Effect of Equivalent Stress Amplitude on Multiaxial Fretting Fatigue Behavior of Al–Zn–Mg Alloy

被引:1
作者
X. S. Jiang
J. X. Jiang
W. X. Liu
T. F. Song
D. Mo
机构
[1] Southwest Jiaotong University,School of Materials Science and Engineering
[2] Chengdu Textile College,Department of Mechanical Engineering and Automation
[3] Shanghai Institute of Technical Physics,Key Laboratory of Infrared Imaging Materials and Detectors
[4] Chinese Academy of Sciences,undefined
来源
Strength of Materials | 2020年 / 52卷
关键词
Al–Zn–Mg alloy; fretting fatigue; multiaxial loading; point contact; ANSYS;
D O I
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中图分类号
学科分类号
摘要
The fretting fatigue behavior in Al–Zn–Mg alloy is investigated under conditions of various equivalent stress amplitudes of cyclic multiaxial loadings and the same contact pressure with a point contact. The ANSYS finite element analysis is used to analyze stress distribution by a numerical study using the 3D finite element method. Fretting regions’ morphology and fracture of specimens are characterized by scanning electron microscopy. Results obtained indicate that at the contact stress of 180 MPa, with increasing of equivalent stress amplitude, the degree of cyclic softening under tension/torsional fretting fatigue loading increases, and the fretting fatigue durability drops with the equivalent stress amplitude. The different equivalent stress amplitudes play a very important role in fretting regions’ morphology and fracture forming. Their influence on the fretting fatigue life is discussed by the comparison of the experimental results.
引用
收藏
页码:458 / 469
页数:11
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