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Simulating the evacuation of a commercial airliner

Published online by Cambridge University Press:  04 July 2016

C. R. Robbins
Affiliation:
Department of Mathematics, University of Strathclyde Glasgow, Scotland
S. McKee
Affiliation:
Department of Mathematics, University of Strathclyde Glasgow, Scotland

Abstract

The discrete element method is modified so as to simulate the movement of passengers evacuating an aircraft. The results display reasonable agreement with timed trials. However, by focusing on the 1985 Manchester air disaster where only some of the exits could be opened and only then a considerable time after landing, it is argued that the certification procedures are inadequate.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2001 

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References

1. Owen, M., Galea, E.R., LAwrence, P.J. and Filippidis, L. The numerical simulation of aircraft evacuation and its application to aircraft design certification, Aeronaut J, June/July 1998, 102, (1016), pp 301312.Google Scholar
2. Thompson, P.A. and Marchant, E.W. Computer and fluid modelling of evacuation, Safety Science, 1995, 18, pp 277389.Google Scholar
3. Robbins, C.R. Discrete element Simulation and its Applications, 1999, PhD Thesis, University of Strathclyde.Google Scholar
4. Ashford, R. Air safety regulation and its commercial impact, The Aeronaut J, March 1991, 95, (943), pp 7787.Google Scholar
5. Muir, H.C. Research into the factors influencing survival in aircraft accidents, Aeronaut J, May 1996, 100, (995), pp 177181.Google Scholar
6. Air Accidents Investigation Branch Report on the accident to Boeing 737-236 Series 1 G-BGJL at Manchester International Airport on 22 August 1985, Aircraft accident report 8/88, 1988, Department of Transport, HMSO, London.Google Scholar
7. Langston, P.A., Tuzun, U. and Hayes, D.M. Discrete element simulation of granular flow in 2D and 3D hoppers: dependence of discharge rate and wall stress on particle interactions, Chem Eng Science, 1995, 50, (6), pp 967987.Google Scholar
8. Ristow, G.H. Simulating granular flow with molecular dynamics, J de Physique 1, 1992, 2, pp 649662.Google Scholar
9. Schafer, J., Dippel, P. and Wolf, D.E. Force schemes in simulations of granular materials, J de Physique 1, 1996, 6, pp 520.Google Scholar
10. Cantor, D. Fires and Human Behaviour, 1980, John Wiley and Sons.Google Scholar