JPH0256303B2 - - Google Patents

Description

[Detailed description of the invention]

[Industrial Field of Application] The present invention relates to magnesia carbon bricks with excellent corrosion resistance. [Prior art and its problems] Magnesia carbon brick is a refractory that combines the corrosion resistance against basic slag due to magnesia, the resistance to wetting against slag due to phosphorous graphite, and the superiority against thermal shock resistance.
As a brick that has both heat resistance and spalling properties, its uses are continuing to expand. Magnesia carbon bricks are generally made by mixing sintered magnesia, typically seawater magnesia clinker, with phosphorous graphite as a carbon source in an appropriate ratio, and using phenolic resins as a binder to induce carbon bonding. It is an unfired brick. The ratio of magnesia raw material to graphite is selected depending on the part where the brick is used, but the blending ratio of graphite is preferably 5% by weight or more from the viewpoint of heat resistance and spalling property, and 40% by weight or less from the viewpoint of oxidation resistance. is suitable. [Problems to be Solved by the Invention] Magnesia carbon bricks having a blending ratio within this range have little spalling wear when used in an actual furnace. Wear therefore proceeds primarily through chemical attack. Various measures have been attempted to retard the chemical erosion rate of magnesia carbon bricks, one of which is the use of fused magnesia as a magnesia raw material. Since slag infiltration through crystal gaps has a large effect on the wear rate of sintered magnesia clinker, fused magnesia, which is made up of almost single crystals, has extremely advantageous characteristics against the above chemical attack. Therefore, when a large amount of fused magnesia is used, specifically, 50% by weight or more of the magnesia raw material, the corrosion resistance is significantly improved compared to bricks using sintered magnesia. However, fused magnesia is much more expensive than sintered magnesia, and is not necessarily a satisfactory material from the viewpoints of cost and performance. For this reason, attempts have been made to use high-purity graphite as a means of improving corrosion resistance and being cheaper than using fused magnesia. Since phosphorous graphite is a natural raw material that coexists with clay minerals, it contains clay as impurities, but it is possible to reduce the amount of impurities other than carbon to 1% by weight or less by using various types. When such high-purity graphite is used in magnesia carbon bricks, corrosion resistance is improved due to the effect of reducing impurities in the matrix. On the other hand, from the viewpoint of dissolution rate in slag and stability in the presence of carbon, sintered magnesia clinker has high purity, large crystal size, low B ₂ O ₃ content,
Preferable properties include high basicity (CaO/SiO ₂ ) of the silicate. Sintered magnesia clinker that satisfies these requirements certainly has good corrosion resistance, and especially in bricks that combine high-purity graphite, the effect of improving corrosion resistance is greater than that of ordinary magnesia/carbon bricks. However, compared to the bricks using a large amount of fused magnesia, the corrosion resistance is inferior, and it is evaluated that it is insufficient for prolonging the life of an actual furnace and improving the melting loss balance. Therefore, the reality is that bricks containing a large amount of fused magnesia are still being used in areas where high corrosion resistance is required, although they are expensive. [Means for Solving the Problems] The present invention aims to control the amount of impurities in magnesia carbon bricks using inexpensive sintered magnesia clinker, and to increase the density of the sintered magnesia clinker to a certain level or higher. It was found that the corrosion resistance was significantly improved by using this method, and the problems of conventional magnesia carbon bricks were solved. The magnesia carbon brick of the present invention contains 60 to 95% by weight of sintered magnesia clinker and 5% by weight of phosphorous graphite.
In magnesia carbon bricks composed of ~40% by weight, impurities in both raw materials, i.e.
The total amount of CaO, SiO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , B ₂ O ₃ etc. is 1
% by weight or less. Generally, sintered magnesia clinker consists of about 98% by weight MgO, with the remainder being CaO, SiO ₂ , Al ₂ O ₃ ,
It is composed of Fe ₂ O ₃ , B ₂ O ₃ , etc. Among them, those with a relatively high CaO content, that is, a high CaO/SiO ₂ molar ratio, are said to be suitable for magnesia carbon bricks because they have a high silicate melting point and excellent coexistence stability with carbon. ing. However, the main impurity in phosphorous graphite, which is another constituent, is SiO ₂ , and even if the basicity of magnesia in the brick matrix is high, SiO ₂ in graphite reacts at high temperatures.
It forms low basicity compositions such as C ₃ Ms ₂ and CMS, resulting in decreased heat resistance and stability in the coexistence of carbon. Therefore, in magnesia carbon bricks, it is desirable to reduce the absolute amount of silicate in the magnesia matrix.
Total amount of SiO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , B ₂ O ₃ etc. is 1% by weight
