A compressible multiphase Mass-of-Fluid model for the simulation of laser-based manufacturing processes

Constantin Zenz; Michele Buttazzoni; Tobias Florian; Katherine Elizabeth Crespo Armijos; Rodrigo Gómez Vázquez; Gerhard Liedl; Andreas Otto

doi:10.1016/j.compfluid.2023.106109

A compressible multiphase Mass-of-Fluid model for the simulation of laser-based manufacturing processes

Constantin Zenz, Michele Buttazzoni, Tobias Florian, Katherine Elizabeth Crespo Armijos, Rodrigo Gómez Vázquez, Gerhard Liedl, Andreas Otto

LKR Light Metals Technologies

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

Abstract

A new model for compressible multiphase flows involving sharp interfaces and phase change is presented, that uses a variant of the Volume-of-Fluid model to track phases by advecting their respective mass, and is hence called Mass-of-Fluid model. The framework is aimed at predicting the coupled multi-physical phenomena involved in most processes encountered in laser material processing, with the aim of minimizing a priori assumptions on the nature of the process. Emphasis is put on the multiphase fluid flow model, especially on the treatment of compressibility and phase change. The model's accuracy and suitability is demonstrated on problems of increasing complexity, including well-known benchmarks and problems encountered in laser material processing, where simulation results are compared to experimental observations.

Originalsprache	Englisch
Aufsatznummer	106109
Seitenumfang	19
Fachzeitschrift	Computers & Fluids
Volume	268
DOIs	https://doi.org/10.1016/j.compfluid.2023.106109
Publikationsstatus	Veröffentlicht - 15 Jan. 2024

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abstract = "A new model for compressible multiphase flows involving sharp interfaces and phase change is presented, that uses a variant of the Volume-of-Fluid model to track phases by advecting their respective mass, and is hence called Mass-of-Fluid model. The framework is aimed at predicting the coupled multi-physical phenomena involved in most processes encountered in laser material processing, with the aim of minimizing a priori assumptions on the nature of the process. Emphasis is put on the multiphase fluid flow model, especially on the treatment of compressibility and phase change. The model's accuracy and suitability is demonstrated on problems of increasing complexity, including well-known benchmarks and problems encountered in laser material processing, where simulation results are compared to experimental observations.",

keywords = "Compressibility, Laser material processing, Mass-of-Fluid, Multiphase flow, OpenFOAM, Volume-of-Fluid",

author = "Constantin Zenz and Michele Buttazzoni and Tobias Florian and Armijos, {Katherine Elizabeth Crespo} and V{\'a}zquez, {Rodrigo G{\'o}mez} and Gerhard Liedl and Andreas Otto",

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AU - Zenz, Constantin

AU - Buttazzoni, Michele

AU - Florian, Tobias

AU - Armijos, Katherine Elizabeth Crespo

AU - Vázquez, Rodrigo Gómez

AU - Liedl, Gerhard

AU - Otto, Andreas

PY - 2024/1/15

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N2 - A new model for compressible multiphase flows involving sharp interfaces and phase change is presented, that uses a variant of the Volume-of-Fluid model to track phases by advecting their respective mass, and is hence called Mass-of-Fluid model. The framework is aimed at predicting the coupled multi-physical phenomena involved in most processes encountered in laser material processing, with the aim of minimizing a priori assumptions on the nature of the process. Emphasis is put on the multiphase fluid flow model, especially on the treatment of compressibility and phase change. The model's accuracy and suitability is demonstrated on problems of increasing complexity, including well-known benchmarks and problems encountered in laser material processing, where simulation results are compared to experimental observations.

AB - A new model for compressible multiphase flows involving sharp interfaces and phase change is presented, that uses a variant of the Volume-of-Fluid model to track phases by advecting their respective mass, and is hence called Mass-of-Fluid model. The framework is aimed at predicting the coupled multi-physical phenomena involved in most processes encountered in laser material processing, with the aim of minimizing a priori assumptions on the nature of the process. Emphasis is put on the multiphase fluid flow model, especially on the treatment of compressibility and phase change. The model's accuracy and suitability is demonstrated on problems of increasing complexity, including well-known benchmarks and problems encountered in laser material processing, where simulation results are compared to experimental observations.

KW - Compressibility

KW - Laser material processing

KW - Mass-of-Fluid

KW - Multiphase flow

KW - OpenFOAM

KW - Volume-of-Fluid

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DO - 10.1016/j.compfluid.2023.106109

M3 - Article

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ER -

A compressible multiphase Mass-of-Fluid model for the simulation of laser-based manufacturing processes

Abstract

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