JP6117428B2 - Rotor casting apparatus and rotor casting method having slide control type vent function - Google Patents

Description

The present invention relates to a rotor casting apparatus and method, and more particularly, prior to the injection of molten metal for casting of a rotor, the casting air quality of the rotor is controlled by venting by controlling the air inside the mold cavity in a sliding manner. The present invention relates to a rotor casting apparatus having a slide control type vent function that can be improved and a rotor casting method.

  A rotor is a general term for a rotating part of an electric motor or a generator. Such a rotor will be described with reference to FIGS. 1 and 2. FIG. 1 is a conceptual diagram showing a general rotor core, and FIG. 2 is a conceptual diagram showing a rotor in which upper and lower end rings are formed from a molten aluminum on the core shown in FIG. 1 by a casting technique.

  As shown in FIG. 1, the core C is formed by laminating a large number of iron cores C1 in which a large number of slots C2 are formed. After such a core C is installed in a predetermined mold (not shown), the molten metal is injected, and the molten metal is cured while passing through the slot C2 to form the rotor R as shown in FIG. At this time, the rotor R has a form in which an upper end ring C3 and a lower end ring C4 are formed on the upper and lower parts of the iron core C1, as shown in FIG. 2, or a form without the upper end ring C3 and / or the lower end ring C4. have.

Conventional techniques for casting the rotor R include a centrifugal casting method using a centrifugal casting machine, a vertical high pressure casting method using a vertical injection method, and a horizontal high pressure casting method using a horizontal injection method. is there.
The rotor manufacturing method using the centrifugal casting method has a high filling rate and excellent efficiency, but has a problem that it cannot be used for general purposes.

  The vertical high-pressure casting method using the vertical pouring method has a high production capacity, so it is widely used at present, but the ingate into which the molten metal is poured is biased to one side, and the ingate in the rotor There is a problem that the bubbles are isolated and distributed in the portion where there is no noise, thereby causing an imbalance of the rotor and vibration noise, which causes a reduction in efficiency. In addition, since the amount of runners is very large, the amount of aluminum that is consumed is large, so that the cost for remelting increases, resulting in high production costs.

  On the other hand, the horizontal high-pressure casting method using the horizontal injection method uses low-cost equipment and can produce a rotor at a low production cost with a small amount of consumed aluminum. There is a problem with a lower filling rate.

  The present invention has been made to solve the above-mentioned problems, and prior to the injection of molten metal for rotor casting, the casting air quality of the rotor is controlled by venting by controlling the air inside the mold cavity in a sliding manner. It is an object of the present invention to provide a rotor casting apparatus having a slide control type vent function capable of improving the speed, a rotor using the same, and a casting method thereof.

In order to achieve the above-described object, the present invention provides a mold assembly in which a rotor core is inserted and molten metal is injected, and before the molten metal is injected into the mold assembly, the internal air of the mold assembly is removed. A rotor casting apparatus comprising vent means for controlling and venting in a sliding manner and a pressing part assembly for pressing a molten metal filled in the mold assembly, wherein the mold assembly is a hollow into which the core is inserted. A mold main body, a first end forming portion provided on one side of the mold main body and used to form one side surface of the rotor, and provided on the other side of the mold main body, and a second end forming portion for use in forming the other side of the rotor, the vent means includes a vacuum pump for discharging the internal air of the mold assembly to the outside, said second end forming portion Is selectively sealed to the other side of the mold body, a vent valve for selectively sealing the communication lines inside said vacuum pump of said mold assembly, the tapered surface formed on one side of the vent valve A taper block that makes surface contact, and an elevating member that moves the taper block downward, and moves the vent valve in a sliding manner by sealing the second end forming portion to the other side of the mold body through the vent valve. It is characterized by including.

According to the present invention, the pressing unit assembly includes a take-out cylinder that pushes out a rotor that has been cast and takes out, and a drive unit that drives the take-out cylinder.
The second end forming part includes a vent valve insertion hole into which a part of the vent valve is inserted.

  Further, according to the present invention, the vent valve has an outer diameter fitted into the vent valve insertion hole, extends outside the vent valve insertion hole, and comes into close contact with the other side surface of the core to the peripheral surface. The taper part which forms the fixed space for forming the upper end ring of a rotor, and the channel | path which the said extraction cylinder can insert are characterized by the above-mentioned.

