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2. Numerical Wire Mesh Model for the Simulation of Noise-Reduction Devices

Author

Marc Terracol and Eric Manoha

Subjects
Physics, 020301 aerospace & aeronautics, business.industry, Wire mesh, Noise reduction, Aerospace Engineering, 02 engineering and technology, Mechanics, Computational fluid dynamics, Kinetic energy, 01 natural sciences, 010305 fluids & plasmas, symbols.namesake, Flow conditions, 0203 mechanical engineering, 0103 physical sciences, symbols, Strouhal number, business, Reynolds-averaged Navier–Stokes equations, Landing gear
Abstract

This study deals with the development of a numerical wire mesh screen model for the unsteady simulation of aeroacoustic configurations. Such devices are indeed of growing interest for practical app...

Published
2021
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6. Numerical simulation of acoustic scattering by a plane turbulent shear layer: Spectral broadening study

Author

Marc Terracol, P. Dupont, Lionel Larchevêque, Iannis Bennaceur, Daniel-Ciprian Mincu, Ivan Mary, ONERA - The French Aerospace Lab [Châtillon], ONERA-Université Paris Saclay (COmUE), Institut universitaire des systèmes thermiques industriels (IUSTI), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), and Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)

Subjects
General Computer Science, Turbulent shear layer, Acoustics, 01 natural sciences, 010305 fluids & plasmas, Scattering, Physics::Fluid Dynamics, symbols.namesake, Spectral broadening, Large-eddy simulation, 0103 physical sciences, Aeroacoustics, 010301 acoustics, Physics, Turbulence, General Engineering, Spectral density, Reynolds number, Acoustic wave, Haystacking, [PHYS.MECA.ACOU]Physics [physics]/Mechanics [physics]/Acoustics [physics.class-ph], Computational physics, Amplitude, Mach number, symbols, Large eddy simulation
Abstract

International audience; The scattering of an acoustic wave by a 3D spatially-developing plane turbulent mixing layer is investigated by means of a Large Eddy Simulation (LES). First, a plane turbulent mixing layer of initial Reynolds number Reω, 0 ≈ 1200 and convective Mach number Mc ≈ 0.12 is computed and its characteristics are validated by comparisons to experimental and numerical studies. Then, an acoustic source is introduced in the computational domain and the LES of both the turbulent mixing layer and the acoustic field is carried out, allowing the direct computation of the scattered pressure field. Computational Aero Acoustics (CAA) methods have been implemented to minimize spurious pressure fluctuations created while the turbulent structures leave the computational domain. The side-lobes of the scattered pressure power spectral density are recovered and a parametric study, involving the convection velocity of the large turbulent structures, the amplitude and the tonal frequency of the source is carried out. The part of scattered energy, the frequency shift of the side-lobes and the spectra decrease are found to be correctly estimated. Analysis of directivity at the side-lobes frequencies show a progressive re-distribution of the acoustic energy, as the acoustic wave propagates through the turbulent shear layer.

Published
2016
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7. Investigation of the Unsteady Flow and Noise Generation in a Slat Cove

Author

Eric Manoha, Benoit Lemoine, Marc Terracol, ONERA - The French Aerospace Lab [Châtillon], ONERA-Université Paris Saclay (COmUE), Laboratoire de Mecanique des Fluides et d'Acoustique (LMFA), École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), and Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)

Subjects
Airfoil, 020301 aerospace & aeronautics, Lift coefficient, Engineering, business.industry, Aerospace Engineering, 02 engineering and technology, Mechanics, Structural engineering, Boundary layer thickness, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, 0203 mechanical engineering, 0103 physical sciences, Aeroacoustics, Mean flow, [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], Computational aeroacoustics, business, Reynolds-averaged Navier–Stokes equations, ComputingMilieux_MISCELLANEOUS, Large eddy simulation
Abstract

This study presents hybrid Reynolds-averaged Navier–Stokes/large-eddy simulations of the unsteady flow and noise-generation phenomena in the slat cove of a high-lift wing profile. These computations are part of a joint numerical/experimental aeroacoustics collaborative program dedicated to slat-flow analysis. A dedicated two-element wing profile (slat plus main body) has been designed to isolate slat noise from other possible sources (e.g., the flap), while minimizing mean flow deflection effects, to improve the fidelity of open-jet wind-tunnel measurements. The design of this two-element airfoil has been performed numerically, using an optimization process based on steady Reynolds-averaged Navier–Stokes calculations. This airfoil has been investigated experimentally at the Ecole Centrale de Lyon open jet facility. Unsteady zonal hybrid Reynolds-averaged Navier–Stokes/large-eddy simulations have been performed to provide a comprehensive description of the unsteady flow inside the slat cove, focusing on th...

