LES of shock wave / turbulent boundary layer interaction

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X Nomenclature T u τ = U u,u 1 v,u 2 w,u 3 x,x 1 y,x 2 z,x 3 √ τw ρ w static temperature friction velocity velocity magnitude streamwise velocity component spanwise velocity component wall-normal velocity component streamwise coordinate in physical space spanwise coordinate in physical space wall-normal coordinate in physical space Greek symbols β compression corner deflection angle δ boundary layer thickness δ 1 displacement thickness δ 2 momentum thickness δ ij Kronecker’s delta µ dynamic viscosity ν = µ ρ kinematic viscosity ν T eddy viscosity λ intermittency factor ρ density τ ij viscous stress tensor components (i,j = 1,2,3) ξ,ξ 1 streamwise coordinate in computational space η,ξ 2 spanwise coordinate in computational space ζ,ξ 3 wall-normal coordinate in computational space χ relaxation parameter Other symbols 〈•〉 {•} Reynolds averged quantity Favre averged quantity
Nomenclature XI Subscripts • S • R • 0 • ∞ • VD • w separation reattachment undisturbed boundary layer free-stream van-Driest transformed at the wall Superscripts • c • ′ • ′′ • + contravariant component fluctuation with respect to Reynolds averged quantity fluctuation with respect to Favre averged quantity in wall units • ∗ dimensional quantity 1 Abbreviations ADM DES DNS LES LIA LSSM MILES RANS RDT RMS RRM SGS SRA SWTBLI TKE appoximate deconvolution model detached-eddy simulation direct numerical simulation large-eddy simulation linear interaction analysis large-scale shock motion monotonically integrated large-eddy simulation Reynolds-averged Navier-Stokes rapid distortion theory root-mean square rescaling-recycling method subgrid-scale strong Reynolds analogy shock wave / turbulent boundary layer interaction turbulent kinetic energy 1 All results are presented in non-dimensional form. The reference parameters are given in section 2.2 (page 21), see also table 1.2 (page 14)
Page 1: Technische Universität München Le
Page 5 and 6: Contents Contents List of figures L
Page 7 and 8: List of Figures 1.1 Examples of can
Page 9: List of Tables 1.1 Streamwise dista
Page 15: Abstract XIII Well-resolved Large-E
Page 18 and 19: Introduction be computed explicitly
Page 20 and 21: Introduction from the region of flo
Page 22 and 23: Introduction large-scale motion and
Page 24 and 25: Introduction decompression corner n
Page 26 and 27: Introduction 1 23 4 567 8 9 10 11 1
Page 28 and 29: Introduction Reynolds numbers mainl
Page 30 and 31: Introduction Parameter value M ∞
Page 33 and 34: Chapter 2 Simulation method 2.1 Dom
Page 35 and 36: 19 2.2 Governing equations The comp
Page 37 and 38: 21 with a reference temperature T
Page 39 and 40: 23 (Stolz et al., 2001a). For simpl
Page 41: 25 2.7 2.65 T w 2.6 2.55 -20 -10 0
Page 44 and 45: Flat plate boundary layer The slow
Page 46 and 47: Flat plate boundary layer (a) (b) F
Page 48 and 49: Flat plate boundary layer δ 0 δ 1
Page 50 and 51: Flat plate boundary layer 1.5 1 x 3
Page 52 and 53: Flat plate boundary layer 1.5 1 x 3
Page 54 and 55: Flat plate boundary layer variation
Page 56 and 57: Compression corner flow parameter v
Page 58 and 59: Compression corner flow Figure 4.2:
Page 60 and 61: Figure 4.3: Three-dimensional mean
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Compression corner flow Figure 4.4:
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Compression corner flow computation
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Compression corner flow a longer de
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Compression corner flow 2 1.5 0 1 E
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Compression corner flow 1.8 1.5 1.2
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Compression corner flow (a) (b) (c)
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Compression corner flow (a) (e) (b)
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Compression corner flow forward-sho
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Compression corner flow tion events
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Compression corner flow 1 0.8 λ 0.
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Compression corner flow (a) (e) (b)
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Compression corner flow replacemen
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Compression corner flow 2 1.5 E2 (a
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Compression corner flow ure 4.21(c)
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Compression corner flow 2 2 1.5 1.5
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Compression corner flow 0.1 〈U〉
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Compression-decompression corner se
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Compression-decompression corner C
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Compression-decompression corner Th
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Compression-decompression corner 0
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Compression-decompression corner 14
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Compression-decompression corner 0.
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Chapter 6 Conclusions The numerical
Page 111 and 112:
Appendix B Summary of compression r
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Hunt & Nixon (1995) Adams (1998), A
Page 115:
Stolz et al. (2001a) Kannepalli et
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Computational details Table C.1: De
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Bibliography Bedarev, I. A., Zhelto
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Bibliography Floryan, J. M. 1991 On
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Bibliography Lee, S., Lele, S. K. &
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Bibliography Moin, P. & Kim, J. 198
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Bibliography Smits, A. J. & Wood, D
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Bibliography Yan, H., Knight, D. D.
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