Crossover analysis in a commercial 6 kW/43kAh vanadium redox flow battery utilizing anion exchange membrane

Crossover analysis in a commercial 6 kW/43kAh vanadium redox flow battery utilizing anion exchange membrane

•Protons are the primary charge carriers in VRFBs employing AEMs.•Regular operation (5–80 % SoC) shows ∼0.5 % electrolyte volume transfer per cycle.•Osmotic effects are the main contributors to volumetric transport.•Impact of diffusion coefficients, pH changes, and bisulfate concentration gradient....

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 490; p. 151947
Main Authors: Oreiro, Sara Noriega, Bentien, Anders, Sloth, Jonas, Rahimi, Mohammad, Madsen, Morten Brun, Drechsler, Terje
Format: Journal Article
Language:English
Published: Elsevier B.V 15-06-2024
Subjects:
Anion exchange membrane
Crossover
Diffusion
Migration
Osmosis
Vanadium redox flow battery
Osmosis
Vanadium redox flow battery
Anion exchange membrane
Crossover
Diffusion
Migration
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Summary:•Protons are the primary charge carriers in VRFBs employing AEMs.•Regular operation (5–80 % SoC) shows ∼0.5 % electrolyte volume transfer per cycle.•Osmotic effects are the main contributors to volumetric transport.•Impact of diffusion coefficients, pH changes, and bisulfate concentration gradient. The volumetric and species transport is a significant source of capacity decay in vanadium redox flow batteries (VRFBs). However, even with the prevalent use of anion exchange membranes (AEMs) in commercial systems, the understanding of the crossover mechanisms in this context remains limited. The primary objective of this study was to gain a deeper comprehension of these mechanisms through experimental investigations conducted on a 6 kW/43kAh VRFB system using AEMs. It is concluded that protons serve as the primary charge carriers, owing to the high ionic concentrations of the electrolyte. During normal operation, there was a consistent pattern of volume transfer from the positive to the negative half-cell (∼0.5 % of the total electrolyte per cycle/day). Experimental assessments performed at different states-of-charge (SoCs) revealed that the volumetric transport towards the anolyte increases with SoC. The osmotic effects are concluded to be the main contributors to the volumetric transport. The osmotic pressure difference is hypothesized to arise from the asymmetric diffusion coefficients of the vanadium ions, changes in pH affecting sulfate and bisulfate equilibrium alongside their different diffusion coefficients, and a likely predominance of the bisulfate concentration gradient in the water transport through the membrane.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2024.151947