Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-19T03:52:19.774Z Has data issue: false hasContentIssue false
  • English
  • Français

Analysis of radiometric, lifetime and fluorescent lifetime imaging for pressure sensitive paint

Published online by Cambridge University Press:  04 July 2016

J. W. Holmes
J. W. Holmes*
Affiliation:
Defence Evaluation and Research Agency (Dera) Bedford, UK
Get access Rights & Permissions [Opens in a new window]

Abstract

Optical pressure measurement using fluorescent techniques is being widely researched for use in windtunnels. The technique offers global coverage of model surface pressures. A paint, the fluorescence of which is dependent on air pressure, is applied to the surface of a windtunnel model and the pressure distribution is obtained from the intensities measured. There are three principle techniques used to produce the surface pressure distributions: radiometric imaging, lifetime measurement and fluorescent lifetime imaging.

Radiometric imaging produces global images. A constant illumination is used to excite the paint. The fluorescent intensity distribution is dependent on the surface pressure. Error analysis reveals that the technique has the highest precision at low absolute pressures. However, wind-off reference images are required to compensate for illumination and paint non-uniformity. Experimental investigation found that although this is able to compensate for rigid structures, model movement introduces registration and geometric errors. These errors can be corrected by processing at the expense of accuracy.

Lifetime measurement is a technique that uses pulsed illumination. The fluorescent lifetime is dependent on the pressure. A wind-off reference image is not required and error analysis predicts that the technique holds an advantage at high absolute pressures.

Fluorescent lifetime imaging produces global images using a modulated light source to excite the paint. The phase and modulation depth of the fluorescent signal are proportional to the pressure. A wind-off reference image is not required and error analysis predicts that the technique has the same advantages as lifetime imaging. Preliminary results from fluorescent lifetime imaging indicate that this technique can be implemented using robust, solid-state technology.

Type
Research Article
Information
The Aeronautical Journal , Volume 102 , Issue 1014 , April 1998 , pp. 189 - 194
Copyright
Copyright © Royal Aeronautical Society 1998 

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. Dowgwillo, R.M. el al The application of the pressure sensitive paint technique to high speed windtunnel testing of a fighter aircraft configuration with complex store loadings, AIAA Paper 94-1932, June 1994.Google Scholar
2. Kavandi, J. Luminescent barometry in windtunnels. Rev Sci Inst, Nov 1990, 61, (11).Google Scholar
3. Engler, R.H. et at Description and assessment of a new optical pressure measurement system (OPMS) demonstrated in the high speed windtunnel of DLR in Gotlingen, DLR Paper FB-92-24, ISBN 0939-2963, 1992.Google Scholar
4. Sellers, ME. and Brill, J.A. Demonstration test of pressure sensitive paint in the AEDC 16 ft transonic windtunnel using the TST model, AIAA Paper 94-2481, June 1994.Google Scholar
5. Stern, V.O. and Volmer, M. liber aie abklingungszeit der fluoreszenz, Physik Zeicher XX, 1919.Google Scholar
6. Donovan, J.F. et al Data analysis techniques for pressure and temperature sensitive paint, AIAA Paper 93-0176, January 1993.Google Scholar
7. Davies, A.G., Bedwell, D., Dunleavy, M. and Brownjohn, N. Recent developments in pressure sensitive paint measurements using the BAe system. Proceedings of CEAS Windtunnel and Windtunnel Test Techniques conference, 14-16 April 1997, Cambridge, UK. 28.1-28.11.Google Scholar
8. Wolfbeis, O.S. Fibre optical fluorosensors in analytical and clinical chemistry, Chem Anal, 1988, 77, Chapter 3.Google Scholar
9. Lakowicz, J.R. el al Fluorescent lifetime imaging, Analytical Biochemistry, 1992, 202, pp 316330.Google Scholar
10. Morgan, C.G. Measurement of luminescence, US Patent 5, 459, 323, October 1995.Google Scholar
11. Oglesby, D.M., Puram, C.K. and Upchurch, B.T. Optimisation of measurements with pressure sensitive paints. NASA TM 4695, June 1995.Google Scholar
12. Holmes, J.W. The relevance of pressure sensitive paint to aerodynamic research, J Fluorescence, 1993, 3, (3).Google Scholar
13. Morris, M.J. et alAerodynamic applications of pressure sensitive paint, AIAA Paper 92-0264, January 1992.Google Scholar