Published
2016
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9. Turbulence and Interactions : Proceedings of the TI 2015 Conference, June 11-14, 2015, Cargèse, Corsica, France

Author

Michel O. Deville, Vincent Couaillier, Jean-Luc Estivalezes, Vincent Gleize, Thiên HiêpLê, Marc Terracol, Stéphane Vincent, Michel O. Deville, Vincent Couaillier, Jean-Luc Estivalezes, Vincent Gleize, Thiên HiêpLê, Marc Terracol, and Stéphane Vincent

Subjects
Turbulence--Mathematical models--Congresses, Turbulence--Congresses
Abstract

This book presents a snapshot of the state-of-art in the field of turbulence modeling, with an emphasis on numerical methods. Topics include direct numerical simulations, large eddy simulations, compressible turbulence, coherent structures, two-phase flow simulation and many more. It includes both theoretical contributions and experimental works, as well as chapters derived from keynote lectures, presented at the fourth Turbulence and Interactions Conference (TI 2015), which was held on June 11-14 in Cargèse, Corsica, France. This multifaceted collection, which reflects the conference´s emphasis on the interplay of theory, experiments and computing in the process of understanding and predicting the physics of complex flows and solving related engineering problems, offers a timely guide for students, researchers and professionals in the field of applied computational fluid dynamics, turbulence modeling and related areas.

Published
2018

12. Physical Analysis of Acoustic Scattering by a Turbulent Shear Layer using Numerical Simulation

Author

Ivan Mary, Dupont Pierre, Lionel Larchevêque, Marc Terracol, Daniel C. Mincu, and Iannis Bennaceur

Subjects
020301 aerospace & aeronautics, Shear layer, Materials science, 0203 mechanical engineering, Computer simulation, Scattering, Turbulence, 0103 physical sciences, 02 engineering and technology, Mechanics, 01 natural sciences, 010305 fluids & plasmas
Published
2016
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13. A mixed overset grid/immersed boundary approach for CFD simulations of complex geometries

Author

Vincent Gleize, Stéphanie Péron, Christophe Benoit, Ivan Mary, and Marc Terracol

Subjects
020301 aerospace & aeronautics, Turbulence, Computer science, business.industry, Computation, Boundary (topology), 02 engineering and technology, Immersed boundary method, Computational fluid dynamics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Computational science, Computational physics, Boundary layer, 0203 mechanical engineering, law, Obstacle, 0103 physical sciences, Cartesian coordinate system, business, ComputingMethodologies_COMPUTERGRAPHICS
Abstract

A methodology to mix Chimera and Immersed Boundary approaches in the same CFD computation is presented in order to deal with complex geometries. Where accuracy is required in a vicinity of an obstacle, a body-fitted mesh is used to accurately simulate the boundary layer. Otherwise, an immersed boundary method (IBM) is applied to deal with this obstacle. Each body-fitted mesh is generated independently in an overset grid fashion. A set of Cartesian grids that are adapted to the spatial resolution of body-fitted grids and immersed boundaries is generated automatically and overlaps the body-fitted grids. In this paper, we describe the overall procedure to mix the overset grid and immersed boundary approaches, then we detail how the present IBM enables to deal with geometrically complex configurations. Finally, preliminary results of the simulation of a turbulent flow past two cylinders in tandem are presented.

Published
2016
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14. Turbulence and Interactions : Proceedings of the TI 2012 Conference

Author

Michel O. Deville, Jean-Luc Estivalezes, Vincent Gleize, Thien-Hiep Lê, Marc Terracol, Stéphane Vincent, Michel O. Deville, Jean-Luc Estivalezes, Vincent Gleize, Thien-Hiep Lê, Marc Terracol, and Stéphane Vincent

Subjects
Engineering, Turbulence--Mathematical models--Congresses, Turbulence--Congresses
Abstract

The book presents a snapshot of the state-of-art in the field of turbulence modeling and covers the latest developments concerning direct numerical simulations, large eddy simulations, compressible turbulence, coherent structures, two-phase flow simulation and other related topics. It provides readers with a comprehensive review of both theory and applications, describing in detail the authors'own experimental results. The book is based on the proceedings of the third Turbulence and Interactions Conference (TI 2012), which was held on June 11-14 in La Saline-les-Bains, La Réunion, France and includes both keynote lectures and outstanding contributed papers presented at the conference. This multifaceted collection, which reflects the conference´s emphasis on the interplay of theory, experiments and computing in the process of understanding and predicting the physics of complex flows and solving related engineering problems, offers a practice-oriented guide for students, researchers and professionals in the field of computational fluid dynamics, turbulence modeling and related areas.

Published
2014

15. Numerical investigation of the tone noise mechanism over laminar airfoils

Author

Marc Terracol, Pierre Sagaut, and G. Desquesnes

Subjects
Physics, Airfoil, Angle of attack, Mechanical Engineering, Acoustics, Direct numerical simulation, Reynolds number, Laminar flow, Condensed Matter Physics, Vortex, Physics::Fluid Dynamics, Boundary layer, symbols.namesake, Mechanics of Materials, symbols, Mean flow
Abstract

