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Design of a turbulent wing for small aircraft using multidisciplinary optimisation

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Design process of a turbulent wing for small aircraft, using multidisciplinary and multi-objective optimisation, based on a genetic algorithm was presented. A generic parametric model of small aircraft wing geometry was developed. In the model, a wide class of wing geometries, with and without high lift devices, was described by a relatively small number of parameters. The optimisation method used the objectives and constraints typical for multidisciplinary wing design, and was applied to the design and optimisation of turbulent wing dedicated for small, two-propeller aircraft. The research was conducted within European Project CESAR. The results of the research have been discussed.
Rocznik
Strony
185--201
Opis fizyczny
Bibliogr. 17 poz., rys. kolor.
Twórcy
autor
  • Instutut Lotnictwa (Institute of Aviation) Aleja Krakowska 110/114 02-256 Warszawa, Poland
autor
  • Instutut Lotnictwa (Institute of Aviation) Aleja Krakowska 110/114 02-256 Warszawa, Poland
Bibliografia
  • 1. C. Nae, V.M. Pricop, Report on base model definition full a/c AC-1 and AC-2, CESAR Deliverable Report No. D1.1.1-1, 2006.
  • 2. W. Stalewski, Parametric Modelling of Aerodynamic Objects - The Key to Successful Design and Optimisation, Proceedings of The International Conference of the European Aerospace Societies Congress, 24-28 October 2011, Venice, Italy.
  • 3. J. Rokicki, W. Stalewski, J. Żółtak, Multidisciplinary Optimisation Of Forward-Swept Wing, in Evolutionary Methods for Design, Optimization and Control, T. Burczynski and J. Périaux [eds.], c CIMNE, Barcelona, Spain, 2009.
  • 4. W. Stalewski, J. Żółtak, Multi-objective and Multidisciplinary Optimization of Wing for Small Aircraft, Proceedings of The International Conference of the European Aerospace Societies Congress, 24–28 October 2011, Venice, Italy.
  • 5. S. Wakayama, I. Kroo, Subsonic wing planform design using multidisciplinary optimisation, Journal of Aircraft, 32, No 4, 1995.
  • 6. S. Obayashi, S. Jeong, K. Chiba, H. Morino, Multi-objective design exploration and its application to regional-jet wing design, Transaction of Japan Society Aero. Space Scientist, 50, No. 167, 1–8, 2007.
  • 7. A. Oyama, Multidisciplinary optimization of transonic wing design based on evolutionary algorithms coupled with CFD solver, Proceedings of ECCOMAS 2000, Barcelona, September 2000.
  • 8. D. Sasaki, S. Obayashi, K. Sawada, R. Himero, Euler/Navier–Stokes optimization of supersonic wing design based on evolutionary algorithm, IAA Journal, 37, 10, 1327–1328, 1999.
  • 9. Y.Y.A. Ko, The multi-disciplinary design optimization of a distributed propulsion blended wing body aircraft, PhD Thesis, Virginia Polytechnic Institute and State University, 2003.
  • 10. E. Kesseler, W.J. Vankan, Multidisciplinary design analysis and multiobjective optimisation applied to aircraft wing, NLT Report TP-2006-748.
  • 11. K. Leoviriyakit, Wing Planform Optimization Via An Adjoint Method, Ph.D. Dissertation, Stanford University, March 2005.
  • 12. W. Stalewski, Numerical optimisation of rotorcraft airfoils based on genetic algorithm and unsteady aerodynamic criteria, Transactions of the Institute of Aviation, 184–185, Warsaw, 2006.
  • 13. J. Sznajder, W. Stalewski, Application of a panel method with viscous-inviscid interaction for determination of aerodynamic characteristics of CESAR baseline aircraft, Transactions of the Institute of Aviation, 207, 2010.
  • 14. Z. Ancik, Report on wing design objectives AC1, turbulent wing, CESAR Deliverable Report No. D1.2.2-3, 2007.
  • 15. Z.Wysocki, W. Kania, A. Suchożebrska, W. Stalewski, J. Żółtak, Airfoil Design and Analysis AC1, Turbulent AFT,HLT, in: CESAR Deliverable Report D1.2.1-09, 2007.
  • 16. W. Stalewski, J. Żółtak, Wing Design and Analysis Report AC1, Turbulent Wing, AFT, HLT, in CESAR Deliverable Report No. D1.2.2-7, 2009.
  • 17. J. Sznajder, Determination of non-linear aerodynamic characteristics of an aircraft using a potential flow model and viscous airfoil characteristics, Transactions of the Institute of Aviation, 207, 2010.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ecd7b0b6-9c04-4847-9f34-aed71404ce9a
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