JP3425263B2 - Shell molding machine - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shell molding machine for molding a shell mold for casting a cylindrical product such as a sleeve of a cylinder block.

[0002]

2. Description of the Related Art Generally, a cylinder block 80 is shown in FIG.
As shown in FIG. 8, a cylindrical sleeve 81 is manufactured by casting, and the sleeve 81 is placed in a cavity of a die casting mold.
A plurality of aluminum alloys are housed side by side, and a molten aluminum alloy is injected into the cavity by a die casting method.

In this case, a sleeve having a large number of projections on its surface is used in order to well bite the sleeve 81 into the aluminum alloy block body 82.
Such sleeves have been produced one by one in a cylindrical shape by casting using a sand mold made of green sand or hard sand.

[0004]

Since the sleeve having a large number of protrusions formed on the surface thereof is manufactured in a cylindrical shape by casting using a sand mold made of raw sand or slag hard sand, a storage core is required. It is very laborious, inefficient, inefficient,
There is a problem that it is not possible to mass-produce two or more sleeves.

The present invention solves the above problems, and an object of the present invention is to eliminate the stop of the shell sand that has entered between the spiny nesting recess and the spiny nesting. It is an object of the present invention to provide a shell-type molding apparatus that operates smoothly and can easily mass-produce an accurate half-shell type shell mold.

[0006]

In order to achieve the above object, in a shell-type molding apparatus according to the present invention, a plurality of product inserts each having a half-cylindrical shape are arranged side by side so that arc-shaped surfaces of adjacent product inserts are formed. The undercut portions are formed with spiny nesting insertion recesses, and these spiny nesting insertion recesses have an arcuate surface having the same curvature as the arcuate surface of the product nest, and a large number of protrusions are provided on this arcuate surface. A lower mold with spiny nesting that can appear and disappear,
An upper die having a cavity formed by continuously forming a plurality of recesses facing the plurality of product nests of the lower die in the upper die body, a spiny nest actuating means for retracting the spiny nest, and a spinee nest insertion recess. includes a sand discharge means for discharging the sand that has entered between the spiny nest, the sand discharge means, said spiny nested interpolation
Sand removal hole that opens at the bottom of the recess and connects to the discharge side
Of the sand removal hole on the side of the spiny nesting insertion recess
The space provided between the opening and the opening on the sand discharge side.
The air blowing opening communicates with the sand removing hole,
Empty from the blowing opening to the opening on the side where the sand is discharged.
And an air blowing hole for blowing air.

A shell type molding apparatus according to the present invention
Further, as the sand discharging means, the spiny container
The child insert recess and this spiny insert insert recess into the insert
The arc of the product nest between the spiny nest
From the top surface side to the bottom of the spiny nesting insertion recess.
You may provide the groove part which encloses.

[0008]

[0009]

With this structure, the upper mold is fitted to the lower mold,
Insert the product insert of the lower mold into the concave part of the cavity, form a space in the shape of the sand mold to be molded between them, blow the shell sand into the space, and heat the upper and lower molds. When the shell sand is hardened and the shell mold is formed, the spiny nest actuating means is activated to retract the spiney nest, and the recesses of the reverse copy of the numerous projections of the spinee nest are formed in the undercut portion of the inner surface thereof. Although a large number of half-shell shell molds are manufactured, the shell sand blown into the space penetrates between the spiny nest insertion recess and the spiny nest.

In this case, air is blown into the air blowing hole, and this air flows through the sand removing hole toward the discharging side, so that the negative pressure effect causes the shell sand to flow from the spiny nesting insertion concave portion toward the sand removing hole side. It is pulled and discharged to the discharge side.
For this reason, the shell sand that has entered between the spiny nest insertion recess and the spiny nest does not stop, the operation of the spiny nest can be smoothly performed, and the shell mold having a precise half-shape can be obtained. Can be mass-produced easily.