  According to the present invention, the tapered block includes a tapered portion corresponding to the tapered surface so as to make surface contact with the tapered surface, and a coupling portion coupled to an end of the elevating member. Features.

  According to the present invention, the elevating member includes an actuator that drives the taper block upward and downward, and a housing that houses the actuator.

According to the present invention, the first end forming part has a fixed space for forming a lower end ring of the rotor in a close contact part in close contact with one side surface of the core.
According to the present invention, the second end forming part has a fixed space for forming an upper end ring of the rotor in a close contact part in close contact with the other side surface of the core.

  Further, according to the present invention, the first end forming portion is provided in a sealing member for sealing one end portion of the mold body and the sealing member, and the molten metal is injected into the mold body side. It includes an injection hole and an exhaust hole.

  In addition, according to the present invention, the pressing unit assembly further includes a plurality of squeeze cylinders that are driven by the driving unit and pressed to improve a filling rate of the upper end ring, and the second end forming unit includes And a plurality of squeeze cylinder insertion holes into which the plurality of squeeze cylinders are inserted.

  According to the present invention, the vent valve further includes a flange having the tapered surface, and the flange further includes a plurality of squeeze cylinder insertion holes into which the plurality of squeeze cylinders are inserted. Features.

  According to the present invention, the tapered portion of the taper block has a long hole-shaped take-out cylinder through hole through which the take-out cylinder penetrates, and a plurality of long-hole squeeze cylinder through holes through which the plurality of squeeze cylinders penetrate. Is further formed.

According to another aspect of the present invention, there is provided a method for casting a rotor according to the present invention, wherein the second end forming portion is spaced apart from the other side of the die body at a predetermined interval. And venting the internal air of the mold assembly through a communication line of the vacuum pump, and the second end forming part on the other side of the mold body using the vent means operated by the injection pressure of the molten metal. Sealing the rotor, casting the rotor by injecting and pressing molten metal into the mold assembly, and advancing the take-out cylinder to take out the rotor. And

  The present invention has an advantage that the casting quality of the rotor can be improved by venting by controlling the internal air of the mold cavity in a sliding manner prior to pouring the molten metal for casting the rotor.

It is a conceptual diagram which shows the core of a common rotor. It is a conceptual diagram which shows the rotor which formed the upper and lower end rings from the molten aluminum in the core shown in FIG. 1 with the casting technique. It is a perspective view which shows the external appearance of the casting machine which has the rotor casting apparatus with a slide control type vent function by this invention. It is a combined perspective view showing the structural relationship of a rotor casting apparatus having a slide control type vent function according to an embodiment of the present invention. It is a disassembled perspective view which shows the structural relationship of the rotor casting apparatus with a slide control type vent function by one Example of this invention. FIG. 6 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention, and FIG. 6 shows a state before the operation of the vent means capable of venting the internal air of the mold cavity. FIG. 7 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention, and FIG. 7 shows a state where casting is possible by the operation of the vent means by the injection pressure of the molten metal. FIG. 8 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention. FIG. 8 shows a state in which the rotor is filled by pouring molten metal. FIG. 9 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention, and FIG. 9 shows a state in which the squeeze cylinder operates to improve the filling rate. FIG. 10 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention, and FIG. 10 shows a state in which a molten metal injection part is separated. FIG. 11 is a conceptual diagram showing a procedure for casting a rotor by the casting apparatus of the present invention, and FIG. 11 shows a process of extracting the rotor cast by the take-out cylinder. FIG. 4 is a cross-sectional view of an upper end ring of a rotor cast by a conventional casting method and a casting method of the present invention, respectively. FIG. 4 is a cross-sectional view of an upper end ring of a rotor cast by a conventional casting method and a casting method of the present invention, respectively.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 3 is a perspective view showing an appearance of a casting machine having a rotor casting apparatus having a slide control type vent function according to the present invention. As shown in FIG. 3, the rotor casting apparatus according to this embodiment is provided inside a caster machine 1 composed of a number of divided molds. However, since such a caster machine 1 has a generally known structure, description thereof will be omitted, and the structural relationship of the rotor casting apparatus provided therein will be mainly described.

