On localization and void coalescence as a precursor to ductile fracture

Tekoğlu, Cihan; Hutchinson, John W.; Pardoen, Thomas

doi:10.1098/rsta.2014.0121

Cited by 129 publications

(127 citation statements)

References 48 publications

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“…In comparison to the previously reported results (Morgeneyer et al 2014b), it can be stated that even in the area closer to the notch root the same mechanisms prevail, namely, the onset and development of slant bands precedes damage, which points out that plasticity is the driving mech- These high levels of plasticity cause damage nucleation and growth leading to the final failure. This type of ductile failure corresponds to Mechanism 2 identified by Tekoglu et al (2015). However, compared with ROI 1, the strained bands in ROI 2 are more numerous and decrease in number when moving away from the notch root.…”

Section: Resultsmentioning

confidence: 83%

Slant strained band development during flat to slant crack transition in AA 2198 T8 sheet: in situ 3D measurements

et al. 2015

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International audienceIn this work 3D strain and damage analyses are performed in the immediate vicinity of the notch root of a at CT-like specimen made of aluminum alloy. Experimental data, partially exploited by Morgeneyer et al (2014b), were obtained by using synchrotron laminography and the 3D reconstructed volumes are subsequently analyzed via Digital Volume Correlation. These data enable for in situ assessments of strain elds and ductile damage in the zone where the stress triaxiality evolves from elevated to lower levels, which is accompanied by at-to-slant crack transition. The measured strain eld patterns in this area are analyzed herein in a systematic manner by studying the incremental strain activity during several loading steps. It is shown that from the very beginning of the loading history multiple slant strained bands appear in front of the notch root while the corresponding damage growth sets in at later loading stages and higher strains. The activity of the dierent strained bands at the notch root is alternating between dierent locations over the loading history. However, the band leading to nal rupture is always active. The region where slant fracture occurs is identied to be in plane strain condition with respect to the crack propagation direction

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Section: Resultsmentioning

confidence: 83%

Slant strained band development during flat to slant crack transition in AA 2198 T8 sheet: in situ 3D measurements

et al. 2015

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“…1). As discussed by Tekoglu et al (2015), polycrystalline materials may also fail due to (i) localized plastic flow only (e.g. necking up to zero cross-sectional area), (ii) localization of plastic flow after damage-free deformation, followed by void growth and nucleation inside the primary band of localization, and (iii) direct coalescence (secondary localization) without any prior occurrence of primary localization.…”

Section: Introductionmentioning

confidence: 97%

Micromechanically-motivated phenomenological Hosford–Coulomb model for predicting ductile fracture initiation at low stress triaxialities

Mohr

Marcadet

2015

International Journal of Solids and Structures

420

151

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a b s t r a c tA phenomenological ductile fracture initiation model for metals is developed for predicting ductile fracture in industrial practice. Its formulation is based on the assumption that the onset of fracture is imminent with the formation of a primary or secondary band of localization. The results from a unit cell analysis on a Levy-von Mises material with spherical defects revealed that a Mohr-Coulomb type of model is suitable for predicting the onset of shear and normal localization. To improve the agreement of the model predictions with experimental results, an extended Mohr-Coulomb criterion is proposed which makes use of the Hosford equivalent stress in combination with the normal stress acting on the plane of maximum shear. A fracture initiation model is obtained by transforming the localization criterion from stress space to the space of equivalent plastic strain, stress triaxiality and Lode angle parameter using the material's isotropic hardening law. Experimental results are presented for three different advanced high strength steels. For each material, the onset of fracture is characterized for five distinct stress states including butterfly shear, notched tension, tension with a central hole and punch experiments. The comparison of model predictions with the experimental results demonstrates that the proposed Hosford-Coulomb model can predict the instant of ductile fracture initiation in advanced high strength steels with good accuracy.

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“…Such simulation models can be supplemented with coalescence criteria (see review by Benzerga and Leblond 2010) to account for localization events at the mesoscale. Note that the latter may even occur before macroscopic localization (Tekoglu et al 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Gurson 1977;Gologanu et al 1993;Benzerga and Besson 2001;Monchiet et al 2008) the evolution law for the void volume fraction (and other possible microstructural state variables) is loading path sensitive and failure predictions with microstructurally-informed coalescence criteria (e.g. Thomason 1985;Pardoen and Hutchinson 2000;Benzerga 2002;Tekoglu et al 2015) are then loading path dependent. However, given the limited benefits of Gurson type of models as far as predicting the elasto-plastic response of sheet metal is concerned, the combination of non-porous plasticity models with damage indicator models provides an attractive framework for predicting loading path dependent fracture initiation in industrial practice.…”

Section: Introductionmentioning

confidence: 99%

Critical hardening rate model for predicting path-dependent ductile fracture

Marcadet

Mohr

2016

Int J Fract

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A new phenomenological framework for predicting ductile fracture after non-proportional loading paths is proposed, implemented into FE software and validated experimentally for a limited set of monotonic and reverse loading conditions. Assuming that ductile fracture initiation is imminent with the formation of a shear band, a shear localization criterion in terms of the elastoplastic tangent matrix is sufficient from a theoretical point of view to predict ductile fracture after proportional and non-proportional loading. As a computationally efficient alternative to analyzing the acoustic tensor, a phenomenological criterion is proposed which expresses the equivalent hardening rate at the onset of fracture as a function of the stress triaxiality and the Lode angle parameter. The mathematical form of the criterion is chosen such that it reduces to the Hosford-Coulomb criterion for proportional loading. The proposed framework implies that the plasticity model is responsible for the effect of loading history on ductile fracture. Important non-isotropic hardening features such as the Bauschinger effect, transient softening and hardening stagnation must be taken into account by the plasticity model formulation to obtain reasonable fracture predictions after nonproportional loading histories. A new comprehensive plasticity model taking the above effects into account is thus an important byproduct of this work. In addition, compression-tension and reverse-shear experiments are performed on specimens extracted from dualphase steel sheets to validate the proposed plasticity and fracture model.

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On localization and void coalescence as a precursor to ductile fracture

Cited by 129 publications

References 48 publications

Slant strained band development during flat to slant crack transition in AA 2198 T8 sheet: in situ 3D measurements

Slant strained band development during flat to slant crack transition in AA 2198 T8 sheet: in situ 3D measurements

Micromechanically-motivated phenomenological Hosford–Coulomb model for predicting ductile fracture initiation at low stress triaxialities

Critical hardening rate model for predicting path-dependent ductile fracture

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