Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-26T07:29:04.107Z Has data issue: false hasContentIssue false

Experimental and numerical investigation of confined unsteady supersonic flow over cavities

Published online by Cambridge University Press:  12 October 2016

T. K. G. Anavaradham
Affiliation:
Defence Research and Development Laboratory, India
B. U. Chandra
Affiliation:
Indian Institute of Technology, Madras, India
V. Babu
Affiliation:
Indian Institute of Technology, Madras, India
S. R. Chakravarthy
Affiliation:
Indian Institute of Technology, Madras, India
S. Panneerselvam
Affiliation:
Defence Research and Development Laboratory, India

Abstract

Experimental investigations were carried out to study the acoustic radiation from a rectangular wall mounted cavity in a confined supersonic flow. The free-stream Mach number was maintained at 1·5 and the cavity length-to-depth ratio was varied from 0·43 to 5·0. Acoustic measurements made on the top wall show jumps in the dominant frequency as the cavity behaviour changes from shallow-to-square-to-deep cavity. Numerical simulations of this unsteady two-dimensional flow using the commercially available software FLUENT have also been carried out. Unsteady pressure data at the same location in the flow field as the pressure transducers in the experiments was collected. FFT analysis of the unsteady pressure data was performed to obtain the dominant acoustic frequencies. The values for these dominant frequencies predicted by the numerical calculations agree well with experimental data. The numerical study also predicts the frequency jump observed in experiments.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2004 

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. Seiner, J.M., Dash, S.M. and Kenzakowski, D.C. Historical survey on enhanced mixing in scramjet engines, 1999, AIAA paper 99-4869.Google Scholar
2. Pimshtein, V.G. Disturbance generation in supersonic jets under acoustic excitation, AIAA J, 1994, 32, (7), pp 13451349.Google Scholar
3. Glass, D.K. Effects of acoustic feedback on the spread and decay of supersonic jets, AIAA J, 1968, 6, (10), pp 18901897.Google Scholar
4. Sato, N., Imamura, R., Shiba, S., Takahashi, S., Tsue, M. and Kono, M. Advanced mixing control in a supersonic airstream with a wallmounted cavity, 1996, AIAA paper 96-4510-CP.Google Scholar
5. Yu, K.H., Wilson, K.J., Smith, R.A. and Schadow, K.C. Experimental investigation on dual-purpose cavity in supersonic reacting flows, 1998, AIAA paper 98-0723.Google Scholar
6. Yu, K.H. and Schadow, K.C. Cavity-actuated supersonic mixing and combustion control, Combustion and Flame, 1994, 99, (2), pp 295301.Google Scholar
7. Yu, K.H., Wilson, K.J. and Schadow, K.C. On the use of combustor wall cavities for mixing enhancement, 1999, Third ASME/JSME Joint Fluids Engineering Conference, FEDSM 99-7255.Google Scholar
8. Mathur, T., Streby, G., Gruber, M., Jackson, K., Donbar, J., Donaldson, W., Jackson, T., Smith, C. and Billig, F. Supersonic combustion experiments with a cavity-based fuel injector, 1999, AIAA paper 99-2102.Google Scholar
9. Ben–Yakar, A. and Hanson, R.K. Cavity flame-holders for ignition and flame stabilisation in scramjets: Review and Experimental Study, 1998, AIAA paper 98-3122.Google Scholar
10. Vinogradov, V.A., Kobigsky, S.A. and Petrov, M.D. Experimental investigation of kerosene fuel combustion in supersonic flow, J Propulsion and Power, 1995, 11, (1), pp 130134.Google Scholar
11. Gruber, M., Jackson, K., Mathur, T. and Billig, F. Experiments with a cavity–based fuel injector for scramjet applications, 1999, Paper 99-7154, 14th International Symposium on Air Breathing Engines, Florence, Italy.Google Scholar
12. Rockwell, D. and Naudauscher, E. Review – Self-sustaining oscillations of flow past cavities, J Fluids Eng, 1978, 100, (6), pp 152165.Google Scholar
13. Rockwell, D. Oscillations of impinging shear layers, AIAA J, 1983, 21, (5), pp 645664.Google Scholar
14. Krishnamurthy, K. Acoustic radiation from two-dimensional rectangular cut-outs in aerodynamic surfaces, 1955, NACA TN 3487.Google Scholar
15. Rossiter, J.E. Wind-tunnel experiments on the flow over rectangular cavities at subsonic and transonic speeds, 1966, ARC R&M 3438.Google Scholar
16. East, L.F. Aerodynamically induced resonance in rectangular cavities, J Sound and Vibration, 1966, 3, (3), pp 277287.Google Scholar
17. Plumblee, H.E., Gibson, J.S. and Lassiter, L.W. A theoretical and experimental investigation of the acoustic response of cavities in aerodynamic flow, 1962, WADD-TR-61-75.Google Scholar
18. Tam, C.K.W. and Block, P.J. W. On the tones and pressure oscillations induced by flow over rectangular cavities, J Fluid Mech, 1978, 89, (2), pp 373399.Google Scholar
19. Heller, H.H., Holmes, D.G. and Covert, E.E. Flow-induced pressure oscillations in shallow cavities, J Sound and Vibration, 1971, 18, (4), pp 545553.Google Scholar
20. Covert, E.E. An approximate calculation of the onset velocity of cavity oscillations, AIAA J, 1970, 8, (12), pp 21892194.Google Scholar
21. Tam, C.K.W. The acoustic modes of a two-dimensional rectangular cavity, J Sound and Vibrations, 1976, 49, (3), pp 353364.Google Scholar
22. Zhang, X. and Edwards, J.A. An investigation of supersonic oscillatory cavity flows driven by thick shear layers, Aeronaut J, December 1990, 94, (940), pp 355365.Google Scholar
23. Zhang, X. and Edwards, J.A. Experimental investigation of supersonic flow over two cavities in tandem, AIAA J, 1992, 30, (5), pp 11821190.Google Scholar
24. Zhang, X. Compressible cavity flow oscillation due to shear layer instabilities and pressure feedback, AIAA J, 1995, 33, (8), pp 14041411.Google Scholar
25. Baurle, R.A., Tam, C.J., and Dasgupta, S. Analysis of unsteady cavity flows for scramjet applications, 2000, AIAA paper 2000-3617.Google Scholar
26. Rizzetta, D.P. Numerical simulation of supersonic flow over a threedimensional cavity, AIAA J, 1988, 26, (7), pp 799807.Google Scholar
27. Zhang, X. and Edwards, J.A. Analysis of unsteady supersonic cavity flow employing an adaptive meshing refinement algorithm, Computers and Fluids, 1996, 25, (4), pp 373393.Google Scholar
28. Lamp, A.M. and Chokani, N. Computation of cavity flows with suppression using jet blowing, J Aircr, 1997, 34, (4), pp 545551.Google Scholar
29. Arunajatesan, S. and Sinha, N. Unsteady RANS-LES simulations of cavity flowfields, 2001, AIAA paper 2001-0516.Google Scholar
30. Rizzetta, D.P. and Visbal, M.R. Large-eddy simulation of supersonic cavity flowfields including flow control, AIAA J, 2003, 41, (8), pp 14521462.Google Scholar
31. Baurle, R.A., Tam, C.-J., Edwards, J.R., and Hassan, H.A. Hybrid simulation approach for cavity flows: blending, algorithm, and boundary treatment issues, AIAA J, 41, (8), pp 14631480.Google Scholar