Scattered echo of surface defect in the far field of Rayleigh wave generated by laser
-
摘要: 为了实现激光超声技术对表面缺陷的定量检测,采用有限方法模拟了激光激发的表面波与表面开口矩形缺陷作用的复杂过程,比较了近场和远场两种不同激发方式下相同接收点的位移信号,发现远场激发下各种模式转换波和反射表面波能充分分离,有利于分析表面波与缺陷作用的复杂过程。在远场激发方式下分别探讨了表面波与缺陷前沿和后沿的作用过程,提取缺陷产生的散射回波特征,并用惠更斯原理分析其产生原因。最后研究了缺陷深度和宽度变化对散射回波特征的影响。结果表明,散射回波特征点到达时间差与缺陷深度和宽度有线性关系。该研究为反问题估算缺陷尺寸提供了理论依据。Abstract: In order to detect the surface defect quantitatively with laser ultrasonic technique, the interaction between the laser-generated surface wave and the open rectangular defect was simulated by means of the finite element method. After comparing the displacement signals at the same receiver generated in the near-field and far-field laser irradiation, it was found that reflected waves could be separated the from the mode-converted waves sufficiently when the laser was located in the far field of the defect, which may be helpful to analyze the complicated process of the interaction between the incident wave and the defect. Then, the wave interaction with either the front or the back of the defect was studied in detail, and Huygens principle was further employed to interpret the possible interaction features among the reflected signals. Finally, the influences of depth and width of the defect on the scattered echo were also studied. The results show that the arrival time difference of the scattered echo is linearly related to the depth and width of the defect. This research may provide the theoretical basis to quantify the defect.
-
-
[1] CHEN K, FU X, DORANTES-GONZALEZ D J, et al. Laser-generated surface acoustic wavetechnique for crack monitoring-areview[J]. International Journal of Automation Technology, 2013, 7(2): 211-220.
[2] ZHAO Y, YAN W, SHEN Z H, et al. Numerical simulation of elastic acoustic wave interaction with surface-breaking defects[J]. Laser Technology, 2010, 34(1):91-94 (in Chinese).
[3] NI C Y, SHI Y F, SHEN Z H, et al. Numerical simulation on near-field surface acoustic waves induced by laser line source[J]. Infrared and Laser Engineering, 2007, 36(s1):324-327 (in Chinese).
[4] ARIAS I, ACHENBACH J D. A model for the ultrasonic detection of surface-breaking cracks by the scanning laser source technique[J]. Wave Motion, 2004, 39(1): 61-75.
[5] ACHENBACH J D. Laser excitation of surface wave motion[J]. Journal of the Mechanics and Physics of Solids, 2003, 51(11): 1885-1902.
[6] SOHN Y, KRISHNASWAMY S. Mass spring lattice modeling of the scanning laser source technique[J]. Ultrasonics, 2002, 39(8): 543-551.
[7] HE Y J, ZHU R H, SHEN Z H,et al. Numerical simulation of laserinduced transient temperature field in cylindrical shell[J]. Laser Technology, 2005, 29(4): 386-388 (in Chinese).
[8] GUAN J F. Numerical study on depth gauging of surface breaking defects using laser-generated surface acoustic waves[J]. Japanese Journal of Applied Physics, 2011, 50(3): 032703.
[9] XU B Q, LIU H K, XU G D,et al. Mixed stress-displacement finite element method for laser-generated ultrasound[J]. Laser Technology, 2014, 38(2): 230-235 (in Chinese).
[10] LIU J S, XU Z H, GU G Q. Numerical study on improvement of signal-to-noise ratio of surface acoustic waves based on laser array[J]. Laser Technology, 2011, 35(3): 403-406 (in Chinese).
[11] WANG G X, YAN G, GUAN J F. Effect of wall thickness of aluminum pipes on laser-induced ultrasonic waves[J]. Laser Technology, 2014, 38(2): 260-265 (in Chinese).
[12] WANG G X, YAN G, GUAN J F. Effect of thickness of metal hollow cylinders on laser thermoelastic generated Rayleigh wave[J]. Laser Technology, 2014, 38(1): 58-64 (in Chinese).
[13] ARIAS I, ACHENBACH J D. Thermoelastic generation of ultrasound by line-focused laser irradiation[J]. International Journal of Solids and Structures, 2003, 40(25): 6917-6935.
[14] SCRUBY C B, DEWHURST R J, HUTCHINS D A, et al. Quantitative studies of thermally generated elastic waves in laser-irradiated metals[J]. Journal of Applied Physics, 1980, 51(12): 6210-6216.
[15] GUAN J F. Numerical study on signal enhancement of the Rayleigh wave in the near-field of surface defects[J]. Japanese Journal of Applied Physics, 2010, 49(6): 062502.
-
期刊类型引用(5)
1. 张宝庆,马群,安阳杰,吉日嘎兰图,石广丰,吴铁华. 机械刻划层分结构铝膜刀具磨损研究. 制造技术与机床. 2024(02): 111-116 . 
百度学术
2. 张海棠. 翡翠鉴定中红外光谱技术运用分析. 科技资讯. 2023(16): 108-111 . 百度学术
3. 付翔,乐文冉,王颖,汪亚,邹林,邓志峰,占生宝. 基于凹面光栅的光谱检测仪性能提升的研究进展. 激光技术. 2023(06): 757-765 . 本站查看
4. 杨春梅,黄梓芸,覃静雯,陆真平,陆太进,汤紫薇. 应用钻石观测仪-红外光谱仪-激光诱导击穿光谱仪鉴定无机材料充填翡翠. 岩矿测试. 2022(02): 281-290 . 百度学术
5. 李锦,姜红,思沐,孙家政. 手持式差分拉曼光谱结合XRF方法在塑料瓶盖成分鉴定中的应用研究. 塑料工业. 2022(05): 152-157 . 百度学术
其他类型引用(1)
计量
- 文章访问数: 9
- HTML全文浏览量: 0
- PDF下载量: 27
- 被引次数: 6
下载: