Numerical modelling of a bromide―polysulphide redox flow battery Part 1: Modelling approach and validation for a pilot-scale system

• Published in: Journal of power sources Vol. 189; no. 2; pp. 1220 - 1230
• Main Authors: SCAMMAN, Daniel P, READE, Gavin W, ROBERTS, Edward P. L
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier 15.04.2009
• Subjects: Applied sciences; Direct energy conversion and energy accumulation; Electrical engineering. Electrical power engineering; Electrical power engineering; Electrochemical conversion: primary and secondary batteries, fuel cells; Exact sciences and technology; British Isles; Solvent effect; Power density; Electrochemical rate constant; Electrode discharge; Numerical model; Redox flow battery; Secondary cell; Polysulfides; Electric batteries; Modeling; Discharge charge cycle; Redox couple; Energetic efficiency; Bromides; Current distribution; Bromide-polysulphide; Redox system; Performance; Energy storage; Concentration distribution
• ISSN: 0378-7753; 1873-2755
• DOI: 10.1016/j.jpowsour.2009.01.071

Numerical modelling of redox flow battery (RFB) systems for energy storage applications allows the technical performance of different designs to be predicted without costly lab, pilot and full-scale testing. A one-dimensional numerical model has been developed for RFB systems with bipolar flow-by electrodes, soluble redox couples, and recirculating batch operation. Overpotential losses were estimated from the Butler-Volmer equation, accounting for mass transfer. The effects of cross-membrane solvent transport and self-discharge were also considered. The model predicted the variation in concentration and current along the electrode and determined the charge-discharge efficiency, energy density and power density. The model was validated using data obtained from a pilot-scale bromide-polysulphide (PSB) system commercialised by Regenesys Technologies (UK) Ltd. Electrochemical rate constants were obtained by fitting the model results to the experimental data, and values of 4 x 10 super(-7) and 3 x 10 super(-8) m s super(-1) were found for the bromide and sulphide electrolytes on the activated carbon electrodes. The model was able to predict cell performance, species concentration, current distribution and electrolyte deterioration for the Regenesys system.