Your search keyword '"Stabilized finite element"' showing total 6 results

1. A robust and accurate finite element framework for cavitating flows with moving fluid-structure interfaces.

Author

Kashyap, Suraj R. and Jaiman, Rajeev K.

Subjects

*CAVITATION, *BUBBLE dynamics, *LINEAR differential equations, *REYNOLDS number, *TRANSPORT equation, *TIME integration scheme

Abstract

• Novel robust and accurate finite element scheme for homogenous mixture cavitation. • Stable linearizations of finite mass transfer for cavitation transport equations. • Fully implicit partitioned iterative coupling for turbulent FSI and cavitation. • Assessment of convergence and accuracy through bubble collapse problem. • Demonstration to 3D pitching hydrofoil undergoing cloud cavitation. In the current work, we present a variational mechanics framework for the coupled numerical prediction of cavitating turbulent flow and structural motion via a stabilized finite element formulation. To model the finite mass transfer rate in cavitation phenomena, we employ the homogenous mixture-based approach via phenomenological scalar transport differential equations given by the linear and nonlinear mass transfer functions. Stable linearizations of the finite mass transfer terms for the mass continuity equation and the reaction term of the scalar transport equations are derived for the robust and accurate implementation. The linearized matrices for the cavitation equation are imparted a positivity-preserving property to address numerical oscillations arising from high-density gradients typical of two-phase cavitating flows. The proposed formulation is strongly coupled in a partitioned manner with an incompressible 3D Navier-Stokes finite element solver, and the unsteady problem is advanced in time using a fully-implicit generalized- α time integration scheme. We first verify the implementation on the benchmark case of the Rayleigh bubble collapse. We demonstrate the accuracy and convergence of the cavitation solver by comparing the numerical solutions with the analytical solutions of the Rayleigh-Plesset equation for bubble dynamics. We find our solver to be robust for large time steps and the absence of spurious oscillations/spikes in the pressure field. The cavitating flow solver is coupled with a hybrid URANS-LES turbulence model. We validate the coupled solver for a very high Reynolds number turbulent cavitating flow over a NACA0012 hydrofoil section. Finally, the proposed method is applied in an Arbitrary Lagrangian-Eulerian framework to study turbulent cavitating flow over a pitching hydrofoil section and the characteristic features of cavitating flows such as re-entrant jet and periodic cavity shedding are discussed. [ABSTRACT FROM AUTHOR]

Published

2021

2. A finite element framework for fluid–structure interaction of turbulent cavitating flows with flexible structures.

Author

Darbhamulla, Nihar B. and Jaiman, Rajeev K.

Subjects

*FLUID-structure interaction, *TURBULENT flow, *FLUID flow, *CAVITATION, *TURBULENCE, *FLEXIBLE structures

Abstract

We present a finite element framework for the numerical prediction of cavitating turbulent flows interacting with flexible structures. The vapor–fluid phases are captured through a homogeneous mixture model, with a scalar transport equation governing the spatio-temporal evolution of cavitation dynamics. High-density gradients in the two-phase cavitating flow motivate the use of a positivity-preserving Petrov–Galerkin stabilization method in the variational framework. A mass transfer source term introduces local compressibility effects arising as a consequence of phase change. The turbulent fluid flow is modeled through a dynamic subgrid-scale method for large eddy simulations. The flexible structure is represented by a set of eigenmodes, obtained through a modal decomposition of the linear elasticity equations. While a partitioned iterative approach is adopted to couple the structural dynamics and cavitating fluid flow, the deforming flow domain is described by an arbitrary Lagrangian–Eulerian frame of reference. We establish the fidelity of the proposed framework by comparing it against experimental and numerical studies for both rigid and flexible hydrofoils in cavitating flows. Under unstable partial cavitating conditions, we identify specific vortical structures leading to cloud cavity collapse. We further explore features of cavitating flow past a rigid body such as re-entrant jet and turbulence-cavity interactions during cloud cavity collapse. Based on the validation study conducted over a flexible NACA66 rectangular hydrofoil, we elucidate the role of cavity and vortex shedding in governing the structural dynamics. Subsequently, we identify a broad spectrum frequency band whose central peak does not correlate to the frequency content of the cavitation dynamics or the natural frequencies of the structure, indicating the induction of unsteady flow patterns around the hydrofoil. Finally, we discuss the coupled fluid–structure dynamics during a cavitation cycle and the underlying mechanism associated with the promotion and mitigation of cavitation. • Unified variational framework for cavitating flow and fluid–structure interaction. • Robust and accurate cavitation modeling via homogeneous mixture theory. • Partitioned iterative coupling for turbulent cavitating flow-structure interaction. • Validation of turbulent cavitating flow for rigid and flexible hydrofoils. • Role of bend-twist coupling in altering cavity-vortex shedding dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

