تعداد نشریات | 159 |

تعداد شمارهها | 6,260 |

تعداد مقالات | 68,089 |

تعداد مشاهده مقاله | 116,522,884 |

تعداد دریافت فایل اصل مقاله | 91,312,585 |

## A comprehensive review on modeling of nanocomposite materials and structures | ||

Journal of Computational Applied Mechanics | ||

مقاله 59، دوره 50، شماره 1، شهریور 2019، صفحه 197-209 اصل مقاله (257.91 K)
| ||

نوع مقاله: Review Paper | ||

شناسه دیجیتال (DOI): 10.22059/jcamech.2019.282388.405 | ||

نویسندگان | ||

Farzad Ebrahimi^{*} ^{1}؛ Ali Dabbagh^{2}
| ||

^{1}Department of Mechanical Engineering, Faculty of Engineering, Imam Khomeini International University, Qazvin, Iran | ||

^{2}School of Mechanical Engineering, College of Engineering, University of Tehran, Tehran, Iran | ||

چکیده | ||

This work presents a historical review of the researches procured by various scientists and engineers dealing with the nanocomposite materials and continuous systems manufactured from such materials. Nanocomposites are advanced type of well-known composite materials which have been reinforced with nanosize reinforcing fibers and/or particles. Such materials can be better suit for the industrial applications of which remarkable improved material properties are needed. In other words, the material properties of nanocomposites are superior to those of macroscale composites due to the enhanced features of materials in the nanoscale. These materials are being more and more employed by designers in the aerospace, mechanics and automotive applications as constituent elements instead of the conventional composite materials. Henceforward, it is of great significance to be aware of the researches conducted in this are by researchers to be able to predict the behaviors of structures consisted of such materials in real working conditions. In what follows, the mechanical analyses performed on different types of nanocomposite structures including carbon nanotube reinforced (CNTR), graphene reinforced (GR), graphene platelet reinforced (GPLR), graphene oxide reinforced (GOR) and multi-scale hybrid (MSH) nanocomposite ones will be reviewed and the most crucial highlights of the proposed scientific activities will be discussed. | ||

کلیدواژهها | ||

Nanocomposite materials؛ Carbon nanotube (CNT)؛ graphene؛ Graphene platelet؛ Graphene oxide؛ Multi-scale hybrid nanocomposites | ||

