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Factor analysis of the uniformity of the transfer current density in vanadium flow battery by an improved three-dimensional transient model

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  • Yuan, Chenguang
  • Xing, Feng
  • Zheng, Qiong
  • Zhang, Huamin
  • Li, Xianfeng
  • Ma, Xiangkun

Abstract

Vanadium flow battery has been regarded as one of the most promising candidates for large-scale energy storage, due to its attractive features of high safety, high performance-price ratio and environmental friendliness. The uniformity of transfer current density is one of the crucial factors affecting the performance of a vanadium flow battery. More uniform distribution of transfer current density will reduce the polarization and improve the battery reliability. In this work, a three-dimensional transient model in combination of the vanadium ions crossover through the separator has been developed. Based on the model, the effect of the applied current density, electrode porosity and electrolyte flow rate on the uniformity of transfer current density has been investigated. The result indicates that a lower applied current density, higher electrode porosity or higher electrolyte flow rate is beneficial to obtain a more uniform transfer current density and a reduced battery polarization. By comparison, the electrode porosity shows the most prominent effect on the uniformity of transfer current density, and a higher porosity is verified to be able to attain a better stability in several charge-discharge cycles. Finally, a preliminary study for an industrial scale battery designs has been performed based on an amplifying model.

Suggested Citation

  • Yuan, Chenguang & Xing, Feng & Zheng, Qiong & Zhang, Huamin & Li, Xianfeng & Ma, Xiangkun, 2020. "Factor analysis of the uniformity of the transfer current density in vanadium flow battery by an improved three-dimensional transient model," Energy, Elsevier, vol. 194(C).
    • Handle: RePEc:eee:energy:v:194:y:2020:i:c:s0360544219325344
    DOI: 10.1016/j.energy.2019.116839
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    References listed on IDEAS

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    1. Zhou, X.L. & Zhao, T.S. & An, L. & Zeng, Y.K. & Yan, X.H., 2015. "A vanadium redox flow battery model incorporating the effect of ion concentrations on ion mobility," Applied Energy, Elsevier, vol. 158(C), pages 157-166.
    2. Oh, Kyeongmin & Yoo, Haneul & Ko, Johan & Won, Seongyeon & Ju, Hyunchul, 2015. "Three-dimensional, transient, nonisothermal model of all-vanadium redox flow batteries," Energy, Elsevier, vol. 81(C), pages 3-14.
    3. Zheng, Qiong & Li, Xianfeng & Cheng, Yuanhui & Ning, Guiling & Xing, Feng & Zhang, Huamin, 2014. "Development and perspective in vanadium flow battery modeling," Applied Energy, Elsevier, vol. 132(C), pages 254-266.
    4. Chevalier, S. & Josset, C. & Auvity, B., 2018. "Analytical solutions and dimensional analysis of pseudo 2D current density distribution model in PEM fuel cells," Renewable Energy, Elsevier, vol. 125(C), pages 738-746.
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    Cited by:

    1. Ikechukwu S. Anyanwu & Fulvio Buzzi & Pekka Peljo & Aldo Bischi & Antonio Bertei, 2024. "System-Level Dynamic Model of Redox Flow Batteries (RFBs) for Energy Losses Analysis," Energies, MDPI, vol. 17(21), pages 1-21, October.
    2. Cheng, Ziqiang & Tenny, Kevin M. & Pizzolato, Alberto & Forner-Cuenca, Antoni & Verda, Vittorio & Chiang, Yet-Ming & Brushett, Fikile R. & Behrou, Reza, 2020. "Data-driven electrode parameter identification for vanadium redox flow batteries through experimental and numerical methods," Applied Energy, Elsevier, vol. 279(C).
    3. Gao, Qingchen & Bao, Zhiming & Li, Weizhuo & Gong, Zhichao & Fan, Linhao & Jiao, Kui, 2024. "Performance analysis and gradient-porosity electrode design of vanadium redox flow batteries based on CFD simulations under open-source environment," Energy, Elsevier, vol. 289(C).
    4. Heidarian, Alireza & Cheung, Sherman C.P. & Ojha, Ruchika & Rosengarten, Gary, 2022. "Effects of current collector shape and configuration on charge percolation and electric conductivity of slurry electrodes for electrochemical systems," Energy, Elsevier, vol. 239(PD).

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