Further, by providing a groove which connects the arcuate surface side of the product insert to the bottom of the spiny insert insertion recess between the spiny insert insertion recess and the spinee insert, the spinee insert insertion recess and the spiny insert insertion recess are formed. Since it is possible to prevent the clogging of the shell sand with the spiny nest, it is possible to smoothly operate the spiny nest, and it is possible to easily mass-produce an accurate half shell shape mold. .

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a side view showing a partial cross section of a shell-type molding apparatus according to the present invention, and FIG. 2 is a cross sectional view taken along line AA of FIG.
3 is a sectional view taken along the line BB of FIG. 2, and FIG. 4 is a sectional view of FIG.
It is sectional drawing which follows the C line.

The shell type molding apparatus according to the present invention comprises a lower mold 1
And the upper mold 2 are roughly configured. The lower mold 1 is provided with a die base 4 fixedly mounted on a pedestal 3, and a lower mold heating plate body 5 is fixedly mounted on the die base 4, and the lower mold heat A product nesting structure 11 is attached to the plate body 5. The lower mold hot plate body 5 and the product nesting structure 11 constitute a lower mold body.

The lower die hot plate body 5 has a hot plate block body 6 which is rectangular in plan view as shown in FIGS. 7 to 9, and an upper surface portion 6 A of the hot plate block body 6 is provided on the upper surface portion 6 A. The left side (MS side) and 2 with the center as Sakai seen from the worker side P
Nested recessed group 7 in each row, 2 rows on the right side (MP side)
Is provided. These nesting mounting recess groups 7 are formed by arranging four nesting mounting recesses 8 at a predetermined interval in the front-rear direction when viewed from the operator side P. A plurality of sand removing holes 9 are formed on the bottom surface of these nesting mounting recesses 8, and these sand removing holes 9 are formed in the lower surface portion 6B of the hot plate block body 6. The hot plate block body 6 has a structure shown in FIG.
Further, as shown in FIG. 6, air blowing holes 9A communicating with the respective sand removing holes 9 are formed.

Further, in the hot plate block body 6, three pin insertion holes 10 are obliquely (tilted forward) from the front side (worker side P) of the hot plate block body 6 toward the three nesting recesses 8 on the front side. Further, three pin insertion holes 10 are formed obliquely (rearward) from the rear surface side toward the three rear side nesting mounting recesses 8. Further, a large number of heater insertion holes 60 are formed in the left surface portion and the right surface portion of the hot plate block body 6, and heaters 61 are inserted into these heater insertion holes 60 (see FIG. 1).

As shown in FIGS. 10 to 13, the product nesting structure 11 is provided with two rows of four product nesting groups 12, each of which has a front product nest 12A. It has two intermediate product inserts 12B and a rear product insert 12C. The product nest 12A on the front side has a rectangular fitting portion 14 formed in the lower part of the nest body 13 having a semicircular cross section.
The flat mating surface portion 15 is formed on the rear portion, and a rectangular spiny nesting insertion recess 16 in a plan view is formed on the rear side portion of the surface of the nesting body 13. Further, from the front surface of the fitting portion 14, the spiny nesting insertion recess 1 is formed.
6, a rod insertion hole portion 17 is formed extending to the end surface of 6,
In addition, from the spiny nesting insertion concave portion 16 to the fitting portion 1
A sand removing hole 18 is formed on the lower surface of No. 4.

The intermediate product insert 12B has a rectangular fitting portion 14 at the bottom of the insert main body 13 having a semicircular cross section.
Is formed, and flat mating surface portions 15 are formed on the front and rear portions of the nesting body 13, and rectangular spiny nesting insertion concave portions 16 having a rectangular shape in plan view are formed on the front and rear portions of the surface of the nesting body 13. There is. Further, a rod insertion hole portion 17 is formed from the front surface portion of the fitting portion 14 to the end surface of the rear side spiny nesting insertion concave portion 16, and the rear surface portion of the fitting portion 14 is located at the front side of the spiny nesting insertion concave portion 16.
A rod insertion hole portion 17 is formed so as to extend to the end surface of the. In addition, from the spiny nesting insertion concave portion 16 to the fitting portion 14
A sand removing hole 18 is formed to extend to the lower surface of the.

