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Free vibration analysis of functionally graded porous materials complex shells with variable thickness | ||
| AUT Journal of Mechanical Engineering | ||
| دوره 9، شماره 2، 2025، صفحه 99-112 اصل مقاله (1.31 M) | ||
| نوع مقاله: Research Article | ||
| شناسه دیجیتال (DOI): 10.22060/ajme.2025.23494.6137 | ||
| نویسندگان | ||
| Farzaneh Jafari Maryaki؛ Alireza Shaterzadeh* | ||
| Faculty of Mechanical Engineering, Shahrood University of Technology, Shahrood, Iran | ||
| چکیده | ||
| This research investigates the vibration characteristics of composite shells featuring a cylindrical-hemispherical geometry, fabricated from functionally graded porous materials with varying thicknesses. Two kinds of boundary conditions are assumed: the first assumes both ends are free, while the second involves clamped and free edges for the cylindrical and hemispherical sections, respectively. The analysis employs three-dimensional elasticity principles in conjunction with the Ritz method, utilizing orthogonal polynomials like Legendre polynomials as admissible functions. The natural frequencies' convergence is demonstrated, and results are validated against prior findings from finite element and analytical methods. After confirming the model's accuracy, the influence of porosity is examined. The results indicate that a higher percentage of porosity leads to a decrease in the shell's natural frequencies. The study also investigates how natural frequencies are affected by various geometric parameters. Ultimately, the outcomes highlight the significant impact of porosity and geometric attributes on the frequencies of porous shells. Additionally, torsional and axisymmetric vibration modes are observed to be more influential under clamped-free conditions than under free-free conditions. A general trend of decreasing frequencies with reduced thickness is identified, and higher porosity levels, leading to lower stiffness, consistently reduce frequencies across all modes. | ||
| کلیدواژهها | ||
| Free Vibrations؛ Functionally Graded Porous Materials؛ Ritz Method؛ Orthogonal Polynomials؛ Complex Shells | ||
| مراجع | ||
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[1] A.R. Shaterzadeh, K. Foroutan, Nonlinear Dynamic Analysis of Eccentrically Stiffened FGM Cylindrical Shells With Elastic Foundation Under Uniform External Pressure, 14 (2016) 11-26. (in persion)
[2] Y. Qu, Y. Chen, X. Long, H. Hua, G. Meng, A modified variational approach for vibration analysis of ring-stiffened conical–cylindrical shell combinations, European Journal of Mechanics-A/Solids, 37 (2013) 200-215.
[3] Y. Qu, S. Wu, Y. Chen, H. Hua, Vibration analysis of ring-stiffened conical–cylindrical–spherical shells based on a modified variational approach, International journal of mechanical Sciences, 69 (2013) 72-84.
[4] J. Hammel, Free vibration of a cylindrical shell with a hemispherical head, 2nd Int. SMiRT Conf. IASMiRT, Raleigh, NC, (1973).
[5] M. Tavakoli, R. Singh, Eigensolutions of joined/hermetic shell structures using the state space method, Journal of Sound and Vibration, 130(1) (1989) 97-123.
[6] J. H. Kang, Three-dimensional vibration analysis of joined thick conical—Cylindrical shells of revolution with variable thickness, Journal of Sound and Vibration, 331(18) (2012) 4187-4198.
[7] J. H. Kang, Free vibrations of combined hemispherical–cylindrical shells of revolution with a top opening, International Journal of Structural Stability and Dynamics, 14(01) (2014) 1350023.
[8] J. H. Kang, Vibration analysis of a circular cylinder closed with a hemi-spheroidal cap having a hole, Archive of Applied Mechanics, 87 (2017) 183-199.
[9] Y. B. Yang, J.-H. Kang, Vibrations of a composite shell of hemiellisoidal-cylindrical shell having variable thickness with and without a top opening, Thin-Walled Structures, 119 (2017) 677-686.
