Processing of Chloride-Containing Productive Solutions after Uranium in situ Leaching by Ion Exchange Method

https://doi.org/10.22146/ijc.34460

Svetlana Titova(1*), Sergey Skripchenko(2), Alexey Smirnov(3), Vladimir Rychkov(4)

(1) Institute of Physics and Technology, Ural Federal University, Russian Federation
(2) Institute of Physics and Technology, Ural Federal University, Russian Federation
(3) Institute of Physics and Technology, Ural Federal University, Russian Federation
(4) Institute of Physics and Technology, Ural Federal University, Russian Federation
(*) Corresponding Author

Abstract


The uranium sorption from productive solutions containing chloride ions using anion-exchange resins was investigated. The VPAE ion exchanger had the highest values of the sorption capacity, which for the experiment in the static mode was 13 kg U m-3, and for the experiment in the dynamic mode, it was equal to 36 kg U m-3. The use of VPAE anion exchanger will make it possible for uranium recovery from productive solutions with an increased content of chloride without sacrificing the productivity of the sorption plant. The process of saturated resins regeneration by various reagents was investigated. The use of ammonium nitrate solution with sulfuric acid ensured maximum value of uranium recovery from the saturated resin phase (76–97%).


Keywords


uranium; ion exchange; chloride ion; regeneration

Full Text:

Full Text PDF


References

[1] Ux Consulting Company, 2017, Uranium Market Outlook - Q1, UxC, Roswell.

[2] Ux Consulting Company, 2017, Uranium Market Outlook - Q2, UxC, Roswell.

[3] World Nuclear Association, 2017, The Nuclear Fuel Report. Global Scenarios for Demand and Supply Availability 2017-2035, World Nuclear University Press, London.

[4] Boytsov, A.V., 2017, World uranium industry: Status, prospects of development, challenges of time, Actual problems of the uranium industry, Astana, 14–21.

[5] Shatalov, V.V., and Tarkhanov, A.V., 2009, Present status of the world and Russian uranium mineral-raw material resources, At. Energy, 107 (5), 310–316.

[6] The Nuclear Energy Agency and the International Atomic Energy Agency, 2016, Uranium 2016: Resources, Production and Demand, OECD.

[7] Khlopkov, A., and Chekina, V., 2014, Governing uranium in Russia, DIIS Report, No. 2014:19, Danish Institute for International Studies, Copenhagen.

[8] Mashkovtsev, G.A., 2017, Uranium potential of Russia, Actual problems of the uranium industry, Astana, 22-23.

[9] International Atomic Energy Agency, 2016, In Situ Leach Uranium Mining: An Overview of Operations, IAEA, Vienna, 20.

[10] Rychkov, V.N., Poponin, N.A., Smirnov, A.L., Dementiev, A.A., and Golovko, V.V., 2010, Experience in the production of uranium concentrates at JSC Dalur, Actual problems of the uranium industry, Almaty.

[11] Pastukhov, A.M., Rychkov, V.N., and Skripchenko, S.Y., 2015, Thermodynamic modeling of the in-situ leaching of uranium, J. Radioanal. Nucl. Chem., 303 (3), 2053–2057.

[12] Ogden, M.D., Moon, E.M., Wilson, A., and Pepper, S.E., 2017, Application of chelating weak base resin Dowex M4195 to the recovery of uranium from mixed sulfate/chloride media, Chem. Eng. J., 317, 80–89.

[13] Moon, E.M., Ogden, M.D., Griffith, C.S., Wilson, A., and Mata, J.P., 2017, Impact of chloride on uranium(VI) speciation in acidic sulfate ion exchange systems: Towards seawater-tolerant mineral processing circuits, J. Ind. Eng. Chem., 51, 255–263.

[14] Cai, P., Tan, K., Shi, W., Hu, E., and Huang A., 2010, Experimental study of ion exchange and neutralization on acid in situ leach uranium mining wastewater, Mod. Mining, 11, 21–23.

[15] Balanovsky, N.V., Koshcheeva, A.M., and Cherednichenko, A.G., 2016, Synthesis and properties of strongly basic acrylate polyfunctional anion-exchange resin for uranium extraction, Moscow Univ. Chem. Bull., 71 (5-6), 336–340.

[16] Cheira, M.F., Atia, B.M., and Kouraim, M.N., 2017, Uranium(VI) recovery from acidic leach liquor by Ambersep 920U SO4 resin: Kinetic, equilibrium and thermodynamic studies, J. Radiat. Res. Appl. Sci., 10 (4), 307–319.

[17] Rychkov, V.N., Smirnov, A.L., Skripchenko, S.Y., Pastukhov, A.M., and Poponin, N.A., 2017, Precipitation of yellowcake from pregnant regenerate by various reagents, J. Radioanal. Nucl. Chem., 314 (3), 1741–1746.

[18] Guettaf, H., Becis, A., Ferhat, K., Hanou, K., Bouchiha, D., Yakoubi, K., and Ferrad, F., 2009, Concentration-purification of uranium from an acid leaching solution, Physics Procedia, 2 (3), 765–771.

[19] Kolomiets, D.N., Troshkina, I.D., Sheremet’ev, M.F., and Konopleva, L.V., 2005, Sorption of uranium from sulfuric acid leaching solutions by strongly basic anion exchangers, Russ. J. Appl. Chem., 78 (5), 722–726.

[20] Pakholkov, V.S., Denisova, L.A., Rychkov, V.N., and Kurnosenko, N.A., 1988, Sorption of uranium(VI) ions from hydrochloric acid and ammonium chloride solutions by anion exchangers, Sov. Radiochem., 29 (3), 353–358.

[21] Nekrasova, N.A., Kudryavtseva, S.P., Milyutin, V.V., Chuveleva, E.A., Firsova, L.A., and Gelis, V.M., 2008, Sorption of uranium from carbonate solutions on various ion exchangers, Radiochemistry, 50 (2), 180–182.

[22] Nascimento, M.R.L., Fatibello-Filho, O., and Teixeira, L.A., 2004, Recovery of uranium from acid mine drainage waters by ion exchange, Miner. Process. Extr. Metall. Rev., 25 (2), 129–142.

[23] Panturu, E., Filcenco-Olteanu, A., Radu, A.D., and Zlagnean, M., 2017, The influence of ultrasounds on the process of uranium desorption, E3S Web Conf., 18, 01034.

[24] Peganov, V.A., Molchanova, T.V., Akimova, I.D., and Zharova, E.V., 2015, Technology for obtaining natural-uranium concentrates to ASTM C 967-08 specifications, At. Energy, 117 (6), 415–421.

[25] ASTM International, 2013, ASTM C967-13. Standard specification for uranium ore concentrate, ASTM, West Conshohocken.



DOI: https://doi.org/10.22146/ijc.34460

Article Metrics

Abstract views : 3201 | views : 2466


Copyright (c) 2018 Indonesian Journal of Chemistry

Creative Commons License
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

 


Indonesian Journal of Chemistry (ISSN 1411-9420 /e-ISSN 2460-1578) - Chemistry Department, Universitas Gadjah Mada, Indonesia.

Web
Analytics View The Statistics of Indones. J. Chem.