Название |
Material constitution and features of low-grade and rebellious iron ore in processing and preparation for ROMELT direct iron ore smelting reduction process |
Информация об авторе |
National Mineral Resources University—University of Mines, Saint-Petersburg, Russia:
T. I. Yushina, Acting Deputy Head of Mineral Processing Department, Assistant Professor, Candidate of Engineering Sciences, yuti62@mail.ru I. O. Krylov, Assistant Professor, Candidate of Engineering Sciences V. S. Valavin, Director of Romelt Science and Education Center, Doctor of Engineering Sciences V. N. Dunaeva, Assistant Professor |
Реферат |
Iron ores, which require beneficiation, currently supply 89% commercial production in Russia. The iron content of all commercial-type ores is 16–72%. Given the actual-to-date practice of ore quality assessment, such ores can be classified as low-grade (25% Fe) and rebellious ore requiring complex methods of dressing to produce a marketable concentrate. In connection with this, it is assumed unfavorable to mine such ore deposits located in the areas lacking developed industrial infrastructure as, for instance, some magnetite ore bodies within the Kursk Magnetic Anomaly and others. The article presents data on basic minerals, average content of iron and rock components of lowgrade, rebellious and natural alloyed iron ore deposits in the Eastern Siberia and Kerch Iron Ore Basin: Nizhne-Angarskoe, Ishimbinskoe, Udorongovskoe, Oktyabrskoe and other deposits. The development of the above mentioned iron ore deposits is problematic because they are either rebellious at iron content of more than 40%, or are inaccessible and far from major transportational routes while being high-grade, or fail to produce standard quality concentrate since huge reserves of such ore feature low content of iron, etc. In this connection, conventional circuit of mining, on-site dressing and delivery to an integrated iron-and-steel works makes mining unprofitable. A way out could be ROMELT technology. Metallurgical treatment in this case needs no complex pretreatment of ore having iron content of 45–50% and below. ROMELT technology eliminates agglomeration stage. Natural alloyed ore is usable. Fuel is natural coal instead of costly coke. Capital investment in construction is much lower in this case as compared with the known analogs in the metallurgy industry. Construction is also feasible in permafrost zone as furnaces and service equipment are installed on pile structures and need no heavy foundations. The advantage of cast iron manufactured by ROMELT process is the low content of Si and Mn, which facilitates its conversion to steel. The study was carried out under financial support from the RF Ministry of Education and Science within the framework of the federal targeted program on R&D in Priority Areas of Advancement of the Russian Science and Technology for 2014–2020. Unique Project Identifier RFMEFI57814X0049). The authors are grateful to S. G. Pak, Assistant to the Mineral Dressing Department at NUST MIS&S, for the participation in the research. |
Библиографический список |
1. Orlov V. P., Verigin M. I., Golivkin N. I. Zhelezorudnaya baza Rossii (Russian iron ore base). Moscow : JSC «Geoinformmark», 1998. 842 p. 2. Petrov I. M., Yushina T. I., Avdeev G. I., Valavin V. S. Analiz sovremennogo sostoyaniya dobychi i pererabotki zheleznykh rud i zhelezorudnogo syrya v Rossiyskoy Federatsii (Analysis of state-of-the-art in iron ore mining and processing in Russian Federation). Gornyi Zhurnal = Mining Journal. 2015. No. 1. pp. 41–48. 3. Sukhodolov A. P. Predposylki i perspektivy formirovaniya kompleksa chernoy metallurgii v Vostochnoy Sibiri i Irkutskoy oblasti (Preconditions and prospects of formation of ferrous metallurgy complex in the Eastern Siberia and Irkutsk Oblast). Izvestiya Irkutskoy gosudarstvennoy ekonomicheskoy akademii = Proceedings of Irkutsk State Economic Academy. 2015. No. 1, Vol. 25. pp. 5–12. 4. Kuznetsov V. A. Zhelezorudnye mestorozhdeniya Sibiri (Siberian iron ore deposits). Novosibirsk : Nauka, 1981. 225 p. 5. Orlova V. P. Zhelezorudnaya baza Rossii (Russian iron ore base). Moscow : LLC «Geoinformmark», 2007. 871 p. 6. Levchenko E. N., Bykhovskiy L. Z., Tigunov L. P. Strontsiy Rossii: nerealizovannye vozmozhnosti (Russian strontium: unrealized possibilities). Mineralnye resursy Rossii. Ekonomika i upravlenie = Mineral Resources of Russia. Economics and Management. 2007. No. 6. pp. 13–19. 7. Kryatov B. M. Zhelezorudnaya otrasl Rossii. Problemy syrevoy bazy (Iron ore branch of Russia. Problems of raw material base). Mineralnye resursy Rossii. Ekonomika i upravlenie = Mineral Resources of Russia. Economics and Management. 2006. No. 1. p. 8. 8. Melnikov A. V., Stepanova V. A., Moiseenko V. G. Metallogenicheskie zony tsentralnoy chasti Priamurskoy zolotonosnoy provintsii (Metallogenic zones of the central part of Priamurye gold-bearing province). Doklady Rossiyskoy Akademii Nauk = Reports of Russian Academy of Sciences. 2014. No. 2, Vol. 458. 9. Liu J., Han Y., Li Y., Zhang S. Study on mechanism and technology of deep reduction for lingyang iron ore. 26th International Mineral Processing Congress, IMPC 2012: Innovative Processing for Sustainable Growth, New Delhi, India. 24–28.09.2012. pp. 2335–2343. 10. Singh R., Rath R., Nayak B., Bhattacharyya K. Development of process for beneficiation of low-grade iron ore samples from orissa, India. XXV International Mineral Processing Congress. IMPC. 2010. pp. 1235–1241. 11. Xiong S.-A., Chun T.-J., Zhu D.-Q., Pan J. A study on beneficiation of low grade highphosphorus iron ore. TMS Annual Meeting TMS. 139th Annual Meeting and Exhibition. Supplemental Proceedings Seattle, WA. 2010. pp. 429–436. 12. Zyma S. M. Composition and structure of limonite ores from Lyubiya deposit (Bosnia and Herzegovina) and their transformation in course of magnetising roasting and metallization. Geologo-mіneralogіchniy vіsnik = Geological and Mineralogical Bulletin. 2011. No. 1 (25). 13. Romenets V. A., Valavin V. S., Pokhvisnev Yu. V., Makeev S. A., Gimmelfarb A. I. Use of the innovative Romelt technology to process iron-bearing wastes from mines and metallurgical plants. Metallurg. 2010. Vol. 54, No. 5. pp. 273–277. 14. Valavin V., Makeev S., Pokhvisnev Yu. V., Zaytsev A., Popov A. Recycling of iron-containing waste of metallurgical works in the countries of black sea economic cooperation (bsec). Metallurgist. 2014. Vol. 58, No. 1. pp. 20–27. |