METAL MOLDED BODY MANUFACTURING APPARATUS BY ELECTROMAGNETIC STIRRING

Abstract

There is provided a metal molded body manufacturing apparatus for electromagnetically stirring metallic molten metal and molding a metal molded body. The metal molded body manufacturing apparatus includes: a die having an inclined side wall; and a moving magnetic field generation section that stirs the molten metal in the die, wherein the moving magnetic field generation section includes a magnetic body, and a coil wound around the magnetic body as a center, and an end surface of the magnetic body is disposed in parallel to an inner surface of the side wall.

Claims

1. A metal molded body manufacturing apparatus for electromagnetically stirring metallic molten metal and molding a metal molded body, the metal molded body manufacturing apparatus comprising: a die including a side wall having an inclined inner surface; and a moving magnetic field generation section that is disposed along an outer periphery of the die, and stirs the molten metal in the die, wherein the moving magnetic field generation section includes a magnetic body, and a coil wound around the magnetic body as a center, and an end surface of the magnetic body is disposed such that a gap between the end surface of the magnetic body and the inner surface of the side wall becomes uniform.

2. The metal molded body manufacturing apparatus according to claim 1, wherein an inclination of the side wall serves as a draft angle for extracting the metal molded body.

3. The metal molded body manufacturing apparatus according to claim 2, wherein the draft angle is 1 to 9.

4. The metal molded body manufacturing apparatus according to claim 1, wherein the side wall has a pair of facing walls that face each other, the moving magnetic field generation section is provided along each of the facing walls, and the moving magnetic field generation sections generate respective moving magnetic fields in reverse directions from each other so as to generate a vortex in the molten metal.

5. The metal molded body manufacturing apparatus according to claim 1, further comprising: an inclined plate to which a base, and the moving magnetic field generation section are fixed; and an inclination adjusting mechanism that adjusts an inclination of the inclined plate to the base so as to uniform the gap between the end surface of the magnetic body and the inner surface of the side wall, the inclination adjusting mechanism being disposed between the inclined plate and the base.

6. The metal molded body manufacturing apparatus according to claim 1, wherein the end surface of the magnetic body of the moving magnetic field generation section extends beyond an upper surface of the molten metal put into the die from below a bottom of the die.

7. The metal molded body manufacturing apparatus according to claim 1, wherein the die has a curved shape in plan view, an additional magnetic body member is provided in the end surface of the magnetic body of the moving magnetic field generation section, and an end surface of the additional magnetic body member is a curved surface along a curved inner surface of the die.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] FIG. 1A is a sectional view illustrating a metal molded body manufacturing apparatus according to an embodiment of the present invention, and FIG. 1B is a sectional view illustrating an example for comparison with the apparatus of FIG. 1A.

[0034] FIG. 2A is a plan view illustrating of a die according to the embodiment, and FIG. 2B is a sectional view taken along a A-A of the die of FIG. 2A.

[0035] FIG. 3 is a schematic plan view illustrating moving magnetic field generation sections and the die.

[0036] FIG. 4A and FIG. 4B each are a schematic view illustrating a state where a coil is wound around a core back.

[0037] FIG. 5A and FIG. 5B each are a schematic view illustrating a state where the coil is wound between slots.

[0038] FIG. 6 is a side view illustrating a metal molded body manufacturing apparatus according to another embodiment.

[0039] FIG. 7A is a front view illustrating a moving magnetic field generation section according the other embodiment and FIG. 7B is a bottom view of the moving magnetic field generation section of FIG. 7A.

[0040] FIG. 8 is a plan view illustrating a manufacturing apparatus according to yet another embodiment.

[0041] FIG. 9A is a plan view illustrating a state where an additional magnetic body is detached from the moving magnetic field generation section of FIG. 8, and FIG. 9B is a plan view of an additional magnetic body member of FIG. 8, and FIG. 9C is a plan view illustrating an additional magnetic body member according to another embodiment.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

First Embodiment

1. Summary

[0042] A manufacturing apparatus for a metal molded body of the present invention (hereinafter simply referred to as a manufacturing apparatus) will be described with reference to FIG. 1. A manufacturing apparatus 1 illustrated in FIG. 1 is an apparatus that stirs molten metal, which is put into a die 2, by moving magnetic field generation sections 3, and molds a metal molded body in the die.

[0043] The metal molded body manufactured by this manufacturing apparatus 1 is subjected to machining for making a press-formed or press-molded article by, for example, a press apparatus (not illustrated) in a next process, or is used as a final molded body without change.

