JPH10296423A - Low pressure casting die - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten the cycle time while the pressurization effect from a sprue is kept by naturally air cooling the periphery of a sprue of a lower die, indirectly water cooling its outer side, and indirectly water cooling the periphery of an upper die. SOLUTION: Though a lower die 7 and an upper die 8 are indirectly water cooled, the effect of the water is transmitted only by a contact surface 27 of a lower die block 24 with the lower die 7 and a contact surface 28 of an upper cooling block 25 with the upper die 8. The lower die 7 is tightened by bolts 12 to a lower die base 11 fixed to a lower die platen 16 of a casting machine by a clamp, etc. A cooling water passage 13 in which cooling water flows is provided on the lower die base 11. The water-cooling effect is also transmitted to the lower die 7 only through a contact surface 14 of the lower die base 11 with the lower die 7. Though the system is inferior in the cooling effect compared with the direct cooling, the directional solidification is not interfered and the uniformity of the temperature distribution of a die is kept, and a sound casting can be manufactured.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a low pressure casting mold used for casting a light alloy vehicle wheel by a low pressure casting method.

[0002]

2. Description of the Related Art In a low-pressure casting method generally used for casting a light alloy, a molten metal is laminar-flow-filled at a low speed into a cavity (mainly a combination of an upper mold, a lower mold, and a horizontal mold) formed in a mold. Entrapment of gas and generation of oxides are suppressed as much as possible in other casting methods. Therefore, it is widely used when manufacturing a cast product having high soundness. However, in order to produce a sound product by the low-pressure casting method, it is necessary to maintain the mold surface temperature to a certain high level in order to secure the flow of molten metal at the time of filling the molten metal. Therefore, it takes time for the mold temperature to drop to the product take-out temperature after solidification of the product is completed after filling the molten metal. Therefore, in order to shorten the casting cycle, the mold is actively cooled with air, water or the like after filling the molten metal.

[0003]

As shown in FIG. 5, most of light alloy vehicle wheels have a thick disk portion 4 which is attached to an axle by bolts and nuts, and a design portion in which thick and thin walls are mixed. 5, a thin rim 6 to which a tire is attached. Currently, from the viewpoint of improving the fuel efficiency of vehicles, weight reduction of wheels is required. In order to achieve this reduction in weight, the shape of the disc and rim cannot be changed drastically due to the attachment to the vehicle body and tires. Have been done. The method of changing the shape of the design portion is mainly to increase the number of openings and thin portions in the design portion, and the design portion has a complex shape in which openings, thin portions, and thick portions are mixed.

Normally, when a vehicle wheel is manufactured by low-pressure casting, a method is adopted in which a molten metal is injected from a disk portion 4 in a central portion, and the molten metal is filled in order to a design portion 5 and a rim portion 6. As a solidification form after filling the molten metal, directional solidification is performed in the rim portion, the design portion, and the disk portion in order in order to sufficiently exert the feeder effect of the gate. As described above, under the current situation where the shape of the design part in which the thick part and the thin part are mixed is complicated, it is very difficult to achieve the directional solidification from the rim part toward the gate.

When water cooling of a mold is introduced for the purpose of shortening the casting cycle, there is a high-temperature holding furnace for holding the molten metal below the lower mold, and it is difficult to cool naturally. A method of providing a cooling path or embedding a chill provided with a water cooling path in a lower mold has been proposed. However, as described above, there is a thin portion in the design part that is in contact with the lower mold, and when water cooling of the lower mold is performed,
In some cases, the solidification of the design part was completed significantly earlier than the thick disk part on the gate side. If there is a solidified portion that breaks the balance of the directional solidification toward the gate, the effect of pressurizing from the gate becomes insufficient and casting defects occur. Therefore, when water cooling is introduced into the lower mold by a conventional method, casting defects may be induced.

