Nondestructive Evaluation of Fiberglass Reinforced Plastic Subjected to Localized Heat Damage, Using Acoustic Emission

Recent Advances in Solids/Structures and Application of Metallic Materials Pub Date : 1997-11-16 DOI:10.1115/imece1997-0529

H. Nayeb-Hashemi, P. Kisnomo, N. Saniei

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引用次数: 5

Abstract

Fiberglass reinforced composites are extensively used in electronic and aerospace applications due to their high specific strength. In these applications, they are often subjected to localized heat damage due to various sources such as electronic over heating, electric arching, and laser beams. In order to ensure their reliability, it is important to predict their residual properties using nondestructive evaluation techniques. Unidirectional fiberglass composite specimens were manufactured using three layers of a fiber glass prepreg. Some of the specimens were subjected to a localized heat damage using a heated copper tip with a diameter of 12.5 mm at 360° C and other specimens were subjected to a laser beam operated at 0.64 Watts/mm2 for various exposure time. In addition, the number of laser damaged spots varied among similar specimens. The specimens were then subjected to tension tests while acoustic emission activities of specimens were collected. The AE activity of all specimens showed three distinct regions. An early activity, followed by a relatively dormant activity period and a high exponential activity before final failure. The period of the dormant activity was independent of the contact heat duration of less than 15 minutes. However, the dormant period for the laser damaged specimens was a function of the number of laser damaged spots. The majority of the early activities for all specimens were related to mechanisms other than fiber fracture. The activity in the dormant period for contact heat damage was mainly controlled by the fiber fracture, while for the undamaged and laser damaged specimens was by the interfacial failure. This could be justified since laser damaged specimens contained numerous damaged fibers leading to a significant interfacial shear stress. The failure modes of specimens further supported this conclusion. The state of the damage in the composite was predicted using the AE-stress delay concept.

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基于声发射的玻璃钢局部热损伤无损评价

玻璃纤维增强复合材料因其高比强度而广泛应用于电子和航空航天领域。在这些应用中，由于电子过热、电拱和激光束等各种来源，它们经常受到局部热损伤。为了保证其可靠性，利用无损评价技术对其残余性能进行预测是十分重要的。用三层玻璃纤维预浸料制备了单向玻璃纤维复合材料试样。部分样品在360°C下使用直径为12.5 mm的加热铜尖进行局部热损伤，其他样品在不同曝光时间下使用0.64瓦/mm2的激光束。此外，在相似的样品中，激光损伤斑的数量也有所不同。然后对试件进行拉伸试验，同时采集试件的声发射活动。所有标本的声发射活性表现为三个不同的区域。一个早期的活动，随后是一个相对休眠的活动期，在最终失败之前是一个高指数的活动。在接触热持续时间小于15分钟的情况下，休眠活动的持续时间不受影响。然而，激光损伤标本的休眠期是激光损伤斑数量的函数。所有试件的大部分早期活动与纤维断裂以外的机制有关。接触热损伤休眠期的活动主要受纤维断裂控制，而未损伤和激光损伤试样的活动主要受界面破坏控制。这可能是合理的，因为激光损伤的样品包含许多损坏的纤维，导致显著的界面剪切应力。试件的破坏模式进一步支持了这一结论。采用ae -应力延迟概念对复合材料的损伤状态进行预测。

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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Recent Advances in Solids/Structures and Application of Metallic Materials

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