A Rapid Deformation Texture Model Incorporating Grain Interactions: Application to Aluminium Hot Rolling Textures

W. Robert; David Piot; Gilles Guiglionda; Julian H. Driver

doi:10.4028/www.scientific.net/SSP.105.265

Paper Titles

Microstructure and Texture of Shear Bands in Cold Rolled Silicon Steel Single Crystals of Goss Orientation
p.239

A Sharp Cube Texture in Warm Rolled and Subsequently Annealed Silver Sheet
p.245

Simulation of Deformation Texture Evolution Using an Intermediate Model
p.251

Effect of Cooling Condition after Warm Rolling on the Development of Microstructure and Texture in an ELC Steel
p.259

A Rapid Deformation Texture Model Incorporating Grain Interactions: Application to Aluminium Hot Rolling Textures
p.265

A New Perspective on the Mathematical Modeling of Highly Nonlinear Anisotropic Plastic Flows in a Heterogeneous Solid
p.271

Correlation of Texture and Plastic Anisotropy in the Al-Mg Alloy AA 5005
p.277

Modeling Texture Evolution during Rolling of Magnesium Alloy AZ31
p.285

Texture Development in Nd-Fe-V and Nd-Fe-B Alloys by Hot Forging in View of Improving Permanent Magnet Properties
p.291

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A Rapid Deformation Texture Model Incorporating Grain Interactions: Application to Aluminium Hot Rolling Textures

Abstract:

A simple and general new approach to predict deformation texture evolution during large plastic strains is presented. The stress in each grain, first calculated by a Taylor model, is then modified by the stresses of adjacent grains thereby making the local slip systems and lattice rotations neighbour dependent. Examples of texture simulations during hot rolling of aluminium alloys are given. The model predictions are compared with the standard Taylor model predictions and with ODF data of the textures measured during hot plane strain compression.

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Solid State Phenomena (Volume 105)

Pages:

265-270

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.105.265

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Online since:

July 2005

Authors:

W. Robert, David Piot, Gilles Guiglionda, Julian H. Driver

Keywords:

Aluminium Alloy, Grain Interaction, Modeling, Polycrystal Plasticity, Texture

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