Litcius/Paper detail

Production of syngas from oil palm shell biomass using microwave gasification

Istiaq Jamil Siddique, Arshad Adam Salema

2024Energy17 citationsDOIOpen Access PDF

Abstract

The research work on microwave gasification (MWG) is limited in the literature compared to pyrolysis, and little attention has been paid to its efficiency. The present study aims to investigate the effect of MW power (20–40 %) and absorber loading (0–15 wt%) on the temperature, gas composition, syngas yield, quality, and efficiencies during gasification of oil palm shell biomass in a 1.25 kW and 2.45 GHz lab-scale microwave (MW) system. Overall, the yield and quality of syngas increased with MW power, but it decreased after reaching optimum absorber loading. The highest product gas (63.3 wt%) with a heating value of 11.66 MJ/m 3 was obtained at an optimum process condition (absorber loading of 10 wt% and MW power of 40 %). Under these conditions, the heating rate of 17 °C/s and maximum syngas (CO + H 2 ) (76.5 vol%) were recorded. The specific energy consumption increased with MW power but dropped with increasing absorber loading, demonstrating MWG to be more energy efficient at higher biomass loading. MW process efficiency (19.7 %) and biomass conversion efficiency (55.6 %) were achieved at optimum process conditions while considering syngas only. The MWG system can become more energy and process-efficient if all byproducts are utilized and scaled up. • Two key main parameters of gasification were investigated, Microwave (MW) power and absorber loading ratio. • 40 % MW power and 10 wt% absorber loading produced the highest gas yield (63.3 wt%). • The lower heating value of gas was 11.66 MJ/m 3 at the above condition. • MW process efficiency of 19.7 % and biomass conversion efficiency of 55.6 % were achieved. • Utilization of all by products and scale up can significantly improve net energy balance.

Topics & Concepts

SyngasPalm oilBiomass (ecology)Shell (structure)Waste managementBiomass gasificationPulp and paper industryEnvironmental scienceMicrowaveProduction (economics)BiofuelEngineeringChemistryAgricultural scienceMechanical engineeringAgronomyOrganic chemistryCatalysisTelecommunicationsEconomicsBiologyMacroeconomicsThermochemical Biomass Conversion ProcessesBiodiesel Production and ApplicationsCatalysis and Hydrodesulfurization Studies