Assessment of volume of fluid and immersed boundary methods for droplet computations

Daniel Lörstad; Marianne Francois; Wei Shyy; Laszlo Fuchs

doi:10.1002/fld.746

Assessment of volume of fluid and immersed boundary methods for droplet computations

Daniel Lörstad^*, Marianne Francois, Wei Shyy, Laszlo Fuchs

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

54 Citations (Scopus)

Abstract

The volume of fluid (VOF) and immersed boundary (IB) methods are two popular computational techniques for multi-fluid dynamics. To help shed light on the performance of both techniques, we present accuracy assessment, which includes interfacial geometry, detailed and global fluid flow characteristics, and computational robustness. The investigation includes the simulations of a droplet under static equilibrium as a limiting test case and a droplet rising due to gravity for Re ≤ 1000. Surface tension force models are key issues in both VOF and IB and alternative treatments are examined resulting in improved solution accuracy. A refined curvature model for VOF is also presented. With the newly developed interfacial treatments incorporated, both IB and VOF perform comparably well for the droplet dynamics under different flow parameters and fluid properties.

Original language	English
Pages (from-to)	109-125
Number of pages	17
Journal	International Journal for Numerical Methods in Fluids
Volume	46
Issue number	2
DOIs	https://doi.org/10.1002/fld.746
Publication status	Published - 20 Sept 2004
Externally published	Yes

Keywords

IB
Immersed boundary
Interfacial flow
Surface tension
VOF
Volume of fluid

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10.1002/fld.746

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abstract = "The volume of fluid (VOF) and immersed boundary (IB) methods are two popular computational techniques for multi-fluid dynamics. To help shed light on the performance of both techniques, we present accuracy assessment, which includes interfacial geometry, detailed and global fluid flow characteristics, and computational robustness. The investigation includes the simulations of a droplet under static equilibrium as a limiting test case and a droplet rising due to gravity for Re ≤ 1000. Surface tension force models are key issues in both VOF and IB and alternative treatments are examined resulting in improved solution accuracy. A refined curvature model for VOF is also presented. With the newly developed interfacial treatments incorporated, both IB and VOF perform comparably well for the droplet dynamics under different flow parameters and fluid properties.",

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T1 - Assessment of volume of fluid and immersed boundary methods for droplet computations

AU - Lörstad, Daniel

AU - Francois, Marianne

AU - Shyy, Wei

AU - Fuchs, Laszlo

PY - 2004/9/20

Y1 - 2004/9/20

N2 - The volume of fluid (VOF) and immersed boundary (IB) methods are two popular computational techniques for multi-fluid dynamics. To help shed light on the performance of both techniques, we present accuracy assessment, which includes interfacial geometry, detailed and global fluid flow characteristics, and computational robustness. The investigation includes the simulations of a droplet under static equilibrium as a limiting test case and a droplet rising due to gravity for Re ≤ 1000. Surface tension force models are key issues in both VOF and IB and alternative treatments are examined resulting in improved solution accuracy. A refined curvature model for VOF is also presented. With the newly developed interfacial treatments incorporated, both IB and VOF perform comparably well for the droplet dynamics under different flow parameters and fluid properties.

AB - The volume of fluid (VOF) and immersed boundary (IB) methods are two popular computational techniques for multi-fluid dynamics. To help shed light on the performance of both techniques, we present accuracy assessment, which includes interfacial geometry, detailed and global fluid flow characteristics, and computational robustness. The investigation includes the simulations of a droplet under static equilibrium as a limiting test case and a droplet rising due to gravity for Re ≤ 1000. Surface tension force models are key issues in both VOF and IB and alternative treatments are examined resulting in improved solution accuracy. A refined curvature model for VOF is also presented. With the newly developed interfacial treatments incorporated, both IB and VOF perform comparably well for the droplet dynamics under different flow parameters and fluid properties.

KW - IB

KW - Immersed boundary

KW - Interfacial flow

KW - Surface tension

KW - VOF

KW - Volume of fluid

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UR - https://openalex.org/W2122665008

U2 - 10.1002/fld.746

DO - 10.1002/fld.746

M3 - Journal Article

SN - 0271-2091

VL - 46

SP - 109

EP - 125

JO - International Journal for Numerical Methods in Fluids

JF - International Journal for Numerical Methods in Fluids

IS - 2

ER -

Assessment of volume of fluid and immersed boundary methods for droplet computations

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Keywords

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