Characterisation of Parameters Influencing the Phase Separation in Copper Solvent Extraction Systems Using Oxime-Type Extractants for the Field Operation

Solvent extraction (SX) is one of the most widely applied hydrometallurgical processes in copper production from oxide ore. As the high-grade ore deposits have been developed and depleted, now only low-grade ore deposits are being developed and are therefore facing obstacles of extreme processing co...

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Published inMetals (Basel ) Vol. 11; no. 11; p. 1785
Main Authors Seo, Sangyun, Lee, Gwang Seop, Kim, Hye Rim, Kim, Jong-Gwan
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.11.2021
Subjects
2-hydroxy-5-nonyl acetophenone oxime (ketoxime)
5-nonylsalicylaldoxime (aldoxime)
Barriers
Behavior
colloidal silica
Copper
Copper ores
copper solvent extraction
Density
Extreme values
flocculant
Gangue
Gravity
Human error
Hydrometallurgy
Impurities
Leaching
Mineral deposits
Oxidation
Parameters
Phase separation
phase separation behaviour
Silicon dioxide
Solvent extraction
Solvent extraction processes
Viscosity
United States > US
South Korea
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Summary:Solvent extraction (SX) is one of the most widely applied hydrometallurgical processes in copper production from oxide ore. As the high-grade ore deposits have been developed and depleted, now only low-grade ore deposits are being developed and are therefore facing obstacles of extreme processing conditions. This results in leaching gangue minerals and requires a more complicated solvent extraction system. Recently, synergistic solvent extraction has been introduced to separate copper from the leached solution with high impurities. However, operational obstacles arise due to the complicated solvent extraction process, including multi-stages of extraction, and using more than one extractant in a single solvent extraction system. The phase separation in solvent extraction is one of the major issues in field operation. A poor phase separation could affect the entire process and eventually cause production loss. Therefore, in this study, the phase separation behaviours were studied in consideration of the field operation. Major parameters considered in the study were the type of diluent, temperature, mixing speed, solution pH and Oxidation Reduction Potential (ORP), and addition of impurities (flocculant and colloidal silica). The phase separation behaviours in the continuous counter-current SX system using a pilot-scale mixer-settler in the above conditions was investigated.
ISSN:2075-4701
2075-4701
DOI:10.3390/met11111785