Primary resonance of double-curved nanocomposite shells using nonlinear theory and multi-scales method: Modeling and analytical solution
Abstract
In this article, the forced vibration of double-curved nanocomposite shells under a time dependent excitation
is studied using nonlinear shell theory and multi-scales method in primary resonance. The nanocomposite
representative volume element consists of two phases, including carbon nanotube (CNT) and matrix. By
generalizing the Ambartsumyan’s first order shear deformation shell theory (FSDT) to the heterogeneous
nanocomposite shells, the nonlinear partial differential equations are derived. Then, the problem is reduced to
the nonlinear forced vibration of damped nanocomposite shells with quadratic and cubic nonlinearities. For
the occurrence of the primary resonance, the damping, nonlinearity, and excitation terms in the disturbance
circuit are reduced to the same order. Applying the multi-scales method to nonlinear ordinary differential
equation, nonlinear frequency–amplitude dependence in primary resonance is obtained.
Volume
137Collections
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