Sage Journals: Discover world-class research

Abstract

One of the main problems in the design of carbon adsorption circuits for the processing of high silver gold ores is that the commonly used gold adsorption models are unable to replicate the frequently observed displacement of silver on carbon by gold in the first contactors of carbon-in-pulp/carbon-in-leach (CIP/CIL) trains operating with high metal loadings on carbon and high silver gold ratios.

A model has been developed by Curtin University's Gold Technology Group to simulate the competitive co-adsorption of gold and silver by activated carbon. The model utilises multi-component equilibrium isotherms and film-diffusion rate equations to describe the adsorption of gold and silver onto activated carbon. The model has been validated using laboratory and plant data.

Case studies are presented to demonstrate the application of the model for the design of a greenfield project processing a gold/silver ore.

Keywords

Gold silver co-adsorption isotherm kinetics modelling simulation CIL/CIP film diffusion

Get full access to this article

View all access options for this article.

References

Barbetti

, Bax

, Avraamides

2015. Competitive silver/gold and copper/gold CIL modelling developments (Project Report, AMIRA Project P420E: Gold Processing Technology). Curtin University, Western Australian School of Mines.

Bax

, Barbetti

, Staunton

, Avraamides

, Eksteen

JJ.

2016. Characterisation and modelling of the behaviour of gold-silver competitive co-adsorption in CIL/CIP circuits. XXVIII International Mineral Processing Congress Proceedings. 4:2132–2141.

Fleming

, Mezei

, Bourricaudy

, Canizares

, Ashbury

2011. Factors influencing the rate of gold cyanide leaching and adsorption on activated carbon, and their impact on the design of CIL and CIP circuits. Miner Eng. 24(6):484–494. doi: 10.1016/j.mineng.2011.03.021

Fleming

, Nicol

MJ.

1984. The absorption of gold cyanide onto activated carbon. III. Factors influencing the rate of loading and the equilibrium capacity. Journal of the South African Institute Mining and Metallurgy. 84(4):85–93.

Johns

MW.

1987. The simulation of gold adsorption by carbon using a film diffusion model. (Masteŕs Thesis). Retrieved from Wits Institutional Repository on DSpace, http://wiredspace.wits.ac.za/.

Millard

2005. Processing of high-silver gold ores. In: Adams

M.D.

, editor. Advances in Gold Ore Processing. Amsterdam, The Netherlands: Elsevier Science; p. 849–860. chapter 34.

Nicol

FM.J.

, A

, Cromberge

1984. The absorption of gold cyanide onto activated carbon. II. application of the kinetic model to multistage absorption circuits. Journal of the South African Institute Mining and Metallurgy. 84(3):70–78.

Sheindorf

, Rebhun

, Sheintuch

1981. A Freundlich type multicomponent isotherm. J Colloid Interface Sci. 79(1):136–142. doi: 10.1016/0021-9797(81)90056-4

Stewart

2012. Insights from simulation of CIL/CIP circuit Part 1 – model development. Miner Process and Extract Metall (Trans. Inst. Min. Metall. C). 121(4):237–241. doi: 10.1179/1743285512Y.0000000026

10.

Van Deventer

JSJ.

1986. Competitive equilibrium adsorption of metal cyanides on activated carbon. Sep Sci Technol. 21(10):1025–1037. doi: 10.1080/01496398608058394

11.

Wadnerkar

, Tade

, Pareek

, Utikar

RP.

2015. Modeling and optimization of carbon in leach (CIL) circuit for gold recovery. Miner Eng. 83:136–148. doi: 10.1016/j.mineng.2015.09.001