Efficient simulation of complex capillary effects in advanced manufacturing processes using the finite volume method

  • The accurate representation of surface tension driven flows in multiphase systems is considered a challeng- ing problem to resolve numerically. Although there have been extensive works in the past that have presented approaches to resolve these so called Marangoni flows at the phase boundaries, the question of how to efficiently resolve the interface in a universal and conservative manner remains largely open in comparison. Such problems are of high practical relevance in many manufacturing processes, especially in the microfluidic regime where capillary effects dominate the local force equilibria. In this work, we present a freely available numerical solver based on the Finite Volume Method that is able to resolve arbitrarily complex, incompressible multiphase systems with the mentioned physics at phase boundaries. An efficient solution with respect to the number of degrees of freedom can be obtained by either using high order WENO stencils or by employing adaptive cell refinement. WeThe accurate representation of surface tension driven flows in multiphase systems is considered a challeng- ing problem to resolve numerically. Although there have been extensive works in the past that have presented approaches to resolve these so called Marangoni flows at the phase boundaries, the question of how to efficiently resolve the interface in a universal and conservative manner remains largely open in comparison. Such problems are of high practical relevance in many manufacturing processes, especially in the microfluidic regime where capillary effects dominate the local force equilibria. In this work, we present a freely available numerical solver based on the Finite Volume Method that is able to resolve arbitrarily complex, incompressible multiphase systems with the mentioned physics at phase boundaries. An efficient solution with respect to the number of degrees of freedom can be obtained by either using high order WENO stencils or by employing adaptive cell refinement. We demonstrate the capabilities of the solver by investigating a model benchmark case as well as a single track laser melting process that is highly relevant within laser additive manufacturing.show moreshow less

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Metadaten
Author:Patrick ZimbrodORCiDGND, Magdalena SchreterORCiD, Johannes SchilpGND
URN:urn:nbn:de:bvb:384-opus4-1064281
Frontdoor URLhttps://opus.bibliothek.uni-augsburg.de/opus4/106428
ISBN:978-1-6654-7096-4OPAC
Parent Title (English):2022 International Conference on Electrical, Computer, Communications and Mechatronics Engineering (ICECCME), 16-18 November 2022, Maldives
Publisher:IEEE
Place of publication:Piscataway, NJ
Editor:Aishath Shehenaz Adam, Mahendra Gooroochurn, Rıza Altınok
Type:Conference Proceeding
Language:English
Year of first Publication:2022
Publishing Institution:Universität Augsburg
Release Date:2023/07/28
First Page:1
Last Page:6
DOI:https://doi.org/10.1109/ICECCME55909.2022.9988504
Institutes:Fakultät für Angewandte Informatik
Fakultät für Angewandte Informatik / Institut für Informatik
Fakultät für Angewandte Informatik / Institut für Informatik / Lehrstuhl für Ingenieurinformatik mit Schwerpunkt Produktionsinformatik
Nachhaltigkeitsziele
Nachhaltigkeitsziele / Ziel 9 - Industrie, Innovation und Infrastruktur
Dewey Decimal Classification:0 Informatik, Informationswissenschaft, allgemeine Werke / 00 Informatik, Wissen, Systeme / 004 Datenverarbeitung; Informatik
Licence (German):Deutsches Urheberrecht