In order to solve the above-mentioned problems, the present inventors fill a cavity of a light alloy vehicle wheel composed of an upper die, a lower die and a horizontal die with a molten metal from near the center of the lower die. It has been proposed that a lower die base and a lower die platen, in which the lower die is cooled by a cooling medium, be fastened to an outer peripheral portion of a die used in a low-pressure casting method (see Japanese Patent Application No. 8-71838). According to this mold structure, it is possible to significantly reduce the cycle time (0.5 to 1.0 minutes) as compared with the related art without obstructing the directional solidification toward the gate.

Here, the cycle time is further reduced to 0.5 to
In order to shorten the time by 1.0 minute, in addition to cooling the lower mold from the outer periphery, it is necessary to strengthen the cooling portion around the gate and quickly complete the solidification of the gate as the final solidification portion. . However, since the gate in low-pressure casting also plays the role of a feeder as a heat source, if the gate is cooled excessively, the directional solidification balance will be lost, and the pressing effect of the gate will be insufficient, and casting defects will occur. Occurs.

In order to shorten the cycle time, the means for cooling the vicinity of the lower mold gate includes, for example, (1) providing a water cooling path directly near the lower mold gate (see, for example, Japanese Patent Application Laid-Open No. Hei 5-269563). (See FIG. 2), (2) Contacting a water cooling block near the lower mold gate (for example, see FIG. 1 of JP-A-4-274859) has been proposed. However, these methods have the following problems. First, according to the method (1), solidification of the gate is reliably promoted, and the cycle time can be reduced. However, in this method, it is extremely difficult to find conditions under which cooling is likely to be excessive and directional solidification can be maintained.
If the amount of cooling water is reduced, the cooling water evaporates, making it difficult to control the amount of water. Further, the inlet side of the water cooling path tends to be cooled more than the outlet side, and the temperature balance in the circumferential direction of the lower mold is lost, and casting defects are likely to occur. If a crack occurs in the lower mold, there is a danger that water will leak from the water cooling path and enter the cavity. Next, according to the method (2), since the lower mold is indirectly cooled, the temperature gradient becomes gentler than in the method (1), and the directional solidification toward the gate is not hindered. However, since the cooling is indirectly performed, a change in the cooling capacity with respect to the cooling conditions (cooling water amount, cooling time, etc.) is remarkable, so that it is not possible to cope with a case where the length of the gate needs to be strictly adjusted as in the case of two-piece casting.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a mold for manufacturing a vehicle wheel made of a light alloy by low pressure casting while maintaining a pressing effect from a gate. An object of the present invention is to provide a low-pressure casting mold that can reduce cycle time and can cope not only with one-piece casting but also with two-piece casting.

[0010]

Means for Solving the Problems The present inventors have conducted intensive studies on the heat flow of a low-pressure casting mold in order to solve the above problems. As a result, air cooling around the lower mold gate, indirectly water cooling the outside, and indirectly water cooling around the upper mold gate, the temperature gradient of the lower mold due to cooling becomes gentler, The present inventors have found that there is no inhibition of directional solidification toward a gate, and have arrived at the present invention. That is, the present invention provides a low-pressure casting mold used in a low-pressure casting method for filling a molten metal from near the center of a lower mold into a vehicle wheel cavity configured by an upper mold, a lower mold, and a horizontal mold, It has a first cooling means for air-cooling the periphery of the gate, a second cooling means for indirectly water-cooling the outside thereof, and a third cooling means for indirectly water-cooling the periphery of the upper mold. It is characterized by the following. In the present invention,
Preferably, the first cooling means and the second cooling means are incorporated in a lower cooling block, and the third cooling means is incorporated in an upper cooling block. In the present invention, it is preferable that the lower mold block and the upper mold block contact only the lower mold and the upper mold, respectively, and only a part of the vicinity of the gate.

