Modelling of overload effects on fatigue crack initiation in case of carbon steel

Mlikota, Marijo; Schmauder, Siegfried; Božić, Željko; Hummel, Martin

doi:10.1111/ffe.12598

Cited by 37 publications

(16 citation statements)

References 28 publications

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“…High‐stress short fatigue cracks are subdivided into microstructural short cracks (MSC) and physical small cracks (PSC) . The microstructure has a significant role in the behavior of MSC .…”

Section: Introductionmentioning

confidence: 99%

Cracking simulation‐based fatigue life assessment

Farag

El‐Kady

Hammouda

2020

Fatigue Fract Eng Mat Struct

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A fracture mechanics numerical model is developed to simulate the collective behavior of growing short fatigue cracks originating from the surface of unnotched round specimens made of a two-phase alloy. The specimen surface roughness is considered resembling microcracks of different sizes and locations along the minimum specimen circumference. Material grains of different phases, sizes, and strengths are randomly distributed over that circumference.Variations in mechanical and microstructural features of grains are randomly distributed. Possible activities of surface cracks are predicted against loading cycles till either fracture occurs or all existing cracks become nonpropagating.The material's S-N curve and fatigue limit can, thus, be assessed. Published experimental data on ferritic-pearlitic steel specimens in push-pull constant amplitude loading (CAL) were utilized. Different specimens were randomly configured and virtually tested. Comparison of experimental results and corresponding predictions validates the model, which, further, recognizes the effect of surface roughness, specimen size, and mean stress on lives. K E Y W O R D Sendurance curve, ferritic-pearlitic steel, fracture mechanics, push-pull loading, short fatigue cracks, surface roughness

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Section: Introductionmentioning

confidence: 99%

Cracking simulation‐based fatigue life assessment

Farag

El‐Kady

Hammouda

2020

Fatigue Fract Eng Mat Struct

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“…slip band length) d, the average shear stress range Δτ on the slip band, the shear modulus G, the crack initiation energy Wc, Poisson's ratio ν, and the CRSS [10][11][12][13][14]. A more extended and detailed description of the implementation of the TM equation into FEM-based modelling and simulation of the crack initiation process has been reported in publications of the authors of this study in [5,[10][11][12][15][16][17][18] and by other researchers, too, in [13,14,19,20].…”

Section: Figurementioning

confidence: 99%

“…Multiscale approach-Coupling of methodologies at the relevant scales, and accompanying outputs (O/P) (CRSS, da/dN -crack growth rate, Nini -number of stress cycles for crack initiation, Nprop -number of stress cycles for crack propagation) [5,15,16,23]. Table 1 contains metallic materials considered in the study from [5] and their mechanical properties; namely the Young's modulus E, the shear modulus G, the Poisson's ratio υ, the yield strength Rp0.2 and the ultimate strength Rm, their average grain size d, and eventually the CRSS values.…”

Section: Figurementioning

confidence: 99%

Simulation-based Understanding of the Critical Resolved Shear Stress Relevance for the Fatigue Performance of Metallic Materials

Mlikota¹,

Schmauder²

2020

Preprint

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The paper introduces a valuable new description of fatigue strength in relation to material properties and thus a new perspective on the overall understanding of the fatigue process. Namely, a relation between the endurance limits and the accompanying values of the critical resolved shear stress (CRSS) for various metallic materials has been discovered by means of a multiscale approach for fatigue simulation. Based on the uniqueness of the relation, there is a strong indication that it is feasible to relate the endurance limit to the CRSS, and not to the ultimate strength as often done in the past.

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“…These initiation cycles are further transferred to the macroscale fatigue crack growth model based on power law equations (e.g., Paris law), which are finally used to estimate the total fatigue life, up to final fracture. By using the presented modelling workflow, the fatigue of metals can be simulated more or less independently of the experimental input [45,46,[49][50][51][52]. starting with the nanoscale, going up to micro-/mesoscales and ending up with the macroscale.…”

Section: Numerical Estimation Of Fatigue Behavior With the Help Of Crssmentioning

confidence: 99%

On the Critical Resolved Shear Stress and Its Importance in the Fatigue Performance of Steels and Other Metals with Different Crystallographic Structures

Mlikota

Schmauder

2018

Metals

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This study deals with the numerical estimation of the fatigue life represented in the form of strength-life (S-N, or Wöhler) curves of metals with different crystallographic structures, namely body-centered cubic (BCC) and face-centered cubic (FCC). Their life curves are determined by analyzing the initiation of a short crack under the influence of microstructure and subsequent growth of the long crack, respectively. Micro-models containing microstructures of the materials are set up by using the finite element method (FEM) and are applied in combination with the Tanaka-Mura (TM) equation in order to estimate the number of cycles required for the crack initiation. The long crack growth analysis is conducted using the Paris law. The study shows that the crystallographic structure is not the predominant factor that determines the shape and position of the fatigue life curve in the S-N diagram, but it is rather the material parameter known as the critical resolved shear stress (CRSS). Even though it is an FCC material, the investigated austenitic stainless steel AISI 304 shows an untypically high fatigue limit (208 MPa), which is higher than the fatigue limit of the BCC vanadium-based micro-alloyed forging steel AISI 1141 (152 MPa).

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Modelling of overload effects on fatigue crack initiation in case of carbon steel

Cited by 37 publications

References 28 publications

Cracking simulation‐based fatigue life assessment

Cracking simulation‐based fatigue life assessment

Simulation-based Understanding of the Critical Resolved Shear Stress Relevance for the Fatigue Performance of Metallic Materials

On the Critical Resolved Shear Stress and Its Importance in the Fatigue Performance of Steels and Other Metals with Different Crystallographic Structures

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