Název:	Experimental 3D concentration profiles along an electrodialysis channel reveal a strong effect of natural convection
Autoři:	Kovář, Petr Smoleň, Michal Pagáč, Jan Kincl, Marek Slouka, Zdeněk
Citace zdrojového dokumentu:	KOVÁŘ, P. SMOLEŇ, M. PAGÁČ, J. KINCL, M. SLOUKA, Z. Experimental 3D concentration profiles along an electrodialysis channel reveal a strong effect of natural convection. DESALINATION, 2023, roč. 548, č. FEB 15 2023, s. nestránkováno. ISSN: 0011-9164
Datum vydání:	2023
Nakladatel:	Elsevier
Typ dokumentu:	článek article
URI:	2-s2.0-85143793308 http://hdl.handle.net/11025/53886
ISSN:	0011-9164
Klíčová slova v dalším jazyce:	electrodialysis;gravity;concentration profiles;current density
Abstrakt v dalším jazyce:	Electrodialysis and electrodeionization separate ionic components from processed water solutions by applying a DC electric field on a stack of ion-exchange membranes. The ion separation indicates ionic concentration changes along the channels in the membrane modules. Simultaneously, concentration polarization at the ion-exchange membranes causes ionic concentration variations across the channels. We constructed a milifluidic cell with a diluate channel to measure spatial concentration profiles under single-path electrodialysis conditions. Desalination of 0.1 M NaCl solution showed that the concentration decreases linearly along the channel when connecting relatively low average current densities (< 30 A/m2), yielding <70 % desalination. Higher average current densities causing desalination close to 100 % produced nonlinear concentration profiles characterized by a steep linear drop followed by an almost constant and small concentration region. We show that at a current density of 50 A/m2, only one-third of the diluate channel is employed for desalination. Interestingly, uniform concentration profiles developed across the channels even at high polarization current densities. Unlike constant concentrations across the channel, we found substantial concentration variation in the vertical direction of the channel, indicating the effect of density gradients and natural convection. This effect was confirmed by optical microscopy and particle image velocimetry of this convection in stagnant solution layers. Natural convection, thus, can represent a mechanism intensifying the mass transfer from the solution bulk to the membrane surfaces.
Práva:	Plný text je přístupný v rámci univerzity přihlášeným uživatelům © Elsevier
Vyskytuje se v kolekcích:	Články / Articles OBD

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