Lund University Publications

Perspectives on Lattice Boltzmann Modeling of Transport Processes with Electrochemical Reactions in SOFCs

• Mark

Abstract

Lattice Boltzmann method (LBM) is alternative computational method to the traditional computational fluid dynamic (CFD) methods. LBM has the ability to with straightforward computational procedure to handle the detail activity at microscale well for simulation of different transport processes. In this study the focus is on the effects of electrochemical reactions and transport processes in an anode of Solid Oxide Fuel Cell (SOFC) at microscale. The electrochemical reactions are captured at specific sites where the so-called three-phase boundaries (TPB) are present. The porous modeling domain is created with randomly placed spheres of two different sizes to resemble the materials Ni and YSZ for the part of the anode close to the... (More)

Lattice Boltzmann method (LBM) is alternative computational method to the traditional computational fluid dynamic (CFD) methods. LBM has the ability to with straightforward computational procedure to handle the detail activity at microscale well for simulation of different transport processes. In this study the focus is on the effects of electrochemical reactions and transport processes in an anode of Solid Oxide Fuel Cell (SOFC) at microscale. The electrochemical reactions are captured at specific sites where the so-called three-phase boundaries (TPB) are present. The porous modeling domain is created with randomly placed spheres of two different sizes to resemble the materials Ni and YSZ for the part of the anode close to the electrolyte. The simulated transport processes are mass, heat, momentum and charge transfer with electrochemical reactions. These are evaluated with the software tools Palabos and MATLAB.

It is concluded that LBM can be used to evaluate the microscopic effect of electrochemical reactions on the transport processes. Case studies are carried out on the current density and the concentration distribution of H2 by changing the porosity, percentage of active reaction sites and particle size. It is shown that an increase in porosity decreases the current density throughout the porous domain while an increase in percentage of active sites has a positive increase in current density. The concentration of H2 decreases throughout the cell when the porosity is increased from 30% to 50%. As a suggestion for future improvements, it might be a good idea to have the active reaction sites placed out in a graded manner with a high density of reaction sites where it is needed (Less)