JPH06184617A - Sleeve refractory for molten steel tapping hole in converter - Google Patents

Abstract

PURPOSE:To prevent the generation of crack by tension stress caused by high temp. at the time of tapping molten steel by constituting a sleeve refractory for tapping the molten steel from a converter with MgO-C series refractory and incorporating Al2O3 in the inside part. CONSTITUTION:The sleeve refractory used to the molten steel tapping hole in the converter is constituted with the MgO-C series refractory and also, in a part 1 being in direct contact with the molten steel in the inside, Al2O3 having >=96% quality is contained at 1-8% outside content and C content in the inside part 1, such as 5-30%, is higher than C content in the outside part 2, such as >=2%. As the Al2O3 is contained in the inside part, MgO, Al3O3 series spinel is generated by high temp. of the passed molten steel, and the structure in the inside part 1 is made to be close because of thermal expansion at this time, and the generation of crack is prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnesia-carbonaceous refractory sleeve for tapping holes in a converter.

[0002]

2. Description of the Related Art Magnesia-carbonaceous refractory is generally used as the material for the sleeve refractory for tapping holes in converters. JP-A-55-116685 and JP-A-62.
As disclosed in Japanese Patent Publication No. 202016 and Japanese Utility Model Publication No. 62-100496. This magnesia-carbonaceous refractory is known as a material having excellent corrosion resistance and spalling resistance.

[0003]

However, unlike the lining refractory in which only the inner surface side of the furnace is the operating surface, the sleeve refractory for the tap hole of the converter has the entire length in the longitudinal direction when molten steel flows through the inner hole. Since it becomes an operating surface, expansion and contraction due to heating-cooling is significant, and even in a magnesia-carbon refractory, cracks due to tensile stress occur on the back side. And
When this crack propagates and reaches the operating surface, it may fall off or fall out during use. Further, molten steel and slag infiltrate into the cracks, and the welding thereof makes it difficult to dismantle the refractory material.

An object of the present invention is to solve the above-mentioned conventional problems in the sleeve refractory for tapping holes in the converter.

[0005]

DISCLOSURE OF THE INVENTION The present invention is a sleeve refractory for a tap hole of a converter characterized by comprising a magnesia-carbonaceous refractory as a whole and containing alumina in the inner peripheral portion. . Further, in the above-mentioned sleeve refractory for tapping hole of converter, the invention is characterized in that the carbon content is smaller in the outer peripheral portion than in the inner peripheral portion.

In the present invention, alumina is contained in the inner peripheral portion. Alumina reacts with magnesia at a high temperature of about 1100 ° C during use to form MgO · Al ₂ O ₃ spinel, but due to the volume expansion accompanying the reaction at that time, the structure of the inner periphery of the sleeve refractory becomes dense. Has the effect of suppressing the infiltration of molten steel and slag.

Since the outer peripheral portion of the sleeve refractory does not come into direct contact with the molten steel, the temperature fluctuation is smaller than that of the inner peripheral portion, but thermal expansion of the inner peripheral portion causes tensile stress in the outer peripheral portion to easily cause cracks. . Therefore, in the present invention, a magnesia-based material having a large strength against tensile stress due to a reduction in carbon content is used.
The carbonaceous refractory is placed on the outer peripheral portion to prevent cracking on the outer peripheral portion.

Moreover, when the magnesia-carbonaceous refractory material having high strength is arranged on the outer peripheral portion in this manner, the refractory material on the inner peripheral portion is subjected to the binding force of the outer peripheral portion to make the structure dense and further improve the corrosion resistance. Target.

For example, the above-mentioned Japanese Patent Laid-Open No. 62-20201.
No. 6 discloses a sleeve refractory for a tap hole of a converter, which has a magnesia-carbon refractory in the inner peripheral portion and a magnesia refractory or a magnesia-dromite refractory in the outer peripheral portion. However, here, in order to reduce the frictional resistance of the outer peripheral surface and prevent the sleeve refractory from slipping off, the outer peripheral portion does not contain any carbon that causes slippage.

On the other hand, in the present invention, the magnesia-carbonaceous refractory is used in both the outer peripheral portion and the inner peripheral portion although the carbon contents are different. Since the material containing no carbon has a large thermal expansion, the effect of the present invention for restraining the thermal expansion of the inner peripheral portion cannot be obtained if it is arranged on the outer peripheral portion.

The magnesia used in the present invention is a sintered product,
It may be an electrofused product or a combination thereof. As with the conventional magnesia-carbon refractory, the grain size is adjusted to coarse grains, medium grains, and fine grains so as to obtain a densely packed structure.

