The present invention relates to a continuous casting apparatus of an ingot formed of titanium or a titanium alloy.
In continuous casting of an ingot, titanium or a titanium alloy melted by heating the melt surface by plasma arc melting (PAM) or electron beam melting (EB) is charged into a bottomless mold and pulled out downward while solidifying it.
Patent Document 1 discloses an automatically controlled plasma melting casting method. In the automatically controlled plasma melting casting method, titanium or a titanium alloy is melted by plasma arc in an inert gas atmosphere, charged into a mold, and solidified. Unlike electron beam melting that is performed in vacuum, the plasma arc melting method performed in an inert gas atmosphere described in Patent Document 1 can cast not only pure titanium but also a titanium alloy.
Patent Document 2 discloses an apparatus for melting and continuous casting a high-melting-point metal ingot by an electron beam method. In the melting and continuous casting apparatus descried in Patent Document 2, an ingot is pulled out while rotating its bottom, and among electron beams for irradiation, the melt surface is irradiated while making the density of electron beams incident along the peripheral part of a mold be higher than that in the central part of the mold.
Since the ingot formed of titanium or a titanium alloy is completed as a product through steps of rolling, forging, heat treatment, etc., an ingot having as a large diameter as φ800 to 1,200 mm is required for obtaining a product excellent in the mechanical properties such as fatigue strength.
Patent Document 1: Japanese Patent No. 3077387
Patent Document 2: JP-A-2009-172665
However, in the case of continuously casting a round ingot having a large diameter by a plasma arc melting method, a plasma torch has a limited heating range. Therefore, in order to melt titanium or a titanium alloy, the melt surface needs to be entirely heated by moving the torch.
Here, in an apparatus for continuously casting a round ingot of titanium (particularly, a titanium alloy) by a plasma arc melting method, significant component segregation is caused with an increase in the ingot diameter as described below. An irregularity or flaw generated on the surface of the obtained ingot due to significant component segregation works out to a surface defect in the subsequent rolling or forging step. Therefore, in the continuous casting of a large-diameter ingot formed of titanium or a titanium alloy, the component segregation must be reduced to establish an improvement of the casting surface.
The component segregation that becomes significant with an increase in the diameter of an ingot is described below. In order to make the diameter of a round ingot large, as the diameter of the round ingot is increased, the total amount of heat required to be input into the melt surface during continuous casting becomes larger.
On the other hand, in the case of performing gradient heating so as to input a large amount of heat in the vicinity of the edge of a round mold and input a small amount of heat near the central part, it is considered that not only the total amount of heat input into the melt surface is decreased and the depth at the center of the molten metal pool is reduced but also the growth of an initial solidified shell can be suppressed. However, in this case, the following problems arise.
In addition, in the case of continuously casting an ingot having as a large diameter as φ800 to 1,200 mm, if only one plasma torch is used for heating the melt surface as shown in
A problem to be solved by the present invention is to provide a continuous casting apparatus of an ingot formed of titanium or a titanium alloy, where an ingot having a good casting face is produced by reducing the component segregation and the life of a plasma torch can be extended by causing no interference of plasma torches with each other.
In order to solve the above problems, the continuous casting apparatus of an ingot formed of titanium or a titanium alloy in the present invention, which continuously casts the ingot formed of titanium or a titanium alloy, includes: a bottomless mold with a circular cross-sectional shape in which a molten metal prepared by melting titanium or a titanium alloy is poured from a top opening and the molten metal is solidified and the molten metal solidified is pulled out downward; and a plasma torch which is disposed on an upper side of the molten metal in the mold and generates a plasma arc that heats the molten metal, wherein a plurality of plasma torches are disposed on the upper side of the molten metal in the mold, and the plurality of plasma torches are moved in a horizontal direction above a melt surface of the molten metal along a trajectory keeping a distance not to allow for interference with each other.
According to this, a plurality of plasma torches are moved while keeping a distance not to allow for interference with each other, whereby the movement distance of each plasma torch can be shortened. As a result, an ingot having a good casting surface can be produced by suppressing the reduction in the ingot temperature and reducing the component segregation, and the life of the plasma torch can be extended by causing no interference of plasma torches with each other.
In the continuous casting apparatus of an ingot formed of titanium or a titanium alloy in the present invention, the number of the plasma torches may be 2, and the plasma torches are moved such that when one plasma torch is located on an upper side in the vicinity of an edge of the mold, the other plasma torch may be located near a central part of the mold.
