JP2011147960A - Apparatus and method for reduced pressure casting - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus and method for reduced pressure casting, wherein, in an effort to ensure a good casting quality and to prevent the intrusion of a release agent, a coolant, and the like into a cavity through a gap between a push-out pin for pushing a cast product out of a casting mold and a through-hole provided for the push-out pin and formed in the casting mold, the push-out pin itself is abolished, while the cast product is still reliably demolded from the casting mold with no risk of being damaged. <P>SOLUTION: The reduced pressure casting apparatus 1 is provided for casting the cast product 20A by depressurizing the cavity 24 of the casting mold 2 composed of a group of a plurality of divided molds. A plurality of inserts 33, 34, 35 protruding into the cavity 24 from the side surface of the cavity 24 are provided in a mold part (movable mold 22) which is one of the plurality of molds 21, 22, 23, ..., wherein the inserts 33, 34, 35 are arranged movable back and forth with respect to the cavity 24. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a technique for reducing the amount of water flowing into a cavity in order to ensure good casting quality in a vacuum casting apparatus and a vacuum casting method for casting under reduced pressure in the cavity.

Conventionally, a part (cast product) having a complicated shape such as a cylinder block which is one of engine parts has been molded by casting (see, for example, “Patent Document 1”). .
In recent years, in order to improve the quality of casting products (casting quality), the reduced pressure casting method is aimed at reducing defects such as entrapment cavities by reducing the pressure inside the cavity before pouring molten metal into the cavity. Casting is also performed.

  The reduced pressure casting apparatus for casting a cast product by the reduced pressure casting method mainly includes a casting mold composed of a plurality of divided mold parts, a nested unit installed in a cavity of the casting mold, 1 includes an extrusion unit for extruding a cast product from the nesting unit, a decompression means for decompressing the inside of the cavity of the casting mold, and the like.

Here, as an example of a vacuum casting apparatus using such a vacuum casting method, a configuration of a conventional vacuum casting apparatus 201 for casting a cylinder block will be described with reference to FIG.
FIG. 6 is a side cross-sectional view showing an overall configuration of a conventional vacuum casting apparatus 201.
In the following description, for convenience, the direction of arrow A in FIG. In FIG. 6, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 201 and will be described below.

The vacuum casting apparatus 201 is mainly composed of a casting mold 202, a nesting unit 203, an extrusion unit 204, and the like.
The casting mold 202 is divided into a plurality of molds such as a fixed mold 221, a movable mold 222, a slide mold 223, 223, etc., and the fixed mold 221 is used as a reference. A movable mold 222 is disposed behind the mold 221, and slide molds 223, 223,... Are disposed radially between the fixed mold 221 and the movable mold 222 in a front view.

  These mold groups 221, 222, 223, 223... Are moved in the front-rear direction (the direction in which the fixed mold 221 and the movable mold 222 are closely spaced) with respect to the fixed mold 221. The slide molds 223, 223,... Are configured to be movable in a direction perpendicular to the moving direction of the movable mold 222 and radially in front view around the center of the fixed mold 221. The

A nesting unit 203 is provided at the center of the movable mold 222 in front view.
The nesting unit 203 includes a plurality of bore pin nestings 233, 233 (only one is shown in FIG. 6) arranged in the left-right direction (horizontal direction and a direction orthogonal to the moving direction of the movable mold 222). The water jacket insert 234 is disposed so as to surround the entire periphery of the bore pin inserts 233, 233, and a plurality of core pins 235 disposed in the vicinity of the outer periphery of the water jacket insert 234. ... 235 (only one is shown in FIG. 6).

  The bore pin inserts 233, 233..., The water jacket inserts 234, and the cast pins 235, 235... Constituting the insert unit 203 extend so as to extend forward. Each is arranged in the central part in front view.

  On the other hand, a concave portion 222a having a substantially rectangular parallelepiped shape is formed in the central portion of the movable die 222 as viewed from the back, extending from the rear surface to the vicinity of the front surface of the movable die 222 with the longitudinal direction of the substantially rectangular parallelepiped shape directed in the horizontal direction. In the front end surface 222b of the recess 222a, a plurality of first through holes 222c, 222c,... And second through holes 222d, 222d,.

  The extrusion unit 204 is housed in the movable mold 222 and slides in the front-rear direction through the recess 222a and the first and second through holes 222c, 222c,. Provided possible.

  That is, the extrusion unit 204 includes an extrusion plate 204a made of a substantially rectangular plate-shaped member, and a plurality of extrusion pins 204b, 204b,. It comprises pins 204c, 204c, etc.

  The push-out unit 204 has the push-out pins 204b, 204b,... And the return pins 204c, 204c,... Through the first and second through holes 222c, 222c,. The front end of the hydraulic cylinder rod 226 is fastened to a fastening member (such as a bolt) on the rear surface of the push plate 204a. It is detachably fixed via a not-shown).

  Then, by extending the rod 226 of the hydraulic cylinder forward, the push plate 204a slides forward in the recess 222a of the movable mold 222, and these push pins 204b, 204b,. The return pins 204c, 204c... Are pushed all at once toward the front.

The extrusion pins 204b, 204b... Are portions for extruding the cast product from the nesting unit 203 when the cast product is removed.
In addition, the return pins 204c, 204c,... Are not fully slid rearward after the cast product is removed, and the front ends of the push pins 204b, 204b,. When protruding from the front surface of the mold 222, for example, when the mold is closed, the entire extrusion unit 204 is forcibly pushed backward by interfering with other parts such as the rear surfaces of the slide molds 223, 223. It is a part for.

A first continuous passage 222e is formed inside the movable mold 222, and the first continuous passage 222e is connected to the first piping member 205 guided from the outside of the casting mold 202 at one end, The other end communicates with the cavity 224.
The first piping member 205 is connected to the first continuous passage 222e at one end, and is connected to the vacuum pump 207, which is a decompression unit, at the other end.
Then, by controlling the operation of the vacuum pump 207, the pressure in the cavity 224 is reduced.

In order to cast a cast product by the reduced pressure casting apparatus 201 having such a configuration, first, a release agent is applied to the side surfaces facing the cavity 224 in the fixed mold 221 and the slide molds 223, 223. Thereafter, the casting mold 202 is “closed”.
Further, in accordance with the “mold closing” of the casting mold 202, the extruding unit 204 is slid rearward so that the extruding pins 204b, 204b... And the return pins 204c, 204c. Store inside.

  When the “mold closing” of the casting mold 202 is completed, the cavity 224 is decompressed by the vacuum pump 207 to fill the cavity 224 with the molten metal, and then the casting mold is gradually cooled with cooling water. By doing so, the cast product is cast.

When the molding of the cast product is completed, the vacuum pump 207 is stopped, the decompression in the cavity 224 is stopped, and the “die opening” of the casting mold 202 is started.
When the “die opening” of the casting mold 202 is completed, the extrusion pins 204b, 204b... Are pushed forward all at once, and the cast product is pushed out from the nesting unit 203.

By the way, when casting a large-sized cylinder block by such a reduced pressure casting apparatus 201, the extrusion pin 204b * 204b ... with which the extrusion unit 204 is equipped normally requires 20-40 pieces.
Therefore, since the same number of first through holes 222c, 222c,... As the number of extrusion pins 204b, 204b,... Are formed in the movable mold 222, these first through holes 222c, 222c,. Usually, 20 to 40 locations are formed.

On the other hand, in order to allow the push pins 204b, 204b,... To slide in the front-rear direction on the inner periphery of the first through holes 222c, 222c,. It is necessary to provide clearances 222f, 222f,... Of about 0.1 mm between the inner periphery of the pins and the outer periphery of the push pins 204b, 204b,.
That is, the casting mold 202 is provided with a plurality of gaps 222f, 222f,... That communicate the recess 222a of the movable mold 222 with the inside of the cavity 224.

  Therefore, for example, at the time of applying the release agent to the casting mold 202, the release agent liquefied with the cooling of the casting mold 202, and a part of the cooling water used for cooling the casting mold, In some cases, the fluid once flows into the concave portion 222a of the movable mold 222 through the plurality of gaps 222f, 222f.

  Accordingly, when the “mold closing” of the casting mold 202 is completed and the pressure in the cavity 224 is reduced, a part of the mold release agent and the cooling water that has flowed into the concave portion 222a again becomes the plurality of gaps 222f. -Part of the release agent and cooling water sucked into the cavity 224 through 222f ... and then sucked into the cavity 224 will be gasified by the heat of the molten metal and rolled into the cast product. This was a cause of casting defects.

In view of this, the following method is conceivable as a countermeasure for reducing the intrusion of moisture such as a mold release agent or cooling water into the cavity 224.
That is, as one method, when the inside of the cavity 224 is depressurized, the concave portion 222a of the movable mold 222 is also depressurized at the same time to eliminate the pressure difference at both ends of the plurality of gaps 222f, 222f. A method for preventing the moisture, such as a mold release agent or cooling water, from entering the cavity 224 can be considered.
Further, as another method, a method is conceivable in which a seal member is provided for each of the plurality of push pins 204b, 204b,... And the plurality of gaps 222f, 222f,. .

However, among these countermeasures, as described above, since the number of the extrusion pins 204b, 204b,... Not realistic.
Therefore, a reduced-pressure casting apparatus in which measures by the former method are taken has been proposed.

Here, the reduced pressure casting apparatus 301 to which the countermeasure by the former method was taken is demonstrated using FIG.
FIG. 7 is a side sectional view showing the overall configuration of a reduced pressure casting apparatus 301 in another conventional example.
In the following description, for convenience, the direction of arrow A in FIG. In FIG. 7, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 301 and will be described below.

