The use of chlorine-containing agents in the processing of spent blocks of uranium deposits

T. Duisebayeva; A. Arbuz

doi:10.31643/2023/6445.29

Authors

T. Duisebayeva Kazakh National University named after al-Farabi
A. Arbuz Nazarbayev University

DOI:

https://doi.org/10.31643/2023/6445.29

Keywords:

uranium mines, associated valuable metals, associated useful components, underground well leaching, productive solution, chlorine-containing solutions.

Abstract

The work is aimed at diversifying existing mines for the extraction and processing of natural uranium through additional processing of spent blocks of uranium deposits with chemical solutions using the method of in-situ well leaching (ISL) in order to extract associated useful components. A feature of this technology is the use of the existing production infrastructure for the extraction of associated useful components in existing uranium mines, without significant capital investments in production infrastructure and mining operations. The technology of underground borehole leaching has been reliably developed in uranium deposits for decades. The fundamental similarity of the technology for the extraction of uranium and a number of associated useful components (APC) - by the ISR method, allows the use of spent ore fields of uranium deposits for the extraction of PPC. The use of ready-made technological infrastructure (wells, pipeline network, pumping equipment, control units, etc.) allows, due to savings on infrastructure costs, to obtain profitability when mining ore-bearing blocks with a content of recoverable components from ≤ 1 g/t, up to 0.1 g/t. Taking into account the indirect savings of significant costs for the reclamation of spent blocks, it will be profitable to mine blocks with a content of recoverable components up to 0.01 g/t. In view of the foregoing, this technology has a good prospect for implementation in production.

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Author Biographies

T. Duisebayeva, Kazakh National University named after al-Farabi

Ph.D. student, al-Farabi Kazakh National University. Leading specialist, JSC "Volkovgeologiya", Bogenbay Batyr 168, Almaty, Kazakhstan.

A. Arbuz, Nazarbayev University

Research Infrastructure Coordinator, Core Facilities, Office the Provost, Nazarbayev University, Nur-Sultan, Kazakhstan.

References

Fazlullin MI, Shatalov VV, Gurov VA, Avdonin GI, Smirnova RN, Stupin VI. Prospects of underground borehole leaching of gold in Russia. Non-ferrous metals. 2002, 10.

Arens VZh. Physico-chemical geotechnologies. M.: MGGU Publishing House. 2001.

Esengaraev EK, Baimbetov BS, Mamyachenkov SV, Surimbaev BN, Prozor NG. Studying the process of gold cyanide leaching using sodium acetate at various ore sizes. Kompleksnoe Ispolzovanie Mineralnogo Syra= Complex Use of Mineral Resources. 2020;1(312):59-68. https://doi.org/10.31643/2020/6445.08

Patent RU 2074958 C1. An environmentally friendly method for underground leaching of precious metals, mainly gold and silver, from ores at the site of their occurrence. Zhagin BP, Vidusov TE, Zabolotsky AI. Publ. 27.10.1996

Patent RU 2094605 C1. A method for extracting gold from ores and an aqueous solution for leaching gold. Blokhin NN, Fedotov GP, Khmelevskaya GA, Zabelsky VK, Avargin VA. Publ. 27.10.1997

Patent RU 2093672 C1. Composition and method for leaching gold. Blokhin NN, Fedotov GP,Khmelevskaya GA, Zabelsky VK, Avargin VA. Publ. 20.10.1997

Samusev AL, Tomskaya ES. Modern methods of intensification of the process of leaching gold from persistent mineral raw materials. Gorny informatsionno-analiticheskiy bulletin. 2015;8:100-105.

Zyryanov MN, Leonov SB. Chloride metallurgy of gold. M.: SP Intermet Engineering. 1997, 288.

Ferron CJ, Fleming CA, Dreisinger D, O’Kane T. Chloride as an alternative to cyanide for the extraction of gold –going full curcle. SGS Minerals Services. 2003, 01.

Orozova GT. Investigation of the process of hydrochlorination of ore waste from the Makmal deposit. Nauka, novye tekhnologii i innovatsii. 2015;2:19-20.

Hasab MG, Rashchi F, Raygan S. Chloride-hypochlorideoxidation and leaching of refractory sulfide gold concentrate. Physicochemical Problems of Mineral Processing. 2013;49(1):61-70.

Ghobeiti Hasab M, Rashchi F, RayganSh. Chloride-hypochlorite leaching and hydrochloric acid washing in multi-stages for extraction of gold from a refractory concentrate. Hydrometallurgy. 2014;142:56-59.

Syed S. Recovery of gold from secondary sources. Review. Hydrometallurgy. 2012;115-116:30-51.

Samusev AL, Minenko VG.Influence of chemical-electrochemical leaching parameters on gold recovery from rebellious minerals. Gornyy informatsionno-analiticheskiy byulleten. 2016;5:301-308.

Prokhorov KV, Burdonov AE. Chloride-hypochlorite leaching of gold from oxidized ores of the Malmyzhskoye deposit. Gorny zhurnal.2018:62-66.

Kwang SN, Byoung HJ, Jeon W, Tae J, Had TT, Myong JK. Use of chloride-hypochlorite leachants to recover gold from tailing. International Journal of Mineral Processing. 2008;86(1-4):131-140.

Riina A, Mari L. Cyanide-free gold leaching in exceptionally mild chloride solutions. Journal of Cleaner Production. 2019;234:9-17.

Khasab MG, Raschi F, Raigan S. Chloride-hypochlorite oxidation and leaching of refractory sulfide gold concentrate. Physico-chemical problems of mineral processing. 2013;49(1):61-70.

Prokhorov KV, Burdonov AE. Chloride-hypochlorite leaching of gold from oxidized ores of the Malmyzhsky birthplace. Mining magazine. 2018, 10.

Yao Ch, Shaobo Sh, Jiantao Zh, Shuai Ch, Lei X, Jianhua L. Fast and Effective Gold Leaching from a Desulfurized Gold Ore Using Acidic Sodium Chlorate Solution at Low Temperature. Industrial & Engineering Chemistry Research, November 1, 2013.