Experimental Investigation and Modeling of Copper Smelting Slags

• Published in: Metallurgical and materials transactions. B, Process metallurgy and materials processing science Vol. 47; no. 5; pp. 2904 - 2918
• Main Authors: Starodub, Konstantin, Kuminova, Yaroslava, Dinsdale, Alan, Cheverikin, Vladimir, Filichkina, Vera, Saynazarov, Abdukahhar, Khvan, Alexandra, Kondratiev, Alex
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.10.2016; Springer Nature B.V
• Subjects: Characterization and Evaluation of Materials; Chemistry; Chemistry and Materials Science; Copper; EXTRACTIVE METALLURGY; MAGNETITE; Materials Science; MATHEMATICAL ANALYSIS; Mathematical models; MATTE; Mattes; MELTING; Metallic Materials; Nanotechnology; Optimization; Slag; Slags; Smelting; Structural Materials; Sulfide compounds; SULFIDES; Surfaces and Interfaces; Thermodynamics; Thin Films; Sulfide Phase; Fayalite; Liquid Slag; Slag Sample; Slag Phase
• ISSN: 1073-5615; 1543-1916
• DOI: 10.1007/s11663-016-0761-3

Effective extraction of copper from sulfide ores requires careful operation of a copper smelter, which in turn depends very much on chemistry of the feed and resulted slag and matte. For example, chemical composition of copper smelting slags has to be in a certain range to ensure that their properties are within specific limits. Disobeying these rules may lead to complications in smelting operation, poor quality of the copper products, and premature shutdown of the copper smelter. In the present paper the microstructure and phase composition of slags from the Almalyk copper flash smelter were investigated experimentally and then modeled thermodynamically to evaluate potential ways of improvement and optimization of the copper smelting process and its products. The slag samples were taken at different stages of the copper smelting process: on slag tapping, after slag transportation to a deposition site, and at the site. Experimental investigation included the XRD, XRF, and SEM techniques, which were also confirmed by the traditional wet chemistry analysis. Thermodynamic modeling was carried out using thermochemical software package MTDATA, which enables thermodynamic and physical properties of the matte, slag, and gas phases to be calculated in a wide range of temperatures, pressures, and chemical compositions. In addition, slag viscosities and corresponding matte settling rates were estimated using the modified Urbain and Utigard–Warczok models, and the Hadamard–Rybczynski equation, respectively. It was found that the copper content in the slags may vary significantly depending on the location of slag sampling. Cu was found to be present as sulfide particles, almost no Cu was found to be dissolved in the slag. Analysis of microstructure and phase composition showed that major phase found in the samples is fayalite, while other phases are complex spinels (based on magnetite), different sulfides, and a glass-like phase. Thermodynamic calculations demonstrated the presence of these phases, their compositions, and optimal ranges of operating conditions. Potential ways of improving the matte grade and optimizing the smelting process were suggested on the basis of the calculations.