According to this, two plasma torches are used, so that the movement distance of each plasma torch can be shortened and the reduction in the ingot temperature can be suppressed. In addition, each of two plasma torches is moved to be located either on the upper side in the vicinity of the edge of a mold or on the upper side near the central part of the mold, so that the entire melt surface can be heated while causing no interference of two plasma torches with each other. As a result, not only an ingot having a good casting surface can be produced by reducing the component segregation but also the life of the plasma torch can be extended.
In addition, assuming that a radius of the melt surface is R, the plasma torch may be moved to locate its center on a trajectory formed after an inner circumferential arc having a radius of 0<r1<R/2 from the center of the melt surface and an outer circumferential arc having a radius of R/2<r2<R from a center of the melt surface are connected by a straight line, and a plasma output of the plasma torch during movement in the inner circumferential arc may be controlled to be lower than a plasma output of the plasma torch during movement in the outer circumferential arc.
According to this, the centers of two plasma torches are moved to be located on a trajectory formed after an inner circumferential arc having a radius of 0<r1<R/2 from the center of the melt surface and an outer circumferential arc having a radius of R/2<r2<R from the center of the melt surface are connected by a straight line, so that the entire melt surface can be heated while causing no interference of two plasma torches with each other. As a result, the life of the plasma torch can be extended. In addition, the plasma output is set high during movement in the outer circumferential arc, and the plasma output is set low during movement in the inner circumferential arc, so that the heat input amount in the vicinity of the edge of a mold can be made large and the heat input amount near the central part of the mold can be made small. In turn, the growth of an initial solidified shell can be suppressed, and the total amount of heat input into the melt surface decreases as compared with the case of uniform heat input. Therefore, the depth of the molten metal pool becomes shallow, and the component segregation can be reduced. As a result, an ingot having a good casting surface can be produced.
In addition, each of the plasma torches may be moved within either one range of two divided semicircles as viewed from a front of the melt surface.
According to this, each plasma torch is moved within either one range of two divided semicircles as viewed from the front of the melt surface, so that trajectories allowing for no interference of two plasma torches with each other can be ensured.
In addition, the movement may be controlled to afford a distance of R/2 or more between centers of the plasma torches.
According to this, the movement is controlled to afford a distance of R/2 or more between centers of the plasma torches, so that a distance allowing for no interference of two plasma torches with each other can be ensured.
The continuous casting apparatus of an ingot formed of titanium or a titanium alloy in the present invention can produce an ingot having a good casting surface by reducing the component segregation and can extend the torch life.
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The embodiments for carrying out the continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to the present invention are described below in line with a specific example by referring to the drawings.
Those described below are merely illustrative and do not indicate application limitations of the continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to the present invention. That is, the continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to the present invention is not limited to the following embodiments, and various changes falling within the scope of claims can be made therein.
The continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention is a continuous casting apparatus where a molten metal obtained by plasma arc melting of titanium or a titanium alloy is poured into a bottomless mold and the molten metal is solidified and the molten metal solidified is pulled out downward, thereby continuously casting an ingot formed of titanium or a titanium alloy. The continuous casting apparatus 1 of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention (hereinafter, simply referred to as “continuous casting apparatus”) is described based on
As shown in
The raw material charging device 4 charges a raw material of titanium or a titanium alloy, such as sponge titanium and scrap, into the cold hearth 3. The plasma torch 5 is disposed on the upper side of the cold hearth 3 and generates a plasma arc to melt the raw material in the cold hearth 3. A molten metal 12 after the melting of raw material in the cold hearth 3 is poured by the cold hearth 3 at a predetermined flow rate into the mold 2 from a melt pouring part 3a.
The mold 2 is made of copper and is formed to be bottomless and have an opening at the top (top opening). In addition, the mold 2 is formed so as to have a circular cross-sectional shape having a diameter (φ) of 800 to 1,200 mm. Inside of at least a part of the cylindrical wall of the mold 2, a water-cooling mechanism (not shown) for cooling the mold with circulating water is provided so as to prevent damage by the high-temperature molten metal 12 poured.
The starting block 6 is moved up and down by a drive part (not shown) and can close the bottom-side opening of the mold 2. The molten metal 12 poured into the mold 2 starts to be solidified from its surface contacted with the mold 2 of a water cooling type. The starting block 6 closing the bottom-side opening part of the mold 2 is drawn downward at a predetermined speed, whereby an ingot 11 having a cylindrical shape resulting from solidification of the molten metal 12 is continuously cast while being pulled out downward.
