• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Chernye Metally →  2024 →  №11 →  Назад

80th anniversary of the Nizhny Tagil Institute of Technology — a branch of the Ural Federal University
Название Effect of coke quality on iron smelting from vanadiumcontaining titanomagnetites
DOI 10.17580/chm.2024.11.02
Автор M. V. Polovets, S. I. Minin, A. A. Forshev, K. B. Pykhteeva, S. A. Zagaynov
Информация об авторе

JSC EVRAZ Nizhny Tagil Iron and Steel Works, Nizhny Tagil, Russia1 ; Ural Federal University named after the first President of Russia B. N. Yeltsin, Yekaterinburg, Russia2

M. V. Polovets, Head of Bureau1, Postgraduate Student2, e-mail: Mikhail.Polovets@evraz.com

 

Ural Federal University named after the first President of Russia B. N. Yeltsin, Yekaterinburg, Russia

S. I. Minin, Senior Lecturer, e-mail: s.i.minin@urfu.ru;

S. A. Zagaynov, Dr. Eng., Prof., e-mail: s.a.zagaynov@urfu.ru

 

JSC EVRAZ Nizhny Tagil Iron and Steel Works, Nizhny Tagil, Russia
A. A. Forshev, Deputy Head of Dept., Head of Division, e-mail: Andrey.Forshev@evraz.com

 

Ural Federal University, Nizhny Tagil Institute of Technology (branch), Nizhny Tagil, Russia.
K. B. Pykhteeva, Cand. Eng., Associate Prof., e-mail: k.b.pykhteeva@urfu.ru
Реферат

The smelting of cast iron from vanadium-containing titanomagnetites has some difficulties, compared to the production of steel-making iron, which are associated with the presence of vanadium and titanium in the charge. An effective way to increase the conversion of vanadium to cast iron and prevent the formation of refractory titanium compounds is to increase the intensity of blast furnace smelting. Improving the quality of coke is one of the ways to increase the intensity of smelting. The effect of coke quality on the efficiency of blast furnaces smelting cast iron from vanadium-containing titanomagnetites is considered, namely, the conditions for the reduction of vanadium and titanium and the desulfurization of cast iron.
Ключевые слова Blast furnace, vanadium cast iron, coke quality, titanomagnetites, JSC EVRAZ NTMK, vanadium, titanium
Библиографический список

1. Gavrilyuk G. G., Lekontsev Yu. A., Abramov S. D. Blast furnace smelting of titanomagnetites. Tula : ASSOD, 1997. 216 p.
2. Smirnov L. A., Deryabin Yu. A., Nosov S. K. Converter processing of vanadium cast iron. Yekaterinburg : Sredne-Uralskoe knizhnoe izdatelstvo, 2000. 528 p.
3. Savchuk N. A., Kurunov I. F. Blast furnace production at the turn of the 21st century. Moscow : Chermetinformatsiya, 2000. 42 p.
4. Beppler E., Langber K., Mulheims K. et. al. Coke quality and its influence on the lower part of blast furnace. Fourth European Coke and Ironmaking Congress, Paris, 2000. Vol. 1. pp. 224–231.
5. Zagaynov S. A., Smirnov L. A., Zazhigaev P. A., Mironov K. V. et al. Improvement of the technology of processing vanadium-containing titanomagnetites. Stal. 2020. No. 12. pp. 11–15.
6. Sobyanina O. N. Research of the main ways of improving cast iron smelting from titanomagnetite raw materials: thesis of inauguration of Dissertation … of Candidate of Engineering Sciences. Yekaterinburg, 2013. 24 p.
7. Standard technological instruction for blast furnace production. Dnepropetrovsk : Oblpoligrafizdat, 1983. 100 p.
8. Tarasov V. P., Khayretdinova O. T., Tomash A. A. On the gas permeability of the softening zone under blast furnace smelting conditions. Izvestiya vuzov. Chernaya metallurgiya. 2002. No. 4. pp. 64–66.
9. Tovarovsky I. G., Lyalyuk V. P. Evolution of blast furnace smelting. Dnepropetrovsk : POROGI, 2001. 424 p.
10. Kolesanov F. F. Movement of gases through a layer of lump materials. Moscow : Metallurgizdat, 1956. 88 p.
11. Kuzin A. V., Khlaponin N. S. Evaluation of gas permeability of the cohesive zone in a blast furnace. Stal. 2019. No. 3. pp. 6–12.
12. Minin S. I., Mironov K. V., Koshkarov D. A., Mikhalev V. A. et al. Regard to the influence of coke granulometric composition on its metallurgical value. Koks i khimiya. 2022. No. 9. pp. 10–14.
13. Qing Q. Lv, Yong S. Tian, Ping Du et al. A study on the characteristics of coke in the hearth of a superlarge blast furnace. PLoS ONE. 2021. Vol. 16, Iss. 3. e0247051. DOI: 10.1371/journal.pone.0247051
14. Mitropolsky A. K. Technique of statistical calculations. 2nd edition, revised and enlarged. Moscow : Nauka, 1971. 568 p.
15. Smirnov L. A., Deryabin Yu. A., Shavrin S. V. Metallurgical processing of vanadium-containing titanomagnetites. Chelyabinsk : Metallurgiya, 1990. 256 p.
16. Sobyanina O. N., Filatov S. V., Zagaynov S. A. Analysis of the features of titanium reduction in a blast furnace. Stal. 2012. No. 3. pp. 9–11.
17. Gimmelfarb A. A., Kotov K. I. Processes of reduction and slag formation in blast furnaces. Moscow : Metallurgiya, 1982. 328 p.
18. Blast furnace production: reference publication. In 2 volumes. Volume 1. Ore preparation and blast furnace process. Edited by Vegman E. F. Moscow : Metallurgiya, 1989. 486 p.
19. Stromberg A. G. Semchenko D. P. Physical chemistry: textbook for chemical specialized universities.
Edited by A. G. Stromberg. 3rd edition, revised and enlarged. Moscow : Vysshaya shkola, 1999. 527 p.
20. Mironov K. V., Tleugabulov B. S., Gileva L. Yu., Mikhalev V. A. Analysis of the influence of technological factors on the performance of titanomagnetite smelting. Iron metallurgy. Development prospects until 2025: Proceedings of the IX International Congress of Blast Furnace Workers. Moscow : Izdatelskiy dom “Kodeks“, 2018. pp. 91–97.
21. Bolshakov V. I. Technology of high-efficient energy-saving blast furnace smelting. Kiev : Naukova Dumka, 2007. 411 p.
Language of full-text русский
Полный текст статьи Получить
Назад