1. Field of the Invention
The present invention relates to a molding device for continuous casting, which is equipped with a stirring unit, of continuous casting equipment that produces a billet, a slab or the like made of non-ferrous metal of a conductor (conductive body), such as Al, Cu, Zn, or an alloy of at least two of them, or an Mg alloy, or other metal.
2. Background Art
In the past, a melt stirring method to be described below has been employed in a mold for continuous casting. That is, for the improvement of the quality of a slab, a billet, or the like, in a process for solidifying the melt, that is, when the melt passes through the mold, a moving magnetic field, which is generated from the outside of the mold by an electromagnetic coil, is applied to the melt present in the mold so that stir occurs in the melt immediately before being solidified. A main object of this stir is to degas the melt and to uniformize the structure. However, since the electromagnetic coil is disposed at the position close to high-temperature melt, not only the cooling of the electromagnetic coil and troublesome maintenance are needed but also large power consumption is naturally needed. In addition, the generation of heat from the electromagnetic coil itself caused by the power consumption cannot be avoided, and this heat has to be removed. Because of this reason, there are various problems in that the device itself cannot but become expensive, and the like.
Patent Document 1: JP 9-99344 A
The invention has been made to solve the above-mentioned problems, and an object of the invention is to provide a molding device for continuous casting with a stirring unit that suppresses the amount of generated heat, requires easy maintenance, and is easy to use actually, as a molding device that can be made small at a low cost regardless of the size of a product to be obtained.
According to an embodiment of the present invention, there is provided a molding device for continuous casting with a stirring unit, the molding device from which a solid-phase casting can be taken out by the cooling of liquid-phase melt of a conductive material, the molding device including:
a mold that forms a casting by cooling the received melt; and
a stirring unit that applies a magnetic field to the melt present in the mold and allows a current to flow in the melt in this state,
wherein the mold includes a cylindrical mold body that is vertically provided,
a central portion of the mold body forms a vertical casting space that includes an upper inlet into which the melt flows and a lower outlet from which a product is taken out,
a transition plate body, which has a ring shape and functions as a transition plate, is disposed at the inlet of the mold space,
the melt is allowed to flow into the casting space from a hole that is formed at a central portion of the transition plate body, and
the stirring unit includes a magnetic field unit including:
a) is a longitudinal sectional view illustrating the entirety of an embodiment of the invention, and
a) is a top view of a transition plate body that is one component of the embodiment, and
a) is a longitudinal sectional view of a lid body of the transition plate body, and
a) is a partial longitudinal sectional side view of an upper magnet, and
a) is a longitudinal sectional view of a magnet body (a yoke body and a permanent magnet body) that is one component of the upper magnet, and
a) is a plan view of a side magnet of another embodiment, and
For deeper understanding of an embodiment of the invention, an electromagnetic stirring unit, which uses electricity as power, of continuous casting equipment in the related art will be described briefly.
In the related art, a fixed amount of melt M of non-ferrous metal is discharged from a melt receiving box that is called a tundish and is poured into a mold that is provided on the lower side by fixed amount of tapping. Cooling water for cooling the mold is circulated in the mold. Accordingly, high-temperature melt starts to solidify from the outer periphery thereof (the mold side) from the moment that the high-temperature melt comes into contact with the mold. Since the melt, which is positioned at the central portion of the mold, is distant from the wall of the mold that is at a low temperature, the solidification of the melt positioned at the central portion of the mold occurs naturally later than that of the melt positioned at the outer peripheral portion of the mold. For this reason, two kinds of melt, that is, liquid (liquid-phase) melt and a solid (solid-phase) casting are simultaneously present in the mold while coming into contact with each other through an interface. Further, generally, if melt is solidified too rapidly, gas remains in the casting (product) that has been changed into a solid and causes the quality of the product to deteriorate. For this reason, degassing is facilitated by the stirring of the melt that is not yet solidified. The electromagnetic stirring unit, which uses electricity as power, has been used for the stirring in the related art.
