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Interaction fluide structure dans un faisceau de tubes : physique et modlisation M. Braza, G. Harran, G. Barbut, Y. Hoarau Journe Thmatique GDR Interaction Fluide-Structure, 4/12/07 EDF- Chatou

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2 Phnomnes physiques capter par lapproche de macrosimulation : Instabilits de basse frquence bien distinctes par rapport la turbulence alatoire Flottement hydrolastique Prdiction des chargements proche-paroi: couplage d lchange nergtique : fluide-structure

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3 Longitudinal vortices along the span in connexion with the von Karman ones THE IMFTs CIRCULAR CYLINDER - DESIDER EU program TEST-CASE In S1 Wind tunnel IMFT : SIMULTANEOUS 3C-PIV and Time-resolved PIV Re=140,000 IUTAM Symposium Unsteady Separated Fmows and their Control, June 2007 and J. Fluids& Structures, in print

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5 Vertical velocity spectrum in a cylinder wake, Re=140 000 Experimental data from PIV (M. Braza,R. Perrin, Y. Hoarau, Journal of Fluids and Structure 2006) and LDV (Djeridi et al, JFTAC 2003) Spectrum from originals signals Spectrum from phase-averaged signals The macrosimulation approach to capture the organised coherent motion and the random turbulence

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OES : Schematic separation of coherent/random turbulence parts in the spectral domain In the physical domain: phase average decomposition: Part (1): to be resolved Part (2): to be modelled by reconsidered statistical turbulence modelling, efficient in high-Re unsteady wall flows (Dervieux, Braza, Dussauge, Notes on Num. Fluid Mech., 1998, Vol. 65, Braza, Perrin, Hoarau, J. Fluids & Struct., 2006, Vol. 22 OES : Organised Eddy Simulation Macrosimulation

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The phase-averaged turbulence stresses: Evaluated by tensorial eddy-viscosity concept Derived from second-order modelling Bourguet, Braza, Perrin, Harran, AIAA J., 45, 2007. / t + / x j + / x j Temporal non-linear convection new turbulent stresses =- /dx i + / x j

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8 Anisotropic OES modelling Considerations from the IMFT circular cylinder exp. study DESIDER EU program, Perrin et al, Exp. in Fluids, 42, 2006 Re=140,000 Bourguet et al, AIAA J, 45, 2007

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10 Anisotropic OES Modelling: Tensorial eddy-viscosity concept * Directional C i coefficient, a jk : Turbulence stress anisotropy, S ij = Strain-rate tensor, advectable directional criterion derived from DRSM Sarkar, Gatski, Speziale transport eqns, JFM 227 * Bourguet, Braza, Perrin, Harran, AIAAJ. 45, 2007 C i = C vi /k

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12 Good agreement of experimental and modeled anisotropy tensor Implementation into NSMB solver PhD R. Bourguet Anisotropic OES modelling

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13 Comparison of the experimental and predicted phase-averaged turbulence shear-stress Bourguet, Braza, Perrin, Harran, AIAAJ, Vol.45,N5, 2007

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14 Yields simplified isotropic OES in agreement with our previous studies derived by DRSM (Hoarau, Braza, IUTAM-02 Symposium Procs, Unsteady Separated Flows) Anisotropic OES modelling

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15 Flow around a NACA 0021 airfoil at 60 angle of attack OES approach and two-equation modelling (isotropic version) *Use of the modified damping function (Jin & Braza, AIAA J. 1994) derived from DNS *use of the eddy-diffusion coefficient adapted by OES/DRSM C =0.02

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16 Fig. 4c. Up: Iso-U velocity averaged field compared with the PIV data, down, phase-averaged experimental field at phase- angle 225 compared with the DES-k-omega (IMFT). PIV -3C Moyenne de phase OES/k- OES

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17 3D structure of shear-layer instability OES approach: allows simulation of 3D shear-layer instability at high-Re Q_criterion Re=140,000

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18 Interaction fluide-structure Faisceau de tubes

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19 Petit Nombre de Scruton Instabilit domine par lamortissement Implique un seule degr de libert (SDOF). Grand nombre de Scruton Instabilit domin par la raideur Implique deux degrs de libert. Variation de la vitesse critique en fonction du paramtre masse- amortissement (S. J. Price, M.P. Paidoussis, J. Fluids & Struct., Vol. 22, 2006)

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20 Modlisation linaire des forces fluide- lastiques x y U k c kc Equation dynamique du cylindre SDOF Modle de force fluide-lastique Connors (1970) quasi-statique Price,Padoussis (1986) processus amnsique Granger Padoussis (1996) processus mmoire Re = 20000

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21 Application linteraction fluide-structure dans un faisceau de tubes Code NSMB Navier-Stokes Multiblock Consortium: EPFL, CFS Engn, KTH, ETHZ, Tech. Univ. Mnich, IMFT, IMFSS, RUAG Aero Prsente application Approche ALE Schmas centrs Prcision au second-ordre temporel et spatial Modlisation OES modles deux quations, de type k- 41616 cellules

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22 Faisceau de tubes configuration statique Re=20 000

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24 Configuration statique

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25 Variation des coefficients de trane et de portance en fonction du temps (Ur=1.18) Analyse spectrale du coefficient de la portance frquence doscillation du cylindre frquence du dtachement tourbillonnaire Avec oscillation verticale du cylindre du milieu la frquence naturelle et amplitude 0.1D

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26 Cylindre du milieu en vibration libre

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27 III. Configuration tudie Dtail du maillage Domaine du calcul P/D=1.75 144 blocs - 73728 cellules

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28 Variation des coefficients de trane et de portance en fonction du temps Analyse spectrale du coefficient de la portance entre les instants t=83.06 s et t=301.6 s. f 0.21 Hz

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29 Conclusion Interaction fluide-structure faisceau de tubes Approche OES : Evaluation des charges paritales - change nergtique fluide-structure Dissociation parties organise et interaction avec turbulence alatoire Approche 2D ( mthode non-intrinsque 3D ) Capacit de prdicition plus haut Re

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30 Perspectives Dveloppements actuels: Prdiction faisceau de tubes avec A_OES Prdiction en 3D Analyse de linstabilit de flottement cylindres en tandem Exprience physique avec TR-PIV/3C-PIV