Specific types of carbon include phosphorous graphite,
One or more selected from earth graphite, artificial graphite, pitch coke, anthracite, carbon black, pitch, and the like. The particle size is not particularly limited, but is preferably 0.5 mm or less. Alumina is, for example, Al ₂
A calcined product, an electrofused product, or a sintered product having O ₃ of 96 wt% or more is used. The ratio is not particularly limited, but is, for example, 10% by weight or less, preferably 1 to 8% by weight on the outside.
Is. If it exceeds 10 wt%, the corrosion resistance decreases, which is not preferable. The particle size is preferably fine to increase reactivity,
For example, it is set to 20 μm or less.

When the carbon content in the outer peripheral portion is smaller than that in the inner peripheral portion, the carbon content in the inner peripheral portion is, for example, 5 to 3.
It is set to 0 wt%. The proportion of carbon in the inner peripheral portion is determined within this range according to the operating conditions of the converter, the size of the sleeve refractory, the amount of carbon in the outer peripheral portion, and the like. If the proportion of carbon in the inner peripheral portion is less than 5 wt%, the effects of the corrosion resistance and spall resistance of carbon become insufficient, and if it exceeds 30 wt%, the oxidation resistance and wear resistance decrease.

The carbon in the outer peripheral portion needs to have a content of 2 wt% or more in order to sufficiently suppress thermal expansion. Also,
In order to restrain the thermal expansion of the inner peripheral portion by its strength, it is preferable that the content of carbon be smaller than that of the inner peripheral portion by, for example, 3 wt% or more.

The magnesia-carbon sleeve refractory material of the present invention constituting the outer peripheral portion and the inner peripheral portion is, in addition to the above-mentioned compounds, various metal powders and metals as long as the effects of the present invention are not impaired. An appropriate amount of one or more selected from oxides, carbides, borides, nitrides and fibers may be added. Examples of metal oxides are spinel, chromia and the like. Further, not only the inner peripheral portion, but may also contain alumina in the outer peripheral portion, the amount of alumina in the outer peripheral portion must be kept to a very small amount in order not to impair the effects of the present invention, Moreover, it is necessary to make the number smaller than the inner peripheral portion.

The sleeve refractory is manufactured by kneading and molding the above-mentioned compound. For kneading, 2 to 5 wt% of phenol resin, furan resin, pitch, etc. is added to the entire refractory composition by external coating. It is preferable to use a rubber press for molding so that a homogeneous structure can be obtained, but a uniaxial molding method can also be used. Further, it is possible to use a rubber press and uniaxial molding together.

In order to make the sleeve refractory into a two-layer structure in which the materials of the inner and outer circumferences are different, for example, a partition plate is put in a molding die, and the compound corresponding to the outer circumference and the inner circumference are separately charged, Mold integrally. Alternatively, the separately molded outer peripheral portion and inner peripheral portion are integrated with the joint surface via mortar or the like.

The thickness of the outer peripheral portion and the inner peripheral portion is not particularly limited, but in order to exert the effect of each portion and because one side is too thin, molding is not easy. It is preferable that the outer peripheral portion: inner peripheral portion is 1: 9 to 9: 1.

After the molding, the strength of the molded body is imparted by heating at about 100 to 800 ° C. to cure the binder. Also, when this is used as a fired product, for example, 12
Reduction baking is performed at 00 ° C. or lower.

The figure schematically shows an example of a cross section of the multilayer sleeve refractory of the present invention. In the figure,
FIG. A is a sectional view along the length direction, and FIG. B is a sectional view taken along line XX of FIG. FIG. 1 shows an example in which the inner peripheral portion (1) and the outer peripheral portion (2) have the same thickness in the longitudinal direction. Figure 2
Is an example in which the base end is entirely made of the same material as the inner peripheral part (1). In the converter in which one end of the sleeve is exposed to the inside of the furnace, the structure of FIG. 2 reduces the temperature fluctuation of the outer peripheral portion.

[0021]

EXAMPLES Examples of the present invention and comparative examples will be shown below. Table 1 shows examples of the present invention, comparative examples and test results thereof.

[0022]

[Table 1]

Thermal expansion coefficient: The inner peripheral compound and the outer peripheral compound shown in the table were kneaded and molded separately. At the time of kneading, a phenol resin was externally added as a binder and 3.5 wt% was added. After pressure molding with a pressure of 1000 / cm ² , 150 ° C
It heat-processed. The coefficient of thermal expansion was measured for each of the materials of the inner peripheral portion and the outer peripheral portion thus obtained.

From these results, it is confirmed that the material of the inner peripheral portion has a large thermal expansion due to the inclusion of alumina.

Bending strength: Bending strength was measured at 1400 ° C. for each material of the inner peripheral portion and the outer peripheral portion obtained in the same manner as above. From this result, it is confirmed that the material having a low carbon content has a high strength. As a result, the outer peripheral portion works as a function of restraining the thermal expansion of the inner peripheral portion.

