Principles of a multistack electrochemical wastewater treatment design

• Published in: Journal of physics. D, Applied physics Vol. 51; no. 6; pp. 65502 - 65512
• Main Authors: Elsahwi, Essam S, Dawson, Francis P, Ruda, Harry E
• Format: Journal Article
• Language: English
• Published: IOP Publishing 14.02.2018
• Subjects: circuit based model; current distribution; electrolyzers; industrial electrochemical systems; leakage currents; small signal analysis; wastewater treatment
• ISSN: 0022-3727; 1361-6463
• DOI: 10.1088/1361-6463/aaa28a

Electrolyzer stacks in a bipolar architecture (cells connected in series) are desirable since power provided to a stack can be transferred at high voltages and low currents and thus the losses in the power bus can be reduced. The anode electrodes (active electrodes) considered as part of this study are single sided but there are manufacturing cost advantages to implementing double side anodes in the future. One of the main concerns with a bipolar stack implementation is the existence of leakage currents (bypass currents). The leakage current is associated with current paths that are not between adjacent anode and cathode pairs. This leads to non uniform current density distributions which compromise the electrochemical conversion efficiency of the stack and can also lead to unwanted side reactions. The objective of this paper is to develop modelling tools for a bipolar architecture consisting of two single sided cells that use single sided anodes. It is assumed that chemical reactions are single electron transfer rate limited and that diffusion and convection effects can be ignored. The design process consists of the flowing two steps: development of a large signal model for the stack, and then the extraction of a small signal model from the large signal model. The small signal model facilitates the design of a controller that satisfies current or voltage regulation requirements. A model has been developed for a single cell and two cells in series but can be generalized to more than two cells in series and to incorporate double sided anode configurations in the future. The developed model is able to determine the leakage current and thus provide a quantitative assessment on the performance of the cell.