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Spatially resolved oxygen reaction, water, and temperature distribution: Experimental results as a function of flow field and implications for polymer electrolyte fuel cell operation

Author

Listed:
  • Lopes, Thiago
  • Beruski, Otavio
  • Manthanwar, Amit M.
  • Korkischko, Ivan
  • Pugliesi, Reynaldo
  • Stanojev, Marco Antonio
  • Andrade, Marcos Leandro Garcia
  • Pistikopoulos, Efstratios N.
  • Perez, Joelma
  • Fonseca, Fabio Coral
  • Meneghini, Julio Romano
  • Kucernak, Anthony R.

Abstract

In situ and ex situ spatially-resolved techniques are employed to investigate reactant distribution and its impacts in a polymer electrolyte fuel cell. Temperature distribution data provides further evidence for secondary flows inferred from reactant imaging data, highlighting the contribution of convection in heat as well as reactant distribution. Water build-up from neutron tomography is linked to component degradation, matching the pattern seen in the reactant distribution and thus suggesting that high, non-uniform local current densities shape degradation patterns in fuel cells. The correlations shown between different techniques confirm the use of the versatile reactant imaging technique, which is used to compare commonly used flow field designs. Among serpentine-type designs, the single serpentine is superior in both equivalent current density and reactant distribution, showing large contributions from convective flow. On the other hand, the interdigitated design is shown to produce larger equivalent current densities, while showing a somewhat poorer reactant distribution. Considering the correlations drawn between the techniques, this suggests that the interdigitated design compromises durability in favour of power output. The results highlight how established techniques provide a robust background for the use of a new and flexible imaging technique toward designing advanced flow fields for practical fuel cell applications.

Suggested Citation

  • Lopes, Thiago & Beruski, Otavio & Manthanwar, Amit M. & Korkischko, Ivan & Pugliesi, Reynaldo & Stanojev, Marco Antonio & Andrade, Marcos Leandro Garcia & Pistikopoulos, Efstratios N. & Perez, Joelma , 2019. "Spatially resolved oxygen reaction, water, and temperature distribution: Experimental results as a function of flow field and implications for polymer electrolyte fuel cell operation," Applied Energy, Elsevier, vol. 252(C), pages 1-1.
    • Handle: RePEc:eee:appene:v:252:y:2019:i:c:14
    DOI: 10.1016/j.apenergy.2019.113421
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    References listed on IDEAS

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    1. Wang, Junye, 2015. "Barriers of scaling-up fuel cells: Cost, durability and reliability," Energy, Elsevier, vol. 80(C), pages 509-521.
    2. John P. Lemmon, 2015. "Energy: Reimagine fuel cells," Nature, Nature, vol. 525(7570), pages 447-449, September.
    3. Christos Kalyvas & Anthony Kucernak & Dan Brett & Gareth Hinds & Steve Atkins & Nigel Brandon, 2014. "Spatially resolved diagnostic methods for polymer electrolyte fuel cells: a review," Wiley Interdisciplinary Reviews: Energy and Environment, Wiley Blackwell, vol. 3(3), pages 254-275, May.
    4. Baik, Kyung Don & Seo, Il Sung, 2018. "Metallic bipolar plate with a multi-hole structure in the rib regions for polymer electrolyte membrane fuel cells," Applied Energy, Elsevier, vol. 212(C), pages 333-339.
    5. Kwan-Soo Lee & Jacob S. Spendelow & Yoong-Kee Choe & Cy Fujimoto & Yu Seung Kim, 2016. "An operationally flexible fuel cell based on quaternary ammonium-biphosphate ion pairs," Nature Energy, Nature, vol. 1(9), pages 1-7, September.
    6. Wang, Junye, 2015. "Theory and practice of flow field designs for fuel cell scaling-up: A critical review," Applied Energy, Elsevier, vol. 157(C), pages 640-663.
    7. Robert C. Armstrong & Catherine Wolfram & Krijn P. de Jong & Robert Gross & Nathan S. Lewis & Brenda Boardman & Arthur J. Ragauskas & Karen Ehrhardt-Martinez & George Crabtree & M. V. Ramana, 2016. "The frontiers of energy," Nature Energy, Nature, vol. 1(1), pages 1-8, January.
    8. Daniel Malko & Anthony Kucernak & Thiago Lopes, 2016. "In situ electrochemical quantification of active sites in Fe–N/C non-precious metal catalysts," Nature Communications, Nature, vol. 7(1), pages 1-7, December.
    9. Singdeo, Debanand & Dey, Tapobrata & Gaikwad, Shrihari & Andreasen, Søren Juhl & Ghosh, Prakash C., 2017. "A new modified-serpentine flow field for application in high temperature polymer electrolyte fuel cell," Applied Energy, Elsevier, vol. 195(C), pages 13-22.
    10. Huo, Sen & Cooper, Nathanial James & Smith, Travis Lee & Park, Jae Wan & Jiao, Kui, 2017. "Experimental investigation on PEM fuel cell cold start behavior containing porous metal foam as cathode flow distributor," Applied Energy, Elsevier, vol. 203(C), pages 101-114.
    11. Nastaran Ranjbar Sahraie & Ulrike I. Kramm & Julian Steinberg & Yuanjian Zhang & Arne Thomas & Tobias Reier & Jens-Peter Paraknowitsch & Peter Strasser, 2015. "Quantifying the density and utilization of active sites in non-precious metal oxygen electroreduction catalysts," Nature Communications, Nature, vol. 6(1), pages 1-9, December.
    12. Li, Wenkai & Zhang, Qinglei & Wang, Chao & Yan, Xiaohui & Shen, Shuiyun & Xia, Guofeng & Zhu, Fengjuan & Zhang, Junliang, 2017. "Experimental and numerical analysis of a three-dimensional flow field for PEMFCs," Applied Energy, Elsevier, vol. 195(C), pages 278-288.
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