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Diesel auto-thermal reforming for solid oxide fuel cell systems: Anode off-gas recycle simulation

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  • Walluk, Mark R.
  • Lin, Jiefeng
  • Waller, Michael G.
  • Smith, Daniel F.
  • Trabold, Thomas A.

Abstract

Diesel auto-thermal reformation (ATR) with solid oxide fuel cell (SOFC) stack anode off-gas recycle (AOGR) has a reliable steam recycling supply to the reformer and improves overall system efficiency. For the lab-scale experiments, it is crucial to develop a cost-effective technique to simulate the AOGR effects on hydrocarbon catalytic reformation due to safety and cost considerations of providing the full recycle composition in the absence of fuel cell stack hardware. The present work combined thermodynamic modeling and experiments to compare diesel ATR performance with AOGR and with direct water/air inputs as recycle simulation (RS). Variations of input water and air flow were employed to simulate the effects of recycle gas on syngas production and to analyze the contribution of recycled CO2 dry reforming. A single-tube reformer with Rh/CeO2–ZrO2 catalyst was used for diesel ATR experiments with a photo-acoustic micro-soot meter to monitor carbon formation in the reformate effluent. Experimental results suggest water and air input flows are two key variables to simulate performance of diesel ATR with AOGR, whereas gas hourly space velocity and reforming temperature do not significantly affect the recycle simulation process in syngas production. The optimum AOGR ratio for an SOFC stack with 65% fuel utilization was identified as 45% for diesel ATR to achieve maximum syngas production and reforming efficiency with a given input air flow.

Suggested Citation

  • Walluk, Mark R. & Lin, Jiefeng & Waller, Michael G. & Smith, Daniel F. & Trabold, Thomas A., 2014. "Diesel auto-thermal reforming for solid oxide fuel cell systems: Anode off-gas recycle simulation," Applied Energy, Elsevier, vol. 130(C), pages 94-102.
    • Handle: RePEc:eee:appene:v:130:y:2014:i:c:p:94-102
    DOI: 10.1016/j.apenergy.2014.04.064
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    Cited by:

    1. Samsun, Remzi Can & Prawitz, Matthias & Tschauder, Andreas & Pasel, Joachim & Pfeifer, Peter & Peters, Ralf & Stolten, Detlef, 2018. "An integrated diesel fuel processing system with thermal start-up for fuel cells," Applied Energy, Elsevier, vol. 226(C), pages 145-159.
    2. Han, Gwangwoo & Lee, Sangho & Bae, Joongmyeon, 2015. "Diesel autothermal reforming with hydrogen peroxide for low-oxygen environments," Applied Energy, Elsevier, vol. 156(C), pages 99-106.
    3. Mingfei Li & Jingjing Wang & Zhengpeng Chen & Xiuyang Qian & Chuanqi Sun & Di Gan & Kai Xiong & Mumin Rao & Chuangting Chen & Xi Li, 2024. "A Comprehensive Review of Thermal Management in Solid Oxide Fuel Cells: Focus on Burners, Heat Exchangers, and Strategies," Energies, MDPI, vol. 17(5), pages 1-30, February.
    4. Samsun, Remzi Can & Prawitz, Matthias & Tschauder, Andreas & Meißner, Jan & Pasel, Joachim & Peters, Ralf, 2020. "Reforming of diesel and jet fuel for fuel cells on a systems level: Steady-state and transient operation," Applied Energy, Elsevier, vol. 279(C).
    5. Lee, Kanghun & Kang, Sanggyu & Ahn, Kook-Young, 2017. "Development of a highly efficient solid oxide fuel cell system," Applied Energy, Elsevier, vol. 205(C), pages 822-833.
    6. Pasel, Joachim & Samsun, Remzi Can & Tschauder, Andreas & Peters, Ralf & Stolten, Detlef, 2017. "Advances in autothermal reformer design," Applied Energy, Elsevier, vol. 198(C), pages 88-98.
    7. Tribioli, Laura & Cozzolino, Raffaello & Chiappini, Daniele & Iora, Paolo, 2016. "Energy management of a plug-in fuel cell/battery hybrid vehicle with on-board fuel processing," Applied Energy, Elsevier, vol. 184(C), pages 140-154.

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