Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure. / Baltic, Sandra; Magnien, Julien; Gänser, Hans-Peter et al.
in: International journal of solids and structures, Jahrgang 207.2020, Nr. December, 23.10.2020, S. 132-144.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Vancouver

Baltic S, Magnien J, Gänser HP, Antretter T, Hammer R. Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure. International journal of solids and structures. 2020 Okt 23;207.2020(December):132-144. doi: 10.1016/j.ijsolstr.2020.10.018

Author

Baltic, Sandra ; Magnien, Julien ; Gänser, Hans-Peter et al. / Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure. in: International journal of solids and structures. 2020 ; Jahrgang 207.2020, Nr. December. S. 132-144.

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@article{8a6d8b4043b94567a330dfa5e62bc65f,
title = "Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure",
abstract = "This article focuses on predicting the instant of failure in a real scale component of complex geometry and loading using a ductile damage model calibrated exclusively on small-scale laboratory specimens of relatively simple shape. The ductile behaviour of a strain hardened aluminium alloy AA1050, formed into a thin-walled component, is modelled by a coupled ductile fracture locus model presented in a recent study (Baltic et al., 2020). The component is exposed to high internal pressure and has a safety vent designed for safe pressure handling. The extensive plastic deformation in the safety vent leads to localised ductile failure occurring at a limit load. The pertaining material parameters were calibrated solely from basic ductile fracture experiments in the preceding work (Baltic et al., 2020), where the bottom section of the thin-walled component was machined into notched and shear samples to characterize different states of stress and to construct a well-defined fracture locus. Although the calibrated material model relies on the local fracture strain measurements, it involves a regularization as a function of the length scale defined as a width of the observed localisation band from Digital Image Correlation (DIC) analysis. In the current study the calibration on small-scale specimens is complemented by a large-scale specimen to determine the length scale correction crucial for capturing the correct width of the localisation band in the analysed structure. This is necessary because the failure initiation zones of the calibration specimens and the real size structure, i.e. their gauge lengths where the localisation band appears, vastly differ in size. Finite element (FE) model results are compared to measurements of the deformation of the aluminium component under pressure and maximum load prior to failure. The numerical and experimental results show an excellent agreement and consistent fracture predictions for various mesh discretizations.",
keywords = "Damage criteria, Failure, Large deformation, Shear band, Structure",
author = "Sandra Baltic and Julien Magnien and Hans-Peter G{\"a}nser and Thomas Antretter and Ren{\'e} Hammer",
year = "2020",
month = oct,
day = "23",
doi = "10.1016/j.ijsolstr.2020.10.018",
language = "English",
volume = "207.2020",
pages = "132--144",
journal = "International journal of solids and structures",
issn = "0020-7683",
publisher = "Elsevier",
number = "December",

}

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TY - JOUR

T1 - Coupled damage variable based on fracture locus: Prediction of ductile failure in a complex structure

AU - Baltic, Sandra

AU - Magnien, Julien

AU - Gänser, Hans-Peter

AU - Antretter, Thomas

AU - Hammer, René

PY - 2020/10/23

Y1 - 2020/10/23

N2 - This article focuses on predicting the instant of failure in a real scale component of complex geometry and loading using a ductile damage model calibrated exclusively on small-scale laboratory specimens of relatively simple shape. The ductile behaviour of a strain hardened aluminium alloy AA1050, formed into a thin-walled component, is modelled by a coupled ductile fracture locus model presented in a recent study (Baltic et al., 2020). The component is exposed to high internal pressure and has a safety vent designed for safe pressure handling. The extensive plastic deformation in the safety vent leads to localised ductile failure occurring at a limit load. The pertaining material parameters were calibrated solely from basic ductile fracture experiments in the preceding work (Baltic et al., 2020), where the bottom section of the thin-walled component was machined into notched and shear samples to characterize different states of stress and to construct a well-defined fracture locus. Although the calibrated material model relies on the local fracture strain measurements, it involves a regularization as a function of the length scale defined as a width of the observed localisation band from Digital Image Correlation (DIC) analysis. In the current study the calibration on small-scale specimens is complemented by a large-scale specimen to determine the length scale correction crucial for capturing the correct width of the localisation band in the analysed structure. This is necessary because the failure initiation zones of the calibration specimens and the real size structure, i.e. their gauge lengths where the localisation band appears, vastly differ in size. Finite element (FE) model results are compared to measurements of the deformation of the aluminium component under pressure and maximum load prior to failure. The numerical and experimental results show an excellent agreement and consistent fracture predictions for various mesh discretizations.

AB - This article focuses on predicting the instant of failure in a real scale component of complex geometry and loading using a ductile damage model calibrated exclusively on small-scale laboratory specimens of relatively simple shape. The ductile behaviour of a strain hardened aluminium alloy AA1050, formed into a thin-walled component, is modelled by a coupled ductile fracture locus model presented in a recent study (Baltic et al., 2020). The component is exposed to high internal pressure and has a safety vent designed for safe pressure handling. The extensive plastic deformation in the safety vent leads to localised ductile failure occurring at a limit load. The pertaining material parameters were calibrated solely from basic ductile fracture experiments in the preceding work (Baltic et al., 2020), where the bottom section of the thin-walled component was machined into notched and shear samples to characterize different states of stress and to construct a well-defined fracture locus. Although the calibrated material model relies on the local fracture strain measurements, it involves a regularization as a function of the length scale defined as a width of the observed localisation band from Digital Image Correlation (DIC) analysis. In the current study the calibration on small-scale specimens is complemented by a large-scale specimen to determine the length scale correction crucial for capturing the correct width of the localisation band in the analysed structure. This is necessary because the failure initiation zones of the calibration specimens and the real size structure, i.e. their gauge lengths where the localisation band appears, vastly differ in size. Finite element (FE) model results are compared to measurements of the deformation of the aluminium component under pressure and maximum load prior to failure. The numerical and experimental results show an excellent agreement and consistent fracture predictions for various mesh discretizations.

KW - Damage criteria

KW - Failure

KW - Large deformation

KW - Shear band

KW - Structure

U2 - 10.1016/j.ijsolstr.2020.10.018

DO - 10.1016/j.ijsolstr.2020.10.018

M3 - Article

VL - 207.2020

SP - 132

EP - 144

JO - International journal of solids and structures

JF - International journal of solids and structures

SN - 0020-7683

IS - December

ER -