• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Tsvetnye Metally →  2016 →  №12 →  Назад

NOBLE METALS AND ALLOYS
Название Electrochlorinator for dissolution of placer platinum
DOI 10.17580/tsm.2016.12.03
Автор Konik K. P., Kuzas E. A., Lobko S. V., Naboychenko S. S.
Информация об авторе

Ekaterinburg Non-Ferrous Metals Processing Plant, Verkhnyaya Pyshma, Russia:

K. P. Konik, Head of Refining Shop
S. V. Lobko, Leading Research Engineer


LLC “ENFMPP — Engineering”, Verkhnyaya Pyshma, Russia:

E. A. Kuzas, Engineer, e-mail: e.kuzas@ezocm.ru

 

Ural Federal University named after the first President of Russia B. N. Yetlsin, Ekaterinburg, Russia:
S. S. Naboychenko, Professor, Head of a Chair of Metallurgy of Heavy Nonferrous Metals
Реферат

In Russian and foreign refineries alike, raw materials, containing platinumgroup metals, are processed by applying technologies such as hydrochlorination, sintering with oxidizers or dissolution in a panitrohydrochloric acid. These technologies are highly intensive, but do not ensure the required completeness of raw material opening per phase. Electrochlorination is efficient and promising platinum-group metal opening method, where precious metals are oxidized with atomic chlorine, which is formed during electrochemical oxidization of chloride-ions on the dissolved material surface. The type of current is the most important of the parameters, influencing the electrochlorinator construction. A laboratory research was performed to study the low-frequency symmetrical AC current and DC current influence on electrochlorination dynamics and placer platinum opening completeness. The experiments disclosed that the usage of DC current and Nafion cation exchange membranes enables the highest speed of placer platinum electrochlorination in hydrochloric acid solution. The specialists at Ekaterinburg Non-Ferrous Metals Processing Plant develop a special industrial DC electrochlorinator with a 200 dm3 operating volume. It can dissolute up to 20 kg of placer platinum per day; achieve at least a 99% completeness of placer platinum opening; obtain sulphate-chloride solutions without nitrate ions, whilst the concentration of platinum is at least 100 dm3; automatically support the electrolyte level in anode and cathode chambers, and change the current load depending on the anolyte’s temperature. The industrial electrochlorinator may also be used for dissolution of other types of precious metals containing raw materials.
Ключевые слова Electrochlorinator, electrochlorination, placer platinum, atomic chlorine, hydrochloric acid, chemisorption, low-frequency symmetrical AC current, Nafion cation exchange membrane
Библиографический список

