项延训

项延训

E-mail: yxxiang@ecust.edu.cn
职位: 校党委组织部,常务副部长

职称: 教授,博士生导师;国家杰青(2020)、国家优青(2016)。研究生招生专业:博士招生专业:080703动力机械及工程、080202机械电子工程;硕士招生专业:080706化工过程机械、080202机械电子工程

 

 

 

 


个人简介:

2000年毕业于同济大学,获应用物理学士学位;2003年毕业于同济大学,获声学硕士学位;2011年毕业于威尼斯欢乐娱人成app,获化工过程机械博士学位。2005年至今任职于华东理工大学,教授,博士生导师;作为项目负责人主持包括国家杰青、优青、NSAF联合基金重点项目在内的7项国家自然科学基金项目、国家重点研发计划课题、装备预研教育部联合基金项目,以及多项省部级项目和企业合作科研项目。入选第十届上海青年科技英才(2020年);获2019年度上海市科技进步奖一等奖(第1完成人);获2017年上海市魏墨盦声学奖;获2015年度上海市自然科学奖一等奖(第1完成人);获2014年上海市科技启明星计划;发表SCI论文60余篇,授权/申请专利18项。

 

联系方法:

上海市梅陇路130号威尼斯欢乐娱人成app(实验17楼),邮编:200237。yxxiang@ecust.edu.cn

研究方向

主要从事材料/构件服役相关的超声检测及评价技术研究,包括:早期微损伤的非线性超声导波检测及定位表征、超声导波损伤检测及定位成像、超声相控阵成像、复杂结构中残余应力的超声表征等。研究内容涉及超声学、材料力学、信号处理等交叉学科。

承担科研项目

[1] 国家自然科学基金NSAF国家安全联合基金重点项目:“多层复杂结构状态的电磁超声相控阵检测方法研究”,项目负责人,批准号:U1930202,2020-2023年; 

[2] 国家重点研发计划课题:“严苛环境下安全性能衰退在线感知和失效预警”,项目负责人,批准号:2018YFC0808806,2018-2021;

[3] 国家自然科学基金优青项目:“非线性超声导波”,项目负责人,批准号:11622430, 2017-2019年;

[4] 国家自然科学基金面上项目:“基于非线性超声导波混频的结构塑性损伤定位及表征方法”,项目负责人,批准号:11774090, 2018-2021年;

[5] 国家自然科学基金面上项目:“微细观尺度下材料蠕变行为的非线性兰姆波评价理论与表征方法”,项目负责人,批准号:11474093,2015-2018年;

[6] 装备预研教育部联合基金项目:“极端条件服役结构健康监测方法及系统”,项目负责人,2018-2019年;

[7] 国家自然科学基金青年项目:“材料蠕变损伤和微组织演化的非线性超声兰姆波评价方法”,项目负责人,项目批准号:11004056,2011-2013年;

获奖成果

[1]. Guang-Jian Gao, Chang Liu, Ning Hu, Ming-Xi Deng, Han Chen, Yan-Xun Xiang. Response of second-harmonic generation of Lamb wave propagation to microdamage thickness in a solid plate. Wave Motion, 2020, 96: 102557.

[2].Han Chen, Guang-Jian Gao, Ning Hu, Ming-Xi Deng, Yan-Xun Xiang. Modeling and simulation of frequency mixing response of two counter-propagating Lamb waves in a two-layered plate. Ultrasonics, 2020, 104, 106109.

[3].Guang-Jian Gao, Ming-Xi Deng, Ning Hu, Yan-Xun Xiang. Enhancement effect of cumulative second-harmonic generation by closed propagation feature of circumferential guided waves. Chinese Physics B, 2020, 29(2): 024301.

[4].Xiao Wang, Yanxun Xiang, Wu-Jun Zhu, Tao-Tao Ding, Hua-Ying Li. Damage assessment in Q690 high strength structural steel using nonlinear Lamb waves. Construction and Building Materials, 2020, 234: 117384.

[5].Jianying Tang, Likun Tong, Yanxun Xiang, Xunlin Qiu, Mingxi Deng, Fuzhen Xuan. Design, Fabrication and Characterization of EMFi-based Ferroelectret Air-coupled Ultrasonic Transducer. Sensors and Actuators A: Physical, 2019, 296: 52-60.

[6].  Maoxun Sun, Yanxun Xiang, Mingxi Deng, Bo Tang, Wujun Zhu and Fu-Zhen Xuan. Experimental and numerical investigations of nonlinear interaction of counter-propagating Lamb waves. Applied Physics Letters, 2019, 114: 011902.

