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Benefits of hybrid production of e-methanol in connection with biomass gasification

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  • Anetjärvi, Eemeli
  • Vakkilainen, Esa
  • Melin, Kristian

Abstract

Both e-methanol and hybrid methanol production can balance the energy systems storing variable wind and solar power and reduce emissions by replacing fossil methanol production. It is expected that hybrid methanol production using additional hydrogen from water electrolysis supplemented with purified product gas from biomass gasification will increase methanol yield and result in lower production costs compared to e-methanol, particularly when using power sources that are not only available all the time during the year. In this article hybrid methanol production with varying hydrogen input from the water electrolysis, e-methanol and biomass gasification-based methanol are evaluated from a techno-economic point of view as a function of key variables. Material and energy balances are estimated using a simulation model in IPSEpro. A key finding is the effect of the hydrogen input on the efficiency and cost of the hybrid process. Converting CO2 will increase product yield by 101% and only CO by 38.1% compared to biomass-to-methanol production. Additionally, the results show better economics for hybrid methanol production compared to e-methanol >10–12 €/MWh electricity prices at 100 kt methanol production scale and <30–35 €/MWh electricity prices better economics than biomass to methanol with a biomass input of 70 MW.

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  • Anetjärvi, Eemeli & Vakkilainen, Esa & Melin, Kristian, 2023. "Benefits of hybrid production of e-methanol in connection with biomass gasification," Energy, Elsevier, vol. 276(C).
  • Handle: RePEc:eee:energy:v:276:y:2023:i:c:s0360544223005960
    DOI: 10.1016/j.energy.2023.127202
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