Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-22T10:15:51.106Z Has data issue: false hasContentIssue false

Planning for super safety: the fail-safe dimension

Published online by Cambridge University Press:  04 July 2016

R. W. Howard*
Affiliation:
GEC Avionics, Rochester, UK

Abstract

It has long been a requirement in air transport that no single failure can have a catastrophic effect. As nothing can ever be failure free, fail-safety in design and operation must be provided in all respects.

This paper explores the design background, application and history of the concept of fail-safety in air transport and the vital role it plays in overall safety. It is suggested that fail-safety is the most important discipline of all those involved in safety in design and operations. Without it, the current air transport safety levels, even using the latest technologies, would not be possible.

In the modern air transport system, all accidents are due either to fail-safety implementations breaking down, or not having been adequately provided, or due to extremely remote multiple coincident failures. It can be argued that inadequacies in fail-safety provisions at the very low target failure rates now demanded, is the main reason for the near constancy of the accident rate, and the consequent increase in numbers of accidents as the world fleet grows. In the forefront of fail-safety problems is the inadequacy of its use in the management operations of crew in the modern air transport cockpit.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2000 

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. Howard, R.W. Breaking through the 106 barrier, Aero J, Aug/Sept 1992, 96, (957), pp 260270.Google Scholar
2. Tye, W. Civil airworthiness, JRAeS, Jan 1966, 70, (661), pp 253257.Google Scholar
3. Boeing Commercial Airplane Group. Statistical summary of commercial jet aircraft accidents, 1991 annual reports.Google Scholar
4. ICAO statistics. Flight Int. 25-31 Jan 2000, p 58.Google Scholar
5. Caidin, M. Boeing 707, Ballantine Books. New York, p 5.Google Scholar
6. Howard, R.W. Automatic flight control in fixed wing aircraft - the first 100 years, AeroJ, Nov 1973, 77, (755) p 537.Google Scholar
7. JCS. Automatic stability, Flight, 2 March 1912, p 191.Google Scholar
8. Doutre speed maintainer, Flight, 15 March 1913, p 315.Google Scholar
9. Wright flying machine stabiliser. Improvements in or connected with flying machines, 6 Feb 1909, UK patent 2913.Google Scholar
10. Arnold, H.H. Global Missions, 1951, Hutchinson, p 40.Google Scholar
11. Howard, R.W. 100 years of automatic flight control, Ibid, p 539.Google Scholar
12. Hughes, T.P. Elmer Sperry, Inventor and Engineer, John Hopkins University Press, 1971, pp 181200.Google Scholar
13. Penrose, H. Test flying during the century, JRAeS, Jan 1966, 70, (661), p 189.Google Scholar
14. Stephens, A.V. Some British contributions to aerodynamics, JRAeS, Jan 1966, 70, p 75.Google Scholar
15. Phillips, E.H. Upset training geared to real world not books, Aviation Week, 12 June, 2000, pp 4446.Google Scholar
16. The first Paris aeronautical salon, Flight, 2 Jan 1909, pp 89.Google Scholar
17. Langley, M. The history of metal aircraft construction, AeroJ, Jan 1971, 75, (721), p 19.Google Scholar
18. Rolls-Royce Heritage Trust. Letter from Colin Green to author, 27 April 2000.Google Scholar
19. Lumsden, A. British Piston Aero Engines and their Aircraft, Airlife Publishing, Shrewsbury, 1994.Google Scholar
20. Davies, R.E.G. Fallacies and Fantasies of Air Transport History, Taladurr Press, McLean, Virginia, 1994, pp 113: The Il'ya Muromets (1913–1922).Google Scholar
21. Rabinowitz, H. Classic Airplanes: Pioneering Aircraft and the Visionaries Who Built Them, Metro Books, 1997, Michael Friedman Publishing Groups, Chapter 6: The Sikorsky Ilya-Mouromet (USSR), pp 3739.Google Scholar
22. Cobham, A. Blazing the trail, JRAeS, Jan 1966, 70, (661), p 268.Google Scholar
23. Cross, R. Great Aircraft and their Pilots, Hugh Evelyn, London, 1971, p 59.Google Scholar
24. Robertson, F.A. deV. Aircraft of the World, Humphrey Milford, Oxford University Press, 1924, Notes for Plate 111.Google Scholar
25. Wings - Vol 2, Orbis Publishing, London & Colourgraph, Leicester, 1980, p 384.Google Scholar
26. Taylor, J.W.R. & Munson, K. Air Transport Before the Second World War, New English Library, 1975, p 41.Google Scholar
27. Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Putnam, London, 1973, p 225.Google Scholar