However, when such an electromagnetic stirring unit is used, there are various problems as described above.
In order to solve these problems, the inventor has previously proposed an invention disclosed in JP 2013-103229 A (prior invention). In this prior invention, current flows in melt in a vertical direction, a magnetic field is applied to the melt in a lateral direction, and the current and the magnetic field are substantially orthogonal to each other, so that the melt M is rotated (stirred) or vibrated by an electromagnetic force according to Fleming's rule. In this prior invention, when the width (diameter or the like) of a product (a billet, a slab, or the like) P is increased, it is possible to cope with the increase of the width of the product by increasing the intensity of a magnetic field of a magnetic field generating unit, accordingly. That is, regardless of whether the product P is a billet having a diameter of several tens centimeters or a slab having a diameter of several tens meters, a permanent magnet having the diameter or having the intensity of a magnetic field according to the diameter may be used. However, the inventor exercises one's ingenuity every day to always produce a more excellent device. As one example, the inventor has a sense of purpose to provide a device that avoids an increase in size, can also be easily manufactured and requires easy maintenance, at a low cost. That is, the inventor proposes a small device for obtaining a high-quality product by stirring or vibrating melt without using a large permanent magnet unit that has the intensity of a magnetic field directly proportional to the increase of the width of the product P even though the width (diameter or the like) of the product P is increased. If each device can be made small in this way, a plurality of devices are disposed in parallel and a plurality of products can be manufactured at a time. Since this challenge is peculiar to the inventor, it is said that other those skilled in the art do not have this task. In order to solve this task, the inventor has performed a lot of experiments on whether melt is actually rotated or vibrated by using a permanent magnet of which the intensity of a magnetic field is lower than the intensity of a magnetic field directly proportional to the diameter. As illustrated in
An embodiment of the invention, which is formed as described above, will be described below. Meanwhile, in the embodiment of the invention to be described below, a billet, a slab, or the like as a product to be taken out is modified to be provided as a higher-quality product. Further, an electromagnet is not used and a permanent magnet is used, and a small permanent magnet, which is not necessarily directly proportional to the diameter of a product P and of which the intensity of a magnetic field is low, is used as the permanent magnet to be used. Furthermore, a molding device, which manufactures a billet or a slab, is in very high temperature environment. Accordingly, even if a permanent magnet is used, the permanent magnet is heated to high temperature by the heat of the melt M. For this reason, it is also considered that the permanent magnet does not function as a magnet. Therefore, an independent structure for cooling a permanent magnet is newly employed in the embodiment of the invention to prevent the function of the permanent magnet from being shut down by heat even though the permanent magnet is disposed outside a water jacket.
An embodiment of the invention will be described below with reference to the drawings. Meanwhile, a scale of a drawing is not necessarily the same in the respective drawings.
As understood from
(1) Melt Supply Unit 1
The melt supply unit 1 includes a tundish (melt receiving box) 1A that receives melt M from a ladle (not illustrated) or the like. The melt M is stored in the tundish (melt receiving box) 1A, inclusion is removed from the melt, and the melt M is supplied to the mold 2 from a melt supply pipe portion 1A1, which is disposed below the tundish and is narrowed to have the shape of a funnel, at a constant supply rate. The melt supply pipe portion 1A1 is liquid-tightly connected to a central annular wall 3A2 of a transition plate body 3A of the mold 2 as described below.
(2) Mold 2
As also understood from
The mold 2 includes a substantially cylindrical mold body 2a (of which the cross-section has a ring shape), the transition plate body 3A that is disposed inside an upper end portion of the mold body 2a, and a cylindrical body 2c that is embedded into an inner peripheral surface of the mold body 2a and is used to shape the surface of a product.
