UFR 4-13 References

From KBwiki
(Redirected from Gold:UFR 4-13 References)
Jump to navigation Jump to search

Front Page

Description

Test Case Studies

Evaluation

Best Practice Advice

References




Compression of vortex in cavity

Underlying Flow Regime 4-13               © copyright ERCOFTAC 2004


References

Arcoumanis, C., Whitelaw, J.H. (1987) “Fluid Mechanics of Internal Combustion Engines -a Review.” Proc. Instn. Mech. Engrs., 201, C1.


Arcoumanis,C., Hu,Z., Whitelaw,J.H., Steady flow characterization of tumble-generating four-valve cylinder heads . Proceedings of the Institution of Mechanical Engineers, v.207, p.203-210. 1993.


Arcoumanis, C., Hu, Z., Vafidis, C., and Whitelaw, J.H., “Tumbling Motion: A Mechanism for Turbulence Enhancement in Spark-Ignition Engines”, SAE paper 900060, (1990).


Baby X. and Floch A. (1997) .“Investigation of the in-cylinder tumble motion in a multi-valve engine: Effect of the piston shape”, SAE 971643.


Borée J , Marc D., Bazile R. and Lecordier B. “On the behavior of a large scale tumbling vortex flow submitted to compression”, ESAIM : Proceedings (Third International Workshop on Vortex), Vol. 7, 1999, 56-65


Borée J , Maurel D. and Bazile R. "Disruption of a compressed vortex", Physics of Fluids , Vol. 14, number 6, June 2002


Borée, J., Corjon, A. & Marc, D. 1997 Analytical and direct numerical study of the evolution and breakdown of a compressed tumbling vortex. In 11th Symp. on Turbulent Shear flows, Grenoble, France, Sept. 8-11


Celik, I. Yavuz, A. Smirnov, J. Smith, E. Amin, and A. Gel. Prediction of in-cylinder turbulence for IC engines. Combustion Science and Technology, 150:339--372, 2000.


Celik I., Yavuz I., and Smirnov A. Large eddy simulations of in-cylinder turbulence for engines. Journal of Engine Research, 2000. Submitted for publication.


Comte-Bellot, G. (1965). Ecoulement turbulent entre deux parois parallèles, Publications Scientifiques et Techniques du Ministère de l'air.


Devesa A., , Moreau J., , Helie J. & Poinsot T., Large Eddy Simulations of jet / tumble interaction in a GDI model engine flow, Technical Report, CERFACS, Toulouse (France) January 12,2004, Reference : TR/CFD/04/


Foucaut, J. M., Carlier, J. and Stanislas, M. (2001). “On the spectral response of particle image velocimetry.” Submitted to Measurement Science and Technology.


Gosman, A.D. (1985) "Multidimensional Modeling of Cold Flows and Turbulence in Reciprocating Engines," SAE 850344.


Gosman A.D, Tsui Y.Y., Favidis (1985), Flow in a model engine with shrouded valve. A combined experimental and computational study. SAE paper 850498.


Grudno, A. D., Trautwein, S. E., Wassenberg, H. J. and Adomeit, G. (1994). “Spatially resolved determination of the turbulent flamme speed from CH band emission measurements under engine conditions.” SAE Paper 940685.


Han, Z. and Reitz R.D., (1995) "Turbulence Modeling of Internal Combustion Engines Using RNG k - e Models,"

Combustion Science and Technology, Volume 106, pp.267-295.


Haworth, D. C. and Jansen, K. Large-eddy simulation on unstructured deforming meshes: towards reciprocating IC engines. Computers and Fluids, 29:493{524), 2000.


Horrocks G.D., Reizes J.A. and Hong G., "Tumble vortex breakdown during the compression stroke of a model internal combustion engine", ASME Internal Combustion Engine Division 2000 Fall Technical Conference, Peoria, IL, 24-27 September 2000.


Hill, P.G. & Zhang, D. 1994 The effects of swirl and tumble on combustion in spark-ignition engines. Prog. Energy Combust. Sci. 20 , 373-429.


Kloeker, J. J., Krause, E. and Kuwahara, K. (1992). Vortical structures and turbulent phenomena in a piston engine model. Proc. of the 13 th ICNMFD, Rom, July 6-10, 1992.


Khalighi, B. (1990) “Intake-Generated Swirl and Tumble Motions in a 4-Valve Engine with Various Intake Configurations-Flow Visualisation and Particle Tracking Velocimetry.” SAE Congress and Exp., Detroit 1990; SAE paper # 900059.


