Litcius/Paper detail

Kinetic Modeling and Numerical Simulation as Tools to Scale Microalgae Cell Membrane Permeabilization by Means of Pulsed Electric Fields (PEF) From Lab to Pilot Plants

Justus Knappert, Christopher McHardy, Cornelia Rauh

2020Frontiers in Bioengineering and Biotechnology27 citationsDOIOpen Access PDF

Abstract

was developed in the present work. The model describes the fraction of perforated cells as a function of the electric field strength, the temperature and the treatment time by using data which were obtained in a milliliter scale batchwise treatment chamber. Thereafter, the model was implemented in a CFD simulation of a pilot-scale continuous treatment chamber with colinear electrode arrangement. The numerical results were compared to experimental measurements of cell permeabilization in a similar continuous treatment chamber. The predicted values and the experimental data agree reasonably well what demonstrates the validity of the proposed model. Therefore, it can be applied to any possible treatment chamber geometry and can be used as a tool for scaling cell permeabilization of microalgae by means of PEF from lab to pilot scale. The present work provides the first contribution showing the applicability of kinetic modeling and numerical simulation for designing PEF processes for the purpose of biorefining microalgae biomass. This can help to develop new processes and to reduce the costs for the development of new treatment chamber designs.

Topics & Concepts

Electric fieldChlorella vulgarisPerforationVoltageScale (ratio)Kinetic energyMechanicsProcess engineeringEnvironmental scienceMaterials scienceNuclear engineeringElectrical engineeringPhysicsBiologyEngineeringComposite materialAlgaeEcologyPunchingQuantum mechanicsMicrobial Inactivation MethodsElectrohydrodynamics and Fluid Dynamics