Fatigue Design with Respect to Component Related Cyclic Material Behaviour and Considerations of Size Effects

Hell, Matthias; Wagener, Rainer; Kaufmann, Heinz; Melz, Tobias

doi:10.1016/j.proeng.2015.12.665

Procedia Engineering

2015

DOI: 10.1016/j.proeng.2015.12.665

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Fatigue Design with Respect to Component Related Cyclic Material Behaviour and Considerations of Size Effects

Matthias Hell

Rainer Wagener

Heinz Kaufmann

et al.

Abstract: Local fatigue approaches, as for example the notch base approach, evaluate fatigue strength on the basis of strain controlled fatigue tests in conjunction with elastic plastic stress strain analyses of component structures, considering crack initiation as fatigue criterion. In case of constant amplitude loading, a cyclic stabilisation of the material behaviour is assumed, neglecting transient effects of cyclic straining at the start of the lifetime. Under variable amplitude loading, this simplification may not… Show more

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“…Other probabilistic fatigue models are based on the weakest link concept which is often described with a Weibull distribution in fatigue limit [5][6][7][8][9][10] but also in fatigue life [11][12][13][14][15]. The probabilistic fatigue limit and fatigue life modeling often resulted in integral approaches to model the probabilistic size effect, which are already put down in design guidelines [16][17][18], but are up to now still under research [19][20][21][22][23]. Particularly in [22], a local probabilistic approach based on a Weibull distribution in LCF life arising from inherent material scatter was validated with Ni-base superalloy specimens.…”

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confidence: 99%

Probabilistic Modeling of Slip System-Based Shear Stresses and Fatigue Behavior of Coarse-Grained Ni-Base Superalloy Considering Local Grain Anisotropy and Grain Orientation

Engel

Mäde

Lion

et al. 2019

Metals

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New probabilistic lifetime approaches for coarse grained Ni-base superalloys supplement current deterministic gas turbine component design philosophies; in order to reduce safety factors and push design limits. The models are based on statistical distributions of parameters, which determine the fatigue behavior under high temperature conditions. In the following paper, Low Cycle Fatigue (LCF) test data of several material batches of polycrystalline Ni-base superalloy René80 with different grain sizes and orientation distribution (random and textured) is presented and evaluated. The textured batch, i.e., with preferential grain orientation, showed higher LCF life. Three approaches to probabilistic crack initiation life modeling are presented. One is based on Weibull distributed crack initiation life while the other two approaches are based on probabilistic Schmid factors. In order to create a realistic Schmid factor distribution, polycrystalline finite element models of the specimens were generated using Voronoi tessellations and the local mechanical behavior investigated in dependence of different grain sizes and statistically distributed grain orientations. All models were first calibrated with test data of the material with random grain orientation and then used to predict the LCF life of the material with preferential grain orientation. By considering the local multiaxiality and resulting inhomogeneous shear stress distributions, as well as grain interaction through polycrystalline Finite Element Analysis (FEA) simulation, the best consistencies between predicted and observed crack initiation lives could be achieved.

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mentioning

confidence: 99%

Probabilistic Modeling of Slip System-Based Shear Stresses and Fatigue Behavior of Coarse-Grained Ni-Base Superalloy Considering Local Grain Anisotropy and Grain Orientation

Engel

Mäde

Lion

et al. 2019

Metals

View full text Add to dashboard Cite

show abstract

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Fatigue Design with Respect to Component Related Cyclic Material Behaviour and Considerations of Size Effects

Cited by 1 publication

References 5 publications

Probabilistic Modeling of Slip System-Based Shear Stresses and Fatigue Behavior of Coarse-Grained Ni-Base Superalloy Considering Local Grain Anisotropy and Grain Orientation

Probabilistic Modeling of Slip System-Based Shear Stresses and Fatigue Behavior of Coarse-Grained Ni-Base Superalloy Considering Local Grain Anisotropy and Grain Orientation

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