RU1786109C - Process for producing titanium steel - Google Patents

Abstract

Usage: in the production of titanium-containing steels. SUMMARY OF THE INVENTION: In the production of titanium-containing steel, synthetic slag is fed into the ladle, melt is discharged, deoxidizers and titanium-containing ferroalloys are introduced, the melt is blown with powdered silicocalcium and further vacuumized in the ladle. The titanium-containing ferroalloys are introduced in two portions, and the purge with silicocalcium powder is carried out in an amount ensuring the reduction of previously oxidized titanium from slag.

Description

The invention relates to ferrous metallurgy, in particular to the production of titanium alloy steels with a low nitrogen content, and can be used in steelmaking workshops.

A known method of out-of-furnace steel processing in the preparation of billets by continuous casting, including preliminary deoxidation with aluminum (0.4-0.5 kg / t), titanium modification (0.2-0.3 kg / t), microalloying with boron (0.65-0.75 kg / t) and the final microalloying with a titanium-cutting flux-cored wire with a flow rate of 0.4-0.6 kg / t in the continuous casting mold.

The disadvantages of this method are the large non-uniformity of the titanium content in the steel and the high fumes of titanium when introduced into the ladle.

A known method of steelmaking, including the reduction of oxides of iron, manganese, chromium, vanadium, tungsten from slag with a basicity of 0.71-0.24 additives

ferrosilicon, silicocalcium, which are introduced at the top in an amount of 2-12 kg / t of steel.

The disadvantages of this method are the high consumption of reducing agent, the low degree of reduction of metals from oxides, and the instability of the results obtained.

A method is known for introducing special elements during the degassing step, comprising introducing elements such as niobium, ianadium, titanium, boron in the form of oxides under vacuum conditions.

The disadvantages of this method are the long duration of the process, high consumption of oxide materials, strong overheating of the metal, reverse transition of elements to slag in the form of nitrides, which does not allow to stably obtain narrow limits on the content of titanium and nitrogen.

The closest in technical essence and the achieved effect is a method of deoxidation and steel modification, including feeding synthetel into the ladle

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slag, the release of the melt, the introduction of deoxidizers and titanium-containing ferroalloys, purging with silicocalcium,

The disadvantages of this method are the high fumes of titanium, its unstable content in the finished steel, and a high nitrogen content.

The purpose of the invention is to increase yield by stabilizing the contents of titanium and nitrogen in steel.

This goal is achieved by the fact that in the production of titanium-containing steel, including the supply of synthetic slag to the ladle, the release of the melt, the introduction of deoxidizers and titanium-containing ferroalloys, the purging with powdered silicokelcium according to the invention, the melt in the ladle is additionally vacuumed, and the titanium-containing ferroalloys are introduced in two portions the first of which is introduced in the amount of 65-85% of the total before purging with silicocalcium, and the second during the evacuation of the melt or after it, while silicocalcium is blown with a flow of 3-5 g / t to 1% okislivshihs titanium oxides in the slag and the melt is evacuated after the completion of blowing powdery silicocalcium.

SUMMARY OF THE INVENTION The invention is based on the dispersed addition of titanium, recovery of titanium; oxides by reduction with strong deoxidants and by evacuation of the melt to prepare the metal before introducing the final portion of titanium-containing ferroalloys.

It is known that titanium has a high affinity for oxygen and nitrogen. However, in this case, titanium must be fully protected from oxidation so that it remains in the metal. Aluminum can take up protective functions, and then purge with reactive powdery reactants. For example, treatment with calcium and barium will allow titanium to be reduced from oxides in the slag. It must also be borne in mind that titanium is a strong nitride forming element, i.e. at certain concentrations of titanium and nitrogen, titanium nitrides may be formed and removed during out-of-furnace treatment.

To prevent this, it is necessary to limit the concentration in the metal of both titanium and nitrogen, which will reduce the likelihood of the formation of nitrides and their removal to the slag phase. Therefore, the limitation of initially introduced titanium into the metal, and then evacuation, virtually eliminates the possibility of the formation of nitrides

and titanium oxides. This allows for narrow limits on the titanium content in the finished steel. Thus, it can be stated that the regulation of processes

oxidation and reduction of titanium, as well as evacuation of the metal, will provide the required titanium and nitrogen content in the finished steel.

The studies carried out were

 it was found that it is most advisable to limit the first sitting portion of titanium to 65-85% of its total amount for melting ..

Titanium consumption less than 65% of its total

the flow rate is impractical, since this leads to the need for a large titanium additive during or after evacuation, a high uneven distribution of titanium in the metal volume; additive

more than 85% leads to a large waste of titanium into the slag and the impossibility of its full recovery from the slag due to subsurface treatment with powdered reagents.

The costs of the powdered reagent for the reduction of titanium from oxides are due to the following circumstances.

The consumption of powdered reagents less than 3 kg for each percentage of titanium oxides in 1 ton of slag does not provide complete

reduction of previously oxidized titanium,

consumption of more than 5 kg is impractical due to

with a drop in efficiency

introduced reagent, the destruction of the lining of the bucket, the deterioration of technical and economic, indicators of steel production, metal saturation with nitrogen.

Thus, in comparison with the known technical solutions claimed

characterized by the portioned introduction of titanium into the metal, the reduction of oxidized titanium from the slag, and the evacuation of the metal.

In the analysis of scientific and technical literature and patent information was not

Known technical solutions have been found that have similar characteristics with distinctive essential features in the proposed combination, which, according to the proposal, provide improved yield and steel quality by stabilizing the titanium and nitrogen contents.

Examples of the method. The method is carried out in an oxygen-converter shop for smelting steel in 160 tons

converters.

After purging in the converter, the metal had the following chemical composition, wt.%: C 0.05; MP 0.11; S 0.014; P 0.008, Temperature 1670 ° C.

The metal was produced in a ladle filled with synthetic slag in an amount of 35 kg / t of steel.

. The chemical composition of slag 4 was as follows, wt.%: CaO 54: 5X2 3.5; A120z 42; FeO 0.5. The temperature of the slag 1700 ° C.

The first portion of Ti 1 grade titanium in an amount of 291 kg / pl was introduced in an amount of 291 kg / pl together with other deoxidizing agents and alloying agents. This amounted to 75% of the total consumption of ferrotitanium for smelting, equal to 388 kg / pl, calculated from the condition of obtaining 0.08% titanium in finished steel.

After entering 291 kg / pl, the titanium content in the metal was 0.03%. Then, the ladle with metal was supplied to the melting finishing unit in the ladle, where metal was first purged with SK-30 silicocalcium grade (FSB 27 grade silicobarium). and then the tuyeres were lifted and SK-30 (FSB-27) subsurface injection was performed to restore the previously oxidized from the first portion of titanium.

The content of titanium oxides in the synthetic slag after the introduction of the first portion of titanium before blowing with silicocalcium powder was 4.5%, after the addition of silicocalcium 0.645%, i.e. the degree of recovery was 90%. The titanium content after purging with silicocalcium (silicobarium) was 0.054%. After that, the metal was sent to the RH evacuation unit, where it was evacuated and 140 kg / pl of ferrotitanium was introduced under the condition of 90% titanium assimilation.

The titanium content in the steel after introducing two portions of ferrotitanium was 0.054 + +0.026 0.08%.

The chemical composition of the obtained steel after all corrective operations was

next, wt.%: C 0.1; Si 0.33; Mp 1.65; S 6.005: P 0.014; AI 0.04; Cr 0.02; NI 0.03; C, 0.15; TI 0.08; Nb 0.03; N, 0.0065.

The relative elongation of the mountains of the pressed sheet in the thickness of 15.7 was 23.6; yield 86.2%.

The analysis of experimental swimming trunks showed that the study of the proposed method of steel production, subject to

the claimed parameters allows to increase the yield by stabilizing the contents of titanium and nitrogen.

To calculate the expected economic effect of the implementation of the proposed

The method for the basic object was adopted by steelmaking 09G2FB steelmaking process in the converter shop - No. 1 of the Novolipetsk Steel.

Claims (1)

The economic efficiency from the implementation of the proposed method for the production of steel will be 0.85 rubles / ton of steel. SUMMARY OF THE INVENTION A method for producing titanium-containing steel, comprising feeding synthetic slag into a ladle, releasing a melt, introducing deoxidizers and titanium-containing ferroalloys, and blowing with powdered silicocalcium. characterized in that, in order to increase the yield by to stabilize the contents of titanium and nitrogen, the melt in the ladle is additionally evacuated, and titanium-containing ferroalloys are introduced in two portions, the first of which is introduced in the amount of 65-85% of the total by blowing the melt with silicocalcium, and the second during or after evacuation, while silicocalcium is blown with a flow rate of 3-5 kg / t of slag into 1% of titanium oxides oxidized to the slag, and the melt is evacuated after the end of purging with powdered silicocalcium.