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Experiments and microsimulation of high-pressure single-cell PEM electrolyzer

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  • Dang, Jian
  • Yang, Fuyuan
  • Li, Yangyang
  • Zhao, Yingpeng
  • Ouyang, Minggao
  • Hu, Song

Abstract

Direct hydrogen production at high pressure by the proton exchange membrane (PEM) can improve the economy of the entire hydrogen-chain. A multi-physical model of a high pressure single-cell electrolyzer is established and the heat transfer, mass transfer, and electrochemical processes are described. The water permeation flow rate is simulated accurately using experimental data obtained under 0-700 bar pressure difference. The double layer effect and mass transfer lag effect are considered in the dynamic model in terms of different time constants. Polarization curves exhibit good consistency at different temperatures and high cathode pressure, and the average the sum of squares due to error (SSE) is less than 0.01. Different film thicknesses correspond to different safe operating zones (hydrogen concentration in oxygen below 2%). A membrane thickness of 250μm allows the cathode pressure to increase to approximately 120 bar, and the minimum operating current density should not be less than 0.2 A/cm2. Increasing the cathode pressure to 200 bar can reduce the water content on the hydrogen side by more than 19.5%. Finally, the temperature control model of circulating water in the electrolysis cell is calibrated and verified by experiments, and the steady-state error is less than 2.5%.

Suggested Citation

  • Dang, Jian & Yang, Fuyuan & Li, Yangyang & Zhao, Yingpeng & Ouyang, Minggao & Hu, Song, 2022. "Experiments and microsimulation of high-pressure single-cell PEM electrolyzer," Applied Energy, Elsevier, vol. 321(C).
    • Handle: RePEc:eee:appene:v:321:y:2022:i:c:s0306261922006961
    DOI: 10.1016/j.apenergy.2022.119351
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    References listed on IDEAS

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    1. Damien Guilbert & Gianpaolo Vitale, 2019. "Dynamic Emulation of a PEM Electrolyzer by Time Constant Based Exponential Model," Energies, MDPI, vol. 12(4), pages 1-17, February.
    2. Espinosa-López, Manuel & Darras, Christophe & Poggi, Philippe & Glises, Raynal & Baucour, Philippe & Rakotondrainibe, André & Besse, Serge & Serre-Combe, Pierre, 2018. "Modelling and experimental validation of a 46 kW PEM high pressure water electrolyzer," Renewable Energy, Elsevier, vol. 119(C), pages 160-173.
    3. Olivier, Pierre & Bourasseau, Cyril & Bouamama, Pr. Belkacem, 2017. "Low-temperature electrolysis system modelling: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 78(C), pages 280-300.
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    Cited by:

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    2. Xu, Boshi & Yang, Yang & Li, Jun & Ye, Dingding & Wang, Yang & Zhang, Liang & Zhu, Xun & Liao, Qiang, 2024. "A comprehensive study of parameters distribution in a short PEM water electrolyzer stack utilizing a full-scale multi-physics model," Energy, Elsevier, vol. 300(C).
    3. Wei-Hsin Chen & Yaun-Sheng Wang & Min-Hsing Chang & Liwen Jin & Lip Huat Saw & Chih-Chia Lin & Ching-Ying Huang, 2023. "Optimization of Flow Channel Design with Porous Medium Layers in a Proton Exchange Membrane Electrolyzer Cell," Energies, MDPI, vol. 16(15), pages 1-14, July.
    4. Hu, Song & Guo, Bin & Ding, Shunliang & Yang, Fuyuan & Dang, Jian & Liu, Biao & Gu, Junjie & Ma, Jugang & Ouyang, Minggao, 2022. "A comprehensive review of alkaline water electrolysis mathematical modeling," Applied Energy, Elsevier, vol. 327(C).

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