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Influence of Turbulence and Thermophysical Fluid Properties on Cavitation Erosion Predictions in Channel Flow Geometries

Journal Article
2019-01-0290
ISSN: 2641-9645, e-ISSN: 2641-9645
DOI: https://doi.org/10.4271/2019-01-0290
Published April 02, 2019 by SAE International in United States
Influence of Turbulence and Thermophysical Fluid Properties on Cavitation Erosion Predictions in Channel Flow Geometries
Sector:
Citation: Magnotti, G., Battistoni, M., Saha, K., and Som, S., "Influence of Turbulence and Thermophysical Fluid Properties on Cavitation Erosion Predictions in Channel Flow Geometries," SAE Int. J. Adv. & Curr. Prac. in Mobility 1(2):691-705, 2019, https://doi.org/10.4271/2019-01-0290.
Language: English

References

  1. Schmidt , D.P. and Corradini , M.L. The Internal Flow of Diesel Fuel Injector Nozzles: A Review Int. J. Engine Research. 2 1 1 22 2001
  2. Arai , M. , Shimizu , M. , and Hiroyasu , H Similarity between the Breakup Lengths of a High Speed Liquid Jet in Atmospheric and Pressurized Conditions ICLASS-91 Gaithersburg, MD 1991
  3. Hiroyaso , H. , Arai , M. , and Shimizu , M. Break-Up Length of a Liquid Jet and Internal Flow in a Nozzle ICLASS-91 Gaithersburg, MD 1991
  4. Soteriou , C. , Andrews , R. , and Smith , M. Direct Injection Diesel Sprays and the Effect of Cavitation and Hydraulic Flip on Atomization SAE Technical Paper 950080 1995 1995 10.4271/950080
  5. Manin , J. , Pickett , L. , Yasutomi , K. Transient Cavitation in Transparent Diesel Injectors ICLASS-2018 Chicago, IL July 23-26, 2018
  6. Skoda , R. , Iben , U. , Morozov , A. , Mihatsch , M. et al. Numerical Simulation of Collapse Induced Shock Dynamics for the Prediction of the Geometry, Pressure and Temperature Impact on the Cavitation Erosion in Micro Channels WIMRC 3rd International Cavitation Forum University of Warwick, UK July 4-6, 2011
  7. Winklhofer , E. , Kull , E. , Kelz , E. , and Morozov , A. Comprehensive Hydraulic and Flow Field Documentation in Model Throttle Experiments under Cavitation Conditions 17th Annual Conference on Liquid Atomization & Spray Systems (ILASS-Europe) Zurich Sep. 2-6, 2001
  8. Morozov , A. and Iben , U. Experimental Analysis and Simulation of Cavitating Throttle Flow 6th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics (HEFAT) Pretoria, South Africa June 30-July 2, 2008
  9. Greif , D. , Morozov , A. , Winklhofer , E. , and Tatschl , R. Experimental and Numerical Investigation of Erosive Effects Due to Cavitation within Injection Equipment Proceedings of 4th ICCHMT Paris-Cachan, France May 17-20, 2005
  10. Battistoni , M. , Duke , D. , Swantek , A.B. , Tilocco , F.Z. et al. Effects of Non-Condensable Gas on Cavitating Nozzles Atomization and Sprays. 25 6 453 483 2015
  11. Battistoni , M. , Som , S. , and Longman , D.E. Comparison of Mixture and Multifluid Models for In-Nozzle Cavitation Prediction J. Eng. Gas Turbines Power 136 6 2014
  12. Koukouvinis , P. , Naseri , H. , and Gavaises , M. Performance of Turbulence and Cavitation Models in Prediction of Incipient and Developed Cavitation International Journal of Engine Research 18 4 333 350 2017
  13. Koukouvinis , P. , Gavaises , M. , Li , J. , and Wang , L. Large Eddy Simulation of Diesel Injector Including Cavitation Effects and Correlation to Erosion Damage Fuel 175 26 39 2016
  14. Zhao , H. , Quan , S. , Dai , M. , Pomraning , E. et al. Validation of a Three-Dimensional Internal Nozzle Flow Model Including Automatic Mesh Generation and Cavitation Effects Journal of Engineering for Gas Turbines and Power 136 9 2014
  15. Magnotti , G.M. , Battistoni , B. , Saha , K. , and Som , S. Evaluation of a New Cavitation Erosion Metric Based on Fluid-Solid Energy Transfer in Channel Flow Simulations 14th Triennial International Conference on Liquid Atomization and Spray Systems (ICLASS) Chicago, IL July 22-26, 2018
