JPH059082A - Refractory for spraying - Google Patents

Abstract

PURPOSE:To provide refractories for spraying having remarkably improved sticking property, especially dropping phenomenon in a spraying process. CONSTITUTION:Basic aluminum lactate modified with an inorg. acid is used as an essential component of refractories for spraying. The amt. of the inorg. acid is 0.5-20wt.% of the amt. of the modified basic aluminum lactate. Sulfuric acid, phosphoric acid or boric acid can be used as the inorg. acid. A hardening accelerator may be added to the refractories.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refractory material for spraying, and more particularly to a refractory material for spraying, which is greatly improved in adhesion, particularly sagging (flowing down) phenomenon in spraying work.

[0002]

2. Description of the Related Art Conventional refractory materials for spraying are castable refractory materials bonded to alumina cement, or those obtained by adding a hardening accelerator such as Li salt or sodium aluminate, water glass, sodium fluorosilicate or condensed aluminum phosphate. In general, a curing agent such as the above, or a combination of aluminum phosphate and various alkaline salts of phosphoric acid and using MgO or Ca (OH) ₂ as the curing agent has been generally used. The usual castable refractory materials are mainly used for structures in cold working, but they are hardly used in hot spraying because of their poor adhesion. Water-glass materials have problems in heat resistance and are often used as acid-resistant materials. Of these, phosphate-based materials excel in hot adhesion and are mainly used as hot repair materials. But heat resistance,
It is not completely satisfactory in terms of corrosion resistance, strength, adhesion, etc. Further, there is a tendency that the number of steel types that do not like to mix the phosphorus component increases, and there is a limit to the use of the phosphoric acid-based binder.

In recent years, in the refractory industry, a technique for effectively utilizing ultrafine powder and a dispersant to make the refractory low in water content, high in density and high in strength has become general. This technology was applied to castable refractories, which are castless refractories commonly referred to as cementless type or cement-free type by those skilled in the art, and which have a low porosity, high density, and high strength. This cementless type castable refractory has a high fluidity because it disintegrates ultrafine powder using a dispersant, and when spraying this, deposits flow down from the spraying surface and an adhesive layer can be formed. Absent. That is, it is difficult to use it as a spray material. As a countermeasure against this, a technique of using a large amount of a dispersant to shift the system from the dispersion region to the coagulation region and using it as a spraying material (Japanese Patent Laid-Open No. 60-11275) or a curing accelerator is used in combination, and after adhesion There is disclosed a technique (Japanese Patent Laid-Open No. 60-235770) that cures immediately to prevent apparent flow-down. Further, the spray material is divided into an aggregate grain portion containing a curing agent and a fine powder portion containing ultrafine powder and a dispersant, and the fine powder portion is kneaded into a slurry in advance, and the aggregate grain portion is sprayed with a spray nozzle. A technique for sufficiently demonstrating the effect of the joint portion by mixing to obtain a sprayed body of high density and high altitude (Japanese Patent Laid-Open Publication No. 6-58242).
No. 0-86079 and Japanese Patent Laid-Open No. 61-101470) are also disclosed.

However, since this cementless type spraying material has high strength and high density, it has a low porosity, it is difficult for the kneading water (added water) to escape from the construction body, and steam is generated when the construction body is rapidly heated. It has the drawback of being prone to explosion. This means that in the case of cold spraying, steam blasting occurs when performing rapid heating and drying after construction, and in hot spraying, it is essential that the spraying at an ambient temperature above the explosion temperature of the sprayed material is essential. It means that it is impossible. Furthermore, if spraying is applied to a high temperature wall surface, the added water is immediately evaporated by the heat of the wall surface, and the sprayed material that has adhered to it is stripped off due to its vapor pressure. If spraying is continued, the wall surface is cooled by the added water and vaporization is suppressed, so that the adhesion gradually starts. However, when the heat capacity of the furnace is large, the temperature of the furnace itself hardly decreases, so that the sprayed work body is rapidly heated and raised in temperature, and a large amount of flaking occurs due to evaporation of internal moisture. In other words, this cementless-type spray material essentially has a problem that it is not suitable for hot spraying at high temperatures from the viewpoint of adhesiveness.

It is well known to those skilled in the art that the explosion temperature of cementless type castable refractories is extremely low. As a countermeasure against this, Al powder is added to facilitate dehydration due to H ₂ gas generation and heat generation. Techniques for adding or adding fiber substances, particularly organic short fibers, are known. When these techniques are applied to spray materials, when Al powder is added, H
_{Since 2} gases are generated, there is a danger of hydrogen gas explosion, and the difference in specific gravity between the organic short fibers and the refractory aggregate is significantly large, and separation occurs during spraying, and the sprayed product tends to become uneven. The technique of adding Al powder is used in JP-A-60-235770, and a recent example of using organic short fibers as a spraying material is JP-A-60-71577. In addition, there is a description in Japanese Patent Laid-Open No. 60-86079 that the defect of explosive explosion during rapid drying, which is contained in alumina cement, has been removed, but since the actual example is not shown and the reason is unclear, It is difficult to confirm the degree of its effect. or,
In JP-A-60-15056, "Tundish hot spraying method", there is a problem of flaking off due to rapid evaporation of water when the surface temperature is 300 ° C or higher, and it has been proposed to arrange a wire mesh as a countermeasure against this problem. However, this is just a convenient method. As described above, the problem of adhesion in hot spraying has not been sufficiently solved in the art.