Two plasma torches 7a and 7b are a torch generating a plasma arc and are provided on the upper side of the top-side opening of the mold 2, i.e., on the upper side of the molten metal 12 in the mold 2. The melt surface of the molten metal 12 poured into the mold 2 is irradiated with plasma arcs generated from two plasma torches 7a and 7b, whereby the molten metal 12 in the mold 2 is heated with plasma arcs. In addition, two plasma torches 7a and 7b are disposed movably in the horizontal direction.
Here, in the case of electron beam melting in a vacuum atmosphere, casting of a titanium alloy is difficult, because trace components evaporate, but in the case of plasma arc melting in an inert gas atmosphere, not only pure titanium but also a titanium alloy can be cast.
The continuous casting apparatus 1 may include a flux charging device for charging solid-phase or liquid-phase flux onto the melt surface of the molten metal 12 in the mold 2. Here, in the case of electron beam melting in a vacuum atmosphere, charging of flux into the molten metal 12 in the mold 2 is difficult, because the flux scatters. On the other hand, the plasma arc melting in an inert gas atmosphere is advantageous in that the flux can be charged into the molten metal 12 in the mold 2.
Next, the trajectories of movements of two plasma torches 7a and 7b in the continuous casting apparatus 1 according to an embodiment of the present invention are described based on
As shown in
Range of plasma torch 7a: the range of x<0 (left semicircle in
Range of plasma torch 7b: the range of x>0 (right semicircle in
When the radius of the molten metal 12 (i.e., ingot 11) is assumed to be R, the plasma torches 7a and 7b are controlled so that respective centers can trace the following trajectories during movement in the direction of A→B→C→D→E→F:
Inner circumferential arc having a radius of 0<r1<R/2: B→C→D for the plasma torch 7a, and D→E→F for the plasma torch 7b
Outer circumferential arc having a radius of R/2<r2<R: E→F→A for the plasma torch 7a, and A→B→C for the plasma torch 7b
Straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc: A→B and D→E for the plasma torch 7a, and C→D and F→A for the plasma torch 7b
That is, the plasma torch 7a is controlled so that its center can trace the following trajectories:
A→B: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
B→C→D: inner circumferential arc
D→E: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
E→F→A: outer circumferential arc
In addition, the plasma torch 7b is controlled so that its center can trace the following trajectories:
A→B→C: outer circumferential arc
C→D: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
D→E→F: inner circumferential arc
F→A: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
As shown in
As shown in
Next, the simulation results of component segregation that is caused when an ingot is continuously cast using the continuous casting apparatus 1 according to an embodiment of the present invention are discussed by referring to
In the simulation according to an embodiment of the present invention, the material of the ingot was Ti-6Al-4V, the size of the mold 2 (i.e., the radius R of the melt surface of the molten metal 12) was 600 mm, and the amount of the raw material melted was 1.3 ton/hour. In addition, as viewed from the front of the melt surface (i.e., from the top-side opening of the mold 2), the coordinates of trajectories of movements of two plasma torches 7a and 7b are as shown in
It is found from the graph showing the history of torch-to-torch distance in
In addition, as seen from
Furthermore, the results of a simulation of measuring the pool depth of the molten metal pool (i.e., the value of z coordinate relative to x coordinate when y=0) formed inside of the mold 2, which is performed for a case where while moving plasma torches 7a and 7b based on the trajectories shown in
Next, in comparison with the above-described continuous casting apparatus 1 according to an embodiment of the present invention, the simulation results of Comparative Example 1 where two plasma torches are moved on trajectories different from the trajectories shown in
In the simulation of Comparative Example 1, the conditions regarding the material of the ingot, the size of the mold 2, and the amount of the raw material melted are the same as in the above-described simulation according to an embodiment of the present invention, and only the trajectories of two plasma torches are changed. In addition, as viewed from the front of the melt surface (i.e., from the top-side opening of the mold 2), the coordinates of trajectories of movements of two plasma torches 7a and 7b are as shown in
Furthermore, in the case where each of the plasma torches 7a and 7b moves in the direction of A→B→C→D→E→F and the moving speed is 50 mm/sec, in Comparative Example 1, two plasma torches 7a and 7b move based on trajectories and positional relationship shown in
As shown in
Next, in comparison with the above-described continuous casting apparatus 1 according to an embodiment of the present invention, the simulation results of Comparative Example 2 where two plasma torches are moved on trajectories different from the trajectories shown in
In the simulation of Comparative Example 2, the conditions regarding the material of the ingot, the size of the mold 2, and the amount of the raw material melted were the same as in the above-described simulation according to an embodiment of the present invention, and only the trajectories and plasma outputs of two plasma torches were changed. In addition, as viewed from the front of the melt surface (i.e., from the top-side opening of the mold 2), the trajectories of movements of two plasma torches 7a and 7b are as shown in
The moving speed of each of the plasma torches 7a and 7b is 50 mm/sec. In addition, the plasma output of each of the plasma torches 7a and 7b is constantly 1,000 kW.
