Fractional dual-phase-lag thermal-mechanical response of an functionally graded spherical microshell with size-dependent effect

Wei Peng, Baocai Pan
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Abstract

Functionally graded materials (FGM) have attracted much attention due to their superior thermal shock resistance in extreme thermal environment. In addition, the memory-dependent feature of transient heat transfer progress can’t be reflected in the frame of integer-order heat conduction model due to the inability of depicting the effect of the past states on the current state. It is noticed that the size-dependent effect of elastic deformation has become significant due to the development of micro-devices. To describe the memory-dependent effect and the size-dependent effect in the functionally graded microstructures, the work aims a thermoelastic model by incorporating the fractional dual-phase-lag heat conduction model and the Eringen’s nonlocal model. To illustrate its application values, the modified model is used to investigate the dynamic performance of an functionally graded spherical microshell subjected to a thermal-mechanical loading. Governing equations including the modified parameters are derived and solved by Laplace transformation. The achieved results show that considering the influences of nonlocal effect and ceramic composition will reduce the thermal deformation under ultrafast heating condition.
具有尺寸依赖效应的功能分级球形微壳的分数双相滞后热机械响应
功能梯度材料(FGM)因其在极端热环境下卓越的抗热震性而备受关注。此外,由于无法描述过去状态对当前状态的影响,整阶热传导模型框架无法反映瞬态传热过程的记忆依赖特征。人们注意到,随着微器件的发展,弹性变形的尺寸依赖效应变得越来越显著。为了描述记忆效应和尺寸效应在功能分级微结构中的影响,该研究通过结合分数双相滞后热传导模型和 Eringen 非局部模型,建立了一个热弹性模型。为了说明该模型的应用价值,我们使用修改后的模型研究了功能分级球形微壳在热机械载荷作用下的动态性能。通过拉普拉斯变换推导并求解了包括修改参数在内的支配方程。结果表明,考虑非局部效应和陶瓷成分的影响将减少超快加热条件下的热变形。
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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