JPH07247154A - Composition. material and member having heat resistance, heat insulating property and corrosion resistance - Google Patents

Abstract

PURPOSE:To improve heat resistance, heat insulating properties, adhesiveness and corrosion resistance. CONSTITUTION:This composition comprises a mixture of 50-70wt.% of a hardening agent composed of raw alunite, sodium silicate powder, leucite, KANSUI (a kind of marble) and sodium silicofluoride and 50-30wt.% of ceramic powder and has heat resistance, heat insulating properties, adhesiveness and corrosion resistance. A proper amount of a hardening material composed of raw alunite, sodium silicate powder, leucite, KANSUI (a kind of marble) and sodium silicofluoride is uniformly mixed with proper amounts of ceramic powder and water to give a material having heat resistance, heat insulating properties, adhesiveness and corrosion resistance. A proper amount of a hardening agent composed of raw alunite, sodium silicate powder, leucite, KANSUI (a kind of marble) and sodium silicofluoride is mixed with proper amounts of ceramic powder and water, molded and solidified.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composition, a material and a building material which are intended to have heat resistance, heat insulation, adhesiveness and corrosion resistance.

[0002]

2. Description of the Related Art A heat-resistant and heat-insulating composition obtained by adding silica, albite and pearlite to a hardening agent composed of cold water, powdered sodium silicate and sodium fluorinated fluorite is known (Japanese Patent Application Laid-Open No. Hei 4).
243948).

[0003]

In the above-mentioned conventional technique, addition of water enables coating, spraying, molding and the like, and exhibits excellent heat resistance and heat insulating properties. The use was expected. However, there was a problem in the rust preventive effect when applied to a metal, the adhesive strength, etc., so that it was necessary to further improve this.

[0004]

The present invention improves the curability and adhesiveness by changing the component ratios of the conventionally known compositions and adding cold water stone and Hakuryu, and further improves the corrosion resistance. Is given.

That is, the invention of the composition is 50% to 70% (by weight) of a hardening agent consisting of raw alunite, powdered sodium silicate, white dragon, cold water stone and sodium silicofluoride, and 50% of ceramics powder.
It is a composition having heat resistance, heat insulation and corrosion resistance, which is characterized by comprising a mixture of ˜30% (weight). Further, the invention of the material is characterized in that an appropriate amount of a hardener composed of raw alunite, powdered sodium silicate, white dragon, cold water stone, and sodium silicofluoride is added to an appropriate amount of a powder of ceramics and water and uniformly mixed. It is a material that has heat resistance, heat insulation, and corrosion resistance. Next, the hardening agent is 40% to 70% (by weight) of raw alunite.
Powdered sodium silicate 30% -40% (weight), Hakuryu 1% -5
% (Wt.), Cold water stone 1% to 10% (wt.), Sodium fluorosilicate 3% to 10% (wt.), Ceramics are zirconia 1% to 10% (wt.), Pearlite 2
% To 12%, silica 2% to 12% (weight), magnesia 7% to 17% (weight), mica 1% to 10% (weight), silica stone 1% to 10% (weight) Is.

Further, the invention of the member is such that an appropriate amount of a hardening agent composed of raw alunite, powdered sodium silicate, white dragon, cold water stone, and sodium silicofluoride is mixed with an appropriate amount of powder of ceramics and water, and the mixture is molded. It is a member having heat resistance, heat insulation, and corrosion resistance characterized by being solidified, and a suitable amount of a hardener composed of raw alunite, powdered sodium silicate, white dragon, cold water stone and sodium silicofluoride, and ceramics. A material having heat resistance, heat insulation and corrosion resistance, which is obtained by layering a material obtained by mixing an appropriate amount of the powder and water and kneading it on the surface of an iron material.

Examples of the above-mentioned ceramics include zirconia, pearlite, alumina, clay, magnesia, silica and bentonite.

