Kroosh Technologies Ltd (Ashdod, Israel):

Kosoy G. M., Chief Ore Concentration Specialist, Doctor of Engineering Sciences, grigory.k@kroosh.com

The article provides a brief overview of the development of technology and equipment for the preparation of finely disseminated ores of ferrous and non-ferrous metals for further processing. Fine screening processes and equipment for crushed ores are considered, including in combination with centrifugal hydraulic classification. The purpose of the work was to improve hydraulic screening performance and efficiency for crushed ores. In order to optimize the preparation of finely disseminated ores for processing, a combined preliminary hydraulic classification process was developed for crushed ores based on the use of a flat-bottomed hydrocyclone and a multi-frequency screen. A pilot plant was used to test the process. The article contains qualitative and quantitative performance indicators for the hydraulic screening of crushed chromium ore with a particle size of 300–0 μm. The total recovery of all size classes below 300 μm into the undersize of the multi-frequency screen was 86.42 % and the recovery of finer ore classes (below 150 μm) was 91.09 to 92.97 %. The resulting combined process using a flat-bottomed hydrocyclone and a multi-frequency screen improves the total equipment performance, ensures high recoveries of fine classes into the undersize, extends the service life of fine sieves and reduces water consumption for oversize irrigation. This combined process is also recommended for use in hydraulic screening of magnetite concentrates at mining and processing plants in order to improve the iron content, as well as in closed fine grinding circuits in order to prevent overgrinding of valuable minerals and reduce the circulating load on the screens.

1. Povarov A. I. Hydrocyclones at concentrating plants. Moscow: Nedra, 1978. 232 p.
2. Bauman A. V. Hydrocyclones. Theory and practice. Novosibirsk: Sibprint, 2020. 58 p.
3. Albuquerque L. G., Wheeler J. E., Valine S. B. Application of high frequency screens in closing grinding circuits. XXIII Encontro nacional de tratamento de minério e metalurgia extrativa (ENTMME). Brasil, 2009. pp. 167–173.
4. Chernova E. V., Chernov D. V. Current status and application of fine screening technology in China. IOP Conference Series: Earth and Environmental Science. 2017. Vol. 87. DOI: 1088/1755-1315/87/2/022005.
5. Bondarenko A. A., Martynov Yu. V. Analysis of the Derrick Stack Sizer screen and prospects for its implementation. Proc. of the IX International youth forum «Education. Science. Production». 2017. pp. 1219–1221.
6. Krush I. I., Borokhovich D. E., Kosoy G. M. Application of Kroosh technology for the separation of bulk materials and polydisperse suspensions. Gorny Informatsionno-analiticheskiy Byulleten'. 2009. No. S14. pp. 171–183.
7. Kosoy G., Krush Y., Slavutin M. Development of multifrequency sieve analyzer. URL: https://grigorykosoy.academia.edu/research#papers (accessed: 03.08.2022).
8. 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. DOI: 10.17580/tsm.2021.06.01.
9. Mamonov S. V. Fine hydraulic screening — a factor in increasing the efficiency of operations of ore preparation and enrichment of copper-zinc ore. Izvestiya Vuzov. Gornyi Zhurnal. 2017. No. 3. pp. 114–120.
10. Shiryaev A. A., Neskoromny E. N., Mironenko A. I., Samokhina S. A., Starykh S. S. Application of fine screening to improve the quality of iron ore concentrate at the processing plant of the ArcelorMittal Kryvyi Rih mining and processing complex. Vestnik Krivorozhskogo Natsionalnogo Universiteta. 2013. No. 34. pp. 120–123.
11. Pelevin A. E., Sytykh N. A. Efficiency of screens and hydrocyclones in closed-cycle grinding of titanomagnetite ore. Gorny Informatsionno-analiticheskiy Byulleten'. 2022. No. 5. pp. 154–166.
12. Pelevin A. E., Sytykh N. A. The features of classification in hydrocyclones in the course of titanium magnetite ore grinding. Izvestiya Vuzov. Gornyi Zhurnal. 2021. No. 1. pp. 74–84.
13. Pelevin A., Saitov V., Dmitriev V. Separation of magnetite concentrate before the last grinding stage. E3S Web of Conferences. 2020. Vol. 177, Iss. 12. DOI: 10.1051/e3sconf/202017701002.
14. Trawinski H. F. The hydraulic cyclone has not yet exhausted its potential applications. Erzmetall: Journal for Exploration, Mining and Metallurgy. 1981. No. 6. pp. 354–360.
15. Trawinski H. F. About the practice of hydrocyclone operation. Proc. of the 2^nd International conference on hydrocyclones. Bath, England, 1984. pp. 393–412.
16. Lopatin A. G. Centrifugal beneficiation of ores and sands. Moscow: Nedra, 1987. 224 p.
17. Yablonsky V. O., KoffiKuame E., Gerayom N. Influence of the operating parameters of a cylindrical hydrocyclone on the process of wastewater separation. Matematicheskie Metody v Tekhnike i Tekhnologiyakh. 2019. Vol. 1. pp. 31–37.
18. Yablonskii V. O. Influence of operating parameters of a cylindrical hydrocyclone on separation factor of nonlinearly viscoplastic suspensions. Chemical and Petroleum Engineering. 2019. Vol. 55, Iss. 3–4. pp. 265–273.
19. Vasilyev A. M., Kuskov V. B. Specific features of the concentration process for fine-grained materials in a shortcone hydrocyclone. Obogashchenie Rud. 2018. No. 2. pp. 30–34. DOI: 10.17580/or.2018.02.06.
20. Hou D., Cui B., Zhang H., Zhao Q., Wei D., Ji A., Feng Y. Designing the hydrocyclone with flat bottom structure for weakening bypass effect. Powder Technology. 2021. Vol. 394. pp. 724–734.
21. Hou D., Zhao Q., Cui B., Wei D., Song Z., Feng Y. Geometrical configuration of hydrocyclone for improving the separation performance. Advanced Powder Technology. 2022. Vol. 33, Iss. 2. DOI: 10.1016/j.apt.2021.103419.