Research ArticleNo Access

Analytical Solution for the Creep Problem of a Rotating Functionally Graded Magneto–Electro–Elastic Hollow Cylinder in Thermal Environment

M. Saadatfar

Department of Mechanical Engineering, University of Qom, Qom, Iran

https://doi.org/10.1142/S1758825119500534Cited by:18 (Source: Crossref)

Abstract

In this paper, an analytical method is presented for the problem of the time-dependent response of a functionally graded magneto–electro–elastic (FGMEE) rotating hollow cylinder in thermal environment. The material properties of FGMEE are supposed to be power-law functions of radius. Applying the equations of equilibrium and electrostatic and magnetostatic equations, a differential equation which includes creep strains is achieved. At first, an exact solution for the primitive stresses, electric and magnetic potentials are achieved by eliminating creep strains in the mentioned differential equation. Then, Prandtl–Reuss equations, as well as Norton’s law, are employed for the FGMEE. Now, creep stress rates can be achieved by considering only creep strains in the mentioned differential equation. As a final step, time-dependent creep stress, electric potential and magnetic potential redistributions at any time can be achieved using an iterative method. Numerical examples are presented to disclose the influence of creep evolution, thermal loading, angular velocity and grading index on the primitive and creep response of the FGMEE hollow cylinder. Results show that the enhancement in tensile hoop stress during the creep evolution must be considered in designing. So, the creep analysis is vital to have more reliable and accurate aerospace smart structures.