مراجع | ||

[1] K. Dastani, M. Moghimi Zand, Dynamic and Static Pull-in instability of electrostatically actuated nano/micro membranes under the effects of Casimir force and squeezed film damping, [2] A. Ghorbanpour Arani, H. Baba Akbar Zarei, E. Haghparast, Application of Halpin-Tsai Method in Modelling and Size-dependent Vibration Analysis of CNTs/fiber/polymer Composite Microplates, [3] N. Kordani, A. Fereidoon, M. Divsalar, A. Farajpour, Forced vibration of piezoelectric nanowires based on nonlocal elasticity theory, [4] m. zakeri, R. Attarnejad, A. M. Ershadbakhsh, Analysis of Euler-Bernoulli nanobeams: A mechanical-based solution, [5] M. Goodarzi, M. Nikkhah Bahrami, V. Tavaf, Refined plate theory for free vibration analysis of FG nanoplates using the nonlocal continuum plate model, [6] M. Arda, M. Aydogdu, Longitudinal Magnetic Field Effect on Torsional Vibration of Carbon Nanotubes, [7] D.-L. Shi, X.-Q. Feng, Y. Y. Huang, K.-C. Hwang, H. Gao, The effect of nanotube waviness and agglomeration on the elastic property of carbon nanotube-reinforced composites, [8] L.-L. Ke, J. Yang, S. Kitipornchai, Nonlinear free vibration of functionally graded carbon nanotube-reinforced composite beams, [9] H.-S. Shen, C.-L. Zhang, Thermal buckling and postbuckling behavior of functionally graded carbon nanotube-reinforced composite plates, [10] H.-S. Shen, Thermal buckling and postbuckling behavior of functionally graded carbon nanotube-reinforced composite cylindrical shells, [11] H.-S. Shen, Y. Xiang, Nonlinear vibration of nanotube-reinforced composite cylindrical shells in thermal environments, [12] B. Sobhani Aragh, A. H. Nasrollah Barati, H. Hedayati, Eshelby–Mori–Tanaka approach for vibrational behavior of continuously graded carbon nanotube-reinforced cylindrical panels, [13] Z.-X. Wang, H.-S. Shen, Nonlinear dynamic response of nanotube-reinforced composite plates resting on elastic foundations in thermal environments, [14] M. H. Yas, N. Samadi, Free vibrations and buckling analysis of carbon nanotube-reinforced composite Timoshenko beams on elastic foundation, [15] A. Alibeigloo, Static analysis of functionally graded carbon nanotube-reinforced composite plate embedded in piezoelectric layers by using theory of elasticity, [16] A. Alibeigloo, Elasticity solution of functionally graded carbon-nanotube-reinforced composite cylindrical panel with piezoelectric sensor and actuator layers, [17] A. Alibeigloo, K. M. Liew, Thermoelastic analysis of functionally graded carbon nanotube-reinforced composite plate using theory of elasticity, [18] L.-L. Ke, J. Yang, S. Kitipornchai, Dynamic Stability of Functionally Graded Carbon Nanotube-Reinforced Composite Beams, [19] Z. X. Lei, K. M. Liew, J. L. Yu, Free vibration analysis of functionally graded carbon nanotube-reinforced composite plates using the element-free kp-Ritz method in thermal environment, [20] P. Malekzadeh, M. Shojaee, Buckling analysis of quadrilateral laminated plates with carbon nanotubes reinforced composite layers, [21] M. Rafiee, J. Yang, S. Kitipornchai, Large amplitude vibration of carbon nanotube reinforced functionally graded composite beams with piezoelectric layers, [22] M. Rafiee, J. Yang, S. Kitipornchai, Thermal bifurcation buckling of piezoelectric carbon nanotube reinforced composite beams, [23] H.-S. Shen, Y. Xiang, Nonlinear analysis of nanotube-reinforced composite beams resting on elastic foundations in thermal environments, [24] H.