JPH0558756A - Production of lightweight aerated concrete - Google Patents

Abstract

PURPOSE:To obtain a lightweight aerated concrete wherein bubbles are uniformly distributed without increasing the sp.gr. of the product concrete by using a soln. of a bean-curd refuse powder in methyl alcohol as the bubble stabilizer. CONSTITUTION:A binder such as cement, an aggregate, a foaming agent and a bubble stabilizer are mixed to produce the objective lightweight aerated concrete. In this case, a soln. of bean-curd refuse powder in methyl alcohol is used as the bubble stabilizer.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing lightweight cellular concrete.

[0002]

2. Description of the Related Art Conventionally, there has been known a method for producing a lightweight cellular concrete by adding a foaming agent such as aluminum powder to a water slurry of a concrete material and generating a gas by a chemical reaction to introduce bubbles. .

In the above-mentioned conventional manufacturing method, since the formed bubbles are coalesced into larger bubbles or defoamed, only the foaming agent is fine and uniform in the water slurry of the concrete material. It is very difficult to leave air bubbles of stable dimensions, and in extreme cases, the air bubble layer and the concrete material layer may be separated.

In order to eliminate such drawbacks, in actual production, it is general to use a foam stabilizer together with a foam stabilizer.

As the bubble stabilizer, substances having a thickening action such as polyvinyl alcohol which is a water-soluble organic polymer and cellulose derivative are generally used.

[0006]

However, even the method of using the bubble stabilizer in combination has not always provided satisfactory results.

That is, in the conventional cell stabilizer, a large amount of cell stabilizer must be used in order to produce a concrete molded body in which cells are uniformly distributed. On the other hand, since it will hinder the foamability of the water slurry of the concrete material, it may increase the specific gravity of the manufactured concrete, and the most important purpose of reducing the weight of the concrete may not be achieved. . As a result, the use of cell stabilizers is in fact very limited.

The present invention has been made in view of the above circumstances, and provides a method for producing a lightweight cellular concrete capable of producing a lightweight cellular concrete in which cells are uniformly distributed without increasing the specific gravity of the produced concrete. The purpose is to.

[0009]

The present invention provides a method for producing a lightweight cellular concrete by mixing a binder such as cement, an aggregate, a foaming agent and a cell stabilizer.
The present invention relates to a method for producing a lightweight cellular concrete, characterized in that an okara powder dissolved in methyl alcohol is used as a cell stabilizer.

[0010]

Therefore, in the present invention, when a solution of okara powder dissolved in methyl alcohol is used as the bubble stabilizer, the protein in the okara powder is decomposed by methyl alcohol and easily dissolved in water. Methyl alcohol becomes methyl cellulose, which is a cellulose derivative.

Therefore, when the okara powder dissolved in methyl alcohol is dissolved in water in which concrete material is kneaded as a bubble stabilizer, a protein component which is decomposed by the methyl alcohol and easily dissolved in water is generated. It acts as a foaming agent and improves the foaming property of the water slurry of the concrete material, and at the same time, improves the stability of bubbles generated by the thickening action of the methyl cellulose.

[0012]

EXAMPLES Examples of the present invention will be described below. Mixing ratio Binder Portland cement Commercially available ordinary product 50 Quick lime (CaO) 10 Aggregate silas balun (fine powder of shirasu) 40 Water 70 Bubble stabilizer Stabilized okara powder with methyl alcohol (2% to water) 1 4 Mix the above to prepare a water slurry of concrete material.

The one prepared by dissolving okara powder in methyl alcohol, which is added as the bubble stabilizer, is a mixture of dried okara powder and powdered okara powder in the ratio of okara powder 2: methyl alcohol 8 to methyl alcohol. Then, this is used by dissolving a 2% amount in water for kneading concrete materials.

Further, a foaming agent of aluminum powder 0.07 in a mixing ratio is added to the prepared water slurry of the concrete material, and a gas is generated in the water slurry of the concrete material by a chemical reaction to introduce bubbles.

The lightweight cellular concrete molding obtained as described above floats horizontally even when an underwater flotation test is carried out, no deviation in specific gravity is observed, and the cut surface is observed to be fine. Air bubbles were distributed uniformly, and no separation between the air bubble layer and the concrete material layer was observed.

That is, when an okara powder dissolved in methyl alcohol is used as the bubble stabilizer, the okara powder has a protein and a fibrous substance. Therefore, if this is dissolved in methyl alcohol, the protein is decomposed. It becomes easily soluble in water, and the fiber becomes methylcellulose, which is a cellulose derivative, due to methyl alcohol.

Therefore, when a solution of okara powder in methyl alcohol is dissolved in water in which concrete materials are kneaded as a bubble stabilizer, the protein component decomposed by the methyl alcohol and easily dissolved in water is foamed. It acts as an agent and improves the foamability of the water slurry of the concrete material, and at the same time, improves the stability of bubbles generated by the thickening action of the methyl cellulose.

As described above, the foam stabilizer in which okara powder is dissolved in methyl alcohol improves the foamability of the water slurry of the concrete material and the stability of the foam generated by adding a very small amount. , Conventionally, the problem that has limited the use of the bubble stabilizer, that is, the problem that the foamability of the water slurry of the concrete material is hindered by the use of the bubble stabilizer can be largely eliminated, It is possible to manufacture lightweight cellular concrete in which cells are uniformly distributed without increasing the specific gravity.

The method for producing lightweight cellular concrete of the present invention is not limited to the above-mentioned embodiment,
Needless to say, various changes can be made without departing from the scope of the present invention.

[0020]

According to the above-described method for producing lightweight cellular concrete of the present invention, the foaming property of the water slurry of the concrete material is improved by using the one in which okara powder is dissolved in methyl alcohol as the cell stabilizer. And the stability of the generated bubbles can be improved,
Conventionally, it was possible to largely eliminate the problem that limited the use of the bubble stabilizer, that is, the problem that the use of the bubble stabilizer impairs the foamability of the water slurry of the concrete material, and the specific gravity of the concrete produced. It is possible to produce an excellent effect that it is possible to produce a lightweight cellular concrete in which cells are uniformly distributed without increasing the value.

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Claims (1)

[Claims] 1. A method for producing a lightweight cellular concrete by mixing a binder such as cement, an aggregate, a foaming agent and a cell stabilizer, wherein the cell stabilizer is okara powder dissolved in methyl alcohol. A method for producing lightweight cellular concrete, which is characterized in that: