RU2157412C1 - Method of production of blast-furnace ferronickel - Google Patents

Abstract

FIELD: metallurgy, particularly, production of pig iron in blast furnaces and nickel matte in shaft furnaces. SUBSTANCE: for production of blast-furnace ferronickel with nickel content of above 8%, method of smelting of magnesian nickel ore includes preparation of ore, production of sinter and its charging into furnace together with coke, supply of heated air blast and discharge of heat products. In so doing, prior to sintering, ore is mixed with hot nickel sinter and fluxed up to basicity CaO/SiO₂=0.4-0.6, and Fe/Ni ratio is maintained within 6-12. In this case, during smelting of sinter in blast furnace, two air tuyeres in region of slag hole are closed. Heat products are discharge through slag and pig iron holes in ratio of (5-9)/1. EFFECT: reduced energy consumption and cost of production of blast-furnace ferronickel. 1 tbl, 1 ex

Description

 The invention relates to the field of ferrous and non-ferrous metallurgy, in particular to the production of pig iron in blast furnaces and the production of nickel matte in shaft furnaces.

A known method of processing oxidized nickel-containing materials [1], including introducing into the charge of agglomeration of fuel and slag of metallurgical production as a flux, mixing the components of the charge, sintering to obtain agglomerate and its subsequent melting. As a flux, slag dump or reverse converter slag of nickel production with a grain size of 30 mm, with a content of Ni = 0.11-2.0%, Co = 0.06-0.35%, and a ratio of FeO / SiO ₂ = 1 is introduced into the sintering mixture , 8-2.4 and the amount providing the ratio of FeO / SiO ₂ in the finished agglomerate of 0.5-0.8.

 The disadvantage of this method is the high iron content in the mixture, in which it is impossible to obtain a domain ferronickel with a nickel content of more than 5%.

 There is also a method of producing ferronickel [2], which includes loading oxidized nickel ore into an electric furnace, supplying a carbon-containing reducing agent, and smelting the ore to produce poor ferronickel with a nickel content of less than 8%. Oxidized nickel ore is also loaded into the second electric furnace, into which the poor ferronickel obtained in the first electric furnace is fed, and the ore is smelted with the formation of enriched ferronickel more than 15%, while the ratio of metallic iron in poor ferronickel and the content of ferric iron in the oxidized ore loaded into the second electric furnace is 1: (1.5-2.5). To obtain poor ferronickel, magnesia or mixed ore is used, and to obtain enriched ferronickel - ferrous.

 The disadvantage of this method is the high energy costs and the cost of production of ferronickel.

The closest in technical essence and the achieved result is a method of smelting ferronickel in a blast furnace [3], which involves the use of unfluxed sinter with a basicity of CaO / SiO ₂ = 0.04-0.1, while the ratio of Fe / Ni is 13.5- 27. The furnace was equipped with 6 air lances with a diameter of 120 mm, and air was supplied through all lances to the furnace. The release of smelting products was carried out through one cast iron and one slag tap hole. The ratio of slag to pig iron was 5.66. The ferronickel obtained by this method contained 4.2-5.5% Ni.

 The disadvantage of this method is the high energy costs and the cost of production of ferronickel, as well as the inability to use magnesia ore to produce rich ferronickel.

 The objective of the invention is to reduce energy costs and production costs when using magnesian nickel ore for the production of blast furnace ferronickel with a nickel content of more than 8%.

The problem is achieved in that in the known method, including the preparation and agglomeration of ore, loading the obtained agglomerate into the furnace together with coke, supplying heated blast through air tuyeres, melting the agglomerate, releasing melting products through slag and cast iron notches, according to the invention, the ore is mixed before agglomeration with hot nickel agglomerate, flux to the main CaO / SiO ₂ = 0.4-0.6 and maintain the ratio Fe / Ni in the range of 6-12, while sintering in the smelting process, close two air lances in the area of the slag notch and in they release melting products through slag and cast iron notches in the ratio of (5-9) / 1.

 Pre-mixing magnesia nickel ore with hot nickel agglomerate increases the strength of the agglomerate and reduces the yield of fines in the finished agglomerate.

The degree of fluxing of the sinter is due to energy costs and the quality of the resulting ferronickel. When the basicity of the CaO / SiO ₂ agglomerate is less than 0.4, the sulfur content in ferronickel exceeds the requirements of steel production for ferroalloys. When the basicity of the CaO / SiO ₂ agglomerate is more than 0.6, the energy costs for the production of ferronickel, in particular coke consumption, increase sharply.

