Current Distribution and Cathode Flooding Prediction in a PEM Fuel Cell
Non-uniform current distribution in polymer
electrolyte membrane fuel cells results in local over-heating,
accelerated ageing, and lower power output than expected. This
issue is very critical when fuel cell experiences water flooding. In
this work, the performance of a PEM fuel cell is investigated under
cathode flooding conditions. Two-dimensional partially flooded
GDL models based on the conservation laws and electrochemical
relations are proposed to study local current density distributions
along flow fields over a wide range of cell operating conditions.
The model results show a direct association between cathode inlet
humidity increases and that of average current density but the
system becomes more sensitive to flooding. The anode inlet
relative humidity shows a similar effect. Operating the cell at
higher temperatures would lead to higher average current densities
and the chance of system being flooded is reduced. In addition,
higher cathode stoichiometries prevent system flooding but the
average current density remains almost constant. The higher anode
stoichiometry leads to higher average current density and higher
sensitivity to cathode flooding.
[1] F. Barbir, PEM Fuel Cells: Theory and Practice. USA: Elsevier
Academic Press, 2005.
[2] C. K. Dyer, "Fuel Cells for Portable Applications," J. Power Sources,
vol. 106, pp. 31-34, 2002.
[3] J. J. Hwang, D. Y. Wang, and N. C. Shih, "Development of a
Lightweight Fuel Cell Vehicle," J. Power Sources, vol. 141, pp. 108-
115, 2005.
[4] S. J. C. Cleghorn, C. R. Derouin, M. S. Wilson, and S. Gottesfeld, "A
Printed Circuit Board Approach to Measuring Current Distribution in
a Fuel Cell," J. Applied Electrochemistry, vol. 28, pp. 663-672, 1998.
[5] J. J. Hwnag, W. R. Chang, R. G. Penng, P. Y. Chen, and A. Su,
"Experimental and Numerical Studies of Local Current Mapping on a
PEM Fuel Cell," Int. J. of Hydrogen Energy, vol. 33, pp. 5718-5727,
2008.
[6] F. B. Weng, A. Su, G. B. Jung, Y. C. Chiu, and S. H. Chan,
"Numerical Prediction of Concentration and Current Distributions in
PEMFC," J. Power Sources, vol. 145, pp. 546-554, 2005.
[7] C. Wieser, A. Helmbold, and E. Glzow, "A New Technique for Two-
Dimensional Current Distribution Measurements in Electrochemical
Cells," J. Applied Electrochemistry, vol. 30, pp. 803-807, 2000.
[8] J. J. Baschuk, and X. Li, "Modelling of Polymer Electrolyte
Membrane Fuel Cells with Variable Degrees of Water Flooding," J.
Power Sources, vol. 86, pp. 181-196, 2000.
[9] J. Larminie, and A. Dicks, Fuel Cell Systems Explained, John Wiley
and Sons, 2003.
[10] A. Hakenjos, H. Muenter, U. Wittstadt, and C. Hebling, "A PEM Fuel
Cell for Combined Measurement of Current and Temperature
Distribution, and Flow Field Flooding," J. Power Sources, vol. 131,
pp. 213-216, 2004.
[11] M. Noponen, T. Mennola, M. Mikkola, T. Hottinen, and P. Lund,
"Measurement of Current Distribution in a Free-Breathing PEMFC,"
J. Power Sources, vol. 106, pp. 304-312, 2002.
[12] Y. G. Yoon, W. Y. Lee, T. H. Yang, G. G. Park, and C. S. Kim,
"Current Distribution in a Single Cell of PEMFC," J. Power Sources,
vol. 118, pp. 193-199, 2003.
[13] G. Bender, M. S. Wilson, and T. A. Zawodzinski, "Further
Refinements in the Segmented Cell Approach to Diagnosing
Performance in Polymer Electrolyte Fuel Cells," J. Power Sources,
vol. 123, pp. 163-171, 2003.
[14] A. B. Geiger, R. Eckl, A. Wokaun, and G.G. Scherer, "An approach to
measuring locally resolved currents in polymer electrolyte fuel cells,"
J. Electrochem. Soc., vol. 151, pp. A394-A398, 2004.
[15] M. M. Mench, C. Y. Wang, and M. Ishikawa, "In Situ Current
Distribution Measurements in Polymer Electrolyte Fuel Cells," J.
Electrochem. Soc., vol. 150, pp. A1052-A1059, 2003.
[16] Z. Liu, Z. Mao, and C. Wang, "A Two Dimensional Partial Flooding
Model for PEMFC," J. Power Sources, vol. 158, pp. 1229-1239,
2006.
