The importance of key operational variables and electrolyte monitoring to the performance of an all vanadium redox flow battery
The importance of key operational variables and electrolyte monitoring to the performance of an all vanadium redox flow battery
BACKGROUND: The all vanadium redox flow battery (VRFB) has become the most common type of rfb, however, it is essential to improve our understanding of the importance of key operational variables, including electrode materials, electrolyte flow rate, current density and temperature, on the cell efficiency together with improved methods for cell monitoring.
RESULTS: Several carbon felts were characterized for their electrode activity. A commercially supplied electrolyte of unknown composition was analysed and was shown to contain a VO2+: V3+ ratio of 4.8:1 (total vanadium species = 1.5 mol dm?3) in 4 mol dm?3 H2SO4. A battery (100 cm2) was assembled using three-dimensional carbon felts and planar carbon feeders as the electrodes with a Nafion® 115 proton exchange membrane. Performance was examined using electrolytes of varying vanadium ion concentration at volumetric flow rating from 0.5–3 mL min1. A suitable volumetric flow rate of electrolyte through each half-cell was found to be in the range 1.5–2.0 mL min?1, corresponding to a mean linear electrolyte velocity of 1.0–10.1 cm s?1 through the carbon felt electrode. At a constant current charge and discharge current density of 100 mA cm?2 the typical voltage efficiencies were 65%. Charge-discharge curves were then simulated using a detailed physical model, which generated good quantitative agreement with experimental cell performance.
CONCLUSIONS: This study has quantified the effect of key process variables on cell efficiency. A mathematical model has been used successfully to describe charge-discharge performance and the use of open-circuit cell voltage has been shown to provide a simple and useful means of cell monitoring.
126-138
Watt-Smith, Matthew J.
c8c5b4b3-47d6-407a-9858-869c6663349d
Ridley, P.
3af0f54e-305b-4cb5-a1ea-03c2b36c2b3a
Wills, R.G.A.
60b7c98f-eced-4b11-aad9-fd2484e26c2c
Shah, A.A.
5c43ac37-c4a7-4256-88ef-8c427886b924
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2
Watt-Smith, Matthew J.
c8c5b4b3-47d6-407a-9858-869c6663349d
Ridley, P.
3af0f54e-305b-4cb5-a1ea-03c2b36c2b3a
Wills, R.G.A.
60b7c98f-eced-4b11-aad9-fd2484e26c2c
Shah, A.A.
5c43ac37-c4a7-4256-88ef-8c427886b924
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2
Watt-Smith, Matthew J., Ridley, P., Wills, R.G.A., Shah, A.A. and Walsh, F.C.
(2012)
The importance of key operational variables and electrolyte monitoring to the performance of an all vanadium redox flow battery.
Journal of Chemical Technology and Biotechnology, 88 (1), .
(doi:10.1002/jctb.3870).
Abstract
BACKGROUND: The all vanadium redox flow battery (VRFB) has become the most common type of rfb, however, it is essential to improve our understanding of the importance of key operational variables, including electrode materials, electrolyte flow rate, current density and temperature, on the cell efficiency together with improved methods for cell monitoring.
RESULTS: Several carbon felts were characterized for their electrode activity. A commercially supplied electrolyte of unknown composition was analysed and was shown to contain a VO2+: V3+ ratio of 4.8:1 (total vanadium species = 1.5 mol dm?3) in 4 mol dm?3 H2SO4. A battery (100 cm2) was assembled using three-dimensional carbon felts and planar carbon feeders as the electrodes with a Nafion® 115 proton exchange membrane. Performance was examined using electrolytes of varying vanadium ion concentration at volumetric flow rating from 0.5–3 mL min1. A suitable volumetric flow rate of electrolyte through each half-cell was found to be in the range 1.5–2.0 mL min?1, corresponding to a mean linear electrolyte velocity of 1.0–10.1 cm s?1 through the carbon felt electrode. At a constant current charge and discharge current density of 100 mA cm?2 the typical voltage efficiencies were 65%. Charge-discharge curves were then simulated using a detailed physical model, which generated good quantitative agreement with experimental cell performance.
CONCLUSIONS: This study has quantified the effect of key process variables on cell efficiency. A mathematical model has been used successfully to describe charge-discharge performance and the use of open-circuit cell voltage has been shown to provide a simple and useful means of cell monitoring.
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e-pub ahead of print date: 28 August 2012
Organisations:
Engineering Science Unit
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Local EPrints ID: 350196
URI: http://eprints.soton.ac.uk/id/eprint/350196
ISSN: 0268-2575
PURE UUID: 981c498f-ce36-467f-a019-6a368ad8e7e7
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Date deposited: 17 Apr 2013 11:59
Last modified: 15 Mar 2024 03:17
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Author:
Matthew J. Watt-Smith
Author:
P. Ridley
Author:
A.A. Shah
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