Geodesic
Simulation of turbulent flow and heat transferin the axi-symmetric cavity with rotating disc
Matematičeskoe modelirovanie, Tome 18 (2006) no. 2, pp. 72-88.

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Turbulent flow and heat transfer of viscous compressible fluid in the closed axi-symmetric cavity with rotating disc are considered. Flow structure, friction and heat transfer properties are investigated depending on gap the between stator and rotor and rotational Reynolds number. The comparison of local and integral properties of the flow, calculated on the base of different turbulence models, with experimental data and correlation dependencies is established. 
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K. N. Volkov. Simulation of turbulent flow and heat transferin the axi-symmetric cavity with rotating disc. Matematičeskoe modelirovanie, Tome 18 (2006) no. 2, pp. 72-88. http://geodesic.mathdoc.fr/item/MM_2006_18_2_a5/

[1] Daily J. W., Nece R., “Chamber dimension effects on induced flow and frictional resistance of enclosed rotating discs”, ASME Journal of Basic Engineering, 82 (1960), 217–232

[2] Kreith F., “Convection heat transfer in rotating systems”, Advances in Heat Transfer, 5 (1968), 129–251

[3] Owen J. M., Rogers R. H., Flow and heat transfer in rotating-disc systems. Rotating cavities, Research Studies Press, Taunton, 1995

[4] Shlikhting G., Teoriya pogranichnogo sloya, Nauka, M., 1974, 738 pp.

[5] Grinspen Kh. P., Teoriya vraschayuschikhsya zhidkostei, Gidrometeoizdat, L., 1975, 300 pp.

[6] Harmand S., Watel B., Desmet B., “Local convective heat exchanges from a rotor facing a stator”, International Journal of Thermal Sciences, 39 (2000), 404–413 | DOI

[7] Djaoui M., Dyment A., Debuchy R., “Heat transfer in a rotor–stator system with a radial inflow”, European Journal of Mechanics. B/Fluids, 20 (2001), 371–398 | DOI | Zbl

[8] Debuchy R., Dyment A., Muhe H., Micheau P., “Radial inflow between a rotating and a stationary disc”, European Journal of Mechanics. B/Fluids, 17:6 (1998), 791–810 | DOI | Zbl

[9] Beretta G. P., Malfa E., “Flow and heat transfer in cavities between rotor and stator disks”, International Journal of Heat and Mass Transfer, 46 (2003), 2715–2726 | DOI | MR

[10] Shevchuk I. V., “Turbulentnyi teploobmen vraschayuschegosya diska pri postoyannoi temperature ili plotnosti teplovogo potoka na stenke”, TVT, 38:3 (2000), 521–523 | MR

[11] Yuan Z. X., Saniei N., Yan X. T., “Turbulent heat transfer on the stationary disk in a rotor-stator system”, International Journal of Heat and Mass Transfer, 46 (2003), 2307–2218

[12] Jacques R., Le Quere P., Daube O., “Axisymmetric numerical simulations of turbulent flow in rotor stator enclosures”, International Journal of Heat and Fluid Flow, 23 (2002), 381–397 | DOI

[13] Iacovides H., Toumpanakis P., “Turbulence modeling of flow in axisymmetric rotor-stator systems”, Proceedings of the 5th International Symposium on Refined Flow Modelling and Turbulence Measurements (7–10 September, 1993, Paris, France), Presses de l'Ecole Nationale des Ponts et Chaussees, Paris, 1993, 383–390

[14] Morse A. P., “Numerical prediction of turbulent flow in rotating cavities”, ASME Journal of Turbomachinery, 110 (1988), 202–212 | DOI

[15] Elena L., Schiestel R., “Turbulence modeling of rotating confined flows”, International Journal of Heat Fluid Flow, 17 (1996), 283–289 | DOI

[16] Launder B. E., Spalding D. B., “The numerical computation of turbulent flows”, Computational Methods in Applied Mechanics Engineering, 3 (1974), 269–289 | DOI | Zbl

[17] Kato M., Launder B. E., “The modelling of turbulent flow around stationary and vibrating square cylinders”, Proceedings of the 9th Symposium on Turbulent Shear Flows (Kyoto, 16–18 August 1993), 9, 1993, 10.4.1–10.4.6

[18] Leschziner M. A., Rodi W., “Calculation of annular and twin parallel jets using various discretization schemes and turbulent-model variations”, ASME Journal of Fluid Engineering, 103 (1981), 353–360

[19] Rodi W., “Experience with two-layer models combining the $k-\varepsilon$ model with one-equation model near wall”, AIAA Paper, 1991, no. 91–021, 16 pp.

[20] Wolfshtein M., “The velocity and temperature distribution of one-dimensional flow with turbulence augmentation and pressure gradient”, International Journal of Heat and Mass Transfer, 12 (1969), 301–318 | DOI

[21] Wilcox D. C., “A two-equation turbulence model for wall-bounded and free-shear flows”, AIAA Paper, 1993, no. 93–2905, 16 pp.

[22] Spalart P. R., Allmaras S. R., “A one equation turbulence model for aerodynamic flows”, AIAA Paper, 1992, no. 92–0439 | Zbl

[23] Dacles-Mariani J., Zilliac G. G., Chow J. S., Bradshaw P., “Numerical/experimental study of a wingtip vortex in the near field”, AIAA Journal, 33:9 (1995), 1561–1568 | DOI

[24] Deck S., Duveau P., d'Espiney P., Guillen P., “Development and application of Spalart-Allmaras oneequation turbulence model to three-dimensional supersonic complex configurations”, Aerospace Science and Technology, 6 (2002), 171–183 | DOI | Zbl

[25] Jones W. P., Musonge P., “Closure of the Reynolds stress and scalar flux equations”, Physics of Fluids, 31:12 (1988), 3589–3604 | DOI | MR | Zbl