Прага, Чехия:

М. А. Меретуков, независимый эксперт, проф., докт. техн. наук, эл. почта: mamer@inbox.ru

ООО «УК ЮГК», г. Пласт, Россия:
К. И. Струков, президент компании, докт. техн. наук, эл. почта: ugold@ugold.ru

При использовании технологий CIP (уголь в пульпе) и RIP (смола в пульпе) для извлечения тяжелых цветных, редких, благородных и радиоактивных металлов ключевым фактором, обусловливающим приемлемые экономические показатели, является износ адсорбентов вследствие истирания и осмотического «шока». В настоящее время в мире с помощью CIP-технологии получают более 50 % золота. Обследование зарубежных горно-металлургических комбинатов позволило установить, что на каждом заводе, применяющем угольную сорбцию золота, потери активного угля, содержащего 0,11–0,14 кг/т Au, составляют около 2 тыс. т/год. Для извлечения золота из «отвального» угля предложены термо обработка, электрохимические и флотационные методы. Непрерывный процесс ионообменной сорбции урана из пульп (после отделения песковой фракции), основой которого являются пачуки со встроенным грохотом, используют во многих странах, включая ЮАР, США, Австралию, Россию и Узбекистан. Смолы гелевой структуры менее устойчивы к осмотическим воздействиям, в то время как макропористые смолы более устойчивы к химической обработке, однако высокая пористость снижает их устойчивость к физическому истиранию. В настоящее время основные поставщики смол («Пьюролайт», «Ром энд Хаас», «Доу» и «Леватит») улучшили качество RIP-смол, предназначенных для применения в гидрометаллургии урана. Годовой износ этих смол обычно не превышает 5 %. Для извлечения мелких частиц хелатирующей смолы предложено использовать пенную флотацию, а для регенерации содержащегося в ней золота — обработку сверхкритической жидкостью.

1. Meretukov M. The main milestones in the chemistry and metallurgy of gold. Chemistry & Industry. 2010. Vol. 87, No. 6. pp. 271–283.
2. Kienle H., Bäder E. Aktivkohle und ihre industrielle Anwendung (Activated Carbon and its Industrial Application). Ferdinand Enke Verlag. Stuttgart, 1980. 214 p.
3. Laxen P., Becker S., Rubin R. Developments in the application of carbonin-pulp to the recovery of gold from South African ores. Journal of the Southern African Institute of Mining and Metallurgy. 1979. Vol. 79, No. 11. pp. 315–327.
4. Marsden J., House I. The chemistry of gold extraction. Ellis Horwood : N. Y., 1993. 597 p.
5. Toledo R., Aragón-Tobar C., Gamez S., Torre E. Reactivation process of activated xarbons: effect on the mechanical and adsorptive properties. Molecules. 2020. Vol. 25. pp. 1681–1690.
6. Louarrat M., Enaimel G., Baзaoui A. et al. Optimization of conditions for the preparation of activated carbon from olive stones for application in gold recovery. Journal of the Southern African Institute of Mining and Metallurgy. 2019. Vol. 119. pp. 297–306.
7. Davidson R., Schoeman N. The management of carbon in a high-tonnage CIP operation. Journal of the Southern African Institute of Mining and Metallurgy. 1991. Vol. 91, No. 6. pp. 195–208.
8. Meretukov M. A. Active carbons and cyanide process. Moscow : “Ore and Metals” Publishing House, 2007. 288 p.
9. Mukhin V., Tarakanovsky V. Development and introduction of new brands of activated carbons for sorption exchange of gold. Mining Magazine. 2003. No. 12. pp. 59, 60.
10. Adams M., Fleming C. The mechanism of adsorption of aurocyanide onto activated carbon. Metallurgical and Materials Transactions B. 1989. Vol. 20B. pp. 315–325.
11. Adams M. The chemistry of the carbon-in-pulp process : Dissertation of the Doctor of Technical Sciences. University of the Witwatersrand. Johannesburg, 1989. 163 p.
12. Joralemon P. The occurrence of gold at the Getchell mine, Nevada. Economic Geology. 1951. Vol. 46, No. 8. pp. 267–310.
13. Bakker E., Voncken J., Rem P. Reducing gold loss in carbon-in-leach processes. Delft University of Technology, CEG Research Sector. Delft, Netherlands, 2004. 13 p.
