Two-Level Model of Inelastic Deformation of FCC Polycrystals and Structure Evolution Description

Pavel S. Volegov; Peter V. Trusov

doi:10.4028/www.scientific.net/AMR.1013.249

Paper Titles

Formation of Surface Layers in Cu-C System
p.224

Structure and Properties of Surface Alloys in Ti-Y System
p.229

Models of Dislocation Formation and Mechanical Twinning by Local Reversible Martensitic Transformations in FCC Nanocrystals
p.234

Effect of Length and Cross-Sectional Area on Ni₃Fe Alloy Plasticity
p.242

Two-Level Model of Inelastic Deformation of FCC Polycrystals and Structure Evolution Description
p.249

Mathematical Modelling of the Flow Structure and Heat Transfer in a Channel with a Porous Insert
p.257

Modeling of Orientation Dependence of Critical Resolved Shear Stress and Deformation Mechanisms on Yield Point of Austenitic Stainless Steels Hardened by Interstitial and Substitution Atoms
p.264

The Influence of Dislocation Junctions on Accumulation of Dislocations in Strained FCC – Single Crystals
p.272

Mathematical Modeling of Elementary Crystallographic Slip, Limited by an Expanding Piecewise-Continuous Closed Dislocation Loop
p.280

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1013Two-Level Model of Inelastic Deformation of FCC...

Two-Level Model of Inelastic Deformation of FCC Polycrystals and Structure Evolution Description

Abstract:

The general structure of the multilevel models of inelastic deformation of materials including the internal structure evolution description was considered in the present paper. It also provides variants to address the key issues of similar type models, which are important for further development of such models. A new approach for constitutive relations coupling between constitutive relations of different scale levels was described. The suggested approach establishes connection of similar characteristics in different scale levels. The proposed coupling method also provides an unambiguous determination of material frame indifferent derivative of the Cauchy stress tensor at the macro scale, which is necessary for the formulation of constitutive relations for large deformations. In order to make it clearer an example of a two-level model of polycrystalline metals is considered; based on the physical sense analysis the hardening laws and lattices rotations of crystallites are suggested.

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Periodical:

Advanced Materials Research (Volume 1013)

Pages:

249-256

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1013.249

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Online since:

October 2014

Authors:

Pavel S. Volegov*, Peter V. Trusov

Keywords:

Constitutive Relations, Crystal Plasticity, Lattice Rotation, Multilevel Models, Quasi-Solid Motion, Texture

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