×
验证码:
换一张
Forgotten Password?
Stay signed in
China Science and Technology Network Pass Registration
×
China Science and Technology Network Pass Registration
Log In
Chinese
|
English
中国科学院力学研究所机构知识库
Knowledge Management System of Institue of Mechanics, CAS
Log In
Register
ALL
ORCID
Title
Creator
Thesis Advisor
Keyword
Document Type
Source Publication
Publisher
Date Issued
Date Accessioned
Indexed By
Funding Project
DOI
Study Hall
Image search
Paste the image URL
Home
Collections
Authors
DocType
Subjects
K-Map
News
Search in the results
Collection
State Key... [22]
Creator
洪友士 [14]
孙成奇 [9]
钱桂安 [8]
潘向南 [7]
Berto F [4]
reprint au... [4]
More...
Document Type
Journal a... [19]
Conference... [3]
Date Issued
2023 [2]
2022 [1]
2021 [4]
2020 [6]
2019 [1]
2018 [3]
More...
Language
英语 [22]
Source Publication
INTERNATI... [22]
Indexed By
SCI [20]
EI [18]
CPCI-S [3]
Funding Project
National N... [5]
CAS Pionee... [3]
National N... [3]
Strategic ... [2]
Strategic ... [2]
CAS Center... [1]
More...
Funding Organization
National N... [7]
CAS Pionee... [3]
Strategic ... [3]
National K... [2]
CAS Center... [1]
CAS Pionee... [1]
More...
Thesis Advisor
×
Knowledge Map
IMECH-IR
Start a Submission
Submissions
Unclaimed
Claimed
Attach Fulltext
Bookmarks
QQ
Weibo
Feedback
Browse/Search Results:
1-10 of 22
Help
Filters
Source Publication:INTERNATIONAL JOURNAL OF FATIGUE
Community:非线性力学国家重点实验室
First author affiliation
The first author
Corresponding Author
Selected(
0
)
Clear
Items/Page:
5
10
15
20
25
30
35
40
45
50
55
60
65
70
75
80
85
90
95
100
Sort:
Select
Author Ascending
Author Descending
Title Ascending
Title Descending
Issue Date Ascending
Issue Date Descending
WOS Cited Times Ascending
WOS Cited Times Descending
Submit date Ascending
Submit date Descending
Journal Impact Factor Ascending
Journal Impact Factor Descending
Nanograin formation mechanism under fatigue loadings in additively manufactured Ti-6Al-4V alloy
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2023, 卷号: 175, 页码: 107821
Authors:
Chi WQ(池维乾)
;
Wang, Wenjing
;
Wu, Lei
;
Duan GH(段桂花)
;
Sun CQ(孙成奇)
Adobe PDF(30782Kb)
  |  
Favorite
  |  
View/Download:51/5
  |  
Submit date:2023/09/05
Additively manufactured titanium alloy
Very high cycle fatigue
Crack initiation
Twinning
Nanograin formation
Nanograin formation and cracking mechanism in Ti alloys under very high cycle fatigue loading
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2023, 卷号: 167, 页码: 10
Authors:
Sun CQ(孙成奇)
;
Wu H(仵涵)
;
Chi, Weiqian
;
Wang, Wenjing
;
Zhang, Guang-Ping
Adobe PDF(22393Kb)
  |  
Favorite
  |  
View/Download:134/6
  |  
Submit date:2023/01/12
Titanium alloy
Very high cycle fatigue
Twinning
Nanograins
Cracking mechanism
High-cycle and very-high-cycle fatigue lifetime prediction of additively manufactured AlSi10Mg via crystal plasticity finite element method
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2022, 卷号: 155, 页码: 11
Authors:
Zhang JM(张佳妹)
;
Li JH(李江华)
;
Wu, Shengchuan
;
Zhang, Wenjie
;
Sun JY(孙经雨)
;
Qian GA(钱桂安)
Adobe PDF(8939Kb)
  |  
Favorite
  |  
View/Download:391/119
  |  
Submit date:2021/11/29
Crystal plasticity
Additive manufacturing
