Advances in Chemical Engineering and Science
Vol.09 No.01(2019), Article ID:90271,18 pages
10.4236/aces.2019.91009
A Review of Promising Electrocoagulation Technology for the Treatment of Wastewater
Mervat A. Sadik
October High Institute for Engineering & Technology, Giza, Egypt
Copyright © 2019 by author(s) and Scientific Research Publishing Inc.
This work is licensed under the Creative Commons Attribution International License (CC BY 4.0).
http://creativecommons.org/licenses/by/4.0/
Received: November 5, 2018; Accepted: January 27, 2019; Published: January 30, 2019
ABSTRACT
A review of the literature published on topics interrelated to electrochemical treatment within wastewater by using sacrificial anodes was presented. Electrocoagulation (EC) is a technique used for water and has a great ability on various wastewater treatments, industrial processed water, and medical treatment. It has potential in removing various pollutants such as chemical oxygen demand turbidity, ammonia, color, and suspended solid. One of the most necessities industries is Textile industries which release large volumes of wastewater that contains different dyes. Azo dyes contain strong N = N bond which is not easily broken by conventional methods. The discharge of this type of wastewater to natural watercourse can pose serious environmental impacts to aquatic life. Electrocoagulation (EC) method depends on several factors as electrode material, current density, operation time and PH. The review describes, discusses and compares the types of that electrode influencing the EC process in various wastewater and leachate. Both operating costs and electrical energy consumption values were found to vary greatly depending on the type of electrodes material and solution being treated.
Keywords:
Wastewater Treatment, Electrochemical Treatment, Electrocoagulation, Sacrificial Anodes
1. Introduction
There are two main significances of wastewater treatment, one is defending the environment and the other one is sustaining fresh water resources. With the ever increasing standard of drinking water supply and the stringent environmental regulations regarding the wastewater discharge, electrochemical technologies have retrieved their importance worldwide during the past two decades. Electrocoagulation-electro flotation (ECF) technology is a treatment process of applying electrical current to treatment and flocculating contaminants devoid of having to add coagulations. Electrocoagulation has olden times as a water treatment technology having been working to remove a varied of pollutants. The textile industry wastewater varies extensively in terms of composition due to the regular impurity in fibers and the chemicals used in different processes. Various types of dyes are produced worldwide and are used in various industries; the author indicated in Table 1 some examples in recent applications of Electrocoagulation in treatment of water and wastewater, such as textile, cosmetic,
Table 1. Examples in recent Applications of Electrocoagulation in Treatment of Water and Wastewater.
paper, leather, pharmaceutical and food industry [1] [2] and [3] . Lately, electrocoagulation (EC) has been playing noticeable role in the drinking water treatment because it affords some substantial advantages such as quite compact, easy operation, automation, no chemical additives, and reduced amount of slug. Wastewater was considered for COD, Biochemical Oxygen Demand (BOD), pH, conductivity, chlorides, turbidity and color [4] , and also in medical waste water [5] [6] . The effect of operating parameters such as current density, electrolysis time, and initial COD concentration was studied. Besides, energy and electrode consumption were examined. Electrocoagulation involves electrodes that are arranged in pairs―anodes and cathodes, whereby anodes (aluminum or iron electrodes) corrode to release active coagulants into solution. These hydroxides/polyhydroxides/polyhydroxy-metallic compounds have a strong affinity treatment of wastewater. Electrocoagulation technology is an alternative method to classic chemical coagulation that involves the use of alum (aluminum sulfate), ferric chloride (FeCl3), or ferrous chloride. EC is talented of reducing chemicals by reason of the fact that the electrodes afford the coagulant in situ. However, sulfate (Fe2SO4) can be very costly depending on the volume of water treated. The coagulant performed a similar function as the electrodes, neutralizing the charge of the particulates, thus allowed them to collect and settle at the bottom of the tank. In addition, electrocoagulation-flotation is talented of reducing waste production, time and electrical energy consumption for wastewater [7] [8] [9] while [10] and [11] enhanced electrocoagulation device for treating various types of industrial wastewater and observed how electrocoagulation-flotation(ECF) reactor can be effective, according to wastewater type, pH, current density and type of metal electrodes (aluminum, steel). Among all the various technologies available, electrolysis is one of the best. The EC offers a substitute to use metal salt or polymer or polyelectrolyte addition so as to destabilize emulsion and suspension. The EC technology has been employed to remove metal, colloidal solid, particle, and soluble inorganic pollutant from the water/wastewater by applying highly charged polymeric metal hydroxide species. These species neutralize the electrostatic charge on suspended solids to facilitate accumulation or coagulation and the resultant separation from aqueous medium.
