Hostname: page-component-848d4c4894-m9kch Total loading time: 0 Render date: 2024-05-19T09:01:24.226Z Has data issue: false hasContentIssue false
  • English
  • Français

CFD for aerodynamic turbulent flows: progress and problems

Published online by Cambridge University Press:  04 July 2016

B. E. Launder
B. E. Launder*
Affiliation:
UMIST, Manchester, UK
Get access Rights & Permissions [Opens in a new window]

Abstract

Current weaknesses in modelling the turbulent stresses arguably provide the main obstacle to relying on CFD predictions of complex aerodynamic flows. The paper reviews some recent strategies for obtaining more reliable models with especial focus on cubic non-linear eddy viscosity models and stress-transport schemes which comply with the two-component limit. Applications are shown for a broad range of test flows. Finally, important remaining weaknesses are considered.

Type
Research Article
Information
The Aeronautical Journal , Volume 104 , Issue 1038 , August 2000 , pp. 337 - 346
Copyright
Copyright © Royal Aeronautical Society 2000 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Chapman, D.R. Computational aerodynamics development and outlook, AIAA J, 1979, 17, 1293.Google Scholar
2. Leschziner, M.A., Batten, P.and Loyau, H. Modelling shock- affected near-wall flows with anisotropy-resolving turbulence closures, Int J Heat Fluid Flow, 2000, 21, pp 239251.Google Scholar
3. Prandtl, L. Uber die ausgebildete Turbulenz, ZAMM, 1925, 5, 136.Google Scholar
4. Taylor, G.I. Eddy motion in the atmosphere, Phil Trans Roy Soc, 1915, 215, pp 126.Google Scholar
5. Speziale, C.G. On non-linear k-l and k-ε models of turbulence, J. Fluid Mech, 1987, 178, pp 459475.Google Scholar
6. Nisizima, S. and Yoshizawa, A. Turbulent channel and couette flows using an anisotropic k-ε model, AIAA J, 1987, 23, pp 414420.Google Scholar
7. Rubinstein, R. and Barton, J.M. Non-linear Reynolds stress models and renormalization group, Phys Fluids, 1990, A2, pp 14721476.Google Scholar
8. Myong, H.K. and Kasagi, N. Prediction of anisotropy of the near-wall turbulence with an anisotropic low-Reynolds-number k-ε turbulence model, Trans ASME J Fluids Eng, 1990, 112, pp 521524.Google Scholar
9. Craft, T.J., Launder, B.E. and Suga, K. Development and application of a cubic eddy-viscosity model of turbulence, Int J Heat Fluid Flow, 1996, 17, pp 108115.Google Scholar
10. Craft, T.J., Launder, B.E. and Suga, K. Prediction of turbulent transitional phenomena with a non-linear eddy viscosity model, Int J Heat Fluid Flow, 1997, 18, pp 1528.Google Scholar
11. Suga, K. Development and Application of a Non-Linear Eddy-Viscosity Model Sensitised to Stress and Strain Invariants, PhD Thesis, Faculty of Technology, University of Manchester, 1995.Google Scholar
12. Rotta, J.C. Statistische Theorie nichthomogener Turbulenz, Z Physik, 1951, 129, pp 547572.Google Scholar
13. Chou, P.Y. On velocity correlation and the solution of the equation of turbulent fluctuation, Q Appl Math, 1945, 3, pp 3854.Google Scholar
14. Millionshtchikov, M.D. On the role of the third moments in isotropic turbulence, CR Acad Sci, SSSR, 1941, 32, p 619.Google Scholar
15. Durbin, P.A. Near-wall turbulence closure without damping functions’, Theor Comp Fluid Dynamics, 1991, 3, pp 113.Google Scholar
16. Manceau, R. Personal communication.Google Scholar
17. Lumley, J.L. Computational modelling of turbulent flows, Adv Appl Mech, 1978, 18, p 123.Google Scholar
18. Shih, T.H.and Lumley, J.L. Modelling pressure correlations in Reynolds stress and scalar flux equations, Rep FDA-85.3,Sibley School of Engineering, Cornell University, 1985.Google Scholar
19. Launder, B.E. and Shima, N. A second-moment closure for the near-wall sublayer — development and application, AIAA J, 1989, 27, pp 1319 1325.Google Scholar
20. Launder, B.E. and Li, S-P. On the elimination of wall-topography parameters from second-moment closure, Phys Fluids, 1994, 6, pp 999 1006.Google Scholar
21. Hinze, J.O. Experimental investigation on secondary currents in the turbulent flow through a straight conduit, Appl Sci Res, 1973, 28, p 453.Google Scholar
22. Fu, S. Computational Modelling of Swirling Flows With Second-Moment Closures, PhD Thesis, Faculty of Technology, University of Manchester, 1988.Google Scholar
23. Launder, B.E. Second-moment closure: present …. and future?, Int J Heat Fluid Flow, 1989, 10, p 282.Google Scholar