If the amount of the above-mentioned curing agent added is 40% or less, it will not cure at room temperature. Generally, if the amount of the curing agent is small, the time required for curing becomes long, so it is usually 50% to 6%.
0% is preferred. If it is around 70% or more, the curing time becomes extremely short.
Less than% is used.

[0009] In the above, by adding cold water stone and Hakuryu, it became hardened from the inside, and the hardening time was shortened overall. In addition, water resistance occurs (14
Since it has water resistance on a daily basis and has corrosion resistance, if it is applied to the surface of iron (0.5 to 5 mm), the corrosion of iron can be surely prevented.

Further, since this material has a very high adhesive force, it can be used as an adhesive material for adhering building materials and building materials or iron and iron.

[0011]

According to the present invention, a hardener composed of raw alunite, powdered sodium silicate, white dragon, cryolite and sodium silicofluoride is mixed with a powder of ceramics. Can be layered on another object (for example, a metal surface) by coating, spraying, or the like. Let it dry naturally,
Water resistance can be exhibited after a considerable time (for example, 14 days) has passed.

However, it has heat resistance, heat insulation and corrosion resistance,
Moreover, it has been found that the adhesive strength becomes extremely large without performing a baking treatment or the like.

[0013]

Example 1 55% (by weight) of raw alunite powder, 35% (by weight) of powdered sodium silicate, 2% by weight of Hakuryu powder (by weight) 4% of coldsuiseki powder, 4% (by weight) of sodium fluorosilicate If 62% (by weight) of the mixture mixed with zirconia 7% (by weight), magnesia 16% (by weight) mica 1% (by weight) silica 1% (by weight) rock wool 13% (by weight) are mixed, A composition of the invention is made (SIT-C700).

A molding material having heat resistance, heat insulation and corrosion resistance can be obtained by putting a mixed material obtained by adding 20 parts of water to 100 parts of the composition and molding the mixture.

The above-mentioned mixed material can be molded into an arbitrary shape as well as having a slightly large amount of water (for example, 23 parts).
It can be spray material or pouring.

For example, when constructing reinforced concrete, it is possible to impart corrosion resistance by spraying the reinforcing steel.

[0017]

[Example 2] To 62.4% (by weight) of the curing agent of Example 1,
Magnesia 29% (weight), Zirconia 7% (weight),
Silica stone 1% (weight) and mica 0.6% (weight) are mixed to obtain the composition of the present invention. A coating material can be prepared by mixing 28% of water with the composition (SIT-C6).
00).

[0018]

Example 3 66% (by weight) of the curing agent of Example 1 was added to zirconia 6% (by weight), pearlite 7% (by weight), silica 7% (by weight), magnesia 12% (by weight) mica 1% (by weight). ) And 1% by weight of silica stone (by weight), the composition of the present invention can be prepared.

A coating material can be obtained by adding 55% (by weight) of water to this composition and kneading the mixture uniformly.
If the water content is 24% (weight), the building material can be molded in a mold (SIT-C200).

[0020]

[Heat Resistance Test 1] Molded product 11 (No.
1, No. 2) No. 1 is 174.2 mm in length and 174. in width.
2mm, thickness 26.5mm. No. 2 is 176.2 mm in length, 176.2 mm in width, and 25.4 mm in thickness. The sample No. 1, N
o. The molded article 2 of 2 was set in one side opening 9 (hole size 140 mm × 140 mm) surrounded by the heat insulation wall 7,
Heated with heaters 10 and 10.

In this case, the temperature was raised to 1100 ° C. in 2 hours,
After being kept for 4 hours, the temperature inside the furnace became as shown in FIG. 3 (almost constant temperature after 2 hours).

In the above, No. Figure 1 shows the backside temperature
It was constant around 260 ° C. and was constant after 4 hours. Therefore, it is considered that the amount of heat transferred to the back surface is equal to that of heating and heat dissipation.

