Abstract
The rolling texture formed in the conventional cold rolling process of commercially pure titanium (CP-Ti) for producing a metal sheet significantly limits the potential applications of CP-Ti sheets in various industrial sectors by impairing the formability. Here, we report that by exploiting a twinning-induced crystallographic texture modification, the rolling texture can be weakened and dispersed effectively, leading to a simultaneous improvement in the formability and yield strength. A two-stage cold rolling process was designed with intermediate annealing at a late stage of the conventional cold rolling process to generate deformation twins. The intermediate annealing drove the activation of {11bar{2}2} twin and {11bar{2}2} – {10bar{1}2} double twin in the second stage of the rolling process by removing the internal reaction stress developed in the first stage of the rolling process through recrystallization, and the crystallographic feature of the {11bar{2}2} twinned region, i.e., {11bar{2}2} twin texture, was effective for <a> type slips and {10bar{1}2} twinning to accommodate a through-thickness strain as well as for reducing the planar anisotropy. This enhanced thinning capability and reduced planar anisotropy in the {11bar{2}2} twin texture led to an improvement of the formability. We demonstrated the feasibility of the suggested two-stage cold rolling process with ASTM grade 2 CP-Ti.
Highlights
Rolling pass 1st to 15th passes 1st stage rolling 16th pass 2nd stage rolling 17th pass
We developed a two-stage cold rolling (TCR) process with intermediate annealing at a late stage of the CCR, which enabled the activation of deformation twins in the second stage of the rolling
Intermediate annealing is employed at a late stage of the CCR when the rolling texture is sufficiently developed so that the crystallographic lattice orientation is favorable for deformation twins
Summary
Rolling pass 1st to 15th passes 1st stage rolling 16th pass 2nd stage rolling 17th pass. Despite the favorable crystallographic lattice orientation for deformation twins, the twinning activity is thoroughly suppressed at this late stage of the CCR because of an increase in the internal reaction stress The latter is a result of the grain refinement realized through the formation of elongated grain structures and twin boundaries as well as the increase in dislocations. We developed a two-stage cold rolling (TCR) process with intermediate annealing at a late stage of the CCR, which enabled the activation of deformation twins in the second stage of the rolling This enablement was realized by removing the internal reaction stress generated in the first stage of the rolling process through recrystallization, thereby allowing an effective control of the crystallographic texture. An optimized TCR process was discussed based on the result
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