TECHNICAL FIELD
[0001] The present invention relates to a method for casting a Ti-Al based alloy that can
accurately controls a concentration of Al.
BACKGROUND ART
[0002] An induction melting furnace (CCIM: cold crucible induction melting apparatus) using
a water-cooled copper crucible is suitable for melting of a Ti-Al based alloy having
a high melting point because impurities are hardly mixed into molten metal from a
melting atmosphere and a crucible.
[0003] In the induction melting furnace, a raw material can be melted in the furnace regardless
of the shape as long as the raw material is smaller than a crucible size, so that
a material such as scrap can be effectively used as the raw material.
[0004] Furthermore, since electromagnetic induction that causes heating in the induction
melting furnace also generates electromagnetic repulsive force that stirs the molten
metal, it is also possible to maintain component homogeneity in the molten metal by
stirring by the electromagnetic repulsive force.
[0005] Therefore, casting of a Ti-Al based alloy using an induction melting furnace is an
effective method for obtaining a high-quality ingot at a high yield for an ingot of
a Ti-Al based alloy which is required to have a high yield due to an expensive raw
material cost.
[0006] In general, since a metal has a higher density in a solid state than in a liquid
state, a volume of a cast body is reduced during solidification. That is, when shrinkage
occurs during solidification, a cavity called a shrinkage cavity is generated as a
defect during casting in a portion where a cooling rate is relatively low and solidification
is delayed. Such a shrinkage cavity is likely to occur particularly in an axial center
portion of an ingot when a small diameter ingot is produced. Therefore, in a case
where a metal melted in an induction melting furnace is cast as a small diameter ingot,
a technique such as the following Patent Literature 1 has been developed in order
to prevent a shrinkage cavity at the time of casting.
[0007] Patent Literature 1 discloses a method for casting an active metal by tapping a molten
metal from a tapping hole provided in a bottom portion of a water-cooled copper crucible
of an induction melting furnace using the crucible, and casting an ingot of an active
metal, in which the ingot has a diameter of 10 mm or more, a ratio (H/D) of a height
H of the ingot to a diameter D of the ingot is 1.5 or more, and when casting is performed
under casting conditions in which a weight of the molten metal tapped in the casting
is 200 kg or less, the casting is performed while setting a temperature of the molten
metal during the casting to a temperature higher than a melting point of the active
metal and adjusting an opening diameter of the tapping hole to control a casting speed
V (mm/sec), which is a speed at which casting proceeds in the mold, to V ≤ 0.1H in
relation to the height H of the ingot.
[0008] In the technique in Patent Literature 1, it is possible to perform casting close
to unidirectional solidification by adjusting the casting speed, and it is possible
to realize a yield of up to 86% by preventing the generation of a shrinkage cavity
in an active metal such as a Ti-Al based alloy.
CITATION LIST
PATENT LITERATURE
SUMMARY OF INVENTION
TECHNICAL PROBLEM
[0010] Incidentally, the technique in Patent Literature 1 focuses on the casting speed as
a factor that can be controlled in actual operation, and discloses a very effective
method for obtaining a high yield.
[0011] However, in addition to defects in the shape such as a shrinkage cavity, there are
also defects in a composition such as a concentration of Al outside a standard range
in a criteria for determining the quality of a product in actual manufacturing.
[0012] In this regard, in Patent Literature 1, although the yield is evaluated based on
a ratio of the shrinkage cavity in a cast piece, how the concentration of Al in the
cast piece changes due to the influence of segregation of Al or the like, in other
words, a defect in the composition such as a concentration of Al is not considered
at all, and the dissolution condition under which the concentration of Al can be controlled
is not found at all.
[0013] That is, the quality of a cast product of a Ti-Al based alloy is required to improve
the comprehensive required quality in consideration of not only the shape but also
the defect in the composition, and it is important to control the concentration of
Al with high accuracy.
[0014] The present invention has been made in view of the above problems, and an object
of the present invention is to provide a method for casting a Ti-Al based alloy in
which a concentration of Al is controlled with high accuracy, and the comprehensive
quality in consideration of not only the shape but also the defect in the composition
can be greatly improved.
SOLUTION TO PROBLEM
[0015] In order to solve the above problems, a method for casting a Ti-Al based alloy according
to the present invention takes the following technical means.
[0016] That is, the method for casting a Ti-Al based alloy according to the present invention
is a method for casting a Ti-Al based alloy including: tapping molten metal from a
tapping hole provided in a bottom portion of a water-cooled copper crucible in an
induction melting furnace using the crucible; and casting an ingot of Ti-Al based
alloy, in which a degree of vacuum in the induction melting furnace at the time of
melting or casting the Ti-Al based alloy is set within a range of 80 Torr to 700 Torr,
and a concentration of Al of the cast ingot is set within ±1.0 mass% of a target value.