The mold body 2a includes a water jacket 2d that is a space formed inside a peripheral wall. The water jacket 2d is formed as a space which is formed inside the peripheral wall of the mold body 2a and of which the cross-section has an annular shape, and includes an inlet and an outlet (not illustrated) for cooling water. That is, the water jacket allows cooling water to flow into the water jacket 2d from the inlet, circulates the cooling water in the water jacket 2d to cool the melt M, and then discharges the cooling water from the outlet. The melt M, which is present in the mold body 2a, is rapidly cooled by the water jacket 2d. Water jackets having well-known various structures may be employed as the water jacket 2d. Accordingly, the detailed description of the water jacket will be omitted.
Moreover, a top portion of the mold body 2a forms a protruding peripheral portion 2e of which the longitudinal section has a chevron shape, and comes into contact with grooves 4b1 of the lid body 4b with a large contact area by meshing with the grooves 4b1 of the lid body 4b as described below. Accordingly, thermal conductivity is improved.
Further, the transition plate body 3A, which is mounted on the mold body 2a, is made of a refractory material and includes the inlet EN.
A top portion of the peripheral annular wall 3A3 also forms a protruding peripheral portion 3A31 of which the section has a chevron shape, and comes into contact with grooves 4b1 of the lid body 4b with a large contact area by meshing with the grooves 4b1 of the lid body 4b (
The cylindrical body 2c is embedded into the inner peripheral surface of the mold body 2a. The cylindrical body 2c is to prevent the high-temperature melt M from coming into direct contact with the mold body 2a. Further, the cylindrical body 2c is made of carbon, and also has a function of smoothening the skin of the surface of the product P. That is, the cylindrical body 2c has both a function of protecting the mold body 2a from heat and a function of improving the quality of the skin of the product P.
(3) Stirring Unit 3
The stirring unit 3 stirs and vibrates a melt M which is not yet solidified, by an electromagnetic force (Lorentz force) according to Fleming's left hand rule. The stirring unit 3 includes a magnetic field unit 4 that generates a magnetic field in the melt M present in the mold body 2a, and an electrode pair 5 that allows current to flow in the melt M.
(3)-1 Magnetic Field Unit 4
As particularly understood from
The lid body 4b is particularly illustrated in
Meanwhile, as understood from the above description, the lid body 4b and the mold body 2a (and the transition plate body 3A) may come into contact with each other with a large contact area, and may employ other structures without being limited to the above-mentioned structure. For example, the pitch of the grooves 4b1 of the lid body 4b may be made smaller so that protrusions and recesses of the grooves 4b1 have finer texture, and the pitch of the protruding peripheral portion 2e and the protruding peripheral portion 3A31 meshing with the grooves 4b1 may also be made smaller accordingly. Accordingly, a contact area between the grooves and the protruding peripheral portions can be further increased. Further, it is also possible to increase a contact area by using the contact with a tapered surface as a simpler structure instead of the meshing with the protrusions and recesses. Furthermore, a fillet of welding, such as an auxiliary member, may be provided between the lid body 4b and the mold body 2a and between the lid body 4b and the transition plate body 3A to increase a contact area between the lid body and both the mold body and the transition plate body.
Meanwhile, for the cooling of the lid body 4b, the lid body 4b and the mold body 2a have only to mesh with each other and the lid body 4b and the transition plate body 3A may not necessarily mesh with each other.