This paper presents the first numerical investigation via direct numerical simulation of the tone noise phenomenon occurring in the flow past laminar airfoils. This phenomenon corresponds to the radiation of discrete acoustic tones in some specific flow conditions, and has received much attention since the 1970s, and several experimental studies have been carried out to identify and understand the underlying physical mechanisms. However, several points remain to be clarified in order to provide a complete explanation of its origin. The flow around a two-dimensional NACA0012 airfoil is considered in order to have a deeper understanding of the tone noise phenomenon. Consistently with previous experimental studies, it is shown that depending on the Reynolds number and angle of attack, two different types of acoustic spectrum are observed: one which exhibits a broadband contribution with a dominant frequency together with a sequence of regularly spaced discrete frequencies, while the other one is only characterized by a simple broadband contribution. The first configuration is typical of the tone noise phenomenon. The present work shows that in this case, the mean flow on the pressure side of the airfoil exhibits a separation bubble near the trailing edge and the main tone frequency is close to the most amplified frequency of the boundary layer. The mechanism proposed in previous works for the main tone generation – which implies the existence of a separation bubble at the pressure side – is therefore validated by numerical simulation. On the other hand, the analysis of the suction side boundary layer reveals that there is no separation and that the most amplified frequency is different from the main tonal one. However, the suction side boundary layer is highly receptive to the tone frequency. Finally, an original explanation for the existence of the secondary discrete frequencies observed in the radiated pressure spectrum is given. They are associated to a bifurcation of the airfoil wake from a symmetric to a non-symmetric vortex pattern. A possible explanation for the existence of this bifurcation is the interaction between the disturbances which are the most amplified by the suction side boundary layer and those originating in the forcing of the suction side flow by the main tone noise mechanism.

Published
2007
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16. Commutation error in LES with time-dependent filter width

Author

S. Léonard, Pierre Sagaut, and Marc Terracol

Subjects
General Computer Science, Low-pass filter, Mathematical analysis, General Engineering, Geometry, Invariant extended Kalman filter, Gaussian filter, Adaptive filter, Filter design, symbols.namesake, Filter (video), Kernel adaptive filter, symbols, m-derived filter, Mathematics
Abstract

This paper presents an investigation of the possible commutation errors arising in Large Eddy Simulations performed with a filter width which varies in time, e.g. when the grid/spectral resolution is modified dynamically during the computations. Some theoretical developments provide an explicit expression for this error, which is shown to depend explicitly on the filter kernel properties, and on the time derivative of the cut-off length. From this analysis, some constraints on the filter kernel are derived in order to minimize the error. The particular case of a Gaussian filter is considered, which yields to a first error term. Finally, the dependency of the temporal commutation error to the variations of the filter width is investigated by performing a priori tests in the case of isotropic homogeneous turbulence with a varying cut-off length.

Published
2007
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17. Aeroacoustic Calculations of the 30P30N High-lift Airfoil using Hybrid RANS/LES methods: Modeling and Grid Resolution Effects

Author

Eric Manoha, Mitsuhiro Murayama, Kazuomi Yamamoto, and Marc Terracol

Subjects
Physics, Airfoil, Noise, Computation, Reflection (physics), Detached eddy simulation, Mechanics, Grid, Reynolds-averaged Navier–Stokes equations, Wind tunnel
Abstract

This study presents several unsteady computations of the 30P30N three-element high-lift airfoil, focused on slat noise prediction. These simulations rely on several RANS/LES approaches: two global hybrid approaches, DDES (Delayed Detached Eddy Simulation) and ZDES (Zonal Detached Eddy Simulation) and one zonal approach, the NLDE (Non-Linear Disturbance Equations). Global approaches compute all the geometry, while zonal simulations only consider an LES domain clustered around the slat to save computational resources. Two grid resolutions are considered, in order to perform a critical comparison of both the modeling and grid resolution effects for this kind of configuration. The obtained results are favorably compared to near-field results measurements obtained in JAXA low-speed Wind Tunnel (JAXA-LWT2): narrow band peaks present in the pressure spectra are well recovered by all the simulations, with a very good agreement with the measurements for the fine grid results, while the medium grid simulations tend to over-estimate the magnitude of these peaks. It is also observed that the DDES approach seems to delay the development of instabilities in the slat cusp shear layer, while other approaches lead to a faster break-up of the shear layer. The zonal NLDE approach leads to significant CPU time savings due to the reduced number of grid points, as well as to shorter transient times. However, such simulations do not account for the whole diffraction and reflection effects, as observed on the far-field acoustic field.

Published
2015
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18. Numerical simulation of spectral broadening of an acoustic wave by a spatially growing turbulent mixing layer

Author

Daniel-Ciprian Mincu, Lionel Larchevêque, Marc Terracol, Dupont Pierre, Ivan Mary, and Iannis Bennaceur

Subjects
Physics, Scattering, Acoustics, Spectral density, Potential flow, Near and far field, Acoustic wave, Mixing (physics), Computational physics, Doppler broadening, Large eddy simulation
Abstract

The scattering of an acoustic wave by a fully turbulent mixing layer is investigated by means of a Large Eddy Simulation. The turbulent characteristics of the mixing layer have been validated by comparison to experimental and numerical studies. Computational Aero Acoustics (CAA) methods have been used to minimize spurious pression fluctuations created while the turbulent structures leave the computational domain. Then, an acoustic source has been placed inside a uniform flow and the acoustic propagation has been validated. Finally, both the turbulent mixing layer and the acoustic field are calculated and the scattering phenomenon is investigated. The ’double-humped’ structures of the far field power spectral density is recovered and a parametrical study, involving the tonal frequency of the source is carried out. The comparison to previous experimental works have been enabled thanks to the definition of a relevant scattering parameter. The spectra are in good agreement with experimental works on acoustic scattering. The frequency shift of the sidelobes and the spectra’s decrease are well predicted and in a good agreement with the ones found in the literature.

