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Numerical investigation on the operation and energy demand of a seven-stage metal hydride hydrogen compression system for Hydrogen Refuelling Stations

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  • Gkanas, Evangelos I.
  • Christodoulou, Christodoulos N.
  • Tzamalis, George
  • Stamatakis, Emmanuel
  • Chroneos, Alexander
  • Deligiannis, Konstantinos
  • Karagiorgis, George
  • Stubos, Athanasios K.

Abstract

In the present work, a numerical analysis on the performance of a seven-stage metal hydride hydrogen compression (MHHC) system is introduced, presented and discussed. The operation efficiency and cost along with the reliability of hydrogen compression is of great importance for the future commercial availability of Hydrogen Refuelling Stations (HRS); thus, significant improvements in hydrogen compression must be achieved and novel methods and approaches are being investigated in that respect. MHHC's offer distinct advantages over conventional mechanical compressors and the present paper aims at contributing to the efficient design and upscaling of such device via advanced numerical simulations of a seven-stage MHHC. The numerical model was supported by and validated with solid experimental data. Furthermore, several different operational temperature ranges for the compressor were examined and the importance of the proper operation conditions is discussed in terms of temperature evolution, pressure profile, cycle duration, compression ratio, thermal energy demand and efficiency.

Suggested Citation

  • Gkanas, Evangelos I. & Christodoulou, Christodoulos N. & Tzamalis, George & Stamatakis, Emmanuel & Chroneos, Alexander & Deligiannis, Konstantinos & Karagiorgis, George & Stubos, Athanasios K., 2020. "Numerical investigation on the operation and energy demand of a seven-stage metal hydride hydrogen compression system for Hydrogen Refuelling Stations," Renewable Energy, Elsevier, vol. 147(P1), pages 164-178.
  • Handle: RePEc:eee:renene:v:147:y:2020:i:p1:p:164-178
    DOI: 10.1016/j.renene.2019.08.104
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    References listed on IDEAS

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    1. Kikkinides, Eustathios S. & Georgiadis, Michael C. & Stubos, Athanasios K., 2006. "Dynamic modelling and optimization of hydrogen storage in metal hydride beds," Energy, Elsevier, vol. 31(13), pages 2428-2446.
    2. Stamatakis, Emmanuel & Zoulias, Emmanuel & Tzamalis, George & Massina, Zoe & Analytis, Vassilis & Christodoulou, Christodoulos & Stubos, Athanasios, 2018. "Metal hydride hydrogen compressors: Current developments & early markets," Renewable Energy, Elsevier, vol. 127(C), pages 850-862.
    3. Gkanas, Evangelos I. & Khzouz, Martin, 2017. "Numerical analysis of candidate materials for multi-stage metal hydride hydrogen compression processes," Renewable Energy, Elsevier, vol. 111(C), pages 484-493.
    4. Witkowski, Andrzej & Rusin, Andrzej & Majkut, Mirosław & Stolecka, Katarzyna, 2017. "Comprehensive analysis of hydrogen compression and pipeline transportation from thermodynamics and safety aspects," Energy, Elsevier, vol. 141(C), pages 2508-2518.
    5. Gkanas, Evangelos I. & Khzouz, Martin & Panagakos, Grigorios & Statheros, Thomas & Mihalakakou, Giouli & Siasos, Gerasimos I. & Skodras, Georgios & Makridis, Sofoklis S., 2018. "Hydrogenation behavior in rectangular metal hydride tanks under effective heat management processes for green building applications," Energy, Elsevier, vol. 142(C), pages 518-530.
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    2. Lu Zhu & Lanli Hu & Serhat Yüksel & Hasan Dinçer & Hüsne Karakuş & Gözde Gülseven Ubay, 2020. "Analysis of Strategic Directions in Sustainable Hydrogen Investment Decisions," Sustainability, MDPI, vol. 12(11), pages 1-19, June.
    3. Guo, Yi & Wang, Qi & Cao, Junhao & Diao, Anna & Peng, Xueyuan, 2024. "Effects of operating parameters on the performance of an embedded two-piston compressor system for green hydrogen," Renewable Energy, Elsevier, vol. 225(C).

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