  The vacuum casting apparatus 301 in another embodiment has the same basic structure as the conventional vacuum casting apparatus 201 described above, and has a partially different configuration in that a pressure reducing means is provided in the concave portion 322a of the movable mold 322.

That is, in the movable mold 322, a second communication path 322g is formed separately from the first communication path 322e communicating with the cavity 324, and the second communication path 322g is formed at one end of the casting mold. The second pipe member 306 led from the outside of 302 is connected and communicated with the concave portion 322a of the movable mold 322 at the other end.
The second piping member 306 is connected to the second communication path 322g at one end, and is connected to the vacuum pump 308 that is a decompression unit at the other end.

  The internal volume of the recess 322a is usually larger than the internal volume of the cavity 324. In order to instantaneously depressurize such a large-capacity space, the vacuum casting apparatus 301 has a large output vacuum. A pump 308 is provided, and a large vacuum tank 307 and an electromagnetic valve 309 are provided in the middle of the second piping member 306.

  The pressure in the recess 322a is reduced by previously reducing the pressure in the vacuum tank 307 by the vacuum pump 308 and controlling the opening / closing operation of the electromagnetic valve 309. That is, when the electromagnetic valve 309 is in the “open state”, the gas in the recess 322a flows into the vacuum tank 307, and the inside of the recess 222a is depressurized.

  When the reduced pressure casting apparatus 301 in such another embodiment is used, when the inside of the cavity 324 is decompressed, the inside of the concave portion 322a of the movable mold 322 can be decompressed at the same time. .. Can be eliminated, so that moisture such as a mold release agent or cooling water can be prevented from entering the cavity 324.

  However, on the other hand, as described above, a high-power vacuum pump 308 and a large vacuum tank 307 are required, and the equipment cost of the vacuum casting apparatus 301 is increased as a whole.

  Therefore, a technique as disclosed in “Patent Document 2” has been disclosed as a countermeasure proposal for reducing the intrusion of moisture including a mold release agent and cooling water into the cavity without increasing the equipment cost.

  That is, in the above-mentioned “Patent Document 2”, a fixed mold, a movable mold disposed to face the fixed mold so as to be close to and away from the fixed mold, and disposed between the fixed mold and the movable mold. A technique relating to a reduced pressure casting mold having a casting mold constituted by a movable intermediate mold is disclosed, wherein the movable intermediate mold is in the proximity and separation direction of the fixed mold and the movable mold. It is comprised by the some metal mold | die part which can move orthogonally and radially with respect to.

When the cast product is removed, first, the movable intermediate mold and the movable mold are simultaneously separated from the fixed mold, and then the movable intermediate mold holds the cast product. Thus, when the movable intermediate mold is separated from the movable mold, the cast product is removed from the nesting unit attached to the movable mold.
Thereafter, the movable intermediate mold moves radially outward of the casting mold, thereby completing the demolding of the cast product.

JP 2001-129654 A JP 2005-231066 A

  According to the technique shown in the above-mentioned “Patent Document 2”, it is not necessary to provide an extrusion pin in the casting mold, and in addition, a large-output vacuum pump, a large-sized vacuum tank, and the like are not necessary, so that the equipment cost is also reduced. It may be possible to reduce the intrusion of moisture, such as a release agent or cooling water, into the cavity without being bulky.

However, because the mold release resistance between the cast product and the core unit is large, it occurs between the cast product and the movable intermediate mold when the movable intermediate mold is separated from the movable mold. Due to the reaction force in the shearing direction, it is difficult to maintain the predetermined posture of the cast product with respect to the movable intermediate mold, and if the mold product is actually demolded by such a reduced pressure casting apparatus, There is also a possibility of damaging the cast product.
Further, even if an attempt is made to hold a predetermined posture of the cast product by the take-out robot, it is practically difficult to hold the cast product by the take-out robot while being held by the movable intermediate mold.

  The present invention has been made in view of the above-described current problems, and in order to ensure good casting quality, an extrusion pin for extruding a cast product from a casting mold, and formation on the casting mold In order to prevent the release agent and cooling water from entering the cavity through the gap between the through hole for the extruded pin, the casting pin itself is abolished and cast without damaging the cast product. It is an object of the present invention to provide a reduced pressure casting apparatus and a reduced pressure casting method that can be surely removed from a mold.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, a reduced pressure casting apparatus for casting a cast product by reducing the pressure in a cavity of a casting mold composed of a plurality of divided mold groups, Any one mold part includes a plurality of nestings projecting from the side surface on the cavity side toward the cavities, and the plurality of nestings are disposed so as to be movable in a direction to advance and retreat with respect to the cavity. Is.

  According to a second aspect of the present invention, in the reduced-pressure casting apparatus according to the second aspect, the mold part including the plurality of inserts communicates the cavity side surface and the surface opposite to the cavity side surface. The plurality of nestings are inserted into the through holes, and ends of the plurality of nestings on the side opposite to the cavity side are connected by a slide plate.

  In Claim 3, It is a pressure reduction casting apparatus of Claim 2, Comprising: In the penetration direction of the said through-hole, the cross-sectional shape of the said through-hole is formed small compared with the cross-sectional shape of the said slide plate, The said plurality An annular seal member is provided between the outer peripheral portion of the through-hole on the surface opposite to the cavity-side surface of the mold part having the insert and the slide plate.

  In Claim 4, It is a pressure reduction casting apparatus as described in any one of Claim 1 thru | or 3, Comprising: The said casting product is a cylinder block, The said several nest | insert has several bore pin nest | inserts. The plurality of bore pin inserts are connected to the slide plate so as to be movable along a protruding direction of the plurality of inserts with respect to the slide plate.

  In Claim 5, It is a pressure reduction casting apparatus as described in any one of Claim 4, Comprising: The latching | locking part which consists of a short column member is formed in the edge part by the side of the said slide plate of the said bore pin nest | insert. The slide plate has a first engagement surface that is engaged with the cavity-side surface of the engagement portion, and a second engagement that is engaged with a surface opposite to the cavity-side surface of the engagement portion. A stop surface is provided, and the locking portion is locked to the first locking surface and the second locking surface, whereby movement of the bore pin nest with respect to the slide plate is restricted.

  In Claim 6, It is a pressure reduction casting method which casts a casting product by decompressing the inside of the cavity of the casting mold comprised from the some divided | segmented metal mold group, Comprising: In one mold part, a plurality of nestings projecting from the side surface on the cavity side toward the cavities are provided, the plurality of nestings are arranged to be movable in a direction to move forward and backward with respect to the cavity, Demolding of the cast product from the casting mold is performed by “retracting” the casting mold and then retracting the plurality of inserts with respect to the cavity.

  According to a seventh aspect of the present invention, in the vacuum casting method according to the sixth aspect, the mold part including the plurality of inserts communicates the cavity side surface and the surface opposite to the cavity side surface. The plurality of inserts are inserted into the through holes, and ends of the plurality of inserts opposite to the cavity side are connected by a slide plate, and the slide plate is connected to the slide plate. By retreating with respect to the cavity, the plurality of nestings retreat with respect to the cavity.

  In Claim 8, It is a pressure reduction casting method of Claim 7, Comprising: In the penetration direction of the said through-hole, the cross-sectional shape of the said through-hole is formed small compared with the cross-sectional shape of the said slide plate, The said some An annular seal member is provided between the outer peripheral portion of the through-hole on the surface opposite to the cavity-side surface of the mold part including the insert, and the cavity of the mold part. By pressing the seal member with the surface opposite to the side surface and the slide plate, the cavity side in the through hole and the opposite side of the cavity are isolated.

  A ninth aspect of the present invention provides the vacuum casting method according to the sixth to eighth aspects, wherein the cast product is a cylinder block, and the plurality of nestings includes a plurality of bore pin nestings, A plurality of bore pin inserts are connected to the slide plate so as to be movable along the protruding direction of the plurality of inserts with respect to the slide plate, and when the slide plate retracts with respect to the cavity, the bore pin The bore pin nesting retreats after a plurality of nestings other than nesting retreat.

  In Claim 10, It is a pressure reduction casting method of Claim 9, Comprising: The latching | locking part which consists of a short column member is formed in the edge part by the side of the said slide board of the said bore pin nest | insert, The said slide board is the said A first locking surface that locks to the cavity-side surface of the locking portion; and a second locking surface that locks to a surface opposite to the cavity-side surface of the locking portion, The movement of the bore pin nest with respect to the slide plate is restricted by the locking portion being locked to the first locking surface and the second locking surface.

  As effects of the present invention, the following effects can be obtained.

  That is, according to the vacuum casting apparatus and vacuum casting method of the present invention, an extrusion pin for extruding a cast product from a casting mold and an extrusion pin formed on the casting mold in order to ensure good casting quality. In order to prevent mold release agent and cooling water from entering the cavity through the gap between the through hole and the through hole, the extrusion pin itself is abolished and the casting product is not damaged, more reliably than the casting mold. A vacuum casting apparatus and a vacuum casting method that can be removed from the mold can be provided.

