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Numerical investigations of assisted heating cold start strategies for proton exchange membrane fuel cell systems

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  • Yang, Zirong
  • Jiao, Kui
  • Wu, Kangcheng
  • Shi, Weilong
  • Jiang, Shangfeng
  • Zhang, Longhai
  • Du, Qing

Abstract

To investigate cold start strategies at the system level, an integrated transient system model is developed, consisting of stack, membrane humidifier, electrochemical hydrogen pump, compressor, and radiator. The unassisted startup from −10 °C succeeds while it fails when started from −20 °C. To achieve the successful startup from −20 °C, various assisted strategies are adopted. For reactant gas heating method, the additional heat carried by gases is averaged about 1.2 W for each individual cell when the temperature of humidifier and hydrogen pump are maintained at 60 °C. Meanwhile, a large amount of moisture is introduced to the stack, which may lead to accelerated failure. For stack heating method, the startup succeeds if the total heating power reaches 40 W. However, the corresponding temperature difference within stack reaches as large as 22.0 °C, which indicates that improving the thermal conductivity of fuel cell materials is of great importance. Under coolant heating method, the startup succeeds if the coolant temperature reaches −5 °C, and the ice formation can even be avoided if the coolant temperature is kept at 10 °C. However, the power consumption for heating coolant is extremely large, indicating that secondary power sources are necessary.

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  • Yang, Zirong & Jiao, Kui & Wu, Kangcheng & Shi, Weilong & Jiang, Shangfeng & Zhang, Longhai & Du, Qing, 2021. "Numerical investigations of assisted heating cold start strategies for proton exchange membrane fuel cell systems," Energy, Elsevier, vol. 222(C).
    • Handle: RePEc:eee:energy:v:222:y:2021:i:c:s0360544221001596
    DOI: 10.1016/j.energy.2021.119910
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    Cited by:

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    2. Zhang, Xiaoqing & Yang, Jiapei & Ma, Xiao & Zhuge, Weilin & Shuai, Shijin, 2022. "Modelling and analysis on effects of penetration of microporous layer into gas diffusion layer in PEM fuel cells: Focusing on mass transport," Energy, Elsevier, vol. 254(PA).
    3. Xu, Jiamin & Zhang, Caizhi & Wan, Zhongmin & Chen, Xi & Chan, Siew Hwa & Tu, Zhengkai, 2022. "Progress and perspectives of integrated thermal management systems in PEM fuel cell vehicles: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 155(C).
    4. Maximilian Schmitz & Matthias Bahr & Sönke Gößling & Stefan Pischinger, 2023. "Analysis of Ice Formation during Start-Up of PEM Fuel Cells at Subzero Temperatures Using Experimental and Simulative Methods," Energies, MDPI, vol. 16(18), pages 1-26, September.
    5. Zang, Linfeng & Hao, Liang & Zhu, Xiaojing, 2023. "Effect of the pore structure of cathode catalyst layer on the PEM fuel cell cold start process," Energy, Elsevier, vol. 271(C).
    6. Dafalla, Ahmed Mohmed & Wei, Lin & Liao, Zihao & Guo, Jian & Jiang, Fangming, 2023. "Influence of cathode channel blockages on the cold start performance of proton exchange membrane fuel cell: A numerical study," Energy, Elsevier, vol. 263(PA).

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