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Vacuum swing adsorption process for post-combustion carbon capture with 3D printed sorbents: Quantifying the improvement in productivity and specific energy over a packed bed system through process simulation and optimization

Shreenath Krishnamurthy

2022Chemical Engineering Science15 citationsDOIOpen Access PDF

Abstract

This fully computational work is dedicated to the simulation and optimization of a 6-step vacuum swing adsorption (VSA) process to study the performance of a 3D printed silica sorbent grafted with amino silane. The performance of the 3D printed sorbent was compared with a representative packed bed. Rigorous optimization showed that that it was possible to achieve 2.35 times improvement in productivity with a VSA process containing a 3D printed sorbent than the one using pellets. The minimum specific energy values were found to 1.06 and 1.19 MJ/kg CO2 captured for the 3D printed sorbent and the packed bed respectively.

Topics & Concepts

SorbentAdsorptionSwingPacked bedMaterials sciencePelletsProcess (computing)Process engineeringActivated carbonSimulated moving bedCombustionWork (physics)Chemical engineeringComputer scienceEngineeringChemistryComposite materialMechanical engineeringOrganic chemistryOperating systemCarbon Dioxide Capture TechnologiesPhase Equilibria and ThermodynamicsMembrane Separation and Gas Transport
Vacuum swing adsorption process for post-combustion carbon capture with 3D printed sorbents: Quantifying the improvement in productivity and specific energy over a packed bed system through process simulation and optimization | Litcius