[7]. Ben Li, Rong Liu, Wujun Zhu, Qiaoxin Zhang, Jingui Yu, Yanxun Xiang, Hongyan Zhou. Research on the interaction between surface laser-pit of Ni-based single crystal alloy and lamb wave under micro-conditions. Applied Surface Science, 2019, 483: 840-848.

 [8]. Ming-Liang Li, Liang-Bing Liu, Guang-Jian Gao, Ming-Xi Deng, Ning Hu, Yan-Xun Xiang, and Wu-Jun Zhu. Response features of nonlinear circumferential guided wave on early damage in inner layer of a composite circular tube. Chinese Physics B, 2019, 28(4): 044301.

 [9]. Yanxun Xiang, Da Teng, Mingxi Deng, Yunze Li , Changjun Liu and Fuzhen Xuan. Characterization of Local Residual Stress at Blade Surfaces by the V(z) Curve Technique. Metals, 2018, 8: 651-662.

 [10]. Wujun Zhu, Yanxun Xiang, Chang-jun Liu, Mingxi Deng, Congyun Ma and Fu-zhen Xuan. Fatigue Damage Evaluation Using Nonlinear Lamb Waves with Quasi Phase-Velocity Matching at Low Frequency. Materials, 2018, 11, 1920; doi:10.3390/ma11101920.

 [11].  Han Chen, Ming-Xi Deng, Ning Hu, Ming-Liang Li, Guang-Jian Gao, Yan-Xun Xiang. Analysis of Second-Harmonic Generation of Low-Frequency Dilatational Lamb Waves in a Two-Layered Composite Plate. Chinese Physics Letters, 2018, 35(11): 114302.

 [12]. Wujun Zhu, Yanxun Xiang, Chang-Jun Liu, Mingxi Deng, Fu-Zhen Xuan. A feasibility study on fatigue damage evaluation using nonlinear Lamb waves with group-velocity mismatching. Ultrasonics, 2018, 90: 18-22.

 [13]. Weibin Li, Mingxi Deng, Ning Hu, Yanxun Xiang. Theoretical analysis and experimental observation of frequency mixing response of ultrasonic Lamb waves. Journal of Applied Physics, 2018. 124: 044901.

 [14].  Wujun Zhu, Yanxun Xiang, Chang-Jun Liu, Mingxi Deng and Fu-Zhen Xuan. Symmetry properties of second harmonics generated by antisymmetric Lamb waves. Journal of Applied Physics, 2018. 123: 104902.

 [15].  Maoxun Sun, Yanxun Xiang, Mingxi Deng, Jichao Xu, Fu-Zhen Xuan. Scanning non-collinear wave mixing for nonlinear ultrasonic detection and localization of plasticity. NDT&E International, 2018. 93: 1-6.

[16].   Mingliang Li, Mingxi Deng, Guangjian Gao, Yanxun Xiang. Modeling of second-harmonic generation of circumferential guided wave propagation in a composite circular tube. Journal of Sound and Vibration, 2018.421: 234-245.

 [17].  Mingliang Li, Mingxi Deng, Guangjian Gao, Yanxun Xiang. Mode pair selection of circumferential guided waves for cumulative second-harmonic generation in a circular tube. Ultrasonics, 2018, 82: 171-177.

[18].  Yanxun Xiang, Congyun Ma, Mingxi Deng, Fu-Zhen Xuan and Jianfeng Zhang.Lamb wave mode and frequency selection for assessment of creep damage in titanium alloy plates. Insight, 2017, 59(4): 196-202.

[19].  Wei-Bin Li, Ming-Xi Deng, Yan-Xun Xiang. Review on second-harmonic generation of ultrasonic guided waves in solid media: (I) theoretical analyses. Chinese Physics B, 2017, 26(11): 114302.

[20].  Ming-Liang Li, Mingxi Deng, Guang-Jian Gao, Han Chen, Yan-Xun Xiang. Influence of change in inner layer thickness of composite circular tube on second-harmonic generation by primary circumferential ultrasonic guided wave propagation. Chinese Physics Letters, 2017, 34(6): 064302.

[21].  Mingxi Deng, Guang-Jian Gao, Yan-Xun Xiang, Ming-Liang Li. Assessment of accumulated damage in circular tubes using nonlinear circumferential guided wave approach A feasibility study. Ultrasonics, 2017, 75: 209-215.

网页发布时间: 2019-05-16