1 is a side sectional view showing the overall configuration of a vacuum casting apparatus according to a first embodiment of the present invention. FIG. 2 is a rear sectional view of the vacuum casting apparatus as seen from the X direction shown in FIG. 1. It is the figure which showed the operation | movement of the pressure reduction casting apparatus (1st Example) at the time of mold removal of a casting product, (a) is the side of the pressure reduction casting apparatus which showed the state by which the biscuit part of the casting product was extruded by the injection chip | tip. Sectional view, (b) is a side sectional view of a vacuum casting apparatus showing a state where the moving mold and the slide mold are each moved in the “opening direction”, and (c) is movable while the casting product is supported by the take-out robot. Side surface sectional drawing of the decompression casting apparatus which showed the state by which the nesting unit was extracted from the cast product. Side surface sectional drawing which showed the whole structure of the pressure reduction casting apparatus which concerns on the 2nd Example of this invention. It is the figure which showed the operation | movement of the movable nesting unit of the pressure reduction casting apparatus (2nd Example) at the time of mold removal of a casting product, (a) is immediately after a movable mold and a slide mold each moved to the "opening direction" (B) is a side cross-sectional view of the movable nest unit near the movable nesting unit, and (c) is a drawing of the bore pin together with the cored pin. Side surface sectional drawing of the movable nest unit vicinity which showed the state extracted. Side surface sectional drawing which showed the whole structure of the conventional pressure reduction casting apparatus. Side surface sectional drawing which showed the whole structure of the pressure reduction casting apparatus which concerns on another conventional Example.

  Next, embodiments of the invention will be described.

[Overall configuration of vacuum casting apparatus (first embodiment) 1]
First, the overall configuration of the vacuum casting apparatus 1 according to the first embodiment will be described with reference to FIG.
In the following description, for convenience, the direction of arrow A in FIG. In FIG. 1, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 1 and will be described below.

The vacuum casting apparatus 1 in the present embodiment (first embodiment) is an apparatus for casting a part (cast product) having an internal space by a vacuum casting method, such as a cylinder block which is one of engine parts. is there.
That is, the vacuum casting apparatus 1 is an apparatus for casting a cast product by providing a nesting in a space portion (hereinafter referred to as “cavity”) 24 formed inside the casting mold 2 to reduce the pressure.
The vacuum casting apparatus 1 is mainly configured by including a casting mold 2 and a movable nesting unit 3.

First, the overall configuration of the casting mold 2 will be described.
The casting mold 2 is a part for pouring molten metal (hereinafter referred to as “molten metal”) 20 into the cavity 24 of the casting mold 2 to form the shape of the cast product.
The casting mold 2 is divided into a plurality of molds such as a fixed mold 21, a movable mold 22, a slide mold 23, 23...

  The fixed mold 21 is a reference part among the mold groups 21, 22, 23, 23... Constituting the casting mold 2, and is provided in the vacuum casting apparatus 1 via a chuck device or the like. The fixed platen 11 is detachably fixed and held.

A slide mold 23, 23, which will be described later, is disposed behind the fixed mold 21, and a movable mold 22, which will be described later, is further disposed behind the slide mold 23, 23,. Is done.
In other words, the fixed mold 21 and the movable mold 22 are disposed so as to be close to and away from each other in the front-rear direction with the slide molds 23, 23.
A space surrounded by the fixed mold 21, the movable mold 22, and the slide molds 23, 23... Is configured as a cavity 24.

  On the rear surface of the fixed mold 21, a substantially rectangular parallelepiped shape having a longitudinal direction in the left-right direction (horizontal direction and a direction orthogonal to the approaching / separating direction of the fixed mold 21 and the movable mold 22) is provided at the center in the rear view. The protrusion 21a protrudes rearward (cavity 24 side), and a plurality of recesses 21b, 21b,... Recessed in a truncated cone shape toward the front are fixed on the rear end surface of the protrusion 21a. They are formed side by side in the left-right direction with a gap.

  When casting a cast product using the casting mold 2, a plurality of bore pin inserts 33, 33... Projecting forward from the side surface of the movable mold 22 on the cavity 224 side toward the cavity 24 side. Are in contact with the recesses 21b, 21b, so that the front ends of the bore pin inserts 33, 33,... Are supported by the protrusions 21a, 21a,.

On the other hand, an injection sleeve 25 is provided through the fixed mold 21 in the front-rear direction.
The injection sleeve 25 is a part serving as a supply path when the molten metal 20 is poured into the cavity 24.

The injection sleeve 25 is made of a hollow member, and the rear end portion thereof penetrates the fixed mold 21.
That is, a supply path for the molten metal 20 penetrating in the front-rear direction is formed in the fixed mold 21 through the inner peripheral portion 25 a of the injection sleeve 25, and the rear end portion of the inner peripheral portion 25 a is a runner of the cavity 24. 24a is communicated.

  On the other hand, a hot water supply port 25b is opened at the upper part of the front end of the injection sleeve 25, and the molten metal 20 is supplied from the ladle 27 to the inner peripheral portion 25a of the injection sleeve 25 through the hot water supply port 25b.

An injection tip 26 is provided in the inner peripheral portion 25 a of the injection sleeve 25.
The injection tip 26 is a part for pushing the molten metal 20 supplied to the inner peripheral portion 25 a of the injection sleeve 25 into the cavity 24.

The injection tip 26 is formed from a short column member having a front sectional shape substantially the same as the front sectional shape of the inner peripheral portion 25a, and is disposed coaxially with the inner peripheral portion 25a.
A support shaft 26a extending forward is provided on the front end surface of the injection tip 26 (the end surface of the injection tip 26 opposite to the cavity 24), and the front end of the support shaft 26a is illustrated in FIG. It is connected to an actuator not shown.

  The injection tip 26 slides in the front-rear direction along the inner peripheral portion 25 a of the injection sleeve 25 by moving the support shaft 26 a in the front-rear direction (the axial center direction of the inner peripheral portion 25 a) by the actuator. It is like that.

  As described above, the movable mold 22 is disposed behind the fixed mold 21 so as to face the fixed mold 21 and can be attached to and detached from the movable platen 12 provided in the vacuum casting apparatus 1 via a chuck device or the like. Is held fixed.

  When the movable platen 12 moves in the horizontal front-rear direction, the movable mold 22 is provided to be movable in the front-rear direction so as to be close to and away from the fixed mold 21.

The front surface (side surface on the cavity 24 side) of the movable mold 22 is formed in a substantially flat shape, while a concave portion 22a having a substantially rectangular parallelepiped shape is formed in the central portion of the rear surface corresponding to the back surface side of the movable mold 22. The rectangular parallelepiped shape is formed from the rear surface of the movable mold 22 to the vicinity of the front surface with the longitudinal direction thereof being directed in the left-right direction.
In addition, in the front end surface 22b of the recess 22a, a first through hole 22c having a substantially rectangular shape in cross-sectional view having a smaller cross-sectional area than the recess 22a is formed in the center portion in the rear view, and the longitudinal direction of the substantially rectangular shape is It is formed in the left-right direction.
Further, in the vicinity of the outer periphery of the first through hole 22c, a plurality of second through holes 22e, 22e,. .. communicates with the recess 22a at the rear end.

  A movable nesting unit 3 to be described later is housed inside the movable mold 22 through the recess 22a, the first through hole 22c, and the second through holes 22e, 22e,. The bore pin inserts 33, 33... And the water jacket insert 34 of the movable insert unit 3 extend forward toward the cavity 24.

A first series passage 22d is formed inside the movable mold 22, and the first series passage 22d is connected to the first piping member 4 guided from the outside of the casting mold 2 at one end, It communicates with the cavity 24 at the other end.
The first piping member 4 is connected to the first continuous passage 22d at one end, and is connected to the vacuum pump 6 that is a decompression unit at the other end.
Then, by controlling the operation of the vacuum pump 6, the atmospheric pressure in the cavity 24 is reduced.

  As described above, the slide molds 23, 23,... Are disposed between the fixed mold 21 and the movable mold 22 that are disposed to face each other in the front-rear direction, and are divided into a plurality of molds. Configured.

  The plurality of slide dies 23, 23... Are formed on a vertical plane (a plane perpendicular to the moving direction of the movable mold 22) by an actuator (not shown) provided in the vacuum casting apparatus 1. Each of the fixed molds 21 is provided so as to be slidable in a radial direction when viewed from the center.

  Here, a casting product is provided on each of the opposing side surfaces of the plurality of slide dies 23, 23,... (That is, the side surface facing the intersection in the moving direction with respect to each slide dies 23, 23...). Are formed in a shape corresponding to a part of the outer shape of each of the slide molds 23a, 23a,..., And the slide molds 23, 23,. The plurality of recesses 23a, 23a,... Are combined to form a side surface of the cavity 24 along the outer shape of one cast product (in the front view, the outer peripheral surface centered on the moving direction of the movable mold 22). ) Is formed.

  The movable mold 22 moves forward toward the fixed mold 21, and the plurality of slide molds 23, 23... Combined with each other are sandwiched between the fixed mold 21 and the movable mold 22. The front and rear sides of the side surface of the cavity 24 formed by the plurality of recesses 23a, 23a,... Are closed by the fixed mold 21 and the movable mold 22, and have an outer shape covering the entire surface of the cast product. A cavity 24 having a corresponding shape is formed.

  As described above, the casting mold 2 is composed of a plurality of mold groups 21, 22, 23,..., And the fixed mold 21 and the movable mold 22 are disposed so as to face each other in the horizontal front-rear direction. Further, slide molds 23, 23... Are arranged between the fixed mold 21 and the movable mold 22.

  In addition, these mold groups 21, 22, 23, 23... Can move the movable mold 22 in the front-rear direction (opposite direction of the fixed mold 21 and the movable mold 22) with the fixed mold 21 as a reference. Further, the slide molds 23, 23... Are movable in the orthogonal direction (perpendicular direction to the moving direction of the movable mold 22), respectively, radially in front view around the central portion of the fixed mold 21. Composed.

