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Coupling particle scale model and <scp>SuperDEM‐CFD</scp> for multiscale simulation of biomass pyrolysis in a packed bed pyrolyzer

Xi Gao, Jia Yu, Liqiang Lu, William A. Rogers

2021AIChE Journal81 citationsDOIOpen Access PDF

Abstract

Abstract An efficient biomass pyrolysis process requires a comprehensive understanding of the chemical and physical phenomena that occur at multi‐length and time scales. In this study, a multiscale computational approach was developed and validated for biomass pyrolysis in a packed‐bed reactor by integrating pyrolysis kinetics, a particle scale model, and Superquadric Discrete Element Method‐Computational Fluid Dynamics (SuperDEM‐CFD) in open‐source code MFiX. A one‐dimensional particle–scale model that discretizes the characteristic length of biomass particle into layers was developed to predict the intraparticle phenomena inside a single particle. The 1D model was validated by comparing it with a single biomass particle pyrolysis experiment. A recently developed SuperDEM‐CFD model was employed to simulate the non‐spherical particle–particle contact and fluid‐particle interaction. The coupled model was applied to simulate the pyrolysis of cubic biomass particles in a packed bed and validated by comparing with experimental data. Simulation with and without particle–scale model was compared, and the effect of the gas–solid heat transfer models was also investigated.

Topics & Concepts

PyrolysisParticle (ecology)Packed bedComputational fluid dynamicsBiomass (ecology)Particle sizeCoupling (piping)Discrete element methodMaterials scienceMechanicsScale (ratio)Heat transferCFD-DEMChemistryChemical engineeringComposite materialPhysicsChromatographyEngineeringOrganic chemistryGeologyQuantum mechanicsOceanographyThermochemical Biomass Conversion ProcessesGranular flow and fluidized bedsHeat and Mass Transfer in Porous Media
Coupling particle scale model and <scp>SuperDEM‐CFD</scp> for multiscale simulation of biomass pyrolysis in a packed bed pyrolyzer | Litcius