-S. Shen, Y. Xiang, Postbuckling of nanotube-reinforced composite cylindrical shells under combined axial and radial mechanical loads in thermal environment, [25] M. H. Yas, A. Pourasghar, S. Kamarian, M. Heshmati, Three-dimensional free vibration analysis of functionally graded nanocomposite cylindrical panels reinforced by carbon nanotube, [26] A. Alibeigloo, Free vibration analysis of functionally graded carbon nanotube-reinforced composite cylindrical panel embedded in piezoelectric layers by using theory of elasticity, [27] R. Ansari, M. Faghih Shojaei, V. Mohammadi, R. Gholami, F. Sadeghi, Nonlinear forced vibration analysis of functionally graded carbon nanotube-reinforced composite Timoshenko beams, [28] Y. Heydarpour, M. M. Aghdam, P. Malekzadeh, Free vibration analysis of rotating functionally graded carbon nanotube-reinforced composite truncated conical shells, [29] Z. X. Lei, L. W. Zhang, K. M. Liew, J. L. Yu, Dynamic stability analysis of carbon nanotube-reinforced functionally graded cylindrical panels using the element-free kp-Ritz method, [30] K. M. Liew, Z. X. Lei, J. L. Yu, L. W. Zhang, Postbuckling of carbon nanotube-reinforced functionally graded cylindrical panels under axial compression using a meshless approach, [31] F. Lin, Y. Xiang, Vibration of carbon nanotube reinforced composite beams based on the first and third order beam theories, [32] H.-S. Shen, Y. Xiang, Postbuckling of axially compressed nanotube-reinforced composite cylindrical panels resting on elastic foundations in thermal environments, [33] L. W. Zhang, Z. X. Lei, K. M. Liew, J. L. Yu, Static and dynamic of carbon nanotube reinforced functionally graded cylindrical panels, [34] L. W. Zhang, Z. X. Lei, K. M. Liew, J. L. Yu, Large deflection geometrically nonlinear analysis of carbon nanotube-reinforced functionally graded cylindrical panels, [35] A. Alibeigloo, A. Emtehani, Static and free vibration analyses of carbon nanotube-reinforced composite plate using differential quadrature method, [36] R. Ansari, E. Hasrati, M. Faghih Shojaei, R. Gholami, A. Shahabodini, Forced vibration analysis of functionally graded carbon nanotube-reinforced composite plates using a numerical strategy, [37] M. Heshmati, M. Yas, F. Daneshmand, A comprehensive study on the vibrational behavior of CNT-reinforced composite beams, [38] J. Jam, Y. Kiani, Low velocity impact response of functionally graded carbon nanotube reinforced composite beams in thermal environment, [39] J. E. Jam, Y. Kiani, Buckling of pressurized functionally graded carbon nanotube reinforced conical shells, [40] Z. Lei, L. Zhang, K. Liew, Free vibration analysis of laminated FG-CNT reinforced composite rectangular plates using the kp-Ritz method, [41] M. Mirzaei, Y. Kiani, Thermal buckling of temperature dependent FG-CNT reinforced composite conical shells, [42] P. Phung-Van, M. Abdel-Wahab, K. Liew, S. Bordas, H. Nguyen-Xuan, Isogeometric analysis of functionally graded carbon nanotube-reinforced composite plates using higher-order shear deformation theory, [43] H.-S. Shen, Y. Xiang, Thermal postbuckling of nanotube-reinforced composite cylindrical panels resting on elastic foundations, [44] N. Wattanasakulpong, A. Chaikittiratana, Exact solutions for static and dynamic analyses of carbon nanotube-reinforced composite plates with Pasternak elastic foundation, [45] L. Zhang, K. Liew, Large deflection analysis of FG-CNT reinforced composite skew plates resting on Pasternak foundations using an element-free approach, [46] L. W. Zhang, Z. X. Lei, K. M. Liew, Free vibration analysis of functionally graded carbon nanotube-reinforced composite triangular plates using the FSDT and element-free IMLS-Ritz method, [47] L. W. Zhang, Z. X. Lei, K. M. Liew, Vibration characteristic of moderately thick functionally graded carbon nanotube reinforced composite skew plates, [48] L. W. Zhang, K. M. Liew, Geometrically nonlinear large deformation analysis of functionally graded carbon nanotube reinforced composite straight-sided quadrilateral plates, [49] A. Alibeigloo, Elasticity solution of functionally graded carbon nanotube-reinforced composite cylindrical panel subjected to thermo mechanical load, [50] R. Ansari, T. Pourashraf, R. Gholami, A. Shahabodini, Analytical solution for nonlinear postbuckling of functionally graded carbon nanotube-reinforced composite shells with piezoelectric layers, [51] R. Ansari, J. Torabi, Numerical study on the buckling and vibration of functionally graded carbon nanotube-reinforced composite conical shells under axial loading, [52] Y. Kiani, Shear buckling of FG-CNT reinforced composite plates using