JPH0841426A - Refractory adhesive - Google Patents

Abstract

PURPOSE:To obtain a refractory adhesive useful in the architectural field, etc., tractable in application sites, having excellent bonding strength, heat resistance and thermal insulation by adding a montmorillonite, etc., to a solution of a silanol having siloxane skeleton(s). CONSTITUTION:This refractory adhesive comprises the following components (A) through (D) and preferably (E). (A): 100 pts.wt. of a solution of a silanol having siloxane skeleton(s) such as a fluoric silanol salt solution obtained by mixing 50 pts.wt. of a metallic silicon, 5-40 pts.wt. of a sodium fluoride, 5-30 pts.wt. of a sodium hydroxide and 30-2000 pts.wt. of water followed by exothermic reaction or reaction under heating; (B): preferably 10-500 pts.wt. of a montmorillonite such as bentonite; (C): preferably 2-100 pts.wt. of a hydrous aluminum silicate; (D): preferably 1-50 pts.wt. of mineral fibers such as Chinese mineral wool, carbon fibers, alumina fibers or alumina-silica fibers; (E): graphite.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fire-resistant adhesive suitable for fields requiring fire resistance and heat resistance such as the construction field.

[0002]

BACKGROUND OF THE INVENTION In the field of construction, structural materials, building materials, etc. are required to have fire resistance, heat resistance, and heat insulation from the viewpoint of fire prevention and disaster prevention. Especially in high-rise buildings, the use of these refractory materials is obligatory, and interior and exterior materials also require a certain level of fire resistance. On the other hand, in order to shorten construction efficiency and improve efficiency, exterior materials, interior materials, and in some cases structural materials,
Adhesive method is used. In addition, in many cases, adhesives are used to make various noncombustible materials into composite materials. Therefore, the building adhesive is required to have sufficient adhesive strength and excellent fire resistance, heat resistance, and heat insulation. Further, when used at a construction site, it is preferable that the handling is easy.

Most of the adhesives used in the past are mainly epoxy resin adhesives, which have a high adhesive strength, but since they are a two-component mixed system, they need to be prepared at the time of use and the workability is poor. It was Further, since it is an organic material, even if the adhered building material itself is non-combustible, the adhesive itself will burn out at the time of high heat such as a fire, and the adhered building material will peel off. Similarly, when a vinyl-based adhesive is used, its fire resistance is inferior.

A sheet-shaped fire-resistant adhesive material containing an inorganic compound as a main component has also been proposed by Japanese Patent Laid-Open No. 4-239079.
This fire-resistant adhesive was prepared by adding poval aqueous solution and cement for eluting polyvalent metal in order to cure silanol having a siloxane skeleton described in JP-A-1-313303, and gelated by alcohol treatment to give a pressure-sensitive adhesive sheet. It is a thing. This sheet-shaped adhesive material is excellent in fire resistance and heat resistance, but for its production, a solution A prepared by mixing cement in an aqueous solution of Poval and a solution B prepared by adding a water-retaining solidifying material such as zeolite to the silanol solution. Were separately prepared, and these were separately treated with alcohol and then mixed, or both liquids had to be mixed and treated with alcohol, then gelled and molded into a sheet, which was troublesome to manufacture. In addition, since it is a sheet having a certain thickness in advance, it was not possible to use an adhesive having an arbitrary thickness at the construction site.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has sufficient adhesive strength, excellent fire resistance, heat resistance, and heat insulation, and is easy to manufacture. It is an object of the present invention to provide a fire resistant adhesive that is easy to handle at a construction site.

[0006]

The object of the present invention is achieved by a refractory adhesive obtained by adding at least montmorillonite, hydrous aluminum silicate and mineral fibers to a silanol solution having a siloxane skeleton.

That is, according to the present invention, a silanol solution having a siloxane skeleton is used as a main ingredient, and montmorillonite, which is a clay mineral, and mineral fiber, which is a heat-insulating filler, are added as fillers to the solution, and the adhesive strength and fire resistance are improved. It is a one-pack type adhesive that is excellent in handling and easy to handle, and is based on the finding found by the present inventor. In a preferred embodiment, graphite is further added and mixed. This fire-resistant adhesive can be used for members such as building materials and furnace materials that require strong adhesive strength and excellent fire resistance and heat resistance. Further, it can be used for bonding wood, metal, porcelain materials such as tiles, and gypsum board.

