Mathematical model for coupled reactive flow and solute transport during heap bioleaching of copper sulfide

Sheng-hua Yin; Ai-xiang Wu; Xi-wen Li; Yi-ming Wang

doi:10.1007/s11771-011-0858-4

Journal of Central South University ›› 2011, Vol. 18 ›› Issue (5) : 1434 -1440. DOI: 10.1007/s11771-011-0858-4

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Mathematical model for coupled reactive flow and solute transport during heap bioleaching of copper sulfide

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Abstract

Based on the momentum and mass conservation equations, a comprehensive model of heap bioleaching process is developed to investigate the interaction between chemical reactions, solution flow, gas flow, and solute transport within the leaching system. The governing equations are solved numerically using the COMSOL Multiphysics software for the coupled reactive flow and solute transport at micro-scale, meso-scale and macro-scale levels. At or near the surface of ore particle, the acid concentration is relatively higher than that in the central area, while the concentration gradient decreases after 72 d of leaching. The flow simulation between ore particles by combining X-ray CT technology shows that the highest velocity in narrow pore reaches 0.375 m/s. The air velocity within the dump shows that the velocity near the top and side surface is relatively high, which leads to the high oxygen concentration in that area. The coupled heat transfer and liquid flow process shows that the solution can act as an effective remover from the heap, dropping the highest temperature from 60 to 38 °C. The reagent transfer coupled with solution flow is also analyzed. The results obtained allow us to obtain a better understanding of the fundamental physical phenomenon of the bioleaching process.

Keywords

copper sulphide / heap bioleaching / leaching reaction / solution flow / solute transport

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Sheng-hua Yin, Ai-xiang Wu, Xi-wen Li, Yi-ming Wang. Mathematical model for coupled reactive flow and solute transport during heap bioleaching of copper sulfide. Journal of Central South University, 2011, 18(5): 1434-1440 DOI:10.1007/s11771-011-0858-4

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References

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[1]	MousaviS. M., JafariA., YaghmaeiS., VossoughiM., SarkomaaP.. Computer simulation of fluid motion in a porous bed using a volume of fluid method: Application in heap leaching [J]. Minerals Engineering, 2006, 19(10): 1077-1083

[2]	PradhanN., NathsarmaK. C., SrinivasaK., SuklaL. B., MishraB. K.. Heap bioleaching of chalcopyrite: A review [J]. Minerals Engineering, 2007, 21(5): 355-365

[3]	WatlingH. R.. The bioleaching of sulphide minerals with emphasis on copper sulphides—A review [J]. Hydrometallurgy, 2006, 84(1/2): 81-108

[4]	WuA.-x., YinS.-h., WangH.-j., QinW.-q., QiuG.-zhou.. Technological assessment of a mining-waste dump at the Dexing copper mine, China, for possible conversion to an in situ bioleaching operation [J]. Bioresource Technology, 2009, 100(6): 1931-1936

[5]	ThielR., SmithM. E.. State of the practice review of heap leach pad design issues [J]. Geotextiles and Geomembranes, 2004, 22(6): 555-568

[6]	BennettC. R., McbrideD., CrossM., GebhardtJ. E., TaylorD. A.. Simulation technology to support base metal ore heap leaching [J]. Mineral Processing and Extractive Metallurgy, 2006, 115(1): 41-48

[7]	BartlettR. W.. Simulation of ore heap leaching using deterministic models [J]. Hydrometallurgy, 1992, 29(3): 231-260

[8]	PaulB. C., SohnH. Y., McCarterM. K.. Model for ferric sulfate leaching of copper ores containing a variety of sulfide minerals. Part 1: Modeling uniform size ore fragments [J]. Metallurgical Transactions B, 1992, 23(5): 537-548

[9]	PantelisG., RitchieA. I. M., StepanyantsY. A.. A conceptual model for the description of oxidation and transport processes in sulphidic waste rock dumps [J]. Applied Mathematical Modelling, 2002, 26(7): 751-770

[10]	BouffardS. C., DixonD. G.. Investigative study into the hydrodynamics of heap leaching processes [J]. Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science, 2001, 32(5): 763-776

[11]	CasasJ. M., MartinezJ., MorenoL., VargosT.. Bioleaching model of a copper-sulphide ore bed in heap and dump configurations [J]. Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science, 1998, 29(4): 899-909

[12]	DixonD. G.. Analysis of heat conservation during copper sulphide heap leaching [J]. Hydrometallurgy, 2000, 58(1): 27-41

[13]	de Andrade LimaL. R. P.. A mathematical model for isothermal heap and column leaching [J]. Brazilian Journal of Chemical Engineering, 2004, 21(3): 435-447

[14]	CariagaE., ConchaF., SepulvedaM.. Flow through porous media with applications to heap leaching of copper ores [J]. Chemical Engineering Journal, 2005, 111(2/3): 151-165

[15]	CrossM., BennettC. R., CroftT. N., McbrideD., GebhardtJ. E.. Computational modeling of reactive multi-phase flows in porous media: Applications to metals extraction and environmental recovery processes [J]. Minerals Engineering, 2006, 19(10): 1098-1108

[16]	SheikhzadehG. A., MehrabianM. A., MansouriS. H., SarrafiA.. Computational modelling of unsaturated flow of liquid in heap leaching-Using the results of column tests to calibrate the model [J]. International Journal of Heat and Mass Transfer, 2005, 48(2): 279-292

[17]	SidbornM., CasasJ., MartinezJ., MorenoL.. Two-dimensional dynamic model of a copper sulphide ore bed [J]. Hydrometallurgy, 2003, 71(1–2): 67-74

[18]	WuA.-x., LiuJ.-z., TangL.-yan.. Simulation of coupled flow in reaction-deformation with mass transfer in heap leaching processes [J]. Applied Mathematics and Mechanics, 2007, 28(3): 327-335

[19]	WuA.-x., YinS.-h., QinW.-q., LiuJ.-s., QiuG.-zhou.. The effect of preferential flow on extraction and surface morphology of copper sulphides during heap leaching [J]. Hydrometallurgy, 2009, 95(1/2): 76-81