4 and 5 are a combined perspective view and an exploded perspective view showing a structural relationship of a rotor casting apparatus having a slide control type vent function according to an embodiment of the present invention.
As shown in FIGS. 1 to 5, the rotor casting apparatus 10 according to this embodiment includes a mold assembly 100 into which the core C of the rotor R is inserted and molten metal is injected, and the inside of the mold assembly 100. Prior to injecting the molten metal, a vent means 200 for venting the internal air of the mold cavity of the mold assembly 100 in a sliding manner and a pressing part assembly 300 for pressing the molten metal filled in the mold assembly 100 are included. It becomes.

  The mold assembly 100 includes a hollow cylindrical mold body 110 into which a core C is inserted, and a first end portion provided on one side of the mold body 110 and used to form one side of the rotor R. It comprises a forming part 120 and a second end forming part 130 provided on the other side of the mold body 110 and used to form the other side of the rotor R.

  The first end forming part 120 is used to form one side surface of the rotor R in close contact with one side surface of the core C while sealing one side of the mold main body 110. When it comprises so that it may have space, it is utilized also for the use which forms the lower end ring C4 of the rotor R. FIG. That is, the first end forming part 120 also serves as a lower end ring forming part.

  The second end forming part 130 is used to form the other side of the rotor R in close contact with the other side of the core C while selectively sealing the other side of the mold body 110. When the contact portion is configured to have a constant space, it is also used for forming the upper end ring C3 of the rotor R. That is, the second end forming part 130 also serves as an upper end ring forming part.

Therefore, in this embodiment, a structural relationship capable of casting the rotor R having the lower end ring C4 and the upper end ring C3 will be described as an example.
For this, the pressing unit assembly 300 includes a plurality of squeeze cylinders 320 inserted into the second end forming unit 130, a take-out cylinder 330 that pushes out the cast rotor R, and the take-out cylinders 330 and a plurality of squeeze. And a drive unit 310 for driving the cylinder 320.

  With such a configuration, after a squeeze bar protrudes from a partial region of the rotor R (in this embodiment, the upper end ring), the squeeze cylinder 320 presses the squeeze bar to improve the filling rate of the molten metal. become. For this reason, the squeeze cylinder 320 does not penetrate the second end forming part 130 but is inserted only in a partial region, and the molten metal filled in the remaining region is injected to form a squeeze bar. Like that. Thereafter, the squeeze cylinder 320 presses the squeeze bar. This will be further described later.

  On the other hand, the second end forming portion 130 is formed so as to penetrate a cylindrical coupling portion main body 131 that seals the other end portion of the mold main body 110, and a central portion of the coupling portion main body 131, and will be described later. A vent valve insertion hole 133 that allows a part of the vent valve 210 of the means 200 to be inserted, and a central part of the coupling part body 131 are formed so as to penetrate the coupling part body 131, and a large number of squeeze cylinders 320 are inserted. It includes a number of squeeze cylinder insertion holes 132 that enable it.

  On the other hand, in this embodiment, the mold body 110 has a hollow cylindrical shape, and has a tubular shape in which left and right end portions are open. Further, the second end forming part 130 has a coupling part main body 131 that covers the right-side open part of the mold main body 110 in the drawing. At this time, the squeeze cylinder insertion hole 132 and the vent valve insertion hole 133 penetrate the coupling portion main body 131.

  However, the second end forming portion 130 is intended to insert the squeeze cylinder 320 and the take-out cylinder 330 as described above, while closing the one side surface of the mold body 110. As long as the object can be achieved, the case where the second end forming portion 130 is formed integrally with the mold body 110 or has another shape must be understood as belonging to the category of the present invention. Don't be.

  On the other hand, in this embodiment, after forming the flange 131a that protrudes in the direction of the mold body 110 at the coupling part body 131 and is inserted into the mold body 110, the squeeze cylinder insertion hole 132 and the vent valve insertion hole 133 are formed. The thing formed so that the flange 131a may be penetrated is shown.

  At this time, the squeeze cylinder 320 is not inserted into the entire area of the squeeze cylinder insertion hole 132 (in other words, up to the end of the squeeze cylinder insertion hole 132 on the mold body 110 side) as described above. It is inserted up to (for example, an intermediate point), and the remaining area is made free. Here, the squeeze bar is formed by pouring molten metal into the remaining remaining area, and the squeeze cylinder 320 presses the formed squeeze bar.

