Publikation: Numerical simulations of fully Eulerian fluid-structure contact interaction using a ghost-penalty cut finite element approach
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In this work, we develop a cut-based unfitted finite element formulation for solving nonlinear, nonstationary fluid-structure interaction with contact in Eulerian coordinates. In the Eulerian description fluid flow modeled by the incompressible Navier-Stokes equations remains in Eulerian coordinates, while elastic solids are transformed from Lagrangian coordinates into the Eulerian system. A monolithic description is adopted. For the spatial discretization, we employ an unfitted finite element method with ghost penalties based on inf-sup stable finite elements. To handle contact, we use a relaxation of the contact condition in combination with a unified Nitsche approach that takes care implicitly of the switch between fluid-structure interaction and contact conditions. The temporal discretization is based on a backward Euler scheme with implicit extensions of solutions at the previous time step. The nonlinear system is solved with a semi-smooth Newton's method with line search. Our formulation, discretization and implementation are substantiated with an elastic falling ball that comes into contact with the bottom boundary, constituting a challenging state-of-the-art benchmark.
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FREI, Stefan, Tobias KNOKE, Marc C. STEINBACH, Anne-Kathrin WENSKE, Thomas WICK, 2025. Numerical simulations of fully Eulerian fluid-structure contact interaction using a ghost-penalty cut finite element approach. In: Advances in Computational Science and Engineering. American Institute of Mathematical Sciences (AIMS). 2025, 3(0), S. 74-94. ISSN 2837-1739. Verfügbar unter: doi: 10.3934/acse.2025005BibTex
@article{Frei2025Numer-75465,
title={Numerical simulations of fully Eulerian fluid-structure contact interaction using a ghost-penalty cut finite element approach},
year={2025},
doi={10.3934/acse.2025005},
number={0},
volume={3},
issn={2837-1739},
journal={Advances in Computational Science and Engineering},
pages={74--94},
author={Frei, Stefan and Knoke, Tobias and Steinbach, Marc C. and Wenske, Anne-Kathrin and Wick, Thomas}
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<dcterms:abstract>In this work, we develop a cut-based unfitted finite element formulation for solving nonlinear, nonstationary fluid-structure interaction with contact in Eulerian coordinates. In the Eulerian description fluid flow modeled by the incompressible Navier-Stokes equations remains in Eulerian coordinates, while elastic solids are transformed from Lagrangian coordinates into the Eulerian system. A monolithic description is adopted. For the spatial discretization, we employ an unfitted finite element method with ghost penalties based on inf-sup stable finite elements. To handle contact, we use a relaxation of the contact condition in combination with a unified Nitsche approach that takes care implicitly of the switch between fluid-structure interaction and contact conditions. The temporal discretization is based on a backward Euler scheme with implicit extensions of solutions at the previous time step. The nonlinear system is solved with a semi-smooth Newton's method with line search. Our formulation, discretization and implementation are substantiated with an elastic falling ball that comes into contact with the bottom boundary, constituting a challenging state-of-the-art benchmark.</dcterms:abstract>
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