2. Manufacturing Apparatus 1

[0044] More specifically, the manufacturing apparatus 1 includes the die 2 having a side wall 5 having an inclined inner surface, and a moving magnetic field generation section 3 that stirs the molten metal in the die 2. An end surface 3a of a magnetic body of the moving magnetic field generation section 3 is disposed such that a gap G (refer to FIG. 1A) with an inner surface 5c of the side wall (hereinafter referred to as an inner wall surface) becomes uniform. The end surface 3a and the inner wall surface 5c are parallel or substantially parallel to each other.

(As to Die 2)

[0045] The die 2 is preferably formed of, for example, a material having low magnetic permeability and a higher melting point than that of the molten metal which is metal put into the die. In this embodiment, stainless steel is used.

[0046] The die 2 (refer to FIG. 2B) has a bottom 4, and a side wall 5 extending upward from a peripheral edge of the bottom 4. The side wall 5 inclines outward toward an opening side so as to extract the metal molded body. The thickness of the side wall 5 is generally uniform, but may not be uniform. In a case where the thickness is not uniform, at least the inner surface only needs to incline outward toward the opening side. The angle of the inclination only needs to be a draft angle for extracting the metal molded body to an axis of the die 2 (an axis perpendicular to a surface of the bottom, or a vertical axis). For example, the draft angle is 1 to 9, and preferably 5 to 7.

(Shape of Die)

[0047] As illustrated in FIG. 2A, in this embodiment, the die 2 has, for example, a long oval shape or an athletics track shape in plan view. That is, the side wall 5 of the die 2 includes a pair of facing walls 5a, 5a facing each other. Respective both ends of the straight facing walls 5a, 5a are connected to the semicircular sections 5b, 5b, so that the above long oval shape or athletics track shape is formed.

[0048] FIG. 2B illustrates a sectional view of FIG. 2A. The side wall 5 inclines so as to expand toward the opening side. In this embodiment, the bottom 4 is flattened.

(Molten Metal)

[0049] The molten metal which is put into the die 2 is metal such as aluminum alloy that is melted.

(Moving Magnetic Field Generation Section 3)

[0050] Returning to FIG. 1A, the moving magnetic field generation sections 3 each include, for example, a magnetic body 6 (hereinafter referred to as a core), and coils 7 wound around the core 6 as a center. As illustrated in FIG. 1A, the moving magnetic field generation sections 3, 3 (refer to two-dot chain lines of FIG. 2A) are disposed such that the end surfaces of the cores 6 are parallel to the inner surfaces of the facing walls 5a, 5a of the side wall and there is clearances between the end surfaces of the core 6 and the outer surfaces of the side wall.

[0051] The end surfaces of the cores 6 of the moving magnetic field generation sections 3 each extend from a position below the bottom 4 of the die 2 to a position above an upper surface of the molten metal put into the die. Therefore, it is possible to reliably move the whole of the molten metal.

(Magnetic Bodies 6 and Coils 7)

[0052] Returning to FIG. 1A, the magnetic bodies 6 and the coils 7 are conventionally known ones. For example, each magnetic body 6 employs, for example, a silicon steel sheet, and is formed by stacking thin sheets because of reduction in influence of an eddy current or the like.

[0053] In each magnetic body 6, a plurality of slots 8 are formed on the side wall side of the die 2 at equal intervals (refer to FIG. 4A). Each slot 8 has a coil 7 wound therearound.

(Principle and the Like)

[0054] FIG. 3 schematically illustrates the manufacturing apparatus 1. In the figure, the three moving magnetic field generation sections 3 are lined to be connected on one side of the die 2. A power source is a three-phase alternating current (AC). Three-phase ACs U, W, V are sequentially applied to coils of terminal symbols R, S, T. Then, a magnetic field (direction of an arrow H) that moves in parallel to the facing wall 5a of the side wall 5 is generated in the die 2. Specifically, a +U-phase current, a W-phase current, a +V-phase current, a U-phase current, a +W-phase current, and a V-phase current are applied to the respective coils 7 illustrated in FIG. 3 in this order from the left of the figure. In these three-phase ACs, phases of the +U-phase, the +V-phase, and the +W-phase are AC currents shifted by 120 in order, and currents of the V-phase, the W-phase, and the U-phase are opposite directions. As to the current flow direction, it is defined that the flow direction from the front to the back of the paper sheet is positive. When a current flows in the positive direction, a clockwise magnetic flux with the coil as the center generates, and when a current flows in the reverse direction, a counterclockwise magnetic flux generates. The magnitude of the magnetic flux density increases as a current value of the coil increases.

[0055] Accordingly, when a current is applied to the coil, a combined magnetic flux density distribution moves from the left to the right (see an arrow ) with lapse of time. That is, a moving magnetic field that moves from the left to the right along the longitudinal direction of the core 6 is formed. Consequently, an induced current is generated in the molten metal, and an electromagnetic force (Lorentz force) is generated in the molten metal. Then, driving force (refer to arrows H1, H2, H3) that provides flows to follow the motion of the moving magnetic field is applied in the molten metal.