ADVANTAGEOUS EFFECTS OF INVENTION
[0017] According to the method for casting a Ti-Al based alloy of the present invention,
it is possible to accurately control the concentration of Al of the cast product,
and it is possible to greatly improve the comprehensive quality in consideration of
not only a defect in the shape of the cast product but also a defect in the composition.
BRIEF DESCRIPTION OF DRAWINGS
[0018]
[FIG. 1] FIG. 1 is a schematic diagram showing a casting apparatus used in a method
for casting a Ti-Al based alloy according to the present embodiment.
[FIG. 2] FIG. 2 is a graph showing a relationship between a degree of vacuum in a
furnace and an evaporation rate of Al from a molten metal.
[FIG. 3] FIG. 3 is a graph showing a relationship between the degree of vacuum in
the furnace and the number of gas defects.
DESCRIPTION OF EMBODIMENTS
[0019] Hereinafter, embodiments of a method for casting a Ti-Al based alloy according to
the present invention will be described in detail with reference to the drawings.
[0020] In the method for casting a Ti-Al based alloy according to the present embodiment,
a molten metal M in which a titanium-aluminum based alloy (Ti-Al-based alloy) having
an active high melting point is melted is poured into a mold 4 to perform casting,
thereby producing a small diameter ingot S (ingot). As the Ti-Al based alloy, various
alloys can be considered, and alloys such as a Ti-3Al-2.5V alloy, a Ti-6Al-6V-2Sn-0.5Fe-0.5Cu
alloy, a Ti-3Al-10V-2Fe alloy, a Ti-5Al-5V-5Mo-3Cr-0.5Fe alloy, a Ti-3Al-8V-6Cr-4Mo-4Zr
alloy, a Ti-3Al-15V-3Cr-3Sn alloy, a Ti-6Al-4V alloy, a Ti-3Al-15Mo-2.7Nb-0.2Si alloy,
a Ti-5Al-2Sn-2Zr-4Mo-4Cr alloy, a Ti-6Al-2Sn-4Zr-6Mo alloy, a Ti-6Al-2Sn-4Zr-2Mo alloy,
a Ti-6Al-5Zr-0.5Mo-0.25Si alloy, a Ti-5.5Al-3.5Sn-3Zr-1Nb-0.25Mo-0.3Si alloy, and
a Ti-5.8Al-4Sn-3.5Zr-0.7Nb-0.5Mo-0.35Si-0.06C alloy are used as alloys used in aircraft
parts.
[0021] Hereinafter, a casting apparatus 1 used in the method for casting a Ti-Al based alloy
according to the present embodiment will be described.
[0022] As shown in FIG. 1, the casting apparatus 1 used in the casting method of the present
embodiment includes an induction melting furnace 3 using a water-cooled copper crucible
2, and a mold 4 into which the molten metal M tapped from a bottom portion of the
crucible 2 is injected. The casting apparatus 1 is used for casting the small diameter
ingot S of a Ti-Al based alloy by tapping the molten metal M from the bottom portion
of the crucible 2 into the mold 4. The induction melting furnace 3, the crucible 2,
and the mold 4 disposed below the induction melting furnace 3 and the crucible 2 are
housed in a single container (vacuum container), and the small diameter ingot S of
a Ti-Al based alloy can be cast while a degree of vacuum in the vacuum container is
set to a predetermined degree.
[0023] According to the present invention, gas defects caused by gas involvement or the
like inside the ingot can be reduced by controlling the degree of vacuum (atmospheric
pressure) in the melting and casting chamber to a predetermined value, and the yield
of the cast product can be improved by keeping a concentration of Al of a cast product
within a standard range.
[0024] The induction melting furnace 3 used in the casting apparatus 1 of the present embodiment
generates an induced current inside a material to be melted to utilize resistive-heating
thereof, and is generally called a cold crucible induction melting apparatus. The
induction melting furnace 3 melts a Ti-Al based alloy by using the water-cooled copper
crucible 2, and is formed of copper without using a refractory that is often used
as a material for the crucible 2 in a general melting furnace. Therefore, the casting
using the induction melting furnace 3 is less likely to be affected by contamination
from the refractory.
[0025] As shown in FIG. 1, the crucible 2 used in the induction melting furnace 3 is formed
in a bottomed cylindrical shape opened upward, and can accommodate the melted Ti-Al
based alloy therein.
