Litcius/Paper detail

Development of enhanced three‐dimensional printed packings for scale‐up of distillation columns: A successful case study

Johannes Neukäufer, Mohamed Adel Ashour, Nadin Sarajlic, Harald Klein, Sebastian Rehfeldt, Heiko Hallmann, Sebastian Meinicke, Jürgen Paschold, Carsten Knösche, Thomas Grützner

2022AIChE Journal20 citationsDOIOpen Access PDF

Abstract

Abstract This publication presents a general approach for the enhancement of packings regarding scalability, separation efficiency, and fluid dynamic properties using three‐dimensional (3D) printing. The methodology is used to develop miniaturized, scalable packings for process development, and scale‐up applications. For this purpose, a 3D printable computer‐aided design version of the Rombopak 9M industrial packing (RP9M‐3D), which is known for its positive scalability properties, was created. An initial characterization by means of computational fluid dynamics simulations and mass transfer measurements reveals positive but also negative design properties. These findings are used to create a more advanced, miniaturized packing structure, the XW‐Pak. The evolved structure is compared to the RP9M‐3D. The simulation and experimental results show that the enhanced packing, which is still in the early stages of development, exhibits higher separation efficiencies with improved scalability properties at the same void fraction and surface area than the RP9M‐3D.

Topics & Concepts

ScalabilityStructured packingMaterials scienceComputer science3D printingAtomic packing factorVoid (composites)Computational fluid dynamics3d printedDistillationScale (ratio)NanotechnologyMass transferProcess engineeringComputational scienceChromatographyMechanicsChemistryEngineeringComposite materialPhysicsCrystallographyBiomedical engineeringQuantum mechanicsDatabaseProcess Optimization and IntegrationAdvanced Control Systems OptimizationExtraction and Separation Processes