24. Nicholson, J.H., Forest, A.E., Oldfield, M.L.G. and Schultz, D.L. Heat transfer optimized turbine rotor blades: an experimental study using transient techniques, ASME Paper 1982, 82-GT-304.Google Scholar
25. Suga, K., Nakaoka, M., Horinouchi, N., Abe, K. and Kondo, Y. Application of a three-equation cubic eddy viscosity model to 3D flows by the unstructured grid method, Proc 3rd Int Symp on Turbulence, Heat and Mass Transfer, Nagano, Y., Hanjalic, K. and Tsuji, T., (Eds) 2000, 373380, Aichi Shuppan, Tokyo.Google Scholar
26. Loyau, H., Batten, P. and Leschziner, M.A. Modelling shock boundary-layer interaction with non-linear eddy-viscosity closures, J Flow, Turb and Comb (in press), 2000.Google Scholar
27. Bachalo, W.D. and Johnson, D.A. An investigation of transonic turbulent boundary layer separation on an axisymmetric flow model, AIAA J, 1986, 24, pp 437443.Google Scholar
28. Apsley, D.D. and Leschziner, M.A. A new low-Reynolds-number 2-equation model for complex flows, Int J Heat Fluid Flow, 1998, 19, p 209.Google Scholar
29. Wilcox, D.C. and Rubesen, M.W. NASA, 1981, TP-1517.Google Scholar
30. Shima, N. Prediction of turbulent boundary layers with a second-moment closure, ASME J Fluids Engg, 1993, 115, pp 5669.Google Scholar
31. Shima, N. Low-Reynolds-numbersecond-moment closure without wall-reflection redistribution terms, Int J Heat Fluid Flow, 1998, 19, p 549.Google Scholar
32. Malecki, P. Etude de modeles de turbulence pour les couches limites tridimensionnelles, Thèse, ENSAE, 1994.Google Scholar
33. Sotiropoulos, F. and Patel, V.C. Application of Reynolds stress transport models to stern and wake flows, J Ship Research, 1995, 99, p 263283.Google Scholar
34. Craft, T.J. and Launder, B.E. The self-similar, three-dimensional wall jet, Proc Turbulence and Shear Flow Phenomena — 1 Banerjee, S. and Eaton, J.K., 1999, pp 11291134. (Eds)Google Scholar
35. Launder, B.E. and Tselipidakis, D. Application of a new second-moment closure to turbulent channel flow rotating in orthogonal mode, Int J Heat Fluid Flow, 1994, 15, pp 210.Google Scholar
36. Craft, T.J. and Launder, B.E. A Reynolds-stress closure designed for complex geometries, Int J Heat Fluid Flow, 1996, 17, pp 245254.Google Scholar
37. Elena, L. and Schiestel, R. Turbulence modelling of rotating confined flows, Int J Heat Fluid Flow, 1996, 17, pp 283289.Google Scholar
38. Ito, M., Yamada, Y., Imao, S. and Gonda, M. Experiments on turbulent flow due to an enclosed rotating disk, Eng. Turbulence Modelling — 1 (Ed). Rodi, W., Elsevier Science, Amsterdam, 1990.Google Scholar
39. Batten, P., Craft, T.J., Leschziner, M.A. and Loyau, H. Reynolds- stress transport modelling for compressible aerodynamic applications, AIAA J, 2000, 37, pp 785796.Google Scholar
40. Jakirlic, S. and Hanjalic, K. A second-moment closure for non- equilibrium and separating high- and low-Reynolds number flows, 10th Symposium on Turbulent Shear Flows, 1995, pp 23.25-23.30.Google Scholar
41. Menter, F.R. Two-equation eddy-viscosity models for engineering applications, AIAA J, 1994, 32.Google Scholar
42. Barberis, D. and Molton, P., Shock-wave/turbulent boundary layer interaction in a three-dimensional flow, Paper AIAA-95-0227, Reno, Nevada, 1995.Google Scholar
43. Wilcox, D.C. Turbulence modelling for CFD, DCW Industries. La Cañada, 1993.Google Scholar
44. Pope, S.B. An explanation of the turbulent round-jet/ plane-jet anomaly, AIAA 7, 1978, 16, pp 279281.Google Scholar
45. Hanjalic, K. and Launder, B.E. Sensitising the dissipation equation to secondary strains, ASME J Fluids Engg, 1980, 102, pp 3440.Google Scholar
46. Hanjalic, K., Launder, B.E. and Schiestel, R. Multiple time-scale concepts in turbulent transport modelling, in Turbulent Shear Flows — 2, 1980, 3649, Springer, Heideberg.Google Scholar
47. Savill, A.M. Chapter 6. One-point closures applied to transition, in Turbulence and Transition Modelling, 1996, 233268, Hallbäck, (Ed) et al, Kluwer.Google Scholar
48. Van Driest, E.R. On turbulent flow near a wall, J Aero Sci, 1956, 23, p1007.Google Scholar
49. Launder, B.E. Low Reynolds number turbulence near walls, UMIST, Mechanical Engineering Department, 1986, TFD/86/4, (see also ASME J Heat Transfer, 1988, 110, pp 11121128.Google Scholar
50. Gant, S. Personal Communication, 2000.Google Scholar
51. Spalart, P. Strategies for turbulence modelling and simulations, Int J Heat Fluid Flow, 2000, 21, pp 252263.Google Scholar