No. Regarding No. 2, similarly, the furnace temperature reached 1100 ° C. in 2 hours and the heating was continued for 2 hours as it was, but the back surface temperature became constant at 188 ° C. In this case as well, it is considered that the heating amount and the heat radiation amount became constant.

[0024]

[Rust resistance test] June 3, 1993: SIT-C600 was applied to the surface of the iron plate to a thickness of 2 mm and then naturally dried.
It was put in water on the 20th of the month and stored as it was until the 3rd of December.
During this period, boiling and natural cooling were repeated 5 times (approximately at equal intervals). On December 3, the SIT-C600 layer was removed, but no rust was found on the coated surface. That is, the coated surface was recognized to be substantially the same as on June 3 (tester, Kowa Chemical Industry Co., Ltd.).

[0025]

[Adhesion resistance test] As shown in FIG.
When the steel material 1a, the test body 4 of the present invention, and the epoxy adhesive 3 were connected to each other and pulled in the directions of arrows 5 and 6, the results shown in Tables 1, 2, and 3 were obtained.

[0026]

[Table 1]

[0027]

[Table 2]

[0028]

[Table 3]

[0029]

According to the present invention, heat resistance, heat insulation, rust prevention and adhesion are excellent. In particular, rust prevention and adhesion are characteristics not found in conventional materials of this kind,
It is an excellent material that will be widely used for various purposes in the future.

[Brief description of drawings]

FIG. 1 is a graph showing heat resistance and heat insulation of the present invention.

FIG. 2 is a graph showing heat resistance and heat insulation.

FIG. 3 is a graph showing the temperature rise in the furnace in the same heat resistance test.

FIG. 4 is an explanatory diagram of a test furnace that similarly measures heat resistance and heat insulation.

FIG. 5 is a front view showing a main part of a tensile test showing adhesiveness.

FIG. 6 is a partial front view of the tensile tester.

[Explanation of symbols]

 1, 1a, 2 Steel materials 3 Epoxy adhesive 4 Specimen 7 Heat insulation wall 8 Furnace 9 Opening 10 Heater 11 Molded product

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display location C04B 22/00 28/26

Claims (6)

[Claims] 1. Hardening agent consisting of raw alunite, powdered sodium silicate, white dragon, cold water stone and sodium silicofluoride 50% to 70%
A composition having heat resistance, heat insulation and corrosion resistance, characterized by comprising a mixture of (weight) and ceramics powder of 50% to 30% (weight). 2. An appropriate amount of a hardener composed of raw alunite, powdered sodium silicate, white dragon, cold water stone, and sodium silicofluoride, and an appropriate amount of ceramics powder and water are added and uniformly mixed. A material with heat resistance, heat insulation, and corrosion resistance. 3. Hardening agent is 40% to 70% of raw alunite.
(Weight) Powdered sodium silicate 30% to 40% (weight), Hakuryu 1% to 5% (weight), Kansui stone 1% to 10% (weight) Sodium fluorosilicate 3% to 10% (weight) The composition and material having heat resistance, heat insulation and corrosion resistance according to claim 1 or 2. 4. Ceramics are zirconia 1% to 1
0% (weight), perlite 2% to 12% weight, silica 2
% -12% (weight), magnesia 7% -17% (weight), mica 1% -10% (weight), silica 1% -10%
The composition and material having heat resistance, heat insulation and corrosion resistance according to claim 1 or 2, wherein the composition is a mixture of (weight). 5. An appropriate amount of a hardener composed of raw alunite, powdered sodium silicate, white dragon, coldsui stone and sodium silicofluoride is added to an appropriate amount of ceramic powder and water, and the mixture is kneaded and molded and solidified. A member with characteristic heat resistance, heat insulation, and corrosion resistance. 6. A material obtained by mixing an appropriate amount of a hardener composed of raw alunite, powdered sodium silicate, white dragon, cold water stone and sodium silicofluoride with an appropriate amount of ceramics powder and water, and kneading the surface of an iron material. Heat resistance, heat insulation, characterized by being layered
A member with corrosion resistance.