2018 - Sustainable Industrial Processing Summit & Exhibition
4-7 November 2018, Rio Othon Palace, Rio De Janeiro, Brazil
| Characterization Strategies for Metallurgical by-Products: Case Study Jarosite Juergen Antrekowitsch1; 0; Gustav Hanke1; 1UNIVERSITY OF LEOBEN, Leoben, Austria; PAPER: 447/Non-ferrous/Keynote (Oral) SCHEDULED: 11:45/Mon./Pontal (50/2nd) ABSTRACT: Metallurgical treatment of ore concentrates produces high amounts of different by-products. These materials often contain high grades of different metals, but are dumped in many cases as there is actually no method of an economical treatment available. For developing, or adapting a proper process, detailed knowledge of the materials characteristics is needed. The chemical composition is relatively easy to determine using standard analytical methods but can only be seen as a first, very general step. Mineralogical characterization is of prime importance to identify and quantify phases carrying the metals of interest as well as valueless phases. The final aim is to develop a characterization procedure which defines the appropriate analytical methods for specific materials. Actually precipitation- and leach-residues from hydrometallurgical zinc production (jarosite) are in the focus of research at University of Leoben. The material contains different valuables such as zinc, lead, copper and silver. Various methods (XRF, ICP-MS, etc.) have been used for chemical analysis as well as XRD for identification of major phases. Scanning electron microscopy is the tool of choice for identifying minor phases and chemical analysis of single grains. So far, the value of the material has been proven. Further work will focus on quantification of already accomplished results. References: [1] Balladares E, Kelm U, Helle S, Parra R, Araneda E. 2014. Chemical-mineralogical characterization of copper smelting flue dust. Dyna. Volume 81(186). p.11-18. [2] Piatak N M, Seal R R, Hammarstrom J M, Meier A L, Briggs P H. 2003. Geochemical Characterization of Slags, Other Mine Waste, and Their Leachate from the Elizabeth and Ely Mines (Vermont), the Ducktown Mining District (Tennessee), and the Clayton Smelter Site (Idaho). US Geological Survey. Open-File Report 03-260. [3] Rizescu C, Bacinschi Z, Stoian E, Polinescu A. 2010. Characterisation of steel mill electric-arc furnace dust. In: Advances in waste management. 4th WSEAS International Conference on Waste Management, Water Pollution, Indoor Climate (WWAI ‘10). p.139-143. [4] Vereš J, Šepelák V, Hredzák S. 2015. Chemical, mineralogical and morphological characterisation of basic oxygen furnace dust. In: Mineral Processing and Extractive Metallurgy, Volume:124(1), p. 1-8. [5] Jamieson H E, Walker S R, Parsons M B. 2015. Mineralogical characterization of mine waste. In: Applied Geochemistry. Volume 57. P. 58-105. [6] Hanke G, Antrekowitsch J. 2018. Characterisation and pyrometallurgical recycling of jarosite type residues out of zinc primary metallurgy. In: World of Metallurgy – Erzmetall. Volume 71.1. p. 25-30. [7] Pappu A, Saxena M, Asolekar S R. 2006. Jarosite characteristics and its utilization potentials. In: Science of the Total Environment. Volume 359.1. p 232-243. [8] Sinclair R J. The Extractive Metallurgy of Zinc. Victoria (Australia): Australasian Institute of Mining and Metallurgy; 2001. p.31-105. [9] Onuk P, Melcher F, Mertz?Kraus R, Gäbler H E, Goldmann S. 2017. Development of a Matrix?Matched Sphalerite Reference Material (MUL?ZnS?1) for Calibration of In Situ Trace Element Measurements by Laser Ablation?Inductively Coupled Plasma?Mass Spectrometry. In: Geostandards and Geoanalytical Research. Volume 41(2). p. 263-272. [10] Wilson S A, Ridley W I, Koenig A E. 2002. Development of sulfide calibration standards for the laser ablation inductively-coupled plasma mass spectrometry technique. In: Journal of Analytical Atomic Spectrometry. Volume 17(4). p. 406-409. |
