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Nonlinear Aerothermoelastic Analysis of Functionally Graded Rectangular Plates Subjected to Hypersonic Airflow Loadings | ||
| AUT Journal of Mechanical Engineering | ||
| مقاله 8، دوره 2، شماره 2، اسفند 2018، صفحه 217-232 اصل مقاله (1.23 M) | ||
| نوع مقاله: Research Article | ||
| شناسه دیجیتال (DOI): 10.22060/ajme.2018.12712.5407 | ||
| نویسندگان | ||
| V. Khalafi1؛ H. Shahverdi* 2؛ S. Noori3 | ||
| 1Aerospace Research Institute, Tehran, Iran | ||
| 2Department of Aerospace Engineering, Amirkabir University of Technology, Tehran, Iran | ||
| 3Department of Mechanical Engineering, Amirkabir University of Technology, Tehran, Iran | ||
| چکیده | ||
| In this study, the aerothermoelastic behavior of functionally graded plates under hypersonic airflow is investigated. The classical plate theory based on both mid-surface and the neutral surface position is used to model the structural treatment. Also, Von Karman strain-displacement relations are utilized to involve the structural nonlinearity. To consider the applied hypersonic aerodynamic loads, nonlinear (third-order) piston theory is employed to model unsteady aerodynamic pressure in hypersonic flow regime. Material properties of the functionally graded panel is assumed to be temperature dependent and altered in the thickness direction according to a simple power law distribution. The generalized differential quadrature method is used to transfer the governing partial differential equation into an ordinary differential equation. The onset of flutter instability, the stability boundaries, and the time response analysis of a functionally graded plate are determined by applying the fourth order Runge-Kutta method. Moreover, the effect of some important parameters such as Mach number, in-plane thermal load, plate thickness ratio, and volume fraction index on the plate aerothermoelastic behavior is examined. Comparison of the obtained results with the available results in the literature confirms the accuracy and reliability of the proposed approach to analyzing aerothermoelastic behavior of functionally graded plates in hypersonic flow. | ||
| کلیدواژهها | ||
| Differential quadrature method؛ Aerothermoelastic؛ Functionally graded material؛ Hypersonic airflow | ||
| مراجع | ||
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[1] Y. Miyamoto, W.A. Kaysser, B.H. Rabin, A. Kawasaki, R.G. Ford, Functionally Graded Materials: Design, Processing and Applications, Kluwer Academic Publisher,Boston, MA, 1999. [2] J.C. Houbolt, A study of several aerothermoelastic problems of aircraft structures in high-speed flight, ETH Zurich, 1958. [3] V.V. Bolotin, Nonconservative problems of the theory of elastic stability, Macmillan, 1963. [4] E.H. Dowell, Nonlinear oscillations of a fluttering plate, AIAA Journal, 4(7) (1966) 1267–1275. [5] E.H. Dowell, Aeroelasticity of Plates and Shells, Noordhoff, in, Leyden, 1975. [6] H.G. Schaeffer, W. L. Heard, Flutter of a flat panel subjected to nonlinear temperature distribution, AIAA Journal, 30(10) (1965) 1918-1923. [7] S.G. Mcintosh, Theoretical considerations of some nonlinear aspects of hypersonic panel flutter, Final Report, NASA Grant NG, 05-020-102, Department of Aeronautics and Astronautics, Stanford University, Stanford, CA, 1970. [8] S.C. Mcintosh, Effect of hypersonic nonlinear aerodynamic loading on panel flutter, AIAA Journal, 11(1) (1973) 29-32. [9] F.E. Eastep, S.C. Mcintosh, Analysis of nonlinear panel flutter and response under random excitation or nonlinear aerodynamic loading, AIAA Journal, 9(3) (1971) 411-418. [10] D.Y. Xue, C. Mei, Finite element nonlinear panel flutter with arbitrary temperatures in supersonic flow, AIAA Journal, 31(1) (1993) 154–62. [11] D.Y. Xue, C. Mei, Finite element nonlinear flutter and fatigue life of two-dimensional panels with temperature effects, Journal of Aircraft, 30(6) (1993) 993-1000. [12] T. Bein, P. Friedmann, X. Zhong, I. Nydick, Hypersonic flutter of a curved shallow panel with aerodynamic heating, AIAA Journal, (1993) 93-1318 [13] G. Cheng, C. Mei, Finite Element Modal Formulation for Hypersonic Panel Flutter Analysis with Thermal Effects, AIAA Journal, 42(4) (2004) 687-695. [14] S.H. Pourtakdoust, S.A. Fazelzadeh, Nonlinear Aerothermoelastic Behavior of Skin Panel with Wall Shear Stress Effect, Journal of Thermal Stresses, 28 (2005) 147-169. [15] A.J. Culler, J.J. McNamara, Studies on fluid–thermal–structural coupling for aerothermoelasticity in hypersonic flow, AIAA Journal, 48(8) (2010) 1721-1738. [16] A.J. Culler, J.J. McNamara, Impact of fluid-thermal-structural coupling on response prediction of hypersonic skin panels, AIAA Journal, 49(11) (2011) 2393-2406. [17] P.Prakash, M. Ganapathi, Supersonic flutter characteristics of functionally graded flat panels Including thermal effects, Composite Structures, 13 (2006) 257-264. [18] H.-S. Shen, Thermal post-buckling behavior of shear deformable FGM plates with temperature-dependent properties, International Journal of Mechanical Sciences, 49(4) (2007) 466-478. [19] K.-J. Sohn, J.-H. Kim, Structural stability of functionally graded panels subjected to aero-thermal loads, Composite Structures, 82 (2008) 317-25. [20] K.