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Efficiency parameters for modern commercial aircraft

Published online by Cambridge University Press:  03 February 2016

R. K. Nangia*
Affiliation:
Bristol, UK

Abstract

Currently, there is great emphasis, worldwide, on environmental issues. This will have an impact on civil aircraft design, manufacture and operation.

Since the advent of the jet engine and swept wing aircraft, the trends have naturally tended towards greater productivity through increasing speed and payload. The cruise speed of conventional civil aircraft is unlikely to increase beyond current levels. Further increases in productivity are achieved by increasing payloads. This has led towards larger aircraft with the capability for increased ranges. It is shown that designing aircraft for longer ranges increases fuel burn significantly.

A series of aircraft operational parameters have been analysed. Selected data and established trends for current and future aircraft are presented. The data has been interpreted into efficiency terms, relating payload, range, fuel consumed and a measure of unit costs. It is shown that ‘value’ (cost) and noise effective efficiencies decrease dramatically with increasing range.

Environmental and economic considerations, in the future, may well demand greater efficiency in preference to productivity. One solution for long-range services is to use short-range hops. Another is via air-to-air refuelling. This will be addressed, in more detail, in a future paper.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2006 

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References

1. Dollyhigh, S.M. and Coen, P.G., Advanced technology and unconventional aircraft concepts, Unconventional Aircraft Concepts, 1987, Delft University Press.Google Scholar
2. McMasters, J.H. and Cummings, R.M., Airplane design — Past, present and future. J Aircr, January-February 2002, AIAA.10.2514/2.2919Google Scholar
3. Green, J.E., Greener by Design — the Technology Challenge, Aeronaut J, February 2002, 106, (1056), Erratum, 109, (1092), February 2005.Google Scholar
4. Green, J.E., Air travel — Greener by Design, mitigating the environmental impact of aviation: opportunities & priorities, Aeronaut J September 2005, 109, (1099).Google Scholar
5. Fielding, J.P., Introduction to Aircraft Design, 1999, Cambridge University Press.Google Scholar
6. Jenkinson, L.R., Simpkin, P. and Rhodes, D., Civil Jet Aircraft Design, 1999, Arnold.Google Scholar
7. Whitford, R., Fundamentals of airliner design, Air International, July 2003.Google Scholar
8. Aerospace Source Book, Aviation Week & Space Technology, McGraw-Hill.Google Scholar
9. Flight International, Reed Business Information.Google Scholar
10. Green, J.E., Küchemann’s weight model as applied in the first Greener by Design Technology Sub Group Report: a correction, adaptation and commentary, Aeronaut J, August 2006, 110, (1110).Google Scholar