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Influence of Injection Timing and Piston Bowl Geometry on PCCI Combustion and Emissions

Journal Article
2009-01-1102
ISSN: 1946-3936, e-ISSN: 1946-3944
DOI: https://doi.org/10.4271/2009-01-1102
Published April 20, 2009 by SAE International in United States
Influence of Injection Timing and Piston Bowl Geometry on PCCI Combustion and Emissions
Sector:
Citation: Cao, L., Bhave, A., Su, H., Mosbach, S. et al., "Influence of Injection Timing and Piston Bowl Geometry on PCCI Combustion and Emissions," SAE Int. J. Engines 2(1):1019-1033, 2009, https://doi.org/10.4271/2009-01-1102.
Language: English

References

  1. Aceves S. M. Flowers D. L. “A Multi-zone Model for Prediction of HCCI Combustion and Emissions” SAE paper 2000-01-0372 2000
  2. Flowers D. Aceves S. Martinez R. Hessel R. Dibble R. W. “Effect of Mixing on Hydrocarbon and Carbon Monoxide Emissions Prediction for Isooctane HCCI Engine Combustion using A Multi-zone Detailed Kinetics Solver” SAE paper 2003-01-1821 2003
  3. Babajimopoulos A. Lavoie G. Assanis D. N. “Modelling HCCI Combustion with High levels of Residual Gas Fraction-A Comparison of two VVA Strategies” SAE paper 2003-01-3220 2003
  4. Babajimopoulos A Assanis D. N. Flowers D. L. Hessel R. P. “A Fully Coupled Computational Fluid Dynamics and Multi-zone Model with Detailed Chemical Kinetics for the Simulation of Premixed Charge Compression Ignition Engines” International Journal of Engine Research 6 497 512 2005
  5. Kong S. C. Reitz R. “Application of Detailed Chemistry and CFD for Predicting Direct Injection HCCI Engine Combustion and Emissions” Proc. Comb. Inst. 29 667 669 2002
  6. Zhang Y. Z. Kung E. H. Haworth D. C. “A PDF method for Multi-dimensional Modelling of HCCI Engine Combustion: Effects of Turbulence/Chemistry Interactions on Ignition Timing and Emissions” Proc. Comb. Inst., 2005 30 2763 2771 2005
  7. Kong S. C. Ayoub N. Reitz R. D. “Modeling Combustion in Compression Ignition Homogeneous Charge Engines” SAE paper 920512 1992
  8. Jhavar R. Rutland C “Effects of Mixing of Early Injection Diesel Combustion” SAE paper 2005-01-0154 2005
  9. Kong S. C. Marriot C. D. Reitz R. D. Christensen M. “Modeling and Experiments of HCCI Combustion Using Detailed Chemical Kinetics with Multi-dimensional CFD” SAE paper 2001-01-1026 2001
  10. Yu Y. Su W. Huang H.Z. “Study of Fuel Distribution on Diesel PCCI Combustion by Development of a New Characteristic-Time Combustion Model,” SAE Int. J. Fuels Lubr. 1 1 957 969 2008
  11. Kong S. C. Kim H. Reitz R. D. Kim Y “Comparisons of Combustion Simulation Using Representative Interactive Flamelet Model and Direct Integration of CFD with Detailed Chemistry” ASME Journal of Gas Turbines and Power 129 252 260 2007
  12. Lehtiniemi H. Zhang Y. Rawat R. Mauss F. “Efficient 3-D CFD Combustion Modeling with Transient Flamelet Models” SAE paper 2008-01-0957 2008
  13. Cook D. J. Pitsch H. Chen J. H. Hawkes E. R. “Flamelet-based modelling of auto-ignition with thermal inhomogeneities for application to HCCI engines” Proc. Combust. Inst. 31 2903 2911 2007
  14. Cao L Su H. Y. Mosbach S. Bhave A. Kraft M. Kook S. Bae C “Studying of the Influence of Direct Injection on PCCI Combustion and Emissions at Engine Idle Condition Using Two dimensional CFD and Stochastic Reactor Model” SAE paper 2008-01-0021 2008
  15. Mosbach S. Su H. Kraft M. Bhave A. Wang Z. Wang J. “Dual Injection HCCI Engine Simulation using a Stochastic Reactor Model” International Journal of Engine Research 8 41 50 2007
  16. Su H. Mosbach S. Kraft M. Bhave A. Kook S. Bae C “Two Stage Fuel Direct Injection in a Diesel Fuelled HCCI Engine” SAE paper 2007-01-1880 2007
  17. Bhave A. Kraft M. Montorsi L. Mauss F. “Modelling a Dual-fuelled Multi-Cylinder HCCI Engine Using a PDF-based Engine Cycle Simulator” SAE paper 2004-01-0561 2004
  18. Tuner M. Pasternak M. Bensler H. Mauss F. “A PDF-Based Model for Full Cycle Simulation of Direct Injected Engines” SAE paper 2008-01-1606 2008
  19. Amsden A. A. “KIVA-3V: A Blocked-structured KIVA Program for Engine with Vertical or Canted Valves” LA-13313-MS 1997
  20. Han Z. Reitz R. “A Temperature Wall Function Formulation for Variable-Density Turbulent Flows with Application to Engine Convective Heat Transfer Modelling” International Journal of Heat and Mass Transfer 40 40 60 1997
  21. Patterson M. A. Reitz R. “Modeling the Effect of Fuel Spray Characteristics on Diesel Engine Combustion and Emissions” SAE paper 980131 1998
  22. O'Rourke P. J. Amsden A. A. “A spray/Wall Interaction Submodel for the KIVA-3 Wall Film Model” SAE paper 2000-01-0271 2000
  23. Hairer E. Wanner G. “Solving Ordinary Differential Equations II: Stiff and Differential-Algebraic Problems” Springer-Verlag 1991
  24. Subramaniam S. Pope S. B. “A mixing model for turbulent reactive flows based on Euclidean minimum spanning trees” Combustion and Flame 115 487 514 1998
  25. Bhave A. Kraft M. Montorsi L. Mauss F. “Sources of CO Emissions in an HCCI Engine: a Numerical Analysis” Combustion and Flame 144 634 637 2006
  26. Christensen M. Johansson B. Hultqvist A. “The Effect of Combustion Chamber Geometry Effects in an HCCI Operation” SAE paper 2002-01-0425 2002
  27. Vressner A. Hultqvist A. Johansson B. “Study on Combustion Chamber Geometry Effects in an HCCI Engine Using High-Speed Cycle-Resolved Chemiluminescence Imaging” SAE paper 2007-01-0217 2007
  28. Shi Y. Reitz R.D. “Assessment of Optimization Methodologies to Study the Effects of Bowl Geometry, Spray Targeting and Swirl Ratio for a Heavy-Duty Diesel Engine Operated at High-Load,” SAE Int. J. Engines 1 1 537 557 2008
  29. Boyarski N. J. Reitz R. D. “Premixed Compression Ignition (PCI) Combustion with Modeling-Generated Piston Bowl Geometry in a Diesel Engine” SAE paper 2006-01-0198 2006

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