Large Strain Deformation and Annealing of Aluminium

X. Huang; Q. Xing; Dorte Juul Jensen; Niels Hansen

doi:10.4028/www.scientific.net/MSF.519-521.79

Paper Titles

Processing of Aluminium Alloys by Severe Plastic Deformation
p.45

The Work Hardening of some Commercial Al Alloys
p.55

The Effect of Boundary Structure on the Mechanical Properties of Aluminium Alloys
p.63

The Work Hardening of Single Phase and Multi-Phase Aluminium Alloys
p.71

Large Strain Deformation and Annealing of Aluminium
p.79

Heterogeneity in Plastic Deformation
p.85

Through-Process Texture Simulation for Aluminium Sheet Fabrication
p.93

Influence of Spatial Grain Orientation Distribution on Sheet Metal Necking
p.103

A Suitable Criterion for Precise Determination of Incipient Necking in Sheet Materials
p.111

HomeMaterials Science ForumMaterials Science Forum Vols. 519-521Large Strain Deformation and Annealing of...

Large Strain Deformation and Annealing of Aluminium

Abstract:

TEM, Kikuchi diffraction analyses, EBSD, neutron diffraction and hardness measurements have been applied in a study of commercial purity aluminum (AA1200) cold rolled to strains 2 and 4 and afterwards recovered by a heat treatment for 2h at temperatures up to 220 °C. The deformation microstructure is a lamellar structure delineated by dislocation boundaries and high angle boundaries ( ) parallel to the rolling plane. The macrotexture is a typical rolling texture which is composed of individual texture components present as micrometer- and submicrometre-sized volumes. In the lamellar structure, correlations have been established between microstructural parameters and the local texture, showing for example that the density of high angle boundaries and the stored energy vary locally. The local variations affect the annealing behaviors in a way that some regions coarsen faster than others, leading to a recovered structure which is heterogeneous.