Solution treatment (precipitation hardening)
e_gulfam
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Jun 02, 2015
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About This Presentation
Solution treatment (precipitation hardening)
Slide Content
Precipitation Hardening
Solution Treatment
Age-Hardening
Age-Hardening
Age-Hardening
A quenched alloy increase its hardness with aging time
this is known as Age-Hardening (Precipitation
hardening)
Steps for age- hardening
The aging treatment accomplished by nucleation &
growth process.
Growth
First we nucleate cementite crystals & cementite
crystals grow in size due to the diffusion of carbon
from surrounding ferrite.
A quenched alloy increase its hardness with aging time
this is known as Age-Hardening (Precipitation
hardening)
Steps for age- hardening
The aging treatment accomplished by nucleation &
growth process.
Growth
First we nucleate cementite crystals & cementite
crystals grow in size due to the diffusion of carbon
from surrounding ferrite.
Continue…..
Removal of carbon from ferrite done in two ways;
1.The formation of new nuclei
2.Growth of previously formed nuclei
Incubation Period
Precipitation not begin immediately it require a (t
o
) before it
detectable.
Here we use Logarithmic units for time because
spontaneous reaction of this nature start rapidly & finish
slowly.
Removal of carbon from ferrite done in two ways;
1.The formation of new nuclei
2.Growth of previously formed nuclei
Incubation Period
Precipitation not begin immediately it require a (t
o
) before it
detectable.
Here we use Logarithmic units for time because
spontaneous reaction of this nature start rapidly & finish
slowly.
The speed at which precipitation occurs varies
with temperature this is shown qualitatively in
fig. At very low temperatures, long times are
required to complete the precipitation because
the diffusion rate is very slow. Here the rate of
reaction is controlled by the rate at which atoms
can migrate.
The rate of precipitation is also very slow at
temperatures just below the solvus line(point e
fig).
with temperature this is shown qualitatively in
fig. At very low temperatures, long times are
required to complete the precipitation because
the diffusion rate is very slow. Here the rate of
reaction is controlled by the rate at which atoms
can migrate.
The rate of precipitation is also very slow at
temperatures just below the solvus line(point e
fig).
Effect of free energy
In this cause the solution is only slightly over
saturated and the free-energy decrease resulting
from precipitation is very small. Nucleation is,
accordingly, slow, and precipitation is controlled
by the rate at which nuclei can form.
Conclusion
The combination of moderates diffusions and
nucleation rate makes precipitation rapid.
In this cause the solution is only slightly over
saturated and the free-energy decrease resulting
from precipitation is very small. Nucleation is,
accordingly, slow, and precipitation is controlled
by the rate at which nuclei can form.
Conclusion
The combination of moderates diffusions and
nucleation rate makes precipitation rapid.
Precipitation of second phase
The most important effect of the precipitation of the
second phase (cementite) is that the matrix (ferrite) is
hardened.
Figure shows a typical hardening curve for a dilute
iron-carbon alloy.
Over aging
Holding, the specimen for too long a period at a given
temperatures causes them to lose their hardness. This
effect is known as over aging.
The most important effect of the precipitation of the
second phase (cementite) is that the matrix (ferrite) is
hardened.
Figure shows a typical hardening curve for a dilute
iron-carbon alloy.
Over aging
Holding, the specimen for too long a period at a given
temperatures causes them to lose their hardness. This
effect is known as over aging.
Effect of different temperatures
The curve mark T
1
represents aging at too low a
temperature. In this cause, atomic motion is so slow
that no appreciable precipitation occurs and
hardening occurs slowly.
A further lowering of the aging temperature below T
1
will effectively stop all precipitation and prevent
hardening.
The curve mark T
1
represents aging at too low a
temperature. In this cause, atomic motion is so slow
that no appreciable precipitation occurs and
hardening occurs slowly.
A further lowering of the aging temperature below T
1
will effectively stop all precipitation and prevent
hardening.
Continue…
Temperature T2 corresponds to an optimum
temperature, a temperature at which maximum
hardening occurs within a reasonable length of time.
At T3 hardening occurs quickly due to rapid diffusion.
However, softening effects also are accelerated,
resulting in a lower maximum hardness.
Temperature T2 corresponds to an optimum
temperature, a temperature at which maximum
hardening occurs within a reasonable length of time.
At T3 hardening occurs quickly due to rapid diffusion.
However, softening effects also are accelerated,
resulting in a lower maximum hardness.
T
2
( 40.5
o
C)
T
1
( 0
o
C )
T
3
( 99
o
C)
2
( 40.5
o
C)
T
1
( 0
o
C )
T
3
( 99
o
C)
Effect of composition
Solubility at room temperature = 8.2 x 10
– 12
percent
– 12
percent
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