[0006] Therefore, one of the applicants of the present invention added a basic aluminum lactate (hereinafter abbreviated as aluminum lactate) as a completely different technique to
We found that we could solve the problem of adhesion of the hot spray material and filed a patent application (Japanese Patent Application No. 62-100500).
issue). This spray material is wonderful and shows excellent performance in actual furnace trials, and is officially adopted as a hot spray repair material.
It has been put to practical use without problems. However, from a certain point of time, a problem of dripping (flowing down) suddenly occurred, which could not be solved by means such as increasing the amount of the curing accelerator.

As a result of the investigation, the problem of sagging (falling down) occurred because the production of aluminum lactate was started in a small amount in a laboratory.
It must be from the time of shifting to mass production in the factory. This is because the amount of aluminum lactate used increased and it was not possible to keep up with small-scale production in a laboratory, and a new mass production facility dedicated to aluminum lactate was put into operation. And the products of the new equipment should be of extremely stable quality. On the other hand, it seems that the old products that were produced in small quantities in the laboratory had poor stability. It was also found that the new aluminum lactate, which is stable in quality, is rich in fluidity and does not have a sagging preventive effect due to the curing accelerator.

[0008]

The problem to be solved is a phenomenon of sagging (flowing down) of deposits at the time of spraying which is newly generated in the invention of Japanese Patent Application No. 62-100500.

[0009]

Means for Solving the Problems Aluminum lactate modified with an inorganic acid is used. In order to find one that does not sag, or one that can prevent sagging by adding a curing accelerator,
As a result of various studies, it was found that by using aluminum lactate modified with an inorganic acid, the sagging (flowing-down) phenomenon was reduced, and the curing accelerator worked effectively to solve the sagging problem. That is, the present invention relates to Japanese Patent Application No. 62-10050.
This is an improvement of the problems that occurred after the No. 0 invention. The present invention will be described in more detail below. All% shown below mean% by weight.

The present invention is also effective for ordinary castable refractory-based, water glass-based, or phosphate-based spraying materials, but for high-density cementless-type and cement-free type spraying materials. Since they are especially effective, they will be mainly described below.

The spray refractory of the present invention basically comprises a refractory aggregate with a controlled particle size and basic aluminum lactate modified with an inorganic acid (hereinafter referred to as modified aluminum lactate).
As long as it is a spray material, it is common to use a binder, a curing agent, and a curing accelerator together. Further, it is more preferable to use the ultrafine powder or the dispersant as described above.

The refractory aggregates include acid, neutral, basic,
Alternatively, known natural or artificial materials may be used alone or in combination of two or more kinds. In the case of sprayed materials, the grain size composition is generally finer than in the case of pouring construction. Ultrafine powder refers to particles having a particle size of 10 μm or less, preferably 1 μm or less, which can be made by crushing refractory aggregates, such as clay, silica, alumina, zirconia,
Materials such as titania, chromia and silicon carbide are commercially available. These may be used alone or in combination depending on the purpose.

Dispersants are silicates, phosphates, carboxylates,
Sulfonates, acrylates, etc. are well known,
Alkaline salts are generally used, and they are also used alone or in combination.

Modified aluminum lactate characterizes the present invention. Al ₂ O ₃ / lactic acid (molar ratio) of 0.3 to 2.0 obtained by reacting a water-soluble aluminum salt and carbonic acid, or an alumina hydrate obtained by reacting carbonate with lactic acid. It is a powder obtained by adding an inorganic acid to a certain aluminum lactate (JP-A-57-8034) to modify and spray-drying. As the inorganic acid, hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, boric acid or the like can be used, and the amount thereof is 0.5 to 20%, preferably 1 to
10 is good. If it is less than 0.5%, the effect of stopping dripping does not appear, and if it exceeds 20%, the properties of aluminum lactate are impaired.
The steam explosive flaking occurs and the hot adhesion decreases. The amount of modified aluminum lactate used is 0.2 when applied to the refractory material.
10 to 10%, preferably 0.3 to 6% is good. This is because if the content is 0.2% or less, it is difficult to recognize the effect, and if it is 10% or more, the strength is significantly reduced.

Aluminum lactate also functions as a dispersant or a binder. Examples of the binder, curing agent, and curing accelerator include cements such as Portland cement, alumina cement, and barium cement, oxides and hydroxides of alkaline earth metals such as MgO and dolomite, ρ-alumina, alumina hydrate, Aluminum phosphate, alkali phosphate,
Aluminum sulfate, sodium silicate, sodium aluminate, L
i-salts, colloidal silica, etc. can be used.
The binder may be used alone or in combination, depending on the purpose. In particular, as the curing accelerator, electrofusion,
Powders of calcined and calcined MgO, calcined dolomite, calcium hydroxide, aluminum sulfate, sodium aluminate, Li salts and the like are preferable.