As understood from
The upper magnet 4a is particularly illustrated in
As understood from
The magnet body 40, which is covered with the cover 43 from below, is illustrated in
Meanwhile, various magnet bodies may be used as the permanent magnet body 42 other than the permanent magnet body illustrated in
Meanwhile, in
(3)-2 Electrode Pair 5
Next, the electrode pair 5 of the stirring unit 3 will be described. As understood from
One end of the rod-shaped electrode 5a is immersed in the melt M present in the tundish (melt receiving box) 1A. Rollers 5b1 of the roller-shaped electrodes 5b are provided so as to come into press contact with the surface of a product (billet) P, which has been taken out, and so as to be electrically conducted to the product. Accordingly, these electrodes 5a and 5b are electrically conducted to each other through the melt M and the product (billet) P. Accordingly, current flows between these electrodes 5a and 5b through the melt M and the product (billet) P as described in detail below. The plurality of roller-shaped electrodes 5b have been provided in this embodiment, but the number of the roller-shaped electrodes 5b may be one or three or more. When the plurality of roller-shaped electrodes 5b are provided, the roller-shaped electrodes 5b may be radially disposed so as to surround the outer periphery of the product (billet) P as illustrated in
In more detail, in
Accordingly, for example, when a DC voltage is applied between the pair of electrodes 5a and 5b from the power control panel 7, direct current flows between the pair of electrodes 5a and 5b through the melt M and the product P. The amount of current flowing between the pair of electrodes 5a and 5b can be controlled as described above. Accordingly, it is possible to select current, which allows liquid-phase melt M to be most efficiently stirred, by a relationship with the lines ML of magnetic force. Further, for example, when a low-frequency AC voltage in the range of about 1 to 5 Hz is applied between the pair of electrodes 5a and 5b from the power control panel 7, the melt M is not rotated in one direction but vibrated. Inclusion contained in the melt M is removed by this vibration.
Next, the operation of the device having the above-mentioned structure will be described.
In
The melt M is solidified in this way. However, before being solidified, the melt M is rotated by making direct current flow between the electrodes 5a and 5b under the presence of a magnetic field generated by the upper magnet 4a and is vibrated by making low-frequency alternating current flow between the electrodes under the presence of a magnetic field generated by the upper magnet. This has been briefly described above, but this is also confirmed by the experiments of the inventor. The melt M forms a product by solidification after the quality of the melt is improved in this way.
The melt M is rotated and vibrated as described above, the mechanism thereof is considered as follows: the rotation and vibration of the melt M is not different from the generation of an electromagnetic force according to Fleming's left hand rule when the lines ML of magnetic force generated from the upper magnet 4a cross current flowing between the electrodes 5a and 5b. It is considered that the lines ML of magnetic force generated from the upper magnet 4a are formed as shown in
In the embodiment of the invention, as described above, a magnetic field is applied to the melt M, which is not yet solidified, from the upper magnet 4a that is disposed on the end face portion of the mold 2. For this reason, even though the width of the mold 2, that is, the diameter of the product P to be obtained is large, that is, several meters like a slab, it is possible to apply a magnetic field to the melt regardless of the width of the mold, so that an electromagnetic force according to Fleming's left hand rule is obtained. Accordingly, it is possible to reliably rotate and vibrate the melt M. That is, even though the product P to be obtained is small like a billet or is large like a slab, a magnetic field unit generating a particularly large and strong magnetic field does not need to be used as the upper magnet 4a regardless of the size of the product. In contrast, as described above, a magnetic field unit that applies a magnetic field having intensity according to the diameter of a product P to be obtained should be used in a device in the related art that laterally applies a magnetic field, as explained above. The magnetic field unit, which applies a magnetic field having such high intensity, actually has a very large size. For this reason, it may be difficult to actually use a magnetic field unit that applies a very large magnetic field or a large magnetic field unit. Further, since the size of the device becomes very large if the magnetic field unit is actually used, it may also be difficult to realize a device that produces a plurality of billets or slabs.
Meanwhile, the electrodes, which are provided with the rollers 5b1 at the tips thereof, are used as the lower electrodes 5b in the above-mentioned embodiment. However, the lower electrodes do not need to be provided with the rollers 5b1. Even though the product P is continuously extruded, electrical conduction between the product P and the electrode 5b has only to be kept and various structures may be employed. For example, elastic members having a predetermined length may be used as the electrodes 5b. In
In the embodiment of
In this embodiment, as understood from
Further, when the side magnet 45 is moved up over the position of
Meanwhile, the side magnet 45 may also be provided outside the water jacket 23.
According to the above-mentioned embodiments of the invention, the following effects are obtained.