  The first end forming part 120 includes a sealing member 121 that seals one end of the mold body 110, and an injection that penetrates the sealing member 121 so that the molten metal is injected into the mold body 110 side. A hole 122 and an exhaust hole 123 are included. At this time, the sealing member 121 is configured such that the inner portion thereof has a constant internal space, and the lower end ring C4 of the rotor R is formed by the molten metal filled therein. However, in the case of the rotor R that does not require the lower end ring C4, the sealing member 121 may be configured as a disk-shaped disk.

  In this embodiment, the sealing member 121 of the first end forming portion 120 covers the left open portion of the mold body 110 in the drawing. Further, the case where nine injection holes 122 and one exhaust hole 123 are provided through the sealing member 121 is illustrated.

  However, the first end forming portion 120 is intended to form one side surface of the rotor R by injecting the molten metal into the mold body 110 as described above. As long as such an object can be achieved, the sealing member 121 of the first end forming portion 120 is formed separately from the mold body 110 as illustrated, or formed integrally with the mold body 110. Needless to say, any of the cases belongs to the category of the present invention. Meanwhile, four to twelve injection holes 122 may be formed.

  The venting means 200 vents the internal air of the mold cavity of the mold assembly 100 to the outside prior to pouring the molten metal into the mold assembly 100, and the vacuum for exhausting the internal air of the mold assembly 100 to the outside. A pump (not shown), a vent valve 210 for selectively sealing the inside of the mold assembly 100 and the communication line of the vacuum pump, a tapered block 220 in surface contact with one side of the vent valve 210, and a tapered block 220. It consists of an elevating member 230 that moves downward and moves the vent valve 210 in a sliding manner.

  The vent valve 210 operates integrally with the second end forming portion 130 of the mold assembly 100. Therefore, the vent valve 210 has an outer diameter that fits into the vent valve insertion hole 133 of the second end portion forming portion 130, and not only has the tapered portion 211 at one end portion side, but also takes out into the inside thereof. The cylinder 330 is configured to have a passage 212 through which it can move. In addition, the vent valve 210 has a flange 214 formed with a tapered surface 213 in surface contact with the tapered portion 221 of the tapered block 220 on the other side. Here, a squeeze cylinder insertion hole 215 into which the squeeze cylinder 320 is inserted is further formed in the flange 214.

  On the other hand, the taper portion 211 extends from the end of the vent valve insertion hole 133 toward the core C and fixes the core C. Accordingly, a space is formed around the tapered portion 211 to fill the molten metal and form the upper end ring C3 of the rotor R.

  On the other hand, in this embodiment, by providing a tapered portion 211 extending from the end of the vent valve insertion hole 133 on the end side of the vent valve 210, the end of the tapered portion 211 is placed on the other side of the core C. In close contact. However, when the tapered portion 211 is not provided, the end portion of the second end portion forming portion 130 is in close contact with the other side surface of the core C, and the core C is fixed.

  The tapered portion 211 aims to provide a space for forming the upper end ring C3 of the rotor R around the tapered portion 211 while pressing and fixing the core C as described above. It goes without saying that any case where the tapered portion 211 has another shape belongs to the category of the present invention as long as such an object can be achieved.

  The tapered block 220 has a tapered portion 221 corresponding to the tapered surface 213 so as to come into surface contact with the tapered surface 213 of the vent valve 210 and a coupling portion 222 coupled to the end of the elevating member 230. The Then, a long hole-shaped take-out cylinder through hole 223 through which the take-out cylinder 330 passes through the tapered portion 221 and a plurality of long-hole-shaped squeeze cylinder through holes 224 through which the squeeze cylinder 320 passes are formed. At this time, the through holes 223 and 224 are formed to have a sufficient length so as not to be applied to the cylinders 330 and 320 even when the tapered block 220 is moved up and down.

  Meanwhile, the taper block 220 is intended to be moved in a sliding manner by the operation of the elevating member 230. It goes without saying that any case where the tapered block 220 has another shape belongs to the scope of the present invention as long as such an object can be achieved.

  The elevating member 230 may include an actuator (not shown) that drives the taper block 220 upward and downward, and a housing 231 that houses the actuator. Here, the actuator is a generic name for the taper block 220 that operates up and down. For example, a commonly used hydraulic or pneumatic cylinder actuator can be used. Alternatively, a mechanical actuator such as a gear that can mesh with the taper block 220 and move the taper block 220 up and down can be used. Alternatively, an electric actuator such as a motor can be used.