14. Bakker E., Voncken J., Rem P. Establishing the loss of carbon fines and the associated loss of gold in ore tailings from carbon-in-pulp/carbon-in-leach processes. Report to Norit Number. 2005. 17 p.
15. Amankwah R., Buah W. Gold recovery from waste activated carbon – a comparison between mechano-chemical pretreatment and charcoal augmented oxidation. CIM Bulletin. 2007. Vol. 100, No. 1102. pp. 16–19.
16. Gallagher N., Hendrix J., Milosavijevic E., Nelson J. Affinity of activated carbon towards some gold(I) complexes. Hydrometallurgy. 1990. Vol. 25, Iss. 3. pp. 305–316.
17. Gomez R. Electrochemical system and method. Patent US 5569370. Published: 1999.
18. McDonnell S. Recovery of activated carbon from gold-ore leaching slurry. RSA Patent ZA 9807294. Published: 1999.
19. Jay W., Breuer P. Gold recovery from carbonaceous adsorbents by ashing and optional leaching. WO Patent 9945158 (Published: 1999).
20. Zhao Y., Sun S., Zhao F. Recovery of gold from waste carbon. Patent 1113961 Chinese. Published: 1995.
21. Amankwah R., Asiam E. Recovery of gold from waste activated carbon. Minerals & Metallurgical Processing. 1996. Vol. 13. pp. 131–134.
22. Amankwah R., Pickles C., Yen W. Gold recovery by microwave augmented ashing of waste activated carbon. Minerals Engineering. 2005. Vol. 18, Iss. 5. pp. 517–526.
23. Hlovor G., Amankwah R. Gold recovery from spent activated carbon. Proceedings of International Conference: Extraction Metallurgy Africa-98. Johannesburg. 1998. pp. 77–79.
24. Ramsay E. Process for the recovery of precious metals from fine carbon. US Patent 2355491 CA. Published: 2003.
25. Hill E., Lin H. Method of recovering gold from the fine carbon residue from a coarse carbon gold recovery process. US Patent 6228334. Published: 2001.
26. Rowe J., McKnight S. Characterization and recovery of gold associated with fine, activated carbon. Proceedings of the World Gold Conference. 2009. pp. 295–298.
27. Lin H., Hill E., Oleson J. Recovering gold from carbon fines by a gold transfer process. Mining, Metallurgy and Exploration. 2002. Vol. 20. pp. 47–51.
28. Lin H., OIeson J., Hollow J., Walsh D. Characterization and flotation of gold in carbon fines at the Fort Knox mine, Alaska. Minerals & Metallurgical Processing. 2002. Vol. 19, No. 1. pp. 21–24.
29. Taylor A., Jansen M. Future trends in PAL plant design for Ni/Co laterites. Proceedings of Ni/Co/Cu ALTA Conference. Australia Perth. 2000. May. 2000. pp. 1–13.

30. Mendes F., Martins A. Recovery of nickel and cobalt from acid leach pulp by ion exchange using chelating resin. Minerals Engineering. 2005. Vol. 18, Iss. 9. pp. 945–954.
31. McKevitt B., Abbasi P., Dreisinger D. A comparison of large bead ion exchange resins for the recovery of base metals in a resin-in-pulp (RIP) circuit. Proceedings of the 6^th Southern African Base Metals Conference. 2011. pp. 337–352.
32. Sole K., Mooiman M., Hardwick E. Present and future applications of ion exchange in hydrometallurgy: An overview. Proceedings of Ion Exchange Conference (IEx). 2016. UK Cambridge. Available at: https://www.researchgate.net/publication/305462927_Present_and_future_applications_of_ion_exchange_in_hydrometallurgy_An_overview.
33. Sole K., Mooiman M., Hardwick E. Ion exchange in hydrometallurgical processing: an overview and selected applications. Separation & Purification Reviews. 2018. Vol. 47. pp. 159–178.
34. van Hege B., van Tonder D., Bell R. et al. Recovery of base metals using MetRIX. Alta 2006. Australia. Perth. May. 2006. 16 p.
35. McCready A., Stumpel E., Lally J. et al. Polymetallic mineralization at the Browns deposit, Rum Jungle mineral field, Australia. Economic Geology. 2004. Vol. 99. pp. 257–277.
