Damage Detection in Composite Based on Time Reversal Lamb Waves Method

doi:10.3969/j.issn.1004-132X.2021.01.004

Abstract

Abstract: In order to detect damage of composites, focusing characteristics of time reversal Lamb waves method was adapted, and PZT sensors were mounted on a composite plate to excite and receive Lamb waves. The time reversal method may realize damage detection quickly and accurately without comparing reference signals. An improved damage imaging method was proposed to realize damage visualization. Experimental results demonstrated the effectivenesses of the detection method and superiority of the improved method.

Key words: Lamb wave, time reversal method, damage image, composite material, structural health monitoring

摘要： 为检测复合材料损伤，利用Lamb波时间反转法的聚焦特性，在复合材料布置压电传感器激励和接收Lamb波。时间反转法无需对比基准信号就能快速准确地实现损伤的判别，提出的改进损伤成像方法可实现损伤情况可视化。实验研究验证了检测方法的有效性和改进损伤成像方法的优越性。

关键词: Lamb波, 时间反转法, 损伤成像, 复合材料, 健康监测

CLC Number:

TB332

XIA Xiaosong;ZHENG Yanping. Damage Detection in Composite Based on Time Reversal Lamb Waves Method[J]. China Mechanical Engineering, DOI: 10.3969/j.issn.1004-132X.2021.01.004.

夏小松;郑艳萍. 基于Lamb波时间反转法的复合材料损伤检测[J]. 中国机械工程, DOI: 10.3969/j.issn.1004-132X.2021.01.004.

References

［1］NJUGUNA J. Lightweight Composite Structures in Transport［M］∥MISRA A. Composite Materials for Aerospace Propulsion Related to Air and Space Transportation. Cambridge, Britain: Woodhead Publishing, 2016: 305-327.
［2］KHANH L. Application of Composite Structures in Commercial Aerospace Actuation Systems［C］∥9th AIAA Applied Aerodynamics Conference. Anaheim, 2001: 2001-1449.
［3］KUMAR S, BHARJ R S. Emerging Composite Material Use in Current Electric Vehicle: a Review［J］. Materialstoday: Proceedings, 2018,5(14, Part 2): 27946-27954.
［4］蔡菊生. 先进复合材料在航空航天领域的应用［J］. 合成材料老化与应用, 2018, 47(6):100-103.
CAI Jusheng. Application of Advanced Composite Materials in Aerospace［J］. Synthetic Materials Aging and Application, 2018, 47(6):100-103.
［5］LIANG Zeng, HUANGLiping, JING Lin. Damage Imaging of Composite Structures Using Multipath Scattering Lamb Waves［J］. Composite Structures, 2019, 216: 331-339.
［6］ZHENG Yuebin, LIU Kehai, WU Zhanjun, et al. Lamb Waves and Electro-mechanical Impedance Based Damage Detection Using a Mobile PZT Transducer Set［J］. Ultrasonics, 2019, 92: 13-20.
［7］HONG Ming, SU Zhongqing, LU Ye, et al. Locating Fatigue Damage Using Temporal Signal Features of Nonlinear Lamb Waves［J］. Mechanical Systems and Signal Processing, 2015, 60/61: 182-197.
［8］HAY T R, ROYER R L, GAO Huidong, et al. A Comparison of Embedded Sensor Lamb Wave Ultrasonic Tomography Approaches for Material Loss Detection［J］. Smart Materials and Structures, 2006,15(4): 946-951.
［9］SHEEN B, CHO Y. A Study on Quantitative Lamb Wave Tomogram via Modified RAPID Algorithm with Shape Factor Optimization［J］. International Journal of Precision Engineering and Manufacturing, 2012, 13(5):671-677.
［10］QIU Lei, YUAN Shenfang, ZHANG Xiaoyue, et al. A Time Reversal Focusing Based Impact Imaging Method and Its Evaluation on Complex Composite Structures［J］. Smart Materials and Structures, 2011, 20(10):105014.
［11］HETTLER J, TABATABAEIPOUR M, DELRUE S, et al. Emerging Technologies in Non-destructive Testing VI［C］∥Proceedings of the 6th International Conference on Emerging Technologies in Non-destructive Testing. Brussels, 2015: 117-123.
［12］WANG Qiang, YUAN Shenfang. Baseline-free Imaging Method Based on New PZT Sensor Arrangements［J］. Journal of Intelligent Material Systems and Structures, 2009, 20(14): 1663-1673.
［13］MOUSTAFA A, SALAMONE S. Fractal Dimension-based Lamb Wave Tomography Algorithm for Damage Detection in Plate-like Structures［J］. Journal of Intelligent Material Systems and Structures, 2012, 23(11): 1269-1276.
［14］CAI Jian, SHI Lihua, YUAN Shenfang, et al. High Spatial Resolution Imaging for Structural Health Monitoring Based on Virtual Time Reversal［J］. Smart Materials and Structures, 2011, 20(5): 55018-55028.
［15］ING R K, FINK M. Self-focusing and Time Recompression of Lamb Waves Using a Time Reversal Mirror［J］. Ultrasonics, 1998, 36(1/5): 179-186.
［16］ING R K, FINK M. Time-reversed Lamb Waves［J］. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 2002, 45(4):1032-1043.
［17］XU Buli, GIURGIUTIU V. Single Mode Tuning Effects on Lamb Wave Time Reversal with Piezoelectric Wafer Active Sensors for Structural Health Monitoring［J］. Journal of Nondestructive Evaluation, 2007, 26(2/4): 123-134.
［18］WANG C H, ROSE J T, CHANG F K. A Synthetic Time-reversal Imaging Method for Structural Health Monitoring［J］. Smart Materials and Structures, 2004, 13: 415-423.
［19］WANG Lei, YUAN Fuguo. Damage Identification in a Composite Plate Using Prestack Reverse-time Migration Technique［J］. Structural Health Monitoring, 2005, 4(3): 195-211.
［20］王强, 袁慎芳, 邱雷, 等. 基于时间反转理论及压电阵列技术的损伤图像监测方法［J］. 测控技术, 2008, 27(2): 8-10.
WANG Qiang, YUAN Shenfang, QIU Lei, et al. A Time-reversal Imaging Method Based on Piezoelectric Array Technique for Structure Health Monitoring［J］. Measurement Control Technology, 2008, 27(2): 8-10.
［21］蔡建, 石立华, 袁慎芳. 基于虚拟时间反转的高分辨率复合材料板结构损伤成像［J］. 复合材料学报, 2012, 29(1): 183-189.
CAI Jian, SHI Lihua, YUAN Shenfang. High-resolution Damage Imaging for Composite Plate Structures Based on Virtual Time Reversal［J］. Acta Materiae Compositae Sinica, 2012, 29(1): 183-189.
［22］LIU Zenghua, XU Qinglong, GONG Yu, et a1. A New Multichannel Time Reversal Focusing Method for Circumferential Lamb Waves and Its Applications for Defect Detection in Thick-walled Pipe with Large-diameter［J］. Ultrasonics, 2014, 54(7): 1967-1976.

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