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Abstract

In this contribution, the 3D thermomechanical behavior of functionally graded plates subjected to transverse thermal loads is investigated by means of a series of 2D finite plate elements. In the framework of the Unified Formulation developed by Carrera (2003), the governing equations for both the heat conduction problem and the resulting thermomechanical bending problem are derived within the principle of virtual work. The order of the axiomatically assumed thickness functions is explicitly chosen independently for the thermal and the mechanical problem, respectively. Upon introduction of the thickness functions, the problem is reduced to 2D and solved by means of the finite element method. The locally varying, effective material properties are approximated by mean field estimates, e.g., the Mori—Tanaka scheme. A numerical assessment of the developed models is given. In particular, the influence of the order of the assumed thickness functions is analyzed. It will be shown that higher order assumptions are mandatory for accurate results in comparison with 3D solutions available in the literature.

Keywords

unified formulation principle of virtual work functionally graded materials finite element method refined models thermal load.

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References

Benveniste, Y. 1987. ‘‘A New Approach to the Application of Mori-Tanaka’s Theory in Composite Materials,’’ Mechanics of Materials, 6:147-157.

Bhaskar, K. , Varadan, T. and Ali, J. 1996. ‘‘Thermoelastic Solution for Orthotropic and Anisotropic Composite Laminates,’’ Composites Part B: Engineering, 27:415-420.

Birman, V. and Byrd, L. 2007. ‘‘Modeling and Analysis of Functionally Graded Materials and Structures,’’ Applied Mechanics Reviews, 60:195-215.

Brischetto, S. and Carrera, E. 2008. ‘‘Advanced Mixed Theories for Bending Analysis of Functionally Graded Plates,’’ Computers and Structures, (in press).

Brischetto, S. , Leetsch, R. , Carrera, E. , Wallmersperger, T. and Kröplin, B. 2008. ‘‘Thermo-mechanical Bending of Functionally Graded Plates,’’ Journal of Thermal Stresses, 31(3):286-308.

Carrera, E. 2003. ‘‘Theories and Finite Elements for Multilayered Plates and Shells: A Unified Compact Formulation with Numerical Assessment and Benchmarking,’’ Archives of Computational Methods in Engineering, 10(3):215-296.

Carrera, E. , Brischetto, S. and Robaldo, A. 2008. ‘‘Variable Kinematic Model for the Analysis of Functionally Graded Material Plates,’’ AIAA Journal, 46(1):194-203.

Cheng, Z.-Q. and Batra, R. 2000. ‘‘Three-dimensional Thermoelastic Deformations of a Functionally Graded Elliptic Plate,’’ Composites Part B: Engineering, 31:97-106.

Görnandt, A. and Gabbert, U. 2002. ‘‘Finite Element Analysis of Thermopiezoelectric Smart Structures,’’ Acta Mechanica, 154:129-140.

10.

Hatta, H. and Taya, M. 1985. ‘‘Effective Thermal Conductivity of a Misoriented Short Fiber Composite,’’ Journal of Applied Physics , 58:2478-2486.

11.

Levin, V.M. 1967. ‘‘Thermal Expansion Coefficients of Heterogeneous Materials,’’ Mekh. Tverd. Tela, 2:88-94.

12.

Miyamoto, Y. , Kaysser, W. , Rabin, B. , Kawasaki, A. and Ford, R. 1999. Functionally Graded Materials: Design, Processing and Applications. Technology and Industrial Arts, Kluwer Academic Publishers, Dordrecht.

13.

Mori, T. and Tanaka, K. 1973. ‘‘Average Stress in Matrix and Average Elastic Energy of Materials with Misfitting Inclusions,’’ Acta Metallurgica, 21:571-574.

14.

Praveen, G. and Reddy, J. 1998. ‘‘Nonlinear Transient Thermoelastic Analysis of Functionally Graded Ceramic-metal Plates,’’ International Journal of Solids and Structures, 35:4457-4476.

15.

Reddy, J.N. 2000. ‘‘Analysis of Functionally Graded Plates , ’’ International Journal for Numerical Methods in Engineering , 47:663-684.

16.

Reddy, J.N. and Cheng, Z.-Q. 2001. ‘‘Three-dimensional Thermomechanical Deformations of Functionally Graded Rectangular Plates,’’ European Journal of Mechanics - A/Solids, 20:841-855.

17.

Reddy, J.N. 2003. Mechanics of Laminated Composite Plates and Shells , 2nd Edn. CRC Press, Boca Raton.

18.

Reissner, E. 1986. ‘‘On a Mixed Variational Theorem and on Shear Deformable Plate Theory,’’ International Journal for Numerical Methods in Engineering, 23:193-198.

19.

Rolfes, R. and Tessmer, J. 2002. ‘‘3D Thermal Analysis of Hybrid Composite Structures,’’ Proceedings of Applied Mathematics and Mechanics, 1:215-216.

20.

Schapery, R.A. 1968. ‘‘Thermal Expansion Coefficients of Composite Materials based on Energy Principles,’’ Journal of Composite Materials, 2:380-404.

21.

Washizu, K. 1975. Variational Methods in Elasticity and Plasticity , Pergamon Press, Oxford.

22.

Zienkiewicz, O. , Taylor, R. , Zhu, J. and Nithiarasu, P. 2005. The Finite Element Method, 6th Edn, Elsevier Butterworth-Heinemann, Oxford.

Thermomechanical Modeling of Functionally Graded Plates

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