Frequency Dependence of the b-Value Used for Acoustic Emission Analysis of Glass Fiber Reinforced Plastics

复合材料期刊(英文) Pub Date : 2017-07-05 DOI:10.4236/OJCM.2017.73007

D. Jung, Y. Mizutani, A. Todoroki, Yoshiro Suzuki

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引用次数: 7

Abstract

Acoustic Emission Testing (AT) is one of the major non-destructive testing methods used for severity evaluation of structures. Amplitude distributions of AE signals are characterized by b-value and the value is mainly used for the severity evaluation of concrete structures until now. The value is assumed to be independent with propagation distance between acoustic emission sources to AE sensors. We evaluate the influence of the wide frequency band encountered in the fracture behavior of glass fiber reinforced plastic (GFRP) on the b-value analysis. In tensile tests, the b-value was determined from an acoustic emission (AE) source generated near a centered hole in a specimen of GFRP. At 15 mm from the hole, the b-value analysis indicated a decreasing trend with increasing tensile stress. At a propagation length of 45 mm, farthest from the hole, a small number of AE signals were received. The attenuation is more rapid for high-frequency AE signals. Thus, the amplitude distribution bandwidth is wide and the b-value changes. This change in b-value for GFRPs is investigated by analyzing the spectral components of the AE signals. For a single-frequency AE source, the b-value is unchanged with propagation length. In contrast, multiple-frequency AE sources produce changes in b-value proportional to the fraction of each spectral component in the received signal. This is due to the frequency dependence of the attenuation with propagation length. From these results, the b-value analysis cannot be applied to considering frequency dependence of AE attenuation.

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用于玻璃纤维增强塑料声发射分析的b值的频率相关性

声发射检测（AT）是用于结构严重性评估的主要无损检测方法之一。声发射信号的振幅分布以b值为特征，该值目前主要用于混凝土结构的严重性评估。假设该值与声发射源到AE传感器之间的传播距离无关。我们评估了玻璃纤维增强塑料（GFRP）断裂行为中遇到的宽频带对b值分析的影响。在拉伸试验中，b值是由GFRP试样中中心孔附近产生的声发射（AE）源确定的。在距离孔15mm处，b值分析表明，随着拉伸应力的增加，b值呈下降趋势。在距离孔最远的45mm的传播长度处，接收到少量AE信号。高频AE信号的衰减速度更快。因此，振幅分布带宽宽并且b值改变。通过分析AE信号的频谱分量来研究GFRP的b值的这种变化。对于单频声发射源，b值随传播长度的变化而不变。相反，多个频率AE源产生的b值变化与接收信号中每个频谱分量的分数成比例。这是由于衰减随传播长度的频率依赖性。根据这些结果，b值分析不能用于考虑AE衰减的频率依赖性。

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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复合材料期刊(英文)

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