Optimization and Analysis of High‐Power Hydrogen/Bromine‐Flow Batteries for Grid‐Scale Energy Storage

For storage of grid‐scale electrical energy, redox‐flow batteries (RFBs) are considered promising technologies. This paper explores the influence of electrolyte composition and ion transport on cell performance by using an integrated approach of experiments and cost modeling. In particular, the impact of the area‐specific resistance on system capability is elucidated for the hydrogen/bromine RFB. The experimental data demonstrate very good performance with 1.46 W cm−2 peak power and 4 A cm−2 limiting current density at ambient conditions for an optimal cell design and reactant concentrations. The data and cost model results show that higher concentrations of RFB reactants do not necessarily result in lower capital cost as there is a tradeoff between cell performance and storage (tank) requirements. In addition, the discharge time and overall efficiency demonstrate nonlinear effects on system cost, with a 3 to 4 hour minimum discharge time showing a key transition to a plateau in terms of cost for typical RFB systems. The presented results are applicable to many different RFB chemistries and technologies and highlight the importance of ohmic effects and associated area‐specific resistance on RFB viability. Hustle and flow: H2/Br2 redox flow battery is studied for grid‐scale energy storage. Optimization of conditions and components demonstrate high ambient performance both in peak power and limiting current density. The combined experiments and cost model reveal the importance of area‐specific resistance and nonintuitive optimized operating conditions.