2. Electrocoagulation Process
The (EC) technology includes coagulation and precipitation of contaminants by a direct current electrolytic process followed by the separation of flocculent (settling or flotation) with or without the addition of coagulation-inducing chemicals. The water is pumped through a unit which consists of pairs of metal sheets called electrodes that are arranged. A direct current electric field is applied to the electrodes to induce the electrochemical reactions needed to achieve the coagulation. Coagulation technology induces Coagulation and precipitation of contaminants. In an EC process the coagulated ions a produced in “in situ” and it involves three successive stages.
1) Information of coagulants by electrolytic oxidation of the sacrificial electrodes.
2) Destabilization of the contaminants, particulates suspension and breaking of emulsions.
3) Aggregation of the destabilized phase to form flocculent.
Electrodes which produce coagulants into water are made from either iron or aluminium. Iron and aluminium cations dissolve from the anodes according to Equation (1) and Equation (2).
Fe(s) → Fen+(aq) + ne− (1)
Al(s) → Al3+(aq) + 3e− (2)
And at cathode according to Equation (3)
2H2O + 2e → H2 + 2OH− (3)
In solution the positively charged ions are attracted with the negatively charged hydroxides to produce ionic hydroxides that have a strong attraction towards dispersed particles as well as counter ions to cause coagulation [12] .
3. Overview of Different Types of Water and Wastewater Recently Treated by Electrocoagulation-Electro Flotation (ECF) Technology
The EC process is the electrochemical generation of metal ions (such as Al and Fe) that act as destabilizing agents and leads to neutralization of electric charge for removing pollutants. This process has been proven to be very effective in removing contaminants from waters and is characterized by reduced sludge production, no requirement of chemicals, and ease of operation and electrical energy consumption. [13] demonstrated removal efficiency 91% of fluoride ions from water by Electrocoagulation process and maximum hardness removal 60% - 70%, while [14] studied effluents from different industrial sectors. Using iron anode, Fe (99.17%), Mn (99.97%),
4. Conclusion
This research has identified a review of efficaciously electrocoagulation application, for the subtraction of precise problematic as toxicity and huge loss quantities of water that unconcerned effectively by Conventional treatment methods. However, this paper has effectively reasoned that the EC technique is alternative method for treatment wastewater. A number of studies using experimental setup in many applications of this promising technology have done better reactors design. From the above literature it can be established that the electrocoagulation is the effective method for the treatment countless wastewater and elimination solids, color, turbidity, BOD and COD. The various rewards for this promising technology are low operation and maintenance cost, high efficiency, time saving, lower sludge production without any addition of chemicals. Maybe this simple reactor in the near future will be in most various factories and water treatment company.
Conflicts of Interest
The author declares no conflicts of interest regarding the publication of this paper.
Cite this paper
Sadik, M.A. (2019) A Review of Promising Electrocoagulation Technology for the Treatment of Wastewater. Advances in Chemical Engineering and Science, 9, 109-126. https://doi.org/10.4236/aces.2019.91009
References
- 1. Kara, S. (2013) Treatment of Transport Container Washing Wastewater by Electrocoagulation. Environmental Progress & Sustainable Energy, 32, 249-256.
https://doi.org/10.1002/ep.11616 - 2. Khaled, B., Wided, B., Bechir, H., Elimame, E., Mouna, L. and Zied, T. (2015) Investigation of Electrocoagulation Reactor Design Parameters Effect on the Removal of Cadmium from Synthetic and Phosphate Industrial Wastewater. Arabian Journal of Chemistry, 2.