The product insert 12C on the rear side has a rectangular fitting portion 14 at the bottom of the insert main body 13 having a semicircular cross section.
To form a flat mating surface portion 15 on the front portion of the nesting body 13.
Is formed, and is a rectangular shape in the plan view of the front side portion of the surface of the nesting main body 13 in the shape of a rectangular spiny nesting insertion recess 16
Is formed. Further, a rod insertion hole portion 17 is formed from the rear surface portion of the fitting portion 14 to the end surface of the spine nesting insertion concave portion 16, and a sand removing hole is formed from the spiny nesting insertion concave portion 16 to the lower surface portion of the fitting portion 14. 18 is formed.

Then, the rod insertion hole portion 1 in the front, middle and rear product nests 12A, 12B and 12C.
7 is a concave portion for mounting a spiny nest 8 with the middle part thereof as a sakai.
The side has a small diameter, and the large diameter hole portion 17A and the small diameter hole portion 1
A step 17C is formed between the step 7C and 7B. Then, in the rod insertion hole portion 17, the small diameter hole portion 17B.
Have the same length L1.

Then, four sets of product nesting groups 12 are mounted in the four sets of nesting mounting recessed groups 7 of the lower hot plate member 5. That is, the product insert 12A on the front side is fixed by bolting after fitting the fitting portion 14 to the front insert mounting recess 8 of the nest mounting recess group 7, and the intermediate product insert 12B is similarly fixed. The insert nesting recess 8 in the middle of the insert nesting recess group 7 is mounted, and the rear product nest 12C is similarly mounted in the nest fitting recess 8 on the rear side of the nest fitting recess group 7.

In this case, adjacent product nests 12A, 1
2B and 12C are in contact with each other at a mating surface portion 15, and a spiny nesting insertion recess 16 is provided in an undercut portion R formed by the arc-shaped surfaces of adjacent product nests 12A, 12B and 12C. The sand removal holes 18 formed in the spiny nesting insertion recesses 16 communicate with the sand removal holes 9 provided in the lower mold hot plate body 5, and these sand removal holes 9 are formed in the die base 4 Which is connected to the discharge hole 9B provided in the
And the discharging hole 9B constitute a sand discharging means.

The rod insertion hole 17 of the front product insert 12A and the front rod insertion hole 17 of the two intermediate product inserts 12B are inserted into the lower die plate 5 by inserting the three front pins. The rod insertion hole 17 on the rear side of the product insert 12C and the two intermediate product inserts 12B, which communicates with the hole 10, is provided on the rear side 3 provided on the lower mold hot plate body 5.
It communicates with the pin insertion hole 10 of the book.

A spacer block 19 is interposed between the inner end surfaces of the product nests 12A, 12B and 12C of the two product nest groups 12 facing each other. The spacer blocks 19 are bolted to the lower mold. It is fixed to the heating plate 5. Also, product nests 12A, 12B, 12
At the outer end of C, left and right end pressing members 20 and 21 are provided by being fixed to the lower mold hot plate body 5 by bolts.

A spline nest 22 is inserted in the spline nest insertion recess 16 so as to be retractable. As shown in FIGS. 14 to 17, the spiny nest 22 has a nest body 23, and the surfaces of the nest body 23 are front, middle, and rear product nests 12A, 12B,
The arcuate surface 23a has the same curvature as the arcuate surface of 12C, and a large number of protrusions 24 are formed on the arcuate surface 23a. In addition, a groove portion 23b is formed at one end of the nesting body 23 to receive sand intrusion. Further, the nest body 23 is provided with two rods 25 so as to project downward, and an end portion of the rod 25 is formed as a screw portion 25a. The groove 23b at one end of the insert main body 23, the sand removing holes 18 and 9, the air blowing hole 9A, and the discharging hole 9B constitute a sand discharging means.

