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Numerical simulation of multi-scale transport processes and reactions in pem fuel cells using two-phase models

Khan, Munir LU ; Yuan, Jinliang LU and Sundén, Bengt LU (2009)
Abstract
A numerical study for the cathode of a PEM fuel cell has been performed in this study. The results have been limited to cathode only because, in PEM fuel cells, the oxygen reduction reactions, ORRs, are considered the rate limiting reactions and govern the fuel cell performance.



The modeling approach utilized the two-phase models involving water phase change for PEM fuel cells i.e. two-phase current (solid and membrane), two-phase flow (gas and liquid water) and two-phase temperature (fluid and solid). The catalyst layer has been modeled using the microscale agglomerate approach where diffusion of oxygen into the agglomerate structure was used to model the reaction rates.



For comparison of the PEM fuel... (More)
A numerical study for the cathode of a PEM fuel cell has been performed in this study. The results have been limited to cathode only because, in PEM fuel cells, the oxygen reduction reactions, ORRs, are considered the rate limiting reactions and govern the fuel cell performance.



The modeling approach utilized the two-phase models involving water phase change for PEM fuel cells i.e. two-phase current (solid and membrane), two-phase flow (gas and liquid water) and two-phase temperature (fluid and solid). The catalyst layer has been modeled using the microscale agglomerate approach where diffusion of oxygen into the agglomerate structure was used to model the reaction rates.



For comparison of the PEM fuel cell performance, detailed study was performed at load conditions of current densities of 0.22, 0.57 and 0.89 A/cm2 explicitly. A varying fuel cell performance was observed under different loads. At low current densities, the temperature, electro-osmotic drag, irreversible and losses are quite low but the membrane phase conductivity showed a decreasing pattern along the length of the cathode. At higher current density (0.89 A/cm2), a sharp decrease in the current was observed due to the mass limitation effects, and due to higher water content, the water flooding effect was observed as more prominent than at lower current densities.



The maximum power density for the present case was observed at 0.55 V. By comparing the results of this study and previous study with single phase flow model, it can be seen that this model is more conservative and captures the mass limitation effects to a great extent and the maximum power density as predicted by the single phase models falls in the mass limitation zone. (Less)
Please use this url to cite or link to this publication:
author
; and
supervisor
organization
publishing date
type
Thesis
publication status
published
subject
keywords
numerical analysis, multi-scale, multi-phase, reacting flows, multi-component
publisher
Lunds tekniska högskola, Institutionen för värme- och kraftteknik
language
English
LU publication?
yes
id
eccacbe3-2785-4759-a6c8-6812084bc2c0 (old id 2205847)
date added to LUP
2016-04-01 13:36:45
date last changed
2018-11-21 20:17:57
@misc{eccacbe3-2785-4759-a6c8-6812084bc2c0,
  abstract     = {{A numerical study for the cathode of a PEM fuel cell has been performed in this study. The results have been limited to cathode only because, in PEM fuel cells, the oxygen reduction reactions, ORRs, are considered the rate limiting reactions and govern the fuel cell performance.<br/><br>
<br/><br>
The modeling approach utilized the two-phase models involving water phase change for PEM fuel cells i.e. two-phase current (solid and membrane), two-phase flow (gas and liquid water) and two-phase temperature (fluid and solid). The catalyst layer has been modeled using the microscale agglomerate approach where diffusion of oxygen into the agglomerate structure was used to model the reaction rates.<br/><br>
<br/><br>
For comparison of the PEM fuel cell performance, detailed study was performed at load conditions of current densities of 0.22, 0.57 and 0.89 A/cm2 explicitly. A varying fuel cell performance was observed under different loads. At low current densities, the temperature, electro-osmotic drag, irreversible and losses are quite low but the membrane phase conductivity showed a decreasing pattern along the length of the cathode. At higher current density (0.89 A/cm2), a sharp decrease in the current was observed due to the mass limitation effects, and due to higher water content, the water flooding effect was observed as more prominent than at lower current densities.<br/><br>
<br/><br>
The maximum power density for the present case was observed at 0.55 V. By comparing the results of this study and previous study with single phase flow model, it can be seen that this model is more conservative and captures the mass limitation effects to a great extent and the maximum power density as predicted by the single phase models falls in the mass limitation zone.}},
  author       = {{Khan, Munir and Yuan, Jinliang and Sundén, Bengt}},
  keywords     = {{numerical analysis; multi-scale; multi-phase; reacting flows; multi-component}},
  language     = {{eng}},
  note         = {{Licentiate Thesis}},
  publisher    = {{Lunds tekniska högskola, Institutionen för värme- och kraftteknik}},
  title        = {{Numerical simulation of multi-scale transport processes and reactions in pem fuel cells using two-phase models}},
  url          = {{https://lup.lub.lu.se/search/files/3477505/2205860.pdf}},
  year         = {{2009}},
}