REVISTA MINERÍA 552 | EDICIÓN SEPTIEMBRE 2023

MINERÍA la mejor puerta de acceso al sector minero MINERÍA / SEPTIEMBRE 2023 / EDICIÓN 552 64 Referencias [1]. S.M. Feteris, J.A., Frew, A. Jowett. 1987. Modelling the Effect of Froth Depth in Flotation. International Journal of Mineral Processing, Vol. 20, pp. 121–135. [2]. Hengtong, L., Dongxia, F., Yang, D., Xiaoyong, Z., Yunong, X. 2022. Coarse Particle Flotation Technology and its Application. Conservation and Utilization of Mineral Resources, pp. 129-137. February 2022 [3]. Darabi, H., Koleini, J., Deglonb, D., Rezai, B., Abdollahy, M. 2020. Investigation of Bubble-Particle Attachment, Detachment and Collection Efficiencies in a Mechanical Flotation Cell. Powder Technology (375), pp 109-123. [4]. Miettinen, T., Ralston, J., Fornasiero, D. 2010. The Limits of Fine Particle Flotation. Minerals Engineering (23), pp. 420–437. [5]. Gontijo, C., Fornasiero, D., Ralston, J. 2007. The Limits of Fine and Coarse Particle Flotation. The Canadian Journal of Chemical Engineering. Vol 85, pp. 739-747. [6]. Crawford, R. and J. Ralston. 1988. The Influence of Particle Size and Contact Angle in Mineral Flotation. International Journal of Mineral Processing. Vol 23, 1, pp. 1-24. [7]. Fornasiero, D., Filipov, L. O. 2017. Innovation in the Flotation of Fine and Coarse Particles. Journal of Physics: Conf. Series 879 012002, 2017. [8]. Markovic, Z., Jankovic, A., Tomanec, R. 2008. Effect of Particle Size and Liberation on Flotation of a Low-Grade Porphyry Copper Ore. Journal of Mining and Metallurgy, 44 A (1), pp 24-30. [9]. Hsih, C.S., Wen, S.B. 1994. An Extension of Gaudin Liberation Model for Quantitatively Representing the Effect of Detachment in Liberation. International Journal of Mineral Processing (42), pp. 15-35. [10]. Bakalarz, A. Duchnowska, M., and Luszczkiewicz, A. 2017. Influence of Liberation of Sulphide Minerals on Flotation of Sedimentary Copper Ore. E3S Web of Conferences 18, 01025. [11]. Mc Ivor, R. E., Finch J. 1991. A Guide to Interfacing of Plant Grinding and Flotation Operations. Minerals Engineering, Vol. 4, pp. 9-23. [12]. Dunne, C., Kawatra, K., Young, K. 2019. Mineral Processing and Extractive Metallurgy Handbook. Ore Liberation Analysis. SME. [13]. Grammatikopoulos, T. 2018. High-Definition Mineralogy by QEMSCAN: From Exploration to Processing. SGS Presentation. [14]. Sutherland, D.N. 1989. Batch Flotation Behaviour of Composite Particles. Minerals Engineering, Vol. 2, No 3, pp. 351-367. [15]. Wang, L. Peng, Y., Runge, K., Bradshaw, D. 2015. A review of Entrainment: Mechanisms, Contributing Factors and Modelling in Flotation. Minerals Engineering (70), pp.77–91. [16]. Bahrami, A., Mirmohammadi, M., Ghorbani, Y., KazeFigura 18. Efecto de la remolienda en la recuperación de cobre y oro. Figure 18. Effect of regrinding on copper and gold recovery. [11]. Mc Ivor, R. E., Finch J. 1991. A Guide to Interfacing of Plant Grinding and Flotation Operations. Minerals Engineering, Vol. 4, pp. 9-23. [12]. Dunne, C., Kawatra, K., Young, K. 2019. Mineral Processing and Extractive Metallurgy Handbook. Ore Liberation Analysis. SME. [13]. Grammatikopoulos, T. 2018. High-Definition Mineralogy by QEMSCAN: From Exploration to Processing. SGS Presentation. [14]. Sutherland, D.N. 1989. Batch Flotation Behaviour of Composite Particles. Minerals Engineering, Vol. 2, No 3, pp. 351-367. [15]. Wang, L. Peng, Y., Runge, K., Bradshaw, D. 2015. A review of Entrainment: Mechanisms, Contributing Factors and Modelling in Flotation. Minerals Engineering (70), pp.77–91. [16]. Bahrami, A., Mirmohammadi, M., Ghorbani, Y., Kazemi, F., Abdollahi, M., and Danesh, 2019. A. Process Mineralogy as a Key Factor Affecting the Flotation Kinetics of Copper Sulfide Minerals. International Journal of Minerals, Metallurgy and Materials. Volume 26, Number 4, pp. 430-439. [17]. Tanaka, Y., Miki, H., Pandhe Wisnu Suyantara, G., Aoki, Y., and Hirajima, T. 2021. Mineralogical Prediction on the Flotation Behavior of Copper and Molybdenum Minerals from Blended Cu–Mo Ores in Seawater. MDPI, 11, 869. [18]. Sung-Su Do. 2010. Hydrodynamic Characterization of a Denver Laboratory Flotation Cell. Thesis. Department of Mining, Metals and Materials Engineering. McGiII University, Montreal, Canada. [19]. Shahbazi, B., Rezai, B. 2009. The Effect of Type and Dosage of Frothers on Coarse Particles Flotation. Iran. J. Chem. Chem. Eng. Vol. 28, No. 1, pp. 95-101.

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