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the contrary, the global behavior of the flow seems to be correctly reproduced using model UM2. Moreover, reasonable agreement with experimental data is obtained on streamwise velocity profile in the perforated zone. However, the velocity is slightly under-estimated near the wall, which is consistent with the comparison of the model with the reference small-scale wall-resolved LES data. Despite this under-estimation, the model UM2 is considered to be correct enough to be used in full combustion chamber flow computations. The model can be used in the presented form in non-isothermal computations: in this case, the wall is implicitly assumed to be adiabatic. Detailed information of the flow around multi-perforated plated is crucial not only to determine which physical characteristics have to be modeled but also to evaluate the exactness of the modeling assumptions. The comparison with the reference small-scale wall-resolved LES data indicates that improvements to the UM2 model can be obtained by refining the modeling of the time- and spatial-averaged streamwise velocity at the hole inlet/outlet and by being able to evaluate the shape of the time-averaged velocity field at the hole inlet/outlet. Acknowledgments The authors are grateful to the European Community for funding this work under the project INTELLECT-DM (Contract No. FP6 - AST3 - CT - 2003 - 502961), and to the CINES (Centre Informatique National pour l’Enseignement Supérieur) and the BSC (Barcelona Supercomputing Center) for the access to supercomputer facilities. The authors would also like to thank Turbomeca and Petre Miron for the access to the LARA experimental database. References 1 Lefebvre, A. H., Gas Turbines Combustion, Taylor & Francis, 1999. 2 Simpson, R. L., “Characteristics of turbulent boundary layers at low Reynolds numbers with and without transpiration,” J. Fluid Mech., Vol. 42, No. 4, 1970, pp. 769–802. 3 Piomelli, U., Ferziger, J. H., Moin, P., and Kim, J., “New approximate boundary conditions for large eddy simulations of wall-bounded flows,” Phys. Fluids A, Vol. 1, No. 6, 1989, pp. 1061–68. 4 MacManus, D. G. and Eaton, J. A., “Flow physics of discrete boundary layer suction - measurements and predictions,” J. Fluid Mech., Vol. 417, 2000, pp. 47–75. 5 Peterson, S. D. and Plesniak, M. W., “Evolution of jets emanating from short holes into crossflow,” J. Fluid Mech., Vol. 503, 2004, pp. 57–91. 6 Peet, Y. V., Film cooling from inclined cylindrical holes using Large-Eddy Simulations, Ph.D. thesis, Stanford University, 2006. 7 Margason, R. J., “Fifty years of jet in crossflow research,” Computational and Experimental Assessment of Jets in Crossflow, edited by U. Winchester, Vol. AGARD-CP-534, 1993, pp. 1–41. 23 of 26
8 Fric, T. and Roshko, A., “Vortical structure in the wake of a transverse jet,” J. Fluid Mech., Vol. 279, 1994, pp. 1–47. 9 Smith, S. H. and Mungal, M. G., “Mixing, structure and scaling of the jet in crossflow,” J. Fluid Mech., Vol. 357, 1998, pp. 83–122. 10 Cortelezzi, L. and Karagozian, A. R., “On the formation of the counter-rotating vortex pair in transverse jets,” J. Fluid Mech., Vol. 446, 2001, pp. 347–373. 11 Muppidi, S. and Mahesh, K., “Direct Numerical Simulation of round turbulent jets in crossflow,” J. Fluid Mech., Vol. 574, 2007, pp. 59–84. 12 Bergeles, G., Gosman, A. D., and Launder, B. E., “The Near-Field Character of a Jet Discharged Normal to a Main Stream,” J. of Heat Transfer, 1976, pp. 373–378. 13 Bergeles, G., Gosman, A. D., and Launder, B. E., “Near-Field Character of a Jet Discharged through a Wall at 30 deg to a Mainstream,” AIAA J., Vol. 15, No. 4, 1977, pp. 499–504. 14 Iourokina, I. V. and Lele, S. K., “Large Eddy Simulation of Film-Cooling Above the Flat Surface with a Large Plenum and Short Exit Holes,” 44th Aerospace Sciences Meeting and Exhibit, 2006. 15 Walters, D. and Leylek, J., “A Detailed Analysis of Film-Cooling Physics: Part 1- Streamwise Injection With Cylindrical Holes,” ASME J. Turbomach., Vol. 122, 2000, pp. 102–112. 16 Yavuzkurt, S., Moffat, R. J., and Kays, W. M., “Full coverage film cooling. Part 1. Three-dimensional measurements of turbulence structure,” J. Fluid Mech., Vol. 101, 1980, pp. 129–158. 17 Gustafsson, K. M. B., Experimental Studies of Effusion Cooling, Ph.D. thesis, Chalmers University of Technology. Göteborg, 2001. 18 Miron, P., Étude expérimentale des lois de parois et du film de refroidissement produit par une zone multiperforée sur une paroi plane., Ph.D. thesis, Université de Pau et des Pays de l’Adour, 2005. 19 Metzger, D. E., Takeuchi, D. I., and Kuenstler, P. A., “Effectiveness and heat transfer with fullcoverage film-cooling,” ASME paper, 1973. 20 Crawford, M. E., Kays, W. M., and Moffat, R. J., “Full-coverage film cooling. Part I : Comparison of Heat Transfer Data for Three Injection Angles,” J. of Engineering for Power, Vol. 102, 1980, pp. 1000–1005. 21 Bazdidi-Tehrani, F. and Andrews, G. E., “Full-coverage discrete hole film cooling : investigation of the effect of variable density ratio,” J. of Engineering for Gas Turbines and Power, Vol. 116, 1994, pp. 587–596. 22 Rouvreau, S., Étude expérimentale de la structure moyenne et instantanée d’un film produit par une zone multiperforée sur une paroi plane. Application au refroidissement des chambres de combustion des moteurs aéronautiques, Ph.D. thesis, E.N.S.M.A. et Faculté des Sciences Fondamentales et Appliquées, 2001. 23 Hay, N. and Lampard, D., “Discharge Coefficient of Turbines Cooling Holes,” ASME J. Turbomach., Vol. 120, 1998, pp. 314–319. 24 Gritsch, M., Schultz, A., and Wittig, S., “Effect of Crossflows on the Discharge Coefficient of Film Cooling Holes With Varying Angles of Inclination and Orientation,” ASME J. Turbomach., Vol. 123, 2001, pp. 781–787. 25 Papanicolaou, E., Giebert, D., Koch, R., and Schultz, A., “A conservation-based discretization approach for conjugate heat transfer calculations in hot-gas ducting turbomachinery components,” International Journal of Heat and Mass Transfer, Vol. 44, 2001, pp. 3413–3429. 26 Harrington, M. K., McWaters, M. A., Bogard, D. G., A., L. C., and Thole, K. A., “Full-coverage film cooling with short normal injection holes,” ASME TURBOEXPO 2001. 2001-GT-0130, 2001. 24 of 26