36. Udayar T., Shange Z., Kotze M., Yahorava O. Durability of ion exchange resins for the recovery of uranium via resin-in-pulp. Proceedings of the International Ion Exchahge Conference (IEX 2012). Cambridge University UK. 2012. September. Available at https://www.researchgate.net/publication/327418047_durability_of_ion_exchange_resins_for_the_recovery_of_uranium_via_resin-in-pulp.
37. van Deventer J., Mikhaylenko M. Notes of practical application of ion exchange resins in uranium extractive metallurgy. ALTA Uranium Conference. 2009. May 28–30. 16 p.
38. Rezkallah A., Cable P. Understanding and reacting to IX resin fouling in U mining with emphasis on silica and ferric compounds and a new IX base route to uranium. ALTA Uranium 2010. Melbourne. 14 p.
39. Hollis R., McAarthur C. The resin-in-pulp process for recovery of uranium. Proceedings of the International Conference on the Peaceful Uses of Atomic Energy. Geneva. 1955. Vol. 8. pp. 54–63.
40. Izzo T., Painter L., Chelminski R. Moab mill starts making U3O8 cake. Engineering and Mining Journal. 1957. Vol. 158, No. 1. pp. 90–98.
41. Painter L., Izzo T. Operation of the resin-in-pulp uranium processing mill at Moab, Utah. Proceedings of the 2^nd United Nations Conference on the Peaceful Uses of Atomic Energy. 1958. Geneva. Vol. 3. pp. 308–386.
42. Beverly R., McArthur C. US Atomic Energy Commission Raw Materials Development Laboratory. 1959. Summary Report. 1954–1959. WIN-115. 101 p. Available at: https://digital.library.unt.edu/ark:/67531/metadc875286/m1/5/.
43. Himsley A. Uranium extraction from turbid liquids by continuous ion exchange process. CIM Bulletin. 1977. Vol. 70, No. 785. September. pp. 148–154.
44. Breymann J., Hollis E., Lynch J. A continuous countercurrent resin-inpulp process. US Atomic Energy Commission Raw Materials Development Laboratory. Winchester. WIN-102. 1958. July 18. ID 92519370.
45. Merritt R. The extractive metallurgy of uranium. Colorado School of Mines, 1971. 593 p.
46. Cloete F. The Relix process for the resin-in-pulp recovery of uranium. Journal of the Southern African Institute of Mining and Metallurgy. 1981. Vol. 81. March. pp. 66–73.
47. Udayar T., Kotze M., Yahorava V. Recovery of uranium from dense slurries via resin-in-pulp. Proceedings of the 6^th Base Metals Conference Phalaborwa. 2011. July 18–20. pp. 49–64.
48. Carr J. A technical evaluation of elution technologies for uranium recovery. Proceedings of the International Conference: ALTA 2010. Perth. Australia. May 18–19. 2010. pp. 58–73.
49. Khan Resources: Khan lays out plan for Dornod uranium project in Mongolia. Press Release. 2009. September 28. 1 p.
50. Mantra Resources: Positive results from resin-in-pulp metallurgical testwork on Nyota Prospect. Proactive. 2009. Available at: https://www.proactiveinvestors.com/companies/news/138456/mantra-resources-unveils-positive-results-from-recent-metallurgical-testwork-on-nyota-prospect-3556.html.
51. Ling Y., Durupt N., Banton N. RIP studies at AREVA: R&D and applications for Niger and Canada projects. Proceedings of the International Conference: Uranium 2010. Saskatoon, Saskatchewan (Canada). 2010. August 15–18. 2010. pp. 27–38.
52. Hladun D. Startup of Kayelekera uranium mine. Proceedings of the International Conference: Uranium 2010. 2010. pp. 415–426.
53. Brown J., Goode J., Fleming C. The re-emergence of resin in pulp with strong base resins as a low-cost, technically viable process for the recovery of uranium. SGS Mineral Services. Technical Paper. 2010. No. 2. p. 1–11.
54. Virnig M., Picardo J., Mackenzie J. et al. The use of AuRIX 100 resin and Gekko Systems Technology for the recovery of gold. Proceedings of the Gold Symposium. 2004. Peru. Lima. May. pp. 1–24.
55. Virnig M., Mackenzie J., Adamson C. The use of guanidine-based extractants for recovery of gold. Journal of the Southern African Institute of Mining and Metallurgy. 1996. pp. 151–156.
56. Cortina J., Meinhardt E., Roijals O., Marti V. Modification and preparation of polymeric adsorbents for precious-metal extraction in hydrometallurgical processes. Reactive & Functional Polymers. 1998. Vol. 36. pp. 149–165.
