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58 Gábor Janiga 43. Janiga, G., Thévenin, D.: Numerical optimisation of a laminar burner to reduce CO emissions. In: T. Lajos, J. Vad (eds.) Proc. Conf. Modelling Fluid Flow, pp. 109–116. Budapest, Hungary (2006) 44. Janiga, G., Thévenin, D.: Reducing the CO emissions in a laminar burner using different numerical optimization methods. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy 221(5), 647–655 (2007) 45. Kee, R.J., Rupley, F.M., Miller, J.A.: Chemkin-II: A Fortran chemical kinetics package for the analysis of gas-phase chemical kinetics. Tech. Rep. SAND89-8009, Sandia National Laboratories, Livermore, California (1989) 46. Kock, F., Herwig, H.: Entropy production calculation for turbulent shear flows and their implementation in CFD codes. International Journal of Heat and Fluid Flow 26, 672–680 (2005) 47. Laverdant, A., Thévenin, D.: Interaction of a gaussian acoustic wave with a turbulent premixed flame. Combustion and Flame 134, 11–19 (2003) 48. Lee, J., Hajela, P.: Parallel genetic algorithm implementation in multidisciplinary rotor blade design. Journal of Aircraft 33(5), 962–969 (1996) 49. Lee, K.S., Kim, W.S., Si, J.M.: Optimal shape and arrangement of staggered pins in the channel of a plate heat exchanger. International Journal of Heat and Mass Transfer 44(17), 3223–3231 (2001) 50. Lindstedt, P.: Modelling of the chemical complexities of flames. Proceedings of the Combustion Institute 27, 269–285 (1998) 51. Liu, Y., Phan-Thien, N.: An optimum spacing problem for three chips mounted on a vertical substrate in an enclosure. Numerical Heat Transfer, Part A: Applications 37, 613–630 (2000) 52. Maas, U., Pope, S.: Simplifying chemical kinetics: Intrinsic low-dimensional manifolds in composition space. Combustion and Flame 88(3-4), 239–264 (1992) 53. Majda, A., Sethian, J.: The derivation and numerical solution of the equations for zero Mach number combustion. Combustion Science and Technology 42, 185–205 (1985) 54. Mäkinen, R., Neittaanmäki, P., Périaux, J., Toivanen, J.: A genetic algorithm for multiobjective design optimization in aerodynamics and electromagnetics. In: K.D. Papailiou, D. Tsahalis, J. Périaux, D. Knörzer (eds.) Computational Fluid Dynamics ’98, Proceedings of the ECCOMAS 98 Conference, vol. 2, pp. 418–422. Wiley, Athens, Greece (1998) 55. Mäkinen, R.A.E., Périaux, J., Toivanen, J.: Multidisciplinary shape optimization in aerodynamics and electromagnetics using genetic algorithms. International Journal for Numerical Methods in Fluids 30(2), 149–159 (1999) 56. Matos, R., Laursen, T., Vargas, J., Bejan, A.: Three-dimensional optimization of staggered finned circular and elliptic tubes in forced convection. International Journal of Thermal Sciences 43(5), 477–487 (2004) 57. Matos, R.S., Vargas, J.V.C., Laursen, T.A., Bejan, A.: Optimally staggered finned circular and elliptic tubes in forced convection. International Journal of Heat and Mass Transfer 47(6–7), 1347–1359 (2004) 58. Message Passing Interface Forum: MPI: A message-passing interface standard. International Journal of Supercomputer Applications 8(3/4) (1994) 59. Michalewicz, Z.: Genetic Algorithms+Data Structures=Evolution Programs. Springer- Verlag, Berlin, Heidelberg, New York (1996) 60. Moser, R.D., J., K., Mansour, N.N.: DNS of turbulent channel flow up to Reτ=590. Physics of Fluids 11, 943–945 (1999) 61. Muyl, F., Dumas, L., Herbert, V.: Hybrid method for aerodynamic shape optimization in automotive industry. Computers & Fluids 33(5–6), 849–858 (2004) 62. Nejati, V., Matsuuchi, K.: Aerodynamics design and genetic algorithms for optimization of airship bodies. JSME International Journal Series B-Fluids and Thermal Engineering 46(4), 610–617 (2003) 63. Nelder, J.A., Mead, R.: A simplex method for function minimization. Computer Journal 7, 308–313 (1965)
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Optimization and Computational Flui
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Editors: Prof. Dr.-Ing. Dominique T
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vi Preface Our first research proje
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viii Contents 2.4.1 GoverningEquati
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x Contents 6.2.3 Parameterization..
