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Methanation of syngas from biomass gasification: Small-scale plant design in Aspen Plus

Biagio Ciccone, Fabio Murena, Giovanna Ruoppolo, Massimo Urciuolo, Paola Brachi

2024Applied Thermal Engineering24 citationsDOIOpen Access PDF

Abstract

The objective of this study is to investigate the upgrading of low-quality nitrogen-diluted syngas derived from biomass air gasification processes into a methane-rich gas stream. Both the thermodynamic and the kinetic aspects are addressed in the paper. Using the Aspen Plus software, a thermodynamic analysis was conducted; then, different plant designs are simulated and compared, including reactor sizing and performance. The results demonstrate that the upgrading of diluted syngas poses challenges which limit its application to small-scale decentralized systems. It was found that a system comprising of four adiabatic fixed-bed reactors, inter-cooling, and efficient water removal achieves a favorable balance between performance and cost. Operating the system at a pressure of 5 bar is deemed adequate as it reduces the required catalyst mass and prevents solid carbon deposition. Notably, this configuration achieved good results, including a 99.4 % CO conversion, 89.3 % CO2 conversion, and 95.6 % CH4 yield. The final methane molar content reached 26.4 %, with a calorific value of 8.62 MJ/Nm3(STP).

Topics & Concepts

SyngasMethanationMethaneProcess engineeringSyngas to gasoline plusSizingBiomass (ecology)Environmental scienceHeat of combustionWaste managementMaterials scienceHydrogenHydrogen productionChemistryEngineeringSteam reformingGeologyOrganic chemistryOceanographyCombustionCatalysts for Methane ReformingCatalytic Processes in Materials ScienceThermochemical Biomass Conversion Processes
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