Simulation of fluid-structure interaction with the interface artificial compressibility method

Joris Degroote; Abigail Swillens; Peter Bruggeman; Robby Haelterman; Patrick Segers; Jan Vierendeels

doi:10.1002/cnm.1276

Simulation of fluid-structure interaction with the interface artificial compressibility method

Joris Degroote
, Abigail Swillens
, Peter Bruggeman
, Robby Haelterman
, Patrick Segers
, Jan Vierendeels

University of Ghent

Onderzoeksoutput: Bijdrage aan een tijdschrift › Artikel › peer review

61 Citaten (Scopus)

Samenvatting

Partitioned fluid-structure interaction simulations of the arterial system are difficult due to the incompressibility of the fluid and the shape of the domain. The interface artificial compressibility (IAC) method mitigates the incompressibility constraint by adding a source term to the continuity equation in the fluid domain adjacent to the fluid-structure interface. This source term imitates the effect of the structure's displacement as a result of the fluid pressure and disappears when the coupling iterations have converged. The IAC method requires a small modification of the flow solver but not of the black-box structural solver and it outperforms a partitioned quasi-Newton coupling of the two black-box solvers in a simulation of a carotid bifurcation.

Originele taal-2	Engels
Pagina's (van-tot)	276-289
Aantal pagina's	14
Tijdschrift	International Journal for Numerical Methods in Biomedical Engineering
Volume	26
Nummer van het tijdschrift	3-4
DOI's	https://doi.org/10.1002/cnm.1276
Status	Gepubliceerd - mrt. 2010

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title = "Simulation of fluid-structure interaction with the interface artificial compressibility method",

abstract = "Partitioned fluid-structure interaction simulations of the arterial system are difficult due to the incompressibility of the fluid and the shape of the domain. The interface artificial compressibility (IAC) method mitigates the incompressibility constraint by adding a source term to the continuity equation in the fluid domain adjacent to the fluid-structure interface. This source term imitates the effect of the structure's displacement as a result of the fluid pressure and disappears when the coupling iterations have converged. The IAC method requires a small modification of the flow solver but not of the black-box structural solver and it outperforms a partitioned quasi-Newton coupling of the two black-box solvers in a simulation of a carotid bifurcation.",

keywords = "Carotid bifurcation, Fluid-structure interaction, Interface artificial compressibility, Interface block quasi-Newton",

author = "Joris Degroote and Abigail Swillens and Peter Bruggeman and Robby Haelterman and Patrick Segers and Jan Vierendeels",

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AU - Swillens, Abigail

AU - Bruggeman, Peter

AU - Haelterman, Robby

AU - Segers, Patrick

AU - Vierendeels, Jan

PY - 2010/3

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N2 - Partitioned fluid-structure interaction simulations of the arterial system are difficult due to the incompressibility of the fluid and the shape of the domain. The interface artificial compressibility (IAC) method mitigates the incompressibility constraint by adding a source term to the continuity equation in the fluid domain adjacent to the fluid-structure interface. This source term imitates the effect of the structure's displacement as a result of the fluid pressure and disappears when the coupling iterations have converged. The IAC method requires a small modification of the flow solver but not of the black-box structural solver and it outperforms a partitioned quasi-Newton coupling of the two black-box solvers in a simulation of a carotid bifurcation.

AB - Partitioned fluid-structure interaction simulations of the arterial system are difficult due to the incompressibility of the fluid and the shape of the domain. The interface artificial compressibility (IAC) method mitigates the incompressibility constraint by adding a source term to the continuity equation in the fluid domain adjacent to the fluid-structure interface. This source term imitates the effect of the structure's displacement as a result of the fluid pressure and disappears when the coupling iterations have converged. The IAC method requires a small modification of the flow solver but not of the black-box structural solver and it outperforms a partitioned quasi-Newton coupling of the two black-box solvers in a simulation of a carotid bifurcation.

KW - Carotid bifurcation

KW - Fluid-structure interaction

KW - Interface artificial compressibility

KW - Interface block quasi-Newton

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Simulation of fluid-structure interaction with the interface artificial compressibility method

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