28. Munson, K. Airliners from 1919 to the Present Day, Peerage Books, 1982, pp 107108.Google Scholar
29. Baker, D. An HP V/1500 mission into Afghanistan, 1918, Aeroplane, Feb 2000, pp 7478.Google Scholar
30. Gibbs-Smith, C.H. Aviation, HMSO, London, 1970, p 176.Google Scholar
31. Munson, K. Airliners from. 1919 to the Present Day, Ibid, p 108.Google Scholar
32. Munson, K. Airliners from 1919 to the Present Day, Ibid, p 100 & pp 110111.Google Scholar
33. Robertson, F.A. deV. Aircraft of the World, Ibid, p 34.Google Scholar
34. Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Ibid, p 232.Google Scholar
35. Munson, K. Airliners from 1919 to the Present Day, Ibid, p 112.Google Scholar
36. Munson, K. Airliners from 1919 to the Present Day, Ibid, p 101 and Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Ibid, pp 404405.Google Scholar
37. Munson, K. Airliners from 1919 to the Present Day, Ibid, pp 110-111 & Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Ibid, p 233.Google Scholar
38. Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Ibid, pp 234235.Google Scholar
39. Jackson, A.J. British Civil Aircraft since 1919 - Vol 1. Ibid, pp 4951.Google Scholar
40. Jackson, A.J. British Civil Aircraft since 1919 - Vol 2, Ibid, pp 100102.Google Scholar
41. The Handley Page type 42, Flight, 28 Nov 1930, pp 1, 3811, 385.Google Scholar
42. Munson, K. Airliners from 1919 to the Present Day, Ibid, p 116.Google Scholar
43. Howard, R.W. The use of redundancy in aircraft flying control systems. Society of Instrument Technology symposium, Session C, 14 Feb 1964.Google Scholar
44. Tye, W. The outlook on airframe fatigue, AeroJ, May 1955, 59, (533), pp 339348.Google Scholar
45. McBrearty, J.F. Fail-safe airframe design, Flight, 6 April 1956, pp 394397.Google Scholar
46. Webber, G.W. Safe automatic landing for the airlines - the Vickers approach on the VC10 family, SAE, NY, Meeting 435A, Los Angeles, 9–13 Oct 1961, pp 910.Google Scholar
47. Howard, R.W. and Bishop, G.S. The development of reliability in airborne electronic equipment with some reference to the VC10 automatic landing system, RAeS/IEE Joint Conference, Session 3- Paper2, Feb 1962.Google Scholar
48. Neal, M. VC10: Vickers-Arm strongs’ long-range jet airliner, Flight Int, 10 May 1962, pp 728742.Google Scholar
49. Howard, R.W. 100 years of automatic flight control, Ibid, p 554 and Webber, G.W. Safe automatic landing for the airlines - the Vickers approach on the VC10 family, Ibid, p 9.Google Scholar
50. Howard, R.W. Concepts of redundancy for all weather landing, Iata Technical Conference, Lucerne, April 1963, Agenda Item 3.3, pp 1620 Google Scholar
51. Howard, R.W. The practical design and testing of the automatic monitoring system in the VC10, Second International R&D Symposium, All Weather Landing Systems, Technical Paper 1, Session 1, FAA, Atlantic City, New Jersey, 16–18 Sept 1963, pp 112.Google Scholar
52. Howard, R.W. and Bishop, G.S. A consideration of equipment reliability requirements for automatic landing systems, Air Registration Board Committee on landing and take-off aids. Document ARB-LTA-19 March 1960 (Public Records Office, Kew).Google Scholar
53. Howard, R.W. 100 years of automatic flight control, Ibid, p 556.Google Scholar
54. Howard, R.W. 100 years of automatic flight control, Ibid, pp 559560.Google Scholar
55. Hills, A.D. The primary flight computer for the Boeing 777- a description, GEC-Marconi Avionics, GEC Review, 11, (1), 1996.Google Scholar
56. Howard, R.W. and Wolfe, B.S. Revolutionary electronic development, Elliott evolve ‘integral redundancy’, Flight Int, 18 Oct 1962, p 655.Google Scholar
57. Calvert, B. Flying Concorde, St Martins Press, 1982.Google Scholar
58. Howard, R.W. Analysing pilot error, Aerosp Int, Oct 1997, 24, (10), pp 2830.Google Scholar
59. Hawkins, F.H. Human Factors in Flight, Gower Technical Press, 1987, p 45.Google Scholar
60. Braithwaite, G.R., Caves, R.E. and Faulkner, J.P.E., A systematic investigation into Australian aviation safety, ICAS-98-1 .9.1, p 6.Google Scholar
61. Lloyd, E. and Tye, W. Systematic safety: safety assessment of aircraft systems, Civil Aviation Authority, London, July 1982.Google Scholar
62. Howard, R.W. Progress in the use of automatic flight controls in safety critical applications, AeroJ, Oct 1980, 84, (837), pp 316326.Google Scholar
63. Human factors team report on the interfaces between flight crews and modern flight deck systems, Federal Aviation Administration, 18 June 1996.Google Scholar