Modeling the role of microplasticity on material response under fatigue loading using a microelement plastic strain accumulation model

IF 3.4 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Mechanics of Materials Pub Date : 2025-05-17 DOI:10.1016/j.mechmat.2025.105377

Bhukya Venkatesh, Srikanth Vedantam

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Abstract

Fatigue failure is greatly impacted by the progressive accumulation of microplastic deformation when subjected to cyclic loading below the macroscopic yielding. This paper presents microplastic deformation and its influence on fatigue response both in low and high cycle fatigue regimes using a recently developed Microelement Plastic Strain Accumulation (MPSA) approach. The MPSA approach is based on the Jenkin–Masing model, which treats materials as a large number of linear elastic–perfectly plastic parallel microelements. This microelement model provides insights into material behavior below the macroscopic yield limit under different loading conditions, which is essential for modeling high cycle fatigue failure of materials. We evaluate the evolution of the microplastic strain, ratcheting strain, stress–strain hysteresis loops, and material degradation during cyclic loading using this model. The evolution of microplastic strain allows the model to predict high cycle fatigue. Finally, we study the strength and stiffness degradation in terms of the fraction in fatigue life.

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利用微单元塑性应变累积模型模拟疲劳载荷下材料微塑性响应的作用

在低于宏观屈服的循环加载条件下，微塑性变形的渐进累积对疲劳破坏的影响很大。本文介绍了微塑性变形及其在低周和高周疲劳状态下对疲劳响应的影响，采用了最近发展的微元素塑性应变积累（MPSA）方法。MPSA方法基于Jenkin-Masing模型，该模型将材料视为大量线性弹性-完美塑性平行微元素。该微元素模型提供了在不同加载条件下宏观屈服极限下材料行为的见解，这对于模拟材料的高周疲劳失效至关重要。我们使用该模型评估了循环加载过程中微塑性应变、棘轮应变、应力-应变滞后回路和材料退化的演变。微塑性应变的演化使该模型能够预测高周疲劳。最后，我们从疲劳寿命的角度研究了强度和刚度的退化。

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

Mechanics of Materials 工程技术-材料科学：综合

CiteScore

7.60

自引率

5.10%

发文量

243

审稿时长

46 days

期刊介绍： Mechanics of Materials is a forum for original scientific research on the flow, fracture, and general constitutive behavior of geophysical, geotechnical and technological materials, with balanced coverage of advanced technological and natural materials, with balanced coverage of theoretical, experimental, and field investigations. Of special concern are macroscopic predictions based on microscopic models, identification of microscopic structures from limited overall macroscopic data, experimental and field results that lead to fundamental understanding of the behavior of materials, and coordinated experimental and analytical investigations that culminate in theories with predictive quality.