Numerical Simulation of the Dynamics of Turbulent Swirling Flames

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BIBLIOGRAPHY [83] A. Huber. Impact of Fuel Supply Impedance and Fuel Staging on Gas Turbine Combustion Stability. PhD Thesis, Technische Universität München, 2009. [84] A. Huber and W. Polifke. Dynamics of Practical Premixed Flames, Part I: Model Structure and Identification. International Journal of Spray and Combustion Dynamics, 1(2):199–228, 2009. [85] A. Huber and W. Polifke. Dynamics of Practical Premixed Flames, Part II: Identification and Interpretation of CFD Data. International Journal of Spray and Combustion Dynamics, 1(2):229–250, 2009. [86] A. Huber, P. Romann, and W. Polifke. Filter-based Time-Domain Impedance Boundary Conditions for CFD Applications. Number GT2008-51195 in Proceedings of ASME Turbo Expo, Berlin, Berlin, Germany, June 9-13 2008. ASME. [87] B. Jones, J.G. Lee, Quay B.D., and D.A. Santavicca. Flame Response Mechanisms Due to Velocity Perturbations in a Lean Premixed Gas Turbine Combustor. Journal of Engineering for Gas Turbines and Power, 133(2):021503, 2011. [88] W.P. Jones and B.E. Launder. The Prediction of Laminarization with a Two-Equation Model of Turbulence. International Journal of Heat and Mass Transfer, 15(2):301 – 314, 1972. [89] R. Kaess, A. Huber, and W. Polifke. Time-domain Impedance Boundary Condition for Compressible Turbulent Flows. Number AIAA 2008-2921 in 14th AIAA/CEAS Aeroacoustics Conference, Vancouver. AIAA, 2008. [90] R. Kaess, T. Poinsot, and W. Polifke. Determination of the Stability Map of a Premix Burner based on Flame Transfer Functions computed with Transient CFD. Number 810304 in Proc. of European Combustion Meeting, Vienna. Combustion Institute, 2009. [91] R. Kaess, W. Polifke, T. Poinsot, N. Noiray, D. Durox, T. Schuller, and S. Candel. CFD-based Mapping of the Thermo-acoustic Stability of a Laminar Premix Burner. Proc. of the Summer Program CTR, Stanford, 2008. 150
BIBLIOGRAPHY [92] S. Kaplan. Power Plants: Characteristics and Costs. Technical Report Order Code RL34746, Congressional Research Service, USA, November 2008. http://www.fas.org/sgp/crs/misc/RL34746.pdf. [93] A. Kaufmann, F. Nicoud, and T. Poinsot. Flow Forcing Techniques for Numerical Simulation of Combustion Instabilities. Combustion and Flame, 131(4):371–385, 2002. [94] A. Kaw. Introduction to Matrix Algebra. Autarkaw, 1st edition, 2008. [95] J. Keller. Thermoacoustic Oscillations in Combustion Chambers of Gas Turbines. AIAA Journal, 33(12):2280–2287, 1995. [96] K.T. Kim, H.J. Lee, J.G. Lee, B.D. Quay, and D. Santavicca. Flame Transfer Function Measurement and Instability Frequency Prediction Using a Thermoacoustic Model. Number GT2009-60026 in Proc. of ASME Turbo Expo 2009, Orlando. ASME, 2009. [97] K.T. Kim, J.G. Lee, H.J. Lee, B.D. Quay, and D. Santavicca. Characterization of Forced Flame Response of Swirl-stabilized Turbulent Premixed Flames. Number GT2009-60031 in Proc. of ASME Turbo Expo 2009, Orlando. ASME, 2009. [98] K.T. Kim, J.G. Lee, B.D. Quay, and Santavicca D.A. Spatially Distributed Flame Transfer Functions for Predicting Combustion Dynamics in Lean Premixed Gas Turbine Combustors. Combust. Flame, 157(9):1718–1730, 2010. [99] W.W. Kim and S. Menon. Numerical Modeling of Turbulent Premixed Flames in the Thin-Reaction-Zones Regime. Combustion Science and Technology, 160(1):119–150, 2000. [100] O. Kitoh. Experimental Study of Turbulent Swirling Flow in a Straight Pipe. Journal of Fluid Mechanics, 225:445–479, 1991. [101] A.N. Kolgomorov. The Local Structure of Turbulence in Incompressible Viscous Fluid for Very Large Reynolds Numbers. Dokl. Akad.Nauk SSSR, 30:299–303, 1941. 151
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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 124 and 125: Identification of Flame Transfer Fu
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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 176 and 177: BIBLIOGRAPHY [102] T. Komarek. Priv
Page 178 and 179: BIBLIOGRAPHY [122] L. Ljung. System
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
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Numerical Simulation of the Dynamics of Turbulent Swirling Flames

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