Journal
THEORETICAL AND APPLIED FRACTURE MECHANICS
Volume 122, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.tafmec.2022.103625
Keywords
Notch fracture mechanics; Full-matrix capture; Total focusing method; Defect sizing; Structural integrity assessment
Categories
Funding
- UK Engineering and Physical Sciences Research Council (EPSRC) [EP/S012362/1]
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Existing structural integrity assessment procedures usually assume flaws to be infinitely sharp, which is often overly conservative. This study examines the sizing limitation and accuracy of ultrasonic array image-based techniques for non-sharp defects and highlights their influence on structural integrity assessments.
Existing structural integrity assessment procedures typically assume flaws to be infinitely sharp when they cannot be considered as local thinned areas. This assumption is often over-conservative, resulting in a pessimistic assessment of structural components and a significant underestimation of their margins of safety against fracture. One of the main challenges while adopting non-destructive evaluation techniques is distinguishing between sharp cracks (e.g., fatigue) and non-sharp defects and identifying the more severe ones. Towards this broader challenge, the present work aims to examine the sizing limitation and accuracy of ultrasonic array image-based techniques for non-sharp defects (surface breaking u-notches) and investigate how these measurements would affect the structural integrity assessment of components. Parametric numerical simulations and experimental measurements are performed to generate full-matrix capture datasets, which are then processed using the total focusing method to form an image. The image-based sizing approach is shown to perform efficiently for notch depths higher than the inspection wavelength (lambda L), i.e. as small as 0.2 mm, and semi-notch widths as small as 0.1 mm. The influence of ultrasonic measurements on structural integrity assessments is highlighted using different case studies in the context of non-sharp defects of fatigue and fracture strength estimates. For the cases under analysis, resolving non-sharp defects led up to 5x and 3x values of effective fracture toughness and fatigue strength, respectively. We have also seen that a 30 % uncertainty in semi-notch width sizing would result in a 30 % and 20 % error in fatigue strength and fracture toughness estimations, respectively.
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