesh-shaped. Bending strength is improved by arranging the magnesia cement-based board in a mesh shape. More specifically, a woven fabric made of glass fiber or other fibers, or a woven nonwoven fabric (
What is called 2-axis assembly, 3-axis assembly, and 4-axis assembly. “Assembly” is preferably a registered trademark of “Polymer Processing Laboratory Co., Ltd.”. Such a reinforcing fiber material is disposed on both sides of the magnesia cement-based board.
Alternatively, the reinforcing fiber material may be a short fiber. In this case, the reinforcing fiber material is dispersed and embedded substantially uniformly in the magnesia cement-based board. Bending strength is improved by dispersing the reinforcing fiber material substantially uniformly.

Further, magnesia cement-based boards include lightweight aggregates. By including a lightweight aggregate, the weight of the magnesia cement-based board can be reduced.
Examples of the lightweight aggregate include pearlite, shirasu balloon, fly ash balloon, and the like, but the present invention is not limited to these.
Such lightweight aggregate is contained in the raw material in an amount of 5 to 20% by weight. 5% by weight
If it is less, the weight of the fireproof panel of the present invention cannot be reduced, and if it exceeds 20% by weight,
This is because the bending strength of the fireproof panel is deteriorated and the moldability of the magnesia cement-based board is deteriorated.

The magnesia cement-based board can be manufactured using a known kneading, molding, and drying method. For example, if the reinforcing fiber material is mesh,
Kneading magnesia cement and lightweight aggregate with water, pouring the kneaded product (slurry) into a formwork with mesh-like reinforcing fiber material, and then spreading, molding and drying the mesh-like reinforcing fiber material Can be manufactured. The slurry impregnates the mesh, and the reinforcing fiber material is embedded in the magnesia cement-based board. When the reinforcing fiber material is a short fiber, water may be added to the magnesia cement, the lightweight aggregate, and the short fiber, kneaded, poured into a mold, molded and dried.

The magnesia cement-based board is bonded to both sides of the phenol foam board. As the adhesive, a known one can be used.
The fireproof panel of the present invention thus produced is used for the waist wall of the curtain wall.

Examples 1 and 2
Add water to 88.6% by weight of magnesia cement and 10% by weight of pearlite,
A woven fabric made of glass fibers kneaded and coated with acrylic resin (0.7
The kneaded product is poured into a mold having a weight (% by weight), and the woven fabric (0.7% by weight)
), Molded and dried to prepare a magnesia cement-based board (specific gravity 1.1) in which reinforcing fiber materials are embedded on both sides. Table 1 shows the thickness of the magnesia cement-based board. In addition, "weight%" said here means the solid content ratio at the time of becoming a board.
Also, a phenol foam board (specific gravity 0.05) was prepared, and the magnesia cement board was adhered to both sides of the phenol foam board using a urethane adhesive to obtain a fireproof panel. Table 1 shows the thickness of the phenol foam board.

Example 3
Water is added to 88.6% by weight of magnesia cement, 10% by weight of pearlite, and 1.4% by weight of alkali-resistant short glass fiber (fiber length 6 mm), kneaded, poured into a mold, molded, and impressed. A magnesia cement-based board (specific gravity 1.1) in which the reinforcing fiber material was dispersed substantially uniformly was prepared. Table 1 shows the thickness of the magnesia board.
Also, a phenol foam board (specific gravity 0.05) was prepared, and the magnesia cement board was adhered to both sides of the phenol foam board using a urethane adhesive to obtain a fireproof panel. Table 1 shows the thickness of the phenol foam board.

Comparative Examples 1, 2, and 3
Instead of the magnesia cement-based board (skin material) in Examples 1-3,
Glass fiber reinforced cement plate (GRC), steel plate, calcium silicate plate was used, and the same phenol foam plate (specific gravity 0.05) used in Examples 1 to 3 (thickness is shown in Table 1) To obtain a fireproof panel. Table 1 shows the thickness and specific gravity of each plate.

Various characteristics of the fireproof panels of Examples 1 to 3 and Comparative Examples 1 to 3 were measured by the following methods. The results are shown in Table 1.
Thermal dimensional stability: The fireproof panel was heated from 10 ° C. to 100 ° C., and the fireproof panel surface appeared to be distorted as “x”, and the unstrained one as “◯”.
-Radio wave reflectivity: We confirmed whether radio wave reflection problems such as TV ghosts would occur. The panel produced as described above was transmitted with radio waves of 80 MHz to 1 GHz on a panel having a length and width of 400 × 400 mm, and the intensity of the radio waves reflected from the panel surface was measured. The incidence and reflection angles of radio waves were measured in the range of 0 to 60 degrees with normal incidence being 0 degrees. The reflection amount of each panel compared with the reflection amount of the iron plate was measured in dB. The one with -15 dB or less was evaluated as a radio wave reflectivity evaluation ○. The measurement method and equipment are in accordance with the `` Radio wave absorber performance measurement method '' being studied by the Architectural Institute of Japan,
It was performed by the free space time domain method.
Fire resistance performance: Measured by a non-bearing wall 60 minutes and 30 minutes fire resistance performance test of the outer wall of the fireproof structure related to the certification based on the provisions of Article 2, Item 7 of the Building Standard Law.
・ Bending test: By holding the short side of a panel of 910 × 1820mm horizontally by human hands and raising and lowering the panel, an accelerated bending stress is applied in addition to the panel's own weight. ”, Those that did not break were marked with“ ◯ ”.

From Examples 1 to 3, the fireproof panel of the present invention was good with respect to all of thermal dimensional stability (dimensional stability due to temperature change), radio wave non-reflectivity, fire resistance, light weight, and bending strength.
On the other hand, the fireproof panel of Comparative Example 1 is lightweight, the fireproof panel of Comparative Example 2 has problems with radio wave non-reflection and thermal dimensional stability, and the fireproof panel of Comparative Example 3 has problems with fire resistance and bending properties. A good one was not obtained.
Further, from Examples 2 and 3, even if the reinforcing fiber material is meshed and embedded on both sides of the magnesia cement-based board, instead of the reinforcing fiber material as a short fiber, evenly dispersed in the magnesia cement-based board, It was found that equivalent results were obtained.
As mentioned above, it turned out that the fireproof panel of this invention has the outstanding result regarding all the characteristics.

Claims (3)

Magnesia cement 75-94.5% by weight and reinforcing fiber material 0.5-5% by weight
And a magnesia cement-based board whose main material is 5 to 20% by weight of lightweight aggregate,
It is characterized by being bonded to both sides of a phenol foam board,
Fireproof panel for curtain wall waist wall. The fireproof panel according to claim 1, wherein the reinforcing fiber material is in a mesh shape and is embedded on both surfaces of a magnesia cement-based board. The fireproof panel according to claim 1, wherein the reinforcing fiber material is a short fiber and is substantially uniformly dispersed in the magnesia cement-based board.