The rod 25 of the spiny nest 22 thus constructed has the rod insertion hole 1
7 is inserted into the spiny nesting insertion concave portion 16 so as to be retractable.

The front and rear parts of the die base 4 are shown in FIG.
As shown in FIG. 3, sliding block positioning arms 26 and 27, which are sliding block positioning holding members, are fixedly installed at the left and right, and the front and rear intermediate parts of the die base 4 are shown in FIG. As shown in FIG.
29 is fixed. The front (one) left and right sliding block positioning arms 26 are provided with a pair of support pieces 30.
The support piece portions 30 are formed with pin holes 31. The front left and right sliding block positioning arms 26 position and hold the front (one) sliding block 32A.

That is, this sliding block 32A is shown in FIG.
As shown in FIGS. 8 and 19, a block main body 33 having a rectangular cross section is provided, and pin sliding mechanism portions 34 are provided at both ends of the block main body 33. The pin sliding mechanism portion 34 has a hole portion 33 formed in the block body 33.
The guide bushes 35 and 36, which are pin holding portions, are inserted into a and the guide bushes 35 and 36 are pressed by the bush pressers 37 and 38. Further, in the block body 33, a pair of three pin insertion holes 39 are formed in parallel in the vertical direction at two places on each of the left and right sides. On the back side of these pin insertion holes 39, a pin receiving member 40 is fixedly attached to the block body 33 as shown in FIG. The pin receiving member 40 has the pin insertion hole 39.
A screw hole 41 is formed so as to face the end face portion of the.

In the sliding block 32A constructed as described above, the guide bushes 35, 36 of the pin sliding mechanism portion 33 can slide on the sliding pin 42 supported by the pair of supporting piece portions 30. It is held by the left and right sliding block positioning arms 26 on the front side.

As shown in FIG. 5, the pull-out pin 43 has a screw hole 43a at its front end surface and a polygonal (octagonal) collar-shaped portion 43b at its rear end. The pull-out pin 43 is connected to the pin insertion hole 3 of the sliding block 32.
9, the withdrawal pins 43 are inserted into the pin insertion holes 10 and the screw portions 25a of the rods 25 of the spiny insert 22 are screwed into the screw holes 43a of the withdrawal pins 43. The pull-out pin 43 is connected to the spiny nest 22. In this case, a stopper portion 43F is formed between the rod 25 and the end portion of the extraction pin 43. In addition, the pin receiving member 40 has a polygonal shape (octagonal) for stopping the rotation of the pull-out pin 43.
The washer 40A is inserted.

Then, the product nests 12A, 12B,
12C is provided with a step portion 17C of the rod insertion hole 17, and the end face of the extraction pin 43 that abuts against the step portion 17C is used as a stopper portion 43F. In the rod insertion hole portion 17, the step portion 17C is used as a sakai. The small diameter hole portion 17B is formed on the side of the spiny nesting insertion concave portion 16 and the small diameter hole portion 1 is formed.
7B length dimension L1 for all the product nests 12A,
By making the same in 12B and 12C, a stopper means is formed where the thermal expansion of the extraction pin 43 is the same.

Further, the screw hole 41 of the pin receiving member 40
The adjusting bolts 44 are screwed into the end of the adjusting bolts 44 and between the end faces of the adjusting bolts 44 and the end faces of the collar-like portions 43b of the extracting pins 43 in order to absorb the length displacement due to the thermal expansion of the extracting pins 43. A gap t is formed, which constitutes the thermal expansion absorbing means of the extraction pin 43.

One working cylinder 45A is attached to the front (one) cylinder holding member 28,
The piston rod 46A of the working cylinder 45A is fixed to the central portion of the sliding block 32A. Then, the working cylinder 45A and the sliding block 32A
The pull-out pin 43 and the pull-out pin 43 constitute a spiny nesting operation means.