Chebyshev-Ritz method, [53] Z. Lei, L. Zhang, K. Liew, Parametric analysis of frequency of rotating laminated CNT reinforced functionally graded cylindrical panels, [54] Z. X. Lei, L. W. Zhang, K. M. Liew, Analysis of laminated CNT reinforced functionally graded plates using the element-free kp-Ritz method, [55] M. Mirzaei, Y. Kiani, Free vibration of functionally graded carbon nanotube reinforced composite cylindrical panels, [56] Z. Song, L. Zhang, K. Liew, Dynamic responses of CNT reinforced composite plates subjected to impact loading, [57] B. Thomas, T. Roy, Vibration analysis of functionally graded carbon nanotube-reinforced composite shell structures, [58] F. Tornabene, N. Fantuzzi, M. Bacciocchi, E. Viola, Effect of agglomeration on the natural frequencies of functionally graded carbon nanotube-reinforced laminated composite doubly-curved shells, [59] H. L. Wu, J. Yang, S. Kitipornchai, Nonlinear vibration of functionally graded carbon nanotube-reinforced composite beams with geometric imperfections, [60] L. Zhang, K. Liew, J. Reddy, Postbuckling analysis of bi-axially compressed laminated nanocomposite plates using the first-order shear deformation theory, [61] L. W. Zhang, K. M. Liew, J. N. Reddy, Postbuckling of carbon nanotube reinforced functionally graded plates with edges elastically restrained against translation and rotation under axial compression, [62] L. W. Zhang, Z. G. Song, K. M. Liew, Optimal shape control of CNT reinforced functionally graded composite plates using piezoelectric patches, [63] R. Ansari, J. Torabi, M. Faghih Shojaei, Buckling and vibration analysis of embedded functionally graded carbon nanotube-reinforced composite annular sector plates under thermal loading, [64] Ö. Civalek, Free vibration of carbon nanotubes reinforced (CNTR) and functionally graded shells and plates based on FSDT via discrete singular convolution method, [65] F. Ebrahimi, N. Farazmandnia, Thermo-mechanical vibration analysis of sandwich beams with functionally graded carbon nanotube-reinforced composite face sheets based on a higher-order shear deformation beam theory, [66] F. Ebrahimi, S. Habibi, Low-velocity impact response of laminated FG-CNT reinforced composite plates in thermal environment, [67] N. Fantuzzi, F. Tornabene, M. Bacciocchi, R. Dimitri, Free vibration analysis of arbitrarily shaped Functionally Graded Carbon Nanotube-reinforced plates, [68] E. García-Macías, L. Rodríguez-Tembleque, R. Castro-Triguero, A. Sáez, Eshelby-Mori-Tanaka approach for post-buckling analysis of axially compressed functionally graded CNT/polymer composite cylindrical panels, [69] A. Ghorbani Shenas, P. Malekzadeh, S. Ziaee, Vibration analysis of pre-twisted functionally graded carbon nanotube reinforced composite beams in thermal environment, [70] P. Kumar, J. Srinivas, Vibration, buckling and bending behavior of functionally graded multi-walled carbon nanotube reinforced polymer composite plates using the layer-wise formulation, [71] M. Nejati, A. Asanjarani, R. Dimitri, F. Tornabene, Static and free vibration analysis of functionally graded conical shells reinforced by carbon nanotubes, [72] Z. Shi, X. Yao, F. Pang, Q. Wang, An exact solution for the free-vibration analysis of functionally graded carbon-nanotube-reinforced composite beams with arbitrary boundary conditions, [73] Q. Wang, X. Cui, B. Qin, Q. Liang, Vibration analysis of the functionally graded carbon nanotube reinforced composite shallow shells with arbitrary boundary conditions, [74] Q. Wang, B. Qin, D. Shi, Q. Liang, A semi-analytical method for vibration analysis of functionally graded carbon nanotube reinforced composite doubly-curved panels and shells of revolution, [75] H. Zarei, M. Fallah, H. Bisadi, A. Daneshmehr, G. Minak, Multiple impact response of temperature-dependent carbon nanotube-reinforced composite (CNTRC) plates with general boundary conditions, [76] L. W. Zhang, Z. G. Song, P. Qiao, K. M. Liew, Modeling of dynamic responses of CNT-reinforced composite cylindrical shells under impact