Mathematical Description of Electric Mass-Transfer Processes Based on Substance Transfer Equation

Studies of the electrodialysis separation processes under pulsed current have faced problems related to the lack of a mathematical description of the electric mass-transfer processes, taking into account unsteady current modes. The main problem when describing electric mass-transfer processes is the...

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Bibliographic Details
Published in:Theoretical foundations of chemical engineering 2023-10, Vol.57 (5), p.952-956
Main Authors: Ravichev, L. V., Ilyina, S. I., Loginov, V. Ya, Bykov, V. I., Titov, A. A.
Format: Article
Language:English
Subjects:
Charge density
Charge transfer
Chemistry
Chemistry and Materials Science
Concentration gradient
Criteria
Density distribution
Electrical resistivity
Electrodialysis
Fluid flow
Industrial Chemistry/Chemical Engineering
Mass transfer
Mathematical analysis
Potential gradient
Pulsed current
Separation
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Summary:Studies of the electrodialysis separation processes under pulsed current have faced problems related to the lack of a mathematical description of the electric mass-transfer processes, taking into account unsteady current modes. The main problem when describing electric mass-transfer processes is the presence of two driving forces, namely the electric potential gradient and the concentration gradient. The objective of the present work is creating a criterion equation describing charge transfer, derived by analogy with the derivation of the substance-transfer equations. As a result, a convective electrical conductivity equation is derived, which expresses in general terms the charge-density distribution in a moving flow. The obtained equation allows us to derive the criteria of electrical similarity, namely the electrical Peclet and Prandtl numbers. The obtained electrical numbers are compared with the classical criteria in terms of their dimensionalities. Using the obtained numbers, the Nusselt number for electric mass-transfer processes is derived, which takes into account the substance transfer both due to the concentration gradient and due to the potential difference, as well as the influence on the electrodialysis separation process of the operating and limiting current density and the geometrical parameters of the plant.
ISSN:0040-5795
1608-3431
DOI:10.1134/S0040579523050524