The rear (other) sliding block 32B
Has the same configuration as the front sliding block 32A, and the rear sliding block 32B is positioned and held by the rear (other) left and right sliding block positioning arms 27 in the same manner as the front sliding block 32A. In addition, the pull-out pins 43 are inserted into the pin insertion holes 39 of the sliding block 32B.
0 is inserted in the screw hole 43 of the extraction pin 43,
The threaded portion 25a of the rod 25 of the spiny nest 22
Are screwed together, and the extraction pin 43 is connected to the spiny nest 22.

Then, the other working cylinder 45B is attached to the rear (other) cylinder holding member 28,
The piston rod 46B of the working cylinder 45B is fixed to the central portion of the sliding block 32B. Then, the working cylinder 45B and the sliding block 32B
The pull-out pin 43 and the pull-out pin 43 constitute a spiny nesting operation means.

Further, as shown in FIG. 2, the pedestal 3, the die base 4 and the lower mold hot plate body 5 are provided with eject pin holes 46 at a plurality of positions. An eject pin 47 is inserted in 46,
These eject pins 47 are connected to each other and are moved up and down by an eject raising / lowering operation mechanism section (not shown), and these constitute push-up means.

The upper mold 2 has an upper mold body 48,
As shown in FIGS. 22 to 24, the upper mold body 48 has a cavity 50 formed on the mold matching surface 49 side, and the cavity 50 forms the product nest 12A of the lower mold 1,
A plurality of recessed portions 51 facing 12B and 12C are formed continuously, and a gate 52 communicating with each recessed portion 51 is provided in the upper mold body 48. Also, the upper mold body 48
Has a heater insertion hole 6 that goes from the front to the rear.
2 are formed in large numbers, and heaters 63 are inserted into these heater insertion holes 62. Also, the upper mold 2 is
It is moved up and down by an up-and-down actuating mechanism (not shown) which is an upper die moving means.

Next, description will be made on the molding of the shell mold by the shell mold molding apparatus configured as described above.

In the lower mold 2, the working cylinder 4
5A and 45B are extended to operate the sliding block 32.
By moving (advancing) A and 32B, the pull-out pin 43 is moved, and the end surface 43F of the pull-out pin 43 is brought into contact with the step portion 17C of the rod insertion hole 17. Therefore, the spiny nest 22 coupled to the pull-out pin 43 is advanced at the same time, and the arcuate surface 23a of the spiny nest 22 is attached to the front, middle, and rear product nests 12.
A large number of protrusions 24 on this arcuate surface 23a are projected in conformity with the surfaces of A, 12B and 12C.

Next, the upper die 2 is lowered by the operation of the elevating and lowering mechanism, and the die matching surface 49 of the upper die body 48.
Is aligned with the mating surface 65 of the lower mold body 64, and the product insert 12A of the lower mold 1 is inserted into the concave portion 51 of the cavity 50.
12B and 12C are inserted, and a space H in the shape of a sand mold to be molded is formed between them.

Next, shell sand (silica sand plus thermosetting polymer material) is blown into the space H from the plurality of gates 52 provided in the upper mold body 48.

Next, the heaters 61 and 63 provided on the upper and lower molds 1 and 2 are energized to raise the temperature to about 350 ° C. and the lower mold body 6
4 and product nests 12A, 12B, 12C are heated.
This heating cures the shell sand and molds the shell mold 70.

Next, the energization of the heaters 61 and 63 is stopped, the upper mold 2 is raised by the operation of the elevating operation mechanism, and the upper mold 2 is separated from the lower mold 1. In this state,
A shell mold 70 is attached to the product inserts 12A, 12B, 12C side of the lower mold 1.

Next, in the lower mold 2, the actuating cylinders 45A and 45B are contracted to retract the sliding blocks 32A and 32B, thereby retracting the pull-out pin 43 and simultaneously moving the spiny nest 22. The arcuate surface 23a is retracted and pulled in from the surfaces of the front, middle, and rear product nests 12A, 12B, 12C, and a large number of protrusions 24 provided on the arcuate surface 23a.
Is released from the shell mold 70. In this case, the protrusion 2
When the length of 4 is about 2 mm, the retracted amount of the spiny nest 22 is about 5 mm.