The movable mold 22 is located at a rear position separated from the fixed mold 21, and the plurality of slide molds 23, 23... Are located at outer positions separated from the fixed mold 21. From the state, the movable mold 22 moves forward toward the fixed mold 21, and slides on the plurality of slide molds 23, 23... The casting mold 2 is “closed”.
As a result, a cavity 24 surrounded by the fixed mold 21, the movable mold 22, and the plurality of slide molds 23, 23... Is formed inside the casting mold 2.

  On the other hand, in the casting mold 2 in such a “mold closed” state, the movable mold 22 moves in the separating direction (rearward) with respect to the fixed mold 21 and a plurality of slide molds 23, 23. The casting mold 2 is “opened” by sliding and moving in the outward direction away from the fixed mold 21 on the vertical plane.

Next, the movable nesting unit 3 will be described.
The movable nesting unit 3 is provided in advance in the cavity 24 as a portion corresponding to the space portion of the cast product before the molten metal 20 is poured into the cavity 24 in casting of the cast product having the space portion therein. The nesting as a member is directed from the front surface of the movable mold 22, which is one of the plurality of mold groups 21, 22, 23... Constituting the casting mold 2, toward the cavity 24. In addition to projecting, it is provided so as to be movable in the front-rear direction (the direction in which the cavity 24 advances and retreats).

  That is, in the vacuum casting apparatus 1 in this embodiment, for example, when a cylinder block is cast as a cast product, the cylinder block surrounds a plurality of cylinder bore portions and the entire circumference of these cylinder bore portions together. A space portion such as a water jacket portion is provided.

  Therefore, before the molten metal 20 is poured into the cavity 24, the bore pin inserts 33, 33,... There is.

  On the other hand, at the time of releasing the cast product, it is necessary to “open the mold” 2 and to pull out the cast product from the bore pin inserts 33, 33.

  Therefore, the movable nesting unit 3 according to the present embodiment is formed as a unit with the bore pin nestings 33, 33..., The water jacket nesting 34 and the like protruding into the cavity 24 during casting as one structure. When the cast product is to be removed from the mold by moving in the front-rear direction with respect to the movable mold 22 through the recessed portion 22a, the first through-hole 22c, the second through-hole 22e, 22e,. The cast product can be easily pulled out from the bore pin inserts 33, 33..., The water jacket insert 34, etc. without providing a plurality of extrusion pins.

[Movable nesting unit 3]
Next, a specific configuration of the movable nesting unit 3 will be described with reference to FIGS. 1 and 2.
As shown in FIG. 1, the movable nesting unit 3 includes a nesting portion 31 and a slide plate 32, and the nesting portion 31 mainly includes a plurality of bore pin nestings 33, 33... And cast pins 35, 35. .. and a water jacket insert 34.

  The bore pin inserts 33, 33,... Are each formed of a solid round bar member, and are forward of the movable die 22 through the first through hole 22c of the movable die 22 (fixed to the movable die 22). It is arranged so as to extend toward the mold 21 side).

  In other words, the plurality of bore pin inserts 33, 33,... Have a fixed distance from each other with the axial direction in the front-rear direction (the approaching and separating direction of the fixed mold 21 and the movable mold 22). They are juxtaposed in the direction (horizontal and perpendicular to the axial direction of the bore pin insert 33).

  At the front end of each bore pin insert 33, a tapered portion 33a whose diameter in front sectional view gradually decreases toward the front is formed and brought into contact with the recess 21b formed on the rear surface of the fixed mold 21 described above. It is like that.

That is, when the movable mold 22 moves forward and the front end portion of the bore pin insert 33 moves toward the recess 21b of the fixed die 21, it is between the recess 21 b and the front end portion of the bore pin insert 33 in plan view. Even if a slight misalignment of the shaft center occurs, the front end of the bore pin insert 33 is corrected by the recess 21b via the taper 33a and pushed back to the normal position.
Therefore, the front end portion of the bore pin insert 33 is reliably brought into contact with the concave portion 21 b of the fixed mold 21.

A stepped region 33b having a slightly reduced cross section is formed in the midway portion in the front-rear direction of each bore pin insert 33.
As will be described later, when the cylinder liner 37 is provided on the outer periphery of the plurality of bore pin inserts 33, 33... At the inner periphery of the water jacket insert 34, the stepped regions 33b, 33b. Thus, the inner peripheral portion of the cylinder liner 37 is securely locked.
Therefore, even when the molten metal 20 is poured into the cavity 24 of the casting mold 2, the cylinder liner 37 is not moved by the pressure of the molten metal 20, and a predetermined arrangement position can be maintained. is there.

  The water jacket insert 34 is inserted into the cavity 24, and includes a main body 34a that actually forms a space of the cast product, and a base 34b that supports the main body 34a.

  The main body 34a is formed of a substantially rectangular tubular member having a longitudinal direction in the left-right direction (a direction in which the plurality of bore pin inserts 33, 33,...) In front view, and the plurality of bore pin inserts 33, 33,. -It is arranged so as to surround the entire periphery of the whole and extend forward.

  More specifically, as shown in FIG. 2, the main body portion 34 a has a cross-sectional shape in front view of each of the bore pin inserts 33 with respect to the plurality of bore pin inserts 33, 33. Are formed so as to have a curved shape along an arc, and are arranged so as to extend forward.

A base 34b is provided at the rear end of the main body 34a.
The base 34b is made of a rectangular parallelepiped member whose longitudinal direction is the left-right direction, and the front sectional shape is substantially the same as the front sectional shape of the first through hole 22c of the movable mold 22.

  Further, a plurality of through holes 34c, 34c,... Penetrating in the front-rear direction are drilled in the base portion 34b, and these through holes 34c, 34c,. These are formed to have the same cross-sectional area, and are formed at the same locations as the positions where the bore pin inserts 33, 33,.

  The rear end portion of the bore pin inserts 33, 33,... Is inserted into the base portion 34b through the plurality of through holes 34c, 34c, and the front surface of the through holes 34c, 34c,. A rear end portion of the main body portion 34a is fixed at the outer peripheral portion of the view.

  Here, as shown in FIG. 2, in the inner peripheral portion of the water jacket insert 34, a cylinder liner 37 made of a fiber molded body or the like is disposed on the outer peripheral portion of the plurality of bore pin inserts 33, 33. .

  That is, the cylinder liner 37 is put into the cavity 24 of the casting mold 2 while being sandwiched between the water jacket insert 34 and the plurality of bore pin inserts 33.

  As will be described later, when the cast product is removed from the casting mold 2, by sliding the movable nesting unit 3 backward, the nesting portion 31 is pulled out from the cavity 24 and the cylinder liner is removed. 37 remains in the cavity 24 and is secured to the cast product.

In the vicinity of the outer peripheral portion of the water jacket insert 34, a plurality of core pins 35, 35... Are disposed (see FIG. 2).
The cast pin 35 is a pin for casting a hole formed in a cast product. In the present embodiment, for example, in the cylinder block, a fastening hole such as a bolt provided in the vicinity of the cylinder bore is formed. Provided for.

The cast pin 35 is formed of a round bar member, and is formed in a tapered shape whose diameter is slightly reduced from the rear end portion toward the front end portion.
The core pin 35 has its axial direction directed in the front-rear direction (opposite direction between the fixed mold 21 and the movable mold 22), and each predetermined location (in a plan view, such as a bolt in a cast product). The rear end portion of the core pin 35 is inserted into the second through hole 22e of the movable mold 22 and faces the recess 22a.

  The slide plate 32 is a portion serving as a base portion of the insert portion 31 including a plurality of bore pin inserts 33, 33..., Cast pins 35, 35.

The slide plate 32 is made of a substantially rectangular plate-like member, and the shape of the flat portion is formed to be approximately the same as the sectional shape of the recess 22 a formed in the movable mold 22 when viewed from the front.
That is, in the slide plate 32, the planar shape of the side surface on which a plurality of inserts such as the bore pin insert 33, the cast pin 35, and the water jacket insert 34 is provided is the through direction of the first through hole 22 c formed in the movable mold 22. The second through-hole 22e is arranged so as to be within the plane of the slide plate 32 when viewed from the front.

  In addition, the slide plate 32 is disposed inside the concave portion 22a with the flat portion facing in the front-rear direction while the longitudinal direction is directed in the left-right direction.

In the front surface of the slide plate 32, rear end portions such as the plurality of bore pin inserts 33, 33..., Cast pins 35, 35. Each is fixed.
In other words, the plurality of inserts including the plurality of bore pin inserts 33, 33..., The casting pins 35 35..., The water jacket insert 34, and the like are the ends on the back surface side (rear side) of the movable mold 22. Are connected by a slide plate 32.

  Further, the movable nesting unit 3 has a plurality of bore pin nestings 33, 33,... And casting pins 35, 35,..., Through the first and second through holes 22c, 222e, 22e,. In addition, the water jacket insert 34 extends in the forward direction, and is embedded in the movable mold 22. On the rear surface of the slide plate 32, the tip of the rod 36 of the hydraulic cylinder is a bolt or the like. It is fixed detachably via a fastening member (not shown).

  Then, by moving the rod 36 of the hydraulic cylinder backward, the slide plate 32 slides backward in the recess 22a of the movable mold 22, and the plurality of bore pin inserts 33, 33. .., And the water jacket insert 34 are moved simultaneously toward the rear.

