پیوندهای مفید
آمار
| تعداد نشریات | 22 |
| تعداد شمارهها | 709 |
| تعداد مقالات | 10,213 |
| تعداد مشاهده مقاله | 71,680,425 |
| تعداد دریافت فایل اصل مقاله | 63,496,342 |
Dynamic Analysis of Functionally Graded Nanobeams Using Various Shear Deformation Theories Based on Doublet Mechanics | ||
| Mechanics of Advanced Composite Structures | ||
| دوره 14، شماره 1 - شماره پیاپی 29، تیر 2027، صفحه 75-97 اصل مقاله (1.66 M) | ||
| نوع مقاله: Research Article | ||
| شناسه دیجیتال (DOI): 10.22075/macs.2026.37204.1823 | ||
| نویسندگان | ||
| Alireza Javanbakht؛ Morteza Karamooz Mahdiabadi* | ||
| Department of Mechanical Engineering, Tarbiat Modares University, Tehran, 1464753111, Iran | ||
| تاریخ دریافت: 29 اسفند 1403، تاریخ بازنگری: 07 آذر 1404، تاریخ پذیرش: 12 دی 1404 | ||
| چکیده | ||
| This study investigates the vibrational behavior of a functionally graded beam using the doublet mechanics theory. This theory accounts for interactions between constituent atoms within a structure, enabling consideration of atomic-scale structure and orientation relative to the beam axis. While classical Euler–Bernoulli and Timoshenko beam theories are commonly used within the framework of doublet mechanics, they typically neglect key terms associated with shear deformation effects. To overcome this limitation, the present research introduces the novel application of higher-order shear deformation theories (HSDTs) within the doublet mechanics framework. This approach, not previously explored in the literature, provides more accurate predictions of vibrational characteristics. The results reveal that employing doublet mechanics can significantly influence natural frequencies, with deviations of up to 5%. | ||
| کلیدواژهها | ||
| Functionally Graded materials؛ Vibration analysis؛ Doublet mechanics؛ Rayleigh-Ritz method؛ Nanostructure | ||
| مراجع | ||
|
[1] Filser, F. T., 2001. Direct ceramic machining of ceramic dental restorations. ETH Zurich. [2] Knoppers, G., Gunnink, J., Van Den Hout, J. & Van Vliet, W., 2005. The reality of functionally graded material products. Intelligent Production Machines and Systems: First I* PROMS Virtual Conference, Elsevier, Amsterdam, pp. 467-474. [3] Mahamood, R. M. & Akinlabi, E. T. 2017. Functionally graded materials, Springer. [4] Azimi, M., Mirjavadi, S. S., Shafiei, N., Hamouda, A. & Davari, E., 2018. Vibration of rotating functionally graded Timoshenko nano-beams with nonlinear thermal distribution. Mechanics of Advanced Materials & Structures, 25, pp. 467-480. [5] Zhong, Z., Chen, S., & Shang, E., 2010. Analytical solution of a functionally graded plate in cylindrical bending. Mechanics of Advanced Materials Structures, 17, pp. 595-602. [6] Pradhan, K. & Chakraverty, S., 2013. Free vibration of Euler and Timoshenko functionally graded beams by Rayleigh–Ritz method. Composites Part B: Engineering, 51, pp. 175-184. [7] Akgöz, B. & Civalek, Ö., 2013. Free vibration analysis of axially functionally graded tapered Bernoulli–Euler microbeams based on the modified couple stress theory. Composite Structures, An International Journal, 98, pp. 314-322. [8] Akgöz, B. & Civalek, Ö., 2013. Buckling analysis of functionally graded microbeams based on the strain gradient theory. Acta Mechanica, 224, pp. 2185-2201. [9] Jin, C., & Wang, X., 2015. Accurate free vibration analysis of Euler functionally graded beams by the weak form quadrature element method. Composite Structures, An International Journal, 125, pp. 41-50. [10] Ansari, R., Gholami, R. & Sahmani, S., 2011. Free vibration analysis of size-dependent functionally graded microbeams based on the strain gradient Timoshenko beam theory. Composite Structures, An International Journal, 94, pp. 221-228. [11] Attia, M. A., 2017. On the mechanics of functionally graded nanobeams with the account of surface elasticity. International Journal of