Published
2015
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19. On the use of a high order overlapping grid method for coupling in CFD/CAA

Author

Pierre Sagaut, G. Desquesnes, Eric Manoha, and Marc Terracol

Subjects
Numerical Analysis, Curvilinear coordinates, Physics and Astronomy (miscellaneous), business.industry, Applied Mathematics, Mathematical analysis, Geometry, Computational fluid dynamics, Vortex shedding, Computer Science Applications, Regular grid, Computational Mathematics, Noise, Modeling and Simulation, Aeroacoustics, Mean flow, business, Interpolation, Mathematics
Abstract

This paper presents a theoretical analysis and two applications of a high-order overlapping grid method for coupling Cartesian and curvilinear grids, developed in order to simulate aerodynamic noise. First, the overlapping grid method based on Lagrange interpolating polynomials is described and a theoretical analysis of the interpolation operator is then carried out. It shows that the interpolation generates spurious modes that depend on the wavenumbers of the signal. Besides it also gives the optimal conditions in which interpolation can be applied. Then an application to the simulation of the aeroacoustic noise generated by the vortex shedding behind a cylinder is presented. During this simulation, it appears that interpolation can create some spurious acoustic modes in regions where hydrodynamic fluctuations are significant, as predicted by the theoretical analysis. It is shown that these spurious modes disappear when a refined Cartesian grid is used (26 points per wavelength of the vortex shedding were found to be adequate in this study). At last, the simulation of the aerodynamic noise of a three element high-lift wing profile has then been carried out. For this application, the main acoustic source at the slat trailing edge is represented analytically. The propagation of the generated acoustic wave is simulated with a mean flow at rest and with a steady turbulent mean flow computed by RANS. The first application allows us to assess the method by comparing the results to a reference solution. The second one shows that the influence of a non-uniform mean flow on the directivity of an acoustic source can be observed in complex geometries. This application therefore shows that the proposed coupling method is well adapted to complex geometries that are usually met in industrial applications.

Published
2006
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20. A Zonal RANS/LES Approach for Noise Sources Prediction

Author

Marc Terracol

Subjects
Airfoil, Computer simulation, Meteorology, Computer science, Turbulence, business.industry, General Chemical Engineering, General Physics and Astronomy, Mechanics, Aerodynamics, Computational fluid dynamics, Noise, Aeroacoustics, Physical and Theoretical Chemistry, Reynolds-averaged Navier–Stokes equations, business
Abstract

Hybrid CFD/CAA methods have generally to be used for the numerical simulation of trailing-edge noise (see [9, 20] for instance). This study focuses on the first step of such hybrid methods, which is to predict the unsteady aerodynamic sources by the mean of a 3D unsteady simulation of the flow. Such a simulation is however generally still away from the numerical capabilities of ‘usual’ supercomputers. This paper investigates the use of a zonal LES method (based on the NLDE – Non-Linear Disturbance Equations – technique) for the numerical prediction of the aerodynamic noise sources. This method makes it possible to perform only zonal LES close to the main elements responsible of sound generation, while the overall configuration is only treated by a RANS approach. Attention will be paid to the specific boundary treatment at the interface between the RANS and LES regions. More precisely, the problem of the generation of turbulent inflow conditions for the LES region will be carefully addressed. The method is first assessed in the simulation of a flat plate ended by a blunted trailing-edge, and then applied to the simulation of the flow over a NACA0012 airfoil with blunted trailing-edge.

Published
2006
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21. Numerical Simulations of Fan Interaction Noise Using a Hybrid Approach

Author

Cyril Polacsek, Stephane Burguburu, Stephane Redonnet, and Marc Terracol

Subjects
Physics, Engineering, Computer simulation, business.industry, Computation, Aerospace Engineering, Mechanics, Computational fluid dynamics, Turbofan, Euler equations, Physics::Fluid Dynamics, Rotor–stator interaction, symbols.namesake, Noise, Classical mechanics, Euler's formula, symbols, Computational aeroacoustics, Reynolds-averaged Navier–Stokes equations, business, Boundary element method, Wind tunnel
Abstract

A source-to-far-field computation procedure aimed at predicting the noise generated by rotor-stator fan interactions is presented here. Interaction noise sources are assessed using a three-dimensional Reynolds-averaged Navier-Stokes (RANS) code. A modal expansion is applied to the computational fluid dynamics (CFD) data, and a source model is used to link the CFD to an Euler code simulating the acoustic propagation. Far-field noise is classically obtained by means of a Kirchhoff integral. The source model is detailed and validated over a selected benchmark. Then the hybrid method is applied to a turbofan model, tested in the German-Dutch Wind Tunnel. Simulations are compared to boundary element method computations previously performed and used here to validate the no-flow solution. Interacting cut-on mode amplitude deduced from CFD output postprocessing is adjusted to fit in-duct measurements on the outer wall. The predicted radiation field is related to the directivity patterns measured at several axial positions upstream of the fan inlet and fairly good agreement is found using the RANS/Euler/Kirchhoff procedure.

