Defect Detection in Carbon-Fiber Composites using Lamb-Wave Tomographic Methods

Defect Detection in Carbon-Fiber Composites using Lamb-Wave Tomographic Methods

Lamb-wave tomography (LWT) offers a powerful nondestructive technique for the health assessment of large structures as their propagation properties depend on the thickness and the mechanical properties of the material. Development of a fast and accurate algorithm for defect detection is of paramount...

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Bibliographic Details
Published in:Research in nondestructive evaluation Vol. 18; no. 2; pp. 101 - 119
Main Authors: Khare, Saurabh, Razdan, Mayuri, Munshi, Prabhat, Soma Sekhar, B. V., Balasubramaniam, K.
Format: Journal Article
Language:English
Published: Taylor & Francis Group 01-04-2007
Subjects:
lamb waves
MART
structural health monitoring
tomographic imaging
Online Access:Get full text
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Summary:Lamb-wave tomography (LWT) offers a powerful nondestructive technique for the health assessment of large structures as their propagation properties depend on the thickness and the mechanical properties of the material. Development of a fast and accurate algorithm for defect detection is of paramount importance in any structural-health-monitoring (SHM) system. The present study explores the prospects of LWT as a SHM technique with an accent on developing a suitable algorithm for real-time inspection. Projection data is collected by electronically scanning an array of ultrasonic sensors arranged in a modified cross-hole geometry. The data thus collected is investigated to extract energy profile of the traveling waves. Multiplicative algebraic reconstruction technique (MART) algorithms are used as a tool for tomographic reconstruction from a set of multiple independent measurements. The performance of algorithms is evaluated from the point of view of the cost of algorithm, achievable resolution, and accuracy of results. Experimental results show that MART is capable of characterizing defects in thin isotropic and composite plates within a reasonable error band (±26% normalized, ±2.6 RMS) and is suitable for application to LWT of large structures such as aircraft skins.
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ISSN:0934-9847
1432-2110
DOI:10.1080/09349840601128812