[0026] A wall of the crucible 2 is formed of copper as described above and water-cooled.
When the wall of the crucible 2 is formed of such water-cooled copper, the temperature
of an inner wall of the crucible 2 does not rise to a predetermined temperature (for
example, 250°C) or higher even when the melted Ti-Al based alloy is accommodated in
the crucible 2. Specifically, a solidified shell called a scull is formed between
an inner peripheral surface of the wall of the crucible 2 and the molten metal when
the melted Ti-Al based alloy described above is put into the water-cooled copper crucible
2. Since the scull serves as a crucible, the molten metal is not contaminated from
the crucible 2.
[0027] The crucible 2 of the present embodiment is a bottom tapping type, and a tapping
hole 5 that can guide the accommodated Ti-Al based alloy downward is formed in the
bottom portion of the crucible 2. An opening diameter of the tapping hole 5 can be
adjusted, and the amount of the molten metal M guided downward can be adjusted. The
opening diameter of the tapping hole 5 may be adjustable by an electromagnetic method
or a mechanical method, or a plurality of valve members having different opening diameters
may be prepared in advance, and the opening diameter of the tapping hole 5 may be
adjusted by replacing the valve members.
[0028] The mold 4 is formed in a bottomed cylindrical shape opened upward.
[0029] Various inner dimensions of the mold 4 can be considered. Assuming that the diameter
of the ingot S is D, the height of the ingot S is H, and the weight of the molten
metal M is W, it is preferable that the inner dimension of the mold 4 is set to a
size that falls within the following application range.
Diameter D (mm) of ingot: 10 ≤ D ≤ 150
Height H (mm) of ingot: 15 ≤ H ≤ 1600
Molten metal weight W (kg): 0.2 ≤ W ≤ 200
[0030] Next, a procedure for casting an active metal using the induction melting furnace
3 described above, in other words, a method for casting a Ti-Al based alloy will be
described.
[0031] In the method for casting a Ti-Al based alloy according to the present embodiment,
in the induction melting furnace 3 using the water-cooled copper crucible 2, the molten
metal M is tapped from the bottom portion of the crucible 2 to the mold 4 to cast
the small diameter ingot S of an active metal. At this time, casting is performed
under the casting conditions in which the diameter of the small diameter ingot S to
be cast is 10 mm or more, the ratio H/D of the height (H) of the ingot S to the diameter
(D) of the ingot S is 1.5 or more, and the weight of the molten metal M tapped by
casting is 200 kg or less. In addition, when casting is performed, the tapping hole
5 whose opening diameter can be adjusted is provided in the bottom portion of the
crucible 2, the temperature of the molten metal M during casting is made higher than
the melting point of the active metal, and the opening diameter of the tapping hole
5 is adjusted, whereby casting is performed while controlling a casting speed V (kg
/ sec), which is a speed at which casting proceeds in the mold 4, to V ≤ 0.1H in relation
to the height H of the ingot S, thereby reducing the number of shrinkage cavities
inside the ingot S and improving the casting yield. In order to prevent "molten metal
clogging" in which the molten metal tapped during casting is clogged and the molten
metal does not flow, the temperature of the molten metal M during casting is preferably
20°C or more higher than the melting point of the active metal, and more preferably
40°C or more higher than the melting point of the active metal.
[0032] Incidentally, even when the ingot S of a Ti-Al based alloy is cast at the casting
speed V (kg/sec) described above, the concentration of Al is gradually decreased during
casting since Al evaporates from the molten metal when the inside of the furnace is
in a vacuum state, and finally, there is a possibility that the concentration of Al
in a composition of the cast product falls below the standard value of the target
concentration of Al. Therefore, in the method for casting a Ti-Al based alloy according
to the present embodiment, the degree of vacuum in the induction melting furnace 3
at the time of melting or casting the Ti-Al based alloy is set to be in the range
of 80 Torr to 700 Torr and the concentration of Al of the cast product (ingot) is
set to be within ±1.0 mass% of a target value when the molten metal M is tapped into
the mold 4 from the tapping hole 5 provided in the bottom portion of the water-cooled
copper crucible 2 of the induction melting furnace 3 to cast the cast product (ingot)
of a Ti-Al based alloy.
[0033] Strictly speaking, the concentration of Al described above differs between a state
of being cast into a cast product (solid state) and a state of a molten metal (liquid
state). However, in the present embodiment, the concentration of Al is set to be within
±1.0 mass% in both cases of solid and liquid.
[0034] The reason why the degree of vacuum in the induction melting furnace 3 described
above is defined within the range of 80 Torr to 700 Torr is as follows.
