About Communications       Author's Guide       Reviewers       Editorial Members       Archive
Archive
Volume 8
2021
Volume 7
2020
Volume 6
2019
Volume 5
2018
Volume 4
2017
Volume 3
2016
Volume 2
2015
Volume 1
2014
AASCIT Communications | Volume 2, Issue 4 | Jun. 19, 2015 online | Page:144-151
Airplane Wing Flutter Boundary Optimization Using Coupled Solver Simulations
Abstract
In the cruising flight regime, an aircraft wing experiences severe aerodynamic forces from all directions and above the critical speeds it initializes the flutter. Flutter phenomenon is a catastrophic one that leads to temporal (or) permanent failure of airplane structural components. To delay the flutter speed boundary or occurrences, a variety of methods have been suggested by many aeroelasticians in the past few decades. This article involves in the flutter boundary optimization using coupled solver simulations especially bending-torsion flutter. Coupling is produced by combining the Computational Fluid Dynamics (CFD) solutions and Computational Structural Dynamics (CSD) solutions with the help of a system coupling through FEA procedure. Initially, it is used to predict the flutter speed of conventional airplane wing configuration and then the analysis is extended to optimize the flutter speed through various material based properties. In specific, the relation among stresses produced on the wing is considered and it is customized to reduce the forced vibration frequency for expanding the flutter boundary. Then, the wing model is aerodynamically optimized with the help of force computations, frequencies and material properties. Numerical results are presented and verified with theoretical calculations to prove the feasibility of present methodology. This iterative design process can be revised again and again until the flutter speed boundary is converged to the optimum velocities.
Authors
[1]
J. Bruce Ralphin Rose, Department of Aeronautical Engineering, Regional centre of Anna University, Tirunelveli, India.
[2]
R. Allocious Britto Rajkumar, Department of Aeronautical Engineering, Regional centre of Anna University, Tirunelveli, India.
Keywords
Flutter Speed, Finite Element Analysis, Computational Fluid Dynamics, CFD-CSD Coupling, Numerical Discretization
Reference
[1]
Philippe Geuzaine, Gregory Brown, Chuck Harris, and Charbel Farhat. “Aeroelastic Dynamic Analysis of a Full F-16 Configuration for Various Flight Conditions”. AIAA JOURNAL Vol. 41, No. 3, March 2003
[2]
XIE ChangChuan, LIU Yi & YANG Chao , “Theoretic analysis and experiment on aeroelasticity of very flexible wing”, science china journal(2012), Vol.55 No.9: 2489–2500
[3]
Jinwu Xiang, Yongju Yan, Daochun Li, Recent advance in nonlinear aeroelastic analysis and control of the aircraft, Chinese Journal of Aeronautics, Volume 27, Issue 1, February 2014, Pages 12–22
[4]
R. M. Bennet and J.W. Edwards, “An overview of recent developments in computational aeroelasticity”, Proceedings of the 29th AIAA Fluid Dynamics Conference, 1998.
[5]
Giulio Romanelli , Tommaso Solcia , “Design and verification of flutter suppression control systems by multidisciplinary co-simulations”, 28th International congress of the aeronautical sciences,2012.
[6]
M. R. Waszak, “Modeling the benchmark active control technology wind tunnel model for application to flutter suppression”, AIAA Technical Paper 3437, 1996.
[7]
Kwan-Hwa Byun, Seung-Moon Jun,”Flutter analysis of f-16 aircraft utilizing test modal data”, 25th International congress of the aeronautical sciences.2006.
[8]
K.H.Byun, C.Y.Park, J.H Kim. Ground Vibration Test on KF-16D. Journal of KSASS, Vol. 33, No.5, pp41-49, 2005.
[9]
Yamaguchi N, Sekiguchi T, Yokota K, and Tsujimoto Y. “Flutter limits and behavior of a flexible thin sheet in high-speed flow—I: analytical method for prediction of the sheet behavior”. ASME Journal of Fluids Engineering. Vol. No. 122, pp 65–73, 2000.
[10]
Shubov MA, ‘On fluttering modes for aircraft wing model in subsonic air flow’. Proc Math Phys Eng Sci. 2014 Dec 8;470(2172):20140582.
[11]
Watanabe Y, Isogai K, Suzuki S, and Sugihara M.”A theoretical study of paper flutter”, Journal of Fluids and Structures. Vol. No. 16 (4), pp 543–560, 2002.
[12]
Watanabe Y, Suzuki S, Sugihara M, and Sueoka Y. “An experimental study of paper flutter”, Journal of Fluids and Structures. Vol No. 16 (4), pp 529–542, 2002.
[13]
Arvind Deivasigamani, Jesse McCarthy, Simon Watkins, Sabu John, Floreana Coman,”Flow-induced flutter of slender cantilever high-compliance plates”, 28th International congress of the aeronautical sciences, 2012.
[14]
Bisplinghoff, R.L., Ashley, H. and Halfman, H., Aeroelasticity. Dover Science, 1996, ISBN 0-486-69189-6, pgs 604-632;
[15]
Tuzcu, I. and Nguyen, N. (2014). "Flutter of Maneuvering Aircraft", J. Aerosp. Eng, ASCE.1943-5525
[16]
Luke, Yudell L., and Dengler, Max A. Tables of the Theodorsen Function for Generalized Motion. J. Aero. Science, 18, p. 478, 1951.
[17]
Rose, JBR and Jinu, GR ‘Influence of aeroelastic control reversal problem in the airplane lateral stability modes’. Proc IMechE Part G: J Aerospace Engineering, Vol. 229, No. 3, pp. 517-533, 2015.
Arcticle History
Submitted: May 13, 2015
Accepted: May 28, 2015
Published: Jun. 19, 2015
The American Association for Science and Technology (AASCIT) is a not-for-profit association
of scientists from all over the world dedicated to advancing the knowledge of science and technology and its related disciplines, fostering the interchange of ideas and information among investigators.
©Copyright 2013 -- 2019 American Association for Science and Technology. All Rights Reserved.