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UNIVERSITE MONTPELLIER II SCIENCES
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Table des matières Remerciements 7
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Remerciements Cette thèse a été
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Liste des symboles Lettres romaines
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Introduction générale La volonté
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Chapitre 1 Contexte industriel et s
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1.1 Les turbines à gaz pour les tu
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1.1 Les turbines à gaz a) b) GAZ C
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1.2 La simulation numérique des é
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1.3 Objectifs et plan de la thèse
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Chapitre 2 L’écoulement autour d
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2.1 Présentation de la configurati
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2.2 Perte de charge au passage d’
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2.3 La multi-perforation : aspects
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2.4 Caractérisation aérodynamique
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2.5 Modélisation de la multi-perfo
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Chapitre 3 Simulations des grandes
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3.2 Simulations des Grandes Echelle
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3.3 Le code de calcul AVBP 3.3.1 As
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3.3 Le code de calcul AVBP dans le
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3.3 Le code de calcul AVBP de sa st
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Chapitre 4 Simulations numériques
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4.1 Quelles simulations pour la mod
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4.2 Choix de la méthode de simulat
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4.2 Choix de la méthode de simulat
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4.3 Sensibilité des simulations au
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Chapitre 5 Simulations numériques
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2 S. Mendez and F. Nicoud COMBUSTIO
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4 S. Mendez and F. Nicoud (c) The i
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6 S. Mendez and F. Nicoud CALCULATI
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8 S. Mendez and F. Nicoud Name Numb
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10 S. Mendez and F. Nicoud x/d z/d
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Page 119 and 120: 22 S. Mendez and F. Nicoud & Mahesh
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Page 127 and 128: 30 S. Mendez and F. Nicoud Region t
Page 129 and 130: 32 S. Mendez and F. Nicoud Expressi
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Page 137 and 138: Chapitre 6 Un modèle adiabatique p
Page 139 and 140: ρ Mass density, kg/m 3 P T V i τ
Page 141 and 142: cence of the jets. This is particul
Page 143 and 144: Simulations. The small-scale LES re
Page 145 and 146: chosen to compare with numerical re
Page 147 and 148: pressure drop of 41 Pa is effective
Page 149 and 150: Region total plate hole solid wall
Page 151 and 152: This equality is almost verified at
Page 153 and 154: V U σ V inj jet cotan(α′ ) V U
Page 155 and 156: PERIODIC Z INFLOW 1 WALL 24 OUTFLOW
Page 157 and 158: part of the plate. Downstream of th
Page 159: streamwise momentum flux. As a cons
Page 163 and 164: Discussion sur la modélisation de
Page 165 and 166: 20 15 10 y/d 5 0 -5 -10 0.0 0.2 0.4
Page 167 and 168: Chapitre 7 Simulations numériques
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Page 171 and 172: Figure 7: Nusselt number over the s
Page 173 and 174: the perforated plate. A Large-Eddy
Page 175 and 176: Les tableaux de flux permettent de
Page 177 and 178: Conclusion générale Dans cette é
Page 179 and 180: Conclusion générale En ce qui con
Page 181 and 182: Bibliographie AKSELVOLL, K. & MOIN,
Page 183 and 184: BIBLIOGRAPHIE CORON, X. 2001 Étude
Page 185 and 186: BIBLIOGRAPHIE HALE, C. A., PLESNIAK
Page 187 and 188: BIBLIOGRAPHIE LIEUWEN, T. & YANG, V
Page 189 and 190: BIBLIOGRAPHIE MOST, A. & BRUEL, P.
Page 191 and 192: BIBLIOGRAPHIE SCHILDKNECHT, M., MIL
Page 193: Annexes
Page 196 and 197: ARTIFICIAL VISCOSITY MODELS A.2.1 T
Page 198 and 199: ARTIFICIAL VISCOSITY MODELS - 4 th
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Page 202: ARTIFICIAL VISCOSITY MODELS 202
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