Investigation of accelerated moving load on dynamic response of FG Timoshenko nanobeam in thermal environment based on nonlocal strain gradient theory

IF 3.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Mohammadreza Eghbali , Seyed Amirhosein Hosseini
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Abstract

For the first time, this paper investigates the forced vibrations of a functionally graded (FG) nanobeam with an accelerating moving load in a thermal environment. There is no exact coupling solution for the vibrations of nanobeam with an accelerated moving load, so this paper aims to provide a method to obtain an accurate solution for nanoscale structures with an accelerated moving load. The equations of motion are derived using Timoshenko's beam theory and the nonlocal strain gradient theory (NSGT). The Laplace method has been used to solve the coupling and exact differential equations. Then, by inverting Laplace from the coupled equations, an exact solution of the temporal response for FG nanobeam with constant acceleration and initial velocity in a thermal environment was obtained. The natural frequency was compared with previous works for validity and had acceptable results. Finally, the effect of parameters such as changes in acceleration and velocity of moving force, negative acceleration, power law index of FG material, different temperatures, nonlocal parameter, and longitudinal scale parameter on the maximum dynamic displacement of nanobeam is investigated. These results can be used better to design FG nanostructures with accelerated moving loads. Considering the sensitivity of data analysis in nano dimensions, it is necessary to provide an analytical solution method in these dimensions to reduce the error percentage in nano dimensions to zero. which is presented in this work for the first time.

基于非局部应变梯度理论的加速运动载荷对热环境中 FG Timoshenko 纳米梁动态响应的影响研究
本文首次研究了热环境中带有加速运动载荷的功能分级(FG)纳米梁的受迫振动。目前还没有加速运动载荷下纳米梁振动的精确耦合解,因此本文旨在提供一种方法,以获得加速运动载荷下纳米结构的精确解。本文利用季莫申科梁理论和非局部应变梯度理论(NSGT)推导出运动方程。拉普拉斯法用于求解耦合和精确微分方程。然后,通过对耦合方程进行拉普拉斯反演,得到了在热环境中具有恒定加速度和初速度的 FG 纳米梁的时间响应精确解。固有频率与之前的研究进行了有效性比较,结果是可以接受的。最后,研究了运动力的加速度和速度变化、负加速度、FG 材料的幂律指数、不同温度、非局部参数和纵向尺度参数等参数对纳米梁最大动态位移的影响。这些结果可以更好地用于设计具有加速运动载荷的 FG 纳米结构。考虑到纳米尺寸数据分析的敏感性,有必要提供纳米尺寸的分析求解方法,以将纳米尺寸的误差率降至零。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Forces in mechanics
Forces in mechanics Mechanics of Materials
CiteScore
3.50
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52 days
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