- 3. Lopez, V.R., Saez, C., Cañizares, P. and Rodrigo, M. (2012) Electrocoagulation of the Effluents from Surfactant-Aided Soil-Remediation Processes. Separation and Purification Technology, 98, 88-93.
https://doi.org/10.1016/j.seppur.2012.07.017 - 4. Mansour, S. and Hasieb, H. (2012) Removal of Ni (II) and Co (II) Mixtures from Synthetic Drinking Water by Electrocoagulation Technique Using Alternating Current. International Journal of Chemical Technology, 4, 31-44.
- 5. Dehghani, M., Seresht, S. and Hashemi, H. (2014) Treatment of Hospital Wastewater by Ectrocoagulationusing Aluminum and Iron Electrodes. International Journal of Environmental Health Engineering, 3, 15.
https://doi.org/10.4103/2277-9183.132687 - 6. Dehghani, M. and Hashemi, H. (2014) Treatment of Hospital Waste Water by Electrocoagulation Using Aluminium and Iron Electrode.
- 7. Almazán, R. Caballero, F. Cruz, V., Díaz, M., Rivero, E. and Gonzalez, I. (2012) Scale-Up of Rotating Cylinder Electrode Electrochemical Reactor for Cu(II) Recovery: Experimental and Simulation Study in Turbulence Regimen. Electrochimica Acta, 77, 262-271.
https://doi.org/10.1016/j.electacta.2012.06.003 - 8. Valente, G., Mendonca, R. and Pereira, J. (2015) The Efficiency of Electrocoagulation Using Aluminum Electrodes in Treating Wastewater from a Dairy Industry. Ciência Rural, 45, 1713-1719.
https://doi.org/10.1590/0103-8478cr20141172 - 9. Valero, D., García, V., Expósito, E., Aldaz, A. and Montiel, V. (2015) Application of Electrodialysis for the Treatment of Almond Industry Wastewater. Journal of Membrane Science, 476, 580-589.
https://doi.org/10.1016/j.memsci.2014.11.007 - 10. Silva, D., Mercon, F., Cerqueira, A., Ximango, P., Costa, D. and Marques, M. (2015) Evaluation of Electrocoagulation as Prertreatment of Oil Emulsions Followed by Reverse Osmosis. Journal of Water Process Engineering, 8, 126-135.
https://doi.org/10.1016/j.jwpe.2015.09.009 - 11. Jame, S. (2012) Electrochemical Treatment of Synthetic Wastewater Containing Textile Dyes. Lamar University, Texas, USA.
- 12. Naje, A.S. and Abbas, S.A. (2013) Electrocoagulation Technology in Wastewater Treatment: A Review of Methods and Applications. Civil and Environmental Research, 3, 29-42.
- 13. Mahammedrafi, P. (2018) An Experimental Study of Electrocoagulation Process Applied for Influence of Fluoride Ions on Hardness Removal. International Journal of Engineering Research and Application, 8, 33-38.
- 14. Warren, R., Lisveth, V., Flores, P., José, L., Guerrero, G., Josué, T., Rea-Marcos, L.M., María, E., Santos, R. and Yuli, P. (Benefits of Electrocoagulation in Treatment of Wastewater) (2018) Removal of Fe and Mn Metals, Oil and Grease and COD. International Journal of Applied Engineering Research, 13, 6450-6462.