Further, it is possible to add Al powder, which is known as a technique for preventing the explosion of cementless type castable refractories, and organic short fibers together, and to add steel fibers and other metal powders as necessary. I can. Of these, organic fibers,
Particularly, natural fibers or synthetic fibers having a low softening and decomposition temperature (for example, JP-A-59-169985, JP-A-61-44772, JP-A-61-77673, JP-A-62-217686). And getting wet with water,
It is preferably used in combination with a substance having good dispersibility (for example, vinylon fiber which is easily soluble).

Experimental Example A composition consisting of 77% of electrofused bauxite containing 95% of Al ₂ O ₃ , 10% of calcined alumina, 4% of silica flour, 8% of high alumina cement, and 1% of sodium phosphate dispersant was further modified lactic acid. A refractory material for spraying was prepared by adding 1% of aluminum or aluminum lactate and 2% of aluminum sulfate as a curing accelerator. This product was tested for flow index and adhesion during hot spraying to 1000 ° C. The results are shown in Table 1.

[0018]

[Table 1]

[0019]

Example: Magnesia 91%, silica flour 4%, high alumina cement 5%, sulfuric acid modified aluminum lactate (sulfuric acid amount 3.1%) 2% externally added, sodium aluminate 1% externally added as an effect promoter. A refractory for spraying was created. When this material was used for repairing the slag line part of the molten steel ladle whose temperature at the spray repair part was about 1000 ° C., the material of this example was excellent in that there was no sag (downflow) and no steam explosion cracking. It showed good adhesion and could easily reach the purpose of repair. On the other hand, the refractory for spraying using aluminum lactate which was not modified with an inorganic acid was not able to achieve the purpose of spray repair because the sagging (flowing down) phenomenon was remarkable and the build-up could not be achieved. Further, although the durability of this example was 15 charges, the durability of the conventional refractory for spraying with a phosphate binder was as follows:
It was only 5 charges.

[0020]

As is clear from the experimental examples (Table 1), when the inorganic acid-modified aluminum lactate is used, the flow index decreases and the fluidity decreases. Moreover, when a curing accelerator is used in combination, the flow index is markedly reduced, and it can be said that it exhibits almost no fluidity. On the other hand, when unmodified aluminum lactate is used, the fluidity increases with time, and it can be seen that no change occurs even if the curing accelerator is added. That is, it is understood that the use of the modified aluminum lactate with an inorganic acid will greatly improve the problem of dripping of the refractory for spraying. This means that "1" in Table 1
The results of the hot adhesion at 000 ° C. ”and the application in an actual furnace are clearly demonstrated. Further, the spray refractory of the present invention is a conventional phosphate-based binder. It is also clear from the examples that the durability is extremely superior to that of the spray refractory.

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] August 5, 1991

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0003

[Correction method] Change

[Correction content]

In recent years, in the refractory industry, a technique for effectively utilizing ultrafine powder and a dispersant to make the refractory low in water content, high in density and high in strength has become general. This technology was applied to castable refractories, which are castless refractories commonly referred to as cementless type or cement-free type by those skilled in the art, and which have a low porosity, high density, and high strength. This cementless type castable refractory has a high fluidity because it disintegrates ultrafine powder using a dispersant, and when spraying this, deposits flow down from the spraying surface and an adhesive layer can be formed. Absent. That is, it is difficult to use it as a spray material. As a countermeasure against this, a technique of using a large amount of a dispersant to shift the system from the dispersion region to the coagulation region and using it as a spraying material (Japanese Patent Laid-Open No. 60-11275) or a curing accelerator is used in combination, and after adhesion There is disclosed a technique (Japanese Patent Laid-Open No. 60-235770) that cures immediately to prevent apparent flow-down. Further, the spray material is divided into an aggregate grain portion containing a curing agent and a fine powder portion containing ultrafine powder and a dispersant, and the fine powder portion is kneaded into a slurry in advance, and the aggregate grain portion is sprayed with a spray nozzle. A technique for sufficiently demonstrating the effect of the joint portion by mixing to obtain a high-density and high-strength spraying construction body (Japanese Patent Application Laid-Open No. 6-58242).
Nos. 0-86079 and 61-101470 are also disclosed.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shinya Yamauchi             5-4-1 Chikko, Tamano-shi, Okayama Japan Special furnace             Material Co., Ltd. (72) Inventor Makoto Hayakawa             5-4-1 Chikko, Tamano-shi, Okayama Japan Special furnace             Material Co., Ltd.

Claims (4)

[Claims] 1. A refractory material for spraying, which comprises a basic aluminum lactate modified with an inorganic acid as an essential component. 2. The refractory material for spraying according to claim 1, wherein the amount of the inorganic acid is 0.5 to 20% by weight in the modified basic aluminum lactate. 3. The refractory material for spraying according to claim 2, wherein the inorganic acid is one or more of sulfuric acid, phosphoric acid and boric acid. 4. The refractory material for spraying according to claim 1, further comprising a curing accelerator.