RU2426798C1 - Procedure for preparing slag for application of scull on lining of converter - Google Patents

Abstract

FIELD: metallurgy. ^ SUBSTANCE: procedure consists in blowing final converter slag of preceding melt containing 7-14 % of MgO during 0.5-2.0 min with oxygen at flow rate of 1-3 m3/min-t of steel. Further slag is thickened with additives of magnesia materials with ratio of CaO to MgO not over 0.3 at amount of 1.5-6.3 kg/t of steel. Scull is applied on lining of the converter by blowing slag with nitrogen. ^ EFFECT: application of scull layer practically on whole surfaces of lining, increased adhesion to refractory surface and raised service life of scull up to 4 melts. ^ 2 cl, 1 tbl, 1 ex

Description

The invention relates to the field of ferrous metallurgy and can be used when applying a protective coating (skull) on the refractory lining of converters.

There is a method of preparing the final converter slag before applying it to the lining of a 160-ton converter by blowing with nitrogen, which provides for the addition of coke in an amount of 0-1200 kg per slag in the range of carbon concentrations in the metal at the output of 0.02-0.10%, and lime magnesia flux (IMP) containing 50% CaO and 32% MgO, with a ratio of CaO to MgO of 1.53 in an amount of 600-2000 kg [1]. However, this method does not provide the necessary protective properties of the skull layer on the converter lining throughout the entire smelting process due to the unsatisfactory physical properties of the final slag due to its significant oxidation by coke carbon and a high proportion of low-melting ferritic phases (calcium ferrites) due to the high CaO content in the magnesian material (IMP), sitting on the slag. The closest in technical essence of the proposed method is a method that, after thickening the final highly basic slag with additives of dolomite and lime, treating it with oxygen in an amount of 25-45 m ³ / min t of slag for 0.5-1.5 min, followed by thickening lime [2]. The proposed technique provides the formation of highly basic homogeneous slags with high adhesion with respect to the refractory lining during the "rolling" of slag on it. However, in this case, the “rolling” of slag onto the converter lining during its swaying provides a skull coating only on a part of the lining surface, which has low wear resistance due to the high proportion of low-melting ferritic phases (up to 60% calcium ferrites) [3].

In the proposed method, the task is to achieve high slag adhesion with respect to the refractory lining of the converter due to homogenization of the final slag and increased wear resistance of the skull coating due to an increase in the fraction of high temperature ferritic phases (magnesiouustite and magnesioferrite in the slag) and, as a consequence, increased stability high technological and technical and economic indicators of the process.

The problem is solved in that in the known method, including leaving the final slag, thickening it with additives of magnesian materials and blowing the slag with nitrogen, the final slag of the previous smelting containing 7-14% MgO is blown with oxygen for 0.5-2.0 min with a flow rate of 1-3 m ³ / min · t of steel, followed by slag thickening with additives of magnesia materials with a CaO to MgO ratio of not more than 0.3 in the amount of 1.5-6.3 kg / t of steel and applied to the lining of the converter skull by blowing slag nitrogen. Technological method provides for the addition of magnesian materials with a CaO to MgO ratio of not more than 0.3 in an amount of 0.6-1.5 kg / t of steel at the time of slag blowing with oxygen when the MgO content in the final slag is less than 7%.

When processing the slag with oxygen for less than 0.5 min at the claimed flow rate, the problem is not solved due to the insufficient amount of iron oxide (Fe ₂ O ₃ ) formed during the oxidation of iron oxide (FeO) with gaseous oxygen.

When the processing time of the slag with oxygen more than 2.0 min, a decrease in the productivity of the converters is observed due to an increase in the duration of the smelting without increasing the efficiency of the claimed method.

The goal is not achieved when the oxygen flow rate is less than 1 m ³ / min · t of steel in the claimed interval for the duration of slag purging due to the lack of iron oxide (Fe ₂ O ₃ ) formed in the slag during the oxidation of ferrous oxide (FeO).

The oxygen consumption of more than 3 m ³ / min · t of steel is accompanied by an increase in its total consumption for melting without increasing the efficiency of the claimed method.

The oxygen treatment of the final slag containing less than 7% MgO does not provide a solution to the problem due to the low fraction of high-temperature ferritic phases formed in the slag (magnesiuustite and magnesioferrite). To solve the problem in this case, magnesia materials with a CaO to MgO ratio of not more than 0.3 in the declared amounts are added to the slag at the time of its treatment with oxygen.

The problem is not solved when the consumption of magnesia materials is less than 0.6 kg / t of steel due to the lack of high-temperature ferritic phases in the slag and when the consumption is more than 1.5 kg / t of steel due to significant heterogenization of the slag.

The task is not achieved when the ratio of CaO to MgO in the magnesia materials used is more than 0.3 due to an increase in the concentration in the slag of low-temperature ferritic phases (calcium ferrites) and a decrease in the proportion of high-temperature ferritic phases.