 Maintaining the ratio of Fe / Ni within 6-12 is due to the task of obtaining ferronickel with a nickel content of more than 8% and its cost. When the ratio of Fe / Ni less than 6 increases the cost of blast furnace ferronickel. When the ratio of Fe / Ni more than 12, it is not possible to obtain an alloy with a nickel content of more than 8%.

 The closure of air tuyeres in the area of the slag notch helps to reduce metal losses with slag discharged through the slag notch. With this process management, sludge of smelting products and additional metal deposition in the furnace are organized. Reducing the loss of metal with slag helps to reduce energy costs for the production of ferronickel.

 The release of smelting products through slag and cast iron notch in the ratio of (5-9) / 1 is due to the estimated ratio of metal to slag and a reduction in energy costs. With a ratio of emissions of less than 5/1, energy costs for the production of ferronickel increase (coke consumption). When the ratio of emissions is more than 9/1, the amount of metal exceeds the amount of slag necessary to ensure such a ratio and the evenness of the blast furnace is violated.

A comparative analysis of the proposed technical solution with the prototype showed that the method for producing blast-furnace ferronickel differs from the known one in that the ore is mixed with hot nickel agglomerate before sintering, fluxed to the basic CaO / SiO ₂ = 0.4-0.6, and the ratio Fe / Ni maintain within 6-12, and when sintering in a blast furnace, two air lances are closed in the area of the slag notch, and the melting products are discharged through the slag and cast iron notches in the ratio of (5-9) / 1. Thus, the inventive charge meets the criterion of "novelty."

 The analysis of sources known in the technical and patent literature did not reveal the use of the claimed features in order to reduce energy costs and production costs when using magnesia nickel ore for the production of blast furnace nickel.

 An example of a specific implementation.

Magnesian nickel ore containing (%): Fe _total - 6-14, Ni - 0.8-1.6, Cr ₂ O ₃ - 0.3-0.95, CaO - 1.34-3.92, MgO - 14.7-17.9, SiO ₂ - 41.5-46.3, Al ₂ O ₃ - 2.8-3.7, pre-mixed with hot nickel agglomerate, crushed, mixed with limestone and coke in a predetermined ratio and sintered on an sinter machine with an area of sintering of 50 m ² . Dosing of the charge components ensured the basicity of the agglomerate in the range of 0.33-0.65. The ratio of Fe / Ni in the agglomerate was maintained in the range 5.5-13 by dosing an iron-containing additive into the sinter charge. The sinter was unloaded into wagons and transported to a blast furnace shop. Agglomerate and coke were loaded into a blast furnace with a volume of 205 m ³ , where heated blast was also fed. Two air lances in the area of the slag taphole were closed before the smelting. Liquid smelting products were discharged through slag and cast iron notches, and the release schedule ensured release through slag and cast iron notches in the ratio (4-10) / 1. To compare the test results was carried out in 6 stages with a change in production parameters. After the end of the campaign, calculations of the cost and energy costs for the production of ferronickel were performed for various production parameters. The results are shown in the table.

 Using the invention provides for the production of ferronickel with a nickel content of more than 8%, while energy costs (coke consumption) are reduced by 29.4-34.5% and production costs are reduced by 22.9-28.9%.

Sources of information
1. Patent N2092587, patentee of OJSC Yuzhuralnickel.

 2. Patent N2088687, patent holder "Gintsvetmet".

 3. Zeidler A.A. Metallurgy of copper and nickel. M .: State scientific and technical publishing house of literature on ferrous and non-ferrous metallurgy, M, 1958, p. 250-287.

Claims (1)

A method of producing blast-furnace ferronickel from magnesian nickel ore, including preparation and agglomeration of ore, loading the obtained agglomerate into a furnace together with coke, feeding heated blast through air tuyeres, sintering smelting, discharge of smelting products through slag and cast iron notches, characterized in that before the sintering is mixed with hot nickel agglomerate to oflyusovyvayut basicity CaO / SiO ₂ = 0.4-0.6 and support ratio Fe / Ni in the range 6-12, wherein during the melting of the agglomerate closed two air tuyere in the area of the slag taphole and discharged products through smelting and slag taphole in a ratio of (5-9) / 1.

Images