THERMAL BUCKLING ANALYSIS OF FUNCTIONALLY GRADED CIRCULAR PLATE RESTING ON THE PASTERNAK ELASTIC FOUNDATION VIA THE DIFFERENTIAL TRANSFORM METHOD

Fatemeh Farhatnia, Mahsa Ghanbari-Mobarakeh, Saeid Rasouli-Jazi, Soheil Oveissi

DOI Number
10.22190/FUME170104004F
First page
545
Last page
563

Abstract


In this paper, we propose a thermal buckling analysis of a functionally graded (FG) circular plate exhibiting polar orthotropic characteristics and resting on the Pasternak elastic foundation. The plate is assumed to be exposed to two kinds of thermal loads, namely, uniform temperature rise and linear temperature rise through thickness. The FG properties are assumed to vary continuously in the direction of thickness according to the simple power law model in terms of the volume fraction of two constituents. The governing equilibrium equations in buckling are based on the Von-Karman nonlinearity. To obtain the critical buckling temperature, we exploit a semi-numerical technique called differential transform method (DTM). This method provides fast accurate results and has a short computational calculation compared with the Taylor expansion method. Furthermore, some numerical examples are provided to consider the influence of various parameters such as volume fraction index, thickness-to-radius ratio, elastic foundation stiffness, modulus ratio of orthotropic materials and influence of boundary conditions. In order to predict the critical buckling temperature, it is observed that the critical temperature can be easily adjusted by appropriate variation of elastic foundation parameters and gradient index of FG material. Finally, the numerical results are compared with those available in the literature to confirm the accuracy and reliability of the DTM to determine the critical buckling temperature.


Keywords

Thermal Buckling, Orthotropic Plate, Functionally Graded Materials (FGM), Pasternak Elastic Foundation, Differential Transform Method (DTM)

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References


Dewey, B.R, Costello, G.A., 1968, Thermal buckling of nonhomogeneous plates, Nuclear Engineering and Design, 7(3), pp. 249-261.

Najafizadeh, M.M., Eslami, M.R., 2002, First-order-theory-based thermoelastic stability of functionally graded material circular plate, AIAA J, 40(7), pp.1444–1450.

Najafizadeh, M.M., Eslami, M.M., 2002 Thermoelastic stability of orthotropic circular plates, Journal of Thermal Stresses, 25(10), pp. 985-1005.

Li, S.R., Zhou, Y.H., Song, X., 2002, Non-linear vibration and thermal buckling of an orthotropic annular plate with a centric rigid mass, Journal of Sound and Vibration, 251(1), pp. 141-152.

Najafizadeh, M.M., Heydari, H.R., 2004, Thermal buckling of functionally graded circular plates based on higher order shear deformation plate theory, European Journal of Mechanics A/Solids., 23, pp. 1085–1100.

Prakash, T., Ganapathi, M., 2006, Asymmetric flexural vibration and thermoelastic stability of FGM circular plates using finite element method, Composites: Part B. Engineering, 37(7–8), pp.642–649.

Zhao, X., Lee, K.M., Liew, K.M., 2009, Mechanical and thermal buckling analysis of functionally graded plates, Composite Structure, 90(2), pp.161-17.

Zenkour, A.M., Sobhy, M., 2010, Thermal buckling of various types of FGM sandwich plates, Composite Structure, 93(1), pp. 93-102.

Jalali, S.K, Naei, M.H., Poorsolhjouy, A., 2010, Thermal stability analysis of circular functionally graded sandwich plates of variable thickness using pseudo-spectral method, Mater. Des., 31(10), pp.4755–63.

Kiani, Y., Eslami, M.R., 2013, An exact solution for thermal buckling of annular FGM plates on an elastic medium, Composites Part B: Engineering, 45(1), pp.101-110.

Jabbari, M., Hashemitaheri, M., Mojahedin, M.R., 2014, Thermal Buckling Analysis of Functionally Graded Thin Circular Plate Made of Saturated Porous Materials, Journal of Thermal Stresses, 37(2), pp. 202-220.

Yaghoobi, H., Fereidooni, A., 2014, Mechanical and thermal buckling analysis of functionally graded plates resting on elastic foundations: An assessment of a simple refined nth-order shear deformation theory, Composites Part B: Engineering, 62, pp. 11-26.

Mansouri, M.H., Shariyat, M., 2014, Thermal buckling predictions of three types of high-order theories for the heterogeneous orthotropic plates, using the new version of DQM, Composite Structure, 113, pp. 40-55.

Mirzaei, M., Kiani, Y., 2016, Thermal buckling of temperature-dependent FG-CNT-reinforced composite plates, Meccanica, 51(9), pp. 2185–2201

Yu, T., Bui, T.Q., Yin, S., Doan, D.H., Wu, C.T., Do, T.V., Tanaka, S., 2016, On the thermal buckling analysis of functionally graded plates with internal defects using extended isogeometric analysis, Composite Structures, 136, pp. 684–695.

Tung, H.V., 2015, Thermal and thermomechanical post-buckling of FGM sandwich plates resting on elastic foundations with tangential edge constraints and temperature-dependent properties, Composite Structures, 131(1), pp. 1028–1039.

Sun, Y., Li, S.R., Batra, R.C., 2016, Thermal buckling and post-buckling of FG Timoshenko beams on nonlinear elastic foundation, Journal of Thermal Stresses, 39(1), pp. 11-26.

Attarinejad, R., Semnani, Sh.J., Shahba, A., 2006, Basic displacement functions for free vibration analysis of non-prismatic Timoshenko beams, Journal of Finite Elements in Analysis and Design, 46 (10), pp. 916–929.

Ozdemir, O., Kaya, M.O., 2006, Flap wise bending vibration analysis of a rotating tapered cantilever Bernoulli–Euler beam by differential transform method, Journal of Sound and Vibration, 289, pp. 413–420.

Yalcin, H.S., Arikoglu, A., Ozkol, I., 2009, Free vibration analysis of circular plates by differential transformation method, Computational and Applied Mathematics, 212, pp.377–386.

Yeh, Y.L., Wang, C.C., Jang, M.J., 2007, Using finite difference and differential transformation method to analyze of large deflections of orthotropic rectangular plate problem, Applied Mathematics and Computation, 190(2), pp.1146-1156.

Abbasi, S., Farhatnia, F., Jazi, S. R., 2013, Application of Differential Transformation Method (DTM) for bending Analysis of Functionally Graded Circular Plates, Caspian Journal of Applied Sciences Research, 2(4), pp. 17-23.

Abbasi, S., Farhatnia, F., Jazi, S.R., 2014, A semi-analytical solution on static analysis of circular plate exposed to non-uniform axisymmetric transverse loading resting on Winkler elastic foundation, Archives of Civil and Mechanical engineering, 14, pp. 476-488.

Lai, R., Ahlawat, N., 2015, Axisymmetric vibrations and buckling analysis of functionally graded circular plates via differential transform method, European Journal of Mechanics A/Solids, 52, pp. 85-94.

Ghiasian, SE., Kiani, Y., Sadighi, M., Eslami, M.R., 2014, Thermal buckling of shear deformable temperature dependent circular/annular FGM plates, International journal of Mechanical Sciences, 81, pp.137-148.

Li, S., Zhang, J., Zhao, Y., 2007, Nonlinear thermomechanical post-buckling of circular FGM plate with geometric imperfection, Thin-Walled Structures, 45(5), pp. 528-536.




DOI: https://doi.org/10.22190/FUME170104004F

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