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Parametric Random Vibration Analysis of an Axially Moving Laminated Shape Memory Alloy Beam Based on Monte Carlo Simulation

Ying Hao, Ming Gao, Jiajie Gong

2022Materials13 citationsDOIOpen Access PDF

Abstract

The study of the bifurcation, random vibration, chaotic dynamics, and control of laminated composite beams are research hotspots. In this paper, the parametric random vibration of an axially moving laminated shape memory alloy (SMA) beam was investigated. In light of the Timoshenko beam theory and taking into consideration axial motion effects and axial forces, a random dynamic equation of laminated SMA beams was deduced. The Falk's polynomial constitutive model of SMA was used to simulate the nonlinear random dynamic behavior of the laminated beam. Additionally, the numerical of the probability density function and power spectral density curves was obtained through the Monte Carlo simulation. The results indicated that the large amplitude vibration character of the beam can be caused by random perturbation on axial velocity.

Topics & Concepts

Axial symmetryMonte Carlo methodParametric statisticsBeam (structure)VibrationTimoshenko beam theoryRandom vibrationShape-memory alloyMaterials scienceNonlinear systemAmplitudeStructural engineeringMechanicsPhysicsComputer simulationProbability density functionEquations of motionSpectral densityNumerical analysisMultiple-scale analysisVibration and Dynamic AnalysisAeroelasticity and Vibration ControlShape Memory Alloy Transformations
Parametric Random Vibration Analysis of an Axially Moving Laminated Shape Memory Alloy Beam Based on Monte Carlo Simulation | Litcius