1. Kotlyar Yu. A., Meretukov M. A., Strizhko L. S. Metallurgiya blago rodnykh metallov : uchebnik (Metallurgy of noble metals : tutorial). In 2 volumes. Volume 2. Moscow : MISiS, “Ore and Metals” Publishing House, 2005. 392 p.
2. Ginzburg S. I., Ezerskaya N. A., Prokofeva I. V., Fedorenko N. V., Shlenskaya V. I., Belskiy N. K. Analiticheskaya khimiya platinovykh metallov (Analytical chemistry of platinum metals). Moscow : Nauka, 1972. 616 p.
3. Upadhyay A. K., Jae-chun Lee, Eun-young Kim, Min-seuk Kim, Byung-Su Kim, Vinay Kumar. Leaching of platinum group metals (PGMs) from spent automotive catalyst using electro-generated chlorine in HCl solution. Journal of Chemical Technology and Biotechnology. 2013. Vol. 88, No. 11. pp. 1991–1999.
4. Kim M., Jae-chun Lee, Sang-woon Park, Jinki Jeong, Vinay Kumar. Dissolution behaviour of platinum by electro-generated chlorine in hydrochloric acid solution. Journal of Chemical Technology and Biotechnology. 2013. Vol. 88, No. 7. pp. 1212–1219.
5. Mpinga C. N., Eksteen J. J., Aldrich C., Dyer L. Direct leach approaches to Platinum Group Metal (PGM) ores and concentrates: A review. Minerals Engineering. 2015. Vol. 78. pp. 93–113.
6. Manis Kumar Jha, Jae-chun Lee, Min-seuk Kim, Jinki Jeong, Byung-Su Kim, Vinay Kumar. Hydrometallurgical recovery/recycling of platinum by the leaching of spent catalysts: A review. Hydrometallurgy. 2013. Vol. 133. pp. 23–32.
7. Herrmann Z, Landau U. Elektroliticheskiy sposob rastvoreniya platiny, primesey platinovykh metallov i/ili splavov platinovykh metallov, soderzhashchikh rodiy, palladiy, iridiy, zoloto i serebro (Electrolytical method of dissolution of platinum, impurities of platinum metals and/or platinum metal alloys, containing rhodium, palladium, irridium, gold and silver). Patent RF, No. 2094534, IPC7 C 25 C 1/20. Applier and Patent-Holder: Shott Glaswerke. No. 93056628/02. Applied: 17.12.93. Published : 27.10.97.
8. Spiridonov B. A., Fedyanin V. I. Sposob elektroliticheskogo rastvoreniya splavov platinovykh metallov (Method of electrolytical dissolution of platinum metal alloys). Applier and Patent-Holder: Voronezh State Technical University. Patent RF, No. 2307203, IPC7 C 25 C 1/20. No. 2006104643/02. Applied: 14.02.06. Published: 27.09.07. Bulletin No. 27. 4 p.
9. Anisimova N. N., Kotukhova G. P., Galantseva T. V., Glazkov V. B., Tikhov I. V., Kamenskiy V. S., Baryshev A. A., Gorshkov V. I. Sposob perera botki materialov, soderzhashchikh platinovye metally i serebro (Method of processing of materials, containing platinum metals and silver). Patent RF, No. 2256711, IPC7 C 22 B 11/00, 3/10, C 25 C 1/20. Applier and Patent-Holder: “Norilsk Nikel” MMC. No. 2003123087/02. Applied: 28.07.03. Published: 20.07.05. Bulletin No. 20. 10 p.
10. Prikladnaya elektrokhimiya : uchebnik dlya vuzov (Applied electrochemistry : tutorial for universities. Ed.: A. P. Tomilov. Moscow : Khimiya, 1984. 520 p.
11. Llopis J., Tordesillas I. M., Muniz M. Anodic corrosion of rhodium in hydrochloric acid solutions. Electrochimica Acta. 1965. Vol. 10, No. 11. pp. 1045–1055.
12. Baraboshkin V. E. Effektivnaya tekhnologiya polucheniya khlorida rodiya (Efficient technology of obtaining of rhodium chloride). XX Mezhdunarodnaya Chernyaevskaya konferentsiya po khimii, analitike i tekhnologii platinovykh metallov : sbornik tezisov (XX International Chernyaev conference on chemistry, analytics and technology of platinum metals : collection of thesises). Krasnoyarsk : Siberian Federal University, 2013. p. 132.
13. Medvedev S. An Electrochemical Method and a Technological Solution to Rhodium Chloride Production [Electronic Resource]. IPMI® 39th Annual Conference : Proceedings. Madison : Omnipress, 2015. 1 CD-ROM.
14. Elektroosazhdenie blagorodnykh i redkikh metallov (Electrosedemintation of noble and rare metals). Ed.: L. I. Kadaner. Kiev : Tekhnika, 1974. 160 p.
15. Lidin R. A., Molochko V. A., Andreeva L. L. Khimicheskie svoystva neorganicheskikh veshchestv : uchebnoe posobie dlya vuzov (Chemical properties of inorganic substances : tutorial for universities). Ed.: R. A. Lidin. Moscow : Khimiya, 2000. 480 p.
16. M. Clyde Day, Joel Selbin. Teoreticheskaya neorganicheskaya khimiya (Theoretical inorganic chemistry). Translated from English. Moscow : Khimiya, 1976. 568 p.
17. Yaroslavtsev A. B., Nikonenko V. V. Ionoobmennye membrannye materialy: svoystva, modifikatsiya i prakticheskoe primenenie (Ion-exchange membrane materials: Properties, modification, and practical application). Rossiyskie nanotekhnologii = Nanotechnologies in Russia. 2009. Vol. 4, No. 3/4. pp. 33–53.
18. Yakimenko L. M., Pasmanik M. I. Spravochnik po proizvodstvu khlora, kausticheskoy sody i osnovnykh khloroproduktov (Reference book for the production of chlorine, caustic sola and basic chlorine products). Moscow : Khimiya, 1976. 440 p.
Language of full-text русский
Полный текст статьи Получить
Назад