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Flight investigations of the effect of yaw on the intake and fan nozzle flow of a natural laminar flow nacelle

Published online by Cambridge University Press:  04 July 2016

H. Riedel
Affiliation:
DLR, Institute for Design Aerodynamics, Braunschweig, Germany
M. Sitzmann
Affiliation:
DLR, Institute for Design Aerodynamics, Braunschweig, Germany

Abstract

Two major technologies in aeronautics promise substantial improvements in the fields of economy and ecology. One is laminar flow technology and the other arises from new developments related to aircraft turbofan engines. The trend in turbofan engine development is towards engines possessing higher bypass ratios. This, however, entails larger engine dimensions, leading not only to an increase in the skin friction drag but also to negative engine-airframe interactions. As a consequence, the need for laminar flow nacelles becomes all the more important as part of the general process of engine-air-frame integration optimisation for advanced transport aircraft.

This paper deals with some results obtained from flight tests with a laminar flow nacelle demonstrator and specifically addresses the topic of aerodynamics of intakes and nozzles. The results described relate to a European collaborative programme in which a natural laminar flow (NLF) nacelle was flight tested. Results of the effect of the angle of yaw on the static pressure distribution on the fan cowl including the intake of an NLF nacelle are presented for the maximum cruise flight condition. At zero yaw, a comparison of Euler calculations with flight test data is made. Measured flow variables of the fan nozzle flow directly downstream of the fan nozzle exit, exemplified by the Mach number and the flow density distributions, are also presented for the condition of maximum cruise.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 1997 

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References

1. Horstmann, K.H., Redeker, G., Quast, A., Drebler, U. and Bieler, H. Flight tests with a natural laminar flow glove on a transport aircraft, AIAA CP 907, 1990.Google Scholar
2. Shipley, P.P., Birch, N.T., Riedel, H., Horstmann, K.H. and Lücking, P. A European collaborative NLF nacelle flight demonstrator, Paper 92-01-005, First European Forum on Laminar Flow Technology, Hamburg, 1992.Google Scholar
3. Barry, B., Parke, S.J., Riedel, H. and Sitzmann, M. The flight testing of natural and hybrid laminar flow nacelles, Paper 94-GT-408, International Gas Turbine and Aeroengine Congress and Exposition of the ASME, The Hague, 1994.Google Scholar
4. Riedel, H., Ronzheimer, A. and Sitzmann, M. Comparison of Euler calculations with flight measurements of the static pressure distribution on a natural laminar flow nacelle. DLR-Mitteilung 96-01, 14-1 to 14-17, 1996.Google Scholar
5. Ronzheimer, A., Rudnik, R., Brodersen, O. and Rossow, C.-C. Interference phenomena of upper-wing-mounted engines, DLR-Mitteilung 96-01, 12-1 to 12-14, 1996.Google Scholar