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Impacts of low-pressure (LP) compressor’s deterioration of a turbofan engine upon fuel-usage of a military aircraft

Published online by Cambridge University Press:  03 February 2016

M. Naeem
M. Naeem*
Affiliation:
College of Aeronautical Engineering (CAE), National University of Sciences & Technology (NUST), Tamiz-ud-din Road, Rawalpindi, Pakistan
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Abstract

Some in-service deterioration in any mechanical device, such as an aircraft’s gas-turbine engine, is inevitable. However, its extent and rate depend upon the qualities of design and manufacture, as well as on the maintenance/repair practices followed by the users. Deterioration of an engine normally results in the engine seeking a different steady operating-point relative to that for an engine without any deterioration. The variation in engine’s steady operating point leads to changes in the specific fuel consumption (SFC) and/or fuel flow (FF). Any rise in SFC and/or FF and thereby the increased quantity of fuel required is of prime importance in military aviation.

For a military aircraft’s mission-profiles (consisting of several flight-segments), using a bespoke computer simulations, the consequences of low-pressure compressor’s deterioration of an aeroengine upon the weight of the fuel that has to be carried and consumed are predicted. This will help in making wiser management decisions (such as whether to remove an aero-engine from the aircraft for maintenance or to continue using it with some changes in aircraft’s mission profile). Hence improved engine utilization can be achieved, so resulting in lower overall life-cycle costs.

Type
Research Article
Information
The Aeronautical Journal , Volume 112 , Issue 1127 , January 2008 , pp. 33 - 45
Copyright
Copyright © Royal Aeronautical Society 2008 

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References

1. Devereux, B. and Singh, R., Use of computer simulation techniques to assess thrust rating as a means of reducing turbo-jet life cycle costs. International Gas-Turbine and Aero Engine Congress and Exposition, The Hague, Netherlands, 1316 June 1994.Google Scholar
2. Naeem, M., Fuel Usage and its Effects on Operational Performance for GE-F404/F-18. MSc Thesis, 1994, Cranfield University, UK.Google Scholar
3. Stevenson, J.D. and Saravanamuttoo, H.I.H., Effects of cycle choice and deterioration on thrust indicators for civil engine. ISABE 95-7077, Twelfth International Symposium on Air-Breathing Engines, Melbourne, Australia, 10-15 September 1995.Google Scholar
4. Naeem, M., Singh, R., and Probert, D., Impacts of aero-engine deteriorations on military aircraft mission’s effectiveness, Aeronaut J, December 2001, 105, (1054), pp 685695.Google Scholar
5. Naeem, M., Implications of Engine Deterioration for a Military Aircraft’s Performance. PhD Thesis, Cranfield University, UK, 1999.Google Scholar
6. Heywood, J.B., Future engine-technology: lessons from the 1980s for the 1990s. J Engineering for Gas Turbines and Power, 1991, 113, pp 319330.Google Scholar
7. Seddigh, F. and Saravanamuttoo, H.I.H., A proposed method for assessing the susceptibility of axial compressors to fouling, J Engineering for Gas Turbines and Power, 1991, 113, pp 595601.Google Scholar
8. Diakunchak, I.S., Performance deterioration in industrial gas-turbines, J Engineering for Gas Turbines and Power, 1992, 114, pp 161168.Google Scholar
9. Dunn, M.G., Padova, C., Moller, J.E. and Adams, R.M., Performance deteriorations of a turbofan and a turbojet engine upon exposure to a dust environment. ASME 87-GT-111, February 1987.Google Scholar
10. Grewal, M.S., Gas-Turbine Engine Performance Deterioration Modelling and Analysis. PhD Thesis, 1988, Cranfield University, UK.Google Scholar
11. Acker, G.F. and Saravanamuttoo, H.I.H., Predicting a gas-turbine’s performance-degradation due to compressor fouling using computer simulation techniques. J Engineering for Gas Turbines and Power, 1989, 111, pp 343350.Google Scholar
12. Saravanamuttoo, H.I.H. and Lakshminarasimha, A.N., A preliminary assessment of compressor fouling. ASME 85-GT-153, March 1985.Google Scholar
13. Sallee, G.P., Kruckenberg, H.D. and Toomy, E.H., Analysis of turbofan-engine performance deterioration and proposed follow-on test. NASA-CR-134769, October 1986.Google Scholar
14. Palmer, J.R., The TURBOMATCH scheme for gas-turbine performance calculations: user’s guide. Cranfield University, UK, 1983.Google Scholar
15. Sallee, G.P., Performance deterioration based on existing (historical) data. NASA-CR-135448, May 1980.Google Scholar
16. Jolly, R.B., Ogaji, S.O.T., Singh, R. and Probert, S.D., Gas-turbine diagnostics using artificial neural-networks for a high bypass ratio military turbofan engine, 2004, Applied Energy, 78, (4), pp 397418.Google Scholar
17. Naeem, M., Impacts of low-pressure (LP) compressor’s deterioration upon an aero-engine’s high-pressure (HP) turbine blade’s life consumption. Aeronaut J, April 2006, 110, (1106), pp 227238.Google Scholar