Sage Journals: Discover world-class research

Abstract

Flash smelting furnace (FSF) technology by Outokumpu is one of the most widely employed methods for copper smelting. Developing an understanding of the impact of the process parameters on smelting operation through modelling is the key to improve the smelting efficiency. Though several numerical approaches for modelling the FSF have been reported, this paper focuses on a detailed approach of computational fluid dynamics (CFD) modelling which overcomes the limitations of the earlier models by incorporating feed mineralogy and smelting reaction kinetics. The FSF based at Birla Copper, Dahej was modelled considering the reaction shaft and settler freeboard as the domain, where most of the gas-solid phase reactions occur. This model provides an exhaustive information on the FSF operation which aids in visualizing the phenomena occurring inside the furnace. A parametric study was done to validate and demonstrate the impact of various process parameters on smelting.

Keywords

Flash smelting furnace reaction shaft copper smelting CFD model parametric study

Get full access to this article

View all access options for this article.

References

Ariyaratne

WKH

, Manjula

EVPJ

, Ratnayake

, Melaaen

MC.

2018. CFD approaches for modeling gas-solids multiphase flows - a review. In Proceedings of The 9th EUROSIM Congress on Modelling and Simulation, EUROSIM 2016, The 57th SIMS Conference on Simulation and Modelling SIMS 2016; Dec. 2018; Vol. 142, p. 680–686. doi:10.3384/ecp17142680.

Bacedoni

, Moreno-Ventas

, Ríos

2020. Copper flash smelting process balance modeling. Metals (Basel). 10(9):1–19. doi:10.3390/met10091229.

Balladares

, Kelm

, Helle

, Parra

, Araneda

2014. Chemical-mineralogical characterization of copper smelting flue dust. DYNA. 81:11–18.

Calvo

, Mudd

, Valero

2016. Decreasing ore grades in global metallic mining: a theoretical issue or a global reality? Resources. 5(4):36. doi:10.3390/resources5040036.

East

RA.

1998. Principles of Gas–Solid Flows, L-S. Fan and C. Zhu, Cambridge University Press. The Edinburgh Building, Cambridge CB2 2RU, UK. 1998. 557pp. Illustrated. £65. Aeronaut J. 102(1017):406–406. doi:10.1017/S0001924000065192.

Pérez-Fontes

, Pérez-Tello

, Prieto-López

, Brown

, Castillón-Barraza

2007. Thermoanalytical study on the oxidation of sulfide minerals at high temperatures. Min Metall Explor. 24(4):275–283.

Robie

, Waldbaum DR.

1968. Thermodynamic properties of minerals and related substances at 298.15°K (25.0°C) and one atmosphere (1.013 Bars) pressure and at higher temperatures. Geol Surv Bull. 1259. doi:10.3133/B1259.

Solghar

, Abdolzadeh

2015. Thermochemical simulation of flash smelting furnace. Proc Inst Mech Eng Part E J Process Mech Eng. 229(1):11–24. doi:10.1177/0954408913502168.

Solnordal

, Jorgensen

FRA

, Koh

PTL

, Hunt

2006. CFD modelling of the flow and reactions in the Olympic Dam flash furnace smelter reaction shaft. Appl Math Model. 30(11):1310–1325. doi:10.1016/j.apm.2006.03.017.

10.

Taskinen

, Jokilaakso

, Lindberg

, Xia

2020. Modelling copper smelting – the flash smelting plant, process and equipment. Min Proc Extractive Metall. 129(2):207–220. doi:10.1080/25726641.2019.1688904.

11.

Varaksin

AY.

2007. Particle-laden flows past bodies. In: Varaksin

, editor. Turbulent particle-laden gas flows. Berlin: Springer Berlin Heidelberg; p. 127–168. doi:10.1007/978-3-540-68054-3_5.

12.

Vázquez

, Moreno-Ventas

, Raposo

, Palma

, Díaz

MJ.

2020. Kinetic evolution of chalcopyrite thermal degradation under oxidative environment. Min Metall Explor. 37(3):923–932. doi:10.1007/s42461-020-00204-x.

13.

White

, Haywood

, Ranasinghe

, Chen

2015. The development and application of a CFD model of copper flash smelting. In Proceedings of the Eleventh International Conference on CFD in the Minerals and Process Industries, Melbourne, Australia; Dec. 2015; p. 7–9.

14.

Yang

, Chen

, Wang

, Yue

2016. Thermal oxidation kinetics analysis of ferrous sulfide under different heating rates 1. Acta Tech. 61:19–28.

15.

Zhou

, Zhou

, Chen

, Mao

2014. Influence analysis of air flow momentum on concentrate dispersion and combustion in copper flash smelting furnace by CFD simulation. JOM. 66(9):1629–1637. doi:10.1007/s11837-014-1115-8.

16.

Zhuo

, Peng

, Zhiqiang

, Jun

, Jiemin

2012. CFD simulation and performance analysis of CJD burner for intensified flash smelting process. In Heat Transfer Summer Conference; Jul. 2012. American Society of Mechanical Engineers, Vol. 44786, p. 1115–1120.

CFD modelling of copper flash smelting furnace – reaction shaft

Abstract

Keywords

Get full access to this article

References