- 15. Naraghi, B., Baneshi, M.M., Amiri, R., Dorost, A. and Biglari, H. (2018) Removal of Reactive Black 5 Dye from Aqueous Solutions by Coupled Electrocoagulation and Bio-Adsorbent Process. Electronic Physician, 10, 7086-7094.
https://doi.org/10.19082/7086 - 16. Thakur, S. and Chauhan, M.S. (2018) Treatment of Dye Wastewater from Textile Industry by Electrocoagulation and Fenton Oxidation: A Review. In: Singh, V., Yadav, S. and Yadava, R., Eds., Water Quality Management. Water Science and Technology Library, Vol. 79, Springer, Singapore, 117-129.
https://doi.org/10.1007/978-981-10-5795-3_11 - 17. Singh, H. and Mishra, B.K. (2017) Assessment of Kinetics Behavior of Electrocoagulation Process for the Removal of Suspended Solids and Metals from Synthetic Water. Environmental Engineering Research, 22, 141-148.
- 18. Majumder, S. and Rida, U. (2017) Removal of COD from Textile Mill Wastewater by Electro-Coagulation Process Using SS/Al as Composite Hydrogel Electrode. International Journal of Innovative Research in Science, Engineering and Technology, 6, 17242-17250.
- 19. Zazouli, M.A., Ahmadi, M. and Charati, J.Y. (2017) Pretreatment of Paper Recycling Plant Wastewater by Electrocoagulation Using Aluminum and Iron Electrodes. Journal of Materials and Environmental Sciences, 8, 2140-2146.
- 20. Li, R., Wang, B., Owete, O., Dertien, J., Lin, C., Ahmad, H. and Chen, G. (2017) Landfill Leachate Treatment by Electrocoagulation and Fiber Filtration. Water Environmental Research, 89, 2015-2020.
- 21. Song, P.P., Yang, Z.H., Zeng, G.M., Yang, X., et al. (2017) Electrocoagulation Treatment of Arsenic in Wastewaters. Chemical Engineering Journal, 81, 707-725.
- 22. Bejjany, B., Lekhlif, B., Eddaqaq, F., Dani, A., Mellouk, H. and Khalid, D. (2017) Treatment of the Surface Water by Electrocoagulation-Electroflotation Process in Internal Loop Airlift Reactor Conductivity Effect on Turbidity Removal and Energy Consumption. Journal of Materials and Environmental Science, 8, 2757-2768.
- 23. Maghanga, J., Segor, K., Irina, J. and Tole, M. (2017) Effect of Process Parameters on the Electro Coagulation of Azo-Dye Wastewater in a Kenyan Textile Factory. IOSR Journal of Applied Chemistry, 10, 1-7.
- 24. Alimohammadi, M., Askari, M., Dehghani, M., Dalvand, A. Saeedi, R., Yetilmezsoy, K., Heibati, B. and McKay, G. (2017) Elimination of Natural Organic Matter by Electrocoagulation Using Bipolar and Monopolar Arrangements of Iron and Aluminum Electrodes. International Journal of Environmental Science and Technology, 14, 2125-2134.
https://doi.org/10.1007/s13762-017-1402-3 - 25. Vidal, J., Espinoza, C., Contreras, N. and Salazar, R. (2017) Elimination of Industrial Textile Dye by Electrocoagulation Using Iron Electrodes. Journal of the Chilean Chemical Society, 62, 3519-3524.
- 26. Sajjadi, S.A., Pakfetrat, A. and Irani, M. (2017) Removal of Remazol Black B Dye by Electrocoagulation Process Coupled with Bentonite as an Aid Coagulant and Natural Adsorbent. Iranian Journal of Health, Safety & Environment, 5, 1058-1065.
- 27. Osman, A.T., Elamin, M.R. and Almalki, M.H. (2017) Treatment of Tannery Wastewater with Nano-Electrocoagulation Process. Journal of Environmental & Analytical Toxicology, 7, 508.
- 28. Nwabanne, J.T. and Obi, C.C. (2017) Abattoir Wastewater Treatment by Electrocoagulation Using Iron Electrodes. Der Chemica Sinica, 8, 254-260.
- 29. Ghalwa, N.M., Musabeh, A.Z. and Farhat, N.B. (2017) Performance Efficiency of Electrocoagulation Adsorption Process of Oxyfluorfen Herbicide from Aqueous Solutions Using Different Anodes. Journal of Environmental and Analytical Toxicology, 7, 448.
