A coupled microvoid elongation and dilation based ductile fracture model for structural steels

Ravi Kiran; Kapil Khandelwal

doi:10.1016/j.engfracmech.2015.06.071

A coupled microvoid elongation and dilation based ductile fracture model for structural steels

Ravi Kiran, Kapil Khandelwal

Research output: Contribution to journal › Article › peer-review

18 Scopus citations

Abstract

This paper presents the formulation, implementation, calibration and validation of microvoid elongation and dilation based continuum damage model (MED-CDM) for ductile fracture simulation. The damage evolution in this model is derived from micromechanical analyses that accounts for the microscopic damage due to microvoid elongation and dilation. The proposed model is implemented in Abaqus® finite element program, and is calibrated and validated using existing experimental data for a range of stress triaxialities. The proposed model is shown to accurately predict the load displacement behavior, fracture strains, fracture initiation locations and the underlying microscopic damage mechanisms that are responsible for the fracture initiation in ASTM A992 structural steels.

Original language	English (US)
Pages (from-to)	15-42
Number of pages	28
Journal	Engineering Fracture Mechanics
Volume	145
DOIs	https://doi.org/10.1016/j.engfracmech.2015.06.071
State	Published - Aug 1 2015
Externally published	Yes

Keywords

Continuum damage model
Ductile fracture
Lode parameter
Microvoid dilation
Microvoid elongation
Triaxiality

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

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10.1016/j.engfracmech.2015.06.071

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title = "A coupled microvoid elongation and dilation based ductile fracture model for structural steels",

abstract = "This paper presents the formulation, implementation, calibration and validation of microvoid elongation and dilation based continuum damage model (MED-CDM) for ductile fracture simulation. The damage evolution in this model is derived from micromechanical analyses that accounts for the microscopic damage due to microvoid elongation and dilation. The proposed model is implemented in Abaqus{\textregistered} finite element program, and is calibrated and validated using existing experimental data for a range of stress triaxialities. The proposed model is shown to accurately predict the load displacement behavior, fracture strains, fracture initiation locations and the underlying microscopic damage mechanisms that are responsible for the fracture initiation in ASTM A992 structural steels.",

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AU - Kiran, Ravi

AU - Khandelwal, Kapil

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N2 - This paper presents the formulation, implementation, calibration and validation of microvoid elongation and dilation based continuum damage model (MED-CDM) for ductile fracture simulation. The damage evolution in this model is derived from micromechanical analyses that accounts for the microscopic damage due to microvoid elongation and dilation. The proposed model is implemented in Abaqus® finite element program, and is calibrated and validated using existing experimental data for a range of stress triaxialities. The proposed model is shown to accurately predict the load displacement behavior, fracture strains, fracture initiation locations and the underlying microscopic damage mechanisms that are responsible for the fracture initiation in ASTM A992 structural steels.

AB - This paper presents the formulation, implementation, calibration and validation of microvoid elongation and dilation based continuum damage model (MED-CDM) for ductile fracture simulation. The damage evolution in this model is derived from micromechanical analyses that accounts for the microscopic damage due to microvoid elongation and dilation. The proposed model is implemented in Abaqus® finite element program, and is calibrated and validated using existing experimental data for a range of stress triaxialities. The proposed model is shown to accurately predict the load displacement behavior, fracture strains, fracture initiation locations and the underlying microscopic damage mechanisms that are responsible for the fracture initiation in ASTM A992 structural steels.

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KW - Ductile fracture

KW - Lode parameter

KW - Microvoid dilation

KW - Microvoid elongation

KW - Triaxiality

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A coupled microvoid elongation and dilation based ductile fracture model for structural steels

Abstract

Keywords

ASJC Scopus subject areas

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