Converging thermoelastic bulk waves using a ring-shaped laser ultrasonic technique and application to thickness detection

2021 IEEE Far East NDT New Technology & Application Forum (FENDT) Pub Date : 2021-12-14 DOI:10.1109/FENDT54151.2021.9749648

Renjie Xue, Xiaochen Wang, Quan Yang, Dong Xu, Y. Sun, Jianwei Zhao

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Abstract

The laser ultrasonic contralateral detection method for material inspections mainly uses longitudinal waves with strong energy in the ablation mechanism. The effect is perfect, but it does not meet non-destructive testing (NDT) requirements due to the damage to the material surface. The thermoelastic mechanism conforms to the principle of NDT, but the excited ultrasonic energy is relatively weak. In this work, an ultrasonic converging method was studied to enhance the signal in the thermoelastic regime based on the phased array principle using a ring-shaped laser ultrasonic technique. An axicon and a convex lens were used to irradiate a ring-shaped laser on an aluminum sample to induce the bulk ultrasound. A two-wave mixing interferometer with a photorefractive crystal was used to measure the ultrasound. The signals were superim-posed at the detection point on the center axis of the laser ring, and the amplitude was enhanced. The ultrasonic signals were affected by the width and diameter of the laser ring. A novel thickness measurement method was proposed in a non-destructive and non-contact manner. The flight times of successive echoes were observed as features to reconstruct thickness.

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利用环形激光超声技术收敛热弹性体波及其在厚度检测中的应用

激光超声对侧检测材料的方法主要利用烧蚀机理中具有强能量的纵波。效果完美，但由于对材料表面的损伤，不符合无损检测(NDT)要求。热弹性机制符合无损检测原理，但激发的超声能量相对较弱。本文利用环形激光超声技术，研究了基于相控阵原理的超声会聚增强热弹性区信号的方法。采用轴突透镜和凸透镜照射环形激光，在铝样品上诱导体超声。采用光折变晶体双波混频干涉仪测量超声。在激光环中心轴线上的检测点叠加信号，增强振幅。超声信号受激光环宽度和直径的影响。提出了一种无损、非接触的新型测厚方法。以连续回波的飞行次数为特征重构厚度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2021 IEEE Far East NDT New Technology & Application Forum (FENDT)

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