Critical Plane Approach-Based Fatigue Life Prediction for Multiaxial Loading: A New Model and its Verification

IF 0.7 4区 材料科学 Q4 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Strength of Materials Pub Date : 2024-07-29 DOI:10.1007/s11223-024-00647-3
P. V. Yakovchuk, E. V. Savchuk, S. M. Shukayev
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Abstract

The results of a comparative analysis of five models of multiaxial fatigue based on the concept of the critical plane are presented. The Fatemi–Socie, Wang–Brown, Wu–Hu–Song, and augmented generalized strain energy models were studied. The durability calculated by these models was compared with experimental data obtained for 10 metal alloys and six multi-axis loading paths. The data analysis showed that the prediction of durability under multiaxial loading can be improved by using a fatigue damage parameter that includes the maximum shear strain and the square of the linear strain at the maximum shear site. The proposed model can be considered a new variant of the Brown-Miller model, where for the first time the fatigue damage parameter was presented as the sum of the maximum shear strain and the linear strain at the maximum shear site. It is shown that this model correlates well with the experimental data for both proportional and non-proportional loading.

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基于临界面法的多轴载荷疲劳寿命预测:新模型及其验证
本文介绍了基于临界面概念的五种多轴疲劳模型的对比分析结果。研究了 Fatemi-Socie、Wang-Brown、Wu-Hu-Song 和增强广义应变能模型。将这些模型计算出的耐久性与 10 种金属合金和六种多轴加载路径的实验数据进行了比较。数据分析显示,使用疲劳损伤参数(包括最大剪切应变和最大剪切部位线性应变的平方)可以改善多轴加载下的耐久性预测。所提出的模型可视为布朗-米勒模型的新变体,其中首次将疲劳损伤参数表述为最大剪切应变与最大剪切部位线性应变之和。研究表明,该模型与比例加载和非比例加载的实验数据相关性良好。
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来源期刊
Strength of Materials
Strength of Materials MATERIALS SCIENCE, CHARACTERIZATION & TESTING-
CiteScore
1.20
自引率
14.30%
发文量
89
审稿时长
6-12 weeks
期刊介绍: Strength of Materials focuses on the strength of materials and structural components subjected to different types of force and thermal loadings, the limiting strength criteria of structures, and the theory of strength of structures. Consideration is given to actual operating conditions, problems of crack resistance and theories of failure, the theory of oscillations of real mechanical systems, and calculations of the stress-strain state of structural components.
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