loads, [77] F. Ebrahimi, N. Farazmandnia, Thermal buckling analysis of functionally graded carbon nanotube-reinforced composite sandwich beams, [78] F. Ebrahimi, P. Rostami, Wave propagation analysis of carbon nanotube reinforced composite beams, [79] F. Ebrahimi, P. Rostami, Propagation of elastic waves in thermally affected embedded carbon-nanotube-reinforced composite beams via various shear deformation plate theories, [80] Q. Wang, F. Pang, B. Qin, Q. Liang, A unified formulation for free vibration of functionally graded carbon nanotube reinforced composite spherical panels and shells of revolution with general elastic restraints by means of the Rayleigh–Ritz method, [81] S. Zghal, A. Frikha, F. Dammak, Non-linear bending analysis of nanocomposites reinforced by graphene-nanotubes with finite shell element and membrane enhancement, [82] R. Zhong, Q. Wang, J. Tang, C. Shuai, B. Qin, Vibration analysis of functionally graded carbon nanotube reinforced composites (FG-CNTRC) circular, annular and sector plates, [83] F.-Y. Zhu, S. Jeong, H. J. Lim, G. J. Yun, Probabilistic multiscale modeling of 3D randomly oriented and aligned wavy CNT nanocomposites and RVE size determination, [84] F. Ebrahimi, Z. E. Hajilak, M. Habibi, H. Safarpour, Buckling and vibration characteristics of a carbon nanotube-reinforced spinning cantilever cylindrical 3D shell conveying viscous fluid flow and carrying spring-mass systems under various temperature distributions, [85] M. Mirzaei, Y. Kiani, Isogeometric thermal buckling analysis of temperature dependent FG graphene reinforced laminated plates using NURBS formulation, [86] H.-S. Shen, F. Lin, Y. Xiang, Nonlinear vibration of functionally graded graphene-reinforced composite laminated beams resting on elastic foundations in thermal environments, [87] H.-S. Shen, F. Lin, Y. Xiang, Nonlinear bending and thermal postbuckling of functionally graded graphene-reinforced composite laminated beams resting on elastic foundations, [88] H.-S. Shen, Y. Xiang, Y. Fan, Nonlinear vibration of functionally graded graphene-reinforced composite laminated cylindrical shells in thermal environments, [89] H.-S. Shen, Y. Xiang, F. Lin, Thermal buckling and postbuckling of functionally graded graphene-reinforced composite laminated plates resting on elastic foundations, [90] H.-S. Shen, Y. Xiang, F. Lin, Nonlinear bending of functionally graded graphene-reinforced composite laminated plates resting on elastic foundations in thermal environments, [91] H.-S. Shen, Y. Xiang, F. Lin, Nonlinear vibration of functionally graded graphene-reinforced composite laminated plates in thermal environments, [92] H.-S. Shen, Y. Xiang, F. Lin, D. Hui, Buckling and postbuckling of functionally graded graphene-reinforced composite laminated plates in thermal environments, [93] Y. Fan, Y. Xiang, H.-S. Shen, D. Hui, Nonlinear low-velocity impact response of FG-GRC laminated plates resting on visco-elastic foundations, [94] Y. Fan, Y. Xiang, H.-S. Shen, H. Wang, Low-velocity impact response of FG-GRC laminated beams resting on visco-elastic foundations, [95] E. García-Macías, L. Rodriguez-Tembleque, A. Sáez, Bending and free vibration analysis of functionally graded graphene vs. carbon nanotube reinforced composite plates, [96] Y. Kiani, Isogeometric large amplitude free vibration of graphene reinforced laminated plates in thermal environment using NURBS formulation, [97] Y. Kiani, NURBS-based isogeometric thermal postbuckling analysis of temperature dependent graphene reinforced composite laminated plates, [98] Y. Kiani, M. Mirzaei, Enhancement of non-linear thermal stability of temperature dependent laminated beams with graphene reinforcements, [99] Z. Lei, Q. Su, H. Zeng, Y. Zhang, C. Yu, Parametric studies on buckling behavior of functionally graded graphene-reinforced composites laminated plates in thermal environment, [100] H.-S. Shen, Y. Xiang, Postbuckling behavior of functionally graded graphene-reinforced composite laminated cylindrical shells under axial compression in thermal environments, [101] H.