  As described above, the movable nesting unit 3 configured to have a plurality of nestings such as the bore pin nesting 33, the water jacket nesting 34, and the cast pin 35 has a side surface (front surface) on the cavity 24 side in the movable mold 22. It arrange | positions so that a movement is possible toward the direction (back) of the back surface side which opposes.

  In the front end surface 22b of the concave portion 22a of the movable mold 22, an annular seal member 28 surrounds the first and second through holes 22c, 22e, 22e,. Arranged.

The movable nesting unit 3 is moved forward by the hydraulic cylinder, and a plurality of nestings such as the bore pin nesting 33, the water jacket nesting 34, and the casting pin 35 protrude from the front surface of the movable mold 22 toward the cavity 24. In the installed state, the seal member 28 is pressed by the front surface of the slide plate 32 and the front end surface 22b of the recess 22a, and the seal member 28 causes the interior of the recess 22a to be inside the first and second through holes 22c, 22e, and 22c. It is sealed with respect to the inside of 22e ....
That is, in the “mold closed” state of the casting mold 2, by moving the movable nest unit 3 forward, the space between the inside of the recess 22 a and the inside of the cavity 24 is sealed by the seal member 28. Is securely sealed against the inside of the recess 22a.

[Demolding method (first embodiment)]
Next, a demolding method of the vacuum casting apparatus 1 according to the first embodiment will be described with reference to FIG.
In the following description, for convenience, the direction of arrow A in FIG. In FIG. 3, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 1 and will be described below.

As shown in FIG. 3A, in order to cast a cast product (hereinafter, referred to as “cast product 20A” in order to distinguish from the molten metal 20) by the reduced pressure casting apparatus 1, first, a fixed mold 21 and a slide After the mold release agent is applied to the side faces of the molds 23, 23,... Facing the cavity 24, the casting mold 2 is “closed”.
Further, in accordance with the “mold closing” of the casting mold 2, the movable nesting unit 3 is slid forward, and the nesting portion 31 including the cylinder liner 37 (see FIGS. 1 and 2) is placed in the cavity 24. Decorate.

  On the other hand, when the “mold closing” of the casting mold 2 is completed, the vacuum pump 6 (see FIG. 1) is activated to depressurize the cavity 24, and the pressure in the cavity 24 becomes a predetermined numerical value. If it reaches, the molten metal is poured into the cavity 24.

  Then, by supplying the cooling water to the casting mold 2 through a supply path (not shown), the casting mold 2 is cooled, and the molten metal 20 in the cavity 24 is also cooled and solidified, and the cast product 20A. Is cast.

  A part of the molten metal 20 filled in the cavity 24 is cooled while entering the inside of the cylinder liner 37, and the cylinder liner 37 is fixed to the cast product 20A.

  On the other hand, when the pressure in the cavity 24 is reduced, since the movable nesting unit 3 has already been slid forward, the seal member 28 disposed in the recess 22a of the movable mold 22 is The state is pressed by the slide plate 32.

  That is, the inside of the recess 22a and the inside of the cavity 24 are sealed by the sealing member 28 and are surely separated in an airtight and liquidtight manner. Even if the pressure is reduced, for example, a small amount of cooling water or a release agent remaining in the recess 22a is sucked into the cavity 24 through the first and second through holes 22c, 22e, 22e,. It is never done.

When the molten metal 20 in the cavity 24 is sufficiently solidified and the molding of the cast product 20A is completed, the vacuum pump 6 (see FIG. 1) is stopped to stop the decompression in the cavity 24, and the cast metal related to the cast product 20A is stopped. Demolding from mold 2 is started.
That is, as shown in FIG. 3 (b), the movable mold 22 and the plurality of slide molds 23, 23... 2 is in a “mold open” state.
More specifically, the movable mold 22 including the plurality of slide molds 23, 23... Moves backward, and then the plurality of slide molds 23, 23. By moving each, the casting mold 2 is in the “open mold” state.

  On the other hand, the injection chip 26 housed in the injection sleeve 25 is moved rearward while pressing the gate biscuits 20a of the cast product 20A following the rearward movement of the movable mold 22.

  Thus, immediately after the casting mold 2 is in the “die opening” state, the casting product 20A is placed on the front surface of the movable mold 22 formed in a substantially flat shape (the movable mold in the casting product 20A). The end biscuits 20a are held by the injection tip 26 while being hooked by the nesting portion 31 extending forward from the front surface of the movable mold 22 while abutting the end face facing the face 22).

When the “die opening” of the casting mold 2 is completed, the casting product 20 </ b> A is gripped at one end by the take-out robot 8 provided in the vacuum casting apparatus 1.
Thereafter, as shown in FIG. 3 (c), when the injection tip 26 moves forward, the cast product 20A is released from the pressed state of the injection tip 26, and the movable nesting unit 3 moves backward. Thus, the nesting part 31 is pulled out from the cast product 20A.
That is, the cast product 20A is supported only by the take-out robot 8 while pressing the rear end surface against the front surface of the movable mold 22 formed in a substantially flat shape.

Note that the nest portion 31 is pulled out from the cylinder liner 37 as the movable nesting unit 3 moves rearward.
That is, the cylinder liner 37 is more firmly fixed to the cast product by the molten metal 20 soaked in the inside than the locking force by the stepped regions 33b, 33b,... Of the bore pin inserts 33, 33,. And stay in the cavity 24.

  Thereafter, the casting product 20A is taken out from the casting mold 2 by the take-out robot 8, and the demolding of the casting product 20A from the casting mold 2 is completed.

[Overall configuration of reduced pressure casting apparatus (second embodiment) 101]
Next, the overall configuration of the vacuum casting apparatus 101 according to the second embodiment will be described with reference to FIG.
In the following description, for the sake of convenience, the direction of arrow A in FIG. In FIG. 4, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 101 and will be described below.

The vacuum casting apparatus 101 in the present embodiment (second embodiment) has the same basic structure as the vacuum casting apparatus 1 in the first embodiment described above, and has some differences in the configuration of the movable nesting unit 103.
Hereinafter, portions having the same configuration as that of the reduced pressure casting apparatus 1 in the first embodiment will be denoted by the same reference numerals as those of the reduced pressure casting apparatus 1 and description thereof will be omitted, and the configuration of the movable nesting unit 103 will be described in detail.

[Movable nesting unit 103]
The movable nesting unit 103 in the present embodiment (second embodiment) is configured to be slidable in the front-rear direction by a single hydraulic cylinder (not shown).
Further, the movable nesting unit 103 has a bore pin nesting 133 and casting pins 135, 135... When the nesting part 131 is pulled out from the casting product 20A when the casting product 20A is removed from the casting mold 2. It is comprised so that a time lag (time shift | offset | difference when these member groups 133 * 134 * 135 * 135 ... start movement) may be produced between the water jacket inserts 134 to include.
Hereinafter, a specific configuration of the movable nesting unit 103 will be described.

  The movable nesting unit 103 includes a nesting portion 131, a slide plate 132, and the like. The nesting portion 131 mainly includes a plurality of bore pin nestings 133, 133,..., Casting pins 135, 135, and a water jacket. It is constituted by a nesting 134 or the like.

  The water jacket insert 134 and the cast pins 135, 135,... Are the same as the water jacket insert 34 and the cast pins 35, 35,. Is omitted.

The bore pin insert 133 is formed by a main body portion 133A, a connecting portion 133B, and a locking portion 133C.
The main body 133A is made of a solid round bar member, and is formed in the same shape as the bore pin insert 33 in the first embodiment described above.

That is, the front end portion of the main body portion 133A is formed with a tapered portion 133a whose front sectional shape gradually decreases in diameter toward the front, and the tapered portion 133a is formed with a recess 21b formed on the rear surface of the fixed mold 21. It comes to contact reliably.
Further, a stepped region 133b having a slightly reduced cross section is formed in the middle part of the main body 133A in the front-rear direction, and the inner peripheral portion of the cylinder liner 37 is securely locked by the stepped region 133b. It is like that.

A connecting portion 133B is provided on the rear end surface of the main body portion 133A.
The coupling portion 133B is formed of a round bar member having a smaller cross-sectional area than the main body portion 133A, and is provided coaxially with the main body portion 133A and extending rearward.

A locking portion 133C is provided on the rear end surface of the coupling portion 133B.
The locking portion 133C is formed of a short column member having a larger cross-sectional area than that of the connecting portion 133B. In the present embodiment, the locking portion 133C is formed having a cross-sectional area substantially the same as that of the main body portion 133A. .
The locking portion 133C is provided coaxially with the connecting portion 133B at the rear end portion of the connecting portion 133B.

As described above, the bore pin insert 133 is integrally formed with the main body portion 133A, the connecting portion 133B, and the locking portion 133C being arranged coaxially.
The plurality of bore pin inserts 133, 133,... Formed by such a shape are forward of the rear surface of the movable mold 22 (movable mold) via the first through hole 22c of the movable mold 22. No. 22 is arranged so as to extend toward the fixed mold 21 side).

  In other words, the plurality of bore pin inserts 133, 133,... Move the locking portions 133C, 133C, ... rearward while directing the axial direction in the front-rear direction (opposite direction of the fixed mold 21 and the movable mold 22). Toward the left and right sides of the left and right direction (horizontal and perpendicular to the axial direction of the bore pin insert 133) with a certain distance from each other.

