Prediction of Earing in IF Steels by Using Crystal Plasticity Finite Element Method

Shi Hoon Choi; Beong Young Lee

doi:10.4028/www.scientific.net/MSF.495-497.1237

Paper Titles

Effect of Deformation Texture Component Composition on Cube Texture Formation during Primary Recrystallization in Ni-Based Alloys
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Calculation of the Parent hcp Grain Orientation from Inherited Variants in the hcp to t and in the hcp to cc Phase Transformations Application to the α-γ Transformation in TiAl-Based Alloys
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Micromechanisms Involved in Grain Boundary Engineering
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Effect of Hexagonal Crystal Structure Anisotropy on the Selective Grain Boundary Mobility during Texture Formation and Secondary Recrystallization in Zn
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Prediction of Earing in IF Steels by Using Crystal Plasticity Finite Element Method
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Effect of Stacking Fault Energy on Evolution of Recrystallization Textures in Drawn Wires and Rolled Sheets
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Mechanisms of New Orientation Formation during Recrystallization of Old Deformed Aluminium Bicrystals
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Grain Boundary Energy and Grain Growth in Highly-Textured Al Films and Foils: Experiment and Simulation
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The Effects of a High Magnetic Field on Microstructure, Grain Boundary Structures and Texture in a Medium Carbon Steel under Different Cooling Rates
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HomeMaterials Science ForumMaterials Science Forum Vols. 495-497Prediction of Earing in IF Steels by Using Crystal...

Prediction of Earing in IF Steels by Using Crystal Plasticity Finite Element Method

Abstract:

The effect of five ideal texture components ({001}<110>, {112}<110>, {111}<110>, {111}<112> and {554}<225>) typical in interstitial free (IF) steels on the development of ears was investigated using crystal plasticity finite element method (CPFEM). For the polycrystal model, the material behavior is described using crystal plasticity theory where each integration point in the element is considered to be a single grain of polycrystalline IF steel. The experimental earing profile for a IF steel was also compared to the earing profile predicted by CPFEM.

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Periodical:

Materials Science Forum (Volumes 495-497)

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1237-1242

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https://doi.org/10.4028/www.scientific.net/MSF.495-497.1237

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Online since:

September 2005

Authors:

Shi Hoon Choi, Beong Young Lee

Keywords:

Crystal Plasticity, Earing, Finite Element Model (FEM), Interstitial Free Steel, Neutron Diffraction

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