Published
2006
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22. Study of stabilization methods for computational aeroacoustics

Author

Marc Terracol and Ronan Guenanff

Subjects
Marketing, Strategy and Management, Finite difference method, Finite difference, Boundary (topology), Euler equations, symbols.namesake, Control theory, Media Technology, Aeroacoustics, symbols, Applied mathematics, General Materials Science, Computational aeroacoustics, Boundary value problem, Numerical stability, Mathematics
Abstract

The use of high-order centered finite difference to solve the Euler equations commonly requires a stabilization procedure. The present work is a theoretical analysis of these stabilization methods that make the whole algorithm (i) still consistent with the continuous problem and (ii) able to run long time simulations. In the present study, a theoretical analysis of the three commonly used methods resorting to the application of high-order filters is performed. An extension to non-periodic boundary conditions is studied to avoid numerical reflection and numerical instabilities due to the use of specific boundary schemes. To cite this article: R. Guenanff, M. Terracol, C. R. Mecanique 333 (2005).

Published
2005
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23. Hybrid methods for airframe noise numerical prediction

Author

Emmanuel Labourasse, Stephane Redonnet, Marc Terracol, P. Sagaut, C. Herrero, and Eric Manoha

Subjects
Fluid Flow and Transfer Processes, Physics, Computer simulation, business.industry, Acoustics, General Engineering, Computational Mechanics, Computational fluid dynamics, Solver, Condensed Matter Physics, Euler equations, Computational physics, symbols.namesake, Noise, Airframe, Aeroacoustics, symbols, business, Large eddy simulation
Abstract

This paper describes some significant steps made towards the numerical simulation of the noise radiated by the high-lift devices of a plane. Since the full numerical simulation of such configuration is still out of reach for present supercomputers, some hybrid strategies have been developed to reduce the overall cost of such simulations. The proposed strategy relies on the coupling of an unsteady nearfield CFD with an acoustic propagation solver based on the resolution of the Euler equations for midfield propagation in an inhomogeneous field, and the use of an integral solver for farfield acoustic predictions.

Published
2005
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24. Multiscale And Multiresolution Approaches In Turbulence - Les, Des And Hybrid Rans/les Methods: Applications And Guidelines (2nd Edition)

Author

Pierre Sagaut, Marc Terracol, Sebastien Deck, Pierre Sagaut, Marc Terracol, and Sebastien Deck

Subjects
Turbulence--Mathematical models
Abstract

The book aims to provide the reader with an updated general presentation of multiscale/multiresolution approaches in turbulent flow simulations. All modern approaches (LES, hybrid RANS/LES, DES, SAS) are discussed and recast in a global comprehensive framework. Both theoretical features and practical implementation details are addressed. Some full scale applications are described, to provide the reader with relevant guidelines to facilitate a future use of these methods.

Published
2013

25. A multilevel-based dynamic approach for subgrid-scale modeling in large-eddy simulation

Author

Marc Terracol and Pierre Sagaut

Subjects
Fluid Flow and Transfer Processes, Physics, Homogeneous isotropic turbulence, Turbulence, Mechanical Engineering, Computational Mechanics, Reynolds number, Dissipation, Condensed Matter Physics, Power law, Open-channel flow, Physics::Fluid Dynamics, symbols.namesake, Mechanics of Materials, Inviscid flow, symbols, Statistical physics, Large eddy simulation
Abstract

In this paper we present a new dynamic methodology to compute the value of the numerical coefficient present in numbers of subgrid models, by mean of a multilevel approach. It is based on the assumption of a power law for the spectral density of kinetic energy in the range of the highest resolved wave numbers. It is shown that this assumption also allows us to define an equivalent law for the subgrid dissipation, and to obtain a reliable estimation for it through the introduction of a three-level flow decomposition. The model coefficient is then simply tuned dynamically during the simulation to ensure the proper amount of subgrid dissipation. This new dynamic procedure has been assessed here in inviscid homogeneous isotropic turbulence and plane channel flow simulations (with skin-friction Reynolds numbers up to 2000).