In the embodiments of the invention, the permanent magnet (upper magnet 4a) is not provided on the side peripheral surface portion (or in the peripheral wall) of the mold 2 but is provided on the end face portion of the mold 2. As described above, this structure is a structure that is never employed by those skilled in the art. If a product P has a large width (diameter) like a slab when a side magnet is provided on the side peripheral surface portion, a stronger and larger magnet should be used. Further, the cylindrical body 2c as a transition ring is generally provided in the inner side of the mold 2. Furthermore, since the mold 2 itself is thick and the cylindrical body 2c has a thickness, a distance between the side magnet and the melt M present in the mold is longer. Accordingly, a side magnet that applies a magnetic field having high intensity, that is, a side magnet having a very large size should be used to apply a magnetic field to the melt M by the side magnet. The increase in size should be avoided for various reasons, for example, when multiple products P are produced, that is, when a plurality of devices need to be simultaneously installed. However, since the upper magnet 4a is provided on the end face portion of the mold 2 in the embodiments of the invention, a permanent magnet, of which the intensity of a magnetic field is directly proportional to the size (increase in size) of a product P, does not need to be used as the upper magnet 4a. The reason for this is that the lines ML of magnetic force can reach the melt M present in the mold from the end face portion of the mold even though the intensity of a magnetic field is not increased to that extent. That is, according to the embodiments of the invention, a large permanent magnet, which has high intensity of a magnetic field directly proportional to the diameter of a product P to be obtained, does not need to be used as a permanent magnet to be used. For this reason, it is possible to make the entire device small.
Further, in the embodiments of the invention, the permanent magnet (upper magnet 4a) is not provided in the water jacket 2d but is provided on the end face portion of the mold 2. Therefore, there is no limit on the size as the permanent magnet is provided in the water jacket 2d, and it is said that flexibility is more excellent when a permanent magnet is employed. Furthermore, since the upper magnet 4a is configured to be able to be cooled by the water jacket 2d, a function as a magnetic field unit can be secured.
Naturally, in the embodiments of the invention, melt M, which is obtained immediately before being solidified, is stirred so that movement, vibration, or the like is applied to the melt M. Accordingly, a degassing effect or the homogenization and refinement of the structure can also be achieved.
Moreover, since the melt M is stirred by an electromagnetic force according to Fleming's left hand rule in the embodiments of the invention, the melt is stirred by the cooperation of small current that flows in the melt M and a magnetic field that goes out of the upper magnet 4a. Accordingly, since a stable, continuous, and reliable stir can be expected unlike a dissolution stir that is performed when large current intermittently flows by an arc welding principle or the like, it is possible to obtain a device that has high continuousness and low noise.
However, the realization of mass production facilities has been required in industries at present. When mass production is considered, it is essential to make a mold as small as possible. Meanwhile, since the device can be made small in the embodiments of the invention, it is possible to construct highly-efficient production facilities for multiple products. That is, an electromagnetic stir in the related art can cope with a case in which several slabs or billets are produced at a time. However, there has been a request on the simultaneous production of more than 100 billets at present. This request cannot be satisfied by the electromagnetic stirring unit in the related art.
However, a permanent magnet is used as a magnetic field generating unit in the device of the invention. For this reason, it is possible to make a stirring unit more compact than an electromagnetic stirring unit in which large current flows. In addition, the permanent magnet is not provided in the lateral direction of the mold but is provided in the longitudinal direction (on the end face portion of the mold). Accordingly, it is possible to make a device small and to sufficiently realize a molding device for mass production facilities.
Further, since the molding device is a permanent magnet type molding device, a unit, which does not generate heat, saves power and energy, and requires low maintenance, can be obtained as a magnetic field generating unit.
Meanwhile, a case in which a billet is obtained as a product has been described above, but it is natural that a device can be adapted to obtain a slab. In this case, it is apparent that components having a circular shape and an annular shape in plain view or a cross-section in the above-mentioned embodiments may have a rectangular shape and a frame shape.
Number | Date | Country | Kind |
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2013-165473 | Aug 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/084920 | 12/26/2013 | WO | 00 |