[0056] Symbol O denotes a neutral point.

[0057] FIG. 4A is a plan view of the moving magnetic field generation section 3 of FIG. 1A. A winding method illustrated in the figure is a core back winding method. The cores 6 of the moving magnetic field generation sections 3 each are formed in a comb-tooth shape, and the coils 7 are wound between the teeth of each core (the above slots 8).

[0058] The slots are filled with the coils (coil conductors) 7. Each core 6 is composed of a rectangular column shaped yoke (core back) 6a, and teeth 9 each having an end fixed to dovetail-shaped grooves 6b formed in the yoke. The number of the teeth 9 is seven, the number of the coils 7 to be wound around the yoke between the teeth is six, and all the coils are wound in the same direction. Therefore, in a case where a current enters from an initially wound coil, and a case where a current enters from a finally wound coil, the polarities are reverse. Each slit 8a that is opened toward the die 2 is formed between the adjacent teeth 9, 9. The yoke 6a and the teeth 9 are each formed of a core formed by superimposing a large number of thin sheets of silicon steel sheets, and these may be integrated.

[0059] In the moving magnetic field generation section 3, as a minimum unit for smoothly generating a moving magnetic field by a three-phase power supply, the six slots 8 are used as the minimum unit. In a case where the further reduced number of the slots is used as the minimum unit, balance is kept by mutual magnetic coupling.

[0060] FIG. 5A illustrates a moving magnetic field generation section 3 according to another embodiment. A winding method illustrated in the figure is an inter-slot winding method. A U-phase coil passes through a leftmost slot and a fourth slot so that the coil is wound around three teeth between the leftmost slot and the fourth slot. Similarly, a V-phase coil passes through a second slot and a fifth slot so that the coil is wound around three teeth between the second slot and the fifth slot. A W-phase coil passes through a third slot and a sixth slot so that the coil is wound around three teeth between the third slot and the sixth slot. These three kinds of coils are overlapped to intersect with each other on the lateral side of the core 6, as illustrated in FIG. 5B.

[0061] In this method, the coils 7 do not wound around a core back 6a, and therefore the core back 6a can be used to fix the moving magnetic field generation section 3.

Conclusion

[0062] Returning to FIG. 1A, the moving magnetic field generation sections 3 are disposed such that the end surfaces of the cores 6 are parallel to the inner surface of the side walls inclining at draft angle. Therefore, a difference in thrust in the vertical direction of the side walls is unlikely to be generated. That is, the whole of a material along the wall surfaces flows, and therefore stirring efficiency is high, growth of crystals is prevented. As illustrated in FIG. 2A, a pair of the moving magnetic field generation sections 3, 3 generate moving magnetic fields in the reverse directions from each other so as to generate a vortex in the molten metal, and therefore stirring efficiency is high.

Second Embodiment

3. Another Embodiment

[0063] Now, FIG. 6 illustrates a manufacturing apparatus according to another embodiment. The manufacturing apparatus 10 includes a base 11 installed on a floor surface of a building such as a factory, and inclined plates 12, which are provided in the base 11, and to which the moving magnetic field generation sections 3 are fixed. The two inclined plates are used as one set, and are provided with the respective moving magnetic field generation sections 3. These inclined plates 12, 12 are disposed so as to face each other. In the base 11, inclination adjusting mechanisms 13 that adjust the inclination of the inclined plates 12 are provided.

(Base 11, Inclined Plates 12, Inclination Adjusting Mechanisms 13)

[0064] The base 11 includes a base plate 11a installed on the floor surface, a placing stand 11b that is erected from the vicinity of a center of the base plate 11a, and allows a die 2 to be placed on an upper surface thereof, and a pair of supporting sections 11c, 11c erected from the base with the placing stand 11b therebetween.

[0065] The inclined plates 12 each are a flat plate shape, and formed of metal such as stainless steel. Each inclined plate is rockingly pivoted to the vicinity of an upper end of the supporting section 11c. A shaft of the rocking is a shaft 12a parallel to a longitudinal axis of the die 2.

[0066] The inclination adjusting mechanisms 13 each include a screw mechanism 13a. The screw mechanism 13a is disposed below the shaft 12a. In the screw mechanism 13a, a male screw member is screwed in the female screw member provided in the supporting section 11c toward the inclined plate 12, so that a lower part of the inclined plate 12 is pressed, and the inclined plate 12 is rotated about the shaft 12a as a rotation center.

[0067] In each inclination adjusting mechanism 13, the moving magnetic field generation section 3 can be disposed such that an end surface of the core 6 is parallel to an inner surface 5c of the side wall by changing the inclination of the inclined plate 12. Therefore, a difference in thrust is unlikely to be generated in molten metal in the vertical direction of the side wall. The whole of the material along the wall surfaces flows, and therefore growth of metal crystals is prevented, and minute metal molded body is formed.

