Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-02T20:35:22.247Z Has data issue: false hasContentIssue false
  • English
  • Français

Intake ground vortex and computational modelling of foreign object ingestion

Published online by Cambridge University Press:  27 January 2016

D.G. MacManus  and
M. Slaby
D.G. MacManus*
Affiliation:
Propulsion Engineering Centre, School of Aerospace, Transport and Manufacturing, Cranfield University, UK
M. Slaby
Affiliation:
Propulsion Engineering Centre, School of Aerospace, Transport and Manufacturing, Cranfield University, UK
*
[email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

When an aero-engine is operating on the ground the formation of a potent inlet ground vortex can arise which has the ability to ingest foreign object debris. The ingestion of foreign objects can cause notable damage to engine components as well as overall performance degradation. The assessment of foreign object ingestion has been conducted using a combination of computational fluid dynamics, analytical modelling and an Euler-Lagrange uncoupled discrete phase particle tracking method. The flow fields for a full-scale aero-engine have been simulated for a range of ground clearances and intake velocity ratios under crosswind conditions. The sensitivity of the debris ingestion thresholds and characteristics to particle size and material density has been evaluated. The characteristics of the ingestion location within the intake are also considered for a range of operating conditions and particle parameters.

Type
Research Article
Information
The Aeronautical Journal , Volume 119 , Issue 1219 , September 2015 , pp. 1123 - 1145
Copyright
Copyright © Royal Aeronautical Society 2015

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.McCreary, I.The Economic Cost of FOD to Airlines, 2008, Insight SRI.Google Scholar
2. Information Paper On French Study On Automatic Fod Detection Systems, 2008, Eurocontrol, Workshop.Google Scholar
3.Brix, S., Neuwerth, G. and Jacob, D. The inlet-vortex system of jet engines operating near the ground, August 2000, AIAA Paper 2000-3998.Google Scholar
4.De Siervi, F., Viguier, H., Greitzer, E. and Tan, C.Mechanisms of inlet vortex formation, J Fluid Mechanics, 1982, 124, pp 173207.Google Scholar
5.Liu, W., Greitzer, E. and Tan, C.Surface static pressures in an inlet vortex flow field, J Engineering for Gas Turbines and Power, 1985, 107, pp 387393.Google Scholar
6.Shin, H., Cheng, W., Greitzer, E. and Tan, C.Inlet vortex formation due to ambient vorticity intensi-fcation, J American Institute of Aeronautics and Astronautics, 1986, 24, (4), pp 687689.Google Scholar
7.Shin, H., Greitzer, E., Cheng, W., Tan, C. and Shippee, C.Circulation measurements and vertical structure in an inlet vortex flow field, J Fluid Mechanics, 1986, 162, pp 463487.Google Scholar
8.Murphy, J. and MacManus, D.Ground vortex aerodynamics under crosswind conditions, Experiments in Fluids, January 2011, 50, pp 109124.Google Scholar
9.Murphy, J. and MacManus, D.Inlet ground vortex aerodynamics under headwind conditions, Aerospace Science and Technology, 2011, 15, pp 207215.CrossRefGoogle Scholar
10.Murphy, J., MacManus, D. and Taylor, M. A quantitative study of intake ground vortices, September 2007, ISABE Paper 2007-1209.Google Scholar
11.Zantopp, S., MacManus, D. and Murphy, J.Computational and experimental study of intake ground vortices, Aeronaut J, December 2010, 114, pp 769784.Google Scholar
12.Mishra, N., Macmanus, D. and Murphy, J.Intake ground vortex characteristics, J Aerospace Eng, 2012, 226, pp 13871400, Proceedings of the Institution of Mechanical Engineers Part G.Google Scholar
13.Jermy, M. and Ho, W.Location of the vortex formation threshold at suction inlets near ground planes by computational fuid dynamics simulation, J Aerospace Eng, 2008, 222, pp 393402, Proceedings of the Institution of Mechanical Engineers Part G.Google Scholar
14.Smith, T. and Cox, P. Debris ingestion by ground vortex into air intake having low ground clearance, August 1969, Rolls-Royce, No IAR 00009.Google Scholar
15.Murphy, J.Intake Ground Vortex Aerodynamics, PhD thesis, 2008, Cranfeld University, UK.Google Scholar
16.Gerhold, M. and Bore, C. Experimental and theoretical investigation into ingestion of debris into air intakes by vortex action, 1984, British Aerospace report, BAe-KGT-R-GEN-01309.Google Scholar
17.Glenny, D.Ingestion of debris into intakes by vortex action, 1968, Ministry of Technology, Aeronautical Research Council, CP No 1114.Google Scholar
18.Ridder, S. and Samuelsson, I.An experimental study of strength and existence domain of ground-to-air inlet vortices by ground board static pressure measurements, 1982, Royal Institute of Technology Report KTH AERO TN 62.Google Scholar
19.Yadlin, Y. and Shmilovich, A. Simulation of vortex fows for airplanes in ground operations, 2006, AIAA Paper 2006-56.Google Scholar
20.Rodert, L. and Garrett, F. Ingestion of foreign objects into turbine engine by vortices, 1955, National Advisory Committee for Aeronautics, NACA TN 3330.Google Scholar
21. Advisory Circular: Measurement, Construction and Maintenance of Skid-Resistant Airport Pavement Surfaces, 1997, US Department of Transportation No 150/5320-12C.Google Scholar
22. Best practices for the mitigation and control of foreign object damage-induced high cycle fatigue in gas turbine engine compression system airfoils, 2005, NATO Science and Technology Organization, Report RTO-TR-AVT-094.Google Scholar
23. Advisory Circular: Debris hazards at civil airports, 1996, US Department of Transportation No 150/5380-5B.Google Scholar
24.Hoxey, R. and Richards, P.Flow patterns and pressure feld around a full-scale building, J Wind Engineering and Industrial Aerodynamics, 1993, 50, pp 203212.CrossRefGoogle Scholar
25.Hanses, F.Surface roughness length, August 1993, US Army Research Laboratory Report ARL-TR-61.Google Scholar
26.Maxey, M. and Riley, J.Equation of motion for a small rigid sphere in a nonuniform flow, Physics of Fluids, 1983, 26, pp 883889.Google Scholar
27.Clift, R., Grace, J. and Weber, M.Bubbles, Drops, and Particles, 1978, Academic Press, London, UK.Google Scholar