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浏览/检索结果: 共22条，第1-10条 帮助 限定条件 发表日期：2022     已选(0)清除 条数/页：5101520253035404550556065707580859095100   排序方式：请选择作者升序作者降序题名升序题名降序发表日期升序发表日期降序提交时间升序提交时间降序 An experimental investigation of fatigue performance and crack initiation characteristics for an SLMed Ti-6Al-4V under different stress ratios up to very-high-cycle regime 期刊论文 INTERNATIONAL JOURNAL OF FATIGUE, 2022, 卷号: 164, 页码: 14 作者:  Fu, Rui;  Zheng, Liang;  Ling, Chao;  Zhong, Zheng;  Hong YS(洪友士) 收藏  |  浏览/下载：24/0  |  提交时间：2022/08/28 Selective laser melting  Ti-6Al-4V  Very-high-cycle fatigue  Crack initiation  Stress intensity factor   Very-high-cycle fatigue induced growth and amorphization of Si particles in additively manufactured AlSi10Mg alloy: Dependence of applied stress ratio 期刊论文 INTERNATIONAL JOURNAL OF FATIGUE, 2022, 卷号: 164, 页码: 107167 作者:  Li JH(李江华);  Sun JY(孙经雨);  Li, Yajing;  Qian GA(钱桂安);  Wang, Zhiyang 收藏  |  浏览/下载：20/0  |  提交时间：2022/10/23 Very-high-cycle fatigue  Stress ratio  Coarsening  Amorphization  AlSi10Mg alloy   High-temperature fatigue behavior and cyclic deformation of a gradient nanostructured RAFM steel 期刊论文 INTERNATIONAL JOURNAL OF FATIGUE, 2022, 卷号: 163 作者:  Zhao, Yanyun;  Liang, Mengtian;  Liu, Shaojun;  Zhang, Weihua 收藏  |  浏览/下载：18/0  |  提交时间：2022/12/23 Gradient nanostructure  RAFM steel  Fatigue property  Strain delocalization  High temperature   High-temperature failure mechanism and defect sensitivity of TC17 titanium alloy in high cycle fatigue 期刊论文 JOURNAL OF MATERIALS SCIENCE & TECHNOLOGY, 2022, 卷号: 122, 页码: 128-140 作者:  Li, Gen;  Sun, Chengqi 收藏  |  浏览/下载：29/0  |  提交时间：2022/06/10 TC17 titanium alloy  High temperature  Defect  High cycle fatigue  Oxygen-rich layer  Rough area   Mechanism of artificial surface defect induced cracking for very high cycle fatigue of Ti alloys 期刊论文 ENGINEERING FRACTURE MECHANICS, 2022, 卷号: 272, 页码: 11 作者:  Sun, Jian;  Peng, Wenjie;  Sun CQ(孙成奇) 收藏  |  浏览/下载：65/0  |  提交时间：2022/09/27 TC17 titanium alloy  Artificial surface defect  Very high cycle fatigue  Crack initiation mechanism  Deformation twins   Investigation on the Fatigue Crack Propagation of Medium-Entropy Alloys with Heterogeneous Microstructures 期刊论文 MATERIALS, 2022, 卷号: 15, 期号: 17, 页码: 14 作者:  Liu, Yang;  Jiang, Ping;  Duan, Guihua;  Wang, Jing;  Zhou, Lingling 收藏  |  浏览/下载：43/0  |  提交时间：2022/09/29 heterogeneous microstructure  MEA  recrystallization annealing  fatigue crack propagation threshold  fatigue crack growth path  cyclic plastic zone   Plastic anisotropy and twin distributions near the fatigue crack tip of textured Mg alloys from in situ synchrotron X-ray diffraction measurements and multiscale mechanics modeling 期刊论文 JOURNAL OF THE MECHANICS AND PHYSICS OF SOLIDS, 2022, 卷号: 165, 页码: 26 作者:  Xie, Di;  Zhang, Wei;  Lyu, Zongyang;  Liaw, Peter K.;  Tran, Huy 收藏  |  浏览/下载：24/0  |  提交时间：2022/07/18 In situ synchrotron X-ray diffraction (S-XRD)  Mg alloy  Fatigue crack  Cohesive interface model  Crystal plasticity finite element method   Role of delta-ferrite in fatigue crack growth of AISI 316 austenitic stainless steel 期刊论文 JOURNAL OF MATERIALS SCIENCE & TECHNOLOGY, 2022, 卷号: 114, 页码: 7-15 作者:  Wang, Qiyu;  Chen, Shenghu;  Lv, Xinliang;  Jiang, Haichang;  Rong, Lijian 收藏  |  浏览/下载：19/0  |  提交时间：2022/07/01 Austenitic stainless steel  delta-ferrite  Accelerated aging  Fatigue crack growth  Crack deflection   Interior initiation and early growth of very high cycle fatigue crack in an additively manufactured Ti-alloy 期刊论文 INTERNATIONAL JOURNAL OF FATIGUE, 2022, 卷号: 160, 页码: 9 作者:  Chi, Weiqian;  Li, Gen;  Wang, Wenjing;  Sun, Chengqi 收藏  |  浏览/下载：41/0  |  提交时间：2022/07/18 Additively manufactured titanium alloy  Very high cycle fatigue  Interior crack initiation  Ultralow crack growth rate  Grain refinement   Different effects of multiscale microstructure on fatigue crack growth path and rate in selective laser melted Ti6Al4V 期刊论文 FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES, 2022, 页码: 11 作者:  Qi, Zhao;  Wang, Bin;  Zhang, Peng;  Liu, Riu;  Zhang, Zhenjun 收藏  |  浏览/下载：23/0  |  提交时间：2022/07/14 fatigue crack growth rate  heat treatment  microstructure  selective laser melting  strength  Ti6Al4V