Free Vibration of Grid-Stiffened Composite Cylindrical Shell Reinforced with Carbon Nanotubes

被引:16
作者
Azarafza, R. [1 ]
Davar, Al. [1 ]
Fayez, M. S. [1 ]
Jam, J. E. [1 ]
机构
[1] Malek Ashtar Univ Technol, Fac Mat & Mfg Technol, Tehran, Iran
来源
MECHANICS OF COMPOSITE MATERIALS | 2020年 / 56卷 / 04期
关键词
composite; nanotube; vibration; grid stiffening; cylindrical shell; MECHANICAL-PROPERTIES; DYNAMIC-RESPONSE; BEHAVIOR; SINGLE;
D O I
10.1007/s11029-020-09899-x
中图分类号
O3 [力学];
学科分类号
08 ; 0801 ;
摘要
A linear free vibration analysis is presented for computing the natural frequencies of a grid-stiffened carbon-nanotube-reinforced composite cylindrical shell. The carbon nanotubes (CNTs) are supposed to be oriented unidirectionally across the shell thickness, and the elastic moduli of the CNT-reinforced polymer composite are calculated using a modified rule of mixtures. In order to obtain the equivalent stiffness parameters of the grid-stiffened cylindrical shell, the smeared stiffness method is employed. The stiffeners are assumed to support the transverse shear loads, bending moments, and axial loads. An analytical method based on the first-order shear deformation theory is used. To validate the results obtained, a 3-D finite-element model is employed using the ABAQUS CAE software.
引用
收藏
页码:505 / 522
页数:18
相关论文
共 37 条
[1]   Mechanical and electrical properties of a MWNT/epoxy composite [J].
Allaoui, A ;
Bai, S ;
Cheng, HM ;
Bai, JB .
COMPOSITES SCIENCE AND TECHNOLOGY, 2002, 62 (15) :1993-1998
[2]   Prediction of dynamic behaviour of FGM shells under arbitrary boundary conditions [J].
Ansari, R. ;
Darvizeh, M. .
COMPOSITE STRUCTURES, 2008, 85 (04) :284-292
[3]   A Study on Effect of Waviness on Mechanical Properties of Multi-Walled Carbon Nanotube/Epoxy Composites Using Modified Halpin-Tsai Theory [J].
Arasteh, R. ;
Omidi, M. ;
Rousta, A. H. A. ;
Kazerooni, H. .
JOURNAL OF MACROMOLECULAR SCIENCE PART B-PHYSICS, 2011, 50 (12) :2464-2480
[4]   Fabrication, Experimental Modal Testing, and a Numerical Analysis of Composite Sandwich Structures with a Grid-Stiffened Core [J].
Azarafza, R. .
MECHANICS OF COMPOSITE MATERIALS, 2018, 54 (04) :537-544
[5]   Small but strong: A review of the mechanical properties of carbon nanotube-polymer composites [J].
Coleman, Jonathan N. ;
Khan, Umar ;
Blau, Werner J. ;
Gun'ko, Yurii K. .
CARBON, 2006, 44 (09) :1624-1652
[6]   Multiwalled carbon nanotube/polymer nanocomposites:: Processing and properties [J].
Dalmas, F ;
Chazeau, L ;
Gauthier, C ;
Masenelli-Varlot, K ;
Dendievel, R ;
Cavaillé, JY ;
Forró, L .
JOURNAL OF POLYMER SCIENCE PART B-POLYMER PHYSICS, 2005, 43 (10) :1186-1197
[7]   Free Vibration Analysis of Rotating Stiffened Composite Cylindrical Shells by using the Layerwise-Differential Quadrature (LW-DQ) Method [J].
Daneshjou, K. ;
Talebitooti, M. .
MECHANICS OF COMPOSITE MATERIALS, 2014, 50 (01) :21-38
[8]   A COMPARATIVE REVIEW STUDY ON THE MANUFACTURING PROCESSES OF COMPOSITE GRID STRUCTURES [J].
Fadavian, A. ;
Davar, A. ;
Jam, J. E. ;
Taghavian, S. H. .
METALLURGICAL & MATERIALS ENGINEERING, 2015, 21 (02) :79-88
[9]   Free vibration of CFRC lattice-core sandwich cylinder with attached mass [J].
Han, Yongshuai ;
Wang, Peng ;
Fan, Hualin ;
Sun, Fangfang ;
Chen, Liming ;
Fang, Daining .
COMPOSITES SCIENCE AND TECHNOLOGY, 2015, 118 :226-235
[10]   Experimental, numerical and analytical investigation of free vibrational behavior of GFRP-stiffened composite cylindrical shells [J].
Hemmatnezhad, M. ;
Rahimi, G. H. ;
Tajik, M. ;
Pellicano, F. .
COMPOSITE STRUCTURES, 2015, 120 :509-518
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