SU876729A1 - Method of steel production - Google Patents

Description

. The invention relates to metallurgy of ferrous metals and can be used in the production of steel in electric steel-smelting furnaces and other steel-making units (open-hearth furnaces and converters}.) oxidative processes do not download oxidizing slag and under this slag. a short period of refining is carried out in the furnace (lasting about 20 minutes), after which The release of smelting, in which the metal is first poured, and only at the end of the release, the LO is lowered with the metal. When this method is carried out in the finished metal, an increased sulfur content is usually observed, which is undesirable in the production of high-quality steels and makes difficult (and in certain production conditions, impossible) to get into the analysis of sulfur in the smelting of high-quality steels with a permissible sulfur content of up to 0.025%. To obtain a low sulfur content in the finished metal, this steel production method is combined with various methods of after-treatment of the metal with synthetic pins or powders. However, the use of these methods with their undoubted merits in terms of obtaining low sulfur content in the metal core is associated with the need to install special equipment and additional costs of up to 5-8 rubles / ton. Other secondary processes for treating steel for the purpose of desulfurization (solid powder mixtures, etc.) are associated with similar disadvantages. 3 The closest to the present invention is a method of steel production in which steel is smelted under one or more oxidative llaks. the period is not downloaded and dusted with powdery deoxidizing agents in the furnace (comminution, calcium carbide, ferrosilicon, etc.). Melting is performed with metal treatment by this slag, for which The production of steel with deoxidation of oxidizing slag in ne allows you to smelt high-quality steel with a permissible limit on sulfur content (up to 0.025%) in small and medium capacity furnaces 2. Significant The disadvantage of this method is an increase in the duration of smelting due to the additional time spent on slag deoxidation in a furnace, such as, for example, in a 40-ton furnace, the duration of smelting is increased by approximately 20 minutes compared to melting Without scorching in the furnace, which leads to a decrease in the productivity of the furnace by 5-10%. In addition, obtaining by the time of release of slag with a low content of ferrous oxide in large modern furnaces is very difficult. The purpose of the invention is to improve those economic indicators. This goal is achieved by the fact that in the method of steel production, including steel production in a steelmaking unit under one or several oxidizing slags, the production and processing of metal in a ladle with furnace slag, the final oxidative slag is released into the ladle before the metal is drained, it is treated with deoxidizing agents This slag is poured metal. After the completion of the oxidation melting period, the oxidizing slag is not downloaded and is not deacidified during the finishing operation. After finishing, oxidizing slag is poured from the furnace into the ladle, which is simultaneously deoxidized with powdered and / or lumpy deoxidizing agents (ferrosilicon, alnine, coke, etc.). Slag deacidification is carried out on the jet and Sealy 9 in the ladle. The deoxidized slag is produced by a metal jet with a powerful jet, which ensures the effective refining of the metal in a highly basic low iron slag. The required basicity of the slag in the ladle is achieved due to the corresponding adjustment of the composition of the oxidizing material in the furnace, in connection with which it is not necessary to add an additive to the ladle in the ladle. A small amount of deoxidizing agents is required to deoxidize the oxidizing slag in the ladle. For example, to reduce the content of ferrous oxide in the shpak by 10% with the amount of slag 5% by weight of the metal, 0.125% by weight of the aluminum metal is required (2 to 27 X 5 X 10/3 X 72 X 100 or 0.13% by weight metal 75% ferrosilicon (28x5x10 / 2x72x75). Considering a small amount of deoxidizing agents and thermal effect; reactions: deoxidation, expect the negative effect of this process on the temperature mode, there is no additional overheating of the smelting before release. Ex. 40 tons, electric furnace for the Kuznetsk Metallurgical Combine on offer Four melts of medium carbon structural steel were carried out to this method (variant A). After the end of the oxidation period, finishing was carried out. To do this, at the end of oxidation, a metal sample was taken for chemical analysis and, without oxidizing, about 3.5 kg of silicomanganese were deposited per ton of metal According to the results of the sample taken at the end of the oxidation, the composition of the metal was adjusted according to the content of carbon and manganese. When the temperature of the metal reached 1590 -1620 C, the production of smelting was started, and aluminum in the amount of 1 kg / ton was introduced into the metal at the two heats before the release. Before the slag was discharged, deoxidizing agents were placed in the amount necessary for both deoxidizing the slag and for further refining the metal to a predetermined silicon content and increasing it with aluminum. For this, 2.0-2.5 kg / ton of aluminum shot and 4.0-4.5 kg / ton of lumpy 75% ferrosilicon were introduced into the ladle.

The release of smelting began with the discharge of oxidizing slag containing (according to the results of the subsequent analysis) from 9.1 to 13.3% of ferrous oxide. For 2-3 minutes, the bulk of the shyak was lowered into the ladle, after which the slag was released to the slag that reacted with deoxidizing agents.

To obtain comparative data, parallel melting was carried out with slag dissolving in the furnace during the refining (option B). Data are summarized 8 table.

With the average content of sulfur in the metal prior to production (.0.022%), treating the metal on the claus with oxidizing furnace slag, deoxidized in the ladle, gives the same result on the sulfur content in the metal and the coefficient (1 in the sulfur distribution in the ladle, as in the control to the melting group with oxidizing slag deoxidation in the furnace during the finishing, while the finishing time in the furnace decreased by 11 minutes with a corresponding increase in the productivity of the furnace.

Thus, the main technical and economic effect when using the proposed method in electric furnace production is to increase the productivity of furnaces by 5-10%.

The preferred method can also be used in steel smelting in other steel-making units where it is generally impossible to deactivate the pork in the furnace (in oxygen-converter workshops, for example. In this case, without affecting the duration of the melting, it allows minimum costs reduced sulfur content in the metal. The effectiveness of the proposed method here is determined for specific conditions either by improving the quality of steel by reducing its sulfur content or by the difference in costs for desulfurization by the proposed method and other methods of secondary desulphurization.

Claims (1)

Claim A method for the production of steel, including steelmaking in a steelmaking unit under one or more oxidizing slags, production and processing of metal in a ladle by furnace slag, characterized in that, in order to improve technical and economic indicators, the final oxidizing slag is released into the ladle before the metal is drained , process it with deoxidants, after VNIIIPI Order 9517/33 PPP ’’ branch Patent, Uzhhorod, st. Project, 4