Combined Electrodialysis and Electrocoagulation as Treatment for Industrial Wastewater Containing Arsenic and Copper

Combined Electrodialysis and Electrocoagulation as Treatment for Industrial Wastewater Containing Arsenic and Copper

In copper smelting processes, acidic effluents are generated that contain inorganic contaminants such as arsenic and copper. Nowadays, the treatment of wastewater is done by physicochemical methods without copper recovery. Electrodialysis is an alternative process that can recover copper. Moreover,...

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Bibliographic Details
Published in:Membranes (Basel) Vol. 13; no. 3; p. 264
Main Authors: Hansen, Henrik K, Gutiérrez, Claudia, Leiva Gonzalez, Jorge, Lazo, Andrea, Hansen, Marcela E, Lazo, Pamela, Ottosen, Lisbeth M, Ortiz, Rodrigo
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 23-02-2023
MDPI
Subjects:
Arsenic
Batch reactors
Contaminants
Copper
copper and arsenic removal
Copper industry
current density
Effluents
Electric currents
Electrocoagulation
Electrodes
Electrodialysis
Industrial wastes
Industrial wastewater
Inorganic contaminants
Mass ratios
Oxidation
Pollutant removal
Purification
Reagents
Sewage
Sludge
Smelters
Stainless steel
Wastewater treatment
Water treatment
Chile
current density
copper and arsenic removal
electrodialysis
electrocoagulation
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Summary:In copper smelting processes, acidic effluents are generated that contain inorganic contaminants such as arsenic and copper. Nowadays, the treatment of wastewater is done by physicochemical methods without copper recovery. Electrodialysis is an alternative process that can recover copper. Moreover, when electrocoagulation is applied to remove arsenic from wastewater, a more stable final sludge of less volume is obtained. The present research studies the application of a combined electrodialysis and electrocoagulation process to (1) recover Cu and (2) precipitate and remove arsenic simultaneously in the same batch reactor, using synthetic wastewater that simulates wastewater from a copper smelter. Copper and arsenic could be removed and separated by the electrodialysis part, and the electrocoagulation of arsenic was verified. With electrodialysis, the arsenic and copper removals were 67% and 100%, respectively, while 82% of the arsenic arriving at the electrocoagulation part of the cell could be precipitated and removed by this process. Initial concentrations were around 815 mg L Cu and 7700 mg L As. The optimal current was found to be 1.36 A due to the shorter treatment times necessary to get removal percentages, recovery percentages and energy/removed copper mass ratios in the same ranges as the values achieved with a current of 1.02 A. In summary, the combined process is a promising tool for simultaneous copper recovery and arsenic removal.
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ISSN:2077-0375
2077-0375
DOI:10.3390/membranes13030264