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Standby thermal model of a vanadium redox flow battery stack with crossover and shunt-current effects

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  • Trovò, Andrea
  • Marini, Giacomo
  • Sutto, Alessandro
  • Alotto, Piergiorgio
  • Giomo, Monica
  • Moro, Federico
  • Guarnieri, Massimo

Abstract

This paper presents an original model capable of simulating the thermal behavior of a vanadium redox flow battery stack in standby condition, i.e. without power and reactant flow, where the temperature distribution in the cells evolves because of ions crossover through the membrane, Joule losses due to shunt currents and inherent self-discharge effects. For the first time, a model is presented that is capable of simulating the cell temperature distribution in the stack and its time evolution considering all above effects. The model is applied to a 9 kW/40-cell stack and validated against measurements from a thermal imager. Numerical results show that shunt currents affect the temperature in the stack and can be responsible for local increases of cell temperatures up to 10 °C if the solutions are initially at high state of charge. This effect can be critical if standby occurs after a period of operation, with the electrolyte stack temperature markedly higher than air temperature. In addition, results show that shunt currents can play a major role in the thermal behavior of compact stacks, based on new materials capable of high power density and low ion crossover. The model presented here can constitute the basis for advanced cooling strategies.

Suggested Citation

  • Trovò, Andrea & Marini, Giacomo & Sutto, Alessandro & Alotto, Piergiorgio & Giomo, Monica & Moro, Federico & Guarnieri, Massimo, 2019. "Standby thermal model of a vanadium redox flow battery stack with crossover and shunt-current effects," Applied Energy, Elsevier, vol. 240(C), pages 893-906.
    • Handle: RePEc:eee:appene:v:240:y:2019:i:c:p:893-906
    DOI: 10.1016/j.apenergy.2019.02.067
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    References listed on IDEAS

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    1. Yin, Cong & Guo, Shaoyun & Fang, Honglin & Liu, Jiayi & Li, Yang & Tang, Hao, 2015. "Numerical and experimental studies of stack shunt current for vanadium redox flow battery," Applied Energy, Elsevier, vol. 151(C), pages 237-248.
    2. Guarnieri, Massimo & Trovò, Andrea & D'Anzi, Angelo & Alotto, Piergiorgio, 2018. "Developing vanadium redox flow technology on a 9-kW 26-kWh industrial scale test facility: Design review and early experiments," Applied Energy, Elsevier, vol. 230(C), pages 1425-1434.
    3. Bhattacharjee, Ankur & Saha, Hiranmay, 2018. "Development of an efficient thermal management system for Vanadium Redox Flow Battery under different charge-discharge conditions," Applied Energy, Elsevier, vol. 230(C), pages 1182-1192.
    4. Yang, Xiao-Guang & Ye, Qiang & Cheng, Ping & Zhao, Tim S., 2015. "Effects of the electric field on ion crossover in vanadium redox flow batteries," Applied Energy, Elsevier, vol. 145(C), pages 306-319.
    5. Wei, Zhongbao & Zhao, Jiyun & Xiong, Binyu, 2014. "Dynamic electro-thermal modeling of all-vanadium redox flow battery with forced cooling strategies," Applied Energy, Elsevier, vol. 135(C), pages 1-10.
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    Cited by:

    1. Trovò, Andrea & Alotto, Piergiorgio & Giomo, Monica & Moro, Federico & Guarnieri, Massimo, 2021. "A validated dynamical model of a kW-class Vanadium Redox Flow Battery," Mathematics and Computers in Simulation (MATCOM), Elsevier, vol. 183(C), pages 66-77.
    2. Guarnieri, Massimo & Trovò, Andrea & Picano, Francesco, 2020. "Enhancing the efficiency of kW-class vanadium redox flow batteries by flow factor modulation: An experimental method," Applied Energy, Elsevier, vol. 262(C).
    3. Alejandro Clemente & Ramon Costa-Castelló, 2020. "Redox Flow Batteries: A Literature Review Oriented to Automatic Control," Energies, MDPI, vol. 13(17), pages 1-31, September.

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