Sensibility Study on Electrochemical Impedance of Proton Exchange Membrane Fuel Cell

doi:10.3901/JME.2021.14.040

Abstract

Abstract: Electrochemical impedance spectroscopy (EIS) can be utilized to characterize the internal state and electrochemical behaviour of fuel cell. The different polarization processes and states in the fuel cell can be identified and quantified by constructing an appropriate equivalent circuit model for impedance fitting. The effects of current density, operating temperature, pressure, cathode/anode stoichiometry, and cathode/anode relative humidity on the proton exchange membrane fuel cell's electrochemical impedance are systematically studied. Based on the equivalent circuit method, the variation of each frequency band's equivalent resistance and its sensitivity to operating conditions are analysed and discussed. The results demonstrate that fuel cell loss is dominated by activation loss, ohmic loss, and mass transfer loss at low, medium, and high current densities, respectively. Under the fixed current density, the cell temperature, pressure, cathode stoichiometry, and cathode relative humidity significantly influence the impedance spectrum. Ohmic impedance is mostly sensitive to the humidity change of anode and cathode. The anode activation impedance is mainly liable to the anode stoichiometry and anode relative humidity. The cathode activation impedance is mostly sensitive to the cathode stoichiometry, followed by temperature and pressure. Mass transfer impedance is mainly susceptible to cathode excess coefficient, followed by pressure and temperature. The experimental results provide guidance for the working condition optimization and internal state monitoring and diagnosis of fuel cell.

Key words: proton exchange membrane fuel cell, electrochemical impedance spectroscopy, equivalent circuit model, external operating conditions, sensitivity analysis

CLC Number:

TM911

ZHANG Shaozhe, DAI Haifeng, YUAN Hao, MING Pingwen, WEI Xuezhe. Sensibility Study on Electrochemical Impedance of Proton Exchange Membrane Fuel Cell[J]. Journal of Mechanical Engineering, 2021, 57(14): 40-51.

References

[1] TANG Z,HUANG Q A,WANG Y J,et al. Recent progress in the use of electrochemical impedance spectroscopy for the measurement,monitoring,diagnosis and optimization of proton exchange membrane fuel cell performance[J]. Journal of Power Sources,2020,468(25):228361-228386.
[2] NIYA S M R,HOORFAR M. Study of proton exchange membrane fuel cells using electrochemical impedance spectroscopy technique-A review[J]. Journal of Power Sources,2013,240(15):281-293.
[3] 曹楚南,张鉴清. 电化学阻抗谱导论[M]. 北京:科学出版社,2002. CAO Chunan,ZHANG Jianqing.An introduction to electrochemical impedance spectroscopy[M].Beijing:Science Press,2002.
[4] RESHETENKO T,KULIKOVSKY A. Impedance spectroscopy characterization of oxygen transport in low- and high-Pt loaded PEM fuel cells[J]. Journal of The Electrochemical Society,2017,164(14):F1633-F1640.
[5] JIANG R,MITTELSTEADT C K,GITTLEMAN C S. Through-plane proton transport resistance of membrane and ohmic resistance distribution in fuel cells[J]. Journal of the Electrochemical Society,2009,156(12):B1440-B1446.
[6] MALEVICH D,HALLIOP E,PEPPLEY B,et al. Effect of relative humidity on electrochemical active area and impedance response of PEM fuel cell[J]. ECS Transactions,2008,16(2):1763-1774.
[7] DHIRDE A M,DALE N V,SALEHFAR H,et al. Equivalent electric circuit modeling and performance analysis of a PEM fuel cell stack using impedance spectroscopy[J]. IEEE Transactions on Energy Conversion,2010,25(3):778-786.
[8] KELLER S,ÖZEL T,SCHERZER A C,et al. Characteristic time constants derived from the low-frequency arc of impedance spectra of fuel cell stacks[J]. Journal of Electrochemical Energy Conversion and Storage,2018,15(2):021002.
[9] KURZ T,HAKENJOS A,KRAEMER J,et al. An impedance-based predictive control strategy for the state-of-health of PEM fuel cell stacks[J]. Journal of Power Sources,2008,180(2):742-747.
[10] ROY S K,HAGELIN-WEAVER H,ORAZEM M E. Application of complementary analytical tools to support interpretation of polymer-electrolyte-membrane fuel cell impedance data[J]. Journal of Power Sources,2011,196(8):3736-3742.
[11] NIYA S M R,PHILLIPS R,HOORFAR M. Process modeling of the impedance characteristics of proton exchange membrane fuel cells[J]. Electrochimica Acta, 2016,191:594-605.
[12] FOUQUET N,DOULET C,NOUILLANT C. Model based PEM fuel cell state-of-health monitoring via ac impedance measurements[J]. Journal of Power Sources,2006,159(2):905-913.
[13] KUHN H,WOKAUN A,SCHERER G G. Exploring single electrode reactions in polymer electrolyte fuel cells[J]. Electrochimica Acta,2007,52(6):2322-2327.
[14] BARSOUKOV E,MACDONALD R J. Impedance spectroscopy:Theory,experiment,and applications[M]. Wiley-Interscience,2005.
[15] SCHMIDT J P,CHROBAK T,ENDER M,et al. Studies on LiFePO4 as cathode material using impedance spectroscopy[J]. Journal of Power Sources,2011,196(12):5342-5348.
[16] LEONIDE A,SONN V,WEBER A,et al. Evaluation and modeling of the cell resistance in anode-supported solid oxide fuel cells[J]. Journal of The Electrochemical Society,2008,155(1):B36-B41.
[17] WEISS A,SCHINDLER S,GALBIATI S,et al. A. Distribution of relaxation times analysis of high-temperature PEM fuel cell impedance spectra[J]. Electrochimica Acta,2017,230:391-398.
[18] PIVAC I,ŠIMIĆ B,BARBIR F. Experimental diagnostics and modeling of inductive phenomena at low frequencies in impedance spectra of proton exchange membrane fuel cells[J]. Journal of Power Sources,2017,365:240-248.