-S. Shen, Y. Xiang, Postbuckling of functionally graded graphene-reinforced composite laminated cylindrical shells subjected to external pressure in thermal environments, [102] H.-S. Shen, Y. Xiang, Y. Fan, Postbuckling of functionally graded graphene-reinforced composite laminated cylindrical panels under axial compression in thermal environments, [103] H.-S. Shen, Y. Xiang, Y. Fan, D. Hui, Nonlinear bending analysis of FG-GRC laminated cylindrical panels on elastic foundations in thermal environments, [104] H.-S. Shen, Y. Xiang, Y. Fan, D. Hui, Nonlinear vibration of functionally graded graphene-reinforced composite laminated cylindrical panels resting on elastic foundations in thermal environments, [105] Y. Fan, Y. Xiang, H.-S. Shen, Nonlinear forced vibration of FG-GRC laminated plates resting on visco-Pasternak foundations, [106] Y. Kiani, Buckling of functionally graded graphene reinforced conical shells under external pressure in thermal environment, [107] Y. Wang, J. Yu, W. Dai, Y. Song, D. Wang, L. Zeng, N. Jiang, Enhanced thermal and electrical properties of epoxy composites reinforced with graphene nanoplatelets, [108] S. Kitipornchai, D. Chen, J. Yang, Free vibration and elastic buckling of functionally graded porous beams reinforced by graphene platelets, [109] M. Song, S. Kitipornchai, J. Yang, Free and forced vibrations of functionally graded polymer composite plates reinforced with graphene nanoplatelets, [110] M. Song, J. Yang, S. Kitipornchai, W. Zhu, Buckling and postbuckling of biaxially compressed functionally graded multilayer graphene nanoplatelet-reinforced polymer composite plates, [111] H. Wu, S. Kitipornchai, J. Yang, Thermal buckling and postbuckling of functionally graded graphene nanocomposite plates, [112] H. Wu, J. Yang, S. Kitipornchai, Dynamic instability of functionally graded multilayer graphene nanocomposite beams in thermal environment, [113] C. Feng, S. Kitipornchai, J. Yang, Nonlinear bending of polymer nanocomposite beams reinforced with non-uniformly distributed graphene platelets (GPLs), [114] J. Yang, H. Wu, S. Kitipornchai, Buckling and postbuckling of functionally graded multilayer graphene platelet-reinforced composite beams, [115] C. Feng, S. Kitipornchai, J. Yang, Nonlinear free vibration of functionally graded polymer composite beams reinforced with graphene nanoplatelets (GPLs), [116] M. R. Barati, A. M. Zenkour, Post-buckling analysis of refined shear deformable graphene platelet reinforced beams with porosities and geometrical imperfection, [117] D. Chen, J. Yang, S. Kitipornchai, Nonlinear vibration and postbuckling of functionally graded graphene reinforced porous nanocomposite beams, [118] B. Yang, S. Kitipornchai, Y.-F. Yang, J. Yang, 3D thermo-mechanical bending solution of functionally graded graphene reinforced circular and annular plates, [119] B. Yang, J. Yang, S. Kitipornchai, Thermoelastic analysis of functionally graded graphene reinforced rectangular plates based on 3D elasticity, [120] M. R. Barati, A. M. Zenkour, Analysis of postbuckling of graded porous GPL-reinforced beams with geometrical imperfection, [121] R. Bahaadini, A. R. Saidi, Aeroelastic analysis of functionally graded rotating blades reinforced with graphene nanoplatelets in supersonic flow, [122] M. R. Barati, A. M. Zenkour, Vibration analysis of functionally graded graphene platelet reinforced cylindrical shells with different porosity distributions, [123] Y. H. Dong, Y. H. Li, D. Chen, J. Yang, Vibration characteristics of functionally graded graphene reinforced porous nanocomposite cylindrical shells with spinning motion, [124] Y. H. Dong, B. Zhu, Y. Wang, Y. H. Li, J. Yang, Nonlinear free vibration of graded graphene reinforced cylindrical shells: Effects of spinning motion and axial load, [125] F. Ebrahimi, M. Habibi, H. Safarpour, On modeling of wave propagation in a thermally affected GNP-reinforced imperfect nanocomposite shell, [126] K. Gao, W. Gao, D. Chen, J. Yang, Nonlinear free vibration of functionally graded graphene platelets reinforced