Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle

Ahmet Kusoglu; Anette M. Karlsson; Michael H. Santare; Simon Cleghorn; William B. Johnson

doi:10.1016/j.jpowsour.2006.05.020

Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle

Ahmet Kusoglu, Anette M. Karlsson, Michael H. Santare, Simon Cleghorn, William B. Johnson

Research output: Contribution to journal › Article › peer-review

Abstract

The mechanical response of fuel cell proton exchange membranes subjected to a single hygro-thermal duty cycle in a fuel cell assembly is investigated through numerical means. To this end, the behavior of the membrane with temperature and humidity dependent material properties is simulated under temperature and humidity loading and unloading conditions. The stress-evolution during a simplified operating cycle is determined using finite element analysis for two clamping methods and two alignments of the bipolar plates. It is shown that compressive, plastic deformation occurs during the hygro-thermal loading, resulting in tensile residual stresses after unloading. These residual in-plane stresses in the membrane may explain the occurrence of cracks and pinholes in the membrane under cyclic loading.

Original language	American English
Journal	Journal of Power Sources
Volume	161
DOIs	https://doi.org/10.1016/j.jpowsour.2006.05.020
State	Published - Oct 27 2006

Keywords

Proton exchange membrane (PEM); Nafion®; ; Hygro-thermal loading; Mechanical response; Linear-elastic
perfectly plastic

Disciplines

Mechanical Engineering

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10.1016/j.jpowsour.2006.05.020License: CC BY

Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-TFinal published version, 2.34 MBLicense: CC BY

http://journals.ohiolink.edu/ejc/article.cgi?issn=03787753&issue=v161i0002&article=987_mrofcmstahc

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title = "Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle",

abstract = " The mechanical response of fuel cell proton exchange membranes subjected to a single hygro-thermal duty cycle in a fuel cell assembly is investigated through numerical means. To this end, the behavior of the membrane with temperature and humidity dependent material properties is simulated under temperature and humidity loading and unloading conditions. The stress-evolution during a simplified operating cycle is determined using finite element analysis for two clamping methods and two alignments of the bipolar plates. It is shown that compressive, plastic deformation occurs during the hygro-thermal loading, resulting in tensile residual stresses after unloading. These residual in-plane stresses in the membrane may explain the occurrence of cracks and pinholes in the membrane under cyclic loading.",

keywords = "Proton exchange membrane (PEM); Nafion{\textregistered}; ; Hygro-thermal loading; Mechanical response; Linear-elastic, perfectly plastic",

author = "Ahmet Kusoglu and Karlsson, \{Anette M.\} and Santare, \{Michael H.\} and Simon Cleghorn and Johnson, \{William B.\}",

note = "Kusoglu, A., Karlsson, A. M., Santare, M. H., 2006, {"}Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle,{"} Journal of Power Sources, 161(2), pp. 987-996.",

year = "2006",

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day = "27",

doi = "10.1016/j.jpowsour.2006.05.020",

language = "American English",

volume = "161",

journal = "Journal of Power Sources",

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TY - JOUR

T1 - Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle

AU - Kusoglu, Ahmet

AU - Karlsson, Anette M.

AU - Santare, Michael H.

AU - Cleghorn, Simon

AU - Johnson, William B.

N1 - Kusoglu, A., Karlsson, A. M., Santare, M. H., 2006, "Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle," Journal of Power Sources, 161(2), pp. 987-996.

PY - 2006/10/27

Y1 - 2006/10/27

N2 - The mechanical response of fuel cell proton exchange membranes subjected to a single hygro-thermal duty cycle in a fuel cell assembly is investigated through numerical means. To this end, the behavior of the membrane with temperature and humidity dependent material properties is simulated under temperature and humidity loading and unloading conditions. The stress-evolution during a simplified operating cycle is determined using finite element analysis for two clamping methods and two alignments of the bipolar plates. It is shown that compressive, plastic deformation occurs during the hygro-thermal loading, resulting in tensile residual stresses after unloading. These residual in-plane stresses in the membrane may explain the occurrence of cracks and pinholes in the membrane under cyclic loading.

AB - The mechanical response of fuel cell proton exchange membranes subjected to a single hygro-thermal duty cycle in a fuel cell assembly is investigated through numerical means. To this end, the behavior of the membrane with temperature and humidity dependent material properties is simulated under temperature and humidity loading and unloading conditions. The stress-evolution during a simplified operating cycle is determined using finite element analysis for two clamping methods and two alignments of the bipolar plates. It is shown that compressive, plastic deformation occurs during the hygro-thermal loading, resulting in tensile residual stresses after unloading. These residual in-plane stresses in the membrane may explain the occurrence of cracks and pinholes in the membrane under cyclic loading.

KW - Proton exchange membrane (PEM); Nafion®; ; Hygro-thermal loading; Mechanical response; Linear-elastic

KW - perfectly plastic

UR - https://engagedscholarship.csuohio.edu/enme_facpub/28

U2 - 10.1016/j.jpowsour.2006.05.020

DO - 10.1016/j.jpowsour.2006.05.020

M3 - Article

VL - 161

JO - Journal of Power Sources

JF - Journal of Power Sources

ER -

Mechanical Response of Fuel Cell Membranes Subjected to a Hygro-Thermal Cycle

Abstract

Keywords

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