- 30. Garg, U.K. and Sharma, C. (2016) Electrocoagulation: Promising Technology for Removal of Fluoride from Drinking Water—A Review. Biological Forum, 8, 248-254.
- 31. Eyvaz, M. (2016) Treatment of Brewery Wastewater with Electrocoagulation: Improving the Process Performance by Using Alternating Pulse Current. International Journal of Electrochemical Science, 11, 4988-5008.
https://doi.org/10.20964/2016.06.11 - 32. Vidal, J., Villegas, L., Peralta-Hernández, J.M. and González, R.S. (2016) Removal of Acid Black 194 Dye from Water by Electrocoagulation with Aluminum Anode. Journal of Environmental Science and Health, Part A, 51, 289-296.
https://doi.org/10.1080/10934529.2015.1109385 - 33. Singh, A., Srivastava, A., Tripathi, A. and Dutt, N.N. (2016) Optimization of Brilliant Green Dye Removal Efficiency by Electrocoagulation Using Response Surface Methodology. World Journal of Environmental Engineering, 4, 23-29.
- 34. Gonçalves, M.V.B., De Oliveira, S.C., Abreu, B.M.P.N., Guerra, E.M. and Cestarolli, D.T. (2016) Electrocoagulation/Electroflotation Process Applied to Decolourization of a Solution Containing the Dye Yellow Sirius K-CF. International Journal of Electrochemical Science, 11, 7576-7583.
https://doi.org/10.20964/2016.09.42 - 35. Zainab, A.H. and Noor, J. (2016) Removal of Reactive Black Wastewater by Electrocoagulation Dye from Synthetic Technique. Journal of Engineering and Sustainable Development, 20, 40-54.
- 36. Santhosh, P., Revathi, D. and Saravanan, K. (2015) Treatment of Sullage Wastewater by Electrocoagulation Using Stainless Steel Electrodes. International Journal of Chemical Science, 13, 1173-1186.
- 37. Un, U.T. and Ocal, S.E. (2015) Removal of Heavy Metals (Cd, Cu, Ni) by Electrocoagulation. International Journal of Environmental Science and Development, 6, 425-429.
https://doi.org/10.7763/IJESD.2015.V6.630 - 38. Khandegar, V. and Saroha, A. (2015) Electrochemical Treatment of Distillery Spent Wash Using Aluminum and Iron Electrodes. Chinese Journal of Chemical Engineering, 20, 439-443.
https://doi.org/10.1016/S1004-9541(11)60204-8 - 39. Pirkarami, A. and Olya, M.E. (2014) Removal of Dye from Industrial Wastewater with an Emphasis on Improving Economic Efficiency and Degradation Mechanism. Journal of Saudi Chemical Society, 21, S179-S186.
https://doi.org/10.1016/j.jscs.2013.12.008 - 40. Sharma, D. (2014) Treatment of Dairy Waste Water by Electrocoagulation Using Aluminum Electrodes and Settling, Filtration Studies. International Journal of ChemTech Research, 6, 591-599.
- 41. Alizadeh, M., Mahvi, A. and Mansoorian, H. (2014) The Survey of Electrocoagulation Process for Removal Dye Reactive Orange 16 from Aqueous Solutions Using Sacrificial Iron Electrodes. Iranian Journal of Health, Safety and Environment, 1, 1-8.
- 42. Kobia, M., Oncel, E., Demrabase, S., Akyole, A. and Ince, M. (2014) The Application of Electrocoagulation Process for Treatment of the Red Mud Dam Wastewater from Bayer’s Process. Journal of Environmental Chemical Engineering, 2, 2211-2220.
https://doi.org/10.1016/j.jece.2014.09.008 - 43. Stergiopoulos, D., Dermentzis, K., Giannakoudakis, P. and Sotiropoulos, S. (2014) Electrochemical Decolorization and Removal of Indigo Carmine Textile Dye from Wastewater. Global NEST Journal, 16, 499-506.
https://doi.org/10.30955/gnj.001330 - 44. Rokovic, M.K., čubrić, M. and Wittine, O. (2014) Phenolic Compounds Removal from Mimosa Tannin Model Water and Olive Mill Wastewater by Energy-Efficient Electrocoagulation Process. Journal of Electrochemical Science and Engineering, 4, 215-225.