porous nanocomposite plates resting on elastic foundation, [127] R. Gholami, R. Ansari, Nonlinear harmonically excited vibration of third-order shear deformable functionally graded graphene platelet-reinforced composite rectangular plates, [128] R. Gholami, R. Ansari, On the Nonlinear Vibrations of Polymer Nanocomposite Rectangular Plates Reinforced by Graphene Nanoplatelets: A Unified Higher-Order Shear Deformable Model, [129] H. Guo, S. Cao, T. Yang, Y. Chen, Vibration of laminated composite quadrilateral plates reinforced with graphene nanoplatelets using the element-free IMLS-Ritz method, [130] H. Guo, S. Cao, T. Yang, Y. Chen, Geometrically nonlinear analysis of laminated composite quadrilateral plates reinforced with graphene nanoplatelets using the element-free IMLS-Ritz method, [131] S. M. Hosseini, C. Zhang, Coupled thermoelastic analysis of an FG multilayer graphene platelets-reinforced nanocomposite cylinder using meshless GFD method: A modified micromechanical model, [132] K. Li, D. Wu, X. Chen, J. Cheng, Z. Liu, W. Gao, M. Liu, Isogeometric Analysis of functionally graded porous plates reinforced by graphene platelets, [133] Q. Li, D. Wu, X. Chen, L. Liu, Y. Yu, W. Gao, Nonlinear vibration and dynamic buckling analyses of sandwich functionally graded porous plate with graphene platelet reinforcement resting on Winkler–Pasternak elastic foundation, [134] D. Liu, S. Kitipornchai, W. Chen, J. Yang, Three-dimensional buckling and free vibration analyses of initially stressed functionally graded graphene reinforced composite cylindrical shell, [135] M. R. Reddy, W. Karunasena, W. Lokuge, Free vibration of functionally graded-GPL reinforced composite plates with different boundary conditions, [136] M. Song, J. Yang, S. Kitipornchai, Bending and buckling analyses of functionally graded polymer composite plates reinforced with graphene nanoplatelets, [137] A. Wang, H. Chen, Y. Hao, W. Zhang, Vibration and bending behavior of functionally graded nanocomposite doubly-curved shallow shells reinforced by graphene nanoplatelets, [138] Y. Wang, C. Feng, Z. Zhao, F. Lu, J. Yang, Torsional buckling of graphene platelets (GPLs) reinforced functionally graded cylindrical shell with cutout, [139] Y. Wang, C. Feng, Z. Zhao, J. Yang, Eigenvalue buckling of functionally graded cylindrical shells reinforced with graphene platelets (GPL), [140] H. Wu, J. Yang, S. Kitipornchai, Parametric instability of thermo-mechanically loaded functionally graded graphene reinforced nanocomposite plates, [141] B. Yang, J. Mei, D. Chen, F. Yu, J. Yang, 3D thermo-mechanical solution of transversely isotropic and functionally graded graphene reinforced elliptical plates, [142] Z. Yang, J. Yang, A. Liu, J. Fu, Nonlinear in-plane instability of functionally graded multilayer graphene reinforced composite shallow arches, [143] S. Blooriyan, R. Ansari, A. Darvizeh, R. Gholami, H. Rouhi, Postbuckling analysis of functionally graded graphene platelet-reinforced polymer composite cylindrical shells using an analytical solution approach, [144] R. Gholami, R. Ansari, Nonlinear stability and vibration of pre/post-buckled multilayer FG-GPLRPC rectangular plates, [145] M. Haboussi, A. Sankar, M. Ganapathi, Nonlinear axisymmetric dynamic buckling of functionally graded graphene reinforced porous nanocomposite spherical caps, [146] S. Qaderi, F. Ebrahimi, A. Seyfi, An investigation of the vibration of multi-layer composite beams reinforced by graphene platelets resting on two parameter viscoelastic foundation, [147] M. Song, X. Li, S. Kitipornchai, Q. Bi, J. Yang, Low-velocity impact response of geometrically nonlinear functionally graded graphene platelet-reinforced nanocomposite plates, [148] Y. Q. Wang, C. Ye, J. W. Zu, Nonlinear vibration of metal foam cylindrical shells reinforced with graphene platelets, [149] Y. Xu, W. Hong, H. Bai, C. Li, G. Shi, Strong and ductile poly(vinyl alcohol)/graphene oxide composite films with a layered structure, [150] X. Bai, C. Wan, Y. Zhang, Y. Zhai, Reinforcement of hydrogenated carboxylated nitrile–butadiene rubber with exfoliated graphene oxide, [151] T. Jiang, T. Kuila, N. H. Kim, B.