[0035] That is, in the present embodiment, the weight of the molten metal used for casting
is 50 kg. A casting time of 15 minutes is required until all of the molten metal is
cast as the ingot S. It is needless to say that the casting time varies depending
on a diameter of a nozzle. Even during the casting time of 15 minutes, the concentration
of Al of the molten metal is gradually decreased due to evaporation. However, when
an amount of decrease in the concentration of Al lost by evaporation is within an
allowable variation range of the standard value of the concentration of Al, the cast
product (ingot) after casting has an appropriate composition as a Ti-Al based alloy.
[0036] The standard value (target value) of the concentration of Al of the Ti-Al based alloy
may be high or low depending on the alloy type of the cast product to be cast. However,
the applicant has confirmed that an appropriate composition can be obtained as a Ti-Al
based alloy when the concentration of Al is kept within ±1.0 mass% of the standard
value of 23.3 mass% to 43.3 mass%. For example, even when the standard value of the
concentration of Al of 30 mass% is targeted, the variation range of the concentration
of Al allowable for the actual cast product with respect to the standard value is
within ± 1.0 mass%.
[0037] Here, in the casting method of the present embodiment, first, a difference between
an upper limit and a lower limit of the allowable variation range with respect to
the standard value, in other words, the variation range of the concentration of Al
is obtained. The variation range of 2.0 mass% thus obtained is divided by the casting
time of 15 minutes. It is nothing but determining a rate of change in the concentration
of Al such that the amount of decrease does not exceed the variation range of the
concentration of Al even when the concentration of Al is decreased in the casting
time of 15 minutes. The rate of change in the concentration of Al as a result of the
calculation described above is calculated to be: 2.0 mass% ÷ 15 min = 0.13 mass%/min
or less.
[0038] After the 0.13 mass%/min described above is calculated, the degree of vacuum at which
the rate of change in the concentration of Al is 0.13 mass%/min or less may be obtained
by actually performing an experiment. The degree of vacuum of the casting obtained
by the experiment in this manner is 80 Torr to 700 Torr described above. The experiment
for determining the range of the degree of vacuum will be described in detail in Examples
described later.
[0039] When casting is performed under the condition in which the degree of vacuum (pressure
in a vacuum container) described above is less than 80 Torr, a large amount of Al
in the molten metal evaporates during casting, and thus the composition of the molten
metal greatly fluctuates during casting, and the fluctuation in the composition of
the cast product cannot be ignored. As a result, the composition (concentration of
Al) of the cast product deviates from the standard value, and a cast product having
poor composition is likely to be generated, which leads to a decrease in yield.
[0040] In addition, when the casting is performed under the condition in which the degree
of vacuum (pressure in the vacuum container) exceeds 700 Torr, the Ti-Al based alloy
is cast in an environment in which a large amount of gas is present. Thus, there is
a high possibility that the gas existing in the surroundings is involved when the
molten metal is solidified in the mold, the gas defects are increased, and the yield
is decreased.
[0041] The gas defects are generated due to the involving of the gas existing in the surrounding
when the molten metal is solidified in the mold 4, and are often formed on a surface
layer of the mold. Therefore, when the degree of vacuum in the furnace at the time
of melting and casting is fine, the amount of gas to be involved is also reduced.
That is, the gas defects can be reduced by improving the degree of vacuum in the furnace.
When the gas defects are reduced, the amount of cutting the cast product in order
to remove the gas defects from the cast product is also reduced, so that the yield
of the cast product can be improved.
[0042] Although there is no quantitative evaluation result of the number of gas defects
in the case of casting at atmospheric pressure, there is a qualitative discussion
that the number of gas defects tends to be decreased as the casting environment for
casting is changed from atmospheric pressure to vacuum. Therefore, by setting the
degree of vacuum at the time of melting or casting to a higher degree of vacuum than
700 Torr described above (lower pressure than 700 Torr), it can be considered that
the number of gas defects can be significantly reduced as compared with the case where
the degree of vacuum is 760 Torr (atmospheric pressure) or more.
[0043] As described above, by performing casting with the degree of vacuum (air pressure
in the vacuum container) set to 80 Torr to 700 Torr, it is possible to appropriately
control the composition (concentration of Al) of the cast product to a standard value
while preventing the generation of the gas defects, and it is possible to greatly
improve the comprehensive quality in consideration of the defect in the composition.
Example
[0044] In Examples, a maximum of 50 kg of a Ti-Al based alloy material (Ti-33.3Al-4.8Nb-2.55Cr
(mass%)) was melted, and a molten metal obtained by melting was used for casting.
