Assessment of pillar-array electrodes for electrochemical flow reactors using a novel hydrodynamic electrode performance factor
Assessment of pillar-array electrodes for electrochemical flow reactors using a novel hydrodynamic electrode performance factor
This work introduces and validates a Hydrodynamic Electrode Performance Factor (HEPF) for flow reactors. Traditional approaches to electrode optimization often rely on separated mass transfer and pressure drop metrics, hindering comparisons. We address this issue by combining electrochemical and hydrodynamic parameters through a new mathematical expression. This formulation draws inspiration from established equations in heat transfer and the widely recognized Chilton-Colburn analogy, aiming to develop a quantification method independent of the experimental arrangement. The HEPF is complementary to the well-established volumetric mass transfer coefficient and to Storck’s energetic effectiveness postulates for electrochemical reactors. Additionally, this study validates the proposed equation experimentally and then applies it to evaluate pillar array electrodes using 2D computational fluid dynamics simulations for laminar flow conditions. Both experimental and simulation approaches are used to analyze the hydrodynamic behaviour of the electrodes, utilizing the Forchheimer and Hagen-Poiseuille numbers. Notably, preliminary turbulence effects are observed at Reynolds numbers as low as 50 to 125. Visualization of velocity streamlines revealed distinct wake formation behind the pillars at these low Reynolds numbers. This study also explores how reactor inlets, outlets, and tubing pressure losses affect electrode performance. Results emphasize the importance of considering pressure drop, which is integral to the new hydrodynamic performance factor. Analysis of pillar array electrodes demonstrates that reducing both interpillar distance and pillar radius leads to improved electrochemical performance.
Rop, Michiel De
fcb0b95f-7e76-497f-925d-4121056d50ba
Arenas, Luis F.
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Wolf, Renée De
fc42e4b7-85c2-4df8-82be-33eb3868f1a0
Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
2 November 2024
Rop, Michiel De
fcb0b95f-7e76-497f-925d-4121056d50ba
Arenas, Luis F.
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Wolf, Renée De
fc42e4b7-85c2-4df8-82be-33eb3868f1a0
Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
Rop, Michiel De, Arenas, Luis F., Wolf, Renée De and Hereijgers, Jonas
(2024)
Assessment of pillar-array electrodes for electrochemical flow reactors using a novel hydrodynamic electrode performance factor.
Chemical Engineering Journal, 500, [156632].
(doi:10.1016/j.cej.2024.156632).
Abstract
This work introduces and validates a Hydrodynamic Electrode Performance Factor (HEPF) for flow reactors. Traditional approaches to electrode optimization often rely on separated mass transfer and pressure drop metrics, hindering comparisons. We address this issue by combining electrochemical and hydrodynamic parameters through a new mathematical expression. This formulation draws inspiration from established equations in heat transfer and the widely recognized Chilton-Colburn analogy, aiming to develop a quantification method independent of the experimental arrangement. The HEPF is complementary to the well-established volumetric mass transfer coefficient and to Storck’s energetic effectiveness postulates for electrochemical reactors. Additionally, this study validates the proposed equation experimentally and then applies it to evaluate pillar array electrodes using 2D computational fluid dynamics simulations for laminar flow conditions. Both experimental and simulation approaches are used to analyze the hydrodynamic behaviour of the electrodes, utilizing the Forchheimer and Hagen-Poiseuille numbers. Notably, preliminary turbulence effects are observed at Reynolds numbers as low as 50 to 125. Visualization of velocity streamlines revealed distinct wake formation behind the pillars at these low Reynolds numbers. This study also explores how reactor inlets, outlets, and tubing pressure losses affect electrode performance. Results emphasize the importance of considering pressure drop, which is integral to the new hydrodynamic performance factor. Analysis of pillar array electrodes demonstrates that reducing both interpillar distance and pillar radius leads to improved electrochemical performance.
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Published date: 2 November 2024
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Local EPrints ID: 501979
URI: http://eprints.soton.ac.uk/id/eprint/501979
ISSN: 1385-8947
PURE UUID: a6483f18-9cb1-49cf-bcf5-1020e7e80a3e
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Date deposited: 12 Jun 2025 17:17
Last modified: 13 Jun 2025 01:55
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Author:
Michiel De Rop
Author:
Renée De Wolf
Author:
Jonas Hereijgers
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