ArticleName |
Improving the technology for obtaining
magnetite concentrate in the processing of magnetiteapatite
ores |
ArticleAuthorData |
Mining Institute of Kola Science Centre of RAS (Apatity, Russia)
Opalev A. S., Vice Director for Sciences, Candidate of Engineering Sciences, a.opalev@ksc.ru Alekseeva S. A., Senior Researcher Palivoda A. A., Engineer of the Ist Category Kalyuzhnaya R. V., Junior Researcher |
Abstract |
The article presents research aimed at improving ore preparation for magnetite-apatite ores from a deposit in the North-West of Russia. The goal is to reduce the formation of fines for the main minerals and improve the iron ore concentrate grade. Specific processing features of the mineral raw materials were considered to substantiate the key principles for optimizing the existing processing circuit. These features include the mineral and chemical composition, grain size distribution for the main minerals in the initial ore and its grinding products, distribution of free and intergrown minerals across the products, the degree of liberation of the main minerals, and more. The best ore preparation parameters were selected by means of a magnetic-gravity separation performance analysis using the Hancock–Luyken criterion. The research findings indicate that the concentrate grade can be improved from 64.5±0.5 to 65.9 % Fetot with a magnetic iron recovery of approximately 98% by introducing preliminary screening of the ore mass upstream of the rod mill and 1 mm check screening of the rod mill overflow at the first processing stage, replacing ineffective hydrocyclone classification with screening at the second stage, and performing final processing using 0.16 mm fine screening, regrinding, and magnetic-gravity separation. When properly implemented, this technology will enhance processing performance by removing undersized product, reducing the grinding load in the second processing stage, and decreasing circulating loads in the circuit. These improvements will minimize the formation of fines of valuable components and enhance their separation efficiency. Furthermore, this approach will significantly reduce the amount of equipment needed in the final processing operations. |
References |
1. Rosa A. C., de Oliveira P. S., Donda J. D. Comparing ball and vertical mills performance: An industrial case study. Proc. of the XXVII International mineral processing congress. 2014. Chap. 8. Comminution processes. pp. 44–52. 2. Moraes M. N., Galery R., Mazzinghy D. B. A review of process models for wet fine classification with high frequency screens. Powder Technology. 2021. Vol. 394. pp. 525–532. 3. Jankovic A., Valery W., Sönmez B., Oliveira R. Effect of circulating load and classification efficiency on HPGR and ball mill capacity. Proc. of the XXVII International mineral processing congress. 2014. Chap. 9. Energy efficiency in comminution. pp. 2–14. 4. Vaisberg L. A., Korovnikov A. N. Fine screening as an alternative to hydraulic classification by size. Obogashchenie Rud. 2004. No. 3. pp. 23–34. 5. Ismagilov R. I., Kozub A. V., Gridasov I. N., Shelepov E. V. Case study: Advanced solutions applied by JSC Andrei Varichev Mikhailovsky GOK to improve ferruginous quartzite concentration performance. Gornaya Promyshlennost'. 2020. No. 4. pp. 98–103. 6. Jankovic A. Comminution and classification technologies of iron ore. Iron ore: Mineralogy, processing and environmental sustainability. 2 ed. Chap. 8. Woodhead Publishing, 2021. pp. 269–308. 7. Baranov V. F., Patkovskaya N. А., Tasina Т. I. Current trends in magnetite iron ores processing technology. Basic trends. Obogashchenie Rud. 2013. No. 3. pp. 10–17. 8. Oleinik T. A., Mulyavko V. I., Lyashenko V. I., Oleinik M. O. Development of technologies and technical means for beneficiation of hematite ores. Chernaya Metallurgiya. Byulleten' Nauchno–tekhnicheskoy i Ekonomicheskoy Informatsii. 2016. No. 5. pp. 5–10. 9. Korovnikov A. N., Buzunova T. A. Ore slurry classification on a vibrating screen. Obogashchenie Rud. 2018. No. 5. pp. 17–21. 10. Leonov V. The practice of Derrick technologies in the mining industry. Mayning Report Glyukauf na Russkom Yazyke. 2014. No. 3. pp. 66–70. 11. Pelevin A. E., Sytykh N. A. Fine hydraulic screening for staged separation of titanium-magnetite concentrate. Obogashchenie Rud. 2021. No. 1. pp. 8–14. 12. Albuquerque L. G., Wheeler J. E., Valine S. B. Application of high frequency screens in closing grinding circuits. Revista Escola de Minas. 2009. Vol. 62, No. 1. pp. 167–173. 13. Pelevin A. E., Sytykh N. A. Efficiency of screens and hydrocyclones in closed-cycle grinding of titanomagnetite ore. Gornyi Informatsionno–analiticheskiy Byulleten'. 2022. No. 5. pp. 154–166. 14. Kosoy G. M., Vinnikov A. Ya. Fine hydraulic screening of ground ores on a multi-frequency screen by Kroosh Technologies: in-process testing. Tsvetnye Metally. 2021. No. 6. pp. 10–15. 15. Rocha G. M., de Assis Silva J., da Silva Ramos K., Lima R. Selective flotation of quartz from hematite by amide–amine: Fundamental studies. Mining Metallurgy & Exploration. 2021. Vol. 38. pp. 2195–2207. 16. Safari M., Hoseinian F. S., Deglon D., Leal Filho L. S., Souza Pinto T. C. Investigation of the reverse flotation of iron ore in three different flotation cells: Mechanical, oscillating grid and pneumatic. Minerals Engineering. 2020. Vol. 150. DOI: 10.1016/j.mineng.2020.106283 17. Pelevin A. E. Iron ore beneficiation technologies in Russia and ways to improve their efficiency. Zapiski Gornogo Instituta. 2022. Vol. 256. pp. 579–592. 18. Senchenko A. E., Kulikov Yu. V., Tokarenko A. V. Inprocess testing — A framework for the effective production modernization at Lebedinsky GOK. Gornyi Zhurnal. 2022. No. 6. pp. 59–67. 19. Rocha G. M., da Cruz M. V. M., Lima N. P., Lima R. M. F. Reverse cationic flotation of iron ore by amide–amine: Bench studies. Journal of Materials Research and Technology. 2022. Vol. 18. pp. 223–230. 20. Ismagilov R. I., Baskaev P. M., Ignatova T. V., Shelepov E. V. The prospects for expanding the iron ore mineral and raw material base through the processing of oxidized ferruginous quartzite of the Mikhailovskoe deposit. Obogashchenie Rud. 2020. No. 3. pp. 19–24. 21. Grinenko V. I., Opalev A. S., Maevsky P. V., Karpov I. V. Improvement of iron ore concentrate quality by gravity and magnetic separation at SSGPO JSC. Gornyi Zhurnal. 2021. No. 10. pp. 81–86. 22. Gzogyan S. R., Scherbakov A. V. Improving the quality of concentrates of Stoilensky GOK JSC with the use of magnetic-gravity separation. Obogashchenie Rud. 2020. No. 6. pp. 3–8. 23. Opalev A. S., Khokhulya M. S., Biryukov V. V. Energy-resource-saving technology for producing magnetite-hematite concentrate from ferruginous quartzites of the group of deposits in the Zaimandrovsky region. Vestnik Kolskogo Nauchnogo Tsentra RAN. 2014. No. 2. pp. 67–73. 24. Opalev A. S., Karpov I. V., Krivovichev S. V. Enhancing magnetite quartzite processing efficiency at Karelsky Okatysh. Gornyi Zhurnal. 2021. No. 11. pp. 66–74. |