An implicit integral formulation to model inviscid fluid flows in obstructed media

Colas, Clément; Ferrand, Martin; Hérard, Jean-Marc; Latché, Jean-Claude; Coupanec, Erwan Le

doi:10.1016/j.compfluid.2019.05.014

Cited by 6 publications

(1 citation statement)

References 16 publications

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“…We discuss below some results of this preliminary study. Other results with distinct EOS are available in [2]. Two subsonic test cases, corresponding to 1D Riemann problems with a diatomic ideal gas EOS (γ = 7 5 ), are performed with CFL= 0.5.…”

Section: Numerical Resultsmentioning

confidence: 99%

A Numerical Convergence Study of Some Open Boundary Conditions for Euler Equations

Colas

Ferrand

Hérard

et al. 2020

Finite Volumes for Complex Applications IX - Methods, Theoretical Aspects, Examples

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We discuss herein the suitability of some open boundary conditions. Considering the Euler system of gas dynamics, we compare approximate solutions of one-dimensional Riemann problems in a bounded sub-domain with the restriction in this sub-domain of the exact solution in the infinite domain. Assuming that no information is known from outside of the domain, some basic open boundary condition specifications are given, and a measure of the L 1-norm of the error inside the computational domain enables to show consistency errors in situations involving outgoing shock waves, depending on the chosen boundary condition formulation. This investigation has been performed with Finite Volume methods, using approximate Riemann solvers in order to compute numerical fluxes for inner interfaces and boundary interfaces.

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Section: Numerical Resultsmentioning

confidence: 99%

A Numerical Convergence Study of Some Open Boundary Conditions for Euler Equations

Colas

Ferrand

Hérard

et al. 2020

Finite Volumes for Complex Applications IX - Methods, Theoretical Aspects, Examples

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A time‐staggered second order conservative time scheme for variable density flow

Amino

Flageul

Benhamadouche

et al. 2022

Numerical Methods in Fluids

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In this study, we present a robust conservative time-staggered scheme for variable density flow. This pressure correction scheme uses the compressible Navier-Stokes equations and is implemented in the collocated finite-volume open-source computational fluid dynamics solver code_saturne. The Helmholtz equation is solved for the pressure increment, taking the thermodynamic pressure into account and avoiding the acoustic time step limitation. The internal energy equation is used and completed by a source term derived from the discrete kinetic energy equation, thus enforcing total energy conservation and consistency for irregular solutions. A numerical analysis providing conditions ensuring the positivity of the thermodynamic variables is proposed. The scheme is verified and validated against analytical and experimental test cases. Its ability to reproduce the pressure variation while conserving the mass is demonstrated. Its conservative property and time convergence order are also verified. An irregular shock solution is studied, emphasizing the importance of the source term in the internal energy equation. Finally, the scheme is validated against reference numerical results on a two-dimensional natural convection cavity and experimental data on a three-dimensional ventilation test case. The comparison against experimental data is made using first-and second-order turbulent simulations.

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Automatic Solid Reconstruction from 3-D Points Set for Flow Simulation via an Immersed Boundary Method

Narváez,

Ferrand,

Fonty

et al. 2023

Springer Proceedings in Mathematics &Amp; Statistics

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An implicit integral formulation to model inviscid fluid flows in obstructed media

Cited by 6 publications

References 16 publications

A Numerical Convergence Study of Some Open Boundary Conditions for Euler Equations

A Numerical Convergence Study of Some Open Boundary Conditions for Euler Equations

A time‐staggered second order conservative time scheme for variable density flow

Automatic Solid Reconstruction from 3-D Points Set for Flow Simulation via an Immersed Boundary Method

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