Linear Static Behavior of Damaged Laminated Composite Plates and Shells

Tornabene, Francesco; Fantuzzi, Nicholas; Bacciocchi, Michele

doi:10.3390/ma10070811

Cited by 29 publications

(18 citation statements)

References 130 publications

(187 reference statements)

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“…3 (carbon atoms are demonstrated in darker color in SiCNT structure). Nanotubes have been modeled as plate, shell, rod, and beam in literature [23][24][25][26][27][28][29][30] to make bending [31,32], buckling [33] , vibration [34] analyses possible theoretically. In this paper, nanotubes are modeled as cylindrical beam by using Euler-Bernoulli beam model.…”

Section: Fig 1 Obtaining Nanotubesmentioning

confidence: 99%

Comparison of small scale effect theories for buckling analysis of nanobeams

Mercan¹,

Cívalek²

2017

International Journal of Engineering &Amp; Applied Sciences

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Theories which consider small scale effect have a great importance on analysis in micro and nano scale. In present paper, three kind of nanotubes (Carbon Nanotube (CNT), Boron Nitride Nanotube (BNNT), and Silicon Carbide Nanotube (SiCNT)) are analyzed in case of buckling on two parameters elastic foundation. Three different small scale theories (Nonlocal Elasticity Theory (NET), Surface Elasticity Theory (SET), and Nonlocal Surface Elasticity Theory (NET&SET)) are applied to calculate the buckling loads. Also Classical Euler-Bernoulli Beam Theory (CT) is used to see the effect of small scale effective theories. Comparative results are given for simply supported nanotubes in figures.

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Section: Fig 1 Obtaining Nanotubesmentioning

confidence: 99%

Comparison of small scale effect theories for buckling analysis of nanobeams

Mercan¹,

Cívalek²

2017

International Journal of Engineering &Amp; Applied Sciences

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“…As far as two-dimensional domains are concerned, the present approach can be easily generalized as shown in [23,117]. In these circumstances, the grid distribution (63) is applied along the main directions α 1 , α 2 by specifying the number of discrete points as I N , I M , respectively.…”

Section: Numerical Techniquementioning

confidence: 99%

“…Advanced composite materials are mainly developed to design stiffer and lighter structures, characterized by an improved and more efficient mechanical behavior. Among them, fiber-reinforced media [1][2][3][4], laminated and sandwich composites [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24], Functionally Graded Materials (FGMs) [25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41], nanocomposites [42][43][44][45][46] and metamaterials [47][48][49][50]…”

Section: Introductionmentioning

confidence: 99%

Effect of Curvilinear Reinforcing Fibers on the Linear Static Behavior of Soft-Core Sandwich Structures

Tornabene

Bacciocchi

2018

J. Compos. Sci.

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The present research deals with the linear static behavior of soft-core sandwich plates and shells. The external skins are reinforced by curvilinear fibers. Their curved paths are described by a general mathematical law that allows the definition of arbitrary placements. The mechanical behavior of these structures is modeled through several Higher-order Shear Deformation Theories (HSDTs) including the zig-zag effect, based on an Equivalent Single Layer (ESL) approach. The solution of the governing equations is achieved numerically by means of the Generalized Differential Quadrature (GDQ) method. A huge number of parametric investigations is proposed in graphical and tabular forms to highlight the influence of the fiber orientation on the static response. The results prove that the structural behavior is affected by such parameters. Thus, the desired structural behavior can be modified by means of a proper choice of the fiber orientation. was investigated by Gürdal and Olmedo [60] to evaluate the stiffness variation effect on the elastic response of the structure. In their work, the orientation of the fibers was defined by two parameters, which consisted of the fiber angle at the center of the laminate and the fiber angle at a specified distance from the center. The manufacturing process of the proposed approach was progressively studied by Waldarth et al. [61], Setoodeh and Gürdal [62], and Setoodeh et al. [63,64]. Jegley et al. [65] proved that the load carrying capability of panels reinforced by curvilinear fibers was superior to the one that characterized panels with straight fibers. Analogously, the stress concentrations around the hole were reduced due to the curvilinear paths of the fibers. Abdalla et al. [66] developed a maximization procedure for the natural frequency of composite panels reinforced by curved fibers. The post-buckling progressive damage behavior and the structural failure of variable-stiffness composite panels were studied by Lopes et al. [67] taking into account the residual thermal stresses caused by the curing process. Gürdal et al. [68] investigated the in-plane and buckling responses of flat rectangular composite laminates with variable stiffness. Their research proved that it was possible to vary either the buckling load or the in-plane stiffness of the structure. The variable-stiffness concept and the two-parameter law for the fiber orientation were extended also to conical and cylindrical shells by Blom et al. [69-71]. Akhavan and Ribeiro [72] investigated the natural frequencies and vibrational modes of variable-stiffness laminated composite plates reinforced by curvilinear fibers by means of a p-version finite element approach. The same topic was analyzed also by Honda and Narita [73], who proposed an analytical method for this purpose. Díaz et al. [74] presented a numerical method for obtaining the interlaminar stresses in variable stiffness composite panels. Coburn et al. [75] highlighted the improved buckling performances of variable-stiffness laminates compared to the ones re...

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“…These structures usually consist of a thick low strength core and two thin stiff outer face sheets. The face sheets have been designed to resist the applied loads and the core layer is employed to stabilize the structure and to withstand shear loads . Due to the high strength‐to‐weight ratio and corrosive resistances of sandwich structures, they are widely used in various industrial applications such as aerospace, automobile, and biomechanics .…”

Section: Introductionmentioning

confidence: 99%

Stress distributions in nanocomposite sandwich cylinders reinforced by aggregated carbon nanotube

et al. 2019

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In order to improve the static response of thick hollow cylinders, a sandwich cylinder with two carbon nanotube (CNT)‐reinforced nanocomposite face sheets are proposed in this article. Moreover, due to the use of optimum amount of high cost CNTs, the CNT distribution is suggested to be functionally graded (FG) along the thickness of cylinder. The stress and deflection profiles of the proposed sandwich cylinders subjected to internal and external pressures have been investigated using a finite element method (FEM) based on an axisymmetric model. The significant effect of formation of CNT agglomerations in the surrounded matrix is considered and the material properties of the resulted nanocomposite are estimated by Eshelby‐Mori‐Tanaka approach. Using the developed axisymmetric FEM model, the effects of CNT aggregation state, volume fraction, and distribution as well as geometrical dimension and loading condition on the stress and deflection distributions of the nanocomposite sandwich cylinders have been characterized. The extensive simulations have revealed that instead of adding higher volume fraction of CNT, the selection of suitable distribution for CNTs can lead to a nanocomposite sandwich cylinder with less deflection. POLYM. COMPOS., 40:E1918–E1927, 2019. © 2019 Society of Plastics Engineers

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Linear Static Behavior of Damaged Laminated Composite Plates and Shells

Cited by 29 publications

References 130 publications

Comparison of small scale effect theories for buckling analysis of nanobeams

Comparison of small scale effect theories for buckling analysis of nanobeams

Effect of Curvilinear Reinforcing Fibers on the Linear Static Behavior of Soft-Core Sandwich Structures

Stress distributions in nanocomposite sandwich cylinders reinforced by aggregated carbon nanotube

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