Fuel cells are electrochemical devices that rely on the transport of reactants (oxygen
and hydrogen) and products (water and heat). These transport processes are coupled
with electrochemistry and further complicated by phase change, porous media
(gas diffusion electrodes) and a complex geometry. This thesis presents a three dimensional,
non-isothermal computational model of a proton exchange membrane
fuel cell (PEMFC). The model was developed to improve fundamental understanding
of transport phenomena in PEMFCs and to investigate the impact of various
operation parameters on performance. The model, which was implemented into a
Computational Fluid Dynamics code, accounts for all major transport phenomena,
including: water and proton transport through the membrane; electrochemical reaction;
transport of electrons; transport and phase change of water in the gas diffusion
electrodes; temperature variation; diffusion of multi-component gas mixtures in the
electrodes; pressure gradients; multi-component convective heat and mass transport
in the gas flow channels.
Simulations employing the single-phase version of the model are performed for
a straight channel section of a complete cell including the anode and cathode flow
channels. Base case simulations are presented and analyzed with a focus on the
physical insight, and fundamental understanding afforded by the availability of detailed
distributions of reactant concentrations, current densities, temperature and
water fluxes. The results are consistent with available experimental observations and
show that significant temperature gradients exist within the cell, with temperature
differences of several degrees Kelvin within the membrane-electrode-assembly. The
three-dimensional nature of the transport processes is particularly pronounced under
the collector plates land area, and has a major impact on the current distribution
and predicted limiting current density. A parametric study with the single-phase
computational model is also presented to investigate the effect of various operating,
geometric and material parameters, including temperature, pressure, stoichiometric
flow ratio, porosity and thickness of the gas diffusion layers, and the ratio between
the channel with and the land area.
The two-phase version of the computational model is used for a domain including a
cooling channel adjacent to the cell. Simulations are performed over a range of current
densities. The analysis reveals a complex interplay between several competing phase
change mechanisms in the gas diffusion electrodes. Results show that the liquid
water saturation is below 0.1 inside both anode and cathode gas diffusion layers.
For the anode side, saturation increases with increasing current density, whereas at
the cathode side saturation reaches a maximum at an intermediate current density
(≈ 1.1Amp/cm2) and decreases thereafter. The simulation show that a variety of
flow regimes for liquid water and vapour are present at different locations in the cell,
and these depend further on current density.
The PEMFC model presented in this thesis has a number of novel features that
enhance the physical realism of the simulations and provide insight, particularly in
heat and water management. The model should serve as a good foundation for future
development of a computationally based design and optimization method. / Graduate
Identifer | oai:union.ndltd.org:uvic.ca/oai:dspace.library.uvic.ca:1828/10188 |
Date | 25 October 2018 |
Creators | Beming, Torsten |
Contributors | Djilali, Nedjib |
Source Sets | University of Victoria |
Language | English, English |
Detected Language | English |
Type | Thesis |
Format | application/pdf |
Rights | Available to the World Wide Web |
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