Published
2003
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26. A time self-adaptive multilevel algorithm for large-eddy simulation

Author

Marc Terracol, Claude Basdevant, and Pierre Sagaut

Subjects
Numerical Analysis, Physics and Astronomy (miscellaneous), Discretization, Computer science, Applied Mathematics, CPU time, Grid, Computer Science Applications, Open-channel flow, Physics::Fluid Dynamics, Computational Mathematics, Multigrid method, Inviscid flow, Modeling and Simulation, Reduction (mathematics), Algorithm, Large eddy simulation
Abstract

An extension of the multilevel method applied to LES proposed in Terracol et al. [J. Comput. Phys. 167 (2001) 439] is introduced here to reduce the CPU times in unsteady simulation of turbulent flows. Flow variables are decomposed into several wavenumber bands, each band being associated to a computational grid in physical space. The general framework associated to such a decomposition is presented, and a new adapted closure is proposed for the subgrid terms which appear at each filtering level, while the closure at the finest level is performed with a classical LES model. CPU time saving is obtained by the use of V-cycles, as in the multigrid terminology. The main part of the simulation is thus performed on the coarse levels, while the smallest resolved scales are kept frozen (quasi-static approximation [Comput. Methods Appl. Mech. Engrg. 159 (1998) 123]). This allows to reduce significantly the CPU times in comparison with classical LES, while the accuracy of the simulation is preserved by the use of a fine discretization level. To ensure the validity of the quasi-static approximation, a dynamic evaluation of the time during which it remains valid is performed at each level through an a priori error estimation of the small-scales time variation. This leads to a totally self-adaptive method in which both the number of levels and the integration times on each grid level are evaluated dynamically. The method is assessed on a fully unsteady time-developing compressible mixing layer at a low-Reynolds number for which a DNS has also been performed, and in the inviscid case. Finally, a plane channel flow configuration has been considered. In all cases, the results obtained are in good agreement with classical LES performed on a fine grid, with CPU time reduction factors of up to five.

Published
2003
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27. Wall-resolved Large Eddy Simulation of a highlift airfoil: detailed flow analysis and noise generation study

Author

Marc Terracol and Eric Manoha

Subjects
Airfoil, Noise generation, Computer science, business.industry, Flow (psychology), Grid cell, Aerospace engineering, business, Reynolds-averaged Navier–Stokes equations, Joint (geology), Wind tunnel, Large eddy simulation
Abstract

This study presents a highly-resolved Large Eddy Simulation of a three-element highlift airfoil with deployed slat and flap, which involves a large amount of CPU resources (2.6 billions of grid cells and 6 millions of CPU hours). The aim of this simulation is double: the first objective is to perform a detailed flow analysis and identify the physical events responsible for noise generation as well as the implied flow mechanisms; the second objective is to provide an important numerical database that may be used in the future to assess more affordable numerical approaches based for instance on hybrid RANS/LES methods. The assessment of the present LES relies on a recent experimental campaign performed in Onera F2 wind tunnel in the framework of a joint Onera/DLR project named LEISA2.

Published
2014
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28. A Multilevel Algorithm for Large-Eddy Simulation of Turbulent Compressible Flows

Author

Marc Terracol, Claude Basdevant, and Pierre Sagaut

Subjects
Numerical Analysis, Mathematical optimization, Physics and Astronomy (miscellaneous), Spacetime, Plane (geometry), Turbulence, Applied Mathematics, Reynolds number, Grid, Computer Science Applications, Open-channel flow, Physics::Fluid Dynamics, Computational Mathematics, symbols.namesake, Modeling and Simulation, symbols, Compressibility, Applied mathematics, Mathematics, Large eddy simulation
Abstract

A multilevel method for large-eddy simulation of turbulent compressible flows is proposed. The method relies on the splitting of the turbulent flowfield into several frequency bands in space and time, each band being associated to a specific computational grid in physical space. This allows to take into account in a deterministic way the information contained on finer grids. A subgrid model adapted to such a decomposition—based on a generalization of the Germano's identity to multilevel decomposition—is also introduced. The approach is validated by several multilevel simulations in a subsonic plane channel flow configuration for a low and a high value of the Reynolds number, while reductions of the CPU times up to 80% are obtained.

Published
2001
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29. Une méthode multiniveau pour la simulation des grandes échelles des écoulements turbulents compressibles

Author

Marc Terracol, Claude Basdevant, and Pierre Sagaut

Subjects
General Physics and Astronomy, General Chemistry
Abstract

Resume Une methode multiniveau pour la Simulation des Grandes Echelles des ecoulements turbulents compressibles instationnaires dans l'espace physique est proposee. Elle est basee sur une decomposition du champ turbulent en plusieurs bandes frequentielles associees a des grilles de calcul emboitees, permettant une prise en compte deterministe des evenements coherents captures sur les grille les plus fines. Un modele statistique sous-maille adapte — base sur une generalisation de la relation de Germano au cadre multiniveau — est egalement introduit. L'approche est finalement validee par un calcul dans une configuration de canal plan subsonique.

Published
2000
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39. Numerical Investigation of the Flow around a Three-Element High-Lift Airfoil Using Two Zonal Hybrid RANS/LES Methods: ZDES and NLDE

Author

Sébastien Deck and Marc Terracol

Subjects
Airfoil, Unsteady flow, Flow (psychology), Reynolds-averaged Navier–Stokes equations, Focus (optics), High lift, Geology, Marine engineering
Abstract

This study deals with the numerical investigation of the flow around a high-lift airfoil with deployed slat and flap, with focus being made on the slat cove region. Two different techniques are used and compared to simulate the unsteady flow around such an airfoil, both being based on a hybrid RANS/LES formulation in order to minimize as much as possible the computational resources. In this paper, a comparison of the results from these two approaches (namely ZDES and NLDE) is presented, both from the statistical and unsteady points of view. The two approaches provide results which are in excellent respective agreement.

