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Influence of cathode flow pulsation on performance of proton exchange membrane fuel cell with interdigitated gas distributors

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  • Ramiar, A.
  • Mahmoudi, A.H.
  • Esmaili, Q.
  • Abdollahzadeh, M.

Abstract

In this paper, a numerical study is conducted in order to investigate the effect of pulsation of air flow at the cathode side of Proton Exchange Membrane (PEM) fuel cell with interdigitated flow field. A two dimensional, isothermal, two-phase, unsteady multi-component transport model is used in order to simulate the transport phenomena. The obtained results are discussed in terms of the influence of flow pulsation on water management and cell performance. The results prove the effectiveness of flow pulsation on improving water removal from cell, enhancing reactants transports to the reaction sites, and increasing the cell performance expressed by increment in the cell limiting current density and maximum output power. The effects of pulsation frequency (f), amplitude (Amp), and mean inlet pressure (Pin) on the performance and the output power of the cell, are also investigated. The performance of the cell has no dependency on the frequency range considered in this study. However, as the pulsation amplitude increases the increment in the cell performance is more obvious. Moreover, applying flow pulsation at low flow rates leads to higher efficiency in water removal and performance enhancement.

Suggested Citation

  • Ramiar, A. & Mahmoudi, A.H. & Esmaili, Q. & Abdollahzadeh, M., 2016. "Influence of cathode flow pulsation on performance of proton exchange membrane fuel cell with interdigitated gas distributors," Energy, Elsevier, vol. 94(C), pages 206-217.
    • Handle: RePEc:eee:energy:v:94:y:2016:i:c:p:206-217
    DOI: 10.1016/j.energy.2015.10.110
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    Cited by:

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    2. Chen, Ben & Wang, Jun & Yang, Tianqi & Cai, Yonghua & Zhang, Caizhi & Chan, Siew Hwa & Yu, Yi & Tu, Zhengkai, 2016. "Carbon corrosion and performance degradation mechanism in a proton exchange membrane fuel cell with dead-ended anode and cathode," Energy, Elsevier, vol. 106(C), pages 54-62.
    3. Xu, Liangfei & Fang, Chuan & Hu, Junming & Cheng, Siliang & Li, Jianqiu & Ouyang, Minggao & Lehnert, Werner, 2017. "Parameter extraction of polymer electrolyte membrane fuel cell based on quasi-dynamic model and periphery signals," Energy, Elsevier, vol. 122(C), pages 675-690.
    4. Asadi, Mohammad Reza & Ghasabehi, Mehrdad & Ghanbari, Sina & Shams, Mehrzad, 2024. "The optimization of an innovative interdigitated flow field proton exchange membrane fuel cell by using artificial intelligence," Energy, Elsevier, vol. 290(C).
    5. Ijaodola, O.S. & El- Hassan, Zaki & Ogungbemi, E. & Khatib, F.N. & Wilberforce, Tabbi & Thompson, James & Olabi, A.G., 2019. "Energy efficiency improvements by investigating the water flooding management on proton exchange membrane fuel cell (PEMFC)," Energy, Elsevier, vol. 179(C), pages 246-267.
    6. Abdollahzadeh, M. & Ribeirinha, P. & Boaventura, M. & Mendes, A., 2018. "Three-dimensional modeling of PEMFC with contaminated anode fuel," Energy, Elsevier, vol. 152(C), pages 939-959.
    7. Guo, Hang & Liu, Xuan & Zhao, Jian Fu & Ye, Fang & Ma, Chong Fang, 2016. "Effect of low gravity on water removal inside proton exchange membrane fuel cells (PEMFCs) with different flow channel configurations," Energy, Elsevier, vol. 112(C), pages 926-934.
    8. Chowdhury, Mohammad Ziauddin & Timurkutluk, Bora, 2018. "Transport phenomena of convergent and divergent serpentine flow fields for PEMFC," Energy, Elsevier, vol. 161(C), pages 104-117.

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