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On the Interaction of Electroconvection at a Membrane Interface with the Bulk Flow in a Spacer-Filled Feed Channel

Stockmeier, Felix ; Stüwe, Lucas ; Kneppeck, Christian ; Musholt, Stephan ; Albert, Katharina ; Linkhorst, John ; Wessling, Matthias (2023)
On the Interaction of Electroconvection at a Membrane Interface with the Bulk Flow in a Spacer-Filled Feed Channel.
In: Journal of Membrane Science, 678
doi: 10.1016/j.memsci.2023.121589
Article, Bibliographie

Abstract

The operational range of electro-driven processes can be extended by (i) reducing diffusion resistances at the membrane/electrolyte interface using spacers and (ii) by electroconvective mixing of the boundary layer at overlimiting current densities. Although many studies have addressed each of these phenomena separately, the details of the interplay of spacer-engineered hydrodynamics and electroconvection are unexplored. In this study, we establish a methodology of a new membrane cell design and the use of a high-speed microparticle tracking velocimetry setup for direct observation and quantification of the 3D velocity field in a spacer-filled electrodialysis channel under process conditions relevant for real electrodialysis applications, i.e., overlimiting currents and elevated Reynolds. We unravel details of the superposition of electroconvective vortices and forced flow velocity with and without an inserted spacer. Overall, the forced flow flattens the vortex structure of electroconvection at increasing Reynolds numbers. In terms of vortex heights, a spacer with intentional dead zones outperforms a commercial spacer that decreases the boundary layer thickness. This study suggests a counter-intuitive spacer design: to exploit electroconvection, an engineered spacer design for maximum use of electroconvection in the far overlimiting region should aim to create intentional regions of low flow velocity.

Item Type: Article
Erschienen: 2023
Creators: Stockmeier, Felix ; Stüwe, Lucas ; Kneppeck, Christian ; Musholt, Stephan ; Albert, Katharina ; Linkhorst, John ; Wessling, Matthias
Type of entry: Bibliographie
Title: On the Interaction of Electroconvection at a Membrane Interface with the Bulk Flow in a Spacer-Filled Feed Channel
Language: English
Date: 2023
Publisher: Elsevier
Journal or Publication Title: Journal of Membrane Science
Volume of the journal: 678
DOI: 10.1016/j.memsci.2023.121589
Abstract:

The operational range of electro-driven processes can be extended by (i) reducing diffusion resistances at the membrane/electrolyte interface using spacers and (ii) by electroconvective mixing of the boundary layer at overlimiting current densities. Although many studies have addressed each of these phenomena separately, the details of the interplay of spacer-engineered hydrodynamics and electroconvection are unexplored. In this study, we establish a methodology of a new membrane cell design and the use of a high-speed microparticle tracking velocimetry setup for direct observation and quantification of the 3D velocity field in a spacer-filled electrodialysis channel under process conditions relevant for real electrodialysis applications, i.e., overlimiting currents and elevated Reynolds. We unravel details of the superposition of electroconvective vortices and forced flow velocity with and without an inserted spacer. Overall, the forced flow flattens the vortex structure of electroconvection at increasing Reynolds numbers. In terms of vortex heights, a spacer with intentional dead zones outperforms a commercial spacer that decreases the boundary layer thickness. This study suggests a counter-intuitive spacer design: to exploit electroconvection, an engineered spacer design for maximum use of electroconvection in the far overlimiting region should aim to create intentional regions of low flow velocity.

Uncontrolled Keywords: 3D PTV, Concentration polarization, Electrodialysis, Hydrodynamics, Ion transport, Spacer, Velocity field
Divisions: 16 Department of Mechanical Engineering
16 Department of Mechanical Engineering > Chair for Process Engineering of Electrochemical Systems
Date Deposited: 13 Sep 2023 11:13
Last Modified: 13 Sep 2023 11:13
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