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References

Akbarzadeh, A. H. and Chen, Z. T. [2012] “ Magnetoelectroelastic behavior of rotating cylinders resting on an elastic foundation under hygrothermal loading,” Smart Materials and Structures 21, 125013. Web of Science, Google Scholar
Babaei, M. H. and Chen, Z. T. [2008] “ Exact solutions for radially polarized and magnetized magneto electro elastic rotating cylinders,” Smart Materials and Structures 17, 025035. Web of Science, Google Scholar
Bakhshizadeh, A., Nejad, M. Z. and Kashkoli, M. D. [2017] “ Time-dependent hygro-thermal creep analysis of pressurized FGM rotating thick cylindrical shells subjected to uniform magnetic field,” Journal of Solid Mechanics 9, 663–679. Google Scholar
Bose, T. and Rattan, M. [2018] “ Modeling creep analysis of thermally graded anisotropic rotating composite disc,” International Journal of Applied Mechanics 10(6), 1850063. Link, Web of Science, Google Scholar
Bose, T., Rattan, M. and Chamoli, N. [2017] “ Steady state creep of isotropic rotating composite disc under thermal gradation,” International Journal of Applied Mechanics 9(6), 1750077. Link, Web of Science, Google Scholar
Dai, H. L., Jiang, H. J. and Yang, L. [2012] “ Time-dependent behaviors of a FGPM hollow sphere under the coupling of multi-fields,” Solid State Science 14, 587–597. Web of Science, Google Scholar
Ghorbanpour Arani, A., Kolahchi, R., Mosallaie Barzoki, R. R. and Loghman, A. [2011a] “ Time-dependent thermo-electro-mechanical creep behavior of radially polarized FGPM rotating cylinder,” Journal of Solid Mechanics 3, 142–157. Google Scholar
Ghorbanpour Arani, A., Mosallaie Barzoki, A. A., Kolahchi, R., Mozdianfard, M. R. and Loghman, A. [2011b] “ Semi-analytical solution of time-dependent electro-thermo-mechanical creep for radially polarized piezoelectric cylinder,” Computer and Structures 89, 1494–1502. Web of Science, Google Scholar
Ghorbanpour Arani, A. and Kolahchi, R. [2014] “ Successive approximation method for time-dependent creep modeling of functionally graded piezoelectric cylinder,” Turkish Journal of Engineering Environmental Science 38, 309–322. Google Scholar
Hou, P. F. and Leung, A. Y. T. [2004] “ The transient responses of magneto-electro-elastic hollow cylinders,” Smart Materials and Structures 13, 762. Web of Science, Google Scholar
Jamian, S., Sato, H., Tsukamoto, H. and Watanabe, Y. [2013] “ Creep analysis of functionally graded material thick-walled cylinder,” Applied Mechanics and Materials 315, 867–871. Google Scholar
Kashkoli, M. D., Tahan, K. N. and Nejad, M. Z. [2017] “ Time-dependent thermomechanical creep behavior of FGM thick hollow cylindrical shells under non-uniform internal pressure,” International Journal of Applied Mechanics 9, 750086. Link, Web of Science, Google Scholar
Kashkoli, M. D., Tahan, K. N. and Nejad, M. Z. [2018] “ Thermomechanical creep analysis of FGM thick cylindrical pressure vessels with variable thickness,” International Journal of Applied Mechanics 10(1), 1850008. Link, Web of Science, Google Scholar
Loghman, A., Abdollahian, M., Jafarzadeh Jazi, M. and Ghorbanpour Arani, A. [2013] “ Semi-analytical solution for electromagnetothermoelastic creep response of functionally graded piezoelectric rotating disk,” International Journal of Thermal Science 65, 254–266. Web of Science, Google Scholar
Loghman, A., Ghorbanpour Arani, A., Amir, A. S. and Vajedi, A. [2010] “ Magnetothermoelastic creep analysis of functionally graded cylinders,” International Journal of Pressure Vessels and Piping 87, 389–395. Web of Science, Google Scholar
Nejad, M. Z. and Kashkoli, M. D. [2014] “ Time-dependent thermo-creep analysis of rotating FGM thick-walled cylindrical pressure vessels under heat flux,” International Journal of Engineering Science 82, 222–237. Web of Science, Google Scholar
Ootao, Y. and Ishihara, M. [2011] “ Exact solution of transient thermal stress problem of a multilayered magneto-electro-thermoelastic hollow cylinder,” Applied Mathematical Modelling 5, 90–103. Google Scholar
Saadatfar, M. [2015] “ Effect of multiphysics conditions on the behavior of an exponentially graded smart cylindrical shell with imperfect bonding,” Meccanica 50, 2135–2152. Web of Science, Google Scholar
Saadatfar, M. [2019a] “ Stress redistribution analysis of piezomagnetic rotating thick-walled cylinder with temperature- and moisture-dependent material properties,” Journal of Applied and Computational Mechanics, https://doi.org/10.22055/jacm.2019.28245.1-468. Web of Science, Google Scholar
Saadatfar, M. [2019b] “ Time-dependent creep response of magneto-electro-elastic rotating disc in thermal and humid environmental condition,” AUT Journal of Mechanical Engineering, https://doi.org/10.22060/ajme.2019.15375.5770. Google Scholar
Saadatfar, M. and Aghaie-Khafri, M. [2014] “ Hygrothermomagnetoelectroelastic analysis of a functionally graded magnetoelectroelastic hollow sphere resting on an elastic foundation,” Smart Material and structures 23, 035004. Web of Science, Google Scholar
Saadatfar, M. and Aghaie-Khafri, M. [2015a] “ Hygrothermal analysis of a rotating smart exponentially graded cylindrical shell with imperfect bonding supported by an elastic foundation,” Aerospace Science and Technology 43, 37–50. Web of Science, Google Scholar
Saadatfar, M. and Aghaie-Khafri, M. [2015b] “ On the behavior of a rotating functionally graded hybrid cylindrical shell with imperfect bonding subjected to hygrothermal condition,” Journal of Thermal Stresses 38, 854–881. Web of Science, Google Scholar
Saadatfar, M. and Aghaie-Khafri, M. [2015c] “ On the magneto-thermo-elastic behavior of a FGM cylindrical shell with pyroelectric layers featuring interlaminar bonding imperfections rested in an elastic foundation,” Journal of Solid Mechanics 7, 344–363. Google Scholar
Sharma, S., Sahay, I. and Kumar, R. [2012] “ Creep transition in non-homogeneous thick-walled circular cylinder under internal and external pressure,” Applied Mathematical Science 122, 6075–6080. Google Scholar
Sharma, S., Yadav, S. and Sharma, R. [2017] “ Thermal creep analysis of functionally graded thick-walled cylinder subjected to torsion and internal and external pressure,” Journal of Solid Mechanics 9, 302–318. Google Scholar
Singh, T. and Gupta, V. K. [2011] “ Effect of anisotropy on steady state creep in functionally graded cylinder,” Composite Structures 93, 747–758. Web of Science, Google Scholar
Singh, T. and Gupta, V. K. [2014] “ Analysis of steady state creep in whisker reinforced functionally graded thick cylinder subjected to internal pressure by considering residual stress,” Mechanics of Advanced Materials and Structures 21, 384–392. Web of Science, Google Scholar
Wang, H. M. and Ding, H. J. [2006] “ Transient responses of a special non-homogeneous magneto-electro-elastic hollow cylinder for a fully coupled axisymmetric plane strain problem,” Acta Mechanica 184, 137–157. Web of Science, Google Scholar