[10] J. H. Kang, Vibrations of a cylindrical shell closed with a hemi-spheroidal dome from a three-dimensional analysis, Acta Mechanica, 228 (2017) 531-545.
[11] J. H. Kang, 3D vibration analysis of hermetic capsules by using Ritz method, International Journal of Structural Stability and Dynamics, 17(03) (2017) 1750040.
[12] J. H. Kang, Three-dimensional vibration analysis of a hermetic capsule with variable thickness, AIAA Journal, 55 (2013) 2093-2102.
[13] S. H. Wu, Y.G. Qu, X.C. Huang, H.X. Hua, Free vibration analysis on combined cylindrical-spherical shell, Applied Mechanics and Materials, 226 (2012) 3-8.
[14] S. Wu, Y. Qu, H. Hua, Vibrations characteristics of joined cylindrical-spherical shell with elastic-support boundary conditions, Journal of mechanical science and technology, 27 (2013) 1265-1272.
[15] S. Wu, Y. Qu, H. Hua, Vibration characteristics of a spherical–cylindrical–spherical shell by a domain decomposition method, Mechanics Research Communications, 49 (2013) 17-26.
[16] J. Lee, Free vibration analysis of joined spherical-cylindrical shells by matched Fourier-Chebyshev expansions, International Journal of Mechanical Sciences, 122 (2017) 53-62.
[17] Y. Zhao, D. Shi, H. Meng, A unified spectro-geometric-Ritz solution for free vibration analysis of conical–cylindrical–spherical shell combination with arbitrary boundary conditions, Archive of Applied Mechanics, 87 (2017) 961-988.
[18] H. Li, F. Pang, Y. Ren, X. Miao, K. Ye, Free vibration characteristics of functionally graded porous spherical shell with general boundary conditions by using first-order shear deformation theory, Thin-Walled Structures, 144 (2019) 106331.
[19] H. Li, F. Pang, X. Wang, Y. Du, H. Chen, Free vibration analysis of uniform and stepped combined paraboloidal, cylindrical and spherical shells with arbitrary boundary conditions, International Journal of Mechanical Sciences, 145 (2018) 64-82.
[20] H. Li, G. Cong, L. Li, F. Pang, J. Lang, A semi analytical solution for free vibration analysis of combined spherical and cylindrical shells with non-uniform thickness based on Ritz method, Thin-Walled Structures, 145 (2019) 106443.
[21] H. Bagheri, Y. Kiani, M. Eslami, Free vibration of FGM conical–spherical shells, Thin-Walled Structures, 160 (2021) 107387.
[22] D. Zhang, Y. Wang, L. Li, Free vibration response of FG porous joined hemispherical–cylindrical–hemispherical shell vessels reinforced by graphene platelet, International Journal of Structural Stability and Dynamics, 23 (2023) 2350025.
[23] E. Sobhani, A.R. Masoodi, Ö. Civalek, A.R. Ahmadi-Pari, Free-damped vibration tangential wave responses of FG-sandwich merged hemispherical-cylindrical shells under effects of artificial springs at merging and boundary conditions, Engineering Structures, 284 (2023) 115958.
[24] E. Sobhani, B. Safaei, Dynamical characteristics of fastening of a cylindrical shell with a hemispherical shell made of graded porous power ceramic-metal under elastic boundary edges, Engineering Analysis with Boundary Elements, 156 (2023) 432-454.
[25] Z. Zhu, Y. Zhang, R. Xu, L. Zhao, G. Wang, Q. Liu, Analysis of thermal-vibration coupling modeling of combined conical-cylindrical shell under complex boundary conditions, Journal of Vibration and Control, 30(15-16) (2024) 3377-3387.
[26] Z. Xu, X.-C. Yu, H. Li, P.-Y. Xu, X.-C. Sun, Y.-F. Zhang, D.-W. Gu, Q.-K. Han, B.-C. Wen, The Vibration Characteristics Analysis of Fiber-Reinforced Thin-Walled Conical–Cylindrical Composite Shells with Artificial Spring Technique, International Journal of Structural Stability and Dynamics, (2024) 2550200.