When oxygen processing slag containing more than 14% MgO, the task is not achieved due to its weak homogenization, because slag in this case is in the region of significant supersaturation of MgO.

Thickening of the slag after it has been treated with oxygen with magnesia materials in an amount of less than 1.5 kg / t of steel does not provide a solution to the problem due to its high fluidity (slag “drains” from the surface of the refractory lining when it is blown with nitrogen). The task is not achieved and with a consumption of more than 6.3 kg / t of steel due to its low adhesion to the refractory lining (the slag is practically not blown by nitrogen, has low adhesion and "rolls" from the refractory surface of the lining).

A comparison of the claimed method of preparing slag for applying a skull on the converter lining with the method selected for the prototype shows that the claimed method, in which the final slag of the previous smelting containing 7-14% MgO, is blown up with oxygen for 0.5-2.0 min with a flow rate of 1-3 m ³ / min · t of steel and an additive at that moment of magnesian materials with a CaO to MgO ratio of not more than 0.3 in an amount of 0.6-1.5 kg / t of steel with an MgO content in the final slag of less than 7 % followed by slag thickening with additives of the above magnesia materials in t he 1,5-6,3 kg / t steel ledge and applying to the surface of the lining of the converter slag by blowing nitrogen provides high adhesion of slag relative to the refractory lining of the converter due to homogenize and increase the final slag of iron oxide (Fe ₂ O ₃₎ therein , increasing the wear resistance of the skull coating by increasing the fraction of high-temperature ferritic phases in the slag and increasing the lining resistance of the converters and meets the criterion of "novelty."

The analysis of patents and scientific and technical literature did not reveal the use of new significant features used in the proposed solution for their functional purpose. Therefore, the present invention meets the criterion of "inventive" level.

The method is as follows: after the metal is released from the converter, it is returned to a vertical position, the purge lance is lowered and the remaining slag is briefly blown with oxygen with a low purge intensity. After the processing of the high-magnesian slag with oxygen is completed, it is thickened with additives of high-magnesian materials and intensive blasting of the slag with nitrogen is started in order to apply a slag skull on the surface of the converter lining.

A specific example of the method

In the converter, the slag remaining after the metal is released, containing basicity 3.6 MgO 10.5%, FeO 23.6%, Fe ₂ O ₃ 8.6%, was treated with oxygen for 1.2 min at a flow rate of 2.2 m ³ / min · t of steel. Then, 2.5 kg / t of steel was added to the slag magnesia material (POF) containing 85% MgO and 6% CaO, with a CaO to MgO ratio of 0.07, and started to be applied on the refractory in accordance with the current TI / 1 / surface slag scull by intensively blowing the slag with nitrogen, prepared in accordance with the claimed method.

The results of the method are shown in the table, which shows that the application of the proposed method for the preparation of slag for applying the skull on the refractory surface of the converter lining provides, in comparison with the known method, an almost 100% coating of the protective skull layer on the surface of the converter lining due to nitrogen slag blowing , an increase in its adhesion to the refractory surface of the lining and an increase in the resistance of the skull to 4 heats due to a reduction to 7–9% of the fraction of low-melting ferritic phase, an increase in I have up to 14% concentration of periclase (MgO) and increase to 16-23% of high-temperature ferritic phases (magnesiouustite and magnesioferrite).

Increasing the wear resistance of the skull cover with its 100% distribution over the refractory surface of the converter lining will ensure its significant increase while maintaining high technological and technical and economic indicators of the converter process.

Information sources

1. Technological instruction TI 102-ST.K-66-2004. Production of vanadium slag and steel in a converter, OJSC NTMK, Nizhny Tagil, 2004.

2. USSR author's certificate, silt C21C 5/28, No. 1839018, decl. 11/01/1989.

3. Babenko A.A., Ogurtsov E.A., Sherba B.C. and others. Improving the temperature and slag regimes of converter smelting with a large proportion of scrap in the metal charge // Steel, 2000. No. 6. S.22-24.

Claims (2)

1. The method of preparing slag for applying a skull on the lining of the converter, including leaving the final slag, thickening it with additives of magnesian materials and blowing the slag with nitrogen, characterized in that the final slag of the previous smelting containing 7-14% MgO for 0.5-2 , 0 min is blown up with oxygen with a flow rate of 1-3 m ³ / min · t of steel, followed by slag thickening with additives of magnesian materials with a ratio of CaO to MgO of not more than 0.3 in the amount of 1.5-6.3 kg / t of steel and applied to converter lining a skull by blowing slag with nitrogen. 2. The method according to claim 1, characterized in that when the MgO content in the final slag is less than 7% at the same time as the slag is blown with oxygen, magnesia material is placed on it with a ratio of CaO to MgO of not more than 0.3 in an amount of 0.6-1.5 kg / t steel.