Abstract
In this paper, the vibration analysis of a partially constrained layer damping plate subjected to moving loads is investigated. In addition, the first four order damping loss factor of the system is optimized with the location of partially constrained layer damping as a design variable. The equations of motion of a partially constrained layer damping plate are derived through the Lagrange equation based on first order shear deformation theory (FSDT). Next, using an extended Rayleigh–Ritz solution together with the penalty method expresses the unknown displacement terms, and the differential quadrature method is proposed to obtain the dynamic response of the system in the time domain. A multi-population genetic algorithm (MPGA) is employed to deal with the optimization of the damping loss factor of a partially constrained layer damping plate. To ensure the accuracy of the method presented in this study, the numerical results are comprehensively verified by experiments and open literature. The optimization results show that the damping loss factor increases when the position of the patch is close to the constraint boundary, and the best strategy is to optimize the low order damping loss factor of the system under moving loads. It is believed that the research results are of interest to engineering science.
Highlights
Lee et al [34] studied the dynamic analysis of composite plates under multi-moving loads based on a third order shear deformation theory (TSDT) and applied the 7-DOF finite element model to analyze the vibration problem
This study investigated the dynamic response analysis of a thin plate with partially constrained layer damping optimization under the moving loads for various boundary conditions
A numerical dynamic model of a partially covered plate under moving loads was established based on the Lagrange equation
Summary
Damping technology is one of the important methods to reduce the vibration and improve the performance of many engineering structures. Zheng et al [24] studied an optimization model to minimize the vibrational energy of a sandwich beam and employed a genetic algorithm-based penalty function to obtain the optimal solutions. This paper deals with the optimal location of the constrained damping layer of a sandwich plate to maximize the damping loss factor by using a multi-population genetic algorithm (MPGA). Lee et al [34] studied the dynamic analysis of composite plates under multi-moving loads based on a third order shear deformation theory (TSDT) and applied the 7-DOF finite element model to analyze the vibration problem. This study investigated the dynamic response analysis of a thin plate with partially constrained layer damping optimization under the moving loads for various boundary conditions. The relationship between the optimization of the damping loss factor and the dynamic response is performed
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