Digital image correlation technique for failure and crack propagation of fibre-reinforced polymer composites – A review

Naufal, Muhammad Irfan; Wong, King Jye; Israr, Haris Ahmad; Nejad, Ali Farokhi; Rahimian Koloor, Seyed Saeid; Gan, Khong Wui; Faizi, Mohd Khairul; Siebert, Geralt

doi:10.1177/26349833241253619

Composites and Advanced Materials

2024

DOI: 10.1177/26349833241253619

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Digital image correlation technique for failure and crack propagation of fibre-reinforced polymer composites – A review

Muhammad Irfan Naufal,

King Jye Wong,

Haris Ahmad Israr

et al.

Abstract: Digital image correlation (DIC) is a powerful technique for determining material deformation and damage and currently is viewed as a potential method to study failure and crack propagation in advanced composite materials. Case studies in concrete, epoxy adhesives, and carbon/epoxy laminates demonstrate the effectiveness of the DIC technique in visualizing crack propagation. This review highlights the applications, challenges, and implementation of the DIC technique in the failure and crack propagation of fibre… Show more

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Characterization of early fatigue damage in CFRP unidirectional laminates based on Micro‐CT

Tianyu,

Zhiming,

et al. 2024

Polymer Composites

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Fatigue damages of Carbon Fiber Reinforced Polymer (CFRP) laminates are not obvious. Obtaining the evolution of the internal fatigue damage in CFRP laminates before visible cracks occur is of vital importance for ensuring structural reliability. Micro X‐ray computed tomography (Micro‐CT) can provide micron scale nondestructive imaging of internal structure of materials. In this paper, a preliminary study was conducted on the early fatigue damage evolution of 0° UD laminates. Axial tension‐tension fatigue tests of [0]16 CFRP laminates were carried out, and the evolutionary behavior of damages was confirmed by fatigue dissipated energy. Then, the internal damages of fatigued specimens were observed and reconstructed using Micro‐CT, and statistical parameters such as damage sphericity, length and angle were calculated. The spatial distribution characteristics of cracks were further acquired by surface porosity and frequency distribution of damage positions in ROI. Early damages from tensile‐tensile fatigue in 0° UD laminates extend along the fiber direction with original defects in the interlayer resin enrichment areas as the nucleus, and tend to concentrate near the width edge of the specimens. Finally, a “sandwich” structural model was developed to analyze the internal stresses of laminates under the influence of interlayer resin enrichment. The FEA results revealed that the internal stresses σy and σz concentrate near the width edges of the specimen, resulting in cracks tend to evolve more in the regions close to edges.Highlights Imaging matrix cracks of specimens by Micro‐CT at 12.91 μm voxel size. Demonstrating evolution patterns of cracks with its morphology statistics. Revealing crack distributions in ROIs with variations of surface porosity. Analyzing internal stress distribution by “sandwich” model created from reality.

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Characterization of early fatigue damage in CFRP unidirectional laminates based on Micro‐CT

Tianyu,

Zhiming,

et al. 2024

Polymer Composites

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Digital image correlation technique for failure and crack propagation of fibre-reinforced polymer composites – A review

Cited by 1 publication

References 189 publications

Characterization of early fatigue damage in CFRP unidirectional laminates based on Micro‐CT

Characterization of early fatigue damage in CFRP unidirectional laminates based on Micro‐CT

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