Lebrère, L., Buffat, M., Le Penven, L., Dillies, B., 1996a, “Application of Reynolds Stress Modeling to Engine Flow Calculations”, ASME Journal of Fluids Engineering, Vol. 118, pp 710-721

960635


Maly, R. R., Eberspach, G. and Pfister, W. (1990). Laser diagnostics for single cycle analysis of crank angle resolved length and time scales in engine combustion. International symposium COMODIA 90.


Marc D., (1998) Etude expérimentale de la compression d'un écoulement de rouleau. Simulation modèle de l'aérodynamique interne des moteurs INP, Toulouse, France


Marc D., Borée, J., Bazile, R. & Charnay, G. (1997), PIV and LDV measurements of tumbling vortex flow in a model square section motored engine, SAE 972834.


Marc,D,Borée J., Bazile R. and Charney G. (1997), Combined PIV and LDV analysis on the evolution and breakdown of compressed tumbling vortex", 11th Symp. on Turbulent Shear flows, Grenoble, France, Sept. 8-11


Maurel, S. (2001). Etude par imagerie laser de la génération et de la rupture d’un écoulement tourbillonnaire compressé. Situation modèle pour la validation de simulations aux grandes échelles dans les moteurs, I.N.P. Toulouse.


McLandress A, Emerson R., McDowell P., Rutland C. J. (1996), “Intake and In-Cylinder Flow Modeling Characterization of Mixing and Comparison with Flow Bench Results”, SAE 960635.


Morse, A. P., Whitelaw, J. H., and Yianneskis (1979), M.(2004), Turbulent Flow Measurements by Laser-Doppler Anemometry in Motored Piston-Cylinder Assemblies. Journal of Fluids Engineering, 101:208-216.


Moureau V., Barton I., Angelberger C., Poinsot T., Towards Large Eddy Simulation in Internal-Combustion Engines: simulation of a compressed tumble flow, SAE 2004-01-1995.


Naitoh, K., Itoh, T., Takagi, Y., and Kuwahara, K. Large Eddy Simulation of Premixed-Flame in Engine based on the Multi-Level Formulation and the Renormalization Group Theory. SAE Paper, 920590, 1992.


Namazian, M., Hansen, S., Lyford-Pike, E., Sanchez-Barsse, J., Rife, J. and Heywood, J. (1980). “Schlieren visualisation of the flow and density fields in the cylinder of a spark ignition engine.” SAE Paper 800044


Reize, J. " Tumble vortex breakdown during the compression stroke of a model of internal engine, conference IMFT , Toulouse, Sep. 2000


Smirnov, A., Celik I., Yavuz I., and Smith J., Preliminary results from LES of in-cylinder turbulence for IC-engines. In SAE International Congress and Exposition, Detroit, Michigan, 1999.


Smirnov A., Yavuz I.and Celik I.. Diesel combustion and LES of in-cylinder turbulence for IC-engines. In In-Cylinder Flows and Combustion Processes, number 33-3 in 99-ICE-247, pages 119--127. ASME Fall Technical Conferece, Ann Arbor, Michigan, 1999.


Sone,K., Unsteady Simulations of Mixing and Combustion

in Internal Combustion Engines, Master of Science in Aerospace Engineering Thesis, Georgia Institute of Technology, 2001.


Verzicco, R., Mohd-Yusof, J., Orlandi, P., Haworth, D., 2000, “Large Eddy Simulation in Complex Geometries Configurations Using Boundary Body Forces”, AIAA Journal, Vol. 38, pp 427-433.


Computational Fluid Dynamics (CFD) Laboratory at Mechanical and Aerospace Engineering (MAE) Department, Publications


http://www.erc.wisc.edu/publications/publications_index.htmEnfine Research Center Publications – University of Wisconsin -Madison


Acknowledgements

 

S. Maurel was granted by the research group Ecoulement Et Combustion of IMFT during the acquisition of this data set and the development of associated PIV algorithms. The compression machine was initially developed under A.R.C. "Moteur Propres et Econome" (1994 - 1998) supported by CNRS Ecotech, Renault et PSA. The latest technical developments were performed under C.E.E. JOULE contract JOF3-CT97-0035 "Large Eddy Simulations for stratified charge Engines". The technical support of G. Couteau, E. Cid and S. Cazin is greatly acknowledged.

We are particularly grateful to Mr G. Charney and J. Borée to allow the access and the use of this database.

© copyright ERCOFTAC 2004



Contributors: Afif Ahmed - RENAULT


Front Page

Description

Test Case Studies

Evaluation

Best Practice Advice

References