The slide plate 132 is mainly composed of a front plate 132a, an intermediate plate 132b, a rear plate 132c, and the like.
The front side plate 132a is made of a substantially rectangular plate-like member, and the shape of the flat portion is formed to be approximately the same as the sectional shape of the concave portion 22a formed in the movable mold 22 when viewed from the front.
In addition, the front side plate 132a is disposed inside the concave portion 22a with the flat portion facing in the front-rear direction while the longitudinal direction is directed in the left-right direction.

A plurality of through-holes 132d, 132d,... Penetrating in the front-rear direction are perforated at the center in the vertical direction of the front side plate 132a.
The thickness dimension of the front side plate 132a is formed smaller than the length dimension in the axial direction of the connecting portions 133B, 133B..., And the through holes 132d, 132d. Is formed at the same position as the position where the bore pin inserts 133, 133,... Are disposed, and the cross-sectional shape thereof is substantially the same as the cross-sectional shape of the connecting portions 133B, 133B,. .

  Further, a water jacket insert 134 is fixed to the front center of the front plate 132a so as to extend forward, and a plurality of through holes 134c. Are communicated with the plurality of through holes 132d, 132d,... Formed in the front side plate 132a.

The plurality of bore pin inserts 133, 133,... Are inserted into the front side plate 132a from the front side with the locking portions 133C facing rearward.
As a result, the plurality of bore pin inserts 133, 133... Are inserted into the through holes 134c, 134c... Formed in the base portion 134b of the water jacket insert 134 at the rear end portion of the main body portion 133A, and the connecting portion 133B. Are inserted into the through holes 132d, 132d,... Of the front plate 132a so as to extend forward from the front surface of the front plate 132a.

  In the front surface of the front plate 132a, in the vicinity of the peripheral portion of the water jacket insert 134, a plurality of core pins 135, 135... ... Protrudes forward (on the cavity 24 side with respect to the movable mold 22) by penetrating through the second through holes 22 e, 22 e... Of the movable mold 22.

The intermediate plate 132b is made of a substantially rectangular plate-like member, and the shape of the flat surface portion is substantially the same as the sectional shape of the recess 22a formed in the movable mold 22 when viewed from the front.
Further, the intermediate plate 132b is disposed inside the concave portion 22a with the flat portion facing in the front-rear direction while the longitudinal direction is directed in the left-right direction.

A plurality of through-holes 132e, 132e,... Penetrating in the front-rear direction are drilled in the center in the vertical direction of the intermediate plate 132b.
The through holes 132e, 132e,... Are formed at the same positions as the positions where the plurality of bore pin inserts 133, 133,. It is formed so as to be substantially the same as the cross-sectional shape of 133C.
The thickness dimension (dimension Y shown in FIG. 4) of the intermediate plate 132b is somewhat larger than the thickness dimension (dimension Z shown in FIG. 4) of the locking portion 133C of each bore pin insert 133.
In other words, the rear side plate 132c is spaced apart from the front side plate 132a with a larger interval than the length dimension of the locking portion 133C in the axial direction.

  Then, the intermediate plate 132b having such a shape is attached to the front plate 132a in the recess 22a of the movable mold 22 with its front surface closely attached to the rear surface of the front plate 132a. The locking portions 133C, 133C,... Of the bore pin inserts 133, 133,... Projecting rearward through the through holes 132d, 132d,.・ Each is inserted into.

The rear side plate 132c is made of a substantially rectangular plate-like member, and the shape of the flat surface portion is substantially the same as the sectional shape of the concave portion 22a formed in the movable mold 22 when viewed from the front.
Further, the rear side plate 132c is disposed inside the concave portion 22a with the plane portion facing in the front-rear direction while the longitudinal direction is directed in the left-right direction.

  The rear plate 132c having such a shape is attached to the intermediate plate 132b with the front surface thereof in close contact with the rear surface of the intermediate plate 132b in the concave portion 22a of the movable mold 22, and as a result, the intermediate plate The rear end portions of the through holes 132e, 132e,... 132b are closed by the front surface of the rear plate 132c.

  As described above, the slide plate 132 is formed by pasting the three front side plates 132a, the intermediate plate 132b, and the rear side plate 132c, each having a substantially rectangular shape, with the flat portions thereof being in close contact with each other.

  That is, the slide plate 132 is a side facing the bore pin insert 133 side with respect to the front plate 132a along the axial direction of the front plate 132a disposed on the bore pin insert 133 side (front side) and the bore pin insert 133. A rear plate 132c disposed on the (rear side), and an intermediate plate 132b is sandwiched between the front plate 132a and the rear plate 132c.

  As a result, the through holes 132d, 132d,... Of the front plate 132a and the through holes 132e, 132e,... Of the intermediate plate 132b are communicated with each other. A plurality of character-shaped concave portions 132f, 132f,... Are formed. In other words, the slide plate 132 includes a plurality of recesses 132f, each of which includes a small-diameter hole that opens to the front surface of the slide plate 132 and a large-diameter hole that is connected to the rear of the small-diameter hole and has a larger diameter than the small-diameter hole. 132f ... are formed.

  .., And the connecting portions 133B, 133B,... And the locking portions 133C, 133C,... Of the bore pin inserts 133, 133 ... are supported by the recesses 132f, 132f,. In addition, the front and rear surfaces of the locking portions 133C, 133C,... Are in contact with the front plate 132a and the rear plate 132c, respectively, so that the bore pin inserts 133, 133,. Is regulated.

  In other words, the plurality of bore pin inserts 133, 133... Are on the front surface of the slide plate 132, that is, the side surface on which other inserts such as the water jacket insert 134 and the plurality of core pins 135. Only the gap between the front side plate 132a and the rear side plate 132c is movable with respect to the slide plate 132 along the protruding direction of the plurality of inserts such as the water jacket insert 134 and the plurality of core pins 135. The slide plate 132 is connected.

  Here, the movable nesting unit 103 has a plurality of bore pin nestings 133, 133,... And cast pins 135, 135,..., Through the first and second through holes 22c, 222e, 22e,. , And the water jacket insert 134 extend in the forward direction, and are housed in the movable mold 22, and on the rear surface of the slide plate 32 (rear side plate 132C), the tip of the rod 136 of the hydraulic cylinder The part is fixed detachably via a fastening member (not shown) such as a bolt.

  Then, by moving the rod 136 of the hydraulic cylinder backward, the slide plate 132 slides backward in the recess 22a of the movable mold 22, and the plurality of bore pin inserts 133, 133. .., And the water jacket insert 134 are moved rearward.

  More specifically, when the rod 136 is moved forward, the front surface of the rear plate 132c and the rear end surfaces of the locking portions 133C, 133C,... Of the bore pin inserts 133, 133,. These bore pin inserts 133 are slid forward together with the water jacket insert 134 and the core pins 135 135 provided on the front surface of the front plate 132a.

  On the other hand, when the rod 136 is moved rearward, first, the water jacket insert 134 and the core pins 135, 135... Provided on the front surface of the front plate 132a are slid rearward.

  After that, from the time when the rear surface of the front side plate 132a and the front end surface of the locking portions 133C, 133C,... Of the bore pin inserts 133, 133,. Along with the water jacket insert 134 and the core pins 135, 135,...

  As described above, the movable nesting unit 103 in this embodiment (second embodiment) includes the bore pin nesting 133 and the core pins 135, 135... When the nesting portion 131 is slid rearward. A time lag is generated at the start of movement with the water jacket insert 134.

  In addition, in the front end surface 22b of the concave portion 22a of the movable mold 22, an annular first seal member 128 collects the first and second through holes 22c, 22e, 22e,. Are arranged so as to surround them.

  In the plurality of bore pin inserts 133, 133,..., Annular second seal members 129, 129,.

  When the movable nesting unit 103 is moved forward by the hydraulic cylinder, the first seal member 128 is pressed by the front surface of the front plate 132a and the front end surface 22b of the recess 22a, and the front surface of the front plate 132a. The second seal members 129, 129,... Are pressed by the rear end surfaces of the body portions 133A, 133A,.

  As a result, the pressed first seal member 128 and the second seal members 129, 129, etc. cause the inside of the recess 22a to be the same as that of the first and second through holes 22c, 22e, 22e,. In the “mold closed” state of the casting mold 2, the movable nest unit 3 is moved forward so that the inside of the recess 22 a is isolated from the inside of the cavity 24 by the seal member 28. .

[Demolding method (second embodiment)]
Next, a demolding method of the vacuum casting apparatus 101 according to the second embodiment will be described with reference to FIG.
In the following description, for convenience, the direction of arrow A in FIG. In FIG. 5, the vertical direction on the drawing is defined as the vertical direction of the vacuum casting apparatus 101 and will be described below.

  In the present embodiment (second embodiment), as described above, the vacuum casting apparatus 101 has the bore pin insert 133 when the insert 131 is pulled out of the cast product 20A when the cast product 20A is removed from the casting mold 2. And the water jacket insert 134 including the core pin 135 are different from the vacuum casting apparatus 1 in the first embodiment in that a time lag is generated.

  Therefore, in the following description, the operation until the molten metal 20 poured into the cavity 24 (see FIG. 4) of the casting mold 2 is cooled and solidified to form the cast product 20A is omitted. The operation when the “mold opening” of the casting mold 2 is completed and the insert 131 is pulled out from the cast product 20A will be described in detail.

  When the molten metal 20 in the cavity 24 is sufficiently solidified and the molding of the cast product 20A is completed, the casting mold 2 is immediately in the “open mold” state, and demolding of the casting product 20A from the casting mold 2 is started. The

  That is, as shown in FIG. 5A, immediately after the “mold opening” of the casting mold 2 is completed, the casting product 20A is pressed by the injection tip 26 while being gripped at one end by the take-out robot 8. Thus, the rear end surface (the end surface facing the movable mold 22 in the cast product 20A) is held against the front surface of the movable mold 22 formed in a substantially flat shape.

