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[1] Li, Yao.Dynamic crushing of a dedicated buffer during the high-speed vertical water entry process[J],OCEAN ENGINEERING,2022,236
[2] Yang, Wenping,郭强.Effect of aging temperature on energy dissipation and high-cycle fatigue properties of FV520B stainl[J],ENGINEERING FRACTURE MECHANICS,2022,242
[3] 郭杏林.Fatigue Behavior Analysis of Cruciform Welded Joints by Infrared Thermographic Method[A],2nd International Conference on Manufacturing Science and Engineering,2022,197-198:1395-1399
[4] Fan, Junling.Infrared thermographic analysis of notch effects on tensile behavior of 30CrMnSiA steel[J],INFRARED PHYSICS TECHNOLOGY,2022,101:110-118
[5] 赵延广.Lock-in infrared thermography for non-destructive testing of grid stiffened composite structure[J],Advanced Science Letters,2022,5(2):593-596
[6] 赵延广.Lock-in Infrared Thermography for the Non-destructive Testing of Fatigue Specimen with Defects[A],International Conference on Frontiers of Manufacturing and Design Science (ICFMD2010),2022,44-47:576-580
[7] Wang X..Lock-in thermographic methodology for fatigue assessment and nonlinear stress measurement[A],International Conference on Experimental Mechanics 2008, ICEM 2008,2022,7375
[8] 赵延广.Lock-in thermography method for the NDT of composite materials[A],International Conference on Experimental Mechanics 2008, ICEM 2008,2022,7375
[9] 赵延广.Testing and evaluation for fatigue crack propagation of Ti-6AL-4V/ELI and 7050-T7452 alloys at high [J],Chinese Journal of Aeronautics,2022
[10] 胡小飞.Thermal-Mechanical Fracture Analysis Considering Heat Flux Singularity[J],JOURNAL OF HEAT TRANSFER TRANSACTIONS OF THE ASME,2022,141(12)
[11] 吕志阳.Ti-6Al-4V/ELI钛合金250℃裂纹扩展性能[J],航空材料学报,2022,38(4):123-129
[12] Fan J.L..Using infrared thermography in effect evaluation of heat treatments on martensite steel[J],Advanced Science Letters,2022,16(1):305-308
[13] Fan, J.L..Using infrared thermography in effect evaluation of heat treatments on martensitic steel[J],Advanced Science Letters,2022,16(1):305-308
[14] 吕志阳.4种典型航空钛合金材料高温裂纹扩展性能对比试验[J],航空动力学报,2022,32(11):2713-2720
[15] 赵延广.An energetic method to evaluate the macro and micro high cycle fatigue behavior of the aluminum allo[J],Journal of Mechanical Engineering Science,2022
[16] Fan, Junling.An energetic method to evaluate the macro and micro high-cycle fatigue behavior of the aluminum al[J],PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C JOURNAL OF ME,2022,232(8,SI):1456-1469
[17] Bao, Fuming.An Improved 2D Meshfree Radial Point Interpolation Method for Stress Concentration Evaluation of W[J],Applied Sciences Basel,2022,10(19)
[18] 徐威.An Ultra-High Frequency Vibration-Based Fatigue Test and Its Comparative Study of a Titanium Alloy[J],Metals,2022,10(11)
[19] 赵延广.Application of third moment method to time-dependent reliability of RC structures under chlorinati[A],10th International Conference on Application of Statistics and Probability in Civil Engineering,2022,391-392
[20] Fan, Junling.A unifying energy approach for high cycle fatigue behavior evaluation[J],MECHANICS OF MATERIALS,2022,120:15-25
[21] 郭杏林.疲劳试验过程中的实时锁相红外热成像无损检测技术[A],中国力学学会2009学术大会,2022,1-6
[22] 胡小飞.On a symplectic analytical singular element for cracks under thermal shock considering heat flux s[J],APPLIED MATHEMATICAL MODELLING,2022,80:1-16
[23] Wang, X. G..Quantitative Thermographic Methodology for fatigue assessment and stress measurement[J],INTERNATIONAL JOURNAL OF FATIGUE,2022,32(12):1970-1976
[24] Fan, Junling.Quantitative thermography for fatigue damage assessment and life prediction of welded components[J],Mechanics of Materials,2022,164
[25] Fan, J. L..Research on fatigue behavior evaluation and fatigue fracture mechanisms of cruciform welded joints[J],MATERIALS SCIENCE AND ENGINEERING A STRUCTURAL MATERIALS PROPERTIES MICROST,2022,528(29-30):8417-8427
[26] Fan, Junling.Research of Fatigue Fracture on Fillet Welded Joints Made of FV520B[A],2nd International Conference on Frontiers of Manufacturing and Design Science (ICFMD 2011),2022,121-126:559-+
[27] Fan, Junling.Stress assessment and fatigue behavior evaluation of components with defects based on the finite e[J],PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C JOURNAL OF ME,2022,229(7,SI):1194-1205
[28] 郭杏林.Q235疲劳试验过程中的实时锁相红外热成像无损检测技术[A],全国MTS岩土混凝土试验研讨会,2009,1
[29] 赵延广.锁相红外热像技术在焊接构件疲劳性能研究中的应用[A],2010年海峡两岸材料破坏/断裂学术会议暨第十届破坏科学研讨会/第八届全国MTS材料试验学术会议,2010,4
[30] 赵延广.发动机材料高周疲劳P-S-N曲线优化处理方法[J],航空材料学报,2020,40(05):96-103
[31] 赵延广.合金钢室、高温高周疲劳性能的研究[J],热加工工艺,2017,46(14):93-95
[32] 赵延广.含缺陷疲劳试件的锁相红外热成像无损检测[J],光学学报,2010,30(10):2776-2781
[33] 许巍.基于振动台的TA11钛合金超高频疲劳实验和验证[J],航空材料学报,2019,39(4):86-92
[34] 樊俊铃.基于有限元法和锁相热像法对含缺陷构件的应力分析与疲劳性能评估[J],材料工程,2022,8:62-71
[35] 赵延广.基于锁相红外热成像理论的复合材料网格加筋结构的无损检测[J],复合材料学报,2022,28(1):199-205
[36] 樊俊铃.定量热像法预测焊接接头的S-N曲线和残余寿命[J],材料工程,2022,12:29-33
[37] Yang, Wenping.对流和辐射换热对金属高周疲劳能量耗散估计的影响[J],Jixie Gongcheng Xuebao/Journal of Mechanical Engineering,2022,57(10):187-195
[38] 发动机材料高周疲劳P-S-N曲线优化处理方法[J],航空材料学报,2021,40(05):96-103
[39] Hu, Xiaofei,Ding, Xing,Zhao, Yanguang,Yao, Weian.On a symplectic analytical singular element for cracks under thermal shock considering heat flux s[J],APPLIED MATHEMATICAL MODELLING,2020,80:1-16
[40] Fan, Junling,Chen, Xianmin,Wang, Dan,Li, Sanyuan,Zhao, Yanguang.Infrared thermographic analysis of notch effects on tensile behavior of 30CrMnSiA steel[J],INFRARED PHYSICS & TECHNOLOGY,2019,101:110-118