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SCIENTIFIC AND TECHNICAL DEVELOPMENTS OF THE VNIIKhT
Название Production of rare earth concentrate from phosphogypsum by heap leaching
DOI 10.17580/tsm.2020.02.07
Автор Koltsov V. Yu., Zakharov А. А., Vlasova T. V., Velichkina N. S.
Информация об авторе

Leading Research Institute of Chemical Technology JSC, Moscow, Russia:

V. Yu. Koltsov, Director for Research, Candidate of Technical Sciences, e-mail: basilik2@yandex.ru
А. А. Zakharov, Engineer
T. V. Vlasova, Lead Engineer
N. S. Velichkina, Senior Researcher, Candidate of Technical Sciences, e-mail: natalia.velichkina@gmail.com

Реферат

There has recently worsened the situation related to the environmental impact produced by mining and metallurgical companies – in particular, due to the growing amount of stored industrial waste, such as overburden, country rock, dumps, and tailings. Phosphogypsum is one of such waste materials resulting from sulphuric acid processing of apatite and phosphate concentrates that entraps most of the rare earth metals (REM) contained in the concentrates. The average concentration of REMs in phosphogypsum is 0.4–0.6%. There exists a great number of processing techniques applicable to dumped phosphogypsum material, and heap leaching of pre-sulphated material (using sour solutions) would be the one that offers the best performance and cost effectiveness. The Leading Research Institute of Chemical Technology has developed a process to prepare phosphogypsum for heap leaching. The process involves phosphogypsum granulation with sulphuric acid, leaching of the obtained granules, sorption of a combination of REMs from the pregnant solution, their desorption from resin and deposition of the concentrate. The laboratory testing involved leaching in a percolation column with the barren solution returning to the leaching stage. A KU-2-8 type of cationite was used to achieve sorption of a combination of REMs from the pregnant leach solution. The obtained results are indicative of the prevailing sorption of a combination of REMs, the recovery of which was 97%, whereas the recovery of impurities was only 18%. Recirculation of the barren solution and the pregnant solution does not affect the process of REM leaching from phosphogypsum granules. Thus, high REM recovery was observed (94%) after 8 cycles of leaching/sorption. The proposed processing technique will ensure a continuous automatic heap leaching process resulting in better performance, higher efficiency and lower processing costs.

Ключевые слова Phosphogypsum, granulation, leaching, rare earth metals, sorption, desorption, deposition, pregnant solution, concentrate
Библиографический список

1. Veselov V. M., Zelevskiy V. M., Abramov Ya. K. et al. Extraction of rareearth elements from hard materials containing rare-earth metals. Patent RF, No. 2519692. Published: 20.06.2014. Bulletin No. 17.
2. Lambert A., Tam J., Azimi G. Microwave Treatment for Extraction of Rare Earth Elements from Phosphogypsum. Rare Metal Technology 2017. Cham : Springer, 2017. pp. 47–53.
3. Hui-Xin Jin, Fu-Zhong Wu, Xiao-Hao Mao. Leaching isomorphism rare earths from phosphorite ore by sulfuric acid and phosphoric acid. Rare Metals. 2017. Vol. 36, No. 10. pp. 840–850.
4. Al-Thyabat S., Zhang P. Extraction of rare earth elements from upgraded phosphate flotation tailings. Minerals & Metallurgical Processing. 2016. Vol. 33, No. 1. pp. 23–30.
5. Grabas K., Paweczyk A., Strk W. et al. Study on the Properties of Waste Apatite Phosphogypsum as a Raw Material of Prospective Applications. Waste and Biomass Valorization. 2019. Vol. 10, No. 10. pp. 3143–3155.
6. Bashlykova T. V., Valkov A. V., Petrov V. I. The extraction of rare-earth elements from phosphogypsum and waste of gold mines. Tsvetnye Metally. 2012. No. 3. pp. 40–42.
7. Gromov B. V. Introduction to the chemical technology of uranium. Moscow : Atomizdat, 1978. 336 p.
8. Glushchenko Yu. G., Kozyrev A. B., Larichkin F. D. Extracting rare earths from phosphogypsum: An aspect of production and cost. Available at: http://rusredmet.ru/d/378331/d/doklad-v-gornom-institute.pdf
9. Koltsov V. Yu., Yudina T. B., Kalashnikov V. Yu., Kuznetsov I. V. A method for processing polymetallic ores. Patent RF, No. 2571676. Published: 20.12.2015. Bulletin No. 35.
10. Beletskiy V. I., Davydova L. G., Kochetkov V. I., Lutsenko I. K., Nosov V. D., Petrov R. P. Research methods applicable to in situ ore leaching : Learner’s guide. Moscow : MGRI, 1981. 109 p.
11. Petrov R. P., Dolgikh P. F., Shumilin I. P. Heap leaching in uranium mining. Moscow : Energoatomizdat, 1988. 151 p.
12. Heap leaching of precious metals. Ed. by M. I. Fazlullin. Moscow : Izdatelstvo Akademii gornykh nauk, 2001. 648 p.
13. Lebedev K. B. Ionites in non-ferrous metallurgy. Moscow : Metallurgiya, 1975. 352 p.
14. Borbat V. F., Adeeva L. N. et al. Understanding the possibility of recovering rare earth elements from heat-and-power plant ashes. Proceedings of the International Conference “Rare Earth Metals: Raw Materials Processing, Production of Compounds and Materials with REMs”. Krasnoyarsk, 1995. pp. 108–191.
15. Kozhakhmetov S. K., Kopbaeva M. P., Panova E. P., Shokobaev N. M. et al. Identifying effective ionites for extracting REMs from the process solutions of uranium wastewater. Proceedings of the international conference “Rare earth elements: Geology, chemistry, production and application”. Moscow : VNIIKhT, 2013. pp. 80–82.
16. Lokshin E. P., Tareeva O. A., Kalinnikov V. T. Method of phosphogypsum processing for manufacture of concentrate of rare-earth elements and gypsum. Patent RF, No. 2458999. Published: 20.08.2012. Bulletin No. 23.
17. Koltsov V. Yu., Novikov P. Yu., Vlasova T. V. et al. Method for phosphogypsum processing. Patent RF, No. 2665512. Published: 30.08.2018. Bulletin No. 25.

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