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High Resolution Scalar Dissipation and Turbulence Length Scale Measurements in an Internal Combustion Engine

Journal Article
2010-01-0185
ISSN: 1946-3936, e-ISSN: 1946-3944
Published April 12, 2010 by SAE International in United States
High Resolution Scalar Dissipation and Turbulence Length Scale Measurements in an Internal Combustion Engine
Sector:
Citation: Petersen, B. and Ghandhi, J., "High Resolution Scalar Dissipation and Turbulence Length Scale Measurements in an Internal Combustion Engine," SAE Int. J. Engines 3(1):65-83, 2010, https://doi.org/10.4271/2010-01-0185.
Language: English

References

  1. Pope, S. “Turbulent Flows,” Cambridge University Press 2000 183 263
  2. Zhang, Y. Ghandhi, J. Rutland, C. Petersen, B. “Large Eddy Simulation of Scalar Dissipation Rate in an Internal Combustion Engine,” SAE Technical Paper 2010-01-0625 2010
  3. Buch, K. Dahm, W. “Experimental Study of the Fine-Scale Structure of Conserved Scalar Mixing in Turbulent Shear Flows, Part 1. Sc≫1,” J. Fluid Mech. 317 21 71 1996
  4. Buch, K. Dahm, W. “Experimental Study of the Fine-Scale Structure of Conserved Scalar Mixing in Turbulent Shear Flows, Part 2. Sc∼1,” J. Fluid Mech. 364 1 29 1998
  5. Rehm, J. Clemens, N. “The Association of Scalar Dissipation Rate Layers and OH Zones with Strain, Vorticity, and 2-D Dilatation Fields in Turbulent Nonpremixed Jets and Jet Flames,” AIAA 99-0676 1999
  6. Su, L. Clemens, N. “Planar Measurements of the Full Three-Dimensional Scalar Dissipation Rate in Gas-Phase Turbulent Flows,” Exp. Fluids 27 507 521 1999
  7. Su, L. “Measurements of the Three-Dimensional Scalar Dissipation Rate in Gas-Phase Planar Turbulent Jets,” Center for Turbulence Research Annual Briefs 1998
  8. Su, L. Clemens, N. “The Structure of Fine-Scale Scalar Mixing in Gas-Phase Planar Turbulent Jets,” J. Fluid Mech. 488 1 29 2003
  9. Kothnur, P. Clemens, N. “Experimental Investigation of the Relationship Between Strain and Scalar Dissipation in Gas-Phase Turbulent Jets,” AIAA 2001-1023 2001
  10. Tsurikov, M. Clemens, N. “The Structure of Dissipative Scales in Axisymmetric Turbulent Gas-Phase Jets,” AIAA 2002-0164 2002
  11. Pitts, W. Richards, C. Levenson M. “Large- and Small-Scale Structures and their Interaction in an Axisymmetric Jet,” NIST Report NISTR 6393 1999
  12. Wang, G. Clemens, N. Varghese, P. “Two-Point, High-Repetition-Rate Rayleigh Thermometry in Flames: Techniques to Correct for Apparent Dissipation Induced Noise,” Applied Optics 44 6741 6751 2005
  13. Wang, G. Barlow, R. Clemens, N. “Quantification of Resolution and Noise Effects on Thermal Dissipation Measurements in Turbulent Non-Premixed Jet Flames,” Proc. Comb. Inst. 31 1525 1532 2007
  14. Wang, G. Karpetis, A. Barlow, R. “Dissipation Length Scales in Turbulent Nonpremixed Jet Flames,” Comb. and Flame 148 62 75 2007
  15. Wang, G. Barlow, R. “Spatial Resolution Effects on the Measurement of Scalar Variance and Scalar Gradient in Turbulent Nonpremixed Jet Flames,” Exp. Fluids 44 633 645 2008
  16. Kaiser, S. Frank, J. “Imaging of Dissipative Structures in the Near Field of a Turbulent Non-Premixed Jet Flame,” Proc. Comb. Inst. 31 1515 1523 2007
  17. Probst, D. Ghandhi, J. “An Experimental Study of Spray Mixing in a Direct Injection Engine,” Int. J. Engine Res. 4 27 45 2003
  18. Wiles, M.A. Probst, D.M. Ghandhi, J.B. “Bulk Cylinder Flow Field Effects on Mixing in DISI Engines,” SAE Technical Paper 2005-01-0096 2005
  19. Mi J. Nathan, G. “The Influence of Probe Resolution on the Measurement of a Passive Scalar and its Derivatives,” Exp. Fluids 34 687 696 2003
  20. Ghandhi, J. “Spatial Resolution and Noise Considerations in Determining Scalar Dissipation Rate from Passive Scalar Image Data,” Exp. Fluids 40 577 588 2006
  21. Southerland, K. Dahm, W. “A Four-Dimensional Experimental Study of Conserved Scalar Mixing in Turbulent Flows,” University of Michigan Report No. 026779-12 1994
  22. Wang G. Clemens N. Barlow N. Varghese P. “A System Model for Assessing Scalar Dissipation Measurement Accuracy in Turbulent Flows,” Meas. Sci. Technol. 18 1287 1303 2007
  23. Wang, G. Clemens, N. “Effects of Imaging System Blur on Measurements of Flow Scalars and Scalar Gradients,” Exp. in Fluids 37 194 205 2004
  24. Antonia, R. Abe, H. Kawamura, F. “Analogy Between Velocity and Scalar Fields in a Turbulent Channel Flow,” J. Fluid Mech. 628 241 268 2009
  25. Petersen, B.R. Ghandhi, J.B. “High Resolution Scalar Dissipation Measurements in an IC Engine,” SAE Int. J. Engines 2 1 475 491 2009
  26. Iverson, R.J. “The Effects of Intake Charge Stratification on HCCI Combustion,” Department of Mechanical Engineering, University of Wisconsin-Madison 2004
  27. Herold, R.E. “Optical Investigations of the Effects of Stratification on Homogeneous Charge Compression Ignition Combustion,” Department of Mechanical Engineering, University of Wisconsin-Madison 2008
  28. Petersen, B. Ghandhi, J. Koch, J. “Fluorescence Saturation Measurements of 3-Pentanone,” Appl. Phys. B 93 639 644 2008
  29. Siegman, A. “How to (Maybe) Measure Laser Beam Quality,” OSA TOPS 17 184 199 1998
  30. Wang, G. Clemens, N. “Effect of Imaging System Blur on Measurements of Flow Scalars and Scalar Gradients,” Exp. in Fluids 37 194 205 2004
  31. Bracco, F. “Structure of Flames in Premixed-Charge IC Engines,” Comb. Sci. Tech. 58 209 230 1988
  32. Petersen, B. Heim, D. Ghandhi, J. “High Resolution Scalar and Velocity Measurements in an IC Engine.” ASME ICES2009-76097 2009
  33. Lele, S. “Compact Finite Difference Schemes with Spectral-Like Resolution,” J. Comp. Phys. 103 16 42 1992

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