Degradation modeling of high temperature proton exchange membrane fuel cells using dual time scale simulation

Degradation modeling of high temperature proton exchange membrane fuel cells using dual time scale simulation

HT-PEM fuel cells suffer from performance losses due to degradation effects. Therefore, the durability of HT-PEM is currently an important factor of research and development. In this paper a novel approach is presented for an integrated short term and long term simulation of HT-PEM accelerated lifet...

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Bibliographic Details
Published in:Journal of power sources Vol. 275; pp. 777 - 784
Main Authors: Pohl, E., Maximini, M., Bauschulte, A., vom Schloß, J., Hermanns, R.T.E.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-02-2015
Subjects:
Accelerated stress test
Accelerated tests
Computer simulation
Degradation
Dual time scale simulation
Durability
Dynamics
Electrochemical impedance spectroscopy
Fuel cells
HT-PEM fuel cells
Life cycle assessment
Mathematical models
OCV test
Time
Degradation
Dual time scale simulation
HT-PEM fuel cells
OCV test
Durability
Accelerated stress test
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Summary:HT-PEM fuel cells suffer from performance losses due to degradation effects. Therefore, the durability of HT-PEM is currently an important factor of research and development. In this paper a novel approach is presented for an integrated short term and long term simulation of HT-PEM accelerated lifetime testing. The physical phenomena of short term and long term effects are commonly modeled separately due to the different time scales. However, in accelerated lifetime testing, long term degradation effects have a crucial impact on the short term dynamics. Our approach addresses this problem by applying a novel method for dual time scale simulation. A transient system simulation is performed for an open voltage cycle test on a HT-PEM fuel cell for a physical time of 35 days. The analysis describes the system dynamics by numerical electrochemical impedance spectroscopy. Furthermore, a performance assessment is performed in order to demonstrate the efficiency of the approach. The presented approach reduces the simulation time by approximately 73% compared to conventional simulation approach without losing too much accuracy. The approach promises a comprehensive perspective considering short term dynamic behavior and long term degradation effects. •Electrochemical effects, thermal effects and degradation effects are described.•An efficient numerical model for long term simulations is presented.•A formal dual time scale simulation approach is proposed.•Analysis of simulation duration and accuracy are performed.
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content type line 23
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2014.11.054