In the present invention, the lower mold and the upper mold have a water cooling path, and the lower mold and the upper mold are brought into contact with only a part of the cooling block and the upper mold cooling block so that the lower mold and the upper mold are indirectly cooled with water from the outer periphery. Thus, the casting cycle can be shortened while promoting directional solidification toward the gate. That is, when cooling the normal mold, a method of directly cooling a portion having a high temperature, that is, in the case of such a lower mold, directly near a central gate portion is employed. However, such cooling not only hinders directional solidification, but also makes the temperature distribution in the lower mold non-uniform, which may cause casting defects. On the other hand, in the present invention, the vicinity of the sprue is air-cooled, and the outside thereof is indirectly water-cooled, so that it is inferior to direct cooling in terms of cooling efficiency, but does not hinder directional solidification, Furthermore, since the uniformity of the temperature distribution of the mold is maintained, a sound casting can be manufactured. Also, the area of the portion where the outer periphery of the lower mold (upper mold) and the lower mold (upper mold) contact can be adjusted in a wide range, so that the cooling amount can be controlled in a wide range in proportion to the contact area. . In addition, the lower mold, the lower mold base and the lower mold platen are fastened with bolts, so that the lower mold, the lower mold base and the lower mold platen can be easily removed, and they are sufficiently adhered to improve thermal conductivity. You can also.

[0012] Among the lower mold parts that contact the design surface facing outward when mounted on a vehicle, a lower mold base or a lower mold platen provided with a water cooling path is provided for each lower mold having various designs. It is common to the above, and it is possible to deal with vehicle wheels of different designs by replacing only the lower mold. Therefore, there is no need to provide a water cooling path in the lower mold for each item or to embed a chill having a water cooling path, so that the cost of the mold can be reduced. In addition, a heat insulating material with high compressive strength is inserted between the upper mold and the mold component parts, and the heat insulation effect is increased by tightening bolts, and the amount of heat flowing from the upper mold to the upper mold platen is suppressed, so that it is farthest from the gate. The upper mold surface temperature in contact with the tip of the thin rim can be prevented from lowering, so that defects can be prevented from occurring at the tip of the rim.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred mold structure of a vehicle wheel according to the present invention will be described below with reference to the drawings. FIG.
1 is a sectional view of a mold according to an embodiment of the present invention. In FIG. 1, a cavity A has a lower mold 7 having various surface shapes determined by wheel design, an upper mold 8 above the lower mold 7, and a left and right slide arranged to fit the lower mold 7 and the upper mold 8. It is basically configured by moving horizontal dies 9 and 10. The molten metal stored in the holding furnace 1 is pressurized by the pressurized gas, so as to rise up the stalk 2 and the gate insert 3 and fill the cavity A. The cavity A is composed of a thick disk portion 4, a thin and thick mixed design portion 5, and a thin rim portion 6 in this order from the gate side. The design portion of the wheel facing outward when mounted on the vehicle has various shapes, and these are formed by the lower mold 7.

A lower mold cooling block 20 is mounted on the lower mold 7 by bolts (not shown). A cooling water path 21 extending along the circumferential direction is provided in the lower cooling block 20.
And an air introduction path 22 and an air exhaust path 23 that communicate with a groove 24 formed around the gate. An upper die cooling block 25 having a cooling water path 26 formed along the circumferential direction is mounted on the upper die 8.

According to this mold structure, the lower mold 7 and the upper mold 8
Is indirectly water-cooled, but the effect of water cooling is conducted only by the contact surface 27 with the lower mold block 24 of the lower mold 7 and the contact surface 28 with the upper mold block 25 of the upper mold 8.

The lower die 7 is provided with a lower platen 16 of a casting machine.
It is fastened by bolts 12 to a lower mold base 11 fixed thereon by a clamp (not shown) or the like. The lower mold base 11 is provided with a cooling water path 13 through which cooling water flows. This water cooling effect is also transmitted to the lower mold 7 only through the contact surface 14 between the lower mold 7 and the lower mold base 11 by bolting. A gap 15 is provided between the side surface of the lower mold 7 and the lower mold base 11.
There is no heat conduction from here. Therefore, the cooling amount can be controlled by arbitrarily changing the area of the contact surface 14 between the lower die 7 and the lower die base 11.

