This paper presents the development of an integrated approach which targets the aerodynamic design of separate-jet exhaust systems for future gas-turbine aero-engines. The proposed framework comprises a series of fundamental modeling theories which are applicable to engine performance simulation, parametric geometry definition, viscous/compressible flow solution, and design space exploration (DSE). A mathematical method has been developed based on class-shape transformation (CST) functions for the geometric design of axisymmetric engines with separate-jet exhausts. Design is carried out based on a set of standard nozzle design parameters along with the flow capacities established from zero-dimensional (0D) cycle analysis. The developed approach has been coupled with an automatic mesh generation and a Reynolds averaged Navier–Stokes (RANS) flow-field solution method, thus forming a complete aerodynamic design tool for separate-jet exhaust systems. The employed aerodynamic method has initially been validated against experimental measurements conducted on a small-scale turbine powered simulator (TPS) nacelle. The developed tool has been subsequently coupled with a comprehensive DSE method based on Latin-hypercube sampling. The overall framework has been deployed to investigate the design space of two civil aero-engines with separate-jet exhausts, representative of current and future architectures, respectively. The inter-relationship between the exhaust systems' thrust and discharge coefficients has been thoroughly quantified. The dominant design variables that affect the aerodynamic performance of both investigated exhaust systems have been determined. A comparative evaluation has been carried out between the optimum exhaust design subdomains established for each engine. The proposed method enables the aerodynamic design of separate-jet exhaust systems for a designated engine cycle, using only a limited set of intuitive design variables. Furthermore, it enables the quantification and correlation of the aerodynamic behavior of separate-jet exhaust systems for designated civil aero-engine architectures. Therefore, it constitutes an enabling technology toward the identification of the fundamental aerodynamic mechanisms that govern the exhaust system performance for a user-specified engine cycle.
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August 2016
Research-Article
Aerodynamic Design of Separate-Jet Exhausts for Future Civil Aero-engines—Part I: Parametric Geometry Definition and Computational Fluid Dynamics Approach
Ioannis Goulos,
Ioannis Goulos
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: i.goulos@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: i.goulos@cranfield.ac.uk
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Tomasz Stankowski,
Tomasz Stankowski
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: t.stankowski@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: t.stankowski@cranfield.ac.uk
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John Otter,
John Otter
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: j.j.otter@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: j.j.otter@cranfield.ac.uk
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David MacManus,
David MacManus
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: D.G.Macmanus@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: D.G.Macmanus@cranfield.ac.uk
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Nicholas Grech,
Nicholas Grech
Installation Aerodynamics,
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Nicholas.Grech@Rolls-Royce.com
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Nicholas.Grech@Rolls-Royce.com
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Christopher Sheaf
Christopher Sheaf
Installation Aerodynamics,
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Christopher.Sheaf@Rolls-Royce.com
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Christopher.Sheaf@Rolls-Royce.com
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Ioannis Goulos
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: i.goulos@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: i.goulos@cranfield.ac.uk
Tomasz Stankowski
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: t.stankowski@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: t.stankowski@cranfield.ac.uk
John Otter
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: j.j.otter@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: j.j.otter@cranfield.ac.uk
David MacManus
Propulsion Engineering Centre,
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: D.G.Macmanus@cranfield.ac.uk
Cranfield University,
Bedfordshire, MK430AL, UK
e-mail: D.G.Macmanus@cranfield.ac.uk
Nicholas Grech
Installation Aerodynamics,
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Nicholas.Grech@Rolls-Royce.com
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Nicholas.Grech@Rolls-Royce.com
Christopher Sheaf
Installation Aerodynamics,
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Christopher.Sheaf@Rolls-Royce.com
Rolls-Royce plc,
Trent Hall 2.2, SinA-17,
Derby DE24 8BJ, UK
e-mail: Christopher.Sheaf@Rolls-Royce.com
Contributed by the Aircraft Engine Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received November 22, 2015; final manuscript received December 18, 2015; published online March 15, 2016. Editor: David Wisler.
J. Eng. Gas Turbines Power. Aug 2016, 138(8): 081201 (14 pages)
Published Online: March 15, 2016
Article history
Received:
November 22, 2015
Revised:
December 18, 2015
Citation
Goulos, I., Stankowski, T., Otter, J., MacManus, D., Grech, N., and Sheaf, C. (March 15, 2016). "Aerodynamic Design of Separate-Jet Exhausts for Future Civil Aero-engines—Part I: Parametric Geometry Definition and Computational Fluid Dynamics Approach." ASME. J. Eng. Gas Turbines Power. August 2016; 138(8): 081201. https://doi.org/10.1115/1.4032649
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