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xii Contents 9.4.1 Multi-objectiveO
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xiv List of Contributors Gábor JAN
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Part I Generalities and methods
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4 Dominique Thévenin 12 10 8 6 4 2
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6 Dominique Thévenin Objective 10
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Page 24 and 25: 10 Dominique Thévenin Parameter 2
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Page 28 and 29: 14 Dominique Thévenin Let us come
Page 30 and 31: 16 Dominique Thévenin References 1
Page 32 and 33: 18 Gábor Janiga 2.1 Introduction D
Page 34 and 35: 20 Gábor Janiga y Tinlet = 293 K 0
Page 36 and 37: 22 Gábor Janiga y [mm] 25 20 15 10
Page 38 and 39: 24 Gábor Janiga Table 2.1 Number o
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Page 44 and 45: 30 Gábor Janiga INPUT FILE Gambit
Page 48 and 49: 34 Gábor Janiga ∆T ∆P Position
Page 50 and 51: 36 Gábor Janiga ∆P [mPa] 2.2 2.0
Page 52 and 53: 38 Gábor Janiga Table 2.3 Speed-up
Page 54 and 55: 40 Gábor Janiga For all computatio
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Page 58 and 59: 44 Gábor Janiga Air mass flow-rate
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Page 66 and 67: 52 Gábor Janiga Error for Re∗ =
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Page 70 and 71: 56 Gábor Janiga References 1. Ali,
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Part II Specific Applications of CF
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112 Nicolas R. Gauger Nomenclature
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114 Nicolas R. Gauger Fig. 5.1 Cost
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116 Nicolas R. Gauger and the four
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118 Nicolas R. Gauger CL := 1 � C
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120 Nicolas R. Gauger the cost func
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122 Nicolas R. Gauger Table 5.1 An
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124 Nicolas R. Gauger The main adva
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126 Nicolas R. Gauger Spalart-Allma
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128 Nicolas R. Gauger (a) (b) Fig.
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134 Nicolas R. Gauger Fig. 5.10 Plo
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136 Nicolas R. Gauger drag, lift, s
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138 Nicolas R. Gauger solution of t
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140 Nicolas R. Gauger the presence
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142 Nicolas R. Gauger Fig. 5.16 Con
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144 Nicolas R. Gauger optimization
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Chapter 6 Numerical Optimization fo
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6 Numerical Optimization for Advanc
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192 Laurent Dumas 7.1 Introducing A
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194 Laurent Dumas C Fig. 7.2 Wake f
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196 Laurent Dumas Table 7.1 Example
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198 Laurent Dumas Fig. 7.5 Numerica
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200 Laurent Dumas 7.3.1.1 Genetic A
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202 Laurent Dumas START Random init
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204 Laurent Dumas • if ˜ J(x ng
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206 Laurent Dumas Table 7.3 Compari
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208 Laurent Dumas Fig. 7.9 General
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210 Laurent Dumas Table 7.4 Four ex
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212 Laurent Dumas Fig. 7.13 Blades
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214 Laurent Dumas Table 7.5 Converg
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Chapter 8 Multi-objective Optimizat
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8 Multi-objective Optimization in C
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8 Multi-objective Optimizatio Fig.
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Chapter 9 CFD-based Optimization fo
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9 CFD-based optimization for paperm
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292 Index heat exchanger, 222, 224,
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