作者：邓进¹, 刘艺灏², 李海洋², 李兵¹, 潘强华¹, 张晓彤², 那雪璐²

作者单位：1. 中国特种设备检测研究院，北京 100029;
2. 中北大学先进制造技术山西省重点实验室，山西 太原 030051

关键词：超声学;激光超声;有限元仿真;斜裂纹

摘要：

该文采用有限元仿真方法分析斜裂纹与激光超声表面波的作用机理。主要研究内容包括：通过建立斜裂纹与激光超声作用的二维仿真模型，分析裂纹处透射波声场的频谱特征；并对不同深度、不同角度、不同宽度的斜裂纹进行仿真计算，实现采用透射系数对斜裂纹几何参数的分析。研究结果表明：激光超声表面波透射系数随斜裂纹深度呈线性变化，深度越大，透射系数越小，且这种变化与倾斜角度无关。同时，当斜裂纹深度大于0.5 mm且倾斜角度在45°~90°和90°~135°范围内，此时透射系数与倾斜角度呈线性关系。此外，透射系数随着裂纹宽度的增大而减小，且这种变化与深度、倾斜角度无关。该文研究结果可为激光超声定量检测斜裂纹的深度、宽度与角度提供有力的仿真研究参考。

Total optical detection technology for quantitative detection of oblique crack
DENG Jin¹, LIU Yihao², LI Haiyang², LI Bing¹, PAN Qianghua¹, ZHANG Xiaotong², NA Xuelu²
1. China Special Equipment Testing and Research Institute, Beijing 100029,China;
2. Shanxi Key Laboratory of Advanced Manufacturing Technology, North China University,Taiyuan 030051,China
Abstract: The mechanism of action between oblique crack and laser ultrasonic surface wave is analyzed by finite element simulation method. The main research contents including: by establishing a two-dimensional simulation model of oblique crack and laser ultrasonic action, the spectral characteristics of the transmitted waves field at the crack are analyzed. The oblique cracks with different depth and angle are simulated, and the geometrical parameters of cracks are analyzed by means of transmission coefficients. The results show that the transmission coefficients of laser ultrasonic surface wave changes linearly with the depth of oblique crack, and the greater the depth, the smaller the transmission coefficient, and this change is independent of the tilt Angle. At the same time, when the depth of the oblique crack is greater than 0.5 mm and the tilt angle is within the range of 45°-90° and 90°-135°, the transmission coefficients are linearly related to the tilt angles. Besides, the transmission coefficient decreases with the increase of width, and this change is independent of the tilt Angle and depth. The results of this paper can provide a powerful reference for the simulation of laser ultrasonic quantitative detection of the depth and angle of oblique cracks.
Keywords: ultrasonics;laser ultrasound;finite element simulation;oblique crack
2022, 48(3):90-98  收稿日期: 2020-12-05;收到修改稿日期: 2021-01-15
基金项目: 山西省高等学校科技创新项目（2019057）；中北大学先进制造技术山西省重点实验室开放课题研究基金（XJZZ202006）；国家重大科研仪器研制项目（61927807）
作者简介: 邓进（1988-），江西抚州市人，工程师，硕士，无损检测技术原理与应用
参考文献
[1] WHITE R M. Generation of elastic waves by transient surface heating[J]. Journal of Applied Physics, 2003, 34(12): 3559-3567
[2] ASKARYAN G A, BULANOV S V, DUDNIKOVA G I, et al. Magnetic interaction of ultrashorthigh-intensity laser pulses in plasmas[J]. Plasma Physics and Controlled Fusion, 1997, 39(5A): 137-144
[3] SCRUBY C B, DEWHURST R J, HUTCHINS D A, et al. Quantitative studies of thennally generated elastic waves laser-radiated metals[J]. Journal of Applied Physics, 2008, 51(12): 6210-6216
[4] ROSE L R F. Point-source representation for laser-generated ultrasound[J]. he Journal of the Acoustical Society of America, 1984, 75(3): 723-732
[5] SPICER J B. Laser ultrasonics in finite structures: comprehensive modelling with supporting experiment [D]. Thesis：THE JOHNS HOPKINS UNIVERSITY, 1991.
[6] BERNSTEINJ R, SPICER J B. Line source representation for laser-generated ultrasound in aluminum[J]. TheJournal of the Acoustical Society of America, 2000, 107(3): 1352-1357
[7] ARIAS I, ACHENBACH J D. Thermoelastic generation of ultrasound by line-focused laser irradiation[J]. International Joumal of Solids and Structures, 2003, 40(25): 6917-6935
[8] ARIAS I, ACHENBACH J D. A model for the ultrasonic detection of surface-breaking cracks by the scanninglaser source technique[J]. Wave Motion, 2004, 39(1): 61-75
[9] 陈龙, 刘星, 詹超, 李阳. 金属箔材弹性常数的激光超声测量方法[J/OL]. 中国激光: 1-17[2020-10-02].
[10] 刘增华, 冯雪健, 任捷, 等. 基于频率-波数分析的激光Lamb波传播特性试验研究[J]. 振动与冲击, 2019, 38(22): 70-78
[11] 张月影, 倪辰荫, 沈中华. 光热调制裂纹闭合可逆/不可逆变化的激光超声监测[J/OL]. 中国激光: 1-14[2020-10-02].
[12] 王纪俊, 沈中华, 许伯强, 等. 金属和非金属材料中激光超声前驱小波分析[J]. 中国激光, 2006(8): 1127-1132
[13] 赵燕飞. 激光超声表面波的特性分析与量化表征研究[D]. 太原: 中北大学, 2020.
[14] 张颖志. 基于激光超声技术的金属表面缺陷检测研究[D]. 大连: 大连理工大学, 2015.
[15] 丁一珊, 杨世锡, 甘春标. 利用激光超声技术研究金属裂纹缺陷的检测波特性[J]. 振动与冲击, 2015, 34(14): 33-37
[16] 郭海洋. 带涂层机械零件表面缺陷的激光超声检测方法研究[D]. 大连: 大连理工大学, 2017.
[17] 李海洋, 李巧霞, 王召巴等. 基于激光超声临界频率的表面缺陷检测与评价[J]. 光学学报, 2018, 38(7): 134-142
[18] 王靖宵, 贾月梅, 冀健龙. 摩擦发电微流体传感器特性的有限元仿真研究[J]. 中国测试, 2020, 46(6): 89-94