Next, the eject raising / lowering operation mechanism is operated to raise the eject pin 47 to raise the shell mold 70.
Is pushed up and the shell mold 70 is released. This shell mold 70 has a half-divided shape, and a large number of recesses of the reverse copy of the large number of protrusions 24 of the spiny insert 22 are formed in the undercut portion of the inner surface thereof.

Next, in the next step, as shown in FIG. 25, four bore cores 71 are set, and the mating surface portions 70A of the shell mold 70 having a half-divided shape are bonded together with an adhesive to form a shell. A mold template is created.

After this shell mold mold is transported to the casting site, aluminum alloy is poured in the casting process to cast four sleeves W shown in FIG. A large number of protrusions 24 'are formed on the undercut sleeve R'of the sleeve W. Then, the sleeve W is cast into an aluminum alloy by a die casting method to form a cylinder block S shown in FIG.

According to the above-mentioned embodiment, the shell sand blown into the space H has the spiny nesting recess 1 formed therein.
6 and the spiny nest 22 to prevent the movement of the spiny nest 22, but the groove 23b at one end of the nest body 23, the sand removing holes 18, 9 and the air By forming the sand discharging means by the blowing hole 9A and the discharging hole 9B, the air blowing hole 9A
Since air is blown into the sand removal hole 9 and the air flows toward the discharge side, the negative pressure effect causes the shell sand to be drawn from the spiny nesting recess 16 toward the sand removal hole 18 and discharged to the discharge side. It For this reason, the shell sand that has entered between the spiny nesting recess 16 and the spiny nesting 22 does not stop, and the operation of the spiny nesting 22 can be performed smoothly.

Further, the spiny nesting insertion concave portion 16 is provided.
And the product nest 1 between the spiny nest 22 and
From the arcuate surface side of 2, the spine nesting insertion recess 1
By providing the groove portion 23b which communicates with the bottom portion of 6, it is possible to prevent the clogging of the shell sand between the spiny nesting insertion recess 16 and the spiny nesting 22, so that the operation of the spiny nesting 22 can be performed smoothly. It can be carried out.

[0049]

As described in detail above, according to the shell-type molding apparatus of the present invention, the upper mold is aligned with the lower mold, and the product insert of the lower mold is inserted into the concave portion of the cavity. A space in the shape of a sand mold to be molded is formed between the two, the shell sand is blown into the space, the upper and lower molds are heated, and the shell sand is hardened to mold the shell mold. The actuating means is actuated to retract the spiny nest, and a half-shell type shell mold in which a large number of recessed portions of the projection of the spiny nest are formed in the undercut portion of the inner surface thereof is manufactured. The shell sand blown into the space penetrates between the spiny nest insertion recess and the spiny nest.

In this case, air is blown into the air blowing hole, and this air flows through the sand removing hole to the discharging side, so that the negative pressure effect causes the shell sand to move from the spine nesting insertion concave portion to the sand removing hole side. It is pulled and discharged to the discharge side.
For this reason, the shell sand that has entered between the spiny nest insertion recess and the spiny nest does not stop, the operation of the spiny nest can be smoothly performed, and the shell mold having a precise half-shape can be obtained. Can be mass-produced easily.

Further, a groove is formed between the spiny nest insertion recess and the spiny nest so as to communicate with the bottom of the spiny nest insertion recess from the arcuate surface side of the product nest. Since it is possible to prevent the clogging of the shell sand with the spiny nest, it is possible to smoothly operate the spiny nest, and it is possible to easily mass-produce an accurate half shell shape mold. .

[Brief description of drawings]

FIG. 1 is a partial cross-sectional side view of a shell-type molding apparatus according to the present invention.

FIG. 2 is a sectional view taken along the line AA of FIG.

3 is a cross-sectional view taken along the line BB of FIG.

4 is a cross-sectional view taken along the line CC of FIG.