- 45. Akanksha, Roopashree, G.B. and Lokesh, K.S. (2014) Comparative Study of Electrode Material (Iron, Aluminium and Stainless Steel) for Treatment of Textile Industry Wastewater. International Journal of Environmental Sciences, 4, 519-531.
- 46. Barrera-Díaz, D., Lugo-Lugo, V. and Bilyeu, B. (2012) A Review of Chemical, Electrochemical and Biological Methods for Aqueous Cr(VI) Reduction. Journal of Hazardous Materials, 223-224, 1-12.
https://doi.org/10.1016/j.jhazmat.2012.04.054 - 47. Khandegar, V. and Saroha, A. (2013) Electrocoagulation for the Treatment of Textile Industry Effluent—A Review. Journal of Environmental Management, 128, 949-963.
https://doi.org/10.1016/j.jenvman.2013.06.043 - 48. Nandi, B. and Patel, S. (2013) Effects of Operational Parameters on the Removal of Brilliant Green Dye from Aqueous Solutions by Electrocoagulation. Arabian Journal of Chemistry, 10, S2961-S2968.
https://doi.org/10.1016/j.arabjc.2013.11.032 - 49. Sahu, O., Mazumdar, B. and Chaudhari, P.K. (2014) Treatment of Wastewater by Electrocoagulation. Environmental Science and Pollution Research, 21, 2397-2413.
https://doi.org/10.1007/s11356-013-2208-6 - 50. El-Ashtoukhy, E., El-Taweel, Y., Abdelwahab, O. and Nassef, E. (2013) Treatment of Petrochemical Wastewater Containing Phenolic Compounds by Electrocoagulation Using a Fixed Bed Electrochemical Reactor. International Journal of Electrochemical Science, 8, 1534-1550.
- 51. Mahmoud, M.S., Farah, J.Y. and Farrag, T.E. (2013) Enhanced Removal of Methylene Blue by Electrocoagulation Using Iron Electrodes. Egyptian Journal of Petroleum, 22, 211-216.
https://doi.org/10.1016/j.ejpe.2012.09.013 - 52. Mahajan, R., Khandegar, V. and Saroha, A. (2013) Treatment of Hospital Operation Theatre Effluent by Electrocoagulation. International Journal of Chemical and Environmental Engineering, 4, 104-107.
- 53. Sarala, C. (2012) Omestic Wastewater Treatment by Electrocoagulation with Fe-Fe Electrodes. International Journal of Engineering Trends and Technology, 3, 530-533.
- 54. Nasrullah, M., Singh, L. and Wahida, A. (2012) Treatment of Sewage by Electrocoagulation and the Effect of High Current Density. International Journal of Energy and Environmental Engineering, 1, 27-31.
- 55. Akyol, A. (2012) Treatment of Paint Manufacturing Wastewater by Electrocoagulation. Desalination, 285, 91-99.
https://doi.org/10.1016/j.desal.2011.09.039 - 56. Gengec, E., Kobya, M., Demirbas, E., Akyol, A. and Oktor, K. (2012) Optimization of Baker’s Yeast Wastewater Using Response Surface Methodology by Electrocoagulation. Desalination, 286, 200-209.
https://doi.org/10.1016/j.desal.2011.11.023 - 57. Ozyonar, F. and Karagozoglu, B. (2012) Systematic Assessment of Electrocoagulation for the Treatment of Marble Processing Wastewater. International Journal of Environmental Science and Technology, 9, 637-646.
https://doi.org/10.1007/s13762-012-0093-z - 58. Zongo, I., Merzouk, B., Palm, K., Wethe, J., Hama Maiga, A., et al. (2012) Study of an Electrocoagulation (EC) Unit for the Treatment of Industrial Effluent of Ouagadougou, Burkina Faso. Advances in Applied Science Research, 3, 572-582.
