Название |
Peculiarities of sphalerite flotation by butyl potassium xanthate and sodium dithiophosphate in lime medium |
Реферат |
This paper shows the results of froth flotation of sphalerite samples in alkaline medium using sulfhydryl collectors in a mechanical flotation cell. Sphalerite coarseness was –71+44 μm. Influence of various factors (pH, collector expenditure and flotation time) on sphalerite recovery was studied. Potassium butyl xanthate and sodium dibutyldithiophosphate were used as collectors for sphalerite flotation; lime was used as medium regulator; and methylisobutylcarbinol was used as a frother agent. There was investigated the kinetics of sphalerite flotation using sodium dithiophosphate and potassium xanthate at pH = 8–12, depending on collector expenditure. Flotation results were analyzed with following definition of sphalerite distribution by fast, medium and slow floatable fraсtions. Investigation results defined the change regularities of sphalerite recovery in froth product, depending on the type of collector expenditure and pH. Experiments have shown that better sphalerite flotation by potassium butyl xanthate was observed at pH = 8 while the flotation by sodium dibutyldithiophosphate was at pH = 10. There was a lowest possible level of flotation recovery of sphalerite at pH = 12 for both collectors. The difference in kinetic behavior of sphalerite flotation by butyl potassium xanthate and sodium dithiophosphate was revealed, concluded in different values of slow, medium and fast floatable fraction parts, depending on collector expenditure in the liquid pulp phase at pH equal to 8 and 10. The part of fast and medium floatable fractions during sodium dibutyldithiophosphate flotation at pH=10 was higher than the one during potassium butyl xanthate flotation. Thus the type of collector and its expenditure affected flotation kinetic behavior at pH equal to 8 and 10. It should be noted that depression of sphalerite flotation in strong alkaline medium was obtained by both collectors. Sphalerite recovery in the froth product at pH = 12 was low, and flotation kinetic was limited by low floatable fractions (0.9). This work was carried out with the financial support of the Ministry of Education and Science of Russian Federation according to the Federal Target Program “Investigations and developments of the priority ways of development of scientific-technological complex of Russia for 2014–2020”, project RFMEFI57514X0085. |
Библиографический список |
1. Bogdanov O. S., Maksimov I. I., Podnek A. K. et al. Teoriya i tekhnologiya flotatsii rud (Theory and technology of ore flotation). Moscow : Nedra, 1990. 363 p. 2. Abramov A. A. Flotatsionnye metody obogashcheniya (Flotation methods of concentration). Moscow : Moscow State Mining University, 2008. 710 p. 3. Bocharov V. A., Ignatkina V. A. Tekhnologiya obogashcheniya poleznykh iskopaemykh : v 2 tomakh. Tom 1: Mineralno-syrevaya baza poleznykh iskopaemykh. Obogashchenie rud tsvetnykh metallov, rud i rossypey redkikh metallov (Mineral concentration technology : in 2 volumes. Volume 1: Mineral resource base. Concentration of ores of non-ferrous metals, ores and placers of rare metals). Moscow : “Ore and Metals” Publishing House, 2007. 472 p. 4. Bocharov V. A., Ryskin M. Ya. Tekhnologiya konditsionirovaniya i selektivnoy flotatsii rud tsvetnykh metallov (Technology of conditioning and selective flotation of non-ferrous metal ores). Moscow : Nedra, 1993. 305 p. 5. Kislyakov L. D., Kozlov G. V., Nagirnyak F. I. et al. Flotatsiya mednotsinkovykh i mednykh rud Urala (Flotation of copper-zinc and copper ores of Urals). Moscow : Nedra, 1966. 336 p. 6. Chandra A. P., Gerson A. R. A review of the fundamental studies of the copper activation mechanisms for selective flotation of the sulfide minerals, sphalerite and pyrite. Advances in Colloid and Interface Science. 2009. Vol. 145. pp. 97–110. 7. Dichmann T. K., Finch J. A. The role of copper ions in sphalerite-pyrite flotation selectivity. Minerals Engineering. 2001. Vol. 4, iss. 2. pp. 217–225. 8. Laskowski J. S., Liu Q., Zhan Y. Sphalerite activation: flotation and electrokinetic studies. Minerals Engineering. 1997. Vol. 10 (8). pp. 787–802. 9. Yamamoto T. Mechanism of depression of pyrite and sphalerite by sulphite. Complex Sulphide Ores. Jones M. J. (Ed.). London : Institute of Mining and Metallurgy, 1980. pp. 71–78. 10. Shen W. Z., Fornasiero D., Ralston J. Flotation of sphalerite and pyrite in the presence of sodium sulfite. International Journal of Mineral Processing. 2001. Vol. 63, iss. 1, June. pp. 17–28. 11. Misra M., Miller J. D., Song Q. Y. The effect of SO2 in the flotation of sphalerite and chalcopyrite. Developments in Mineral Processing, Flotation of Sulphide Minerals. Forssberg K. S. E. (Ed.). Amsterdam : Elsevier, 1985. pp. 175–196. 