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On suitable inlet boundary conditions for fluid-structure interaction problems in a channel

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    0504010 - ÚT 2020 RIV CZ eng J - Journal Article
    Valášek, J. - Sváček, P. - Horáček, Jaromír
    On suitable inlet boundary conditions for fluid-structure interaction problems in a channel.
    Applications of Mathematics. Roč. 64, č. 2 (2019), s. 225-251. ISSN 0862-7940. E-ISSN 1572-9109
    R&D Projects: GA ČR(CZ) GA16-01246S
    Institutional support: RVO:61388998
    Keywords : flow-induced vibration * 2D incompressible Navier-Stokes equations * linear elasticity * inlet boundary conditions * flutter instability
    OECD category: Acoustics
    Impact factor: 0.544, year: 2019
    Method of publishing: Limited access
    https://articles.math.cas.cz/10.21136/AM.2019.0267-18

    We are interested in the numerical solution of a two-dimensional fluid-structure interaction problem. A special attention is paid to the choice of physically relevant inlet boundary conditions for the case of channel closing. Three types of the inlet boundary conditions are considered. Beside the classical Dirichlet and the do-nothing boundary conditions also a generalized boundary condition motivated by the penalization prescription of the Dirichlet boundary condition is applied. The fluid flow is described by the incompressible Navier-Stokes equations in the arbitrary Lagrangian-Eulerian (ALE) form and the elastic body creating a part of the channel wall is modelled with the aid of linear elasticity. Both models are coupled with the boundary conditions prescribed at the common interface.
    The elastic and the fluid flow problems are approximated by the finite element method. The detailed derivation of the weak formulation including the boundary conditions is presented. The pseudo-elastic approach for construction of the ALE mapping is used. Results of numerical simulations for three considered inlet boundary conditions are compared. The flutter velocity is determined for a specific model problem and it is shown that the boundary condition with the penalization approach is suitable for the case of the fluid flow in a channel with vibrating walls.
    Permanent Link: http://hdl.handle.net/11104/0298227

     
     
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