Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-24T11:57:29.991Z Has data issue: false hasContentIssue false
  • English
  • Français

An investigation of supersonic oscillatory cavity flows driven by thick shear layers

Published online by Cambridge University Press:  04 July 2016

X. Zhang  and
J. A. Edwards
X. Zhang
Affiliation:
Department of Engineering, University of Cambridge
J. A. Edwards
Affiliation:
Department of Engineering, University of Cambridge
Get access Rights & Permissions [Opens in a new window]

Abstract

Flows around two-dimensional rectangular cavities driven by thick shear layers are investigated experimentally at two supersonic Mach numbers (Me = 1.5 and 2.5) to show the effects of variations in Mach number and length to depth ratio of the cavity. Flow oscillation is observed in the cavity. The characteristics of the oscillatory behaviour are determined by Mach number and the length of depth ratio of the cavity, as well as the shear layer spanning the cavity. Two oscillatory mechanisms can be identified: one in which a strong trailing-edge vortex and vortices which are shed from the leading-edge interact, the other in which a transverse oscillation of a single vortex occurs within the cavity. Changes in the time-dependent and the time-mean flow characteristics at different flow conditions are discussed.

The time-dependent experimental results are compared with existing theoretical analyses of the frequencies. For one of these characteristic types of oscillation, the longitudinal oscillation, an existing theoretical description is improved with a modified phase relation.

Type
Research Article
Information
The Aeronautical Journal , Volume 94 , Issue 940 , December 1990 , pp. 355 - 364
Copyright
Copyright © Royal Aeronautical Society 1990 

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.)

Footnotes

Now in the Department of Aeronautics and Astronautics, The University, Southampton

Now in the College of Aeronautics, Cranfield

References

1. Zhang, X., and Edwards, J. A. Computational analysis of unsteady supersonic cavity flows driven by thick shear layers. Aeronaut J, Nov 1988, 92, (919), pp 365374.Google Scholar
2. Zhang, X. An Experimental and Computational Investigation Into Supersonic Shear Layer Driven Single and Multiple Cavity Flowfields. PhD Thesis, Department of Engineering, University of Cambridge, 1987.Google Scholar
3. Rizzetta, D. P. Numerical simulation of supersonic flows over a three-dimensional cavity. AIAA J, July 1988, 26, (7), pp 799807.Google Scholar
4. Edwards, J. A. and Zhang, X. Some Aspects of Supersonic Flow over a Cavity Cascade. AIAA Paper 86-2025, 1986.Google Scholar
5. Zhang, X. and Edwards, J. A. An Experimental Investigation of Supersonic Flow over Two Cavities in Tandem. AIAA Paper 90-3087, 1990.Google Scholar
6. Heller, H. H., Holmes, G., and Covert, E. E. Flow Induced Pressure Oscillations in Shallow Cavities. AFFDL-TR-70-104, 1970.Google Scholar
7. Rossiter, J. E. Wind Tunnel Experiment on the Flow Over Rectangular Cavities at Subsonic and Transonic Speeds. ARC R&M 3438, 1964.Google Scholar
8. Tam, C. K. W. and Block, P. J. W. On the tones and pressure oscillations induced by flow over rectangular cavities. J FluidMech, 1978, 89, (2), pp 373399.Google Scholar
9. Krishnamurty, K. Acoustic Radiation From Two-Dimensional Cutout in Aerodynamic Surface. NACA TN 3487, 1955.Google Scholar
10. Plumblee, H. F., Gibson, G. S. and Lassiter, L. W. A Theoretical and Experimental Investigation of the Acoustic Response of Cavities in an Aerodynamic Flow. WADD-TR-61- 76, 1962.Google Scholar
11. Heller, H. H. and Bliss, D. B. Aerodynamically Induced Pressure Oscillations in Cavities - Physical Mechanism and Suppression Concepts. AFFDL-TR-74-33, 1974.Google Scholar
12. Rockwell, D. and Naudascker, E. Review of self-sustaining oscillations of flow past cavities. J Fluids Eng, June 1978, 100, pp 152165.Google Scholar
13. Rockwell, D. and Naudascker, E. Self-sustained oscillations of impinging free shear layers. Ann Rev Fluid Mech, 1979, 11, pp 6794.Google Scholar
14. Winter, K. G. and Gaudet, L. Turbulent Boundary-Layer Studies at High Reynolds Numbers at Mach Numbers Between 0·2 and 2.8.” ARC R&M 3712, 1970.Google Scholar
15. Newland, D. E. An Introduction to Random Vibration and Spectral Analysis. Langman, New York, 1984.Google Scholar
16. Edwards, J. A. Some Applications of the Temporal Properties of Holographic Interferometry. Aeroelastic Research Report ARR 90306, Rolls-Royce Pic, 1988.Google Scholar
17. Maull, D. J. and East, L. F. Three-dimensional flow in cavities. J Fluid Mech, 1963, 16, (4), pp 620632.Google Scholar
18. Petrie, H. L., Sammimy, M. and Addy, A. L. Compressible separated flow. AIAA J, Dec 1986, 24, (12), pp 19711978.Google Scholar
19. Charwat, A. F., Roos, J. N. and Hitz, J. A. An investigation of separated flows. Part I: The pressure field, Part II: Flow in the cavity and heat transfer. J Aerosp Sci, June/July 1961, 28, (6)/(7), pp 457470, 513-527.Google Scholar