Abstract
The pyrometallurgical processes for primary copper production have only off-line and time-demanding analytical techniques to characterize the in and out streams of the smelting and converting steps. Since these processes are highly exothermic, relevant process information could potentially be obtained from the visible and near-infrared radiation emitted to the environment. In this work, we apply spectral sensing and multivariate data analysis methodologies to identify and classify copper and iron sulfide minerals present in the blend from spectra measured during their combustion in a laboratory drop-tube setup, in which chemical reactions that take place in flash smelting furnaces can be reproduced. Controlled combustion experiments were conducted with two industrial concentrates and with high-grade mineral species as well, with a focus on pyrite and chalcopyrite. Exploratory analysis by means of Principal Component Analysis (PCA) applied on the spectral data depicted high correlation features among species with similar elemental compositions. Classification algorithms were tested on the spectral data, and a classification accuracy of 95.3% with a support vector machine (SVM) algorithm with a Gaussian kernel was achieved. The results obtained by the described procedures are shown to be very promising as a first step in the development of a predictive and analytical tool in search of fitting the current need for real-time control of pyrometallurgical processes.
Highlights
The flash smelting process was developed in Finland in the late 1940s, and it has become one of the main copper production technologies in the world, given its high production and fast implementation capabilities at industrial and commercial scales
Mineral oxidation at high temperatures is the core in such processes, since it involves complex energy and mass transfer mechanisms, as well as gaseous and intermediate species production
The research related to this combustion process has tried to uncover the chemical and physical behaviors of those mineral particles present in copper concentrates in flash smelting conditions [4,5,6]
Summary
The flash smelting process was developed in Finland in the late 1940s, and it has become one of the main copper production technologies in the world, given its high production and fast implementation capabilities at industrial and commercial scales. This process has attracted the interest of researchers for more than five decades, from the first works that allowed understanding the mineralogy and combustion kinetics of specific mineral particles, to modern works focused on the development and application of computer fluid dynamics (CFD) models [1,2,3]. Optical information at specific wavelengths has been used to describe the oxidation of the main sulfide minerals such as chalcopyrite (CuFeS2 ) and pyrite (FeS2 ) [4,6], to estimate ignition temperatures [8,9,10], single particle temperature [4,6], and to model particle size distributions [11]
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