Experimental and Numerical Study of Swirling ... - Solid Mechanics
Experimental and Numerical Study of Swirling ... - Solid Mechanics Experimental and Numerical Study of Swirling ... - Solid Mechanics
Experimental and Numerical Study of Swirling Flow in Scavenging Process for 2-Stroke Marine Diesel Engines References Lucca-Negro O., O’Doherty T., ‘‘Vortex breakdown: a review,’’ Prog. Energy Combust. Sci., 27, pp. 431---481 (2000). Luweig H., Ergänzung zu der arbeit:’’Stabilität der strömung in einem zylinderischen ringraum’’, Z. Flugwiss, 9, 11, pp. 359-361 (1961). Lübcke H., Schmidt S., Rung T. and Thiele F., ‘‘Comparison of LES and RANS for bluff-body flows,’’ Journal of Wind Engineering and Industrial Aerodynamics, 89, (2001). MAN Diesel, Direct Communication with MAN DIESEL A/S personnel, 2010. McGeorge H. D., ‘‘Marine Auxiliary Machinery,’’ 7th edition, Butterworth- Heinemann, (1999). Moene A. F., ‘‘Swirling Pipe Flow with Axial Strain: Experiment and Large Eddy Simulation,’’ PhD thesis, Technical University of Eindhoven, (2003). Najafi A. F., Saidi M. H., Sadeghipour M. S., Souhar M., ‘‘Numerical analysis of turbulent swirling decay pipe flow,’’ International Communications in Heat and Mass Transfer, 32, 5, pp. 627-638 (2005). Nakagawa H., Kato S., Tateishi M., Adachi T., Tsujimura H., and Nakashima M., ‘‘Airflow in the Cylinder of a 2-Stroke Cycle Uniflow Scavenging Diesel Engine During Compression Stroke,’’ JSME International Journal, 33-II, 3, pp. 591-598 (1990). Nishimoto N. and Takeyuki K., ‘‘A Study on the Influence of Intel Angel and Reynolds Number on the Flow-Pattern of Uniflow Scavenging Air,’’ SAE Transactions, 93, (1984). Novak F. and Sarpkaya T., ‘‘ Turbulent Vortex Breakdown at High Reynolds Numbers,’’ AIAA, 38, 5, pp. 825-834 (2000). Orszag S.A. and Yakhot V., "Renormalization-Group Analysis of Turbulence," Phys. Rev. Lett. 57, pp. 1722---1724 (1986). Yakhot V. and Smith L.M., ‘‘The renormalization group, the -expansion and derivation of turbulence models,’’ J. Sci. Comput., 7, pp. 35---61 (1992). Pani B.S. and Rajaratnam, N., ‘‘Swirling circular turbulent wall jets,’’ IAHR Journal of Hydraulic Research, 14, 2, pp. 145-154 (1976). Parchen R. R. and Steenbergen W., ‘‘An Experimental and Numerical Study of Turbulent Swirling Pipe Flows,’’ Journal of Fluids Engineering, 120, pp. 54-61 (1998). 176 References
Experimental and Numerical Study of Swirling Flow in Scavenging Process for 2-Stroke Marine Diesel Engines References Pashtrapanska M., Jovanovic´ J., Lienhart H. and Durts F., ‘‘Turbulence Measurements in a Swirling Pipe Flow,’’ Experiment in Fluids, 41, pp. 813- 827, (2006). Pergolesi Flavio, ‘‘Scavenging flow in a model of two stroke Diesel engine,’’ Masters Thesis, (2009). Pevzner L. A., ‘‘Aspects of marine low-speed, cross-head diesel engine lubrication,’’ Lubrication Engineering, 54, 6, pp. 16-21 (1998). Pulkrabek, W. W., ‘‘Engineering fundamentals of the internal combustion engine,’’ Pearson Prentice-Hall, (2003). Rajaratnam N., ‘‘Turbulent Jets,’’ Elsevier Publishing Co., Amsterdam and New York, (1976). Raunek, ‘‘Uniflow & Loop Scavenging Procedure,’’ article published online (www.brighthub.com), (2009). Rocklage-Marliani G., Schmidts M. and Ram V.I.V., ‘‘Three-dimensional Laser-Dopp.ler Velocimeter Measurements in Swirling Turbulent Pipe Flow,’’ Flow Turbulence and Combustion, 70, pp. 43-67 (2003). Schweitzer P. H., ‘‘Scavenging of two-stroke cycle diesel engines,’’ The Macmillan Co., New York, N. Y., (1949). Sturgess G. J. and Syed S. A., ‘‘Calculation of confined swirling flows,’’ AIAA 23rd Aerospace Meeting, (1985). Speziale