Combination process; Copper recovery; Electrodialysis; Electrolysis; Water reuse
Indexed keywords
COMBINATION PROCESS;
COPPER RECOVERY;
EDX ANALYSIS;
EFFLUENT WATERS;
ENERGY CONSUMPTION;
HIGH CONCENTRATION;
LABORATORY SCALE;
LOW CONCENTRATIONS;
OPERATING PARAMETERS;
OPTIMAL CONDITIONS;
SEM;
WATER FLUX;
WATER REUSE;
COPPER;
EFFLUENTS;
ELECTRODIALYSIS;
ELECTROLYSIS;
ENERGY UTILIZATION;
OPTIMIZATION;
RECOVERY;
WASTEWATER;
WASTEWATER TREATMENT;
WATER CONSERVATION;
WATER SUPPLY;
WASTEWATER RECLAMATION;
COPPER;
WATER;
COPPER;
ELECTROKINESIS;
EXPERIMENTAL STUDY;
LABORATORY METHOD;
WASTEWATER;
WATER USE;
ARTICLE;
ELECTRIC POTENTIAL;
ELECTRODIALYSIS;
ELECTROLYSIS;
ELECTROPLATING INDUSTRY;
ENERGY CONSUMPTION;
ROENTGEN SPECTROSCOPY;
SCANNING ELECTRON MICROSCOPY;
WASTE WATER MANAGEMENT;
WASTE WATER RECYCLING;
COPPER;
COPPER SULFATE;
ELECTROLYSIS;
ELECTROPLATING;
EQUIPMENT DESIGN;
MICROSCOPY, ELECTRON, SCANNING;
PERMEABILITY;
TIME FACTORS;
WASTE DISPOSAL, FLUID;
WATER;
WATER POLLUTANTS;
WATER POLLUTANTS, CHEMICAL;
WATER PURIFICATION;
Copper recovery and cyanide oxidation by electrowinning from a spent copper-cyanide electroplating electrolyte
Dutra A.J.B., Rocha G.P., Pombo F.R. Copper recovery and cyanide oxidation by electrowinning from a spent copper-cyanide electroplating electrolyte. J. Hazard. Mater. 2008, 152:648-655.
Rapid recovery of dilute copper from a simulated Cu-SDS solution with low-cost steel wool cathode reactor
Chang S.H., Wang K.S., Hu P.I., Lui I.C. Rapid recovery of dilute copper from a simulated Cu-SDS solution with low-cost steel wool cathode reactor. J. Hazard. Mater. 2008, 163:544-549.
The removal and recovery of cadmium diluted aqueous solutions by biosorption and electrolysis at laboratory scale
Butter T.J., Evison L.M., Hancock I.C., Holland F.S., Matis K.A., Philipson A., Sheikh A.I., Zouboulis A.I. The removal and recovery of cadmium diluted aqueous solutions by biosorption and electrolysis at laboratory scale. Water Res. 1998, 32:400-406.
Selective electrodeposition of metal from simulated waste solutions
Armstrong R.D., Todd M., Atkinson J.W., Scott K. Selective electrodeposition of metal from simulated waste solutions. J. Appl. Electrochem. 1996, 26:379-384.
Recovery of copper powder from copper bleed electrolyte of an Indian copper smelter by electrolysis
Agrawal A., Kumari S., Bagchi D., Kumar V., Pandey B.D. Recovery of copper powder from copper bleed electrolyte of an Indian copper smelter by electrolysis. Miner. Eng. 2007, 20:95-97.
Recovery of nickel powder from copper bleed electrolyte of an Indian copper smelter by electrolysis
Agrawal A., Bagchi D., Kumari S., Kumar V., Pandey B.D. Recovery of nickel powder from copper bleed electrolyte of an Indian copper smelter by electrolysis. Power Technol. 2007, 177:133-139.
Copper and nickel selective recovery by electrowinning from electronic and galvanic industrial solutions
Fornari P., Abbruzzese C. Copper and nickel selective recovery by electrowinning from electronic and galvanic industrial solutions. Hydrometallurgy 1999, 52:209-222.
The recovery of copper and tin from waste tin stripping solution: Part I. Thermodynamic analysis
Buckle R., Roy S. The recovery of copper and tin from waste tin stripping solution: Part I. Thermodynamic analysis. Sep. Purif. Technol. 2008, 62:86-96.
A comparative study on Cu, Cr and As removal from CCA-treated wood waste by dialytic and electrodialytic processes
Velizarova E., Ribeiro A.B., Ottosen L.M. A comparative study on Cu, Cr and As removal from CCA-treated wood waste by dialytic and electrodialytic processes. J. Hazard. Mater. 2002, B94:147-160.
The use of electrodialysis for metal separation and water recovery from CuSO4-H2SO4-Fe solutions
Cifuentes L., Garcia I., Arriagada P., Casas J.M. The use of electrodialysis for metal separation and water recovery from CuSO4-H2SO4-Fe solutions. Sep. Purif. Technol. 2009, 65:105-108.
Separation of copper ions by electrodialysis using Taguchi experimental design
Mohammadi T., Moheb A., Sadrzadeh M., RazmP A. Separation of copper ions by electrodialysis using Taguchi experimental design. Desalination 2004, 169:21-31.
