Although in the past it was common practice to fully anneal the rod before wire drawing, continuous processing is now usually practiced, that is the as-worked rod with retained substructure goes directly to the cold forming. Drawing of the rod through 12 dies with 20% reduction per die brings the total true strain to 6.89.
Strain Hardening from Cold Drawing
Although in the past it was common practice to fully anneal the rod before wire drawing,
continuous processing is now usually practiced, that is the as-worked rod with retained
substructure goes directly to the cold forming. Drawing of the rod through 12 dies with
20% reduction per die brings the total true strain to 6.89. Such additional strain of 2.56,
about, 60% of the hot rolling, requires only 60% of the dislocation motion, but brings
about much more dislocation storage and a higher rate of strain hardening because of
comparatively little dynamic recovery at ambient temperature. The strain hardening in wire
drawing of EC Al and some dilute alloys was linear when there was a retained hot worked
substructure, but became zero or negative when the rod had recrystallized grains or coarse
particle distributions. The softening is likely the result of dynamic recovery, not
recrystallization, since no new grains were observed.
The cold worked cell structure is built on the existing hot worked structure without tearing
it apart. Dislocations become entangled in the existing sub-boundaries, thus making them more
ragged and reducing the links of the wall networks, and also form new walls partitioning
the subgrains and decreasing the cell size to 0.5-0.8µm. This behavior is similar to that
found upon reloading of a cold worked specimen after cell growth in static recovery; the flow
curve is lower than the initial cold work curve of recrystallized material because dislocations
are accumulating on the recovered substructure in a different way from on the purely cold worked.
The hot worked structure in Al-0.65 Fe is much more stable and less disturbed by the cold
working than EC wire or commercial aluminum because of the stabilizing effect of the 0.2µm
The cold working decreases the conductivity of the wire relative to the hot rolled rod because
of the greatly increased dislocation density.
Primary particles of FeAl3
greater than 0.6µm diameter, are not sharable, i.e. dislocations
cannot pass through them. As they do not change shape, the surrounding matrix flows around
them undergoing additional complex deformation. This results in creation of cells much smaller
than the average size with dense, high misorientation walls. The needle-like, eutectic particles
, or Fe2
0.2µm diameter are also not shearable by individual dislocations. The metal flows relatively
easily around these thin rods, so that they give rise to merely additional dislocations. However,
dislocations accumulating along their length exert bending stresses that fracture them into segments
only a little longer than their diameter.
Solid Solution Hardening and Stabilization
The potential solution hardening by Fe is high because of the large atomic size difference
of 5.9%; however, the actual hardening depends on the amount dissolved. In a 0.5% Fe alloy,
the strength after quenching from 640°C to retain 0.05%Fe in solution and severely deforming
is about 190 MPa compared to 170 MPa for furnace cooling for precipitation. A 0.05% Fe alloy
similarly treated has strengths of 170 and 110 MPa respectively. These strengths increase
slightly upon low temperature aging as solute segregates to the dislocations but decline to
about 40 MPa at 310°C as precipitation and recrystallization take place. However, precipitation
during hot rolling returns the concentration to equilibrium which at the finishing temperature
is at such a low level that it provides very little hardening, even though the Fe atoms form weak.
Strength and Stability from Grain Size and Shape
In the course of rolling and wire drawing, the grains become fibrous, lengthening by a factor of
100 in the direction of the wire axis and decreasing in diameter by a factor of 10 in the plane
normal to it; the rows of eutectic particles are reduced in spacing to about 2 µm. The longitudinal
strength is raised because the area for glide of mobile dislocations in slip planes diagonal to
the axis is much restricted.
Resistance to Softening of a Hot Worked Substructure Strengthening from cold working has very
low stability at elevated temperatures because the high density, high energy substructure readily
gives rise to recrystallization unless some additional factor blocks it and provides an opportunity
for recovery to gradually lower the strain energy and improve the stability. On the other hand,
since Al is highly capable of recovery, limiting its degree is important in maintaining strength.
In the first stable of recovery, tangles diminish in density and rearrange into neat sub-boundaries
redundant dislocations annihilate with retention of the substructure scale and much of the strength.
The polygonization in this stage is initially speeded up by the internal stresses in cell walls and
interiors. In the second stage, the strength declines severely as subgrains become non-uniformly
larger through walls either disintegrating as their dislocations leave to incorporate into others,
or migrating to amalgamate with others.
Fine Dispersion Stabilization
The fractured FeAl3
eutectic rods of about 0.2 µm diameter fairly uniformly distributed play an
important role in stabilizing the substructure. The 109
density of 0.075-0.5 µm particles is
the same as the number of 1 µm cells per mm3
, so that there is about one particle per cell;
whereas for EC there is only one for every two cells.
In Al-10% Fe atomized-powder extrusion-compacted alloy, the dendritic FeAl3 uniformly distributed
in particles of 0.3-0.03µm, stabilizes the hot worked substructure and impedes recrystallization
for up to 1000 hrs at 320°C. In combination with recovery annealing, θ particles in Al-Cu alloys
stabilize the substructure up to 400°C. Dilute dispersion alloys show good stability to work
softening but coarse dispersions (0.7 Fe. 2-6 Ni) do not. Rapid non-uniform subgrain growth was
observed in EC Al during annealing.
Large particles 0.6µm in diameter have a destabilizing influence in so far as they serve as
centers of nucleation because they have created around themselves local regions of fine
subgrains with very high misorientations.
Such large particles 0.6-2.5µm widely spaced have been observed to accelerate recrystllization
in Al-Fe alloys, as well as in several other alloy systems.
Al-Mn and Al-Mg-Si alloys with large particles of 1µm, from chill casting and in the former
stabilization arose from 0.04µm precipitates of MnAl6 not from Mn in solution. This behavior
as confirmed for Al-Mn alloys with additional fine precipitates of either ZrAl3 or MnAl6.
Similar inhibition was found in a commercial RR58 and special alloys here the large
particles were Fe-Ni intermetallics and the fine, 0.2µm spheres of MgCuSi.