• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Chernye Metally →  2018 →  №1 →  Назад

Ironmaking
Название Analysis of vanadium behaviour in the conditions of high intensity of blast furnace melting
Автор K. V. Mironov, V. A. Mikhalev, K. B. Pykhteeva, B. S. Tleugabulov
Информация об авторе

EVRAZ Nizhniy Tagil Metallurgical Works (Nizhniy Tagil, Russia):

K. V. Mironov, Head of the blast furnace shop
V. A. Mikhalev, Head of blast furnace bureau, Technical administration

 

Nizhniy Tagil Technological Institute — affiliate of the Ural Federal University (Nizhniy Tagil, Russia):
K. B. Pykhteeva, Dr. Eng., Associate Professor, e-mail: pyhkb@mail.ru
B. S. Tleugabulov, Dr. Eng., Associate Professor, e-mail: bstz10@mail.ru
Реферат

Vanadium-to-hot metal recovery factor is one of the efficiency indicators of the blast furnace melting of titanium magnetite materials. This paper shows a generalizing analysis of the vanadium behavior in the course of the blast furnace process. Vanadium is found in several oxidation states between +3 and +5 in the initial agglomerated raw material. In the solid-phase reduction process at moderate temperatures, some of the higher vanadium oxides are carried away with the gas, and some are deposited on the top levels, creating a top circulation loop. Gas flow parameters affect the portion of vanadium losses attributed to the crude BF top gas (inclusive of those carried away with dusts and sludges). Vanadium melting process improvements resulted into the change of these parameters: the pressure increased, the specific gas yield and its temperature decreased. This ensured decreasing vanadium losses carried away with the gas. Vanadium is reduced in the straight way only from the lower oxides. In this case most vanadium is reduced into metallic state from primary and intermediate slags. This paper studies the influence of various factors on vanadium distribution between cast iron and slag and shows the challenges of blast furnace melting of titanium magnetites. Partial sublimation of vanadium in high-temperature zones to form the secondary circulation zone is an additional feature of vanadium behavior in the blast furnace melting process. Varying of blast furnace performance rates affects vanadium behavior in the course of melting. The higher is the melting performance rate, the higher is vanadium-to-hot metal recovery rate is generally as well. Reduction of vanadium losses carried away with the crude top gas is one of the reasons why vanadium recovery factor increases.
Ключевые слова Blast furnace, melting, performance, cast iron, vanadium, recovery, top gas, titanium
Библиографический список

1. Mitchell P. S. Supply and use of vanadium. Paper presented at 56th VDEh Raw Materials Committee — Dusseldorf, Germany. 1996. p. 15.
2. Smirnov L. A., Kushnarev A. V. Modern state and prospects of processing of titanium-magnetite vanadium-bearing raw materials in Russia. Chernaya metallurgiya. 2013. No. 5. pp. 3–20.
3. Kushnarev A. V. 75th anniversary of Nizhniy Tagil metallurgical combine. Chernye Metally. 2015. No. 7. pp. 12–15.
4. Gavrilyuk G. G., Lekontsev Yu. A., Abramov S. D. Blast furnace melting of titanium magnetites. Tula : ASSOD. 1997. 216 p.
5. Vlokh Yu. V. Development prospects for Kachkanar Mining and Processing Integrated Works. Gornyi Zhurnal. 2016. No 7. pp. 46–50.
6. Smirnov L. A., Deryabin Yu. A., Shavrin S. V. Metallurgical processing of vanadium-bearing titanium magnetites. Chelyabinsk : Metallurgiya, 1990. 256 p.
7. Kushnarev A. V., Filippov V. V., Mikhalev V. A., Tleugabulov B. S. System improvement of vanadium hot metal process at EVRAZ NTMK. CIS Iron and Steel Review. 2017. Vol. 13. pp. 13–17.
8. Filatov S. V., Kirichkov A. A., Mikhalev V. A. et al. Smelting low-silica hot metal at OAO NTMK. Steel in Translation. 2010. Vol. 40, No. 5. pp. 443–445.
9. Zagainov S. A., Filatov S. V., Sobianina O. N., Gordon, Y. M. Technological solutions for intensive production of low silicon hot metal in blast furnace processing vanadium containing titania-magnetite. 6th International Congress on the Science and Technology of Ironmaking 2012, ICSTI 2012 — Including Proceedings from the 42nd Ironmaking and Raw Materials Seminar, and the 13th Brazilian Symposium on Iron Ore. pp. 1406–1415.
10. Gerasimov Ya. M., Krestovikov A. I., Gorbov S. M. Chemical thermodynamics in non-ferrous metallurgy. Vol. 5. Moscow: Metallurgiya. 1973. 196 p.
11. Lyakishev N. P., Slotvinskiy-Sidak N. P., Pliner Yu. L. et al. Vanadium in ferrous metallurgy. Moscow: Metallurgiya, 1983. 192 p.
12. Reznichenko I. A., Shabalin L. I. Titanium magnetites. Deposits, metallurgy, chemical technology. Moscow: Nauka, 1986. 295 p.
13. Avdonina M. P., Komornikov G. I., Klimova N. S. Effect of chemical and mineral composition of Kachkanar concentrate on the composition and properties of agglomerates. Trudy instituta Uralmekhanobr. 1970. Iss. 17. pp. 236–245.
14. Pykhteeva K. B., Tleugabulov B. S. Investigation of nature of vanadium evaporation from blast furnace during the melting of titanium magnetites. Izvestiya vuzov. Chernaya metallurgiya. 2014. No. 6. pp. 16–19.
15. Wang Li, Yimin Zhang, Tao Liu, Jing Huang, Yi Wang. Comparison of ion exchange and solvent extraction in recovering vanadium from sulphuric acid leach solutions of stone coal. Hydrometallurgy. 2013. Vol. 131–132. pp. 1–7.
16. Sobyanina O. N., Zagainov S. A., Filatov S. V. Analysis of titanium Reduction in a Blast Furnace. Steel in Translation. 2012. Vol. 42, No. 3. pp. 246–248.
Language of full-text русский
Полный текст статьи Получить
Назад