Published
2012
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40. Investigation of the unsteady flow and noise sources generation in a slat cove: hybrid zonal RANS/LES simulation and dedicated experiment

Author

Marc Terracol, Eric Manoha, and Benoit Lemoine

Subjects
Airfoil, geography, Engineering, geography.geographical_feature_category, business.industry, Computation, Acoustics, Deflection (engineering), Aeroacoustics, Mean flow, Reynolds-averaged Navier–Stokes equations, business, Cove, Simulation, Wind tunnel
Abstract

This study presents numerical simulations of the unsteady flow and noise generation phenomena in the slat cove of a highlift wing profile by mean of a zonal hybrid RANS/LES approach. These computations are part of a joint numerical/experimental aeroacoustics collaborative program, dedicated to slat flow analysis. For that purpose, a dedicated twoelement wing profile (slat+main body) has been designed in order to isolate the slat noise sources from other possible spurious sources (flap for instance), while minimizing mean flow deflection effects in order to improve the reliability of open-jet wind tunnel measurements. The design of this two-element airfoil has been done numerically using an optimization process based on steady RANS calculations. This airfoil has been investigated experimentally in Ecole Centrale de Lyon open jet facility, therefore providing unsteady wall-pressure measurements in the slat cove area and farfield acoustic measurements. Unsteady zonal hybrid RANS/LES simulations have been performed to provide a comprehensive description of the unsteady flow inside the slat cove, with focus being made on the noise generation processes. A fine physical unsteady analysis of the flow inside the slat cove is presented, as well as a comparison of numerical results with available experimental ones. The pressure spectra associated to the slat cove flow appear to be characterized by several tonal peaks emerging from a global broadband content. The existence of such peaks is discussed and attributed to a feedback loop involving the main shear layer inside the slat cove. A theoretical law is proposed and assessed at the end of the paper to predict the associated tonal frequencies.

Published
2011
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41. An Explicit Filtering Method for Large Eddy Simulation on Unstructured Meshes

Author

Marc Terracol, Fabien Griman, and Pierre Sagaut

Subjects
Mathematical optimization, Operator (computer programming), Spatial filter, Applied mathematics, Context (language use), Polygon mesh, Filter (signal processing), Deconvolution, Grid, Large eddy simulation, Mathematics
Abstract

This paper presents the development of an explicit filtering method for Large Eddy simulation in the framework of unstructured grids. The proposed method relies on the approximate deconvolution model, complemented with a modified Smagorinsky term. This term aims at accountin g for long-range interactions in the wavenumber space between resolved and subgrid scales. Both a classical and a multiscale formulation of this term are considered. An analytical evaluation procedure is described in order to adjust the model coefficient to our explicit filtering framework. The method relies on the introduction o f a discrete filtering operator. For that purpose, a simple volume averaging operator has been chosen in order to perform explicit filtering because of its ease of implementation on unstructured meshes. A discrete characterization procedure of this operator is also proposed in order to estimate locally in space the shape of the filter wh ich is required for the analytical evaluation of the Smagorinsky coefficient. The method is assessed using both h exahedral and tetrahedral grids on a classical homogneneous isotropic turbulence test case. First results obtained for the turbulent flow around a circular cylinder, at a diameter-based Reynolds number of 3,900 are also presented. I. Introduction Large eddy simulation is a tridimensional method that allows a fine unsteady analysis of turbulent flows. This method is based on a separation between large and small scales of the flow, only large scales being resolved while the small one’s influence is represented by a subgrid scale model. This separ ation between large and small scales is generally assumed in practice as being due to a high-pass spatial filtering of th e solution. Unfortunately, on unstructured meshes, many parameters prevent from exactly characterizing the effect ive filtering operator and therefore to develop adapted subg rid models to account for the unresolved scales. Besides, it sho uld be necessary to account for the numerical scheme’s influence, which can act as an additionnal filtering step 1 . Indeed, the use of dissipative numerical scheme to perform large eddy simulations on unstructured meshes is not well suitable because of their interaction with the subgrid scale model. Therefore, the use of more accurate numerical schemes seems fundamentally more suitable. However, the development of high-order schemes on unstructured meshes remains a significant challenge today and such schemes are moreover generally observed to be unstable in realistic configuratio ns, thus requiring an additional artificial stabilization. In this study, we will investigate a possible alternative to perform LES on unstructured grids, which relies on the use of explicit filtering methods. In such methods, a discrete fil tering operator is applied explicitely during the simulati on. In this specific context, the effective filter then becomes dire ctly known and is no longer assumed to be due implicitely to the grid and to the numerical scheme. Indeed, the introduction of this explicit filter allows to control the effective filt er. This technique seems also very interesting by its potential stabilizing effects that could make the use of low dissipative numerical schemes possible. In this paper, different strategies for explicit filtering w ill be discussed and an approximate deconvolution method based on Stolz and Adams 2 original approach will be presented. Subgrid scale modelin g associated to this method will also be considered. Since this approach is based on the intro duction of a specific discrete filter, a method to construct a discrete filtering operator on unstructured meshes will the refore be proposed. The explicit filtering method will first be detailed in sectio n II, where two possible implementations of the Approximate Deconvolution Method (ADM) will be considered. Since ADM only makes it possible to account for local interactions in the wavenumber space, an additional closure based on the Smagorinsky model will be proposed in order to

