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Combining the Heatpipe Reformer technology with hydrogen-intensified methanation for production of synthetic natural gas

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  • Leimert, Jonas M.
  • Neubert, Michael
  • Treiber, Peter
  • Dillig, Marius
  • Karl, Jürgen

Abstract

Recent developments in the energy sector require a combination of renewable carbon sources (e.g. biomass) and water electrolysis as a basis for electrical energy storage. While many approaches concentrate on the usage of hydrogen from electrolysis with CO2 for the generation of second generation fuels like synthetic natural gas, the presented paper introduces a combination with the Heatpipe Reformer biomass gasification process: This process produces a synthesis gas, which can be fully and directly converted to methane using additional hydrogen produced in an electrolyser. Furthermore, the applied nickel catalyst is able to convert higher hydrocarbons in the syngas, increasing methane yield and resulting in higher process efficiencies and no additional scrubbing for the adaptation of the CHO stoichiometry is necessary. The Heatpipe Reformer also allows pressurized gasification, which is beneficial for a subsequent methanation step.

Suggested Citation

  • Leimert, Jonas M. & Neubert, Michael & Treiber, Peter & Dillig, Marius & Karl, Jürgen, 2018. "Combining the Heatpipe Reformer technology with hydrogen-intensified methanation for production of synthetic natural gas," Applied Energy, Elsevier, vol. 217(C), pages 37-46.
    • Handle: RePEc:eee:appene:v:217:y:2018:i:c:p:37-46
    DOI: 10.1016/j.apenergy.2018.02.127
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    References listed on IDEAS

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    Cited by:

    1. Kolb, Sebastian & Plankenbühler, Thomas & Frank, Jonas & Dettelbacher, Johannes & Ludwig, Ralf & Karl, Jürgen & Dillig, Marius, 2021. "Scenarios for the integration of renewable gases into the German natural gas market – A simulation-based optimisation approach," Renewable and Sustainable Energy Reviews, Elsevier, vol. 139(C).
    2. Bryngemark, Elina, 2019. "Second generation biofuels and the competition for forest raw materials: A partial equilibrium analysis of Sweden," Forest Policy and Economics, Elsevier, vol. 109(C).
    3. Zhu, Jianhua & Peng, Yan & Gong, Zhuping & Sun, Yanming & Lai, Chaoan & Wang, Qing & Zhu, Xiaojun & Gan, Zhongxue, 2019. "Dynamic analysis of SNG and PNG supply: The stability and robustness view #," Energy, Elsevier, vol. 185(C), pages 717-729.
    4. Kolb, Sebastian & Plankenbühler, Thomas & Hofmann, Katharina & Bergerson, Joule & Karl, Jürgen, 2021. "Life cycle greenhouse gas emissions of renewable gas technologies: A comparative review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 146(C).
    5. Wang, Yongli & Wang, Yudong & Huang, Yujing & Li, Fang & Zeng, Ming & Li, Jiapu & Wang, Xiaohai & Zhang, Fuwei, 2019. "Planning and operation method of the regional integrated energy system considering economy and environment," Energy, Elsevier, vol. 171(C), pages 731-750.
    6. Neubert, Michael & Hauser, Alexander & Pourhossein, Babak & Dillig, Marius & Karl, Juergen, 2018. "Experimental evaluation of a heat pipe cooled structured reactor as part of a two-stage catalytic methanation process in power-to-gas applications," Applied Energy, Elsevier, vol. 229(C), pages 289-298.
    7. Koytsoumpa, E.I. & Magiri – Skouloudi, D. & Karellas, S. & Kakaras, E., 2021. "Bioenergy with carbon capture and utilization: A review on the potential deployment towards a European circular bioeconomy," Renewable and Sustainable Energy Reviews, Elsevier, vol. 152(C).
    8. Koytsoumpa, Efthymia Ioanna & Karellas, Sotirios & Kakaras, Emmanouil, 2019. "Modelling of Substitute Natural Gas production via combined gasification and power to fuel," Renewable Energy, Elsevier, vol. 135(C), pages 1354-1370.

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