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Ammonia as an efficient COX-free hydrogen carrier: Fundamentals and feasibility analyses for fuel cell applications

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  • Cha, Junyoung
  • Jo, Young Suk
  • Jeong, Hyangsoo
  • Han, Jonghee
  • Nam, Suk Woo
  • Song, Kwang Ho
  • Yoon, Chang Won

Abstract

A COX-free 1 kW-class hydrogen power pack fueled by liquid ammonia is presented. For applications in a practical-scale hydrogen production system in conjunction with a polymer electrolyte membrane fuel cell, Ru catalysts supported on La-doped alumina (Ru/La(x)-Al2O3) were pelletized by varying the lanthanum doping content (x mol%) to control catalytic activities. An optimized Ru(1.06 wt%)/La(20)-Al2O3 pellet catalyst presents a >99.7% conversion efficiency at 500 °C under a gas hourly space velocity of 5000 mL gcat−1 h−1. Various materials were screened to remove residual ammonia from the product stream, and the X zeolite was chosen as a highly capable adsorbent. Based on the synthesized catalyst and screened adsorbent, a power pack consisting of a dehydrogenation reactor, an adsorbent tower, and a 1 kW-class polymer electrolyte membrane fuel cell was designed and manufactured. The as-integrated system can convert 9 L min−1 of ammonia into 13.4 L min−1 of hydrogen, powering a 1 kW-class fuel-cell continuously for >2 h without any performance degradation. To achieve autothermal and COX-free operations, heat required for ammonia dehydrogenation was provided by unutilized hydrogen from the fuel cell, drastically increasing the overall efficiency of the system to >49% while removing the external heat source, isobutane. Finally, a drone tethered to the system was operated, demonstrating the feasibility of an elongated flight time of >4 h, much longer than 14 min with Li-polymer battery loaded on the drone. The system is expected to meet the United States Department of Energy’s 2020 gravimetric and volumetric hydrogen storage targets of 4.5 wt% and 30 gH2 L−1 at system weights of 43 kg and 50 kg, respectively.

Suggested Citation

  • Cha, Junyoung & Jo, Young Suk & Jeong, Hyangsoo & Han, Jonghee & Nam, Suk Woo & Song, Kwang Ho & Yoon, Chang Won, 2018. "Ammonia as an efficient COX-free hydrogen carrier: Fundamentals and feasibility analyses for fuel cell applications," Applied Energy, Elsevier, vol. 224(C), pages 194-204.
    • Handle: RePEc:eee:appene:v:224:y:2018:i:c:p:194-204
    DOI: 10.1016/j.apenergy.2018.04.100
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    1. Hoffman, Peter, 1994. "Hydrogen--the optimum chemical fuel," Applied Energy, Elsevier, vol. 47(2-3), pages 183-199.
    2. Brian C. H. Steele & Angelika Heinzel, 2001. "Materials for fuel-cell technologies," Nature, Nature, vol. 414(6861), pages 345-352, November.
    3. Dell, R. M. & Bridger, N. J., 1975. "Hydrogen--The ultimate fuel," Applied Energy, Elsevier, vol. 1(4), pages 279-292, October.
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    3. Sun, Shangcong & Jiang, Qiuqiao & Zhao, Dongyue & Cao, Tiantian & Sha, Hao & Zhang, Chuankun & Song, Haitao & Da, Zhijian, 2022. "Ammonia as hydrogen carrier: Advances in ammonia decomposition catalysts for promising hydrogen production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 169(C).
    4. Cha, Junyoung & Park, Yongha & Brigljević, Boris & Lee, Boreum & Lim, Dongjun & Lee, Taeho & Jeong, Hyangsoo & Kim, Yongmin & Sohn, Hyuntae & Mikulčić, Hrvoje & Lee, Kyung Moon & Nam, Dong Hoon & Lee,, 2021. "An efficient process for sustainable and scalable hydrogen production from green ammonia," Renewable and Sustainable Energy Reviews, Elsevier, vol. 152(C).
    5. Byun, Manhee & Lim, Dongjun & Lee, Boreum & Kim, Ayeon & Lee, In-Beum & Brigljević, Boris & Lim, Hankwon, 2022. "Economically feasible decarbonization of the Haber-Bosch process through supercritical CO2 Allam cycle integration," Applied Energy, Elsevier, vol. 307(C).
    6. Luo, Yu & Liao, Shuting & Chen, Shuai & Fang, Huihuang & Zhong, Fulan & Lin, Li & Zhou, Chen & Chen, Chongqi & Cai, Guohui & Au, Chak-Tong & Jiang, Lilong, 2022. "Optimized coupling of ammonia decomposition and electrochemical oxidation in a tubular direct ammonia solid oxide fuel cell for high-efficiency power generation," Applied Energy, Elsevier, vol. 307(C).
    7. Lee, Boreum & Lim, Dongjun & Lee, Hyunjun & Lim, Hankwon, 2021. "Which water electrolysis technology is appropriate?: Critical insights of potential water electrolysis for green ammonia production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 143(C).
    8. Brigljević, Boris & Byun, Manhee & Lim, Hankwon, 2020. "Design, economic evaluation, and market uncertainty analysis of LOHC-based, CO2 free, hydrogen delivery systems," Applied Energy, Elsevier, vol. 274(C).
    9. Perčić, Maja & Vladimir, Nikola & Jovanović, Ivana & Koričan, Marija, 2022. "Application of fuel cells with zero-carbon fuels in short-sea shipping," Applied Energy, Elsevier, vol. 309(C).
    10. Hassan, I.A. & Ramadan, Haitham S. & Saleh, Mohamed A. & Hissel, Daniel, 2021. "Hydrogen storage technologies for stationary and mobile applications: Review, analysis and perspectives," Renewable and Sustainable Energy Reviews, Elsevier, vol. 149(C).
    11. Pashchenko, Dmitry & Mustafin, Ravil & Karpilov, Igor, 2022. "Ammonia-fired chemically recuperated gas turbine: Thermodynamic analysis of cycle and recuperation system," Energy, Elsevier, vol. 252(C).

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