- 59. Harif, T., Khai, M. and Adin, A. (2012) Electrocoagulation versus Chemical Coagulation Coagulation/Flocculation Mechanisms and Resulting Floc Characteristics. Water Research, 46, 3177-3188.
https://doi.org/10.1016/j.watres.2012.03.034 - 60. Baudequin, C., Couallier, E., Rakib, M., Deguerry, I., Severac, R. and Pabon, M. (2011) Purification of Firefighting Water Containing a Fluorinated Surfactant by Reverse Osmosis Coupled to Electrocoagulation-Filtration. Separation and Purification Technology, 76, 275-282.
https://doi.org/10.1016/j.seppur.2010.10.016 - 61. Dalvand, A., Gholami, M., Joneidi, A. and Mahmoodi, N. (2011) Dye Removal, Energy Consumption and Operating Cost of Electrocoagulation of Textile Wastewater as a Clean Process. CLEAN—Soil, Air, Water, 39, 665-672.
https://doi.org/10.1002/clen.201000233 - 62. Bouhezila, F., Hariti, M., Lounici, H. and Mameri, N. (2011) Treatment of the OUED SMAR Town Landfill Leachate by an Electrochemical Reactor. Desalination, 280, 347-353.
https://doi.org/10.1016/j.desal.2011.07.032 - 63. Zhao, X., Zhang, B., Liu, H. and Qu, J. (2011) Simultaneous Removal of Arsenite and Fluoride via an Integrated Electro-Oxidation and Electrocoagulation Process. Chemosphere, 83, 726-729.
https://doi.org/10.1016/j.chemosphere.2011.01.055 - 64. Bellebia, S., Kacha, S., Bouyakoub, A. and Derriche, Z. (2011) Experimental Investigation of Chemical Oxygen Demand and Turbidity Removal from Cardboard Paper Mill Effluents Using Combined Electrocoagulation and Adsorption Processes. Environmental Progress & Sustainable Energy, 31, 361-370.
https://doi.org/10.1002/ep.10556 - 65. Chafi, M., Gourich, B., Essadki, A., Vial, C. and Fabregat, A. (2011) Comparison of Electrocoagulation Using Iron and Aluminium Electrodes with Chemical Coagulation for the Removal of a Highly Soluble Acid Dye. Desalination, 281, 285-292.
https://doi.org/10.1016/j.desal.2011.08.004 - 66. Hanay, Ö. and Hasar, H. (2011) Effect of Anions on Removing Cu2+, Mn2+ and Zn2+ in Electrocoagulation Process Using Aluminum Electrodes. Journal of Hazardous Materials, 189, 572-576.
https://doi.org/10.1016/j.jhazmat.2011.02.073 - 67. Janpoor, F., Torabian, A. and Khatibikamal, V. (2011) Treatment of Laundry Waste-Water by Electrocoagulation. Journal of Chemical Technology & Biotechnology, 86, 1113-1120.
https://doi.org/10.1002/jctb.2625 - 68. Bayar, S., Yıldız, Y., Yılmaz, A. and Irdemez, S. (2011) The Effect of Stirring Speed and Current Density on Removal Efficiency of Poultry Slaughterhouse Wastewater by Electrocoagulation Method. Desalination, 280, 103-107.
https://doi.org/10.1016/j.desal.2011.06.061
Abbreviation
AC, alternating current (amp); BOD, biochemical oxygen demand (mg/L); COD, chemical oxygen demand (mg/L); DC, direct current (amp); F, Faraday’s constant (96, 500 C/mol); ppm, parts per million; SS, suspended solids (mg/L); TDS, total dissolved solids (mg/L); TFS, total fixed solids (mg/L); TOC, total organic carbon (mg/L); TSS, total suspended solids (mg/L); TVS, total volatile solids (mg/L).
Nomenclature