Moisture effect on the combustion of a single copper concentrate particle in a flash smelting furnace

E. Hassan Zaim; S. H. Mansouri; A. Arab Solghar

doi:10.1007/s12613-014-0902-0

International Journal of Minerals, Metallurgy, and Materials ›› 2014, Vol. 21 ›› Issue (3) : 251 -258. DOI: 10.1007/s12613-014-0902-0

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Moisture effect on the combustion of a single copper concentrate particle in a flash smelting furnace

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Abstract

A mathematical model has been presented to study the combustion of a single copper concentrate particle with high moisture content. By using the presented model, the effect of particle moisture content on particle temperature, sulfur oxidation, and combustion heat generation has been evaluated. The mineralogical composition of the commonly used concentrate at Khatoonabad flash smelting furnace has been used in this study. It was found that the particle moisture content is removed in the sub-second time range and thus the moisture has marginal impact on the variation of particle temperature and on the reaction rate when the gas temperature is assumed to be constant in the reaction shaft. When a concentrate with high moisture content is charged, the particle size enlargement due to the agglomeration of concentrate particles causes an abrupt fall in the particle reaction rate.

Keywords

flash smelting furnaces / copper smelting / moisture / combustion

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E. Hassan Zaim, S. H. Mansouri, A. Arab Solghar. Moisture effect on the combustion of a single copper concentrate particle in a flash smelting furnace. International Journal of Minerals, Metallurgy, and Materials, 2014, 21(3): 251-258 DOI:10.1007/s12613-014-0902-0

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References

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[1]	Jorgensen FRA. Single-particle combustion of chalcopyrite. Proc. Australas. Inst. Min. Metall., 1983 37

[2]	Otero A, Brimacombe JK, Richards GG. Kinetics of the flash reaction of copper concentrates. Copper 91, 1991 459

[3]	Jorgensen FRA, Moyle FJ, Wadsley MW. Structural changes associated with the ignition of pyrite and chalcopyrite during flash smelting. Process Mineralogy IX: International Symposium on Applied Mineralogy (MAC-ICAM-CAM), Montreal, 1989 323

[4]	Laurila T, Oikari R, Joutsenoja T, Mikkola P, Kilpinen TR, Taskinen P, Hernberg R. Pyrometric temperature and size measurements of chalcopyrite particles during flash oxidation in a laminar flow reactor. Metall. Mater. Trans. B, 2005, 36, 201.

[5]	Jokilaakso AT, Suominen RO, Taskinen P A, Lilius K R. Oxidation of chalcopyrite in simulated suspension smelting. Trans. Inst. Min. Metall. C, 1991, 100, 79

[6]	Chaubal PC, Sohn HY. Intrinsic kinetics of the oxidation of chalcopyrite particles under isothermal and nonisothermal conditions. Metall. Trans. B, 1986, 17(1): 51.

[7]	Sohn HY, Chaubal PC. The ignition and combustion of chalcopyrite concentrate particles under suspension-smelting conditions. Metall. Trans. B, 1993, 24(6): 975.

[8]	Järvi J, Jokilaakso A, Ahokainen T. Mathematical mod modelling of chalcocite oxidation reactions. International Symposium on Computer Applications in Metallurgy and Materials Processing, 1998 19

[9]	Peuraniemi EJ, Jokilaakso A. Reaction sequences in sulphide particle oxidation. EPD Congress 2000 as Held at the 2000 TMS Annual Meeting, 2000 173

[10]	Vaarno J, Järvi J, Ahokainen T, Laurila T, Taskinen P. Development of a mathematical model of flash smelting and converting processes. Third International Conference on CFD in the Mineral and Process Industries, 2003 147

[11]	Chen HR, Mei C, Xie K, Li XF, Zhou J, Wang XH, Ge ZL. Operation optimization of concentrate burner in copcopper flash smelting furnace. Trans. Nonferrous Met. Soc. China, 2004, 14(3): 631

[12]	Chen Z, Wang YX, Zhou J, Liu AM, Mei C. Simulation study of intensified flash smelting process. Copper 2010, 2010 1313

[13]	Choshnova D, Stefanov B. Computer simulation of combustion processes of a sulphide charge. J. Univ. Chem. Technol. Metall., 2010, 45, 437

[14]	Choshnova D, Stefanov B. Structure of a torch formed during melting of copper charge in a furnace Outokumpu. Russ. J. Non Ferrous Met., 2011, 52, 62.