Published
2010
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42. Numerical investigation of the turbulent flow around a truncated cylinder: noise reduction aspects

Author

Marc Terracol and Victor Kopiev

Subjects
Physics::Fluid Dynamics, Physics, Noise, Turbulence, Noise reduction, Cylinder, Potential flow around a circular cylinder, Truncation (statistics), Mechanics, Aerodynamics, Large eddy simulation
Abstract

This paper presents a numerical investigation by mean of Large Eddy Simulation of the turbulent flow around a regular circular cylinder, and around one which is truncated in its rear part. Such a configuration was inspired by the experimental works of Kopiev et al., who suggested that performing a truncation of the cylinder should lead to a significant reduction of the noise emitted by the turbulent flow past the cylinder. In our simulations, it is observed – as already done in experiments – that a significant reduction (-2dB) of the noise radiation intensity is obtained in the truncated geometry case. A careful analysis of both the acoustic and aerodynamic results is then performed in order to highlight specific flow modifications that may be responsible for this noise reduction.

Published
2008
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44. Direct Numerical Solution of the Crossflow Instabilities Induced by a Periodic Roughness Array on a swept cylinder: receptivity and stability investigations

Author

Grégoire Casalis, Marc Terracol, and Estelle Piot

Subjects
Boundary layer, Optics, Amplitude, business.industry, Direct numerical simulation, Cylinder, Laminar flow, Mechanics, business, Curvature, Boundary layer thickness, Instability, Mathematics
Abstract

A direct numerical simulation of the o w around a swept cylinder in the presence of a micro-roughness array has been performed. The roughness elements are placed periodically in the spanwise direction and their heigth is equal to one tenth of the boundary layer thickness. The aim of the simulation is to compute the amplitude of the crosso w instability waves generated within the laminar boundary layer by the presence of the roughness array. Results show that both a steady and an unsteady instability waves are generated, even if the roughness forcing is purely steady. A linear stability analysis based on the OrrSommerfeld equations is used to characterize these waves. The unsteady one is the traveling crosso w wave which is the most amplied according to this theory. The steady one must be distinguished from the roughness-induced response. This can be done with help of the biorthogonal decomposition method developed by Tumin and extended in this work to a swept boundary layer. This method is also a way to evaluate precisely the receptivity coecien ts. This has been done for both the unsteady and the steady crosso w waves. The results obtained for the steady crosso w wave should be considered with caution, since the non-parallel and curvature eects, not taken into account yet in the decomposition method, may be signican t for this specic zero frequency.

Published
2007
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47. Nonlinear global modes in hot jets

Author

Pierre Sagaut, Marc Terracol, Patrick Huerre, Lutz Lesshafft, Laboratoire d'hydrodynamique (LadHyX), École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS), ONERA - The French Aerospace Lab [Châtillon], ONERA-Université Paris Saclay (COmUE), Laboratoire de modélisation en mécanique (LMM), Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), and Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)

Subjects
Physics, Jet (fluid), [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Mechanics of the fluids [physics.class-ph], Base flow, Mechanical Engineering, Mode (statistics), Base (geometry), Front (oceanography), Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, [SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph], Nonlinear system, Classical mechanics, Mechanics of Materials, 0103 physical sciences, Upstream (networking), [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], 010306 general physics
Abstract

International audience; Since the experiments of Monkewitz et al. (J. Fluid Mech. vol. 213, 1990, p. 611), sufficiently hot circular jets have been known to give rise to self-sustained synchronized oscillations induced by a locally absolutely unstable region. In the present investigation, numerical simulations are carried out in order to determine if such synchronized states correspond to a nonlinear global mode of the underlying base flow, as predicted in the framework of Ginzburg - Landau model equations. Two configurations of slowly developing base flows are considered. In the presence of a pocket of absolute instability embedded within a convectively unstable jet, global oscillations are shown to be generated by a steep nonlinear front located at the upstream station of marginal absolute instability. The global frequency is given, within 10% accuracy, by the absolute frequency at the front location and, as expected on theoretical grounds, the front displays the same slope as a k--wave. For jet flows displaying absolutely unstable inlet conditions, global instability is observed to arise if the streamwise extent of the absolutely unstable region is sufficiently large: While local absolute instability sets in for ambient-to-jet temperature ratios S = 0.453, global modes only appear for S = 0.3125. In agreement with theoretical predictions, the selected frequency near the onset of global instability coincides with the absolute frequency at the inlet. For lower S, it gradually departs from this value. © 2006 Cambridge University Press.

Published
2006
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