Corrosion resistance is not sufficient in a range exceeding 1% by weight, and corrosion resistance is dramatically improved in a range of 1% by weight or less. However, the purpose of the present invention cannot be achieved only by regulating the composition, and the bulk specific gravity of the sintered magnesia clinker used is 3.40 or more, preferably 3.43.
Must be above. As long as the bulk specific gravity does not exceed 3.40, no matter how much the impurities in the brick are reduced, the improvement in corrosion resistance is slight and the desired effect cannot be achieved. This is because sintered magnesia clinker with a bulk specific gravity not exceeding 3.40 has a large number of closed pores in the single crystal, so the dissolution rate into the slag is high, and it is poorly stabilized when carbon coexists, so it is possible to reduce impurities. This is presumed to be due to the fact that the effect of improving corrosion resistance is not exhibited. The sintered magnesia clinker used in the present invention necessarily has an MgO purity of 99% or more in order to highly control the impurity content in the brick, and similarly, the impurity content in the phosphorescent graphite must be 99% or higher. It is assumed that the amount is also 1% by weight or less. However, if the MgO purity of the sintered magnesia clinker is extremely high, graphite with a slightly higher amount of impurities may be used as long as the total amount of impurities in the brick does not exceed 1% by weight. The magnesia carbon brick according to the present invention is
The above-mentioned sintered magnesia clinker and phosphorous graphite are arbitrarily mixed in the range of 60 to 95% by weight and 5 to 40% by weight, respectively, and then kneaded and molded by a conventional method.The binder used at this time is carbon. For the purpose of strengthening the bond, phenolic resins containing a large amount of fixed carbon are suitable. In the case of novolak type phenolic resin, it causes a polycondensation reaction at around 100℃ in the coexistence with hexamethylenetetraamine, a curing agent, and
Since it develops sufficient strength at 200℃, it can be used in actual furnaces as an unfired brick. The magnesia carbon brick according to the present invention is
It is an unfired brick made by bonding sintered magnesia clinker and phosphorous graphite with a phenolic resin, but in addition to these, metals, carbides, etc. can be added for the purpose of preventing oxidation, etc., if necessary. [Examples] Example 1 Magnesia carbon bricks shown in Table 3 were manufactured using magnesia clinker and phosphorous graphite having the properties shown in Tables 1 and 2. Example 1 has the same corrosion resistance as the brick using 50% by weight of fused magnesia in Comparative Example 1,
Also, compared to Comparative Example 3, its superiority in characteristics is clear. The bricks of Example 1 and Comparative Example 1 were used by bonding them to the trunnion of a 300-ton converter. Table 4 shows the erosion rate. The bricks of Example 1 tended to have a slightly lower erosion rate. Considering the brick cost index, the superiority of the bricks made of Example 1 is obvious. Example 2 Magnesia carbon bricks shown in Table 6 were manufactured using sintered magnesia clinker A shown in Table 1 and phosphorous graphite shown in Table 5. As is clear from the characteristics in Table 6, a clear decrease in corrosion resistance was observed in a range exceeding the total amount of impurities according to the present invention, proving the necessity of the scope of the present invention. Example 3 Magnesia carbon bricks shown in Table 8 were manufactured using the magnesia clinker shown in Table 7 and the phosphorescent graphite shown in Table 2. As is clear from the characteristics in Table 8, Examples 3 and 4
Corrosion resistance is improved compared to Comparative Example 4, which has a high impurity content in the brick, and Comparative Example 5, which has a low bulk specific gravity of magnesia clinker. The bricks of Example 4 and Comparative Example 5 were used in the hot spot section of a 70t electric furnace for comparison. Table 9 shows the erosion rate. The brick of Example 4 had an erosion rate of about 30
% has been improved, making it possible to extend the life of the furnace.

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[Table] Use

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[Table] Use

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[Table] * Rotating slag erosion test
1700℃ C〓S=2.0, TFe=10.0% slag used

〔Effect of the invention〕

The magnesia carbon brick according to the present invention is
It has the same corrosion resistance as conventional, expensive magnesia carbon bricks that use fused magnesia, so it offers significant cost benefits, and the corrosion resistance is significantly improved compared to conventional materials that do not use fused magnesia. Therefore, it is possible to measure the life-up of the applicable furnace. Examples of uses of the magnesia carbon bricks according to the present invention include, but are not limited to, converters, electric furnaces, secondary smelting furnaces, ladles, pig iron mixers, etc.

Claims (1)

[Claims] 1. In a magnesia carbon brick consisting of 60 to 95% by weight of sintered magnesia clinker and 5 to 40% by weight of phosphorous graphite, the total amount of impurities in both raw materials is 1% by weight or less, and the bulk specific gravity of the sintered magnesia clinker A magnesia carbon brick characterized by having a value of 3.40 or more.