[1] SHABAN, M. and ALIPOUR, M. M. Semi-analytical solution for free vibration of thick functionally graded plates rested on elastic foundation with elastically restrained edge. Acta Mechanica Solida Sinica, 24(4), 340-354(2011)
[2] ALIBEIGLOO, A. and MADOLIAT, R. Static analysis of cross-ply laminated plates with integrated surface piezoelectric layers using differential quadrature. Composite Structures, 88(3), 342-353(2009)
[3] DAI, H. L., LUO, W. F., and DAI, T. Multi-field coupling static bending of a finite length inhomogeneous double-layered structure with inner hollow cylinder and outer shell. Applied Mathematical Modelling, 40(11-12), 6006-6025(2016)
[4] JIN, Z. H. Some notes on the linear viscoelasticity of functionally graded materials. Mathematics and Mechanics of Solids, 11(2), 216-224(2006)
[5] XING, Y. and LIU, B. Characteristic equations and closed-form solutions for free vibrations of rectangular mindlin plates. Acta Mechanica Solida Sinica, 22(2), 125-136(2009)
[6] GUO, J., SUN, T., and PAN, E. Three-dimensional buckling of embedded multilayered magnetoelectroelastic nanoplates/graphene sheets with nonlocal effect. Journal of Intelligent Material Systems and Structures, 30(18-19), 2870-2893(2019)
[7] GUO, J., CHEN, J., and PAN, E. Size-dependent behavior of functionally graded anisotropic composite plates. International Journal of Engineering Science, 106, 110-124(2016)
[8] MISHRA, D., YOON, S., SEO, Y., and PAK, Y. E. Analytical solutions of electroelastic fields in piezoelectric thin-film multilayer:applications to piezoelectric sensors and actuators. Acta Mechanica, 231(4), 1435-1459(2020)
[9] SHABAN, M. and MAZAHERI, H. Size dependent electro-static analysis of smart micro-sandwich panels with functionally graded core. Acta Mechanica, 232(9), 1-37(2020)
[10] FUKUI, N. and YAMANAKA, Y. Elastic analysis for thick-walled tubes of functionally graded material subjected to internal pressure. JSME International Journal, Series 1:Solid Mechanics, Strength of Materials, 35(4), 379-385(1992)
[11] DAI, H. L., FU Y. M., and DONG, Z. M. Exact solutions for functionally graded pressure vessels in a uniform magnetic field. International Journal of Solids and Structures, 43(18-19), 5570-5580(2006)
[12] DAI, H. L. and FU, Y. M. Magnetothermoelastic interactions in hollow structures of functionally graded material subjected to mechanical loads. International Journal of Pressure Vessels and Piping, 84(3), 132-138(2007)
[13] LOGHMAN, A. and PARSA, H. Exact solution for magneto-thermo-elastic behaviour of double-walled cylinder made of an inner FGM and an outer homogeneous layer. International Journal of Mechanical Sciences, 88, 93-99(2014)
[14] DAI, H. L., RAO, Y. N., and JIANG, H. J. An analytical method for magnetothermoelastic analysis of functionally graded hollow cylinders. Applied Mathematics and Computation, 218(4), 1467-1477(2011)
[15] VEDELD, K. and SOLLUND, H. A. Stresses in heated pressurized multi-layer cylinders in generalized plane strain conditions. International Journal of Pressure Vessels and Piping, 120-121, 27-35(2014)
[16] CHEN, P. Y. P. Axisymmetric thermal stresses in an anisotropic finite hollow cylinder. Journal of Thermal Stresses, 6(2-4), 197-205(1983)
[17] JABBARI, M., BAHTUI, A., and ESLAMI, M. R. Axisymmetric mechanical and thermal stresses in thick short length FGM cylinders. International Journal of Pressure Vessels and Piping, 86(5), 296-306(2009)
[18] WEI, X. X. and CHAU, K. T. Finite and transversely isotropic elastic cylinders under compression with end constraint induced by friction. International Journal of Solids and Structures, 46(9), 1953-1965(2009)
[19] LEKHNITSKII, S. G., FERN, P., and BRANDSTATTER, J. J. Theory of Elasticity of an Anisotropic Body, Holden-Day, San Francisco, 206-212(1963)
[20] HUMBERT, L., COLPO, F., and BOTSIS, J. An axisymmetric stress analysis in a single fibre composite of finite length under a thermal expansion mismatch. European Journal of Mechanics, A/Solids, 28(2), 257-265(2009)
