A Model for Fatigue Crack Growth in the Paris Regime under the Variability of Cyclic Hardening and Elastic Properties

Kebir, Tayeb; Benguediab, M.; Imad, A.

doi:10.1515/fas-2017-0010

Cited by 8 publications

(4 citation statements)

References 42 publications

(73 reference statements)

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“…where a is the length of the crack, N is the number of cycles, C is the Paris constant, and m is the Paris exponent. Both C and m are dependent strongly on the cyclic hardening exponent and mechanical properties [42], and they are obtained experimentally. Several authors [43,44] identified a very consistent empirical relationship between Paris' law parameters, which was supported by experimental results, such as [45,46].…”

Section: Mixed-mode Fatigue Life Evaluation Proceduresmentioning

confidence: 79%

Prediction of Fatigue Crack Growth Rate and Stress Intensity Factors Using the Finite Element Method

Fageehi

2022

Advances in Materials Science and Engineering

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This study investigates crack growth and stress intensity factors via finite element methods in linear elastic fracture mechanics. The procedure involves estimating stress intensity factors (SIFs), crack trajectory, and fatigue life, using two different softwares in both two and three-dimensional analyses. Crack modeling was done in a variety of ways depending on the software. ANSYS Mechanical R19.2 and FRANC2D/L software were used to prognosticate fatigue crack growth, fatigue life, and associated stress intensity factors under plane stress state. Fatigue analysis was governed by Paris’s law and crack growth direction by the theory of maximum circumferential stress. The results show that the fatigue growth was attracted to the hole and either changes its direction to reach the hole or floats by the hole and grows as the hole is missed. The findings of the study agree with other experimental and numerical crack propagation studies presented in the literature.

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Section: Mixed-mode Fatigue Life Evaluation Proceduresmentioning

confidence: 79%

Prediction of Fatigue Crack Growth Rate and Stress Intensity Factors Using the Finite Element Method

Fageehi

2022

Advances in Materials Science and Engineering

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“…This observation suggests as a physical interpretation that the growth rate of cracks is significantly influenced by the cyclic strain hardening characteristics at the material crack tip. This phenomenon has been extensively studied in literature through analytical efforts as well as experimental results, and it has been found to have a direct impact on FCGR [25][26][27]65 and has been associated with the crack closure phenomenon. 66 Furthermore, Equation ( 25), considering the stress ratio effect, may be appropriately modified to also include the residual stresses effect in FCGR analysis.…”

Section: Methodsmentioning

confidence: 99%

Analytical modeling of fatigue crack growth in plastically pre‐strained steels

Prosgolitis,

Kermanidis

2024

Fatigue Fract Eng Mat Struct

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AbstractΑ fatigue crack growth analysis to simulate the effect of plastic pre‐straining on fatigue crack growth by taking into account the cyclic material properties is presented. A critical energy concept is implemented, which correlates the critical energy for failure under low cycle fatigue with the critical energy at the crack tip from the SED criterion, using an appropriate scaling factor. The fatigue damage process area controlling the crack increment is defined by the cyclic plastic zone. Analytical fatigue crack growth rates in plastically pre‐strained steels are verified and compared with experimental data in the S355MC and S460MC HSLA steels showing good agreement.

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“…The values of 'm' and 'C' are listed in table 1. The value of 'm' is crucial in determining the fatigue crack resistance [23][24][25]. The corresponding modeling equations for selected C(T) samples are shown as equations (5) to (8).…”

Section: Fatigue Crack Growth Behavior With Different Notch Locationsmentioning

confidence: 99%

Quasi-in-situ observation of fatigue crack growth behavior of friction stir welded 2024-T4 joint

Yang,

Samiuddin,

Chen

et al. 2024

Mater. Res. Express

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This study presents a quasi-in-situ observation of the fatigue crack growth behavior in a friction stir welded 2024-T4 joint. The microstructure and fatigue properties of the joint were investigated using electron backscatter diffraction (EBSD) technique, scanning electron microscopy (SEM), and fatigue crack growth tests. The fatigue crack growth behavior of the joint was examined by conducting fatigue crack growth tests with different notch locations. The results show that the sample with the notch in the stir zone (SZ) exhibited the highest resistance to fatigue crack growth, followed by the notched samples of the Advancing side (AS) and Retreating side (RS) weldments. Microstructural observations showed a homogeneous microstructure with a fine grain size in SZ and it was observed that this fine-grained structure significantly enhanced the material's resistance to fatigue crack growth. The experimental results were further analyzed using the Paris model to provide a quantitative understanding of the crack growth behavior. The study underlines the impact of microstructural characteristics and notch location on the fatigue performance of the weldment. Overall, the quasi-in-situ observations and experimental findings contribute to a comprehensive understanding of the fatigue crack growth behavior in friction stir welded 2024-T4 joints.

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A Model for Fatigue Crack Growth in the Paris Regime under the Variability of Cyclic Hardening and Elastic Properties

Cited by 8 publications

References 42 publications

Prediction of Fatigue Crack Growth Rate and Stress Intensity Factors Using the Finite Element Method

Prediction of Fatigue Crack Growth Rate and Stress Intensity Factors Using the Finite Element Method

Analytical modeling of fatigue crack growth in plastically pre‐strained steels

Quasi-in-situ observation of fatigue crack growth behavior of friction stir welded 2024-T4 joint

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