Thermodynamic Phase Conversion Mechanism on Copper–Cobalt Slag Cleaning Process Using Gypsum Wastes as Sulfurizing Agent

A promising copper–cobalt slag cleaning technique has been proposed, involving employing gypsum wastes as a sulfurizing agent to sulfurize copper, cobalt, and iron and enrich a condensed matte from copper–cobalt slag. This work thermodynamically investigated the phase conversion mechanism in the Cu...

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Bibliographic Details
Published in:Journal of sustainable metallurgy 2021-12, Vol.7 (4), p.1643-1653
Main Authors: Li, Yun, Chang, Cong, Jie, Yafei, Jin, Wei, Chen, Yongming, Wan, Xingbang, Tang, Chaobo, Yang, Shenghai
Format: Article
Language:English
Subjects:
Calcium sulfides
Cleaning
Cobalt
Conversion
Copper
Copper converters
Copper mattes
Copper oxides
Copper sulfides
Earth and Environmental Science
Environment
Flash smelting
Gypsum
Iron oxides
Metallic Materials
Research Article
Slag
Sustainable Development
Thermodynamic models
Wastes
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Summary:A promising copper–cobalt slag cleaning technique has been proposed, involving employing gypsum wastes as a sulfurizing agent to sulfurize copper, cobalt, and iron and enrich a condensed matte from copper–cobalt slag. This work thermodynamically investigated the phase conversion mechanism in the Cu 2 O–CoO–Fe 3 O 4 –FeO–CaSO 4 –C system, at the same time, calculated the equilibrium of the “matte–slag–gas.” The results show that CaSO 4 can be selectively reduced to CaS without self-decomposition to CaO and SO 2 . Cu 2 O and CoO lost in slag can be sulfurized by CaS to Cu 2 S and CoS. Fe x O y tended to stay in oxides. Whereas, in the “matte–slag–gas” equilibrium system, a matte containing Cu 2 S, CoS, FeS, Fe, Co, and Cu was obtained. In addition, industrial copper flash smelting slag was used to conduct beach-scale experiments to validate the thermodynamic modeling results and detect the copper and cobalt recovery efficiency. The experimental results reveal that more than 92% copper and 94% cobalt were recovered in matte. The sulfur and calcium in gypsum waste transferred to matte and cleaned slag, respectively. Thus, the values in the slag and gypsum wastes can be recycled simultaneously. Graphical Abstract
ISSN:2199-3823
2199-3831
DOI:10.1007/s40831-021-00432-5