Abstract
Buckling and vibration study of the shape memory polymer composites (SMPC) across the glass transition temperature under heterogeneous loading conditions are presented. Finite element analysis based on C° continuity equation through the higher order shear deformation theory (HSDT) is employed considering non linear Von Karman approach to estimate critical buckling and vibration for the temperature span from 273 to 373 K. Extensive numerical investigations are presented to understand the effect of temperature, boundary conditions, aspect ratio, fiber orientations, laminate stacking and modes of phenomenon on the buckling and vibration behavior of SMPC beam along with the validation and convergence study. Effect of thermal conditions, particularly in the glass transition region of the shape memory polymer, is considerable and presents cohesive relation between dynamic modulus properties with magnitude of critical buckling and vibration. Moreover, it has also been inferred that type of axial loading condition along with the corresponding boundary conditions significantly affect the buckling and vibration load across the glass transition region.
Highlights
Shape memory polymers (SMP) possess the feature to deform under the application of stress and regain its original orientation in the vicinity of a stimulus such as electricity, magnetic field, heat, chemical or moisture [1]
Buckling and vibration behavior of shape memory polymer composites (SMPC) beam subjected to axially heterogeneous in-plane loading conditions are analyzed in this paper through C° continuity based Higher order shear deformation theory (HSDT) using Von Karman non-linearity
It was noticed that temperature significantly controls the buckling and vibrations of the SMPC, in the glass transition region of the matrix, because of its volatile behavior
Summary
Shape memory polymers (SMP) possess the feature to deform under the application of stress and regain its original orientation in the vicinity of a stimulus such as electricity, magnetic field, heat, chemical or moisture [1]. SMPC beams are constantly subjected to numerous elastic instabilities, among which buckling and vibration would be focus of analysis in this paper. As per the available literature, the study the buckling and vibration phenomenon with their mode-shapes for SMPC beams under the axially heterogeneous in-plane loads has rarely been studied. In the present study, buckling and vibration analysis of SMPC laminated beams subjected to axially varying in-plane load has been investigated. The paper presents buckling and vibrations analysis of SMPC beam for different boundary conditions, aspect ratio, fiber orientation, laminate stacking and modes of phenomenon.
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