  At this time, the nesting part 131 of the movable nesting unit 103 is inserted into the cast product 20A, and the cast product 20A is hooked by the movable nesting unit 103.

When the “die opening” of the casting mold 2 is completed, the casting product 20 </ b> A is gripped at one end by the take-out robot 8 provided in the vacuum casting apparatus 101.
Thereafter, as shown in FIG. 5B, when the injection tip 26 moves forward, the cast product 20A is released from the pressed state of the injection tip 26, and the movable nesting unit 103 slides backward. Start.

When the movable nesting unit 103 slides backward, first, the water jacket insert 134 and the core pin 135 are slid backward.
That is, the water jacket insert 134 and the cast pin 135 are directly fixed to the front surface of the slide plate 132 (front plate 132a), and follow the sliding of the slide plate 132 to the rear, The jacket insert 134 and the core pin 135 are slid rearward.

  On the other hand, the bore pin insert 133 is supported so as to be slidable back and forth in the recess 132f formed in the slide plate 132 via the connecting portion 133B and the locking portion 133C. Even if the sliding is started, it does not slide backward immediately but stays in the casting product 20A.

  Then, the rearward movement distance of the slide plate 132 is such that the thickness dimension of the intermediate plate 132b (dimension Y shown in FIG. 4) and the thickness dimension of the locking portion 133C of the bore pin insert 133 (dimension Z shown in FIG. 4). When the difference (Y-Z) is reached, the front end surface of the locking portion 133C comes into contact with the rear surface of the front side plate 132a.

  Thereafter, as shown in FIG. 5C, when the movable nesting unit 103 slides further rearward, the bore pin nesting 133 is pulled out rearward by the front side plate 132a of the slide plate 132 via the locking portion 133C. At the same time, the water jacket insert 134 and the core pin 135 fixed to the front surface of the front plate 132a are further slid rearward.

  Then, when the insert portion 131 including the bore pin insert 133, the water jacket insert 134, and the cast pin 135 is completely removed from the cast product 20A, the cast product 20A is formed on the front surface of the movable mold 22 formed in a substantially flat shape. In addition, the rear end face (the end face facing the movable mold 22 in the cast product 20A) is pressed against the rear end face, and is supported only by the take-out robot 8.

  Thereafter, the casting product 20A is taken out from the casting mold 2 by the take-out robot 8, and the demolding of the casting product 20A from the casting mold 2 is completed.

  As described above, the vacuum casting apparatus 1 (101) in the first and second embodiments is divided into a plurality of divided fixed mold 21, movable mold 22, slide molds 23, 23, etc. A reduced pressure casting apparatus 1 (101) for casting a cast product 20A by decompressing the inside of a cavity 24 of a casting mold 2 composed of a mold group consisting of the plurality of mold groups 21, 22, 23, In any one of the mold parts (movable mold 22 in this embodiment), the cavity 24 is protruded from the side surface (front surface of the movable mold 22) toward the cavity 24. A plurality of inserts such as a bore pin insert 33 (133), a water jacket insert 34 (134), and a cast pin 35 (135) are provided, and the plurality of inserts 33, 34, 35 (133, 134, 135) It is set to be arranged to be movable in the (longitudinal direction in the movable mold 22) direction forward and backward relative to I 24.

  Further, the vacuum casting method based on the vacuum casting apparatus 1 (101) of the first and second embodiments is divided into a plurality of divided fixed die 21, movable die 22, slide die 23, 23,. A vacuum casting apparatus 1 (101) for casting a cast product 20A by decompressing the inside of a cavity 24 of a casting mold 2 composed of a group of molds made up of a plurality of mold groups 21, 22, 23... Are projected from the side surface (front surface of the movable mold 22) on the cavity 24 side toward the cavity 24 in any one mold part (movable mold 22 in this embodiment). A plurality of inserts such as a bore pin insert 33 (133), a water jacket insert 34 (134), and a core pin 35 (135), and the plurality of inserts 33, 34, 35 (133, 134, 135) Said key The casting product 20A is disposed so as to be movable forward and backward with respect to the bite 24 (front and rear direction in the movable mold 22), and when the casting product 20A is removed from the casting mold 2, the casting mold 2 is opened. After that, the plurality of inserts 33, 34, and 35 (133, 134, and 135) are retracted (moved backward) with respect to the cavity 24.

  By having such a configuration, according to the reduced pressure casting apparatus 1 (101) and the reduced pressure casting method of the first and second embodiments, the cast product from the casting mold in order to ensure good casting quality. In order to prevent the release agent and cooling water from entering the cavity through the gap between the extrusion pin for extruding the extrusion pin and the through hole for the extrusion pin formed in the casting mold, the extrusion pin itself In addition, it is possible to provide a reduced pressure casting apparatus and a reduced pressure casting method that can be surely removed from the casting mold without damaging the cast product.

  That is, in the reduced pressure casting apparatus 1 (101) and the reduced pressure casting method in the first and second embodiments, after the mold 2 is "opened", a plurality of inserts 33, 34 and 35 (133 134 and 135) are moved to the rear side of the movable mold 22, and the plurality of inserts 33, 34 and 35 (133, 134 and 135) are pulled out from the inside of the cast product 20A. It is not necessary to provide an extruding pin for extruding a cast product from 34 · 35 (133 · 134 · 135).

Further, when the plurality of inserts 33, 34, and 35 (133, 134, and 135) move to the rear surface side of the movable mold 22, the cast product 20A and the plurality of inserts 33, 34, and 35 (133, 134, and 135) are provided. The cast product 20 </ b> A also tends to move to the rear side of the movable mold 22 due to the mold release resistance, but the cast product 20 </ b> A is dammed to the movable mold 22 on the way.
That is, when the plurality of inserts 33, 34, and 35 (133, 134, and 135) are pulled out from the inside of the cast product 20A, the cast product 20A has a rear end surface (a plurality of inserts 33, 34, and 35 (133, 134, and 133)). 135), the surface on the side on which the front surface of the movable mold 22 formed in a substantially flat shape (a plurality of inserts 33, 34, 35 (133, 134, 135) is projected). ).

Accordingly, the reaction force generated when the plurality of inserts 33, 34, and 35 (133, 134, and 135) are pulled out from the inside of the cast product 20A is received by the entire front surface of the movable mold 22 formed in a substantially planar shape. Compared to the case where the cast product 20A is held by the reaction force in the shearing direction generated between the cast product 20A and the slide molds 23, 23... (Movable intermediate mold) as in the prior art. The posture of the cast product 20A can be held more stably.
Therefore, the cast product 20A is surely removed from the casting mold 2 without worrying about breakage during the removal.

  In the vacuum casting apparatus 1 (101) in the first and second embodiments, the movable mold (mold part) 22 including the plurality of nestings 33, 34, and 35 (133, 134, and 135) is There are first and second through holes 22c and 22e that communicate the surface on the cavity 24 side (the front surface of the movable mold 22) and the surface opposite the surface on the cavity 24 side (the rear surface of the movable mold 22). The plurality of inserts 33, 34, and 35 (133, 134, and 135) are inserted into the first and second through holes 22c and 22e, and the plurality of inserts 33, 34, and 35 (133 134 and 135), the end opposite to the cavity 24 side (the rear end of the plurality of nestings 33, 34, and 35 (133, 134, and 135)) is connected by the slide plate 32 (132). I am going to do that.

  In the vacuum casting method in the first and second embodiments, the movable mold (mold part) 22 including the plurality of nestings 33, 34, and 35 (133, 134, and 135) is disposed on the cavity 24 side. A plurality of first and second through holes 22c and 22e that communicate a surface (front surface of the movable mold 22) and a surface opposite to the surface on the cavity 24 side (rear surface of the movable mold 22); Nests 33, 34, and 35 (133, 134, and 135) are inserted into the first and second through holes 22c and 22e, and the plurality of nests 33, 34, and 35 (133, 134, and 135) The end of the cavity 24 opposite to the cavity 24 (the rear ends of the plurality of inserts 33, 34, 35 (133, 134, 135)) is connected by a slide plate 32 (132). (132) By causing regression against serial cavity (moving backward), wherein the plurality of nested has decided to regress (moved rearward) with respect to said cavity.

  As described above, since the plurality of nestings 33, 34, and 35 (133, 134, and 135) are configured to move simultaneously through the slide plate 32 (132), the plurality of nestings 33, 34, and 35 ( For the actuator for moving 133, 134, 135), only one hydraulic cylinder for moving the slide plate 32 (132) is required, which is economical.

  Further, in the reduced pressure casting apparatus 1 (101) and the reduced pressure casting method in the first and second embodiments, the penetrating direction of the first and second through holes 22c and 22e (the longitudinal direction in the movable mold 22). The cross-sectional shape (total) of the first and second through holes 22c and 22e is smaller than the cross-sectional shape of the slide plate 32 (132), and the plurality of nestings 33, 34, and 35 (133) are formed. The first and second surfaces of the movable mold (mold part) 22 provided with 134 and 135) on the surface opposite the cavity 24 side (front surface of the movable mold 22) (the rear surface of the movable mold 22). An annular seal member 28 (128) is provided between the outer periphery of the two through holes 22c and 22e and the slide plate 32 (132).

