Well-to-Wheels analysis of hydrogen production from bio-oil reforming for use in internal combustion engines

The environmental profile of hydrogen depends greatly on the nature of the feedstock and the production process. In this Well-to-Wheels (WTW) study, the environmental impacts of hydrogen production from lignocellulosic biomass via pyrolysis and subsequent steam reforming of bio-oil were evaluated an...

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Bibliographic Details
Published in:International journal of hydrogen energy 2011-09, Vol.36 (18), p.11501-11511
Main Author: Heracleous, Eleni
Format: Article
Language:English
Subjects:
Alternative fuels. Production and utilization
Applied sciences
Bio-oil steam reforming
Biomass
Biomass pyrolysis
Demand
Energy
Energy consumption
Energy use
Exact sciences and technology
Fossils
Fuels
H 2-ICE vehicle
Hydrogen
Hydrogen production
Natural gas
Pyrolysis
Reforming
Well-to-Wheels study
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Summary:The environmental profile of hydrogen depends greatly on the nature of the feedstock and the production process. In this Well-to-Wheels (WTW) study, the environmental impacts of hydrogen production from lignocellulosic biomass via pyrolysis and subsequent steam reforming of bio-oil were evaluated and compared to the conventional production of hydrogen from natural gas steam reforming. Hydrogen was assumed to be used as transportation fuel in an internal combustion engine vehicle. Two scenarios for the provision of lignocellulosic biomass were considered: wood waste and dedicated willow cultivation. The WTW analysis showed that the production of bio-hydrogen consumes less fossil energy in the total lifecycle, mainly due to the renewable nature of the fuel that results in zero energy consumption in the combustion step. The total (fossil and renewable) energy demand is however higher compared to fossil hydrogen, due to the higher process energy demands and methanol used to stabilize bio-oil. Improvements could occur if these are sourced from renewable energy sources. The overall benefit of using a CO 2 neutral renewable feedstock for the production of hydrogen is unquestionable. In terms of global warming, production of hydrogen from biomass through pyrolysis and reforming results in major GHG emissions, ranging from 40% to 50%, depending on the biomass source. The use of cultivated biomass aggravates the GHG emissions balance, mainly due to the N 2O emissions at the cultivation step. ► LCA of hydrogen produced from biomass from biomass via pyrolysis and reforming. ► Hydrogen from biomass results in major GHG emission savings (40–50%). ► Bio-hydrogen lifecycle consumes less fossil energy than hydrogen from natural gas. ► Total (fossil and renewable) energy demand is higher compared to fossil hydrogen.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2011.06.052