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A Refined 0D Turbulence Model to Predict Tumble and Turbulence in SI Engines

Journal Article
03-12-01-0002
ISSN: 1946-3936, e-ISSN: 1946-3944
Published November 19, 2018 by SAE International in United States
A Refined 0D Turbulence Model to Predict Tumble and Turbulence in SI Engines
Sector:
Citation: Bozza, F., Teodosio, L., De Bellis, V., Fontanesi, S. et al., "A Refined 0D Turbulence Model to Predict Tumble and Turbulence in SI Engines," SAE Int. J. Engines 12(1):15-30, 2019, https://doi.org/10.4271/03-12-01-0002.
Language: English

References

  1. Hires , S. , Tabaczynski , R. , and Novak , J. The Prediction of Ignition Delay and Combustion Intervals for a Homogeneous Charge, Spark Ignition Engine SAE Technical Paper 780232 1978 10.4271/780232
  2. Blizard , N. and Keck , J. Experimental and Theoretical Investigation of Turbulent Burning Model for Internal Combustion Engines SAE Technical Paper 740191 1974 10.4271/740191
  3. Morel , T. , Rackmil , C. , Keribar , R. , and Jennings , M. Model for Heat Transfer and Combustion In Spark Ignited Engines and its Comparison with Experiments SAE Technical Paper 880198 1988 10.4271/880198
  4. Richard , S. , Bougrine , S. , Font , G. , Lafossas , F.A. et al. On the Reduction of a 3D CFD Combustion Model to Build a Physical 0D Model for Simulating Heat Release, Knock and Pollutants in SI Engines Oil & Gas Science and Technology - Rev. IFP 64 3 223 242 2009 10.2516/ogst/2008055
  5. Gatowsky , J. and Heywood , J. Flame Photographs in a Spark-Ignition Engine Combustion and Flame 56 1 71 81 1984 10.1016/0010-2180(84)90006-3
  6. Gouldin , F. An Application of Fractals to Modeling Premixed Turbulent Flames Combustion and Flame 68 3 249 266 1987 10.1016/0010-2180(87)90003-4
  7. Millo , F. , Luisi , S. , Borean , F. , and Stroppiana , A. Numerical and Experimental Investigation on Combustion Characteristics of a Spark Ignition Engine with an Early Intake Valve Closing Load Control Fuel 121 298 310 2014 10.1016/j.fuel.2013.12.047
  8. Luo , X. , Teng , H. , Lin , Y. , Li , B. et al. A Comparative Study on Influence of EIVC and LIVC on Fuel Economy of a TGDI Engine Part II: Influences of Intake Event and Intake Valve Closing Timing on the Cylinder Charge Motion SAE Technical Paper 2017-01-2246 2017 10.4271/2017-01-2246
  9. Borgnakke , C. , Arpaci , V. , and Tabaczynski , R. A Model for the Instantaneous Heat Transfer and Turbulence in a Spark Ignition Engine SAE Technical Paper 800287 1980 10.4271/800287
  10. Morel , T. and Mansour , N. Modeling of Turbulence in Internal Combustion Engines SAE Technical Paper 820040 1982 10.4271/820040
  11. Morel , T. and Keribar , R. A Model for Predicting Spatially and Time Resolved Convective Heat Transfer in Bowl-in-Piston Combustion Chambers SAE Technical Paper 850204 1985 10.4271/850204
  12. Sjeric , M. , Kozarac , D. , and Bogensperger , M. Implementation of a Single Zone k-ε Turbulence Model in a Multi Zone Combustion Model SAE Technical Paper 2012-01-0130 2012 10.4271/2012-01-0130
  13. Dulbecco , A. , Richard , S. , Laget , O. , and Aubret , P. Development of a Quasi-Dimensional K-k Turbulence Model for Direct Injection Spark Ignition (DISI) Engines Based on the Formal Reduction of a 3D CFD Approach SAE Technical Paper 2016-01-2229 2016 10.4271/2016-01-2229
  14. Kim , N. , Kim , J. , Ko , I. , Choi , H. et al. A Study on the Refinement of Turbulence Intensity Prediction for the Estimation of In-Cylinder Pressure in a Spark-Ignited Engine SAE Technical Paper 2017-01-0525 2017 10.4271/2017-01-0525
  15. Lafossas , F. , Colin , O. , Le Berr , F. , and Menegazzi , P. Application of a New 1D Combustion Model to Gasoline Transient Engine Operation SAE Technical Paper 2005-01-2107 2005 10.4271/2005-01-2107
  16. Ramajo , D. , Zanotti , A. , and Nigro , N. Assessment of a Zero-Dimensional Model of Tumble in Four-Valve High Performance Engine International Journal of Numerical Methods for Heat & Fluid Flow 17 8 770 787 2007 10.1108/09615530710825765
  17. Achuth , M. and Mehta , P.S. Predictions of Tumble and Turbulence in Four-Valve Pentroof Spark Ignition Engines International Journal of Engine Research 2 3 209 227 2001 10.1243/1468087011545442
  18. Grasreiner , S. , Neumann , J. , Luttermann , C. , Wensing , M. et al. A Quasi-Dimensional Model of Turbulence and Global Charge Motion for Spark Ignition Engines with Fully Variable Valvetrains International Journal of Engine Research 15 7 805 816 2014 10.1177/1468087414521615
  19. Fogla , N. , Bybee , M. , Mirzaeian , M. , Millo , F. et al. Development of a K-k-∊ Phenomenological Model to Predict In-Cylinder Turbulence SAE Int. J. Engines 10 2 562 575 2017 10.4271/2017-01-0542
  20. Dai , W. , Newman , C. , and Davis , G. Predictions of In-Cylinder Tumble Flow and Combustion in SI Engines with a Quasi-Dimensional Model SAE Technical Paper 961962 1996 10.4271/961962
  21. Jones , P. and Junday , J. Full Cycle Computational Fluid Dynamics Calculations in a Motored Four Valve Pent Roof Combustion Chamber and Comparison with Experiment SAE Technical Paper 950286 1995 10.4271/950286
  22. Khalighi , B. , El Tahry , S. , Haworth , D. , and Huebler , M. Computation and Measurement of Flow and Combustion in a Four-Valve Engine with Intake Variations SAE Technical Paper 950287 1995 10.4271/950287
  23. Bozza , F. , De Bellis , V. , Berni , F. , D’Adamo , A. et al. Refinement of a 0D Turbulence Model to Predict Tumble and Turbulent Intensity in SI Engines. Part I: 3D Analyses SAE Technical Paper 2018-01-0850 2018 10.4271/2018-01-0850
  24. De Bellis , V. , Bozza , F. , Fontanesi , S. , Severi , E. et al. Development of a Phenomenological Turbulence Model through a Hierarchical 1D/3D Approach Applied to a VVA Turbocharged Engine SAE Int. J. Engines 9 1 506 519 2016 10.4271/2016-01-0545
  25. Yakhot , V. and Orszag , S.A. Renormalization Group Analysis of Turbulence. I. Basic Theory J. Sci. Comput. 1 3 51 1986 10.1007/BF01061452
  26. Bozza , F. , Teodosio , L. , De Bellis , V. , Fontanesi , S. et al. Refinement of a 0D Turbulence Model to Predict Tumble and Turbulent Intensity in SI Engines. Part II: Model Concept, Validation and Discussion SAE Technical Paper 2018-01-0856 2018 10.4271/2018-01-0856

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