Hostname: page-component-848d4c4894-75dct Total loading time: 0 Render date: 2024-05-14T20:32:34.423Z Has data issue: false hasContentIssue false
  • English
  • Français

On the effect of stage length on the efficiency of air transport

Published online by Cambridge University Press:  27 January 2016

D. I. A. Poll
D. I. A. Poll*
Affiliation:
Cranfield University, Cranfield, Bedfordshire, UK
*
d.i.a.poll@cranfield.ac.uk
Get access Rights & Permissions [Opens in a new window]

Abstract

It is generally recognised that fuel can be saved on long haul routes if non-stop flights are broken down into a number of short stages. As fuel costs rise, these savings may eventually become economically attractive to airlines. ‘Staging’ may also play a role in the reduction of aviation’s impact upon climate change. To allow an accurate estimate of the potential benefits, an analytic model has been developed from first principles, with closure provided by data from existing aircraft. The analysis captures the relevant parameters and their influence is quantified. It has been found that significant savings are only available for distances greater than about 5,500km and a stop at the halfway point is either the best, or close to the best, strategy. For the longest routes, optimal staging with existing long range aircraft can give savings of up to 12%. However, if aircraft optimised for the stage lengths are used, this may be increased to up to 28% and, if the floor area per passenger is reduced to the short haul level, a limiting value of about 45% may be possible. The aircraft design passenger number and, provided it is constant, the load factor have little, or no, effect upon the percentage savings. Maximum use of staging on all current routes longer than 5,500km could reduce the total fuel consumed by between 3% and 20%, with a consequent reduction in global fleet annual fuel burn of between 1% and 6%. However, the savings for a given route are reduced as aircraft become more efficient.

Type
Research Article
Information
The Aeronautical Journal , Volume 115 , Issue 1167 , May 2011 , pp. 273 - 283
Copyright
Copyright © Royal Aeronautical Society 2011 

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. Green, J.E. Greener by Design – the technology challenge, Aeronaut J, February 2002, 106, (1056), pp 57113.Google Scholar
2. Green, J.E. Küchemann’s weight model as applied in the Greener by Design Technology Sub Group Report: a correction, adaptation and commentary, Aeronaut J, August 2006, 110, (1110), pp 511516.Google Scholar
3. Nangia, R.K. Efficiency parameters for modern commercial aircraft, Aeronaut J, August 2006, 110, (1110), pp 495510.Google Scholar
4. Hahn, A.S. Staging Airliner Service, AIAA-2007-7759, 7th AIAA Aviation Technology, Integration and Operations Conference (ATIO), Belfast, Northern Ireland, UK, 18-20 September 2007.Google Scholar
5. Creemers, W.L.H. and Slingerland, R. Impact of intermediate stops on long-range jet-transport design, AIAA-2007-7849, 7th AIAA Aviation Technology, Integration and Operations Conference (ATIO), Belfast, Northern Ireland, UK, 18-20 September 2007.Google Scholar
6. Langhans, S., Linke, F., Nolte, P and Schnieder, H. System analysis for future long range operation concepts. 27th ICAS Congress, Nice, France, 2010.Google Scholar
7. Martinez-Val, R., Perez, E., Cuerno, C. and Palacin, J.F. Cost-range trade-off in the design and operation of long range transport airplanes. 27th ICAS Congress, Nice, France, 2010.Google Scholar
8. Kenway, G.K.W., Henderson, R., Hicken, J.E., Kuntawala, N.B., Zingg, D.W., Martins, J.R.R.A. and McKeand, R.G. Reducing aviation’s environmental impact through large aircraft for short ranges. AIAA 2010-1015, 48th AIAA Aerospace Sciences Meeting, Orlando, Florida, US, 4-7 January 2010.Google Scholar
9. Poll, D.I.A. The optimum aeroplane and beyond, Aeronaut J, March 2009, 113, (1141), pp 151164.Google Scholar
10. Shevell, R.S. Fundamentals of Flight (2nd Ed), Prentice Hall, 1989, ISBN 0-13-339060-8.Google Scholar
11. Jenkinson, L.R., Simpkin, P. and Rhodes, D. Civil Jet Aircraft Design, Arnold, 1999, ISBN 0 340 74152 X.Google Scholar
12. Poll, D.I.A. A first order method for the determination of the leading mass characteristics of civil transport, Aeronaut J, May 2011, 115, (1166), pp xxxx.Google Scholar
13. Eyers, C., Norman, P., Middel, J., Plohr, M., Michot, S., Atkinson, K. and Christou, R. 2004: AERO2k global aviation emissions inventories for 2002 and 2025. Technical report, QinetiQ Ltd., Farnborough, UK, qinetiq/04/01113.Google Scholar