发表论文:
[1]魏勤,尤建飞.超声C扫描系统在颗粒增强型金属基复合材料无损检测中的应用.华东船舶工业学院学报(自然科学版),2003(03):66-69.
[2]魏勤,苏虹,彭如海.聚焦换能器在SiCp/Al复合材料超声无损检测中的应用. 实验力学,2003(02):265-270.
[3]魏勤,张迎元,尤建飞.用超声衰减法研究喷射沉积6061Al/SiCp复合材料的阻尼性能[J].应用声学,2004(06):20-23.
[4]魏勤,张迎元.超声法测定铝基碳化硅复合材料的SiC体积比[J].实验力学,2005(03):393-397.
[5]魏勤,董师润,徐颖梅.超声纯横波法测试45~#钢的内部应力.实验力学, 2007,No.92(06):588-592.
[6]魏勤,董师润,徐秉汉等.超声双折射法测试铝合金的内部应力[J].应用声学,2008(05):401-406.
[7]魏勤,朱金连,宋广三.铝合金薄板的超声透射法检测[J].无损检测,2009,31(08):625-627.
[8]魏勤,罗琅,张礼华.超声纵波法测试铝合金内部的载荷应力[J].无损检测,2009,31(03):217-219-228.
[9]魏勤,李甲兵,孟赟.射频信号时间域反射法监测液位[J].江苏科技大学学报(自然科学版),2009,23(01):91-94.
[10]魏勤,骆英.超声法研究SiC体积比对SiCp/Al复合材料力学性能的影响[J].机械强度,2011,33(02):179-182.
[11]魏勤,卫婷,宋广三.声双折射法研究再结晶退火处理对45#钢微观组织的影响[J].应用声学,2011,30(03):220-226.
[12]魏勤,颜信全,周武波等.压电晶片传感器监测金属薄板的腐蚀[J].应用声学,2011,30(06):469-474.
[13]魏勤,卫婷,宋广三.超声瑞利波测试材料表面载荷应力的实验研究[J].实验力学,2011,26(02):176-180.
[14]魏勤,骆英,王自平等.Lamb波驱动器的最佳激励波形选择[J].压电与声光,2011,33(06):863-866.
[15]魏勤,卫婷,董师润等.超声波法测量金属材料的杨氏模量和剪切模量[J].江苏科技大学学报(自然科学版),2012,26(01):27-30.
[16]魏勤,骆英.液层负载作用下薄板中腐蚀的Lamb波检测[J].振动.测试与诊断,2013,33(S1):41-44.
[17]赵军辉,魏勤,袁媛等.Lamb波检测板中裂纹的有限元模拟[J].压电与声光,2013,35(03):320-328.
[18]许烨东,魏勤,智达.翻边压电晶片激励Lamb波声场研究[J].应用声学,2015,34(06):547-553.
[19]智达,赵军辉,许烨东等.超声S0导波检测腐蚀缺陷[J].无损检测,2015,37(01):16-21.
[20] Wei Q, Zhu JG, Chen W. Anisotropic Mechanical Properties of Plasma-Sprayed Thermal Barrier Coatings at High Temperature Determined by Ultrasonic Method, Journal of Thermal Spray Technology, 2016.25(3):605-612.DOI10.1007/s11666-016-0378-8. (中科院二区)
[21]魏勤,修博宇,穆金书等.基于非线性波调制CFRP板冲击损伤的检测研究[J].江苏科技大学学报(自然科学版),2019,33(02):121-126.
[22] Wei Qin, Wu Wenxin, He Wei, Zhu Jianguo. 3D Finite Element Simulation of Shot Peening Using a Sequential Model with Multiple-Shot Impacts, International journal of computational methods,2020,17(3): 1850137. DOI10.1142/S0219876218501372. (中科院三区)
[23]魏勤,田晓华,宋广三等.非线性Lamb波混频法及板中微裂纹的检测[J].江苏科技大学学报(自然科学版),2020,34(02):110-114.
[24] Wei Qin, Zhu L, Zhu JG, et al. Characterization of impact fatigue damage in CFRP composites using nonlinear acoustic resonance method[J]. Composite Structures, 2020:112804. (中科院一区)
[25] 朱利勇, 尹嘉雯, 韩梦,魏勤. 基于非线性声学共振法的CFRP板冲击疲劳损伤检测研究[J]. 江苏科技大学学报:自然科学版, 2020, 34(5):6.
[26] Yin J, Wei Qin *, Zhu L , et al. Nonlinear frequency mixing of Lamb wave for detecting randomly distributed microcracks in thin plates[J]. Wave Motion, 2020, 99(1):102663. (中科院二区)
[27]韩梦, 尹嘉雯, 黄军科,等. 铝合金板疲劳微裂纹超声红外成像检测的数值及实验研究[J]. 应用声学, 2022, 41(5):8.
[28]魏勤, 万佳, 汪海宾,等. 新工科人才培养模式下超声检测实验教学改革与实践[J]. 实验室研究与探索, 2022, 41(4):5.
[29] Wei Qin, Han Meng, Zhu Jianguo, et al. Experimental and numerical investigation on detection fatigue crack in metallic plate by vibro-thermography. Infrared Physics & Technology, 2022,126: 104347. DIO 10.1016/j.infrared.2022.104347. (中科院二区)
[30] Junke Huang, Qin Wei*, Lijun Zhuo*, Detection and quantification of artificial delaminations in CFRP composites using ultrasonic thermography, Infrared Physics & Technology, 2023 (130):104579. (中科院二区)
[31] Li Wei, Qin Wei*, Junke Huang, et al. Nonlinear frequency mixing of counter-propagating collinear A0-S0 mode Lamb waves for delamination detection in CFRP composite plate, Nondestructive Testing and Evaluation, 2023. (中科院三区)
[32] Qin Wei, Junke Huang, Jianguo Zhu, et al. Experimental investigation on detection of coating debonds in thermal barrier coatings using vibrothermography with a piezoceramic actuator, NDT and E International, 2023,4:102859. (中科院一区)