作者：陈乐, 王悦民, 耿海泉, 叶伟, 邓文力

作者单位：海军工程大学动力工程学院, 湖北 武汉 430033

关键词：超声导波;时频分析;模态分离;频散补偿;缺陷定位

摘要：

为减少超声导波多模态和频散特性对管道缺陷检测应用时的不利影响，研究弯曲导波模态分离和导波频散补偿的方法。首先将导波信号进行时频分析，并与理论计算的时频曲线进行对比，确定信号中的各个模态，然后将各个模态信号进行频散补偿处理，最后将频散补偿后的信号相加，得到最后的结果。管道缺陷检测实验表明，由多模态和频散特性产生的多个波包可由STFT方法识别出每个波包所属的模态，经频散补偿后多个波包可对应在同一缺陷位置。实验证明导波信号经模态识别、分离和频散补偿后更利于缺陷的识别和定位，同时该方法也为弯曲导波的应用提供理论基础。

Research on mode separation and dispersion compensation of flexural mode guided wave

CHEN Le, WANG Yuemin, GENG Haiquan, YE Wei, DENG Wenli

College of Power Engineering, Naval University of Engineering, Wuhan 430033, China

Abstract: In order to reduce the adverse effects of multi-modality and dispersion characteristics of ultrasonic guided wave signal on the detection of pipeline defects, the methods of flexural guided wave mode separation and dispersion compensation are studied. Firstly, the guide wave signal frequency analysis and theoretical calculation of frequency curve were compared to determine the signal of each modal, and then the signal of each modal was processed by dispersive compensation algorithm; Finally, the final results were obtained by adding the compensated signals. From the pipeline defect detection experiment results, it can be seen:multiple wave packets caused by multi-modal and frequency dispersion characteristics can be identified by STFT method and each wave packet can correspond to the same defect position after dispersion compensation. The experimental results show that the guided wave signal is more conducive to the identification and localization of the defects after the modal identification, separation and dispersion compensation, and the method provides a theoretical basis for the application of flexural guided wave.

Keywords: ultrasonic guided wave;time frequency analysis;mode separation;dispersion compensation;defect localization

2016, 42(12): 132-135  收稿日期: 2016-06-13;收到修改稿日期: 2016-07-28

基金项目: 总装备部装备预研基金项目（9140A27020115JB11001）

作者简介: 陈乐(1986-),男,山东淄博市人,博士研究生,研究方向为导波无损检测技术。

参考文献

[1] 陈志奎,贾少攀,赵亮,等. 基于物联网和超声导波的管道检测系统研究[J]. 中国测试,2013,39(2):94-97.
[2] 王悦民,谢俊丽,刘东,等. 基于磁致伸缩效应的导波无损检测技术研究进展[J]. 无损检测,2007,29(5):280-284.
[3] 苗晓婷. 基于导波的结构健康监测中特征提取技术与损伤识别方法的研究[D]. 上海:上海交通大学,2011.
[4] SHIN H J, ROSE J L. Guided waves by axisymmetric and non-axisymmetric surface loading on hollow cylinders[J]. Ultrasonics,1999,37(5):355-363.
[5] EVERY A G, SHATALOV M Y, YENWONG-FAI A S. Progress in the analysis of non-axisymmetric wave propagation in a homogeneous solid circular cylinder of a piezoelectric transversely isotropic material[J]. Physics Procedia,2010,3(1):473-479.
[6] 他得安,刘镇清. 超声无损检测中的二维快速Fourier变换及Wigner-Ville变换[J]. 无损检测,2001,23(7):313-316.
[7] 周正干,冯占英,高翌飞,等. 时频分析在超声导波信号分析中的应用[J]. 北京航空航天大学学报,2008,34(7):833-837.
[8] WILCOX P D. A rapid signal processing technique to remove the effect of dispersion from guided wave signals[J].IEEE Transactions on Ultrasonics Ferroelectrics & Frequency Control,2003,50(4):419-427.
[9] FINK M. Time reversal of ultrasonic fields. I. Basic principles[J]. IEEE Transactions on Ultrasonics Ferroelectrics & Frequency Control,1992,39(5):555-566.
[10] ING R K, FINK M. Self-focusing and time recompression of Lamb waves using a time reversal mirror[J]. Ultrasonics,1998,36(1):179-186.
[11] ZENG L, LIN J, LEI Y, et al. Waveform design for high-resolution damage detection using lamb waves[J]. IEEE Transactions on Ultrasonics Ferroelectrics & Frequency Control,2013,60(5):1025-1029.
[12] LIU L, YUAN F G. A linear mapping technique for dispersion removal of Lamb waves[J]. Structural Health Monitoring,2010,9(1):75-86.
[13] 孙雅欣,吴斌,何存富,等. 时频分析在杆中导波传播特性研究中的应用[J]. 仪器仪表学报,2006,27(z2):1316-1317.