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CFRP porosity ultrasonic characterization method based on ultrasonic backscattered signal recurrence quantification analysis

An ultrasonic backscattering and quantitative analysis technology, which is applied in the analysis of solids using sonic/ultrasonic/infrasonic waves, can solve the problems of low accuracy of sound velocity and density measurement, inability to establish a general porosity curve in the manufacturing process, and high manufacturing difficulty. Strict requirements for stable process, good promotion and application prospects, and low detection environment requirements

Active Publication Date: 2017-11-17
DALIAN UNIV OF TECH
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Problems solved by technology

Ultrasonic sound velocity method, ultrasonic acoustic impedance method, etc. have the disadvantages of high resolution requirements of the detection system, low accuracy of sound velocity and density measurement, etc., resulting in low applicability
Ultrasonic attenuation method has the advantages of clear detection principle, simple test method, and less influence by fiber content. It is currently the most commonly used non-destructive testing method for porosity. However, it is limited by the bottom echo. Unusable when present or weak
However, the comparison test block method has low applicability due to the difficulty in making the comparison test block, and the difference in the manufacturing process will lead to the inability to establish a general curve of porosity and ultrasonic attenuation coefficient.

Method used

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  • CFRP porosity ultrasonic characterization method based on ultrasonic backscattered signal recurrence quantification analysis
  • CFRP porosity ultrasonic characterization method based on ultrasonic backscattered signal recurrence quantification analysis
  • CFRP porosity ultrasonic characterization method based on ultrasonic backscattered signal recurrence quantification analysis

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Embodiment Construction

[0031] The connection diagram of the ultrasonic signal acquisition system adopted by the present invention is as follows: figure 1 shown. The experimental sample in this embodiment is a multi-directional CFRP laminate prepared by hot-pressing prepreg, with a fiber content of 69±3%. The specific calculation steps are as follows:

[0032] (1) Acquisition of ultrasonic backscattered signals

[0033] With the help of the ultrasonic C-scanning system, the CFRP laminate is scanned by the ultrasonic reflection method, and the area with a relatively uniform color is selected as the area to be studied according to the obtained scanning image. figure 1 The ultrasonic signal acquisition system shown in the figure collects ultrasonic backscattering signals from 32 parts in the area to be studied, and takes the signals as the time series to be studied, as shown in figure 2 (a) shown.

[0034] (2) Phase space reconstruction

[0035] For an ultrasonic backscatter signal {x i}(i=1, 2,....

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Abstract

The invention relates to a CFRP porosity ultrasonic characterization method based on ultrasonic backscattered signal recurrence quantification analysis, and belongs to the technical field of nondestructive detection. The method comprises the steps that an ultrasonic signal collecting system composed of an ultrasonic flaw detector, a delay block probe and a digital oscilloscope is adopted, an ultrasonic backscattered signal is collected, and phase-space reconstruction is conducted on the ultrasonic backscattered signal. Distance between every two time vectors in a phase space is calculated, a reference threshold value is set, a two-dimensional recursive matrix is obtained, and the two-dimensional recursive matrix is visualized to obtain a Recurrence Plot (RP). An RP graph is subjected to quantitative calculation through RQA quantitative index Recurrence Rate (RR), the correlation between the CFRP porosity P and RR is established finally, RR=aP-1, and characterization of the porosity is achieved. Compared with an ultrasonic attenuation method, the limitation that when a bottom echo does not exist or is weak, the porosity cannot be characterized is overcome through the method, and a good popularization prospect is achieved.

Description

technical field [0001] The invention relates to an ultrasonic characterization method of CFRP porosity based on recursive quantitative analysis of ultrasonic backscattering signals, which belongs to the technical field of nondestructive testing. Background technique [0002] CFRP has the advantages of designable performance, high specific strength and specific stiffness, good fatigue performance, corrosion resistance, and integral molding, and is widely used in aerospace and other fields. In the process of CFRP processing and preparation, pores will inevitably be generated, and CFRP completely free of pores does not exist. The void content is characterized by porosity. Porosity has a great influence on the mechanical properties of CFRP. Studies have pointed out that for every 1% increase in porosity, the interlaminar shear performance of composite materials decreases by 5% to 15%, until the porosity reaches 4%, this rule remains basically unchanged; with the increase of po...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G01N29/06
Inventor 林莉何晓晨金士杰丁珊珊罗忠兵
Owner DALIAN UNIV OF TECH
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