Crack resistance; phenolic resin in formulation 3.
5 wt% was added and kneaded, and about 10 by a rubber press
Inner and outer peripheral parts were integrally molded with a pressing force of 00 / cm ² and then heat treated at about 200 ° C. to obtain an inner diameter of 200 × thickness of 100 ×
The measurement was performed on a sleeve refractory having a length of 1200 mm.
Examples 1 to 5 and Comparative Examples 2 to 3 are sleeve refractories having different materials for the inner and outer peripheries, and the outer peripheral part and the inner peripheral part are formed to have the same thickness. Comparative Example 1 is a sleeve refractory having the same material as a whole.

At 1650 ° C., a sample including a boundary surface between an inner peripheral portion and an outer peripheral portion is placed inside an annular assembly arranged such that the inner peripheral portion is on the inner side and the boundary surface is parallel to the surface to be heated. After the heating and air-cooling operations were repeated, the state of crack generation in the inner peripheral portion and the outer peripheral portion was evaluated in four grades of large, medium, small and none. In Examples 1 to 3, few cracks were generated in the inner peripheral portion, and in Examples 4 to 8, cracks were hardly generated in both the inner peripheral portion and the outer peripheral portion.

Actual machine test: Among the sleeve refractories manufactured in the same manner as the method shown in the above-mentioned crack resistance, Example 2, Example 4, Comparative Example 1, Comparative Example 2 and Comparative Example 4 were actually tested. As a refractory for tapped holes in a 300 t converter, the infiltration state of the metal, the crack generation state, the dismantling property and the number of times of service were measured. The state of intrusion of metal and the state of crack formation were visually evaluated after use, and were evaluated as large, medium and small. As for dismantling property, the required times were compared and shown by ○, △, ×. As is clear from this result, the sleeve refractories obtained from the examples of the present invention have good durability and dismantling property.

Comparative Example 1 is a magnesia-carbonaceous refractory made of the same material as a whole. The crack resistance and the actual machine test are inferior to the examples of the present invention. Comparative Example 2 is a magnesia-carbonaceous refractory in the inner peripheral portion, but is a magnesia substance containing no carbon in the outer peripheral portion, and the inner peripheral portion is not constrained by the outer peripheral portion, so crack resistance and an actual machine test are performed. Both are inferior. In Comparative Example 3, both the outer peripheral portion and the inner peripheral portion were made of magnesia-carbonaceous refractory, and contrary to the present invention, the carbon content was larger in the outer peripheral portion than in the inner peripheral portion, and due to the thermal stress of the inner peripheral portion. Since the outer peripheral portion was cracked and the outer peripheral portion had no restraining force on the inner peripheral portion, no improvement in durability was observed. In Comparative Example 4, both the outer peripheral portion and the inner peripheral portion were made of a magnesia-carbon refractory material, and contrary to the present invention, the same amount of calcined alumina was added to both the outer peripheral portion and the inner peripheral portion. The outer peripheral portion expands due to the addition of alumina, and the effect of restraining the expansion of the inner peripheral portion is not as great as that of the present invention. Therefore, in the actual machine test, the durability is inferior to the inventive examples.

[0030]

INDUSTRIAL APPLICABILITY The sleeve refractory produced according to the present invention is originally made of magnesia-carbon refractory because it has a multi-layered structure in which the inner and outer peripheral parts are made of a specific material. In combination with the corrosion resistance and the spalling resistance, it exhibits excellent effects on the durability and dismantling required as a refractory for tapholes in converters.

[Brief description of drawings]

FIG. 1 schematically shows a cross section of a sleeve refractory material of the present invention. FIG. A is a sectional view along the length direction, and FIG. B is a sectional view taken along line XX of FIG.

FIG. 2 is a schematic view showing a cross section of the sleeve refractory material of the present invention. FIG. A is a sectional view taken along the length direction, and FIG. B is a sectional view perpendicular to the length direction. This is an example in which the entire base end portion is made of the material of the inner peripheral portion 1.

[Simple explanation of symbols]

 1 inner circumference 2 outer circumference

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Tsuneo Kitai 1-3-1, Niihama, Arai-cho, Takasago, Hyogo Prefecture Harima Ceramic Co., Ltd. (72) Naoto Okamoto 1-3-3, Niihama, Arai-cho, Takasago, Hyogo Prefecture No. Harima Ceramic Co., Ltd. (72) Inventor Masato Tanaka 1-3-1, Niihama, Arai-cho, Takasago, Hyogo Prefecture Harima Ceramic Co., Ltd.

Claims (2)

[Claims] 1. A sleeve refractory for a tap hole of a converter characterized in that it is entirely made of a magnesia-carbonaceous refractory and contains alumina in its inner peripheral portion. 2. The sleeve refractory for a tap hole of a converter according to claim 1, wherein the carbon content is smaller in the outer peripheral portion than in the inner peripheral portion.