Theoretical Foundations and Technological Capabilities of Hydrocarbonyl Process while Recovering Copper from Technogenic Wastes

• Autorzy: Fedoseev I. V. , Barkan M. S. , Kornev A. B. , Danilov A. S.

Identyfikatory

DOI

10.12911/22998993/91264

• Języki publikacji: EN

Abstrakty

EN

Secondary processing of waste from metallurgical and other industries becomes an urgent issue in the face of increasing anthropogenic pressure and a shortage of sources of materials. The paper shows the results of chemical and technological studies of processes, executing in the Cu(II) – Cu(I) – Cl^- – CO – H₂О system. The processing technology of copper-bearing intermediate products multicomponent leaching solutions, permitting high purity copper production at the least economic cost, is proposed.

Słowa kluczowe

EN

polymetallic sulphide ores; high purity copper; hydrocarbonyl process; reduction ratio; producer gas

• Wydawca: Polskie Towarzystwo Inżynierii Ekologicznej ; Lublin University of Technology
• Czasopismo: Journal of Ecological Engineering
• Rocznik: 2018
• Tom: Vol. 19, nr 5
• Strony: 33--37
• Opis fizyczny: Bibliogr. 10 poz., rys., tab.

Twórcy

autor

Fedoseev I. V.

• Geoecology Department, Saint-Petersburg Mining University, 21st Line 2, Saint-Petersburg, 199106, Russia

autor

Barkan M. S.

• Geoecology Department, Saint-Petersburg Mining University, 21st Line 2, Saint-Petersburg, 199106, Russia

autor

Kornev A. B.

• Geoecology Department, Saint-Petersburg Mining University, 21st Line 2, Saint-Petersburg, 199106, Russia

autor

Danilov A. S.

• Geoecology Department, Saint-Petersburg Mining University, 21st Line 2, Saint-Petersburg, 199106, Russia

Bibliografia

• 1. Altushkin I.A., Levin V.V., Sizikov A.V., Korol Yu.A. 2017. Experience of development of porphyry copper type deposits type in the Urals. Zapiski Gornogo Instituta, 228, 641–648.
• 2. Fedoseev I.V., Maksimov V.V. 2012. The use of hydrocarbonyl process in copper production technology development. Tcvetnye Metally (Non-Ferrous Metals), 9, 21–23.
• 3. Fedoseev I.V., Barkan M.Sh. 2016. Hydrometallurgical processing development of sulphide coppernickel intermediate products. Tcvetnye Metally (Non-Ferrous Metals), 5, 27–31.
• 4. Haavanlammi L., Karonen J., Rodriges K. 2011. HydroCopper® – Copper production technology development. Tcvetnye Metally (Non-Ferrous Metals), 7, 24–26.
• 5. Khomchenko O.A., Sadovskaia G.I., Bezbrovskii V.L., Smirnov P.V., Tcapakh S.L. 2014. Development and implementation of nickel and cobalt chloride production technology at JSC Kolskaya Mining and Metallurgical Company. Tcvetnye Metally (Non-Ferrous Metals), 9, 81–88.
• 6. Lundstrom M., Aromma J., Forsen O., et al. 2005. Leaching of chalcopyrite in cupric chloride solution. Hydrometallyrgy, 77, 1–2, 89–95.
• 7. Mushkatin L.M., Diachenko V.T. 2009. Problems and prospects for the development of Russian metallurgical facilities of JSC “MMC “Norilsk Nickel” company in the period up to 2020. Tcvetnye Metally (Non-Ferrous Metals), 9, 12–17 (in Russian).
• 8. Schlesinger M.E., King M.J., Sole W.G. 2011. Devenport, Extractive metallurgy of Copper, 5th ed. Oxford, UK.
• 9. Tcapakh S.L., Lutova L.S., Chetvernin A.Iu. 2012. Copper depositional mechanisms from chloride solutions in the presence of elemental sulphur and reducer. Tcvetnye Metally (Non-Ferrous Metals), 4, 26–31 (in Russian).
• 10. Valkamak K., Karonen J. 2013. Outotec’s chloride based process for production of copper cathode from primary copper sulfide concentrates. Proceeding of Copper, Santiago, Chili, 285–295.