ArticleName |
Extraction of tungsten from the tin production slags |
Abstract |
Skimmings Tin production depending on the type of raw materials may contain not only residual impurities Tin, but also high concentrations of other metals, such as tungsten. When it reaches extremely high concentrations in the ash, the latter may be used as secondary raw materials. So, according to the content of tungsten slag recycling Tin raw materials containing tungsten, can be more than 12%. With more than half of the total number of tungsten is in the form of scheelite (CaWO4) and the rest is part of the aluminosilicate glass. To extract tungsten from the slag in the production of Tin were offered technology used in processing the raw material tungsten of the first stage: sintering or melting with soda, followed by leaching and a number of other ways including autoclave technology and leaching of nitric acid. They all have a number of disadvantages, the most important of which are: the inability to reach optimal regimes of complex. In this study for extraction of tungsten slag production of Tin was applied previously developed method for the decomposition of Tungsten concentrate. This approach eliminates the disadvantages of the proposed and used in the industry and is the decomposition of tungsten concentrate is carried out at low temperature in the fusible melt-of Na2CO3 – NaNO3. The way is simple technological scheme and using standard equipment. In the present work experiences have shown the ability to extract tungsten in aqueous solution from slag containing tungsten Tin production by low-temperature (600 оС) decomposition in the melt of carbonate-sodium nitrate. |
References |
1. Lebedev I. S., Dyakov V. E., Terebenin A. N. Kompleksnaya metallurgiya olova (Complex metallurgy of tin). Novosibirsk : Novosibirskiy Pisatel, 2004. 548 p. 2. Kablukov V. I., Maslov V. I., Dulepov E. V. Kompleksnoe ispolzovanie mineralnogo syrya — Complex usage of mineral raw materials. 1988. No. 7. p. 52. 3. Varnek V. A., Dyakov V. E., Asanov I. P. et al. Izvestiya vuzov. Tsvetnaya metallurgiya — Russian Journal of Non-Ferrous Metals. 1998. No. 2. p. 6. 4. Maslenitskiy N. N., Drachev N. L., Boyko A. V. et al. Uspekhi i dostizheniya Nalchikskogo gidrometallurgicheskogo zavoda (Successes and achievements of Nalchik Hydrometallurgical Plant). Moscow : Central Scientific and Research Institute of Economics and Information of Non-ferrous metallurgy, 1992. p. 72. 5. Zelikman A. N., Nikitina L. S. Volfram (Tungsten). Moscow : Metallurgiya, 1978. 272 p. 6. Zelikman A. N., Korshunov B. G. Metallurgiya redkikh metallov (Metallurgy of rare metals). Moscow : Metallurgiya, 1991. 432 p. 7. Avvakumov E. G. Mekhanicheskie metody aktivatsii khimicheskikh protsessov (Mechanic methods of activation of chemical processes). Novosibirsk : Nauka, 1986. 304 p. 8. Zelikman A. N., Medvedev A. S., Rakova N. N. Tsvetnye Metally — Non-ferrous metals. 1986. No. 4. p. 61. 9. Medvedev A. S. Nauchnye osnovy protsessov polucheniya redkikh metallov, ikh soedineniy i kompozitov (Scientific basis of obtaining processes of rare metals, their compounds and composites). Moscow : Metallurgiya, 1990. p. 6. 10. Smitells K. J. Volfram (Tungsten). Moscow : Metallurgiya, 1958. 11. Nikiforov K. A., Mokosoev M. V., Zoltoev E. V. et al. Dzhidinskiy rayon : problemy razvitiya i osvoeniya mineralnykh resursov (Dzhidinsk region : problems of development and mastering of mineral resources). Novosibirsk : Nauka, 1984. 12. Atlas of Thermoanalytical Curves (TG, DTG, DTA-curves Measured simultaneously). Under the editorship of Dr. G. Liptay. London, New York, Rheine. Iss. 4. p. 247. 13. Amanzholova L. U., Shoinbaev A. T. Trudy respublikanskoy nauchno-prakticheskoy konferentsii (Proceedings of republican scientific and practical conference). Temirtau, Republic of Kazakhstan, 2005. p. 170. 14. Amanzholova L. U., Kvyatkovskaya M. N., Koshkunova A. Zh. et al. Trudy respublikanskoy nauchno-prakticheskoy konferentsii “Problemy i perspektivy razvitiya Pribalkhashya” (Proceedings of republican scientific and practical conference “Problems and development prospects of Pribalkhashye”). Balkhash, Republic of Kazakhstan, 2007. p. 77. 15. Amanzholova L. U. Azotnokisloe razlozhenie sheelitovykh kontsentratov i razrabotka tekhnologii polucheniya tovarnoy produktsii : avtoreferat ... kandidata tekhnicheskikh nauk (Nitric acid decomposition of scheelite concentrates and development of obtaining technology of marketable products : thesis of inauguration of Dissertation ... of Candidate of Engineering Sciences). Almaty : Institute of Comprehensive Exploitation of Mineral Resources, 2010. 18 p. 16. Kopylov N. I., Kaminskiy Yu. D., Polugrudov A. V. Zhurnal neorganicheskoy khimii – Russian Journal of Inorganic Chemistry. 1998. Vol. 43, No. 12. p. 2086. 17. Kaminskiy Yu. D., Polugrudov A. V., Kopylov N. I. et al. Izvestiya vuzov. Tsvetnaya metallurgiya — Russian Journal of Non-Ferrous Metals. 1996. No. 4. p. 16. 18. Medvedev A. S., Polugrudov A. V., Kaminskiy Yu. D. et al. Tsvetnye Metally — Non-ferrous metals. 1997. No. 10. p. 50. 19. Kaminskiy Yu. D., Kopylov N. I. Khimiya v interesakh ustoychivogo razvitiya — Chemistry for Sustainable Development. 2000. Vol. 8, Iss. 3. p. 793. 20. Kaminskiy Yu. D., Kopylov N. I., Polugrudov A. V. Sposob pererabotki volframovogo kontsentrata (Processing method of tungsten concentrate). Patent RF, No. 2094511. Applied : October 26, 1995. Published : October 27, 1997. |