Petr Sváček scite author profile

The subject of this paper is the numerical simulation of the interaction of two-dimensional incompressible viscous flow and a vibrating airfoil. A solid airfoil with two degrees of freedom, which can rotate around the elastic axis and oscillate in the vertical direction, is considered. The numerical simulation consists of the finite element solution of the Navier-Stokes equations, coupled with the system of ordinary differential equations describing the airfoil motion. The high Reynolds numbers considered 10 5 210 6 require the application of a suitable stabilization of the finite element discretization. The method presented in this paper is based on the laminar model and the turbulence modelling is not applied here. The time-dependent computational domain and a moving grid are taken into account with the aid of the arbitrary Lagrangian-Eulerian (ALE) formulation of the Navier-Stokes equations. Special attention is paid to the time discretization and the solution of the nonlinear discrete problem on each time level is performed. As a result, a sufficiently accurate and robust method is developed, which is applied to the case of flow-induced airfoil vibrations with large amplitudes after the loss of aeroelastic stability. The computational results are compared with known aerodynamical data and with results of aeroelastic calculations obtained by NASTRAN code for a linear approximation. r

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Numerical analysis of flow-induced nonlinear vibrations of an airfoil with three degrees of freedom

Feistauer

Horáček

Růžička

et al. 2011

Computers & Fluids

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Finite element approximation of flow induced vibrations of human vocal folds model: Effects of inflow boundary conditions and the length of subglottal and supraglottal channel on phonation onset

Sváček

Horáček

2018

Applied Mathematics and Computation

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Numerical simulation of interaction between turbulent flow and a vibrating airfoil

Dubcová

Feistauer

Horáček

et al. 2008

Comput. Visual Sci.

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On the Application of Acoustic Analogies in the Numerical Simulation of Human Phonation Process

Valášek

Kaltenbacher

Sváček

2018

Flow Turbulence Combust

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Petr Sváček

Numerical simulation of flow induced airfoil vibrations with large amplitudes

Numerical analysis of flow-induced nonlinear vibrations of an airfoil with three degrees of freedom

Finite element approximation of flow induced vibrations of human vocal folds model: Effects of inflow boundary conditions and the length of subglottal and supraglottal channel on phonation onset

Numerical simulation of interaction between turbulent flow and a vibrating airfoil

On the Application of Acoustic Analogies in the Numerical Simulation of Human Phonation Process

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