On the modelling of the electrochemical phenomena at the electrode-solution interface of a PEF treatment chamber: Effect of electrical parameters and chemical composition of model liquid food

•Use of a Multiphysics model to predict the metals release phenomena in a PEF chamber.•The amount of metal releases increases with increasing the PEF treatment intensity.•Pulse frequency is the main parameter affecting the occurrence of the metal release.•The presence of halides in the medium compos...

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Bibliographic Details
Published in:Journal of food engineering 2015-11, Vol.165, p.45-51
Main Authors: Pataro, Gianpiero, Barca, Giuseppe M.J., Donsì, Giorgio, Ferrari, Giovanna
Format: Article
Language:English
Subjects:
Electrical parameters
Finite Element Method (FEM)
Metal release
Product composition
Pulsed electric field (PEF)
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Summary:•Use of a Multiphysics model to predict the metals release phenomena in a PEF chamber.•The amount of metal releases increases with increasing the PEF treatment intensity.•Pulse frequency is the main parameter affecting the occurrence of the metal release.•The presence of halides in the medium composition reduces the electrodes lifetime. In this work, a Multiphysics model based on the Finite Element Method (FEM), was used to study the effect of different electrical parameters as well as chemical composition of the treatment medium on the metal release from the stainless steel (type AISI 316L) electrodes of a PEF chamber. A total of 15 processing conditions obtained by coupling different field strength (12–31kV/cm) and total specific energy input (20–100kJ/kg) were simulated with two model liquid food solutions with the same pH (7) and electrical conductivity (2mS/cm at 25°C) but different halides concentration. The results showed that the concentration of metallic elements (Fe, Cr and Ni) increased with decreasing the field strength applied or increasing the total specific energy input. These results were attributed to the predominant effect of the pulse frequency, rather than the applied voltage, on the average Faradaic current density values which, in turn, determine the extent of the metal release. Moreover, it was shown that the presence of halides in the composition of the processed product, may lower the breakdown potential and increase the Faradaic current density value which lead to an intense localized metal release from the electrode’s surface.
ISSN:0260-8774
1873-5770
DOI:10.1016/j.jfoodeng.2015.05.010