[21] SHENG, H. Y. and YE, J. State space solution for axisymmetric bending of angle-ply laminated cylinder with clamped edges. Composite Structures, 68(1), 119-128(2005)
[22] ALIBEIGLOO, A. Thermoelastic solution for static deformations of functionally graded cylindrical shell bonded to thin piezoelectric layers. Composite Structures, 93(2), 961-972(2011)
[23] LEKHNITSKII, S. G. Theory of Elasticity of an Anisotropic Body, Mir Publishers, Moscow, 256-262(1981)
[24] REN, J. G. Exact solutions for laminated composite cylindrical shells in cylindrical bending. Journal of Reinforced Plastics and Composites, 11(4), 340-371(1992)
[25] ZHANG, T. and SHI, Z. Two-dimensional exact analysis for piezoelectric curved actuators. Journal of Micromechanics and Microengineering, 16(3), 640-647(2006)
[26] KARDOMATEAS, G. A., RODCHEUY, N., and FROSTIG, Y. Elasticity solution for curved sandwich beams/panels and comparison with structural theories. AIAA Journal, 55(9), 3153-3160(2017)
[27] SHABAN, M. and MAZAHERI, H. Closed-form elasticity solution for smart curved sandwich panels with soft core. Applied Mathematical Modelling, 76, 50-70(2019)
[28] YE, J. and SOLDATOS, K. P. Three-dimensional stress analysis of orthotropic and cross-ply laminated hollow cylinders and cylindrical panels. Computer Methods in Applied Mechanics and Engineering, 117(3-4), 331-351(1994)
[29] HEYLIGER, P. A note on the static behavior of simply-supported laminated piezoelectric cylinders. International Journal of Solids and Structures, 34(29), 3781-3794(1997)
[30] KAPURIA, S., DUMIR, P. C., and SENGUPTA, S. Nonaxisymmetric exact piezothermoelastic solution for laminated cylindrical shell. AIAA Journal, 35(11), 1792-1795(1997)
[31] NOSIER, A. and RUHI, M. Three dimensional analysis of laminated cylindrical panels with piezoelectric layers. International Journal of Engineering Transactions B:Applications, 19(1), 61-72(2006)
[32] WU, C., SYN, Y., and LO, J. Three-dimensional solutions of multilayered piezoelectric hollow cylinders by an asymptotic approach. International Journal of Mechanical Sciences, 49, 669-689(2007)
[33] MIRI, A. K. and NOSIER, A. Out-of-plane stresses in composite shell panels:layerwise and elasticity solutions. Acta Mechanica, 220(1-4), 15-32(2011)
[34] WU, C. P. and TSAI, T. C. Exact solutions of functionally graded piezoelectric material sandwich cylinders by a modified Pagano method. Applied Mathematical Modelling, 36(5), 1910-1930(2012)
[35] WU, C. P. and CHEN, H. Exact solutions of free vibration of simply supported functionally graded piezoelectric sandwich cylinders using a modified Pagano method. Journal of Sandwich Structures and Materials, 15(2) 229-257(2013)
[36] ALIBEIGLOO, A. Elasticity solution of functionally graded carbon nanotube-reinforced composite cylindrical panel subjected to thermo mechanical load. Composites Part B:Engineering, 87, 214-226(2016)
[37] ALIBEIGLOO, A. Thermoelastic analysis of functionally graded carbon nanotube reinforced composite cylindrical panel embedded in piezoelectric sensor and actuator layers. Composites Part B:Engineering, 98, 225-243(2016)
[38] LI, Y. S., FENG, W. J., and ZHANG, C. Buckling and vibration of the two-dimensional quasicrystal cylindrical shells under axial compression. Applied Mathematical Modelling, 50, 68-91(2017)
[39] LI, Y., YANG, L., ZHANG, L., and GAO, Y. Static response of functionally graded multilayered one-dimensional quasicrystal cylindrical shells. Mathematics and Mechanics of Solids, 1-14(2018)
[40] BRISCHETTO, S. Exponential matrix method for the solution of exact 3D equilibrium equations for free vibrations of functionally graded plates and shells. Journal of Sandwich Structures and Materials, 21(1), 77-114(2019)
[41] DAI, H. L. and WANG, X. Dynamic responses of piezoelectric hollow cylinders in an axial magnetic field. International Journal of Solids and Structures, 41(18-19), 5231-5246(2004)
[42] SADD, M. H. Elasticity:Theory, Applications, and Numerics, Academic Press, Amesterdam, 145-147(2014)
Email Alert
RSS