The application of digital image correlation (DIC) in fatigue experimentation: A review

Hebert, J. A.; Khonsari, M. M.

doi:10.1111/ffe.13931

Cited by 20 publications

(4 citation statements)

References 167 publications

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“…Overall, literature shows that the integration of experimental DIC (especially HRDIC) and algorithmic analyses yields deep understanding of crack growth behaviour and its underlying mechanisms 40 . However, this approach requires entirely new test infrastructures, including interconnected hardware, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…As a consequence, for fracture mechanics, digital image correlation (DIC) has become a state-of-the-art method for generating full-field information of displacements and strains during crack growth experiments . For instance, DIC has been successfully applied together with numerical or analytical approaches to calculate the J-integral, stress intensity factors or T-stress 20,23,[25][26][27]29,[31][32][33][34][37][38][39][40][41] , analyse the crack tip plastic zone 21,22 , crack opening displacements 36,37 , or mechanisms acting locally at the crack tip, such as strain accumulation 24 . However, the non-automated acquisition and analysis of DIC data is not readily scalable in terms of time and the amount of information that can be processed.…”

mentioning

confidence: 99%

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Next generation fatigue crack growth experiments of aerospace materials

Strohmann,

Melching,

Paysan

et al. 2024

Sci Rep

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Today’s societal challenges require rapid response and smart materials solutions in almost all technical areas. Driven by these needs, data-driven research has emerged as an enabler for faster innovation cycles. In fields such as chemistry, materials science and life sciences, automatic and even autonomous data generation and processing is already accelerating knowledge discovery. In contrast, in experimental mechanics, complex investigations like studying fatigue crack growth in structural materials have traditionally adhered to standardized procedures with limited adoption of the digital transformation. In this work, we present a novel infrastructure for data-centric experimental mechanics in the field of fatigue crack growth. Our methodology incorporates a robust code base that complements a multi-scale digital image correlation and robot-assisted test rig. Using this approach, the information-to-cost ratio of fatigue crack growth experiments in aerospace materials is significantly higher compared to traditional experiments. Thus, serves as a catalyst for discovering new scientific knowledge in the field of structural materials and structures.

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

Next generation fatigue crack growth experiments of aerospace materials

Strohmann,

Melching,

Paysan

et al. 2024

Sci Rep

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“…And the crack length is monitored during the test. Common monitoring methods of crack length include plastic replica method, magnetic particle inspection method, images captured by means of optical microscope, 23 and DIC testing technology 43 . However, cracks are usually described using crack depth, and how to monitor crack depth variation has been a challenge for fatigue test of full‐scale axles.…”

Section: Introductionmentioning

confidence: 99%

Research on monitoring method for crack depth of railway hollow axle during bench test

Yan,

Wang,

Zhou

et al. 2023

Fatigue Fract Eng Mat Struct

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Hollow axles are critical safety components for high‐speed trains, and the operational safety of the axle is ensured by combining infinite life design and damage tolerance analysis based on ultrasonic testing. The establishment of the ultrasonic inspection interval requires the axle bench test, but it has been a challenge to obtain the initial crack at a determined depth. This paper proposes a method for predicting the transverse crack depth of axles by combining a full‐scale axle bench test with simulation analysis. The monitoring of crack depth is achieved by measuring the cracks on the axle surface. The crack propagation test was conducted to validate the prediction method with good results. The test results demonstrate the potential of crack monitoring methods in axle crack monitoring and provide new ideas for axle safety monitoring.

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“…Alternatively, methods like crack opening displacement (COD) or J‐integral have been developed for a direct assessment of

K

from full‐field DIC. [ 6,7 ] However, under mixed‐mode conditions, they are still under research. [ 8 ] All these methods require clear recognition of the crack tip itself.…”

Section: Introductionmentioning

confidence: 99%

Application of high‐performance DIC for a comprehensive evaluation of biaxial fatigue crack growth experiments

Blug

Conrad

Bertz

et al. 2023

Strain

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Precise determination of the remaining service life of technical components requires sufficient knowledge of fatigue crack growth behaviour and the growth rate of defects. Cracks in real components often experience multiaxial far field stresses due to their complex geometry and composite loadings acting on it. Digital image correlation (DIC) is well established for crack length and displacement measurements, but it usually requires sample preparation with speckle paint and interferes with mechanical extensometers. To overcome these limitations, we use a novel 2D DIC system combining a graphics processing unit (GPU) with a CoaXPress 2.0 camera, acquiring up to 3 GB/s of image data. It enables real‐time evaluation of both integral strain like an extensometer and full‐field DIC on images selected automatically in real‐time. This combination enables the use of one single sensor for strain‐controlled testing and fatigue crack growth characterisation. The full‐field displacement is compared to a finite‐element model (FEM) simulating the actual crack contour measured by the DIC system. The results show that high‐performance DIC has the potential to simultaneously simplify crack‐growth experiments and provide comprehensive fracture mechanical information.

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The application of digital image correlation (DIC) in fatigue experimentation: A review

Cited by 20 publications

References 167 publications

Next generation fatigue crack growth experiments of aerospace materials

Next generation fatigue crack growth experiments of aerospace materials

Research on monitoring method for crack depth of railway hollow axle during bench test

Application of high‐performance DIC for a comprehensive evaluation of biaxial fatigue crack growth experiments

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