Ritsumeikan University Researcher Database
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HE LEI
Department / Course
College of Science and Engineering Department of Mechanical Engineering
Title / Position
Assistant Professor
Papers
1.
2024/06/10
Multiaxial creep–fatigue failure mechanism and life prediction of a turbine blade based on a unified numerical solution approach │ (Co-authored)
2.
2024/05
Fatigue behaviors and life evaluation of AISI304 stainless steel under non-proportional multiaxial random loading │ International Journal of Fatigue │ (Co-authored)
3.
2023
Multiaxial creep-fatigue constitutive modeling and damage evaluation for type F82H steel under non-proportional loading conditions │ International Journal of Fatigue │ (Co-authored)
4.
2022/11/23
Fatigue life evaluation model for various austenitic stainless steels at elevated temperatures via alloy features-based machine learning approach │ Fatigue Fract Eng Mater Struct │ (Co-authored)
5.
2022/07
Establishment of unified creep–fatigue life prediction under various temperatures and investigation of failure physical mechanism for Type 304 stainless steel │ Fatigue Fract Eng Mater Struct │ (Co-authored)
6.
2022/06/06
On multiaxial creep–fatigue considering the non-proportional loading effect: Constitutive modeling, deformation mechanism, and life prediction │ International Journal of Plasticity │ (Co-authored)
7.
2022
Machine-learning-based investigation into the effect of defect/inclusion on fatigue behavior in steels │ (Co-authored)
8.
2021
Machine learning-based predictions of fatigue life and fatigue limit for steels │ Journal of Materials Science & Technology │ (Co-authored)
9.
2021
Quantitative Analysis of the Recovery Process in Pure Iron
Using X-Ray Diffraction Line Profile Analysis │ (Co-authored)
10.
2020
Cumulative fatigue damage of stress below the fatigue limit
in weldment steel under block loading │ (Co-authored)
11.
2018
Effect of high-amplitude loading on accumulated fatigue damage under
variable-amplitude loading in 316 stainless steel │ (Co-authored)
12.
2017
Fatigue life prediction method for AISI 316 stainless steel under
variable-amplitude loading considering low-amplitude loading
below the endurance limit in the ultrahigh cycle regime │ (Co-authored)