  Therefore, as long as the taper block 220 can be moved up and down, any actuator according to the present invention should be understood as belonging to the category of the present invention regardless of its type.

  This embodiment shows a state in which the actuator rod 232 is coupled to the coupling portion 222 of the taper block 220 in a state where the actuator is built in the thick flat plate housing 231. However, this is only an example for explaining the present invention. For example, the case where the actuator is not incorporated in the housing 231 and the case where the actuator is mounted outside the housing 231 belongs to the category of the present invention. Needless to say.

  On the other hand, the inside of the mold assembly 100 according to this embodiment is vented by a vacuum pump. Here, the vent line of the vacuum pump is formed by the exhaust hole 123 of the first end forming part 120, the through hole in the center of the core C, and the gap between the mold body 110 and the second end forming part 130. The Therefore, venting by the vacuum pump is performed before the molten metal is injected into the mold assembly 100, that is, in a state where the mold main body 110 and the second end portion forming portion 130 are not in close contact with each other. The operation is not performed in a state where the mold body 110 and the second end forming portion 130 are in close contact with each other. That is, according to the present invention, before the molten metal is injected into the mold assembly 100, the internal air is vented and the respective components are brought into close contact with each other in a form that can be cast by the slide principle at the time of molten metal injection. It is.

  Meanwhile, the driving unit 310 of the pressing unit assembly 300 may include an actuator (not shown) that drives the take-out cylinder 330 and the squeeze cylinder 320 and a housing 311 that houses the actuator. Here, the actuator is a generic name for the take-out cylinder 330 and the squeeze cylinder 320 that move forward and backward. For example, a commonly used hydraulic or pneumatic cylinder actuator can be used. Alternatively, a mechanical actuator such as a gear that can mesh with each cylinder 320, 330 and move the cylinder 320, 330 back and forth can be used. Alternatively, an electrical actuator such as a motor can be used.

  Therefore, the actuator of the present invention must be understood as belonging to the category of the present invention as long as the cylinders 320 and 330 can be moved forward and backward.

  In this embodiment, an actuator is incorporated in a thick disk-shaped housing 311. However, this is only an example for explaining the present invention. For example, any case where the actuator is not built in the housing 311 and is mounted outside the housing 311 belongs to the category of the present invention. Needless to say.

The rotor R can be cast and manufactured in a state where the air inside the mold assembly 100 is vented by the casting apparatus 10 of the present invention as described above.
Hereinafter, a method for casting the rotor R using the casting apparatus 10 of the present invention will be described with reference to FIGS.

  6 to 11 are conceptual diagrams showing a procedure for casting the rotor by the casting apparatus of the present invention, FIG. 6 shows a state before the operation of the vent means capable of venting the internal air of the mold cavity, and FIG. FIG. 8 shows a state where casting is possible by the operation of the vent means by the injection pressure of the molten metal, FIG. 8 shows a state where the casting is filled by injection of the molten metal, and FIG. 9 shows a state where the squeeze cylinder operates to improve the filling rate. 10 shows a state where the molten metal injection portion is separated, and FIG. 11 shows a process of extracting the rotor cast by the take-out cylinder.

  The rotor casting method of the present invention is a method of casting a rotor using the rotor casting apparatus 10 having the slide control type vent function of the present invention described above. On the other hand, the method using the rotor casting apparatus 10 of the present invention is performed in a state where the mold body 110 and the second end forming portion 130 are not in close contact with each other in the initial stage.

  The present invention includes a venting step for venting air inside the mold assembly 100 before the molten metal is injected into the mold assembly 100 (see FIG. 6). For this purpose, the air is exhausted by the vacuum pump through the exhaust hole 123 of the first end forming part 120, the central through hole of the core C, and the vent line formed by the gap between the mold body 110 and the second end forming part 130. Vent.

  Thereafter, if a signal for injecting the molten metal into the molten metal injection portion is transmitted to the vacuum pump and the lifting member 230, the vacuum pump stops further operation, and the lifting member 230 is operated to move the taper block 220 downward. Let Thus, as the taper block 220 gradually moves downward, the taper portion 221 pushes the taper surface 213 of the vent valve 210 more and more. As a result, the vent valve 210 and the second end forming portion 130 move simultaneously, the second end forming portion 130 is in close contact with the mold body 110 and the other side portion of the mold body 110 is sealed, and the vent valve 210 is sealed. The end portion of the core C is brought into close contact with the other side surface of the core C to fix the core C (see FIG. 7). That is, the sealing step is performed after the venting step.