A silanol solution is disclosed in JP-A-1-31330.
3 and the silanol having a siloxane skeleton described in JP-A-4-239079 can be used. In particular, a fluoric silanol salt solution containing silicon, fluorine, and sodium as a basic skeletal element is preferable, and metallic silicon, sodium fluoride (or hydrogen fluoride), sodium hydroxide, and water are mixed to heat or generate heat. It is possible to obtain by reacting. The mixing ratio is not particularly limited. If the silanol liquid produced becomes excessively alkaline, waste liquid treatment becomes necessary. Therefore, it is better not to use more sodium fluoride (or hydrogen fluoride) or sodium hydroxide than necessary. In addition, it is advantageous from the viewpoint of production that excess water is not used in order to carry out the heating reaction only by the heat generated by the mixed reaction of water and sodium hydroxide. If the exothermic reaction is insufficient, heat to bring the reaction solution to a boil. The less water used in producing this silanol solution, the more viscous silanol solution, and the more water used, the less viscous silanol solution. It is preferable that the silanol liquid used as the main component of the adhesive is viscous to some extent, but if the amount of water used is reduced to increase the viscosity, water will evaporate due to an exothermic reaction. I can't get it.

From this viewpoint, 5 to 40 parts by weight of sodium fluoride and 5 to 40 parts by weight of metallic silicon are used.
Preference is given to using 30 parts by weight of sodium hydroxide and 30 to 2000 parts by weight of water. More preferably, 5
For 0 parts by weight of metallic silicon, 5 to 20 parts by weight of sodium fluoride, 5 to 20 parts by weight of sodium hydroxide and 30 to 200 parts by weight of water are used. A particularly preferred silanol solution is 50 parts by weight of metallic silicon, 1
0 to 20 parts by weight of sodium fluoride, 10 to 20 parts by weight of sodium hydroxide and 100 to 200 parts by weight of water are mixed to cause an exothermic reaction, and after cooling to room temperature, the generated floating slag and precipitation residue are removed. Viscous supernatant (fluoric silanol salt solution) can be used.

Montmorillonite is a clay mineral that is the main component of acid clay and bentonite, and swells when it contains water. In the present invention, it is used as a thickening agent. Bentonite, which is Na- or Ca-montmorillonite, is preferable as the montmorillonite. The mixing ratio is preferably 10 to 500 parts by weight of montmorillonite with respect to 100 parts by weight of the silanol solution.

As the hydrous aluminum silicate, commercially available purified montmorillonite obtained by refining bentonite can be used. For 100 parts by weight of silanol solution,
It is preferable to mix 2 to 100 parts by weight of hydrous aluminum silicate.

Mineral fibers, that is, inorganic fibrous materials, are used as heat insulating fillers, and fire resistant fiber materials such as Chinese cotton, carbon fibers, alumina fibers, and alumina silica fibers can be used. China cotton is preferred. The mixing ratio is preferably 1 to 50 parts by weight of mineral fiber to 100 parts by weight of silanol solution.

The adhesive of the present invention includes graphite (carbon
Graphite) may be mixed. Graphite has a foaming action when heated, and has the effect of increasing the heat insulating action of the adhesive. The mixing ratio is preferably 2 to 10 parts by weight of graphite with respect to 100 parts by weight of the silanol solution.

The mixing ratio of these montmorillonite, hydrous aluminum silicate, mineral fiber and graphite is 10 to 3 hydrous aluminum silicate with respect to 50 parts by weight of montmorillonite.
It is preferably 0 parts by weight, 5 to 20 parts by weight of mineral fibers, and 1 to 5 parts by weight of graphite. A viscous liquid can be obtained by mixing the above mixture with the silanol solution described above, and can be used as it is as the adhesive of the present invention. Immediately after application to a member to be adhered, it exhibits adhesiveness, but the member does not peel off. Further, as the drying progresses, the siloxane bond in the silanol increases and the adhesive strength becomes stronger.

[0015]

Example 1 10 kg of a metallic silicon block, 2.2 kg of sodium fluoride and 2.2 kg of sodium hydroxide were placed in a reaction vessel, and finally 22 L (Kg) of water was added. The reaction solution is heated by an exothermic reaction and boils at about 80 ° C. to about 12
Reached 0 ° C. This was left to stand, and when the temperature dropped to room temperature, the slag floating on the upper surface of the reaction solution was removed.
At the bottom of the reaction vessel, undissolved metallic silicon and sodium fluoride were precipitated as residues. The precipitate was also discarded and the viscous liquid as the supernatant was taken to obtain the desired silanol solution.