5 is an enlarged view of a portion D in FIG.

FIG. 6 is an enlarged view of a section D-1 of FIG.

FIG. 7 is a plan view of a lower hot plate body.

8 is a cross-sectional view taken along the line EE of FIG.

9 is a sectional view taken along the line FF of FIG.

FIG. 10 is a plan view of a product nesting structure.

11 is a cross-sectional view taken along the line GG of FIG.

12 is a partial cross-sectional view taken from the direction I in FIG.

FIG. 13 is a plan view of a single product nest.

FIG. 14 is a plan view of a spiny nest.

FIG. 15 is a side view of the same spiny nest.

16 is a sectional view taken along the line JJ of FIG.

17 is a cross-sectional view taken along the line KK of FIG.

FIG. 18 (1) is a front view of a sliding block mechanism portion. (2) is a sectional view taken along line LL of (1).
(3) is a sectional view taken along the line TT of (2).

FIG. 19 (1) is a front view of a sliding block.
(2) is a sectional view in which the same portion is omitted. (3) is (2)
FIG. 6 is a view from the direction M in FIG.

FIG. 20 is a plan view of the pin receiving member.

21 is a cross-sectional view taken along the line NN of FIG.

FIG. 22 is a plan view of the upper mold.

23 is a cross-sectional view taken along the line OO of FIG.

24 is a cross-sectional view taken along the line QQ of FIG.

FIG. 25 is a plan view of a shell mold including a bore core and a half-shell type mold.

FIG. 26 is a perspective view of a quadruple sleeve.

FIG. 27 is a perspective view of a cylinder block.

FIG. 28 is a perspective view of a conventional cylinder block.

[Explanation of symbols]

1 Lower mold 2 Upper mold 9, 18 Sand removal hole 9A Air blow hole 9A 9B discharge hole 12A, 12B, 12C Product nesting 16 Spiny nesting recess 17 Rod insertion hole 22 Spiny Nesting 23a Arc surface 24 protrusions 32A, 32B sliding block 43 Extraction pin

Front page continuation (72) Inventor Yasuo Kawai 1907 Hirata-cho, Suzuka-shi, Mie Honda Motor Co., Ltd. Suzuka Factory (56) Reference JP-A-6-190504 (JP, A) JP-A-55-128344 ( JP, A) Actual development Sho 61-77156 (JP, U) Actual development Hei 5-70745 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) B22C 13 / 08,9 / 06 B22D 17 / 22,19 / 00

Claims (2)

(57) [Claims] 1. A plurality of product inserts each having a half-cylindrical shape are arranged, a spiny insert insertion recess is formed in an undercut portion formed by an arcuate surface of adjacent product inserts, and the spiny insert insertion recesses are formed in the undercut parts. A lower die having an arcuate surface having the same curvature as the arcuate surface of the product insert and having a plurality of protrusions provided on this arcuate surface so as to be retractable, and an upper die body having the above-mentioned lower die An upper mold having a cavity formed by connecting a plurality of recesses facing a plurality of product nests, a spiny nest actuating means for projecting and retracting the spiny nest, and an intrusion between the spiny nest insertion recess and the spiny nest. A sand discharging means for discharging the formed sand, the sand discharging means being open at the bottom of the spiny nesting insertion concave portion and discharging the sand.
Side of the sand removal hole and the opening of the sand removal hole on the side of the recess for inserting the spiny insert.
Blown between the opening and the opening on the side where sand is discharged.
Blow-in opening communicates with the sand removal hole and blows the air.
Air from the plugging opening to the opening on the side where the sand is discharged.
A shell-type molding apparatus comprising: an air blowing hole for blowing air . 2.The shell type molding apparatus according to claim 1.
hand, The sand discharging means further comprises: The spiny nesting recess and this spiny nesting
Inserted into the insertion recess and between the spiny nest
From the arc-shaped surface side of the product insert, the spiny insert
Equipped with a groove that communicates with the bottom of the insertion recess Shell type molding
Place