3. A finite element framework for fluid–membrane interactions involving fracture.

Author

Furquan, Mohd and Mittal, Sanjay

Subjects

*STRUCTURAL failures, *FLUID flow, *HYDROSTATIC pressure, *FINITE element method, *GALERKIN methods

Abstract

We propose a novel framework for investigating fluid–membrane interactions involving fracture, and apply it to simulate initial stages during the bursting of a balloon. Fluid flow is computed using a stabilized space–time finite element method over a body-fitted mesh. The membrane is modelled as a hyperelastic material and the equations are solved using the standard Galerkin method. Structural failure is incorporated using the element deletion technique based on a simple strain based criterion. Change in topology of the fluid domain due to element deletion is handled without resorting to remeshing. The coincident fluid nodes on either side of the deleted membrane elements on the surface of the balloon are connected, thereby allowing the fluid to gush through the opening. First, fluid–membrane interaction, without failure, in a square sail with fixed edges is studied. The sail exhibits vibration owing to vortices shed from its edges. We then study the inflation and deflation of a spherical balloon equipped with an inlet pipe. A hydrostatic pressure gradient is applied to drive the flow into the balloon. Effect of different values of membrane density, stiffness and the hydrostatic pressure gradient on inflation rate and balloon shape is studied. The bursting of the inflated balloon is initiated by deleting one structural element on its surface. The proposed algorithm is then applied to simulate the subsequent dynamics of the fluid–membrane system. [ABSTRACT FROM AUTHOR]

Published

2023

4. Numerical simulation of blood flows through a porous interface

Author

Jean-Frédéric Gerbeau, Miguel Angel Fernández, Vincent Martin, Numerical simulation of biological flows (REO), Laboratoire Jacques-Louis Lions (LJLL), Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)-Inria Paris-Rocquencourt, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria), Laboratoire de Mathématiques Appliquées de Compiègne (LMAC), and Université de Technologie de Compiègne (UTC)

Subjects

medicine.medical_treatment, Physics::Medical Physics, 0206 medical engineering, fluid-structure interaction, Geometry, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Stabilized finite element, Physics::Fluid Dynamics, Aneurysm, Fluid–structure interaction, medicine, blood flow, cardiovascular diseases, 0101 mathematics, Computer Science::Distributed, Parallel, and Cluster Computing, Mathematics, Numerical Analysis, terminal aneurysm, Computer simulation, Applied Mathematics, Numerical analysis, Stent, sieve problem, Mechanics, Stokes flow, equipment and supplies, medicine.disease, 020601 biomedical engineering, Finite element method, Computational Mathematics, Modeling and Simulation, cardiovascular system, Dissipative system, stent, [MATH.MATH-NA]Mathematics [math]/Numerical Analysis [math.NA], Analysis

Abstract

International audience; We propose a model for a medical device, called a stent, designed for the treatment of cerebral aneurysms. The stent consists of a grid, immersed in the blood flow and located at the inlet of the aneurysm. It aims at promoting a clot within the aneurysm. The blood flow is modelled by the incompressible Navier-Stokes equations and the stent by a dissipative surface term. We propose a stabilized finite element method for this model and we analyse its convergence in the case of the Stokes equations. We present numerical results for academical test cases, and on a realistic aneurysm obtained from medical imaging.

Published

2008

5. Contribution à la modélisation des interactions fluides-structures

Author

Belakroum, Rassim, Legrand, Mathias, Université de Reims Champagne-Ardenne (URCA), Université de Reims Champagne-Ardenne, and Mahfoud Kadia

Subjects

éclatements tourbillonnaires, ballottement, approche pseudo-élastique, stabilized finite element, sloshing, Interactions fluides-structures, [SPI.MECA]Engineering Sciences [physics]/Mechanics [physics.med-ph], [SPI.MECA] Engineering Sciences [physics]/Mechanics [physics.med-ph], éléments finis stabilisés, méthode de Gauss-Seidel par bloc, coupling algorithm, instability, maillage déformable, deformable mesh, Fluid-structure interaction, filtre de Smagorinsky, pseudo-elastic approach, vortex shedding, Instabilité, algorithme de couplage, arbitrary Lagrangian Eulerian formulation, formulation arbitrairement Lagrangienne Eulérienne

