Metal Recovery from Wastewater Using Electrodialysis Separation
Abstract
:1. Introduction
2. Methodology and Review Structure
3. Fundamentals of Electrodialysis Processes
3.1. Operational Principle
3.2. Mass Transport Mechanism
4. Application of the Technique
4.1. General Application
4.2. Applications to Wastewater Containing Metals
4.2.1. Single Metal Recovery from Aqueous Effluents
4.2.2. Multiple Metal Recovery from Aqueous Effluents
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Industries | Al | As | Cd | Cr | Cu | Hg | Pb | Ni | Zn | Co | Fe | Mn |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Paper mills | x | x | x | x | x | x | x | |||||
Organic chemistry | x | x | x | x | x | x | x | |||||
Fertilizer | x | x | x | x | x | x | x | x | x | |||
Petroleum refinery | x | x | x | x | x | x | x | x | ||||
Steel works | x | x | x | x | x | x | x | x | x | |||
Aircrafts | x | x | x | x | x | x | x | |||||
Textile mills | x | |||||||||||
Power plants | x | |||||||||||
Pharmaceutical | x | x | x | x | x | x | x | |||||
Engineering | x | x | x | x | x | x | x | |||||
Metal smelters | x | |||||||||||
Electroplating | x | x | x | |||||||||
Mining | x | |||||||||||
Ferromanganese production | x | x |
Research Questions | |
---|---|
Q1 | What are the fundamentals of electrodialysis? |
Q2 | Can electrodialysis be used to treat wastewater? |
Q3 | Is electrodialysis used to separate metals from industrial wastewater? |
Database (2008–2023) | Electrodialysis and Metals | Electrodialysis and Metals and Wastewater | Electrodialysis and Metals and Wastewater and Recovery |
---|---|---|---|
Scopus | 676 | 239 | 111 |
Web of Science | 648 | 185 | 111 |
Sciencedirect | 227 | 80 | 44 |
Metal | Sources | Recovery (%) | Time | Max V | Current Density (mA cm−2) | Energy (kWh/g) | Feed | pH | Membrane | Ref. |
---|---|---|---|---|---|---|---|---|---|---|
As | Copper slag | 96.50 | 45 h | 9 | 3 | - | - | - | BPMs | [40] |
As | Geothermal water | 91 As(III) 98 As(V) | 60 min | 25 | - | - | 5 mg/L As(III) 60 mg/L As(V) | 8 | CMB and AHA | [41] |
Cd | Phosphate ore | 84.30 | 24 h | 8 | 10 | - | 50 mL 0.5 M Acetic acid + 2 g phosphate ore | 4.5 | CEM and AEM | [42] |
Cr | Chromite ore | 82 | 350 h | 5 | 3 | 0.395 | 50 mL water NaNO3 + 50 g solid | 13.5 | BPMs | [43] |
Cr | Aqueous solution | 87.8 Cr(III) | 24 h | 4 | 0.5 | 0.73 | 5 g/L Na2SO4 | 12 | BPM, CEM and AEM | [44] |
Cr | Chromium slag | 70.6 Cr(VI) | 300 h | - | 3 | - | 50 mL water + 50 g solid | - | BPMs | [45] |
Cu | Electroplating sludge | 96.4 | 5 h | - | 50 | 5.3 | 4 g/L Cu2+ | 0.5 | BPM, CEM, AEM | [46] |
Cu | Pregnant leaching solutions | 99.2 | 5 h | 2.5 | 8 | 2.11 | 2.5 g/L Cu2+ | - | - | [47] |
Ni | Electroless plating bath | 82.34 | 3 h | - | 3.5 | 0.0182 | 325 mg/L Ni2+ | 3 | AEM | [48] |
Ni | Electroplating sludge | 94 | 28 h | - | 20 | - | S/L ratio 1:15 | - | BPM and CEM | [49] |
Pb | Lead battery manufacture | 75 | 4 h | 40 | - | 7 kWh/m3 | 5 mg/L Pb2+ 1000 mg/L SO4− | - | AEM: PC SA CEM: PC SK | [50] |
Zn | Electroplating waste | 86.6 | 60 min | - | 2.5 | - | 0.748 M ZnSO4·7H2O + Citric acid | 4 | CMH-AMH Ralex membranes | [51] |
Li | Spent LIB leachate | 63.91 | 3 h | 15 | - | - | 7 | - | [52] |
Metal | Sources | Recovery (%) | Time | Max V | Current Density (mA cm−2) | Energy | Feed | Stage | Membrane | Ref |
---|---|---|---|---|---|---|---|---|---|---|
Cr(VI) Ni | Industrial effluent | 97.9 97.1 | 90 min | 25 | - | 38.57 Wh/L | 50 mg/L 50 mg/L | 1 | Ionac MC 3470 Ionac MA 3475 | [55] |
Fe Ni Cu | Printed circuit boards | - | 50 min | 30 | 50 | - | - | 1 | PC Acid 60 (PCCell GmbH)CMH RALEX® (MEGA | [56] |
Co Zn | Sulfuric acid solution | 93 100 | 5 h | - | 5 | - | 0.01 M 0.01 M | 1 | MK-40 CEM MK-40 AEM | [57] |
As(III) Se(IV) Se(VI) | Brackish water | 58 80 80 | - | 25 | - | - | 50–1000 µg/L | 1 | - | [58] |
Cu Ni | Electroplating wastewater | 90.7 90.2 | 25 min | 12 | 22.5 | - | 22.3 mg/L 24.4 mg/L | 1 | AMX Astom CMX Astom | [59] |
Ni Co Li Mn | Lithium-ion battery leaching solution | 99.8 87.3 99 99 | 180 min | 18 | - | 9.65 kWh/mol 15.3 kWh/mol - - | 0.01 M 0.003 M 0.003 M 0.003 M | 3 | Neosepta AMXNeosepta CMXPCA PC 400D | [60] |
Li Co | Lithium-ion battery leaching solution | 66 33 | 144 h | - | 1 | - | 1.75 g LiCoO2 350 mL 0.1 M HCl | 1 | Neosepta CMX | [61] |
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Share and Cite
Cerrillo-Gonzalez, M.d.M.; Villen-Guzman, M.; Rodriguez-Maroto, J.M.; Paz-Garcia, J.M. Metal Recovery from Wastewater Using Electrodialysis Separation. Metals 2024, 14, 38. https://doi.org/10.3390/met14010038
Cerrillo-Gonzalez MdM, Villen-Guzman M, Rodriguez-Maroto JM, Paz-Garcia JM. Metal Recovery from Wastewater Using Electrodialysis Separation. Metals. 2024; 14(1):38. https://doi.org/10.3390/met14010038
Chicago/Turabian StyleCerrillo-Gonzalez, Maria del Mar, Maria Villen-Guzman, Jose Miguel Rodriguez-Maroto, and Juan Manuel Paz-Garcia. 2024. "Metal Recovery from Wastewater Using Electrodialysis Separation" Metals 14, no. 1: 38. https://doi.org/10.3390/met14010038
APA StyleCerrillo-Gonzalez, M. d. M., Villen-Guzman, M., Rodriguez-Maroto, J. M., & Paz-Garcia, J. M. (2024). Metal Recovery from Wastewater Using Electrodialysis Separation. Metals, 14(1), 38. https://doi.org/10.3390/met14010038