The significance of coherent flow structures for the turbulent mixing ...

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Bibliography [13] CARLIER J, KÄHLER CJ, STANISLAS M (2001) Experimental study of eddy structures in a turbulent boundary layer using PIV, 4th Intl. Symp. on Particle Image Velocimety, Göttingen, Germany, Sept. 17–19 [14] DI CICCA GM, IUSO G, SPAZZINI PG, ONORATO M (2002) PIV study of the influence of large-scale stream-wise vortices on a turbulent boundary layer, Exp. Fluids 33, pp. 663–669 [15] CORINO ER, BRODKEY RS (1969) A visual investigation of the wall region in turbulent flow, J. Fluid Mech. 37, pp. 1–36 [16] DREEBEN TD, POPE SB (1997) Probability density function and Reynolds-stress modeling of near wall turbulent flows Phys. Fluids 9, pp. 154–163 [17] ECHOLS WH, YOUNG YA (1963) Studies of portable air-operated aerosol generators, NRL Report 5929, Naval Research Laboratory, Washington D.C. [18] Ehrenfried K. (2002) Processing calibration-grid images using Hough transformation, Meas. Sci. Tech. 13, pp. 975–983 [19] FAVRE AJ, GAVIGLIO JJ, DUMAS RJ (1957) Space-time double correlations and spectra in a turbulent boundary layer, J. Fluid Mech. 2, pp. 313–342 [20] FAVRE AJ, GAVIGLIO JJ, DUMAS RJ (1958) Further space-time correlations of velocity in a turbulent boundary layer, J. Fluid Mech. 3, pp. 344–356 [21] FERNHOLZ HH, FINLEY PJ (1996) The incompressible zero-pressure-gradient turbulent boundary layer: An assessment of the data, Prog. Aerospace Sci. 32, pp. 245–311 [22] FINCHAM A, DELERCE G (1999) Advanced optimization of correlation imaging velocimetry algorithms, 3rd International Workshop on PIV, University of California, Santa Barbara, USA, Sept. 16-18 [23] GEBELEIN H (1935) Turbulenz, Springer-Verlag, Berlin [24] GRANT HL (1971) The large eddies of turbulent motion, J. Fluid Mech. 4, pp. 149–190 [25] GUPTA AK, LAUFER J, KAPLAN RE (1971) Spatial structure in the viscous sublayer, J. Fluid Mech. 50, pp. 493–512 [26] HAMA FR (1962) Streaklines in a perturbed shear flow, Phys. Fluids 5, pp. 644–650 [27] HART DP (2000) PIV error correction, in Laser Techniques Applied to Fluid Mechanics, ed. RJ Adrian et al , Springer-Verlag, Berlin Heidelberg, pp. 19–36 [28] HEAD MR, BANDYOPADHYAY P (1981) New aspects of turbulent boundary-layer structure, J. Fluid Mech. 107, pp. 297–338 [29] HINSCH K (1993) Particle image velocimetry (PIV), in Speckle Metrology, ed. RS Sirohi, Marcel Dekker, New York, pp. 235–324 170
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The significance of coherent flow s
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Contents 1 Introduction 5 2 Particl
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1 Introduction One of the fascinati
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As order can be always observed whe
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were not considered in detail in th
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varying signal can be transformed i
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2 Particle Image Velocimetry The tr
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2.1 Principles It is of fundamental
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’ ’“ ” ”• Ž Ž Ž Ž
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¹ and 2.2 Generation of appropriat
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2.2 Generation of appropriate trace
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2.3 Registration of the particle im
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2.3 Registration of the particle im
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ë ë 2.3 Registration of the parti
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ýÿþ¡ û û ¢ ¢ £ôþ¡ î¥
Page 31 and 32:
or = ö D Q ù ù ?xö ù Y[Z]\ & &
Page 33 and 34:
ñ † † † † † † † †
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˜ E ˜ T ˜ T 2.4 Particle image
Page 37 and 38:
3 Stereo-scopic Particle Image Velo
Page 39 and 40:
› B › B › J ù ž & 3.1 Princ
Page 41 and 42:
Æ e¼c’„ïG ù # #dc’e › B
Page 43 and 44:
Ð È Ñ ù Ñ ù Ð È Ð È Ñ ù
Page 45 and 46:
3.2 Evaluation of stereo-scopic ima
Page 47 and 48:
ú ¦ 3.3 Calibration validation by
Page 49 and 50:
4 Multiplane Stereo Particle Image