12. Chanturiya E. L., Vishkova A. A., Lapshina G. A., Amplieva E. E. K voprosu o vzaimosvyazi elektrokhimicheskikh i flotatsionnykh svoystv pirita zolotosoderzhashchikh kolchedannykh rud s ego sostavom i vnutrenney strukturoy (To the question about the interconnection of electrochemical and flotation properties of pyrite of gold-bearing pyritic ores with its content and inner structure). Gornyy informatsionno-analiticheskiy byulleten = Mining Informational and Analytical Bulletin. 2009. No. 14, Special issue. pp. 215–228. 13. Goryachev B. E., Nikolaev A. A. Printsipy postroeniya kineticheskikh «ionnykh» modeley formirovaniya sorbtsionnogo sloya sobiratelya na poverkhnosti sulfidov tsvetnykh tyazhelykh metallov (Principles of kinetic “ion” modeling of adsorptive collector layer at the surface of nonferrous heavy metal sulfides). Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh = Journal of Mining Science. 2013. No. 3. pp. 169–178. 14. Rubinshteyn Yu. B. Kinetika flotatsii (Flotation kinetics). Moscow : Nedra, 1980. 375 p. 15. Goryachev B. E., Naing Linoo, Nikolaev A. A. Osobennosti flotatsii pirita odnogo iz medno-tsinkovykh mestorozhdeniy Uralskogo regiona butilovym ksantogenatom kaliya i ditiofosfatom natriya (Peculiarities of flotation of pyrite of one of copper-zinc deposits of Ural region by potassium butyl xanthate and sodum dithiophosphate). Tsvetnye Metally = Non-ferrous metals. 2014. No. 6. pp. 16–22. 16. Goryachev B. E., Naing Linoo, Nikolaev A. A., Polyakova Yu. N. Osobennosti vliyaniya kationov medi, tsinka i zheleza na flotiruemost pirita odnogo iz medno-tsinkovykh mestorozhdeniy Urala (Peculiarities of influence of copper, zinc and iron cations on flotability of pyrite of one of copper-zinc Ural deposits). Tsvetnye Metally = Non-ferrous metals. 2015. No. 1. pp. 12–17. 17. Nikolaev A. A., So Tu, Goryachev B. E. Issledovanie zakonomernostey kinetiki flotatsii neaktivirovannogo sfalerita kompozitsiyami sulfgidrilnykh sobirateley flotometricheskim metodom (Investigation of regularities of kinetics of non-activated sphalerite flotation by sulfhydryl collector compositions using flotometric method). Gornyy informatsionno-analiticheskiy byulleten = Mining Informational and Analytical Bulletin. 2015. No. 6. pp. 86–95. 18. Ryaboy V. I., Shenderovich V. A., Kretov V. P. Primenenie aeroflotov pri flotatsii rud (Application of aeroflots during ore flotation). Obogashchenie Rud = Mineral processing. 2005. No. 6. pp. 43–44. 19. Ryaboy V. I., Kretov V. P., Smirnova V. Yu. Ispolzovanie dialkilditiofosfatov pri flotatsii sulfidnykh rud (Dialkydithiophosphate use during sulfide ore flotation). IX Kongress obogatiteley stran SNG : sbornik materialov. Tom II (The IX Congress of dressers in the CIS countries : collection of materials. Volume II). Moscow : MISiS, 2013. pp. 496–497. 20. Bocharov V. A., Ignatkina V. A. Osobennosti ispolzovaniya kompozitsiy sobirateley v tekhnologii selektivnoy flotatsii piritnykh rud tsvetnykh metallov (Peculiarities of use of collector compositions in the technology of selective flotation of pyrite ores of non-ferrous metals). Gornyy informatsionnoanaliticheskiy byulleten = Mining Informational and Analytical Bulletin. 2012. No. 8. pp. 168–171. 21. Ignatkina V. A., Bocharov V. A., Sabanova M. N., Orekhova N. N. Selektivnyy reagentnyy rezhim flotatsii kolchedannoy medno-tsinkovoy rudy Yubileynogo mestorozhdeniya s ispolzovaniem sochetaniya sulfgidrilnykh sobirateley (Selective reagent mode of flotation of pyrite copper-zinc ore of Yubileynoe deposit using the combination of sulfhydryl collectors). Tsvetnye Metally = Non-ferrous metals. 2012. No. 2. pp. 16–20. 22. Chanturiya V. A. Sovremennoe sostoyanie i osnovnye napravleniya razvitiya flotatsii (Modern content and basic ways of flotation development). Obogashchenie Rud = Mineral processing. 2005. No. 6. 23. Mashevskiy G. N., Petrov A. V., Romanenko S. A., Sufyanov F. S., Balmanova A. Zh. Novyy podkhod k regulirovaniyu flotatsionnogo protsessa selektivnogo otdeleniya sulfidnykh mineralov ot pirita v izvestkovoy srede (A new approach to regulating the process of sulfide minerals selective flotation separation from pyrite in lime medium). Obogashchenie Rud = Mineral processing. 2012. No. 1. 24. Ryaboy V. I., Aygelov A. T. Promyshlennyy opyt organizatsii proizvodstva i primeneniya flotoreagentov v usloviyakh gorno-obogatitelnogo predpriyatiya (Industrial experience in organization of production and application of flotation reagents under the condition of an ore-dressing facility). Obogashchenie Rud = Mineral processing. 2009. No. 2. 25. Ignatkina V. A., Bocharov V. A. Osobennosti flotatsii raznovidnostey sulfidov medi i sfalerita kolchedannykh rud (Features of flotation of various copper sulfides and sphalerite contained in sulfide ore). Gornyi Zhurnal = Mining Journal. 2014. No. 12. |