Engineering Science, 115, pp. 73-101. [12] Dehrouyeh-Semnani, A. M., Mostafaei, H. & Nikkhah-Bahrami, M., 2016. Free flexural vibration of geometrically imperfect functionally graded microbeams. International Journal of Engineering Science, 105, pp. 56-79. [13] Fang, J., Gu, J. & Wang, H., 2018. Size-dependent three-dimensional free vibration of rotating functionally graded microbeams based on a modified couple stress theory. International Journal of Mechanical Sciences, 136, pp. 188-199. [14] Rahmani, A., Babaei, A. & Faroughi, S., 2020. Vibration characteristics of functionally graded micro-beam carrying an attached mass. Mechanics of Advanced Composite Structures, 7, pp. 49-58. [15] Sina, S., Navazi, H. & Haddadpour, H., 2009. An analytical method for free vibration analysis of functionally graded beams. Materials Design, 30, pp. 741-747. [16] Li, X.-F., 2008. A unified approach for analyzing static and dynamic behaviors of functionally graded Timoshenko and Euler–Bernoulli beams. Journal of Sound and vibration, 318, pp. 1210-1229. [17] Thai, H.-T. & Vo, T. P., 2012. Bending and free vibration of functionally graded beams using various higher-order shear deformation beam theories. International journal of mechanical sciences, 62, pp. 57-66. [18] Şimşek, M., 2010. Fundamental frequency analysis of functionally graded beams by using different higher-order beam theories. Nuclear Engineering Design, 240, pp. 697-705. [19] Alimohammadi Madanouei, I. and Karamooz Mahdiabadi, M., 2025. Free and Forced Vibration Mitigation of Nonlinear Functionally Graded Beams Based on Higher-Order Shear Deformation Theories Using NES. International Journal of Structural Stability and Dynamics, 25(23), 2550244. [20] Ghobad, Y., Mahdiabadi, M. K. & Farrokhabadi, A., 2024. High-frequency vibration analysis of laminated composite plates using energy flow and shear deformation theories. Thin-Walled Structures, 205, 112524. [21] Babaei, A., Noorani, M.-R. S. & Ghanbari, A., 2017. Temperature-dependent free vibration analysis of functionally graded micro-beams based on the modified couple stress theory. Microsystem technologies, 23, pp. 4599-4610. [22] Van Vinh, P., 2025. A novel modified nonlocal strain gradient theory for comprehensive analysis of functionally graded nanoplates. Acta Mechanica, 236, pp. 173-204. [23] Son, L. T., Vinh, P. V., Chinh, N. V. & M. Sedighi, H., 2025. High-frequency temperature-dependent vibration of nonlocal functionally graded sandwich nanoplates resting on elastic foundations. Mechanics of Advanced Materials Structures, 32, pp. 957-978. [24] Son, L. T., Belarbi, M.-O., Tounsi, A., Ziou, H., Avcar, M. & Van Vinh, P., 2025. Nonlocal vibration analysis of functionally graded sandwich nanoplates resting on general viscoelastic foundations. Mechanics of Advanced Materials Structures, pp. 1-18. [25] Van Vinh, P. & Tounsi, A., 2022. Free vibration analysis of functionally graded doubly curved nanoshells using nonlocal first-order shear deformation theory with variable nonlocal parameters. Thin-Walled Structures, 174, 109084. [26] Alimoradzadeh, M., Sedighi, H. M., Van Vinh, P. & Sofiyev, A. H., 2025. Primary and secondary resonance characteristics of electro-thermo-mechanically loaded GNP-Reinforced MEMS beams: A microstructurally informed approach. Mechanical Systems & Signal Processing, 238, 113162. [27] Uzun, B. & Yayli, M. Ö., 2024. Porosity and deformable boundary effects on the dynamic of nonlocal sigmoid and power-law FG nanobeams embedded in the Winkler–Pasternak medium. Journal of Vibration Engineering & Technologies, 12, pp. 3193-3212. [28] Ghazwani, M. H., Alnujaie, A., Tounsi, A. & Van Vinh, P., 2024. On the high-frequency analysis of exponentially graded nanobeams resting on Winkler–Pasternak foundations. Journal of Vibration Engineering Technologies, 12, pp. 8113-8130. [29] Dadashi, M. and