Next, in the above-mentioned mold structure, in the case where the vicinity of the gate is indirectly water-cooled for the purpose of shortening the cycle time, conditions under which the cooling can be enhanced while maintaining directional solidification are shown in FIG. 1 is the same as the mold structure). In FIG. 2, the area (X ₁ ) to be air-cooled by the lower mold cooling block 20 is within a radius R ₁ , and the area (X ₂ ) to be water-cooled by the cooling block 20 is a radius R ₂ and a radius R _1.
(R ₂ −R ₁ ). In the same figure,
The region (X ₃ ) to be water-cooled by the upper die cooling block 25 is a region (R ₄ −R ₃ ) between the radius R ₄ and the radius R ₃ . As a result of performing a casting experiment using R _{1 to} R ₄ as parameters, the region X ₁ to be air-cooled by the lower mold cooling block is set to 0 to 0.
60 mm, the area X ₂ to be water-cooled by the block is 60 to 100 mm, and the area X ₃ to be water-cooled by the upper mold cooling block is in the range of 70 to 100 mm, so that both directional solidification and enhanced cooling can be achieved. Was confirmed.

FIG. 3 and FIG. 4 show examples in which the temperature distribution on the surface of the lower mold is measured along the radial direction and the circumferential direction in this embodiment and the conventional example in which a water cooling path is directly provided near the lower mold gate. FIG.
From this, it can be seen that the present embodiment has a temperature gradient toward the gate on the mold surface without excessive cooling of the gate, as compared with the conventional example, and directional solidification is maintained. From FIG.
According to the present invention, it can be understood that a substantially uniform temperature distribution can be obtained along the circumferential direction regardless of the positions of the inlet and the outlet of the cooling water.

[0019]

According to the present invention, when manufacturing a light alloy vehicle wheel by low pressure casting, the cycle time can be greatly reduced without the occurrence of casting defects.

[Brief description of the drawings]

FIG. 1 is a sectional view of a vehicle wheel mold according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a vehicle wheel mold for explaining the positional relationship between the mold and the cooling means of the present invention.

FIG. 3 is a diagram illustrating a temperature distribution in a radial direction of a lower mold of a vehicle wheel mold.

FIG. 4 is a diagram illustrating a surface temperature distribution in a circumferential direction of a lower mold of a vehicle wheel mold.

FIG. 5 is a sectional view of a vehicle wheel.

[Explanation of symbols]

1 holding furnace, 4 disk section, 5 design section,
6 rim, 7 lower die, 8 upper die, 9, 10 horizontal type, 11 lower die base, 13 cooling water path, 14 contact surface, 16 lower die platen, 17 upper die base, 1
8 Insulation material, 20 Lower mold block 25 Upper mold block

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Ryoji Iijima 5200, Sankeijiri, Kumagaya-shi, Saitama Prefecture Inside the Kumagaya Plant, Hitachi Metals Co., Ltd. 72) Inventor Togen Tamura 5200 Mikajiri, Kumagaya City, Saitama Prefecture Inside the Kumagaya Plant of Hitachi Metals, Ltd.

Claims (3)

[Claims] 1. A low-pressure casting mold used for a low-pressure casting method for filling a molten metal into a light alloy vehicle wheel cavity constituted by an upper mold, a lower mold, and a horizontal mold from near the center of the lower mold. A first cooling means for air cooling around the lower mold gate, a second cooling means for indirectly water cooling the outside of the lower mold gate, and a third cooling means for indirectly water cooling the periphery of the upper mold gate. A low-pressure casting mold having cooling means. 2. The cooling device according to claim 1, wherein the first cooling means and the second cooling means are incorporated in a lower cooling block, and the third cooling means is incorporated in an upper cooling block. Low pressure casting mold. 3. The low-pressure casting mold according to claim 2, wherein the lower mold cooling block and the upper mold cooling block are in contact with only the vicinity of the lower and upper mold gates, respectively.