[17] J. J. Baschuk, and X. Li, "A general formulation for a mathematical
PEM fuel cell model," J. Power Sources, vol. 142, pp. 134-153, 2004.
[18] G. Inoue, Y. Matsukuma, and M. Minemoto, "Effect of gas channel
depth on current density distribution of polymer electrolyte fuel cell
by numerical analysis including gas flow through gas diffusion layer,"
J. Power Sources, vol. 157, pp. 136-152, 2006.
[19] X. Li, Principles of Fuel Cells. New York: Taylor & Francis, 2006.
[20] G. Karimi, F. Jafarpour, and X. Li, "Characterization of flooding and
two-phase flow in polymer electrolyte membrane fuel cell stacks," J.
Power Sources, vol. 187, pp. 156-164, 2009.
[21] A. Jamekhorshid, G. Karimi, and X. Li, "Current Distribution in a
Polymer Electrolyte Membrane Fuel Cell under Flooding Conditions,"
in Proc. 7th Int. Fuel Cell Science, Engineering & Technology Conf.,
California, 2009.
[22] T. V. Nguyen, and R. E. White, "A Water and Heat Management
Model for Proton-Exchange-Membrane Fuel Cells," J. Electrochem.
Soc., vol. 140, pp. 2178-2186, 1993.
[23] T. E. Springer, T. A. Zawodzinski, and S. Gottesfeld, "Polymer
Electrolyte Fuel Cell Model," J. Electrochem. Soc., vol. 138, pp.
2334-2342, 1991.
[24] C. L. Marr, "Performance Modelling of a Proton Exchange Membrane
Fuel Cell," M.S. Thesis Dept. Mech. Eng., University of Victoria,
Canada, 1996.
[25] D. M. Bernardi, and M. W. Verbrugge, "A Mathematical Model of the
Solid-Polymer-Electrolyte Fuel Cell," J. Electrochem. Soc., vol. 139,
pp. 2477-2491, 1992.
[26] S. Kakac, R. S. Shah, and W. Aung, Handbook of Single-phase
Convective Heat Transfer. New York: John Wiley and Sons, 1987,
pp. 345-349.
[27] Chemical Engineering Handbook, 5th ed., McGraw-Hill, 1983.
[1] F. Barbir, PEM Fuel Cells: Theory and Practice. USA: Elsevier
Academic Press, 2005.
[2] C. K. Dyer, "Fuel Cells for Portable Applications," J. Power Sources,
vol. 106, pp. 31-34, 2002.
[3] J. J. Hwang, D. Y. Wang, and N. C. Shih, "Development of a
Lightweight Fuel Cell Vehicle," J. Power Sources, vol. 141, pp. 108-
115, 2005.
[4] S. J. C. Cleghorn, C. R. Derouin, M. S. Wilson, and S. Gottesfeld, "A
Printed Circuit Board Approach to Measuring Current Distribution in
a Fuel Cell," J. Applied Electrochemistry, vol. 28, pp. 663-672, 1998.
[5] J. J. Hwnag, W. R. Chang, R. G. Penng, P. Y. Chen, and A. Su,
"Experimental and Numerical Studies of Local Current Mapping on a
PEM Fuel Cell," Int. J. of Hydrogen Energy, vol. 33, pp. 5718-5727,
2008.
[6] F. B. Weng, A. Su, G. B. Jung, Y. C. Chiu, and S. H. Chan,
"Numerical Prediction of Concentration and Current Distributions in
PEMFC," J. Power Sources, vol. 145, pp. 546-554, 2005.
[7] C. Wieser, A. Helmbold, and E. Glzow, "A New Technique for Two-
Dimensional Current Distribution Measurements in Electrochemical
Cells," J. Applied Electrochemistry, vol. 30, pp. 803-807, 2000.
[8] J. J. Baschuk, and X. Li, "Modelling of Polymer Electrolyte
Membrane Fuel Cells with Variable Degrees of Water Flooding," J.
Power Sources, vol. 86, pp. 181-196, 2000.
[9] J. Larminie, and A. Dicks, Fuel Cell Systems Explained, John Wiley
and Sons, 2003.
[10] A. Hakenjos, H. Muenter, U. Wittstadt, and C. Hebling, "A PEM Fuel
Cell for Combined Measurement of Current and Temperature
Distribution, and Flow Field Flooding," J. Power Sources, vol. 131,
pp. 213-216, 2004.
[11] M. Noponen, T. Mennola, M. Mikkola, T. Hottinen, and P. Lund,
"Measurement of Current Distribution in a Free-Breathing PEMFC,"
J. Power Sources, vol. 106, pp. 304-312, 2002.
[12] Y. G. Yoon, W. Y. Lee, T. H. Yang, G. G. Park, and C. S. Kim,
"Current Distribution in a Single Cell of PEMFC," J. Power Sources,
vol. 118, pp. 193-199, 2003.