57. Dippenaar A., Proudfoot M. The performance of the AAC pumpcell circuits at the gold fields limited driefontein and kloof operations. Randol Innovative Metallurgy Forum. Perth. Australia. 2005. 9 p.
58. Van Tonder D., Van Hege B. Uranium recovery from acid leach liquors. The optimisation of RIP/SX based flowsheets. Proceedings of the 4^th Base Metals Conference. 2–4 September. 2007. pp. 241–260.
59. Schoem N., Rogans E., MacIntosh A. AAC Pumpcells: a cost effective means of gold recovery from low grade slurries. Journal of the Southern African Institute of Mining and Metallurgy. 1996. pp. 173–179.
60. McArthur D., Rogans E. The evaluation of the AAC pump-cell circuits at Anglogold’s West Wits operations. Journal of the Southern African Institute of Mining and Metallurgy. 2002. Vol. 102. pp. 181–188.
61. Yahorava V., Scheepers J., Kotze M., Auerswald D. Evaluation of various durability tests to assess resins for in-pulp applications. Proceedings of International Conference: Base Metals. 2009. pp. 341–358.
62. Green B., Kotze M., Wyethe J. Developments in ion exchange: The Mintek perspective. JOM. 2002. Vol. 54, No. 10. pp. 37–43.
63. Fleming C. Recovery of gold by resin-in-pulp at the golden jubilee mine. Proceedings of International Symposium: Precious Metals’89. 1989. pp. 105–119.
64. Zaganiaris E. Effect of physical and chemical structure of ion exchange resin on silica fouling in acid leach liquors in uranium hydrometallurgy. International Conference: Hydrometallurgy 81. June 30 – July 03. 1981. England. Manchester. 15 p.
65. Yahorava V., Scheepers J., Kotze M. Comparison of various anion exchange resins for the recovery of uranium by means of RIP. ALTA Uranium Conference. 2009. Australia. Perth. May 28–30. 15 p.
66. Yahorava V., Scheepers J., Kotze M., Auerswald D. Evaluation of variousdura bility tests to assess resins for in-pulp applications. Base Metals Conference. 2009. May. 18 p.
67. Duyvesteyn S., Doyle F. Loading and froth flotation of a chelating ionexchange resin. Proceedings of International Conference: Separation processes: heavy metals, ions and minerals. 1995. Las Vegas. February 12–16. pp. 123–134.
68. Clifford T., Bartle K. Chemistry goes supercritical. Chemistry in Britain. 1993. June. pp. 499–502.
69. Phelps C., Smart N., Wai C. Past, present, and possible future applications of supercritical fluid extraction technology. Journal of Chemical Education. 1996. Vol. 73. pp. 1163–1170.
70. Dias A., de Aguiar A., Rostagno M. Extraction of natural products using supercritical fluids and pressurized liquids assisted by ultrasound: Current status and trends. Ultrasonics Sonochemistry. 2021. Vol. 74. Ch. 105584.
71. Otu E. Elution of gold from activated carbon using supercritical carbon dioxide. Separation Science and Technology. 1997. Vol. 32, Iss. 6. pp. 1107–1114.
72. Glennon J., Harris S., Walker A. et al. Carrying gold in supercritical CO₂. Gold Bulletin. 1999. Vol. 32, No. 2. pp. 51–58.
73. Otu E., Wilson J. Supercritical carbon dioxide elution of gold-cyanide complex from activated carbon. Separation Science and Technology. 2000. Vol. 35. pp. 1879–1886.
74. van Zyl P., Breet E., Williams C. Recovery of KAu(CN)2 from granular activated carbon using supercritical CO₂. The Journal of Supercritical Fluids. 2008. Vol. 47, Iss. 1. pp. 31–36.
75. Manjare S., Dhingra K. Supercritical fluids in separation and purification: A review. Materials Science for Energy Technologies. 2019. Vol. 2, Iss. 3. pp. 463–484.
76. van Zyl P. Recovery of gold from spent matrices using supercritical carbon dioxide: thesis of dissertation. Doctor of Chemistry. North-West University. Potchefstroom, RSA. 2007. 118 p.
77. Turysbekova G., Meretukov M., Bektai E. Gold: innovations in chemistry and metallurgy. Almaty, 2015. 632 p.