Very-high-cycle fatigue
AlSi10Mg alloy
Defects
Crack initiation mechanisms under two stress ratios up to very-high-cycle fatigue regime for a selective laser melted Ti-6Al-4V
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2021, 卷号: 149, 页码: 10
Authors:
Du LM(杜雷鸣)
;
Pan XN(潘向南)
;
Qian GA(钱桂安)
;
Zheng L(郑亮)
;
Hong YS(洪友士)
Adobe PDF(14294Kb)
  |  
Favorite
  |  
View/Download:303/59
  |  
Submit date:2021/08/03
Very-high-cycle fatigue
Crack initiation mechanism
Stress ratio
Ti-6Al-4V
Selective laser melting
A segmented load spectrum model for high-speed trains and its inflection stress as an indicator for line quality
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2021, 卷号: 148, 页码: 12
Authors:
Yuan, Zheng
;
Chen XJ(陈贤佳)
;
Ma, Lijun
;
Li, Qiang
;
Sun, Shouguang
;
Wei YJ(魏宇杰)
Adobe PDF(4436Kb)
  |  
Favorite
  |  
View/Download:376/101
  |  
Submit date:2021/06/15
Load spectrum
Segmented Weibull distribution
Bogie frame
High-speed train
Inflection stress
Crack initiation behavior and fatigue performance up to very-high-cycle regime of AlSi10Mg fabricated by selective laser melting with two powder sizes
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2021, 卷号: 143, 页码: 12
Authors:
Jian ZM(渐徵墨)
;
Qian GA(钱桂安)
;
Paolino, D. S.
;
Tridello, A.
;
Berto, F.
;
Hong YS(洪友士)
Adobe PDF(12679Kb)
  |  
Favorite
  |  
View/Download:383/76
  |  
Submit date:2021/03/03
Selective laser melting
AlSi10Mg
VHCF
Defects
Crack initiation
Effects of inclusion size and stress ratio on the very-high-cycle fatigue behavior of pearlitic steel
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2021, 卷号: 142, 页码: 11
Authors:
Cong, Tao
;
Qian, Guian
;
Zhang, Guanzhen
;
Wu, Si
;
Pan, Xiangnan
;
Du, Leiming
;
Liu, Xiaolong
Adobe PDF(13962Kb)
  |  
Favorite
  |  
View/Download:262/54
  |  
Submit date:2021/01/12
Pearlitic steel
Very-high-cycle fatigue
Inclusion size
Stress ratio
Nanograins
Very-high-cycle fatigue behavior of AlSi10Mg manufactured by selective laser melting: Effect of build orientation and mean stress
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2020, 卷号: 138, 页码: 9
Authors:
Qian GA(钱桂安)
;
Jian ZM
;
Qian YJ
;
Pan XN(潘向南)
;
Ma XF
;
Hong YS(洪友士)
Adobe PDF(11591Kb)
  |  
Favorite
  |  
View/Download:413/187
  |  
Submit date:2020/08/26
Selective laser melting
Very-high-cycle fatigue
AlSi10Mg
Crack initiation
Fatigue strength
Special Issue ESIAM19 International Journal of Fatigue
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2020, 卷号: 136, 页码: 1
Authors:
Berto F
;
Susmel L
;
Van H B
;
Torgersen J
;
Qian GA(钱桂安)
Adobe PDF(231Kb)
  |  
Favorite
  |  
View/Download:259/85
  |  
Submit date:2020/07/06
Very-high-cycle fatigue behavior of Ti-6Al-4V manufactured by selective laser melting: Effect of build orientation
期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2020, 卷号: 136, 页码: 13
Authors:
Qian GA(钱桂安)
;
Li YF(李彦峰)
;
Paolino DS
;
Tridello A
;
Berto F
;
Hong YS(洪友士)
Adobe PDF(6442Kb)
  |  
Favorite
  |  
View/Download:451/166
  |  
Submit date:2020/07/06
High-cycle fatigue (HCF)
Very-high-cycle fatigue (VHCF)
Selective laser melting (SLM)
Titanium alloy
Building direction
Fatigue design