[0045] Specifically, the materials described above were heated using the water-cooled copper
crucible 2 in the cold crucible induction melting furnace 3 shown in FIG. 1, a molten
metal melted by heating was held in the furnace in which a degree of vacuum was changed
in a range of 0.001 Torr to 700 Torr, a concentration of Al of the molten metal was
measured, and a relationship between the degree of vacuum in the furnace and an evaporation
rate of Al was investigated. The results are shown in FIG. 2.
[0046] As shown in FIG. 2, it can be seen that there is a relationship between the degree
of vacuum in the furnace and the evaporation rate of Al that the higher the degree
of vacuum in the furnace is, the lower the evaporation rate of Al is. Further, based
on the obtained data, the evaporation rate of Al was 0.13 mass%/min or less even when
the degree of vacuum in the furnace was 0.001 Torr, but in order to safely and reliably
perform casting, the case of 80 Torr was considered to be the lower limit value of
the degree of vacuum at which the evaporation rate of Al was 0.13 mass%/min or less,
and the control range of the degree of vacuum was set to 80 Torr or more.
[0047] After the relationship between the degree of vacuum in the furnace and the evaporation
rate of Al was obtained in advance by the procedure described above, a cast product
(ingot) was cast by actually tapping into the cast mold 4.
[0048] Note that casting was performed by tapping the molten metal from a graphite nozzle
(tapping hole 5) installed at a bottom portion of the crucible 2 in which the molten
metal was sealed, and solidifying the molten metal with the graphite mold 4 located
below the crucible 2. The casting was also performed under an Ar atmosphere with reduced
pressure, in other words, under an Ar atmosphere in which the degree of vacuum was
controlled in the range of 0.001 Torr to 700 Torr. The cast product (ingot) to be
produced can be changed in accordance with the shape of the graphite mold 4. In the
present embodiment, an ingot was produced by casting with two types of the graphite
mold 4 having a rectangular nozzle opening shape and the graphite mold 4 having a
circular nozzle opening shape. Specifically, there are two types of nozzle opening
shapes, 65 mm x 65 mm and 55 mm x 55 mm for a rectangular shape, and ϕ72 mm and ϕ50
mm for a circular shape. A cylindrical ingot is obtained when the nozzle opening shape
is circular, and a prismatic ingot is obtained when the nozzle opening shape is rectangular.
[0049] A height of the ingot is between 620 mm and 1520 mm, and a casting speed of the ingot
is in a range of 0.18%/s to 0.4%/s, although they depend on experiments.
[0050] With respect to the obtained ingot product, the applicant has confirmed that the
evaporation rate of Al is suppressed in the range of the degree of vacuum of the present
embodiment, and an ingot in which the concentration of Al is controlled to be in the
range of ± 1.0 mass% of a target value is obtained. When a Ti-Al alloy having a target
value of concentration of Al of 33.3 mass% was cast at 80 Torr by the method of the
present invention, the concentration of Al was within ± 1 mass% of the target value
of 33.3 mass% and was 32.79 mass%.
[0051] Among the obtained ingots, the number of gas defects per unit height of the ingot
was measured for the cast product cast at a degree of vacuum of 200 Torr, and was
30/mm or less. This shows a result that the number of gas defects is significantly
reduced compared with the number of gas defects being on order of several hundred
in the case of casting under atmospheric pressure, and that the generation of gas
defects is prevented.
[0052] As shown in the above results, the concentration of Al can be controlled with high
accuracy by setting the degree of vacuum in the induction melting furnace 3 at the
time of melting or casting the Ti-Al based alloy within the range of 80 Torr to 700
Torr when the molten metal is tapped from the tapping hole 5 provided in the bottom
portion of the water-cooled copper crucible 2 of the induction melting furnace 3 to
the mold 4 to cast the ingot of the Ti-Al based alloy, and by setting the concentration
of Al of the cast ingot within ±1.0 mass% of the target value, and the comprehensive
quality of the cast product can be greatly improved considering not only the defect
of the shape but also the defect of the composition.
[0053] It should be understood that the embodiments disclosed herein are illustrative and
non-restrictive in all respects. In particular, items that are not explicitly disclosed
in the embodiments disclosed herein, such as operating conditions, operational conditions,
various parameters, and dimensions, weights, volumes, and the like of components do
not depart from the scope of normal implementation by those skilled in the art, and
values that can be easily assumed by those skilled in the art are adopted.
REFERENCE SIGNS LIST
[0055]
1 Casting apparatus
2 Crucible
3 Induction melting furnace
4 Mold
5 Tapping hole
M Molten metal
S Cast Product (ingot)