Characterization of a multiple-channel electrochemical cell by Computational Fluid Dynamics (CFD) and Residence Time Distribution (RTD)

Multiple-channel electrochemical cells are used for the electrocoagulation treatment of pollutants, but sometimes their use can be limited because of lack of knowledge of both hydrodynamic and current distribution performance. Most of the research devoted to electrocoagulation processes, do not present a preliminary hydrodynamic study of the selected cell. Thus, in this paper the importance of having a hydrodynamic characterization and current distribution analysis of a multi-channel electrochemical cell is highlighted. Studies of primary current distribution and, hydrodynamics were supported on applications of the COMSOL Multhiphysics™ and FLUENT™ software, respectively. The flow path was described by the residence time distribution (RTD) method. The current distribution analysis showed that a better distribution is obtained when an interelectrode gap of 3 cm is chosen. The RTD charts and the flow distribution described accurately channeling sections and stagnant zones that must be taken into account, since channeling reduce the entrapment of mud and stagnant zones promote the formation of clots. ©The Electrochemical Society.

Current distribution; Current distribution analysis; Electrocoagulation; Flow distribution; Flow path; Hydrodynamic characterization; Interelectrode gaps; Multi-channel; Multiple-channel; Primary currents; Residence time distributions; Stagnant zones; Coagulation; Computational fluid dynamics; Electric current distribution measurement; Electrochemical cells; Electrolytic analysis; Electrolytic cells; Hydrodynamics; Electrochemistry

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