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Towards H2-free shipboard storage: Energetic and risk analysis of oxidative methanol steam reforming in integrated fuel cell systems

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  • Russo, Danilo
  • Portarapillo, Maria
  • Turco, Maria
  • Di Benedetto, Almerinda

Abstract

This work investigates the energy self-sufficiency of a methanol-based hydrogen production system through oxidative steam reforming integrated with HT-PEM fuel cells, explores process conditions for autothermal systems, and assesses accident scenarios during refueling/unloading and accidental releases. Comparisons with conventional marine gasoil highlighted differences in risk indices, pool fire zones, and toxicity. Results show that the thermal self-sufficiency can be achieved under stoichiometric conditions, but also in more water-rich conditions (water/MeOH <2, or up to 3 when Air/MeOH >0.5), eventually heat recovery from products cooling. The individual risk index is always below 10−5 years−1, the pool fire impact zone for the methanol-based system is always smaller than that of marine gasoil (up to 14 m diameter for the considered maritime case study); in contrast, the issue of toxicity is more relevant (even at distances >100 m). In the absence of the blanketing system, only partial use of the liquid is permitted under safe conditions, which in the case of pure methanol and methanol-water mixture at stoichiometric composition corresponds to 25 % of the total volume. Thanks to the effect of water, the adoption of methanol-water mixtures with H2O/MeOH = 3 is intrinsically safe.

Suggested Citation

  • Russo, Danilo & Portarapillo, Maria & Turco, Maria & Di Benedetto, Almerinda, 2025. "Towards H2-free shipboard storage: Energetic and risk analysis of oxidative methanol steam reforming in integrated fuel cell systems," Energy, Elsevier, vol. 320(C).
    • Handle: RePEc:eee:energy:v:320:y:2025:i:c:s0360544225010187
    DOI: 10.1016/j.energy.2025.135376
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    References listed on IDEAS

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