Numerical Simulation of the Dynamics of Turbulent Swirling Flames

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BIBLIOGRAPHY [122] L. Ljung. System Identification: Theory for the User. Prentice Hall PTR, 2nd edition, 1999. [123] L. Ljung. Perspectives on System Identification. Annual Reviews in Control, 34(1):1–12, 2010. [124] M. Lohrmann and H. Büchner. Scaling of Stability Limits in Lean- Premixed Gas Turbine Combustors. Number GT2004-53710 in Proc. of ASME Turbo Expo 2004 Power for Land, Sea and Air, page 11, Vienna, Austria, June 14-17 2004. ASME. [125] O. Lucca-Negro and T. O’Doherty. Vortex Breakdown: A Review. Progress in Energy and Combustion Science, 27:431–481, 2001. [126] Ch. Martin, L. Benoit, Y. Sommerer, F. Nicoud, and T. Poinsot. LES and Acoustic Analysis of Combustion Instability in a Staged Turbulent Swirled Combustor. AIAA Journal, 44(4):741–750, 2006. [127] E. Mastorakos, A.M.K.P. Taylor, and J.H. Whitelaw. Extinction of Turbulent Counterflow Flames with Reactants Diluted by Hot Products. Combust. Flame, 102:101–114, 1995. [128] F.R. Menter, M. Kuntz, and R. Langtry. Ten Years of Industrial Experience with the SST Turbulence Model. In K. Hanjalic, Y. Nagano, and M. Tummers, editors, Turbulence, Heat and Mass Transfer 4, pages 625– 632. Begell House, Inc., 2003. [129] H.J. Merk. An Analysis of Unstable Combustion of Premixed Gases. Symposium (International) on Combustion, 6(1):500–512, 1957. [130] P. Moin and J. Kim. Tackling Turbulence with Supercomputers. Scientific American, 276(1):62–68, 1997. [131] Y. S. M. Morsi, P. G. Holland, and B. R. Clayton. Prediction of Turbulent Swirling Flows in Axisymmetric Annuli. Applied Mathematical Modelling, 19(10):613–620, 1995. 154
BIBLIOGRAPHY [132] V. Moureau, G. Lartigue, Y. Sommerer, C. Angelberger, O. Colin, and Poinsot T. Numerical Methods for Unsteady Compressible Multicomponent Reacting Flows on Fixed and Moving Grids. J. Comput. Phys., 202:710–736, 2005. [133] F. Nicoud and F. Ducros. Subgrid-scale Stress Modeling Based on the Square of the Velocity Gradient Tensor. Flow Turb. Combust., 62:183– 200, 1999. [134] N. Noiray, D. Durox, T. Schuller, and S. Candel. A Unified Framework for Nonlinear Combustion Instability Analysis based on the Flame Describing Function. Journal of Fluid Mechanics, 615:139–167, 2008. [135] C. C. Paige and M. A. Saunders. LSQR: An Algorithm for Sparse Linear Equations and Sparse Least Squares. ACM Trans. Math. Softw., 8(1):43– 71, 1982. [136] P. Palies. Dynamique et Instabilités de Combustion des Flammes Swirlées. PhD thesis, Ecole Centrale Paris, 2010. [137] P. Palies, D. Durox, T. Schuller, and S. Candel. The Combined Dynamics of Swirler and Turbulent Premixed Swirling Flames. Combust. Flame, 157:1698–1717, 2010. [138] P. Palies, D. Durox, T. Schuller, and S. Candel. Swirling Flame Instability Analysis Based on the Flame Describing Function Methodology. Number GT2010-22294 in Proc. of ASME Turbo Expo 2010, Glasgow, UK, page 10, Glasgow, UK, June 14-18 2010. ASME. [139] P. Palies, D. Durox, T. Schuller, and S. Candel. Acoustic-convective Mode Conversion in an Aerofoil Cascade. Journal of Fluid Mechanics, 672:545– 569, 2011. [140] P. Palies, D. Durox, T. Schuller, and S. Candel. Experimental Study on the Effect of Swirler Geometry and Swirl Number on Flame Describing Functions. Combustion Science and Technology, 183(7):704–717, 2011. 155
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Technische Universität München In
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gas turbine combustion during my in
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Zusammenfassung Die Dynamik von per
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CONTENTS 3.3.3 Influence of Swirler
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CONTENTS A.7.4 Inlet . . . . . . .
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LIST OF FIGURES 3.2 Scheme of deter
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LIST OF FIGURES 5.21 Instantaneous
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LIST OF FIGURES 5.47 FTFs from expe
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List of Tables 2.1 LES Combustion M
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Nomenclature R i j Two-point veloci
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Nomenclature M MF O prop r stoich S
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xxiv Nomenclature
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Introduction Figure 1.1: Left: Worl
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Introduction Figure 1.4: Illustrati
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Introduction fluctuations of the he
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Introduction tor walls, increasing
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Turbulent Reacting Flows Figure 2.1
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Turbulent Reacting Flows time scale
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Turbulent Reacting Flows instantane
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Turbulent Reacting Flows as the pro
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Turbulent Reacting Flows where s L
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Turbulent Reacting Flows 2.4.2 Fund
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Turbulent Reacting Flows 2.4.2.1 Mo
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Turbulent Reacting Flows Some of th
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Turbulent Reacting Flows Table 2.1:
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Turbulent Reacting Flows port equat
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3 Response of Premixed Flames to Ve
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Response of Premixed Flames to Velo
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System Identification put, the heat
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System Identification Figure 4.2: U
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System Identification 4.2 The Wiene
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System Identification Figure 4.3: S
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System Identification 4.3 The LES/S
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System Identification A flow chart
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Identification of Flame Transfer Fu
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Page 128 and 129: Identification of Flame Transfer Fu
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Page 148 and 149: Stability Analysis with Low-Order N
Page 160 and 161: Summary and Conclusions series gene
Page 162 and 163: Summary and Conclusions • The ide
Page 164 and 165: Outlook tion. The system identifica
Page 166 and 167: BIBLIOGRAPHY [8] H. Büchner, C. Hi
Page 168 and 169: BIBLIOGRAPHY [28] P.J. Colucci, F.A
Page 170 and 171: BIBLIOGRAPHY [48] D. Fanaca. Influe
Page 172 and 173: BIBLIOGRAPHY [65] M. Germano, U. Pi
Page 174 and 175: BIBLIOGRAPHY [83] A. Huber. Impact
Page 176 and 177: BIBLIOGRAPHY [102] T. Komarek. Priv
Page 180 and 181: BIBLIOGRAPHY [141] P. Palies, T. Sc
Page 182 and 183: BIBLIOGRAPHY [163] S.B. Pope. Compu
Page 184 and 185: BIBLIOGRAPHY [183] F. Selimefendigi
Page 186 and 187: BIBLIOGRAPHY [200] L. Tay Wo Chong,
Page 188 and 189: BIBLIOGRAPHY [223] B.T. Zinn and T.
Page 190 and 191: Appendices Figure A.1: Evaluation o
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Page 200 and 201: Appendices ends of the duct, the fo
Page 202 and 203: Appendices Figure A.6: Scheme for f
Page 204 and 205: Appendices Expressing Eqs. (A.59) a
Page 206 and 207: Appendices Figure A.7: Scattering M
Page 208 and 209: Appendices ping [45] is used. The i
Page 210 and 211: Appendices 4. Load in TECPLOT only
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Numerical Simulation of the Dynamics of Turbulent Swirling Flames

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