[27] N.D. Duc, V.D. Quang, V.T.T. Anh, The nonlinear dynamic and vibration of the S-FGM shallow spherical shells resting on an elastic foundations including temperature effects, International Journal of Mechanical Sciences, 123 (2017) 54-63.
[28] H. Li, F. Pang, H. Chen, Y. Du, Vibration analysis of functionally graded porous cylindrical shell with arbitrary boundary restraints by using a semi analytical method, Composites Part B: Engineering, 164 (2019) 249-264.
[29] K. Xie, M. Chen, An analytical method for free vibrations of functionally graded cylindrical shells with arbitrary intermediate ring supports, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 43 (2021) 1-24.
[30] F. Kiani, M. Hekmatifar, D. Toghraie, Analysis of forced and free vibrations of composite porous core sandwich cylindrical shells and FG-CNTs reinforced face sheets resting on visco-Pasternak foundation under uniform thermal field, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42(10) (2020) 504.
[31] A.A.P. Zanoosi, Size-dependent thermo-mechanical free vibration analysis of functionally graded porous microbeams based on modified strain gradient theory, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42(5) (2020) 236.
[32] R. Ansari, M.Z. Ershadi, A. Mirsabetnazar, M.F. Oskouie, Nonlinear large amplitude vibrations of annular sector functionally graded porous composite plates under instantaneous hygro-thermal shock, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 46(9) (2024) 541.
[33] W. Zhao, X. Gong, D. Guo, C. Li, Free vibration and thermal buckling analysis of FGM sandwich circular plate under transverse non-uniform temperature rise, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 46(2) (2024) 108.
[34] J.-H. Kang, Vibrations of complex shells with variable thickness, Journal of Engineering Mechanics, 143(8) (2017) 04017053.
[35] D.H. Bich, D.G. Ninh, T.I. Thinh, Non-linear buckling analysis of FGM toroidal shell segments filled inside by an elastic medium under external pressure loads including temperature effects, Composites Part B: Engineering, 87 (2016) 75-91.
[36] D.G. Ninh, D.H. Bich, Nonlinear buckling of eccentrically stiffened functionally graded toroidal shell segments under torsional load surrounded by elastic foundation in thermal environment, Mechanics Research Communications, 72 (2016)1-15.
[37] T.N. Doan, A.T. Nguyen, P. Van Binh, T. Van Hung, V.Q. Tru, D.T. Luat, Static analysis of FGM cylindrical shells and the effect of stress concentration using quasi-3D type higher-order shear deformation theory, Composite Structures, 262 (2021) 113357.
[38] H. Chung, Free vibration analysis of circular cylindrical shells, Journal of Sound and Vibration, 74(3) (1981) 331-350.
[39] S. Sun, D. Cao, Q. Han, Vibration studies of rotating cylindrical shells with arbitrary edges using characteristic orthogonal polynomials in the Rayleigh–Ritz method, International Journal of Mechanical Sciences, 68 (2013) 180-189.
[40] C.L. Dym, Some new results for the vibrations of circular cylinders, Journal of sound and Vibration, 29(2) (1973) 189-205.
[41] K. Forsberg, Influence of boundary conditions on the modal characteristics of thin cylindrical shells, AIAA journal, 2(12) (1964) 2150-2157.
[42] G. Galletly, J. Mistry, The free vibrations of cylindrical shells with various end closures, Nuclear Engineering and Design, 30(2) (1974) 249-268.
[43] N.D. Duc, P.D. Nguyen, N.D. Khoa, Nonlinear dynamic analysis and vibration of eccentrically stiffened S-FGM elliptical cylindrical shells surrounded on elastic foundations in thermal environments, Thin-walled structures, 117 (2017) 178-189. | ||
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