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£ è ¤ ó 4.2 Four-pulse-laser S
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£ ¤ £ £ 4.2 Four-pulse-laser Sy
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( ì ( æ ( ì è ð ( ( ( ( ( ( ì
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æ ( | | | | | | | ì æ õ æ õ
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4.5 Simplified recording system 4.5
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4.7 Monochromatic aberrations refle
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º¹ n 4.7 Monochromatic aberration
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4.8 Feasibility study experiments i
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4.8 Feasibility study 10 20 30 40 5
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é¥î ëÝïñð€òôó 5 Invest
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I L § § § : ? ; õ : I I I W
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5.2 Experimental set-up α4 α3 α2
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{ : { L Ø { 9 D { 9 D T W ð 9
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: T ž ž ò 5.3 Statistical pro
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¾ ¾ 5.3.2 Spatial auto- and cross
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½ Ë 5.3 Statistical properties of
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½ Ë 5.3 Statistical properties of
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ô ó ñ ½ ñ ô ó 5.3 Statistica
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æ å ä ã ã ã ½ Ë ä æ å ½
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æ æ å ä À Â ½ 5.3 Statistica
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½ 5.4 Properties of coherent veloc
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» % %QÄ ¾ Ó turbulent velocit
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* Ó , Ó * Á , Â 5.4 Properties
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! 6 Investigation of the xz-plane O
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6.1 Experimental set-up the (virtua
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ß ß 6.2 Statistical properties
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g ˆ g ˆ 6.2 Statistical propertie
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— ¯ 6.2 Statistical properties o
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å å ç æ æ ã ã ã å å è æ
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6.2.3 Spatial cross-correlation fun
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6.2 Statistical properties of the b
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6.2 Statistical properties of the b
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performed at and the second at
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6.3 Spatio-temporal buffer layer st
Page 119 and 120: M M æ æ æ æ æ æ ã ã ã H M
Page 121 and 122: V W V 6.4 Properties of coherent ve
Page 123 and 124: 6.4 Properties of coherent velocity
Page 133 and 134: d d 6.4 Properties of coherent velo
Page 135 and 136: '§ 'Î ª ¿ ¦ '§ ')( 7 Investi
Page 137 and 138: % { s s s s 7.1 Experimental set-up
Page 139 and 140: ‘ — s 7.2 Statistical propertie
Page 141 and 142: 7.2 Statistical properties of the l
Page 143 and 144: ¿ 7.2.2 Spatial cross-correlations
Page 145 and 146: ¿ 7.2 Statistical properties of th
Page 147 and 148: ô ô 7.3 Spatio-temporal correlati
Page 149 and 150: 7.3 Spatio-temporal correlations wi
Page 151 and 152: ¨ ¨ ¨ 7.3 Spati
Page 153 and 154: £ 7.4 Spatio-temporal correlations
Page 161 and 162: ¿ 7.5 Properties of coherent veloc
Page 163 and 164: ¿ 8 Summary The first part of this
Page 165 and 166: aperture, it is shown how to elimin
Page 167 and 168: ¡ ¿ tures keep their spatial orga
Page 169: Bibliography [1] ACARLAR MS, SMITH
Page 173 and 174: [60] KNEUBÜHL FK, SIGRIST MW (1995
Page 175 and 176: [93] SMITH CR, METZLER SP (1983) Th
Page 177 and 178: Z k l l l l l { l R q ‡ ˆ ’
Page 179 and 180: Ø á a Õ Œ v momentum thickness,
Page 181 and 182: Index Kolmogorov micro-scale . . .
Page 183 and 184: Acknowledgement First of all I woul
Page 185: Lebenslauf von Christian Joachim K
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