Article Type : Research Article
Authors : Run Xu, Lim S, Reddy NS, Nam T, Ahn HJ and Kim K
Keywords : Modelling; TiAl; Dentrite; The secondary arm space; analysis; Temperature; Cooling rate; Composition difference; Gibbs free energy
The simulation of cooling rate and
temperature & solidified speed has been established for the sake of
searching their intrintic relationship. It is observed that the temperature
will become low with speed to be increased firstly. It fits to the principle
well. The cooling rate increases with the solidified speed becomes bigger
secondly. At last in dentrite the cooling rate of solidification has been high
with decreasing temperature. That fits to principle well according to the
tendency of three parameters in this paper. For further research the deeper
relationship need to be studied further as this paper’s destination. In
addition the cooling rate will increase from 2K/s to 58K/s when the secondary
arm space changes from 10?m to 250?m in dentrite of TiAl.
The change of temperature
in the solid and liquid in solidification transformation can deduce their
related formula. The curve expresses its trend better. From this relation their
secondary dendrite arm space composition will change when the transformation
happens. It is known that the temperature in solidification can solve their
relationship. In this study in terms of these equations the deduction and
analysis is done and the error analysis to them is done. Here the solid and
liquid equation is explored within line and find the simple formula which make
us to calculate the cooling rate rapidly [1,2]. Therefore in this study the
model of temperature and composition has been established to observe the trend
and intrinsic relationship between them. Then the error is checked with
variance to both of constant. TiAl as a promise materials has been searched and
developed for many years. However the cooling rate with compositions is not
much yet, so in this study the equation is established through temperature and composition
according to the phase diagram. It is modelled with cooling rate and
composition difference too in directional solidification test. The detail value
is combined through phase equilibrium line and it is compared with thermal
dynamics. The research scope is from 0 to pure Al here [3]. On the other side
the relationship with cooling rate and energy difference & temperature has
been investigated according to varied speed respectively for the application.
According to the solidified crystalline and phase diagram the application will
be known. In addition relationship between cooling rate and energy difference
& temperature are drawn for further research in this study. To calculate
the cooling rate is our destination in the end in terms of the composition in
TiAl alloys. Therefore the establishment equation between temperature and
cooing rate in terms of the equilibrium diagram [3-6].
Simulation
It is supposed that
Crate=Kv --- (1)
Here v is the solidified
speed, mm/s; K is coefficient; Crate is the cooling rate, K/s.
Since v=0.21 mm/s,
Crate=4.5K/s within Ls=210mm
Ls is the solidified
length.
Substitute them into (1)
it has been calculated
K=22 K/mm
So it has Crate=22v ---
(2)
It is supposed that
T=K1/v --- (3)
Substitute them above
into (3) it has
T=440/v -- (4)
Here K1 =440Kmm/s
Substitute Crate=22v into
(4) it has
T=9,680/Crate --- (5)
Since T=44,260/L
Here L is secondary arm
space in dentrite. Substitute it into (5)
It has Crate=219*L --- (6) (Figure 1).
In Figure 1 the curve between temperature and solidified speed has been expressed. It is observed that with speed increasing from 600mm/hr to 3,200mm/hr the temperature will decrease from 2,400K to 600K. The temperature will become low with speed to be increased. It fits to the principle well. As seen in Figure 2 the relationship between cooling rate and solidified speed is exhibited according to the equation above. When the solidified speed increases from 0 to 5,000mm the cooling rate will decrease from 0?/s to 30?/s in TiAl with solidification. The bigger solidified speed expresses that higher cooling rate. It fits to principle very well. So the whole cooling rate will change a certain with the parameter of speed changing. It expresses that the cooling rate increases with the solidified speed becomes bigger.
Figure 1: The relationship between temperature and speed in metal.
Figure 2: The relationship between cooling rate and dentrite secondary arm space in TiAl.
Figure 3: The relationship between cooling rate and temperature in TiAl.
Figure 4: The relationship between cooling rate and temperature in TiAl.
In Figure 3 the cooling
rate will increase from 2K/s to 58K/s when the secondary arm space changes from
10?m to 250?m in dentrite of TiAl. It explains that the bigger secondary arm
space will be if the cooling rate is bigger too. It fits to the principle well
too. As seen in Figure 4 when the solidified cooling rate decreases from 30K/s
to 3K/s the temperature will increase from 350K to 4,500K. So the maximum
cooling rate is 30K/s under 350K. In dentrite the cooling rate of
solidification has been high with decreasing temperature. In short only if the
temperature decreases the cooling rate will increase which fits to the theory
well. So for the sake of increasing the cooling rate the controlling
temperature is necessary (Figure 2,3).
When the solidified speed in dentrite is
from 600mm/hr to 3,200mm/hr the temperature changes from 2,400K to 500K. The
period one of cooling rate is from 0K/s to 30 K/s in increasing speed from 0 to
5,000mm/hr. When cooling rate increases from 30K/s to 3K/s the speed changes
from 400K to 4,400K in TiAl. Meantime the cooling rate increases with the
solidified speed becomes bigger.
This work was supported
by the Korea of Science and Engineering Fund, under the Specified Base program
(96-0300-11-01-03).