  On the other hand, prior to performing the venting step, a preliminary step of inserting the core C into the mold body 110 can be performed. In addition, prior to performing a venting step of venting air with a vacuum pump, a molten metal manufacturing step of manufacturing a molten metal may be further included. At this time, the molten metal used was aluminum having a purity of 99.5% or more, and the molten metal having a molten metal temperature of 700 ° C. to 750 ° C. was found to be preferable in many experimental results.

  In addition, the present invention includes an insertion step of inserting the squeeze cylinder 320 into only a partial region of the second end forming part 130 (see FIG. 7). At this time, as described above, the squeeze cylinder 320 can be inserted into only a partial region of the squeeze cylinder insertion hole 132 of the second end forming part 130 and the squeeze bar can be formed by the remaining space.

  On the other hand, FIG. 7 shows that the squeeze cylinder 320 is inserted up to a partial region of the squeeze cylinder insertion hole 132 and the remaining region 130a is vacant. A squeeze bar, which will be described later, is formed by injecting molten metal into the remaining region 130a.

  After performing the insertion step, an end ring forming step is performed in which the mold body 110 is filled with the molten metal using the molten metal injection portion 240 to form the lower end ring C4 and the upper end ring C3 (see FIG. 8). After performing the end ring forming step, the filled molten metal is injected into the remaining end portion 130a of the second end forming portion 130 where the squeeze cylinder 320 is inserted and squeezed onto the upper end ring C3. A squeeze bar forming step for forming the bar SB is performed (see FIG. 9).

  As described above, since the squeeze cylinder 320 is inserted only in a partial region of the squeeze cylinder insertion hole 132 of the second end forming portion 130 and the remaining region 130a is vacant (see FIG. 8), the remaining region 130a. As a result, the squeeze bar SB is formed (see FIG. 11). Thereafter, the molten metal injection part 240 is separated and the squeeze cylinder 320 is advanced to press the squeeze bar SB (see FIG. 9) to cast the rotor R (see FIG. 10). In other words, after the squeeze bar is formed larger than the volume of the original rotor R, the compression compression generally generated by pressing the squeeze bar can be compensated, and the casting quality can be improved. Become.

  On the other hand, it has been found from many experimental results that it is preferable to push the squeeze bar SB by moving the squeeze cylinder 320 forward 0.05 seconds to 3 seconds after the formation of the squeeze bar SB. The squeeze bar SB is formed on the upper end ring C3 (see FIG. 9) of the rotor R, and can have a cylindrical shape having a height of 2 mm to 10 mm and a diameter of 1 mm to 15 mm from the upper end ring C3.

  And after performing the step which presses a squeeze bar, the take-out cylinder 330 advances and the take-out step which takes out the rotor R is performed. At this time, when the take-out cylinder 330 moves forward, after passing through the passage 212 of the vent valve 210 described above, the rotor R is pushed out so that the rotor R is detached from the mold body 110. It can be so.

With the rotor casting method of the present invention as described above, the filling rate of the molten metal can be improved and the casting quality can be easily improved.
Hereinafter, the case of casting by the present invention and the case of casting by the conventional casting method will be compared and described.

  FIG. 12 is a cross-sectional photograph of the upper end ring cast according to the prior art, and FIG. 13 is a cross-sectional photograph of the upper end ring cast according to the present invention. As shown in FIG. 12, it can be seen that the molten metal filling rate is about 79% due to air that cannot be discharged when cast by the prior art, and the structure is not dense, and pores are generated in some places. However, as shown in FIG. 13, when cast according to the present invention, the filling rate of the molten metal becomes about 98% and the structure becomes dense by venting the air inside the mold cavity prior to the injection of the molten metal. I understand that.

  What has been described above is merely an embodiment for carrying out a rotor casting apparatus having a slide control type vent function according to the present invention, a rotor using the same, and a casting method thereof. The present invention is not limited, and various modifications can be made by anyone having ordinary knowledge in the field to which the invention belongs without departing from the gist of the invention as claimed in the following claims. It can be said that there is a technical spirit of the present invention.

