- Page 1: Technische Universität München In
- Page 4 and 5: gas turbine combustion during my in
- Page 6 and 7: Zusammenfassung Die Dynamik von per
- Page 8 and 9: CONTENTS 3.3.3 Influence of Swirler
- Page 10 and 11: CONTENTS A.7.4 Inlet . . . . . . .
- Page 12 and 13: LIST OF FIGURES 3.2 Scheme of deter
- Page 14 and 15: LIST OF FIGURES 5.21 Instantaneous
- Page 16 and 17: LIST OF FIGURES 5.47 FTFs from expe
- Page 18 and 19: List of Tables 2.1 LES Combustion M
- Page 20 and 21: Nomenclature R i j Two-point veloci
- Page 24 and 25: xxiv Nomenclature
- Page 26 and 27: Introduction Figure 1.1: Left: Worl
- Page 28 and 29: Introduction Figure 1.4: Illustrati
- Page 30 and 31: Introduction fluctuations of the he
- Page 32 and 33: Introduction tor walls, increasing
- Page 34 and 35: Turbulent Reacting Flows Figure 2.1
- Page 36 and 37: Turbulent Reacting Flows Figure 2.2
- Page 38 and 39: Turbulent Reacting Flows time scale
- Page 40 and 41: Turbulent Reacting Flows instantane
- Page 42 and 43: Turbulent Reacting Flows as the pro
- Page 44 and 45: Turbulent Reacting Flows where s L
- Page 46 and 47: Turbulent Reacting Flows Figure 2.6
- Page 48 and 49: Turbulent Reacting Flows 2.4.2 Fund
- Page 50 and 51: Turbulent Reacting Flows 2.4.2.1 Mo
- Page 52 and 53: Turbulent Reacting Flows Some of th
- Page 54 and 55: Turbulent Reacting Flows Table 2.1:
- Page 56 and 57: Turbulent Reacting Flows port equat
- Page 58 and 59: 3 Response of Premixed Flames to Ve
- Page 60 and 61: Response of Premixed Flames to Velo
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Response of Premixed Flames to Velo
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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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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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Identification of Flame Transfer Fu
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6 Stability Analysis with Low-Order
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Stability Analysis with Low-Order N
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Stability Analysis with Low-Order N
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Stability Analysis with Low-Order N
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Stability Analysis with Low-Order N
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Stability Analysis with Low-Order N
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Stability Analysis with Low-Order N
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Summary and Conclusions series gene
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Summary and Conclusions • The ide
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Outlook tion. The system identifica
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BIBLIOGRAPHY [8] H. Büchner, C. Hi
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BIBLIOGRAPHY [28] P.J. Colucci, F.A
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BIBLIOGRAPHY [48] D. Fanaca. Influe
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BIBLIOGRAPHY [65] M. Germano, U. Pi
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BIBLIOGRAPHY [83] A. Huber. Impact
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BIBLIOGRAPHY [102] T. Komarek. Priv
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BIBLIOGRAPHY [122] L. Ljung. System
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BIBLIOGRAPHY [141] P. Palies, T. Sc
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BIBLIOGRAPHY [163] S.B. Pope. Compu
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BIBLIOGRAPHY [183] F. Selimefendigi
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BIBLIOGRAPHY [200] L. Tay Wo Chong,
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BIBLIOGRAPHY [223] B.T. Zinn and T.
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Appendices Figure A.1: Evaluation o
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Appendices Table A.1: One Step Reac
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Appendices and isotropic, the energ
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Appendices Figure A.2: DRBS Input s
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Appendices (a) The flow is homentro
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Appendices ends of the duct, the fo
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Appendices Figure A.6: Scheme for f
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Appendices Expressing Eqs. (A.59) a
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Appendices Figure A.7: Scattering M
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Appendices ping [45] is used. The i
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Appendices 4. Load in TECPLOT only