  16. Neroorkar , K. , Shields , B. , Grover , R.O. , Plaza Torres , A. et al. Application of the Homogeneous Relaxation Model to Simulating Cavitating Flow of a Diesel Fuel SAE Technical Paper 2012-01-269 2012 10.4271/2012-01-1269
  17. Brusiani , F. , Negro , S. , Bianchi , G.M. , Moulai , M. et al. Comparison of the Homogeneous Relaxation Model and a Rayleigh Plesset Cavitation Model in Predicting the Cavitating Flow through Various Injector Hole Shapes SAE Technical Paper 2013-01-1613 2013 10.4271/2013-01-1613
  18. Salvador , F.J. , Romero , J.-V. , Roselló , M.-D. , and Martínez-López , J. Validation of a Code for Modeling Cavitation Phenomena in Diesel Injector Nozzles Mathematical and Computer Modelling 52 7 1123 1132 2010
  19. Mihatsch , M.S.
  20. Singhal , A.K. , Athavale , M.M. , Li , H. , and Jiang , Y. Mathematical Basis and Validation of the Full Cavitation Model J. Fluids Engineering. 124 3 617 624 2002
  21. Zwart , P.J. , Gerber , A.G. , and Belamri , T. A Two-Phase Flow Model for Predicting Cavitation Dynamics Fifth International Conference on Multiphase Flow Yokohama, Japan 2004
  22. Martínez , I. http://webserver.dmt.upm.es/~isidoro/bk3/c15/Fuel%20properties.pdf
  23. Kim , K.-H. , Chahine , G. , Franc , J.-P. , and Karimi , A. Advanced Experimental and Numerical Techniques for Cavitation Erosion Prediction 106 New York, NY Springer 2016
  24. Dular , M. and Petkovšek , M. On the Mechanisms of Cavitation Erosion - Coupling High Speed Videos to Damage Patterns Experimental Thermal and Fluid Science 68 1 359 370 2015
  25. Gavaises , M. , Papoulias , D. , Andriotis , A. , Giannadakis , E. et al. Link Between Cavitation Development and Erosion Damage in Diesel Injector Nozzles SAE Technical Paper 2007-01-0246 2007 10.4271/2007-01-0246
  26. Richards , K.J. , Senecal , P.K. , and Pomraning , E. CONVERGE 2.3 Manual Madison, WI Convergent Science 2018
  27. Aluminum Properties, Metals and Alloys in the Unified Numbering System Eighth Society of Automotive Engineers, Inc. and American Society for Testing and Materials 1999
  28. Payri , R. , Salvador , F.J. , Gimeno , J. , and Bracho , G. The Effect of Temperature and Pressure on Thermodynamic Properties of Diesel and Biodiesel Fuels Fuel 90 3 1172 1180 2011
  29. Bilicki , Z. and Kestin , J. Physical Aspects of the Relaxation Model in Two-Phase Flow Proc. R. Soc. Lond. A. 428 379 397 1990
  30. Pomraning , E. 2000
  31. Werner , H. and Wengle , H. Large Eddy Simulation of Turbulent Flow over and around a Cube in a Plane Channel Proceedings of the Eighth Symposium on Turbulent Shear Flows 2 1991
  32. Launder , B. and Spalding , D. The Numerical Computation of Turbulent Flows Computer Methods in Applied Mechanics and Engineering 3 2 269 289 1974
  33. Pope , S.B. Turbulent Flows Cambridge Cambridge University Press 2000
  34. Mihatsch , M.S. , Schmidt , S.J. , and Adams , N.A. Cavitation Erosion Prediction Based on Analysis of Flow Dynamics and Impact Load Spectra Physics of Fluids 27 103302 2015
  35. Mihatsch , M.S. , Schmidt , S.J. , Thalhamer , M. , and Adams , N.A. Numerical Prediction of Erosive Collapse Events in Unsteady Compressible Cavitating Flows Eça L. , Oñate E. , García-Espinosa J. , Kvamsdal T. , and Bergan P. MARINE 2011, IV International Conference on Computational Methods in Marine Engineering, Computational Methods in Applied Sciences 29 Dordrecht Springer 2013
  36. Brennen , C.E. Cavitation and Bubble Dynamics New York Cambridge University Press 2014
  37. Jang , W. and Aral , M.M. Concentration Evolution of Gas Species within a Collapsing Bubble in a Liquid Medium Environmental Fluid Mechanics 3 173 193 2003
  38. Iben , U. , Wolf , F. , Freudigmann , H.-A. , and Fröhlich , W.H.J. Optical Measurements of Gas Bubbles in Oil behind a Cavitating Micro-Orifice Flow Experiments in Fluids 56 6 1 10 2014
  39. Battino , R. , Rettich , T.R. , and Tominaga , T. The Solubility of Nitrogen and Air in Liquids J. Phys. Chem. Ref. Data 13 563 1984
  40. Landau , L.D. and Lifshitz , E.M. Fluid Mechanics Second 6 1987

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