[13] G. Bender, M. S. Wilson, and T. A. Zawodzinski, "Further
Refinements in the Segmented Cell Approach to Diagnosing
Performance in Polymer Electrolyte Fuel Cells," J. Power Sources,
vol. 123, pp. 163-171, 2003.
[14] A. B. Geiger, R. Eckl, A. Wokaun, and G.G. Scherer, "An approach to
measuring locally resolved currents in polymer electrolyte fuel cells,"
J. Electrochem. Soc., vol. 151, pp. A394-A398, 2004.
[15] M. M. Mench, C. Y. Wang, and M. Ishikawa, "In Situ Current
Distribution Measurements in Polymer Electrolyte Fuel Cells," J.
Electrochem. Soc., vol. 150, pp. A1052-A1059, 2003.
[16] Z. Liu, Z. Mao, and C. Wang, "A Two Dimensional Partial Flooding
Model for PEMFC," J. Power Sources, vol. 158, pp. 1229-1239,
2006.
[17] J. J. Baschuk, and X. Li, "A general formulation for a mathematical
PEM fuel cell model," J. Power Sources, vol. 142, pp. 134-153, 2004.
[18] G. Inoue, Y. Matsukuma, and M. Minemoto, "Effect of gas channel
depth on current density distribution of polymer electrolyte fuel cell
by numerical analysis including gas flow through gas diffusion layer,"
J. Power Sources, vol. 157, pp. 136-152, 2006.
[19] X. Li, Principles of Fuel Cells. New York: Taylor & Francis, 2006.
[20] G. Karimi, F. Jafarpour, and X. Li, "Characterization of flooding and
two-phase flow in polymer electrolyte membrane fuel cell stacks," J.
Power Sources, vol. 187, pp. 156-164, 2009.
[21] A. Jamekhorshid, G. Karimi, and X. Li, "Current Distribution in a
Polymer Electrolyte Membrane Fuel Cell under Flooding Conditions,"
in Proc. 7th Int. Fuel Cell Science, Engineering & Technology Conf.,
California, 2009.
[22] T. V. Nguyen, and R. E. White, "A Water and Heat Management
Model for Proton-Exchange-Membrane Fuel Cells," J. Electrochem.
Soc., vol. 140, pp. 2178-2186, 1993.
[23] T. E. Springer, T. A. Zawodzinski, and S. Gottesfeld, "Polymer
Electrolyte Fuel Cell Model," J. Electrochem. Soc., vol. 138, pp.
2334-2342, 1991.
[24] C. L. Marr, "Performance Modelling of a Proton Exchange Membrane
Fuel Cell," M.S. Thesis Dept. Mech. Eng., University of Victoria,
Canada, 1996.
[25] D. M. Bernardi, and M. W. Verbrugge, "A Mathematical Model of the
Solid-Polymer-Electrolyte Fuel Cell," J. Electrochem. Soc., vol. 139,
pp. 2477-2491, 1992.
[26] S. Kakac, R. S. Shah, and W. Aung, Handbook of Single-phase
Convective Heat Transfer. New York: John Wiley and Sons, 1987,
pp. 345-349.
[27] Chemical Engineering Handbook, 5th ed., McGraw-Hill, 1983.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:57953", author = "A. Jamekhorshid and G. Karimi and I. Noshadi and A. Jahangiri", title = "Current Distribution and Cathode Flooding Prediction in a PEM Fuel Cell", abstract = "Non-uniform current distribution in polymer
electrolyte membrane fuel cells results in local over-heating,
accelerated ageing, and lower power output than expected. This
issue is very critical when fuel cell experiences water flooding. In
this work, the performance of a PEM fuel cell is investigated under
cathode flooding conditions. Two-dimensional partially flooded
GDL models based on the conservation laws and electrochemical
relations are proposed to study local current density distributions
along flow fields over a wide range of cell operating conditions.
The model results show a direct association between cathode inlet
humidity increases and that of average current density but the
system becomes more sensitive to flooding. The anode inlet
relative humidity shows a similar effect. Operating the cell at
higher temperatures would lead to higher average current densities
and the chance of system being flooded is reduced. In addition,
higher cathode stoichiometries prevent system flooding but the
average current density remains almost constant. The higher anode
stoichiometry leads to higher average current density and higher
sensitivity to cathode flooding.", keywords = "Current distribution, Flooding, Hydrogen energysystem, PEM fuel cell.", volume = "4", number = "2", pages = "210-9", }
