Modeling the thermal behavior of functionally graded media with a spherical gap: rectified sine wave heating via fourth-order Moore–Gibson–Thompson model

IF 2.1 4区材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Mechanics of Time-Dependent Materials Pub Date : 2024-03-28 DOI:10.1007/s11043-024-09688-2

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Abstract

The main objective of this work is to introduce a new thermal conductivity model that can be utilized to solve the infinite thermal diffusion problem in the Green and Naghdi type III model. This proposed model incorporates two key concepts: the fourth-order Moore–Gibson–Thompson (MGT) concept and thermal relaxation. By incorporating higher-order terms, the fourth-order MGT model provides a more accurate representation of the thermal behavior of the material. The thermal behavior of a functionally graded (FG) infinite medium containing a spherical gap is then studied using this model. A rectified sine wave heating system is applied to the traction-free gap surface. Power functions are utilized to model the uniform radial variation of the physical properties of the FG medium. The physical variables under investigation were meticulously examined, considering the impacts of heterogeneity, relaxation duration, and thermal frequency. These variables were estimated numerically using a suitable technique for Laplace transformations. Through this work, the expected outcomes may be able to make a significant contribution to the field of thermoelastic analysis in advanced and FG materials, as well as to engineering applications.

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带有球形间隙的功能分级介质热行为建模：通过四阶摩尔-吉布森-汤普森模型进行正弦波整流加热

摘要本文的主要目的是介绍一种新的导热模型，该模型可用于解决格林和纳格迪 III 型模型中的无限热扩散问题。该模型包含两个关键概念：四阶摩尔-吉布森-汤普森（MGT）概念和热松弛。通过纳入高阶项，四阶 MGT 模型能更准确地表示材料的热行为。然后，利用该模型研究了含有球形间隙的功能分级（FG）无限介质的热行为。无牵引间隙表面采用整流正弦波加热系统。利用幂函数来模拟 FG 介质物理特性的均匀径向变化。考虑到异质性、松弛持续时间和热频率的影响，对所研究的物理变量进行了细致的检查。使用拉普拉斯变换的适当技术对这些变量进行了数值估算。通过这项工作，预期成果可能会对先进材料和 FG 材料的热弹性分析领域以及工程应用做出重大贡献。

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来源期刊

Mechanics of Time-Dependent Materials 工程技术-材料科学：表征与测试

CiteScore

4.90

自引率

8.00%

发文量

审稿时长

>12 weeks

期刊介绍： Mechanics of Time-Dependent Materials accepts contributions dealing with the time-dependent mechanical properties of solid polymers, metals, ceramics, concrete, wood, or their composites. It is recognized that certain materials can be in the melt state as function of temperature and/or pressure. Contributions concerned with fundamental issues relating to processing and melt-to-solid transition behaviour are welcome, as are contributions addressing time-dependent failure and fracture phenomena. Manuscripts addressing environmental issues will be considered if they relate to time-dependent mechanical properties. The journal promotes the transfer of knowledge between various disciplines that deal with the properties of time-dependent solid materials but approach these from different angles. Among these disciplines are: Mechanical Engineering, Aerospace Engineering, Chemical Engineering, Rheology, Materials Science, Polymer Physics, Design, and others.