Abstract
We provide an analytical investigation of the nonlinear vibration behavior of thick sandwich nanocomposite beams reinforced by functionally graded (FG) graphene nanoplatelet (GPL) sheets, with a power-law-based distribution throughout the thickness. We assume the total amount of the reinforcement phase to remain constant in the beam, while defining a relationship between the GPL maximum weight fraction, the power-law parameter, and the thickness of the face sheets. The shear and rotation effects are here considered using a higher-order laminated beam model. The nonlinear partial differential equations (PDEs) of motion are derived from the Von Kármán strain-displacement relationships, here solved by applying an expansion of free vibration modes. The numerical results demonstrate the key role of the amplitudes on the vibration response of GPL-reinforced sandwich beams, whose nonlinear oscillation behavior is very important in the physical science, mechanical structures and other mathematical analyses. The sensitivity of the response to the total amount of GPLs is explored herein, along with the possible effects related to the power-law parameter, the structural geometry, and the environmental conditions. The results indicate that changing the nanofiller distribution patterns with the proposed model can remarkably increase or decrease the effective stiffness of laminated composite beams.
Highlights
Sandwich structures, generally made of a soft core and two hard face sheets, are largely used in the aerospace, oil, gas, and petrochemical industries, due to their enhanced mechanical properties, namely, a high strength-to-weight ratio and a high resistance to heat, humidity, and noise [1,2,3,4,5]
graphene nanoplatelet (GPL)-reinforced sandwich beams, whose nonlinear oscillation behavior is very important in the physical science, mechanical structures and other mathematical analyses
The sensitivity of the response to the total amount of GPLs is explored along with the possible effects related to the power-law parameter, the structural geometry, and the environmental conditions
Summary
Generally made of a soft core and two hard face sheets, are largely used in the aerospace, oil, gas, and petrochemical industries, due to their enhanced mechanical properties, namely, a high strength-to-weight ratio and a high resistance to heat, humidity, and noise [1,2,3,4,5]. The presence of some reinforcing layers in sandwich structures represents one important issue to consider for a general improvement of their mechanical properties [21,22,23,24]. With the advancement of nanotechnology, carbon nanotubes (CNTs) and graphene sheets (GSs) are two alternative options for the reinforcement of structures, due to their extraordinary properties. This has led to an extensive research on the behavior of sandwich structures reinforced with nanocomposites [25,26,27,28]
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