Mahdiabadi, M.K., 2025. Dynamic Analysis of Functionally Graded Sandwich Doubly Curved Nanoshells Using Variable Nonlocal Elasticity Theory. International Journal of Structural Stability and Dynamics, 25(12), p.2550122. [30] Ferrari, M., Granik, V. & Imam, A., 1997. Introduction to doublet mechanics. Advances in Doublet Mechanics, Springer, pp. 1-26. [31] Gul, U. & Aydogdu, M., 2021. Dynamic analysis of functionally graded beams with periodic nanostructures. Composite Structures, An International Journal, 257, 113169. [32] Granik, V., 1978. Microstructural mechanics of granular media, Technique Report IM/MGU 78-241, Institute of Mechanics of Moscow State University. Russian. [33] Granik, V. T. & Ferrari, M., 1993. Microstructural mechanics of granular media. Mechanics of Materials, 15, pp. 301-322. [34] Gul, U., Aydogdu, M. & Gaygusuzoglu, G., 2017. Axial dynamics of a nanorod embedded in an elastic medium using doublet mechanics. Composite Structures, An International Journal, 160, pp. 1268-1278. [35] Gul, U. & Aydogdu, M., 2018. Noncoaxial vibration and buckling analysis of embedded double-walled carbon nanotubes by using doublet mechanics. Composites Part B: Engineering, 137, pp. 60-73. [36] Gul, U. & Aydogdu, M., 2021. A micro/nano-scale Timoshenko-Ehrenfest beam model for bending, buckling and vibration analyses based on doublet mechanics theory. European Journal of Mechanics-A/Solids, 86, 104199. [37] Abdelrahman, A. A., Shanab, R. A., Esen, I. & Eltaher, M. a. J. S., 2022. Effect of moving load on dynamics of nanoscale Timoshenko CNTs embedded in elastic media based on doublet mechanics theory. Composite Structures, An International Journal, 44, pp. 255-270. [38] Eltaher, M., Abdelrahman, A. A. & Esen, I., 2021. Dynamic analysis of nanoscale Timoshenko CNTs based on doublet mechanics under moving load. The European Physical Journal Plus, 136, 705. [39] Eltaher, M. A. & Mohamed, N., 2020. Nonlinear stability and vibration of imperfect CNTs by doublet mechanics. Applied Mathematics & Computation, 382, 125311. [40] Eltaher, M. A., Mohamed, N. & Mohamed, S. A., 2020. Nonlinear buckling and free vibration of curved CNTs by doublet mechanics. Smart Structures & Systems, An International Journal, 26, pp. 213-226. [41] Civalek, Ö., Uzun, B. & Yaylı, M. Ö., 2024. Longitudinal vibration analysis of FG nanorod restrained with axial springs using doublet mechanics. Waves in Random Complex Media, 34, pp. 4937-4959. [42] Pradhan, K. K. & Chakraverty, S., 2014. Effects of different shear deformation theories on free vibration of functionally graded beams. International Journal of Mechanical Sciences, 82, pp. 149-160. [43] Assie, A. E., Mohamed, S. M., Shanab, R. A., Abo-Bakr, R. M. & Eltaher, M. A. 2023. Static Buckling of 2D FG Porous Plates Resting on Elastic Foundation based on Unified Shear Theories. Journal of Applied & Computational Mechanics, 9, pp. 239-258. [44] Shanab, R., Mohamed, S., Tharwan, M. Y., Assie, A. E. & Eltaher, M. A., 2022. Buckling of 2D FG Porous unified shear plates resting on elastic foundation based on neutral axis. Steel & Composite Structures, An International Journal, 45, pp. 729-747. [45] Mohamed, S., Assie, A. E., Mohamed, N. & Eltaher, M. A., 2022. Static and stress analyses of bi-directional FG porous plate using unified higher order kinematics theories. Steel & Composite Structures, An International Journal, pp. 305-330. [46] Karamanli, A., 2021. Structural behaviours of zigzag and armchair nanobeams using finite element doublet mechanics. European Journal of Mechanics-A/Solids, 89, 104287. [47] Ferrari, M., Granik, V. T., Imam, A. & Nadeau, J. C., 2008. Advances in doublet mechanics, 45. Springer Science & Business Media. [48] Rao, S. S., 2019. Vibration of continuous systems. John Wiley & Sons. | ||
|
آمار تعداد مشاهده مقاله: 199 تعداد دریافت فایل اصل مقاله: 72 |
||