-J. Sohn, J.-H. Kim, Nonlinear thermal flutter of functionally graded panels under a supersonic flow, Composite Structure, 88 (2009) 380-87. [21] S. A. Fazelzadeh, M. Hosseini, H. Madani, Thermal Divergence of Supersonic Functionally Graded Plates, Journal of Thermal Stresses, 34 (8) (2011) 759-777. [22] M. Hoseini, S. A. Fazelzadeh, P. Marzocca, Chaotic and Bifurcation Dynamic Behavior of Functionally Graded Curved Panels Under Aero-Thermal Loads, IJBC-D International Journal of Bifurcation and Chaos, 21 (2011) 931-954. [23] P. Marzocca, S.A. Fazelzadeh, M. Hosseini, A review of nonlinear aero-thermo-elasticity of functionally graded panels, Journal of Thermal Stresses, 34 (5 & 6) (2011) 536-568. [24] H.M. Navazi, H. Haddadpour, Nonlinear aero-thermoelastic analysis of homogeneous and functionally graded plates in supersonic airflow using coupled models, Composite Structures, 93 (2011) 2554-65. [25] A.H. Sofiyev, Buckling analysis of freely-supported functionally graded truncated conical shells under external pressures, Composite Structures, (132) (2015) 746-758. [26] A.H. Sofiyev, On the vibration and stability of shear deformable FGM truncated conical shells subjected to an axial load, Composites Part B Engineering, (80) (2015 ) 53-62. [27] M.R. Amoozgar, H. Shahverdi, Analysis of nonlinear fully intrinsic equations of geometrically exact beams using generalized differential quadrature method, Acta Mech, 227(5) (2016) 1265-1277. [28] R.E. Bellman, J. Casti, Differential quadrature and long-term integration, Journal of Mathematical Analysis and Applications, 34 (1971) 235-238. [29] C.W. Bert, S.K. Jang, A.G. Striz, Two new approximate methods for analyzing free vibration of structural components, AIAA Journal, 26 (1988) 612-618. [30] C.W. Bert, M. Malik, Differential quadrature in computational mechanics: a review, Applied mechanics reviews, 49 (1996) 1-27. [31] C.W. Bert, S.K. Jang, A.G. Striz, Nonlinear bending analysis of orthotropic rectangular plates by the method of differential quadrature, Computational Mechanics, 5 (1989) 217-226. [32] C. Shu, B.E. Richards, Application of generalized differential quadrature to solve two-dimensional incompressible Navier-Stoaks equations, International Journal for Numerical Methods in Fluids, 15 (1992) 791-798. [33] C. Shu, C.M. Wang, Treatment of mixed and non-uniform boundary conditions in GDQ vibration analysis of rectangular plate, Engineering structures, 21 (1999) 125-134. [34] S.A. Fazelzadeh, P. Malekzadeh, P. Zahedinejad, M. Hosseini, Vibration analysis of functionally graded thin-walled rotating blades under high-temperature supersonic gas flow using the DQM, Journal of Sound and Vibration, 306 (2007) 333–348. [35] F. Tornabene, A. Liverani, G. Caligiana, FGM and laminated doubly curved shells and panels of revolution with a free-form meridian: A 2-D GDQ solution for free vibrations, International Journal of Mechanical Sciences, 53( 6) (2011) 446-470. [36] F. Tornabene, N. Fantuzzi, M. Bacciocchi,The local GDQ method applied to general higher-order theories of doubly-curved laminated composite Shells and Panels: the Free Vibration Analysis, Composite Structures, 116(1) (2014) 637-660. [37] F. Tornabene, N. Fantuzzi, E. Viola, R.C. Batra, Stress and strain recovery for functionally graded free-form and doubly-curved sandwich shells using higher-order equivalent single layer theory, Composite Structures, 119(1) (2015) 67-89. [38] N. Fantuzzi, F. Tornabene, E. Viola, Four-parameter functionally graded cracked plates of arbitrary shape: A GDQFEM solution for free vibrations, Mechanics of Advanced Materials and Structures, 23 (2016) 89-107 [39] F. Tornabene, N. Fantuzzi, F. Ubertini, E. Viola, Strong formulation finite element method based on differential quadrature: A survey, Applied Mechanics Reviews, 67(2) (2015) 1-55. [40] H. Shahverdi, V. Khalafi, S. Noori, Aerothermoelastic analysis of functionally graded plates using generalized differential quadrature method, Latin American Journal of Solids and Structures, 13 (2016) 797-819 [41] H. Shahverdi, V. Khalafi, 2016. Bifurcation analysis of FG curved panels under simultaneous aerodynamic and thermal loads in hypersonic flow, Composite Structures, 146 (2016) 84-94. [42] B.A. Miller, J.J. McNamara, S.M. Spottswood, A.J. Culler, The impact of flow induced loads on snap-through behavior of acoustically excited, thermally buckled panels, Journal of Sound and Vibration, 330 (2011) 5736-5752. [43] D.-G. Zhang, Y.-H. Zhou, A theoretical analysis of FGM thin plates based on physical neutral surface, Computational Material Science, 44 (2008) 716-720. [44] D.-G. Zhang, Nonlinear bending analysis of FGM beams based on physical neutral surface and high order shear deformation theory, Composite Structures, 100 (2013) 121-126. [45] C. Shu, Differential Quadrature and It’s application in engineering, Springer-Verlag London Limited, London, 2000. [46] S. Tomasiello, Differential quadrature method: Application to Initial-Boundary-Value Problems, Journal of Sound and Vibration, 218(4) (1998) 573-585. | ||
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