  The present invention can improve the casting quality of the rotor by controlling and venting the internal air of the mold cavity in a sliding manner prior to pouring the molten metal for casting the rotor. It is very useful for manufacturing the rotor of an AC induction motor used for the production.

Claims (12)

A mold assembly in which the core of the rotor is inserted and molten metal is injected, vent means for controlling and venting the internal air of the mold assembly in a sliding manner prior to pouring the molten metal into the mold assembly; and A rotor casting apparatus including a pressing part assembly that presses the molten metal filled in the mold assembly,
The mold assembly includes a hollow mold body into which the core is inserted, a first end forming part provided on one side of the mold body and used to form one side of the rotor; A second end forming portion provided on the other side of the mold body and used to form the other side of the rotor,
The vent means includes: a vacuum pump that discharges the internal air of the mold assembly to the outside; and the second end forming portion is selectively sealed to the other side of the mold body, and the interior of the mold assembly is A vent valve that selectively seals the communication line of the vacuum pump, a taper block that is in surface contact with a tapered surface formed on one side of the vent valve, and the vent is moved in a sliding manner by moving the taper block downward. A rotor casting apparatus having a slide control type vent function, comprising: an elevating member that moves the valve and seals the second end forming portion to the other side of the mold body through the vent valve . The pressing unit assembly includes a take-out cylinder that pushes out a rotor that has been cast and takes out, and a drive unit that drives the take-out cylinder,
The rotor casting apparatus with a slide control type vent function according to claim 1 , wherein the second end forming part includes a vent valve insertion hole into which a part of the vent valve is inserted. The vent valve has an outer diameter that fits into the vent valve insertion hole, extends out of the vent valve insertion hole, is in close contact with the other side of the core, and has an upper end ring of the rotor on the peripheral surface. The rotor casting apparatus having a slide control type vent function according to claim 2 , comprising a tapered portion that forms a constant space for forming and a passage into which the take-out cylinder can be inserted. The tapered block, characterized in that it comprises a tapered portion in the form corresponding to the tapered surface to surface contact with the tapered surface, and a coupling portion coupled to an end portion of the elevation member, according to claim 3 A rotor casting apparatus having a slide control type vent function described in 1. 5. The rotor casting apparatus according to claim 4 , wherein the elevating member includes an actuator that drives the taper block upward and downward, and a housing that houses the actuator. 6. 3. The slide control according to claim 2 , wherein the first end forming part has a constant space for forming a lower end ring of the rotor in a close contact part in close contact with one side surface of the core. Rotor casting machine with a vent function. 3. The slide control according to claim 2 , wherein the second end forming part has a fixed space for forming an upper end ring of the rotor in a close contact part in close contact with the other side surface of the core. Rotor casting machine with a vent function. The first end forming portion includes a sealing member that seals one end of the mold body, and an injection hole that penetrates the sealing member and allows molten metal to be injected into the mold body. The rotor casting apparatus having a slide control type vent function according to claim 2 , further comprising an exhaust hole. The pressing unit assembly further includes a plurality of squeeze cylinders that are driven by the driving unit and press to improve a filling rate of the upper end ring,
5. The rotor casting apparatus having a slide control type vent function according to claim 4 , wherein the second end forming part further includes a plurality of squeeze cylinder insertion holes into which the plurality of squeeze cylinders are inserted. . The vent valve further includes a flange formed with the tapered surface,
The rotor casting apparatus according to claim 9 , wherein the flange further includes a plurality of squeeze cylinder insertion holes into which the plurality of squeeze cylinders are inserted. The tapered portion of the tapered block is further formed with a long hole-shaped take-out cylinder through hole through which the take-out cylinder penetrates and a plurality of long-hole squeeze cylinder through holes through which the plurality of squeeze cylinders penetrate. The rotor casting apparatus having a slide control type vent function according to claim 9 , characterized in that the rotor casting apparatus has a slide control type vent function. A method of casting a rotor using a rotor casting apparatus having a slide control type vent function according to claim 2 ,
The internal air of the mold assembly is vented through the communication line of the vacuum pump and the interior of the mold assembly formed by separating the second end forming portion from the other side of the mold body at a predetermined interval. Stages,
Sealing the other side of the mold body to the second end forming part using the vent valve operated by the elevating member;
Casting the rotor by injecting and pressing molten metal into the mold assembly; and
And a step of moving the take-out cylinder forward to take out the rotor.