El papel depresor del pH durante la flotación sin colector de mineral de galena
Resumen
La recuperación del mineral de galena (PbS) durante la flotación sin colector, desciende con el incremento del pH y con la disminución del potencial de pulpa Eh (mV) referido al electrodo estándar de hidrogeno. La depresión del PbS, durante la flotación, se atribuye al estado superficial que adquiere en ambientes alcalinos, caracterizada por FTIR, el cual consiste de intensas bandas de enlace de especies covalentes tales como; el ion sulfato libre con una longitud de onda en 1097 cm-1, sulfo óxidos S = O en 1400 cm-1, indicando la oxidación del azufre de la última capa atómica y ion hidroxilo OH- en 1638 cm-1, se forman, además, débiles bandas de absorción de los enlaces Pb – O. Mientras que cuando la recuperación de galena es óptima 75 % w/w, el azufre de la superficie se combina con el metal formando sulfatos coordinados de manera monodentada con tres bandas de absorción, así como enlaces Pb - OH del hidróxido de plomo Pb(OH)2 y enlaces Pb – O, del PbO2.
Descargas
Citas
Worner H K, Mitchell R W. (Editors), Minerals of Broken Hill, Australian Mining & Smelting Limited, Griffin Press, Melbourne, Australia, editors.
Feng Q, Chen J. Electrochemistry of Sulfide Minerals Flotation. Central South University Press, editors.
Sajjad A, Seyed K M, Mahdi G. Chemical and colloidal aspects of collectorless flotation behavior of sulfide and non-sulfide minerals. Advances in Colloid and Interface Science 2015; 225: 203-217.
Rao S R, Finch J A. Base metal oxide flotation using long chain xanthates. Int. J. Miner. Process 2003; 69: 251– 258.
Fuerstenau M C., Misra M, Palmer B R. Xanthate adsorption on selected sulphides in the presence of oxygen. Inter. J. Miner. Process 1980; 29I (1–2): 111-119.
Finkelstein N P, Allsion S A, Lovell V M, Stewart B V. Advances in Interf Pheno. of Particulate/Solution/Gas Systems (Eds. P. Somasundaran and R. B. Grieves). AIChE: New York. 1975; 71(150): 165- 175.
Buckley A N, Hamilton I C, Woods R. Investigation of the surface oxidation of sulphide minerals by linear potential sweep and X-ray photoelectron. In: K. S. E. Forssberg (ed.), Flotation of Sulphide Minerals, Elsevier. Amsterdam 1985; 6: 41- 60.
Xingjie W, Wenqing Q, Fen J, Ruizeng L, Daowei W. Inhibition of galena flotation by humic acid: Identification of the adsorption site for humic acid on moderately oxidized galena surface. Minerals Engineering 2019; 137: 102-107.
Bolin N, Laskowski J. Polysaccharides in flotation of sulphides. Part II. Copper/ lead separation with dextrin and sodium hydroxide. Int. J. Miner. Process. 1991; 33: 235–241.
Bulatovic S, Wyslouzil D M. Selection and evaluation of different depressants systems for flotation of complex sulphide ores, Miner. Eng. 1995; 8 (1–2): 63–76.
Sarquís P E, Aguado J M, Mahamud M M, Dzioba R. Tannins: the organic depressants alternative in selective flotation of sulfides, J. Clean. Prod. 2014; 84 (1): 723–726.
Valdivieso A, Ledesma L A, Cabrera A, Navarro O A. Carboxymethylcellulose (CMC) as PbS depressant in the processing of Pb Cu bulk concentrates. Adsorption and floatability studies. Miner. Eng. 2017; 112: 77–83.
Wang D, Jiao F, Qin W, Wang X. Effect of surface oxidation on the flotation separation of chalcopyrite and galena using sodium humate as depressant. Sep. Sci. Technol. 2017; 53: 961–972.
Kar B, Sahoo H, Rath S S, Das B. Investigations on different starches as depressants for iron ore flotation. Miner. Eng. 2013; 49: 1–6.
Sarquís P E, Menéndez A, Mahamud J, Dzioba R. Tannins: the organic depressants alternative in selective flotation of sulfides. J. Clean. Prod. 2014; 84: 723–726.
Liu Q, Laskowski J S. The role of metal hydroxides at mineral surfaces in dextrin adsorption, II. Chalcopyrite galena separations in the presence of dextrin. Int. J. Miner. Process. 1989; 27: 147–155.
Bo F, Wenpu Z, Yutao G, Tao W, Guodong L, Huihui W, Guichun H. The flotation separation of galena and pyrite using serpentine as depressant. Powder Technology 2019; 342: 486–490.
J. Solana López. Servicio Geológico Mexicano, Fideicomiso de fomento minero. Inventario físico de los recursos minerales del municipio Zimapán, Estado de Hidalgo. 2008
Nakamoto K. Infrared and Raman Spectra of Inorganic and Coordination Compounds., New York, Wiley, editors.
Hug S J. In Situ Fourier Transform Infrared Measurements of Sulfate Adsorption on Hematite in Aqueous Solutions. Journal of Colloid and Interface Science 1997; 188(2): 415-422.
M. Reyes P. (2013) Modificación superficial de mineral de pirita y precipitados de Hierro: comportamiento en medios acuosos y de molienda. UMSNH, editor.
Yuehua H, Wei S, Dianzuo W. Electrochemistry of flotation of sulphide minerals. Tsinghua University Press. Springer, editors.
Sun S, Li B, Wang D. Collectorless flotation of sulphide minerals. J. Cent. South Inst. Min. Metall. 1990; 21(5): 473 – 478.
Fornasiero D, Ralston J. Effect of surface oxide/hydroxide products on the collectorless flotation of copper activated sphalerite. International Journal of Mineral Processing 2006; 78(4): 231-237.
Ekmekçi, Z. and H. Demirel, Effects of galvanic interaction on collectorless flotation behavior of chalcopyrite and pyrite. International journal of mineral processing, 1997. 52(1): p. 31-48.