  Further, in the vacuum casting method in the first and second embodiments, the first and second through holes in the through direction of the first and second through holes 22c and 22e (the front-rear direction in the movable mold 22). The movable die having the plurality of inserts 33, 34, and 35 (133, 134, and 135) is formed so that the sectional shape of 22c and 22e (the total) is smaller than the sectional shape of the slide plate 32 (132). The outer peripheral portion of the first and second through holes 22c and 22e on the surface (the rear surface of the movable mold 22) opposite to the cavity 24 side surface (the front surface of the movable mold 22) of the (mold part) 22 An annular seal member 28 (128) is provided between the slide plate 32 (132) and the cavity 24 side surface of the movable mold (mold part) 22 (front surface of the movable mold 22). The opposite surface (movable mold 2 The back surface) and the slide plate 32 (132) are used to press the sealing member 28 (128), so that the cavity 24 side and the opposite side of the cavity 24 in the first and second through holes 22c and 22e are formed. Is going to be isolated.

  By having such a configuration, the cavity 24 side (front side) where the plurality of inserts 33, 34, 35 (133, 134, 135) of the movable mold 22 are provided, and the slide plate 32 (132) side ( The rear surface side is reliably isolated by the seal member 28 (128) without being communicated by the first and second through holes 22c and 22e.

Therefore, as in the conventional vacuum casting apparatus 301 as shown in FIG. 7, for example, when the inside of the cavity 324 is decompressed, the inside of the recess 322 a provided on the back surface side of the movable mold 322 is also decompressed at the same time. Depressurization means (vacuum tank 307, vacuum pump 308, etc.) for eliminating the difference in pressure at both ends of the gaps 322f, 322f,... And preventing moisture including a release agent or cooling water from entering the cavity 224. It is no longer necessary to provide
Therefore, the structure of the casting mold 2 (specifically, the movable mold 22) can be simplified, and the entire equipment is economical.

  In the vacuum casting apparatus 101 and the casting method according to the second embodiment, the cast product 20A is a cylinder block, and the plurality of inserts 133, 134, 135 include a plurality of bore pin inserts 133, 133,. The plurality of bore pin inserts 133, 133... Along the protruding direction of the plurality of inserts 133, 134, 135 with respect to the slide plate 132 (the front-rear direction in the movable mold 22). The slide plate 132 is connected to the slide plate 132 so as to be movable.

  Further, in the reduced pressure casting method in the present embodiment, the cast product 20A is a cylinder block, and the plurality of inserts 133, 134, 135 are configured to have a plurality of bore pin inserts 133, 133,. The plurality of bore pin inserts 133, 133,... Are slidable relative to the slide plate 132 along the projecting direction of the inserts 133, 134, 135 (the front-rear direction in the movable mold 22). When the slide plate 132 is connected to the plate 132 and retracts (moves backward) with respect to the cavity 24, a plurality of inserts other than the bore pin inserts 133, 133,... (Water jacket insert 134 and cast pin) 135) retreat (move backward), then the bore pin inserts 133, 133. It is set to be moved).

  As described above, when the slide plate 132 is moved toward the rear surface side of the movable mold 22, a time lag is generated between the bore pin insert 133 and the water jacket insert 134 including the core pin 135. By doing so, the output of the actuator provided in the slide plate 132 can be reduced, and the entire equipment is economical.

  That is, when pulling out the plurality of nesting portions 133, 134, 135 from the cast product 20A, first, the water jacket insert 134 including the cast pin 135 is pulled out from the cast product 20A, and then the bore pin insert 133 is cast. It is pulled out from the product 20A.

  Therefore, as an output required for the actuator, immediately after the movement of the slide plate 132, the water jacket insert 134 including the core pin 135 having a relatively small mold release resistance with respect to the casting mold 2 is pulled out from the cast product 20A. In order to pull out only the bore pin insert 133 from the cast product 20A, the release resistance with respect to the casting mold 2 is relatively larger than that of the water jacket insert 134 including the cast pins 135. Is sufficient.

  Therefore, if it considers as the whole installation, about the actuator provided in the slide board 132, the output required in order to extract these several nest | insert parts 133 * 134 * 135 from the casting product 20A can be reduced.

  Further, in the reduced pressure casting apparatus 101 and the reduced pressure casting method in the second embodiment, a locking portion 133C made of a short column member is formed at the end of the bore pin insert 133 on the slide plate 132 side, and the slide The plate 132 has a first locking surface (a rear surface of the front plate 132a) that is locked to the cavity 24 side surface of the locking portion 133C, and a surface opposite to the cavity 24 side surface of the locking portion 133C. A second locking surface (front surface of the rear side plate 132c), and the locking portion 133C has the first locking surface (rear surface of the front side plate 132a) and a second locking surface (rear side). It is supposed that the movement of the bore pin inserts 133, 133... Relative to the slide plate 132 is restricted by being locked to the front surface of the side plate 132c.

  By having such a configuration, there is no other complicated structure such as providing an actuator in the bore pin insert 133 separately, and between the bore pin insert 133 and the water jacket insert 134 including the core pin 135, A configuration that causes a time lag can be realized and is economical.

1 Vacuum casting equipment (first embodiment)
2 Casting mold 20A Casting product 21 Fixed mold 22 Movable mold 22c First through hole 22e Second through hole 23 Slide mold 24 Cavity 28 Seal member 32 Slide plate 33 Bore pin insert 34 Water jacket insert 35 Casting pin 101 Depressurization Casting device (second embodiment)
128 First seal member 132 Slide plate 132a Front plate 132c Rear plate 133 Bore pin insert 133C Locking portion 134 Water jacket insert 135 Cast pin

Claims (10)

A vacuum casting apparatus for casting a cast product by decompressing a cavity of a casting mold composed of a plurality of divided mold groups,
In any one mold part of the plurality of mold groups, a plurality of nests protruding from the side surface on the cavity side toward the cavity are provided.
The plurality of nestings are arranged so as to be movable in a direction to advance and retreat with respect to the cavity.
A vacuum casting apparatus characterized by that. The mold part including the plurality of nestings has a through-hole that communicates a surface on the cavity side and a surface opposite to the surface on the cavity side,
The plurality of nests are inserted into the through holes,
The ends of the plurality of nestings opposite to the cavity side are connected by a slide plate.
The reduced-pressure casting apparatus according to claim 1, wherein: In the penetration direction of the through-hole, the cross-sectional shape of the through-hole is formed smaller than the cross-sectional shape of the slide plate,
An annular seal member is provided between the outer peripheral portion of the through hole on the surface opposite to the cavity side surface of the mold part including the plurality of inserts and the slide plate.
The reduced-pressure casting apparatus according to claim 2, wherein: The casting product is a cylinder block;
The plurality of nestings are configured with a plurality of bore pin nestings;
The plurality of bore pin nestings are
The slide plate is connected to the slide plate so as to be movable along the protruding direction of the plurality of inserts.
The vacuum casting apparatus according to any one of claims 1 to 3, wherein the vacuum casting apparatus is characterized in that At the end of the bore pin insert on the slide plate side, a locking portion made of a short column member is formed,
The slide plate has a first locking surface that is locked to the cavity-side surface of the locking portion, and a second locking surface that is locked to a surface opposite to the cavity-side surface of the locking portion. And
The locking portion is locked to the first locking surface and the second locking surface, thereby restricting movement of the bore pin nest with respect to the slide plate.
The reduced pressure casting apparatus according to claim 4, wherein: A vacuum casting method for casting a cast product by decompressing a cavity of a casting mold composed of a plurality of divided mold groups,
In any one mold part of the plurality of mold groups, a plurality of nests protruding from the side surface on the cavity side toward the cavity are provided.
The plurality of nestings are arranged so as to be movable in a direction to advance and retreat with respect to the cavity,
Demolding of the cast product from the casting mold is performed by retreating the plurality of inserts with respect to the cavity after the mold is “opened”.
A vacuum casting method characterized by the above. The mold part including the plurality of nestings has a through-hole that communicates a surface on the cavity side and a surface opposite to the surface on the cavity side,
The plurality of nests are inserted into the through holes,
The ends of the plurality of inserts opposite to the cavity side are connected by a slide plate,
By retracting the slide plate relative to the cavity, the plurality of nestings retract relative to the cavity;
The vacuum casting method according to claim 6, wherein: In the penetration direction of the through-hole, the cross-sectional shape of the through-hole is formed smaller than the cross-sectional shape of the slide plate,
An annular seal member is provided between the outer peripheral portion of the through hole on the surface opposite to the cavity side surface of the mold part including the plurality of inserts, and the slide plate,
By pressing the seal member with the surface opposite to the cavity side surface of the mold part and the slide plate, the cavity side in the through hole and the opposite side of the cavity are isolated,
The vacuum casting method according to claim 7, wherein: The casting product is a cylinder block;
The plurality of nestings are configured with a plurality of bore pin nestings;
The plurality of bore pin nestings are
The slide plate is connected to the slide plate so as to be movable along the protruding direction of the plurality of nests,
When the slide plate retracts with respect to the cavity, the bore pin nest retracts after a plurality of nests other than the bore pin nest retract.
The vacuum casting method according to any one of claims 6 to 8, wherein the vacuum casting method is characterized. At the end of the bore pin insert on the slide plate side, a locking portion made of a short column member is formed,
The slide plate has a first locking surface that is locked to the cavity-side surface of the locking portion, and a second locking surface that is locked to a surface opposite to the cavity-side surface of the locking portion. And
The locking portion is locked to the first locking surface and the second locking surface, thereby restricting movement of the bore pin nest with respect to the slide plate.
The vacuum casting method according to claim 9, wherein:

Images