C. G., Sarkar S. and Gatski T. B.,"Modelling the Pressure-Strain Correlation of Turbulence: An Invariant Dynamical Systems App.roach,"JFM, 227, pp. 245-272 (1991). Sarpkaya, T., ‘‘Effect of the Adverse Pressure Gradient on Vortex Breakdown,’’ AIAA Journal, 12, pp. 602-607 (1974). Sarpkaya T., ‘‘Turbulent Vortex Breakdown,’’ Physics of Fluids, 7, 10, pp. 2301---2303 (1995). Saric W.S., ‘‘Görtler Vortices,’’ Annual Review of Fluid Mechanics, 26: pp. 379-409 (1994). Saffman P. G., ‘‘Vortex Dynamics,’’ Cambridge University Press, (1995). Senoo Y., Kawaguchi W. and Nagata T., ‘‘Swirl Flow in Conical Diffusers,’’ Bulletin of the JSME, 21, 112 (1978). Sloan D., Smith P. and Smoot L., ‘‘Modeling of swirl in turbulent flow systems,’’ Prog. Energ. Combust. Sci., 12, pp. 163---250 (1986). 177 References
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<strong>Experimental</strong> <strong>and</strong> <strong>Numerical</strong> <strong>Study</strong> <strong>of</strong> <strong>Swirling</strong> Flow in Scavenging Process for 2-Stroke<br />
Marine Diesel Engines<br />
References<br />
Pashtrapanska M., Jovanovic´ J., Lienhart H. <strong>and</strong> Durts F., ‘‘Turbulence<br />
Measurements in a <strong>Swirling</strong> Pipe Flow,’’ Experiment in Fluids, 41, pp. 813-<br />
827, (2006).<br />
Pergolesi Flavio, ‘‘Scavenging flow in a model <strong>of</strong> two stroke Diesel engine,’’<br />
Masters Thesis, (2009).<br />
Pevzner L. A., ‘‘Aspects <strong>of</strong> marine low-speed, cross-head diesel engine<br />
lubrication,’’ Lubrication Engineering, 54, 6, pp. 16-21 (1998).<br />
Pulkrabek, W. W., ‘‘Engineering fundamentals <strong>of</strong> the internal combustion<br />
engine,’’ Pearson Prentice-Hall, (2003).<br />
Rajaratnam N., ‘‘Turbulent Jets,’’ Elsevier Publishing Co., Amsterdam <strong>and</strong><br />
New York, (1976).<br />
Raunek, ‘‘Uniflow & Loop Scavenging Procedure,’’ article published online<br />
(www.brighthub.com), (2009).<br />
Rocklage-Marliani G., Schmidts M. <strong>and</strong> Ram V.I.V., ‘‘Three-dimensional<br />
Laser-Dopp.ler Velocimeter Measurements in <strong>Swirling</strong> Turbulent Pipe<br />
Flow,’’ Flow Turbulence <strong>and</strong> Combustion, 70, pp. 43-67 (2003).<br />
Schweitzer P. H., ‘‘Scavenging <strong>of</strong> two-stroke cycle diesel engines,’’ The<br />
Macmillan Co., New York, N. Y., (1949).<br />
Sturgess G. J. <strong>and</strong> Syed S. A., ‘‘Calculation <strong>of</strong> confined swirling flows,’’<br />
AIAA 23rd Aerospace Meeting, (1985).<br />
Speziale C. G., Sarkar S. <strong>and</strong> Gatski T. B.,"Modelling the Pressure-Strain<br />
Correlation <strong>of</strong> Turbulence: An Invariant Dynamical Systems<br />
App.roach,"JFM, 227, pp. 245-272 (1991).<br />
Sarpkaya, T., ‘‘Effect <strong>of</strong> the Adverse Pressure Gradient on Vortex<br />
Breakdown,’’ AIAA Journal, 12, pp. 602-607 (1974).<br />
Sarpkaya T., ‘‘Turbulent Vortex Breakdown,’’ Physics <strong>of</strong> Fluids, 7, 10, pp.<br />
2301---2303 (1995).<br />
Saric W.S., ‘‘Görtler Vortices,’’ Annual Review <strong>of</strong> Fluid <strong>Mechanics</strong>, 26: pp.<br />
379-409 (1994).<br />
Saffman P. G., ‘‘Vortex Dynamics,’’ Cambridge University Press, (1995).<br />
Senoo Y., Kawaguchi W. <strong>and</strong> Nagata T., ‘‘Swirl Flow in Conical Diffusers,’’<br />
Bulletin <strong>of</strong> the JSME, 21, 112 (1978).<br />
Sloan D., Smith P. <strong>and</strong> Smoot L., ‘‘Modeling <strong>of</strong> swirl in turbulent flow<br />
systems,’’ Prog. Energ. Combust. Sci., 12, pp. 163---250 (1986).<br />
177<br />
References