With respect to 10 kg of the obtained silanol solution,
Bentonite 3Kg, China Fiber 300g,
Purified montmorillonite (hydrous aluminum silicate) 500
g and 800 g of graphite fine powder were added and well stirred. The mixed solution was extremely viscous and did not drip, but had a fluidity such that it could be applied to the adhesive surface.

When this mixed solution was applied as an adhesive to a board building material, it showed sufficient adhesive strength not inferior to the conventional epoxy adhesive. When a flame was sprayed from the side of the bonded board with a gas burner, the adhesive itself smoked with the conventional epoxy adhesive and finally burned out, and the board was peeled off. On the other hand, with the adhesive of this example, even if the burner was applied for the same time, the board did not burn out or smoke, and the board remained firmly bonded. The burner heating was continued, but the board did not come off until the board started burning.

[0018]

Example 2 For 2 kg of the silanol solution of Example 1,
Bentonite 10kg, China Fiber 1kg,
2 kg of purified montmorillonite (hydrated aluminum silicate: trade name "Bengel") and 200 g of graphite fine powder were added and well stirred. The mixed solution was extremely viscous, but had a fluidity such that it could be applied to the adhesive surface.

This adhesive was applied to one surface and laminated on each other to prepare Samples 1, 2 and 3 of plywood, and an adhesive strength test was conducted. After leaving for about 1 month, using a tensile tester, pulling speed 1mm
The adhesive strength was measured under the condition of / min. The adhesion strengths of Samples 1, 2, and 3 were 8.2 Kgf / cm ² , 8.1 Kgf / cm ² , and
It was 6.7 Kgf / cm ² , and the average was 7.7 Kgf / cm ² .
This value is JIS A 6909 according to the JIS standard for interior materials.
(Thin finish coating material) and JIS A 6910 (multi-layer finish coating material) have a standard adhesion strength of 3 to 5 Kgf / cm ² , and the adhesive of this example has sufficient adhesion. It was shown to have strength. Further, the adhesive of this example did not peel off the plywood until the plywood burned out, and neither the adhesive burned out nor smoked even when the burner heating similar to that in Example 1 was performed.

[0020]

As described above, the fire-resistant adhesive of the present invention is a fire-resistant adhesive obtained by adding montmorillonite, hydrous aluminum silicate, mineral fibers and graphite to a silanol solution having a siloxane skeleton. It has sufficient adhesive strength and excellent fire resistance, heat resistance, and heat insulation properties, and is easy to manufacture and easy to handle at the construction site.

Claims (7)

[Claims] 1. A refractory adhesive obtained by adding at least montmorillonite, hydrated aluminum silicate and mineral fibers to a silanol solution having a siloxane skeleton. 2. A refractory adhesive containing: (a) 100 parts by weight of a silanol solution having a siloxane skeleton, (b) 10-500 parts by weight of montmorillonite,
(c) 2 to 100 parts by weight of hydrous aluminum silicate, (d) 1
~ 50 parts by weight of mineral fiber, 3. The silanol solution is metallic silicon,
The fire-resistant adhesive composition according to claim 1 or 2, which is a fluoric silanol salt solution obtained after an exothermic or heating reaction by mixing sodium fluoride (or hydrogen fluoride), sodium hydroxide and water. Agent. 4. The silanol solution comprises 50 parts by weight of metallic silicon, 5 to 40 parts by weight of sodium fluoride, 5 to 5 parts by weight.
The fire-resistant adhesive according to claim 3, which is a fluoric silanol salt solution obtained by mixing 30 parts by weight of sodium hydroxide and 30 to 2000 parts by weight of water and generating an exothermic or heating reaction. 5. The fire resistant adhesive according to claim 1, wherein the montmorillonite is bentonite. 6. The fire resistant adhesive according to claim 1, wherein the mineral fiber is any one of Chinese cotton, carbon fiber, alumina fiber and alumina silica fiber. 7. The fire resistant adhesive according to claim 1, wherein the fire resistant adhesive further contains graphite.