A general approach to the mechanical analysis of continuous local inhomogeneity using continuum mechanics theory and a new general energy-based-model

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
Saeed Shahsavari, S.M.A. Boutorabi
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引用次数: 0

Abstract

While usually we don't know complete geometrical and physical information on the occurred inhomogeneity, but in order to study the related phenomena, continuum mechanics theory as well as exiting energy-based models need direct information from the desired system in order to A General Approach to the Mechanical Analysis of Continuous Local Inhomogeneity Using Continuum Mechanics Theory and A New General Energy-Based- Modelapply the field equations. Of course, theories and ideas based on the unification of mechanics and thermodynamics can offer other solutions. This paper establishes a general energy based model to study effects of local inhomogeneity on the mechanical behavior of materials using thermodynamic laws with a new deviation as well as new approach to the total energy. In fact, the main goal is that the established model can be used with a wide range of applications and appropriate accuracy, both theoretically and experimentally, while not getting involved with excessive computational complexity. It can be noted that the extracted formulations develop possibility to study inhomogeneity effects on the mechanical behavior without any more limiting conditions. In addition, due to that study of the stored and dissipated energy, usually, has the main role in the investigating of the inhomogeneity effects on the mechanical behavior, also the point of view in the presented model is in complete agreement to provide the conditions for this study directly. Therefore, the prediction possibility of the inhomogeneity effects on the mechanical behavior will be provided with the smallest volume of needed calculations. Also, due to that the structure and properties of the inhomogeneity are unknown usually, the formulations aren't dependent to these knowledge directly, and can be analyzed theoretically and experimentally to study the homogeneity part, as a known material. In the following, feasible processes are studied using extracted formulations. To validate the equations, a rectangular material shape with local inhomogeneity is considered, and extracted equations are developed for that. To consider our mean on the stored and dissipated energies, it is assumed that the homogeneity part of material has viscoelastic behavior, and the equations are developed to Maxwell and Kelvin viscoelastic models in different homogeneity parts of the body. In the following, classical continuum mechanic theory due to elasticity theory is used, and the field equations are developed to the considered body. Finally, results are discussed, compared as well as their differences, and corresponding capabilities for functional completion are discussed. Finally, the fundamental equivalence of the results is studied, and matching of the results between continuum mechanics theory and extracted formulations is shown.

用连续力学理论和一种新的基于能量的通用模型对连续局部不均匀性进行力学分析的通用方法
虽然我们通常不知道发生的不均匀性的完整几何和物理信息,但为了研究相关现象,连续体力学理论以及现有的基于能量的模型需要来自所需系统的直接信息,以便使用连续体力学理论对连续局部不均匀性进行力学分析的通用方法和一种新的基于能量模型应用场方程。当然,基于力学和热力学统一的理论和思想可以提供其他解决方案。本文建立了一个基于能量的通用模型,利用具有新偏差的热力学定律以及总能量的新方法来研究局部不均匀性对材料力学行为的影响。事实上,主要目标是所建立的模型可以在理论和实验上具有广泛的应用和适当的精度,同时不涉及过多的计算复杂性。可以注意到,提取的配方开发了在没有任何更多限制条件的情况下研究不均匀性对机械行为的影响的可能性。此外,由于对储存和耗散能量的研究通常在研究不均匀性对力学行为的影响方面发挥着主要作用,因此所提出的模型中的观点完全一致,可以直接为这项研究提供条件。因此,不均匀性对机械行为影响的预测可能性将以所需计算的最小体积提供。此外,由于不均匀性的结构和性质通常是未知的,因此配方不直接依赖于这些知识,可以从理论和实验上进行分析,以研究作为已知材料的均匀性部分。在下文中,使用提取的配方研究了可行的工艺。为了验证方程,考虑了具有局部不均匀性的矩形材料形状,并为此开发了提取的方程。为了考虑我们对储存和耗散能量的平均值,假设材料的均质部分具有粘弹性行为,并将方程发展为身体不同均质部分的Maxwell和Kelvin粘弹性模型。在下文中,使用了由弹性理论引起的经典连续介质力学理论,并将场方程发展到被考虑的物体。最后,对结果进行了讨论、比较以及它们的差异,并讨论了相应的功能完成能力。最后,研究了结果的基本等价性,并表明了连续介质力学理论和提取的公式之间的结果匹配性。
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
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
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68 days
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