Photo-Acoustic Based Non-Contact and Non-Destructive Evaluation for Detection of Damage Precursors in Composites

Siqi Wang, L. Xiang, Yingtao Liu, Hong Liu
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引用次数: 2

Abstract

Damage precursor in composites can lead to large structural damages, such as delamination, in carbon fiber reinforced plastic (CFRP) composites due to complex load conditions and environmental effects. In addition, multiple types of damage precursors including micro-scale matrix cracks, fiber pull-out from matrix, and fiber breakages, are extremely difficult to detect due to the limitation of resolution of current non-destructive evaluation (NDE) technologies. This paper presents a photo-acoustic based non-contact NDE system for the detection of damage precursors with extremely high resolution up to one hundred micrometers. This system consists of three major components: picoseconds pulsed laser based ultrasonic actuator, ultrasound receiver, and data processing and computing subsystem. Picoseconds pulsed laser is used to generate ultrasonic propagations in composites during the NDE process, and the ultrasound signals are recorded by the ultrasound receiver. Three-dimensional microstructure of the individual composites grid within the composite is able to be reconstructed for further analysis. The size and position of the damage precursors are evaluated with high accuracy up to 100 μm. The experimental results demonstrate that this imaging system is able to provide a novel non-contact approach with extremely high resolution for damage detection of CFRP composites. In addition, the developed NDE system has a wide industrial application in aerospace, automobile, civil, mechanical, and other key industries.
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基于光声的复合材料损伤前驱体检测的非接触无损评价
复合材料中的损伤前驱体由于复杂的载荷条件和环境影响,会导致碳纤维增强塑料(CFRP)复合材料发生较大的结构损伤,如分层。此外,由于现有无损检测技术的分辨率限制,多种类型的损伤前兆,包括微尺度基体裂纹、纤维从基体中拉出、纤维断裂等,都极难检测到。本文提出了一种基于光声的非接触无损检测系统,该系统具有极高的分辨率,可达100微米。该系统由三个主要部分组成:皮秒脉冲激光超声致动器、超声接收器和数据处理与计算子系统。在无损检测过程中,利用皮秒脉冲激光在复合材料中产生超声传播,超声信号由超声接收器记录。复合材料内单个复合材料网格的三维微观结构能够被重建,以便进一步分析。对损伤前驱体的尺寸和位置进行了高精度评估,精度可达100 μm。实验结果表明,该成像系统能够为CFRP复合材料的损伤检测提供一种新颖的非接触、超高分辨率的方法。开发的无损检测系统在航空航天、汽车、民用、机械等重点行业有着广泛的工业应用。
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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