-C. Ku, J. H. Lee, Enhanced mechanical properties of silanized silica nanoparticle attached graphene oxide/epoxy composites, [152] S. Chuah, Z. Pan, J. G. Sanjayan, C. M. Wang, W. H. Duan, Nano reinforced cement and concrete composites and new perspective from graphene oxide, [153] Z. Pan, L. He, L. Qiu, A. H. Korayem, G. Li, J. W. Zhu, F. Collins, D. Li, W. H. Duan, M. C. Wang, Mechanical properties and microstructure of a graphene oxide–cement composite, [154] Z. Zhang, Y. Li, H. Wu, H. Zhang, H. Wu, S. Jiang, G. Chai, Mechanical analysis of functionally graded graphene oxide-reinforced composite beams based on the first-order shear deformation theory, [155] F. Ebrahimi, M. Nouraei, A. Dabbagh, Thermal vibration analysis of embedded graphene oxide powder-reinforced nanocomposite plates, [156] E. Thostenson, W. Li, D. Wang, Z. Ren, T. Chou, Carbon nanotube/carbon fiber hybrid multiscale composites, [157] S. Mareishi, M. Rafiee, X. He, K. Liew, Nonlinear free vibration, postbuckling and nonlinear static deflection of piezoelectric fiber-reinforced laminated composite beams, [158] M. Rafiee, X. Liu, X. He, S. Kitipornchai, Geometrically nonlinear free vibration of shear deformable piezoelectric carbon nanotube/fiber/polymer multiscale laminated composite plates, [159] X. He, M. Rafiee, S. Mareishi, K. Liew, Large amplitude vibration of fractionally damped viscoelastic CNTs/fiber/polymer multiscale composite beams, [160] M. Rafiee, F. Nitzsche, M. Labrosse, Rotating nanocomposite thin-walled beams undergoing large deformation, [161] F. Ebrahimi, S. Habibi, Nonlinear eccentric low-velocity impact response of a polymer-carbon nanotube-fiber multiscale nanocomposite plate resting on elastic foundations in hygrothermal environments, [162] M. Rafiee, F. Nitzsche, M. R. Labrosse, Modeling and mechanical analysis of multiscale fiber-reinforced graphene composites: Nonlinear bending, thermal post-buckling and large amplitude vibration, [163] M. K. Hassanzadeh-Aghdam, R. Ansari, A. Darvizeh, Micromechanical analysis of carbon nanotube-coated fiber-reinforced hybrid composites, [164] M.-K. Hassanzadeh-Aghdam, R. Ansari, A. Darvizeh, Multi-stage micromechanical modeling of effective elastic properties of carbon fiber/carbon nanotube-reinforced polymer hybrid composites, [165] X. Shi, M. K. Hassanzadeh-Aghdam, R. Ansari, A comprehensive micromechanical analysis of the thermoelastic properties of polymer nanocomposites containing carbon nanotubes with fully random microstructures, [166] R. Gholami, R. Ansari, Nonlinear bending of third-order shear deformable carbon nanotube/fiber/polymer multiscale laminated composite rectangular plates with different edge supports, [167] F. Ebrahimi, A. Dabbagh, On thermo-mechanical vibration analysis of multi-scale hybrid composite beams, [168] M. Rafiee, F. Nitzsche, J. Laliberte, S. Hind, F. Robitaille, M. R. Labrosse, Thermal properties of doubly reinforced fiberglass/epoxy composites with graphene nanoplatelets, graphene oxide and reduced-graphene oxide, [169] A. Dabbagh, A. Rastgoo, F. Ebrahimi, Finite element vibration analysis of multi-scale hybrid nanocomposite beams via a refined beam theory, [170] F. Ebrahimi, A. Dabbagh, Vibration analysis of graphene oxide powder-/carbon fiber-reinforced multi-scale porous nanocomposite beams: A finite-element study, [171] M. Karimiasl, F. Ebrahimi, B. Akgöz, Buckling and post-buckling responses of smart doubly curved composite shallow shells embedded in SMA fiber under hygro-thermal loading, [172] M. Karimiasl, F. Ebrahimi, V. Mahesh, Nonlinear free and forced vibration analysis of multiscale composite doubly curved shell embedded in shape-memory alloy fiber under hygrothermal environment, [173] M. Karimiasl, F. Ebrahimi, M. Vinyas, Nonlinear vibration analysis of multiscale doubly curved piezoelectric composite shell in hygrothermal environment, | ||

آمار تعداد مشاهده مقاله: 2,527 تعداد دریافت فایل اصل مقاله: 1,139 |