[0068] In the manufacturing apparatus 10, moving mechanisms 14 that allow the supporting sections 11c to be freely movable to the bases plate 11a may be provided. As the moving mechanism 14 (two-dot chain lines), conventionally known mechanisms such as slide mechanisms can be used. By use of the moving mechanisms 14, the inclined plates 12 are brought closer to or away from the side wall 5, that is, are moved with parallel translation to adjust the gaps.

[0069] As the manufacturing apparatus 10, both the moving mechanisms 14 and the inclination adjusting mechanisms 13 are preferably provided.

(Transposing Mechanism of Laminar Flow)

[0070] For example, as illustrated in FIG. 7A and FIG. 7B, a moving magnetic field generation section 15 that generates a inclined vertical flow P can be used. In this case, the inclined vertical flow is generated in molten metal, and molten metal in upper and lower layers in a die is transposed. Consequently, residual gas venting is facilitated, more efficient stirring is attained, and therefore it is possible to make crystal grains fine.

[0071] More specifically, in the moving magnetic field generation section 15, slits 8b obtained by inclining (skewing) two central slits in the advancing direction from a bottom to a top are formed. Consequently, coil end portions are the same appearance as a general coil end, and therefore there is no waste in assembling appearance.

[0072] As the shape of the bottom of the die 2, a hemispherical bottom for smoothly reversing a downward flow of axially moving molten metal 1 to an upward flow is preferably provided (not illustrated). Reference numeral 8c in FIG. 7B denotes a wedge or plate for holding the coil 7 in the slot 8.

Third Embodiment

[0073] FIG. 8 illustrates a manufacturing apparatus according to another embodiment. This embodiment includes a large number of parts which are the same as the parts described in the above embodiments, and therefore the same parts are denoted by the same reference numerals, and description thereof will be omitted.

[0074] A manufacturing apparatus 16 illustrated in FIG. 8 includes a die 17 having an inverted T-shape in plan view, and a plurality of pairs of the moving magnetic field generation sections 3 disposed along a wall surface of the die so as to sandwich the die 17.

[0075] Near a root of the T shape of the die 17, curved side walls 17a having curved inner surfaces are provided. In this embodiment, moving magnetic field generation sections 18 having curved surfaces parallel to the curved inner surfaces are provided so as to face the curved inner surfaces of the curved side walls 17a in order to maintain uniform gaps. Additional magnetic body members 19 are provided on end surfaces of cores 7 of the moving magnetic field generation sections 18. End surfaces 19a of the additional magnetic body members are curved surfaces along the curved side walls 17a of the die 17. The additional magnetic body members 19 are mounted on teeth 9 of cores 6 that generate magnetic fields, are designed so as to be parallel to the inner surfaces of the curved side walls 17a by magnetically extending the teeth 9.

[0076] A moving magnetic generation section of this embodiment includes twelve moving magnetic field generation sections 3 provided on liner parts, and the two moving magnetic field generation sections 18 provided at corners. Thus, the moving magnetic field generation section is divided, and two kinds of the moving magnetic field generation sections are further combined and disposed, so that it is possible to correspond to various shaped of dies. Consequently, it is possible to uniformly stir molten metal in various shaped dies (refer to arrows in the figure).

[0077] Now, details of the curved moving magnetic field generation sections 18 will be described with reference to FIG. 9A and FIG. 9B. FIG. 9A illustrates a state where an additional magnetic body member 19 is detached from the moving magnetic field generation section 18 of FIG. 8. Insertion ports 18a are formed in distal end surfaces (surfaces facing the side wall of the die) of the teeth 9 of the moving magnetic field generation section in FIG. 9A. On the other hand, as illustrated in FIG. 9B, insertion sections 19b that slide to be inserted into the insertion ports 18a are formed in proximal end surfaces of the additional magnetic body member 19. The additional magnetic body member 19 is freely engaged and disengaged by sliding. Therefore, an additional magnetic body member in accordance with a curved shape of a die only needs to be prepared with respect to the single moving magnetic field generation sections 18 as a base, and therefore this configuration is economical.

[0078] FIG. 9C illustrates an additional magnetic body member 20 having a recessed curved surface.

[0079] The additional magnetic body member may be curved in the height direction (not illustrated).

4. Modification

[0080] As a material of the die 2, metal having heat resistance withstanding of the high temperature of molten metal, and having magnetic permeability (for example, stainless steel), ceramics, and the like can be used.

[0081] The die may have a shape such as an arc shape or a forked shape in plan view.

[0082] The upper part of the die 2 is opened in this embodiment, but may be closed by an openable lid. In this case, the lid is opened, and molten metal is put into the die or extracted a metal molded body.