After two-pass rolling, some twins

After two-pass rolling, some twins are found in the grains.
The stress relief annealing makes many of them disappear,
instead of isometric crystal grains, causing the grain refinement.
Three types of rolling deformation processes make different
influences on the alloy. As for the sheet 1, the upside
surface suffers a relatively larger deformation than the downside
surface; meanwhile, the stress inhomogeneously distributes
on the same surface, and DRX easily occurs in the coarse
grains. After changing the rolling directions, such as sheet 2,
the same surface possesses similar deflection, increasing the
uniformity of grain size. Sheet 3 not only possesses similar
deflection in the same surface, but also makes the upside and
downside surfaces be deformed uniformly. The grains are
refined and become more uniform with the changing of rolling
direction, which weakens the anisotropy of the alloy. Sheet 3
possesses the smallest grain size and the most uniform grains,
thus possessing the outstanding comprehensive mechanical
performance.
As a supplement coordinate deformation mechanism, the
twining during rolling process can not only provide some independent
slip systems, but also cut the coarse grains and cause
grain refinement [13]. Changing rolling directions can affect
the distribution of accumulated deformation twinning, especially
the compression twinning and double twinning. During
the low temperature rolling and heat treatment, the recrystallization
occurs. With the procedure of transformation from twin
boundaries into recrystallization grain boundaries, the texture
evolves with a small deflection, thereby affecting the strength
and elongation of the alloy. The anisotropy of the alloy also
changes.
Kaiser et al. [16] proposed that the distribution of the (0002)
basal plane has a significant influence on the planar anisotropy
of the sheet. As mentioned by Chen et al. [17], the texture
exhibits greater spreading of the basal poles toward the RD than
the TD, whereby activation of the basal slip in the sheet rolling
direction is preferred to the TD. This would result in lower
stresses necessary for the 90 °C orientation, hence decreasing
the yield strength. Lee et al. [18] calculated the Lankford
parameter of the rolled RD, TD and ND directions. The results
revealed that the r-values of the RD plane are much greater than
those of the TD and ND planes. Therefore, the strength in RD is
larger than that in TD. With the changing of rolling directions,
the basal pole in (0002) basal plane starts deflecting, no longer
toward RD. As for sheet 3, the basal peak distributes from the
c-axis toward the intermediate between RD and TD. Meanwhile,
the maximum of the pole density decreases in the inverse
pole figures, thus weakening the anisotropy of the alloy.