Anais dos Seminários de Redução, Minério de Ferro e Aglomeração


ISSN 2594-357X

Título

TECHNOLOGICAL SOLUTIONS FOR INTENSIVE PRODUCTION OF LOW SILICON HOT METAL IN BLAST FURNACE PROCESSING VANADIUM CONTAINING TITANIA-MAGNETITE

TECHNOLOGICAL SOLUTIONS FOR INTENSIVE PRODUCTION OF LOW SILICON HOT METAL IN BLAST FURNACE PROCESSING VANADIUM CONTAINING TITANIA-MAGNETITE

DOI

10.5151/2594-357X-22242

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Resumo

Production of low silicon hot metal is an essential part of successful treatment of vanadium containing titania-magnetite ore in blast furnace. The formation of titanium carbides and titanium nitrides very much depends on solubility of titanium in hot metal. The analysis showed that with reduction in silicon content the content of titanium in hot metal is also reduced. Similarity in silicon and titanium reduction allows usage of the same factors to control content of these elements in hot metal. Increase in furnace pressure reduces silicon and titanium content in hot metal and first of all titanium-carbide formation. At actual blast furnace conditions the content of titanium carbides is far from equilibrium and materials residence time is an important control parameter. Increase in coke strength after reaction (CSR) improves permeability of coke packing and accelerates filtration of the melt, suppressing titanium-carbides formation. Increase in hearth’s height to width ratio with the same hearth’s volume also positively affects operation of blast furnace. Uniform descent of pellets and sinter, and uniform distribution of limestone in furnace cross-section stabilize the heat transfer conditions further suppressing formation of titaniumcarbides. The practical measures to retard titanium-carbides formation and to produce high quality low silicon and low titanium hot metal are proposed and implemented at Nizgniy Tagil I & S Works in Russia (NTMK) with increase in blast furnace specific productivity up to 3.5 thm/m3/day.

 

Production of low silicon hot metal is an essential part of successful treatment of vanadium containing titania-magnetite ore in blast furnace. The formation of titanium carbides and titanium nitrides very much depends on solubility of titanium in hot metal. The analysis showed that with reduction in silicon content the content of titanium in hot metal is also reduced. Similarity in silicon and titanium reduction allows usage of the same factors to control content of these elements in hot metal. Increase in furnace pressure reduces silicon and titanium content in hot metal and first of all titanium-carbide formation. At actual blast furnace conditions the content of titanium carbides is far from equilibrium and materials residence time is an important control parameter. Increase in coke strength after reaction (CSR) improves permeability of coke packing and accelerates filtration of the melt, suppressing titanium-carbides formation. Increase in hearth’s height to width ratio with the same hearth’s volume also positively affects operation of blast furnace. Uniform descent of pellets and sinter, and uniform distribution of limestone in furnace cross-section stabilize the heat transfer conditions further suppressing formation of titaniumcarbides. The practical measures to retard titanium-carbides formation and to produce high quality low silicon and low titanium hot metal are proposed and implemented at Nizgniy Tagil I & S Works in Russia (NTMK) with increase in blast furnace specific productivity up to 3.5 thm/m3/day.

Palavras-chave

Blast furnace; Titania-magnetite; Vanadium; Low silicon; Hot metal; Titanium-carbides.

Blast furnace; Titania-magnetite; Vanadium; Low silicon; Hot metal; Titanium-carbides.

Como citar

Zagainov, Sergei A.; Filatov, Sergei V.; Sobianina, Olga N.; Gordon, Yakov M.. TECHNOLOGICAL SOLUTIONS FOR INTENSIVE PRODUCTION OF LOW SILICON HOT METAL IN BLAST FURNACE PROCESSING VANADIUM CONTAINING TITANIA-MAGNETITE , p. 1406-1415. In: 42º Seminário de Redução de Minério de Ferro e Matérias-primas / 13º Seminário Brasileiro de Minério de Ferro / 6th International Congress on the Science and Technology of Ironmaking, Rio de Jabeiro, 2012.
ISSN: 2594-357X , DOI 10.5151/2594-357X-22242