As seen from
Furthermore, the results of a simulation of measuring the pool depth of the molten metal pool formed inside of the mold 2, with the heat input amount in the mold 2 being shown by a cross-sectional view, which is performed for a case where while moving plasma torches 7a and 7b based on the trajectory shown in
As described above, in the continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention, two plasma torches 7a and 7b are used, so that the movement distance of each plasma torch 7a or 7b can be shortened and reduction in the ingot temperature can be suppressed. In addition, each of two plasma torches 7a and 7b is moved to be located either on the upper side in the vicinity of the edge of a mold 2 or on the upper side near the central part of the mold 2, so that the entire melt surface can be heated without causing interference of two plasma torches 7a and 7b with each other.
Furthermore, the centers of two plasma torches 7a and 7b are moved to be located on trajectories formed after an inner circumferential arc having a radius of 0<r1<R/2 from the center of the melt surface and an outer circumferential arc having a radius of R/2<r2<R from the center of the melt surface are connected by a straight line, so that the entire melt surface can be heated without causing interference of two plasma torches 7a and 7b with each other. As a result, the life of the torch can be extended. In addition, the plasma output is set high when the plasma torches 7a and 7b move in the outer circumferential arc, and the plasma output is set low during movement in the inner circumferential arc, so that the heat input amount in the vicinity of the edge of a mold 2 can be made large and the heat input amount near the central part of the mold 2 can be made small. In turn, the growth of an initial solidified shell can be suppressed, and the total amount of heat input into the melt surface decreases as compared with uniform heat input. Therefore, the depth of the molten metal pool becomes shallow, and the component segregation can be reduced.
As a result, in the continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention, an ingot 11 having a good casting surface can be produced by reducing the component segregation and the lives of plasma torches 7a and 7b can be extended by causing no interference of plasma torches 7a and 7b with each other.
In the foregoing pages, the present invention has been described with reference to preferred embodiments thereof, but the present invention is not limited to these embodiments, and various changes falling within the scope of claims can be made therein.
In the above-described continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention, with respect to trajectories of movements of two plasma torches 7a and 7b, assuming that when the molten metal 12 is viewed from the front of the melt surface, the center of the molten metal 12 in the mold 2 is an origin and the melt surface perpendicular to the central axis of the molten metal 12 is an xy plane, two plasma torches 7a and 7b are controlled so that each center can move in the range of x<0 or x>0, but the present invention is not limited thereto.
For example, as shown in
Inner circumferential arc having a radius of 0<r1<R/2: B→C→D for the plasma torch 7a, and D→E→F for the plasma torch 7b
Outer circumferential arc having a radius of R/2<r2<R: E→F→A for the plasma torch 7a, and A→B→C for the plasma torch 7b
Straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc: A→B and D→E for the plasma torch 7a, and C→D and F→A for the plasma torch 7b
That is, in
For plasma torch 7a:
A→B: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
B→C→D: inner circumferential arc (range of x>0)
D→E: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
E→F→A: outer circumferential arc (range of x<0)
For plasma torch 7b:
A→B→C: outer circumferential arc (range of x>0)
C→D: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
D→E→F: inner circumferential arc (range of x<0)
F→A: straight line connecting two arcs, i.e., inner circumferential arc and outer circumferential arc
Also in such a case, the centers of two plasma torches 7a and 7b are moved to be located on trajectories formed after an inner circumferential arc having a radius of 0<r1<R/2 from the center of the melt surface and an outer circumferential arc having a radius of R/2<r2<R from the center of the melt surface are connected by a straight line, so that the entire melt surface can be heated without causing interference of two plasma torches 7a and 7b with each other.
Any other trajectories may be employed as long as the entire melt surface can be heated without causing interference of two plasma torches 7a and 7b with each other.
In the above-described continuous casting apparatus of an ingot formed of titanium or a titanium alloy according to an embodiment of the present invention, two plasma torches 7a and 7b are used as the plasma torch, but the present invention is not limited thereto. Using a plurality of plasma torches, their trajectories may be ensured so that the entire melt surface can be heated without causing interference with each other.
This application is based on Japanese Patent Application No. 2013-135205 filed on Jun. 27, 2013, the contents of which are incorporated herein by way of reference.
Number | Date | Country | Kind |
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2013-135205 | Jun 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP14/65517 | 6/11/2014 | WO | 00 |