Abstract

The main goals sought by this thesis target the development and expertise of a methodologyfor numerical simulation of fluid-structure interactions problems. In order to identify thestudied problem progressively, we are interested primarily in numerical simulation of flowsaround bluff bodies, especially the phenomenon of vortex shedding in the wake zone of abluff body of different shapes. We used the finite element method by adopting the stabilizedGLS (Galerkin Least-Square) technique. For the treatment of turbulence, we opted the LES(Large-Eddy Simulation) method using the Smagorinsky filter. In the second phase, we wereinterested in flows in deformable media. We undertook the ALE (Arbitrary LagrangianEulerian) formulation by considering a deformable mesh. To update the grid of the dynamicmesh, we used a pseudo-elastic approach. To appraise the implemented methodology, wedecided to approach the problem of sloshing at the free surface of a tank partially filled withliquid. In the final part, we were interested in vibration behavior of a solid body under theeffect of fluid flow. By using a fully implicit coupling algorithm based on a relaxed BlocGauss-Seidel method, we studied the phenomenon of aeroelastic instability of cable-stayedbridges. To validate the numerical model treating fluid-structure interactions by experimentaldata, we investigated the vibration behavior of a real deck sectional model under the effect ofa uniform wind., Les buts principaux recherchés de la présente thèse visent au développement et à l’expertised’une méthodologie de simulation numérique des problèmes d’interactions fluides-structures.Afin de cerner progressivement le problème étudié, nous nous sommes intéressés en premierlieu à la simulation numérique des écoulements autour d’obstacles solides, plusparticulièrement au phénomène d’éclatements tourbillonnaires dans la zone de sillaged’obstacles de différentes formes. Nous avons utilisé la méthode des éléments finis enadoptant la technique de stabilisation GLS (Galerkin Least-Square). Pour le traitement de laturbulence, nous avons opté pour la méthode LES (Large-Eddy Simulation) en utilisant lefiltre de Smagorinsky. En deuxième phase, nous nous sommes intéressés aux écoulements enmilieux déformables. Nous avons entrepris la formulation ALE (Arbitrairement LagrangienneEulérienne) en considérant un maillage déformable. Pour la mise à jour de la grille dumaillage dynamique, nous avons utilisé une approche pseudo-élastique. Afin d’expertiser laméthodologie mise en œuvre, nous avons choisi d’aborder le problème des ballottements à lasurface libre de réservoirs partiellement remplis de liquide. En dernière partie, nous noussommes intéressés au comportement vibratoire d’un corps solide sous l’effet d’un écoulementde fluide. Par l’utilisation d’un algorithme de couplage totalement implicite basé sur laméthode de Gauss-Seidel par Bloc, nous avons abordé le phénomène des instabilitésaéroélastiques des ponts à haubans. Pour la validation du modèle numérique traitant lesinteractions fluides-structures par les données expérimentales, nous nous sommes intéressésau comportement vibratoire d’une maquette sectionnelle d’un tablier de pont réel sous l’effetd’un vent soufflant uniforme.

Published

2011

6. Numerical simulation of blood flows through a porous interface

Author

Fernández, Miguel Angel, Gerbeau, Jean-Frédéric, Martin, Vincent, Numerical simulation of biological flows (REO), Laboratoire Jacques-Louis Lions (LJLL), Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)-Inria Paris-Rocquencourt, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria), Laboratoire de Mathématiques Appliquées de Compiègne (LMAC), Université de Technologie de Compiègne (UTC), This work was partially supported by Cardiatis., and INRIA

Subjects

terminal aneurysm, Physics::Medical Physics, stabilized finite element, fluid-structure interaction, sieve problem, equipment and supplies, Physics::Fluid Dynamics, cardiovascular system, blood flow, stent, cardiovascular diseases, Computer Science::Distributed, Parallel, and Cluster Computing, ACM: G.: Mathematics of Computing/G.1: NUMERICAL ANALYSIS, [MATH.MATH-NA]Mathematics [math]/Numerical Analysis [math.NA]

Abstract

We propose a model for a medical device, called a stent, designed for the treatment of cerebral aneurysms. The stent consists of a grid, immersed in the blood flow and located at the inlet of the aneurysm. It aims at promoting a clot within the aneurysm. The blood flow is modelled by the incompressible Navier-Stokes equations and the stent by a dissipative surface term. We propose a stabilized finite element method for this model and we analyse its convergence in the case of the Stokes equations. We present numerical results for academical test cases, and on a realistic aneurysm obtained from medical imaging.

Published

2007