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Power and heat co-generation by micro-tubular flame fuel cell on a porous media burner

Author

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  • Wang, Yuqing
  • Zeng, Hongyu
  • Shi, Yixiang
  • Cao, Tianyu
  • Cai, Ningsheng
  • Ye, Xiaofeng
  • Wang, Shaorong

Abstract

A flame fuel cell setup is designed and built based on a micro-tubular solid oxide fuel cell and a two-layer porous media burner. The stable operation limits of the burner are obtained by adjusting the inlet gas velocity and the equivalence ratio. Methane fuel-rich flames are stabilized inside the burner from the equivalence ratio of 1.4–1.8. The effects of the equivalence ratio and the gas velocity on the temperature distribution inside the burner and the combustion products are studied. Using a burner efficiency based on lower heating values, up to 41.1% of methane was converted to H2 and CO at the equivalence ratio of 1.7. The maximum mole fraction of H2 and CO reached 9.32% and 8.18% respectively. Flame fuel cell experiments are carried out with different equivalence ratios. The tubular SOFC is directly heated up and reduced by the fuel-rich flame. The maximum power generated by the flame fuel cell reached 0.55 W at the equivalence ratio of 1.7 and the inlet gas velocity of 0.15 m/s.

Suggested Citation

  • Wang, Yuqing & Zeng, Hongyu & Shi, Yixiang & Cao, Tianyu & Cai, Ningsheng & Ye, Xiaofeng & Wang, Shaorong, 2016. "Power and heat co-generation by micro-tubular flame fuel cell on a porous media burner," Energy, Elsevier, vol. 109(C), pages 117-123.
    • Handle: RePEc:eee:energy:v:109:y:2016:i:c:p:117-123
    DOI: 10.1016/j.energy.2016.04.095
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    References listed on IDEAS

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    Cited by:

    1. Zeng, Hongyu & Wang, Yuqing & Shi, Yixiang & Cai, Ningsheng & Yuan, Dazhong, 2018. "Highly thermal integrated heat pipe-solid oxide fuel cell," Applied Energy, Elsevier, vol. 216(C), pages 613-619.
    2. Zeng, Hongyu & Gong, Siqi & Shi, Yixiang & Wang, Yuqing & Cai, Ningsheng, 2019. "Micro-tubular solid oxide fuel cell stack operated with catalytically enhanced porous media fuel-rich combustor," Energy, Elsevier, vol. 179(C), pages 154-162.
    3. Banerjee, Abhisek & Paul, Diplina, 2021. "Developments and applications of porous medium combustion: A recent review," Energy, Elsevier, vol. 221(C).
    4. Rashid, Kashif & Dong, Sang Keun & Mehran, Muhammad Taqi, 2017. "Numerical investigations to determine the optimal operating conditions for 1 kW-class flat-tubular solid oxide fuel cell stack," Energy, Elsevier, vol. 141(C), pages 673-691.
    5. Alexander R. Hartwell & Cole A. Wilhelm & Thomas S. Welles & Ryan J. Milcarek & Jeongmin Ahn, 2022. "Effects of Synthesis Gas Concentration, Composition, and Operational Time on Tubular Solid Oxide Fuel Cell Performance," Sustainability, MDPI, vol. 14(13), pages 1-16, June.
    6. Rhushikesh Ghotkar & Ryan J. Milcarek, 2022. "Modeling of the Kinetic Factors in Flame-Assisted Fuel Cells," Sustainability, MDPI, vol. 14(7), pages 1-18, March.
    7. Milcarek, Ryan J. & DeBiase, Vincent P. & Ahn, Jeongmin, 2020. "Investigation of startup, performance and cycling of a residential furnace integrated with micro-tubular flame-assisted fuel cells for micro-combined heat and power," Energy, Elsevier, vol. 196(C).
    8. Milcarek, Ryan J. & Ahn, Jeongmin, 2019. "Micro-tubular flame-assisted fuel cells running methane, propane and butane: On soot, efficiency and power density," Energy, Elsevier, vol. 169(C), pages 776-782.
    9. Janvekar, Ayub Ahmed & Miskam, M.A. & Abas, Aizat & Ahmad, Zainal Arifin & Juntakan, T. & Abdullah, M.Z., 2017. "Effects of the preheat layer thickness on surface/submerged flame during porous media combustion of micro burner," Energy, Elsevier, vol. 122(C), pages 103-110.
    10. Skabelund, B.B. & Milcarek, R.J., 2022. "Review of thermal partial oxidation reforming with integrated solid oxide fuel cell power generation," Renewable and Sustainable Energy Reviews, Elsevier, vol. 168(C).

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