Litcius/Paper detail

Scaling of a catalytic cracking fluidized bed downer reactor based on computational fluid dynamics simulations

Parinya Khongprom, Supawadee Ratchasombat, Waritnan Wanchan, Panut Bumphenkiattikul, Sunun Limtrakul

2020RSC Advances15 citationsDOIOpen Access PDF

Abstract

Circulating fluidized bed downer reactors (downer reactors) exhibit good heat and mass transfer, and the flow behavior approaches the ideal plug flow. This reactor is superior for catalytic cracking reactions in which the intermediate is the desired product. However, the hydrodynamic behavior and reactor performance have mostly been investigated in small-scale or laboratory-scale reactors. The objective of this study was to investigate the up-scaling of the catalytic cracking of heavy oil in three downer reactors with heights of 5, 15, and 30 m, using computational fluid dynamics simulations. A two-fluid model with the kinetic theory of granular flow was used to predict the hydrodynamics and performance of the chemical reactions. The kinetics of catalytic cracking of heavy oil were described by a 4-lump kinetic model. The chemical performance similarity was identified by using radial and axial distributions of heavy oil conversion, gasoline mass fraction, and gasoline selectivity. The chemical performance similarity cannot be achieved by using the hydrodynamic similarity parameter . A modified up-scaling parameter was proposed, . The chemical performance similarity of identical catalytic cracking downer reactors can be achieved with deviation in the range of ±10% and mean relative absolute error of less than 5%.

Topics & Concepts

Fluid catalytic crackingFluidized bedScalingCrackingGasolinePlug flow reactor modelChemistryDynamic similarityMechanicsThermodynamicsMaterials scienceContinuous stirred-tank reactorPhysicsPhysical chemistryMathematicsOrganic chemistryReynolds numberGeometryTurbulenceGranular flow and fluidized bedsMineral Processing and GrindingFluid Dynamics and Mixing