During the second half of the 90 s, NASA performed experimental investigations on six novel thrust reverser (TR) designs; core-mounted target-type thrust reverser (CMTTTR) design is one of them. To assess the CMTTTR efficiency and performance, NASA conducted several wind tunnel tests at sea level static (SLS) conditions. The results from these experiments are used in this paper series to validate the computational fluid dynamics (CFD) results. This paper is part one of the three-part series. Parts 1 and 2 discuss the CMTTTR in stowed and deployed configurations; all analyses in the first two papers are performed at SLS conditions. Part 3 discusses the CMTTTR in the forward flight condition. The key objectives of this paper are: first, to perform the three-dimensional (3D) CFD analysis of the reverser in stowed configuration; all analyses are performed at SLS condition. The second objective is to validate the acquired CFD results against the experimental data provided by NASA (Scott, C. A., 1995, “Static Performance of Six Innovative Thrust Reverser Concepts for Subsonic Transport Applications: Summary of the NASA Langley Innovative Thrust Reverser Test Program,” NASA—Langley Research Centre, Hampton, VA, Report No. TM-2000-210300). The third objective is to verify the fan and overall engine net thrust values acquired from the aforementioned CFD analyses against those derived based on one-dimensional (1D) engine performance simulations. The fourth and final objective is to examine and discuss the overall flow physics associated with the CMTTTR under stowed configuration. To support the successful implementation of the overall investigation, full-scale 3D computer aided design (CAD) models are created, representing a fully integrated GE-90 engine, B777 wing, and pylon configuration. Overall, a good agreement is found between the CFD and test results; the difference between the two was less than 5%.
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September 2018
Research-Article
Computational Fluid Dynamics Investigation of a Core-Mounted Target-Type Thrust Reverser—Part 1: Reverser Stowed Configuration
Tashfeen Mahmood,
Tashfeen Mahmood
Defence Equipment and Services,
Ministry of Defence,
Bristol BS34 8JH, UK
e-mail: dr.tashfeenmahmood@gmail.com
Ministry of Defence,
Bristol BS34 8JH, UK
e-mail: dr.tashfeenmahmood@gmail.com
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Anthony Jackson,
Anthony Jackson
Centre for Propulsion Engineering,
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: a.j.b.jackson@cranfield.ac.uk
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: a.j.b.jackson@cranfield.ac.uk
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Vishal Sethi,
Vishal Sethi
Centre for Propulsion Engineering,
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: v.sethi@cranfield.ac.uk
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: v.sethi@cranfield.ac.uk
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Bidur Khanal,
Bidur Khanal
Centre for Defence Engineering,
Cranfield University,
Shrivenham SN6 8 LA, UK
e-mail: b.khanal@cranfield.ac.uk
Cranfield University,
Shrivenham SN6 8 LA, UK
e-mail: b.khanal@cranfield.ac.uk
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Fakhre Ali
Fakhre Ali
Applied Mechanics Department,
Chalmers University of Technology,
Hörsalsvägen 7A,
Göteborg 412-96, Sweden
e-mail: aeroali@yahoo.com
Chalmers University of Technology,
Hörsalsvägen 7A,
Göteborg 412-96, Sweden
e-mail: aeroali@yahoo.com
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Tashfeen Mahmood
Defence Equipment and Services,
Ministry of Defence,
Bristol BS34 8JH, UK
e-mail: dr.tashfeenmahmood@gmail.com
Ministry of Defence,
Bristol BS34 8JH, UK
e-mail: dr.tashfeenmahmood@gmail.com
Anthony Jackson
Centre for Propulsion Engineering,
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: a.j.b.jackson@cranfield.ac.uk
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: a.j.b.jackson@cranfield.ac.uk
Vishal Sethi
Centre for Propulsion Engineering,
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: v.sethi@cranfield.ac.uk
Cranfield University,
Bedfordshire MK43 0AL, UK
e-mail: v.sethi@cranfield.ac.uk
Bidur Khanal
Centre for Defence Engineering,
Cranfield University,
Shrivenham SN6 8 LA, UK
e-mail: b.khanal@cranfield.ac.uk
Cranfield University,
Shrivenham SN6 8 LA, UK
e-mail: b.khanal@cranfield.ac.uk
Fakhre Ali
Applied Mechanics Department,
Chalmers University of Technology,
Hörsalsvägen 7A,
Göteborg 412-96, Sweden
e-mail: aeroali@yahoo.com
Chalmers University of Technology,
Hörsalsvägen 7A,
Göteborg 412-96, Sweden
e-mail: aeroali@yahoo.com
Contributed by the Aircraft Engine Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received August 17, 2017; final manuscript received November 8, 2017; published online June 15, 2018. Editor: David Wisler.
J. Eng. Gas Turbines Power. Sep 2018, 140(9): 091204 (8 pages)
Published Online: June 15, 2018
Article history
Received:
August 17, 2017
Revised:
November 8, 2017
Citation
Mahmood, T., Jackson, A., Sethi, V., Khanal, B., and Ali, F. (June 15, 2018). "Computational Fluid Dynamics Investigation of a Core-Mounted Target-Type Thrust Reverser—Part 1: Reverser Stowed Configuration." ASME. J. Eng. Gas Turbines Power. September 2018; 140(9): 091204. https://doi.org/10.1115/1.4038816
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