UFR 3-05 References: Difference between revisions

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Shock/boundary-layer interaction (on airplanes)

Underlying Flow Regime 3-05               © copyright ERCOFTAC 2004


References

1. P. Batten, H. Loyau and M. Leschziner (eds.), “Workshop on shock-boundary-layer interaction”, UMIST, 25th-26th March 1997, UMIST report.

2. M.O. Bristeau, R. Glowinski, J. Periaux and H. Viviand (Eds), “Numerical Simulation of Compressible Navier-Stokes Flows”, In Proceedings of the 1985 GAMM Workshop, Notes on Numerical Fluid Mechanics, Vol. 18, 1985.

3. S.A. Skebe, I. Greber and W.R. Hingst, “Investigation of Two-Dimensional Shock-Wave/Boundary-Layer Interactions”, AIAA, 25(6), 1987.

4. J.M. Delery, “Investigation of strong shock-boundary layer interaction in 2-D transonic flows with emphasis on turbulence phenomena”, AIAA-81-1245.

5. W. Haase, F. Brandsma, E. Elsholz, M. Leschziner and D. Schwamborn (Eds), “EUROVAL — An European Initiative on Validation of CFD Codes”, Notes on Numerical Fluid Mechanics, Vol. 42, 1992.

6. T. Pot, J. Delery and C.Quelin, “Interaction choc-couche limite dans un canal transonique tridemensionnel — nouvells experiences en vue de la validation du code canai.” Technical Report 92/7078 Ay, ONERA, Fevrier 1991

7. W.D. Bachalo and D.A. Johnson, “Transonic turbulent boundary layer separation generated on an axi-symmetric flow model”, AIAA Journal, Vol. 24, p. 437, 1986.

8. R.G.M. Hassan and J.J. McGuirk, “Assessment of turbulence transport models for transonic flow over an axi-symmetric bump”, The Aeronautical Journal, Paper No. 2562, January 2001.

9. B.E. Launder and B.I. Sharma, “Application of the energy-dissipation model of turbulence to the calculation of flow near a spinning disc”, Letters in Hear and Mass Transfer, 1974, Vol 1 pp 131-138.

10. D.C. Wilcox, “Reassessment of the scale determining equation for advanced turbulence models”, AIAA J. 1988, Vol 26, pp1299-1310.

11. F.R. Menter, “Two-equation eddy viscosity turbulence models for engineering applications”, AIAA Journal, Vol 32, pp1598-1605, 1994.

12. C.G Speziale “On non-linear k-l and k-ε models of turbulence”, J. Fluid Mech, Vol 178, pp 459-475, 1997.

13. K. Suga “Development and Application of a Non-linear Eddy-Viscosity Model Sensitised to Stress and Strain Invariants.” PhD Thesis, UMIST, 1995.

14. D.D. Apsley and M.A. Leschziner, “A new low-Re non-linear two-equation turbulence model”, Int. J. Heat and Fluid Flow, Vol 18, pp 15-28, 1997.

15. M.M Gibson and B.E. Launder, “Ground effects on pressure fluctuations in the atmospheric boundary layer”, J. Fluid Mech., Vol 86, pp 491-511, 1978.

16. K. Hanjalic and S. Jakirlic and I. Hadzic “Expanding the limits of ‘equilibrium’ second-moment turbulence closures”, Fluid Dynamics Research, Vol 20, pp 25-41, 1997.

17. D.C. Wilcox, “Multiscale model for turbulent flows”, AIAA Journal, Vol 26, pp 1311-1320, 1988.

18. P.R. Spalart and S.R. Allmaras “A One-Equation Turbulence Model for Aerodynamic Flows”, AIAA-92-0439.

19. P.A. Durbin “Near-Wall Turbulence Closure Modelling Without ‘Damping Functions’ ” , Theoretical and Computational Fluid Dynamics, Vol. 3, pp 1-13, 1991.

© copyright ERCOFTAC 2004



Contributors: Antony Hutton - QinetiQ


Front Page

Description

Test Case Studies

Evaluation

Best Practice Advice

References