Autothermal downdraft oxy-steam co-gasification of biomass and plastic wastes for hydrogen-rich syngas production: An Aspen plus modelling

The potential of H2-rich syngas generation using downdraft co-gasification of biomass and plastic wastes is investigated using an autothermal restricted equilibrium study using Aspen Plus. A comprehensive sensitivity analysis is carried out to impart the influence of important process parameters, vi...

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Bibliographic Details
Published in:International journal of hydrogen energy 2024-09, Vol.81, p.1045-1061
Main Authors: Ranjan, Nishant, Kumar, Sandeep, Mahajani, Sanjay M
Format: Article
Language:English
Subjects:
Aspen plus
Biomass
Co-gasification
Hydrogen
Oxy-steam
Plastic waste
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Summary:The potential of H2-rich syngas generation using downdraft co-gasification of biomass and plastic wastes is investigated using an autothermal restricted equilibrium study using Aspen Plus. A comprehensive sensitivity analysis is carried out to impart the influence of important process parameters, viz. equivalence ratio(ER: 0.1–0.5), feed plastic content(FPC: 0–30 %), steam to feed ratio(SFR: 0–4) and steam temperature(150–1000 °C) on performance parameters, viz. syngas composition, gasification temperature(GT), lower heating value(LHV), cold gas efficiency(CGE), gasification energy efficiency(GEE) and hydrogen energy efficiency(HEE). The ER and SFR showed dominant effects on performance. The increase in ER from 0.1 to 0.5 causes an increase in GT from 565 °C to 1734 °C. The highest syngas H2 content and HEE of 52.1 % and 36.9 %, respectively, are obtained for 0.25 ER. The increase in SFR improves the syngas H2 content at the cost of LHV and GEE, with the highest HEE of 36.9 % obtained at 0.25 ER. The analysis of variance(ANOVA) and response surface methodology(RSM) has also been studied along with the multi-objective optimisation(MOO). [Display omitted] •Autothermal oxy-steam biomass-plastic co-gasification was modelled with Aspen Plus.•Increase in equivalence ratio to 0.5 increased gasification temperature to 1734 °C.•Hydrogen energy efficiency gets maximised at 0.25 equivalence ratio.•An increase in feed plastic content improves gasification performance.•Increase in steam-to-feed ratio improves H2 content at the expense of efficiencies.
ISSN:0360-3199
DOI:10.1016/j.ijhydene.2024.07.218