Development of Micro-mechanical Constitutive Model for Alumina at High Strain Rates Using Unified Mechanics Theory

Procedia Structural Integrity Pub Date : 2024-01-01 DOI:10.1016/j.prostr.2024.05.043

Brahmadathan V B , Lakshmana Rao C

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Abstract

Ceramic materials used in mechanical applications show variations in their properties due to the presence of cracks. Micro-cracks within the material (size, orientation and density) affect the ceramic material’s strength and other mechanical properties. This study developed a micro-mechanics-based model that accounts for the original orientation of micro-cracks and their propagation as wing cracks. Unlike other micromechanics-based models, the current model defines failure based on entropy associated with crack propagation within the material. Entropy is calculated from energy dissipation from crack propagation from the pre-existing flaws in the ceramic. The Unified Mechanics Theory (UMT) is used to define entropy-based damage in the ceramic material, in which a parameter called thermodynamic state index (TSI) is employed to describe the state of the material. A representative volume element (RVE) with a pre-existing flaw is used to calculate the energy dissipated during the wing crack propagation. The effect of various crack lengths and orientations is incorporated with a probability density function. The strain rate effects are implemented using dynamic crack growth law. The stress-strain curve at strain rate from quasi-static to high strain rate (10^-3-10⁶) is plotted for Alumina under dynamic compression.

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利用统一力学理论开发高应变速率下氧化铝的微观力学结构模型

机械应用中使用的陶瓷材料会因裂纹的存在而导致性能变化。材料内部的微裂纹（尺寸、方向和密度）会影响陶瓷材料的强度和其他机械性能。本研究开发了一种基于微观力学的模型，该模型考虑了微裂纹的原始取向及其作为翼状裂纹的扩展。与其他基于微观力学的模型不同，目前的模型是根据与材料内部裂纹扩展相关的熵来定义失效的。熵是根据陶瓷中预先存在的缺陷所产生的裂纹扩展能量消耗计算得出的。统一力学理论（UMT）用于定义陶瓷材料中基于熵的破坏，其中采用了一个称为热力学状态指数（TSI）的参数来描述材料的状态。使用预先存在缺陷的代表性体积元素（RVE）来计算翼裂纹扩展过程中耗散的能量。各种裂纹长度和方向的影响都包含在概率密度函数中。应变率效应使用动态裂纹增长规律来实现。绘制了氧化铝在动态压缩下从准静态到高应变率（10-3-106）的应力-应变曲线。

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

Procedia Structural Integrity

CiteScore

1.70

自引率

0.00%

发文量