Improved Finite Volume multiphase flow simulation model for strongly inhomogeneous porous media

Christof Obertscheider; Miro Duhovic; Ewald Fauster

Improved Finite Volume multiphase flow simulation model for strongly inhomogeneous porous media

Christof Obertscheider, Miro Duhovic, Ewald Fauster

Fakultät Technik

University of Leoben

Publikation: Konferenzbeitrag › Abstract › peer-review

Abstract

In all liquid composite molding (LCM) technologies, dry fiber preforms are placed into a mold which is subsequently closed or sealed with a flexible bag by drawing a vacuum. Placing a highly permeable flow distribution medium (DM) on top of the fiber preform (FP), often separated by a perforated release film or peel ply, allows for fast in-plane resin distribution and subsequent preform impregnation in out-of-plane direction. FP and DM typically exhibit differences in permeability of several orders of magnitude. Fluid flow through stacked layers of FP and DM can be studied experimentally by means of linear or radial flow experiments as well as by methods of Computational Fluid Dynamics (CFD), i.e. numerical filling simulations. Here, the open source package OpenFOAM was used.

Originalsprache	Englisch
Publikationsstatus	Veröffentlicht - 2025
Veranstaltung	The 16th International Conference on Flow Processes in Composite Materials - Khalifa University, Abu Dhabi, Vereinigte Arabische Emirate Dauer: 14 Jan. 2025 → 16 Jan. 2025

Konferenz

Konferenz	The 16th International Conference on Flow Processes in Composite Materials
Kurztitel	FPCM16
Land/Gebiet	Vereinigte Arabische Emirate
Ort	Abu Dhabi
Zeitraum	14/01/25 → 16/01/25

Dieses zitieren

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title = "Improved Finite Volume multiphase flow simulation model for strongly inhomogeneous porous media",

abstract = "In all liquid composite molding (LCM) technologies, dry fiber preforms are placed into a mold which is subsequently closed or sealed with a flexible bag by drawing a vacuum. Placing a highly permeable flow distribution medium (DM) on top of the fiber preform (FP), often separated by a perforated release film or peel ply, allows for fast in-plane resin distribution and subsequent preform impregnation in out-of-plane direction. FP and DM typically exhibit differences in permeability of several orders of magnitude. Fluid flow through stacked layers of FP and DM can be studied experimentally by means of linear or radial flow experiments as well as by methods of Computational Fluid Dynamics (CFD), i.e. numerical filling simulations. Here, the open source package OpenFOAM was used.",

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T1 - Improved Finite Volume multiphase flow simulation model for strongly inhomogeneous porous media

AU - Obertscheider, Christof

AU - Duhovic, Miro

AU - Fauster, Ewald

PY - 2025

Y1 - 2025

N2 - In all liquid composite molding (LCM) technologies, dry fiber preforms are placed into a mold which is subsequently closed or sealed with a flexible bag by drawing a vacuum. Placing a highly permeable flow distribution medium (DM) on top of the fiber preform (FP), often separated by a perforated release film or peel ply, allows for fast in-plane resin distribution and subsequent preform impregnation in out-of-plane direction. FP and DM typically exhibit differences in permeability of several orders of magnitude. Fluid flow through stacked layers of FP and DM can be studied experimentally by means of linear or radial flow experiments as well as by methods of Computational Fluid Dynamics (CFD), i.e. numerical filling simulations. Here, the open source package OpenFOAM was used.

AB - In all liquid composite molding (LCM) technologies, dry fiber preforms are placed into a mold which is subsequently closed or sealed with a flexible bag by drawing a vacuum. Placing a highly permeable flow distribution medium (DM) on top of the fiber preform (FP), often separated by a perforated release film or peel ply, allows for fast in-plane resin distribution and subsequent preform impregnation in out-of-plane direction. FP and DM typically exhibit differences in permeability of several orders of magnitude. Fluid flow through stacked layers of FP and DM can be studied experimentally by means of linear or radial flow experiments as well as by methods of Computational Fluid Dynamics (CFD), i.e. numerical filling simulations. Here, the open source package OpenFOAM was used.

M3 - Abstract

T2 - The 16th International Conference on Flow Processes in Composite Materials

Y2 - 14 January 2025 through 16 January 2025

ER -