Nonlinear static and dynamic performance of CNT reinforced and nanoclay modified laminated nanocomposite plate

Abstract

Under static and dynamic loading circumstances, the mechanically and thermo-initiated nonlinear static and dynamic assessment of the bending response of single-walled carbon nanotubes' (CNTs') fibers with a nanoclay particle reinforced polymer hybrid laminated composite plate is investigated. To evaluate the effective elastic characteristics of the CNTs' fibers on the nanoclay particle modified polymer hybrid laminated plate, a modified Halpin-Tsai method is applied in an orthotropic way. The theory of higher-order shear deformation and complete kinematics (nonlinear) are used to develop the fundamental nonlinear dynamic formulation. A user-interactive finite element method-based MATLAB program solves the governing equations for nonlinear dynamic systems utilizing Newmark's period integration and the Newton-Raphson method. The effects of variation in the quantity of CNTs' fibers and particles of nanoclay, presence of interphases around CNTs' fibers and nanoclay particles, variation in phases of the CNTs' fibers on the nanoclay particle modified polymer hybrid laminated plate, and variation in plies of the laminated hybrid plate under clamped and simply supported conditions on the transverse central deflection response are explored in depth.