Quantitative non-destructive testing of metallic foam based on direct current potential drop method

Jing Zhang; Shejuan Xie; Xiaojuan Wang; Yong Li; Zhenmao Chen

doi:10.1109/TMAG.2011.2172679

Quantitative non-destructive testing of metallic foam based on direct current potential drop method

Jing Zhang
, Shejuan Xie
, Xiaojuan Wang
, Yong Li
, Zhenmao Chen

School of Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

To detect cavity defects in metallic foam and to predict its size, a quantitative nondestructive testing (NDT) method based on the direct current potential drop (DCPD) technique was proposed and validated in this study. At first, an efficient forward analysis scheme was introduced to simulate the DCPD signals. In order to obtain measured signals for defect reconstruction, specimens of practical aluminum metal foam with defects of different sizes were fabricated and inspected then by using a DCPD testing system. Third, an inverse analysis scheme in model based optimization category was proposed and implemented for sizing cavity defects in the metal foam. Through inversion of both simulated and measured DCPD signals, the validity of both the forward and the inverse analysis schemes was demonstrated for the quantitative DCPD evaluation of the metallic foam.

Original language	English
Article number	6136602
Pages (from-to)	375-378
Number of pages	4
Journal	IEEE Transactions on Magnetics
Volume	48
Issue number	2
DOIs	https://doi.org/10.1109/TMAG.2011.2172679
State	Published - Feb 2012

Keywords

Cavity defect
direct current potential drop (DCPD)
fast forward simulation
inversion
metallic foam (MF)
quantitative nondestructive evaluation (QNDE)

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10.1109/TMAG.2011.2172679

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title = "Quantitative non-destructive testing of metallic foam based on direct current potential drop method",

abstract = "To detect cavity defects in metallic foam and to predict its size, a quantitative nondestructive testing (NDT) method based on the direct current potential drop (DCPD) technique was proposed and validated in this study. At first, an efficient forward analysis scheme was introduced to simulate the DCPD signals. In order to obtain measured signals for defect reconstruction, specimens of practical aluminum metal foam with defects of different sizes were fabricated and inspected then by using a DCPD testing system. Third, an inverse analysis scheme in model based optimization category was proposed and implemented for sizing cavity defects in the metal foam. Through inversion of both simulated and measured DCPD signals, the validity of both the forward and the inverse analysis schemes was demonstrated for the quantitative DCPD evaluation of the metallic foam.",

keywords = "Cavity defect, direct current potential drop (DCPD), fast forward simulation, inversion, metallic foam (MF), quantitative nondestructive evaluation (QNDE)",

author = "Jing Zhang and Shejuan Xie and Xiaojuan Wang and Yong Li and Zhenmao Chen",

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AU - Zhang, Jing

AU - Xie, Shejuan

AU - Wang, Xiaojuan

AU - Li, Yong

AU - Chen, Zhenmao

PY - 2012/2

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AB - To detect cavity defects in metallic foam and to predict its size, a quantitative nondestructive testing (NDT) method based on the direct current potential drop (DCPD) technique was proposed and validated in this study. At first, an efficient forward analysis scheme was introduced to simulate the DCPD signals. In order to obtain measured signals for defect reconstruction, specimens of practical aluminum metal foam with defects of different sizes were fabricated and inspected then by using a DCPD testing system. Third, an inverse analysis scheme in model based optimization category was proposed and implemented for sizing cavity defects in the metal foam. Through inversion of both simulated and measured DCPD signals, the validity of both the forward and the inverse analysis schemes was demonstrated for the quantitative DCPD evaluation of the metallic foam.

KW - Cavity defect

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KW - inversion

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Quantitative non-destructive testing of metallic foam based on direct current potential drop method

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Keywords

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