JP2502588B2 - Mold making equipment - Google Patents

Description

TECHNICAL FIELD The present invention relates to a mold making apparatus.

(Prior art) As a technique for molding a mold, the opening / closing mold for molding is closed, and the blow hole of the head of the blow tank that stores the molding sand is aligned with the molding sand supply hole of the mold to blow tank. By supplying molding air into the mold by supplying air into the mold, the molding sand is fired by the mold and the molded mold is released from the mold by eject pins and taken out. Is generally known. For example,
Japanese Patent Laid-Open No. 60-60138 describes a technique of attaching and detaching a blow head (blow plate) having the blow hole to a blow tank body in a mold making apparatus.

Thus, in such molding technology, a method of supplying the molding sand to the mold, removing the blow tank from the mold, and attaching the ejecting device to the mold after firing the molding sand is used. There is. In this case, the eject pin is usually supported by an eject plate provided in an elevating unit that is separate from the blow tank, and the elevating unit moves the eject plate up and down to perform the above-mentioned mold release by the eject pin. Is.

(Problems to be Solved by the Invention) In the case of the above-mentioned conventional ejecting means, since the elevating unit is provided separately from the device on the blow tank side, the elevating drive means is required to operate the plurality of eject pins without tilting. (Cylinder device) and elevating guide means are required to be provided, and there is a problem that the mold making device becomes large in size together with the device on the blow tank side. The present invention is intended to solve such a problem.

(Means for Solving the Problems) A mold making apparatus of the present invention includes a blow tank for supplying molding sand to a mold for molding a mold, and at least the molding sand and air connected to the blow tank. A pipe for supplying one of the pipes, a piston is fixed to the outer periphery of the pipe, and a cylinder body is inserted into the pipe so that the pipe serves as a piston rod and is divided into two chambers by the piston. The cylinder body is provided with an eject plate holding means for supporting a plurality of eject pins.

(Operation) In the case of the above-described mold making apparatus, the pipe for the blow tank serves as the piston rod of the cylinder device that operates the eject plate, and the cylinder body moves back and forth using this pipe as a guide, whereby the eject plate moves forward and backward without tilting. become.

(Effect of the invention) Therefore, according to the present invention, the piston is fixed to the pipe for the blow tank, the cylinder main body is fitted and inserted, and the eject plate holding means of the cylinder main body is provided.
The pipe is used as a guide rod for advancing and retracting the piston rod or the eject plate in the cylinder device, so that the eject plate can be advanced and retracted without tilting while reducing the number of parts and downsizing or simplification of the molding machine. Is possible.

(Example) Hereinafter, the Example of this invention is described based on drawing.

In the mold making apparatus shown in FIG. 1, 1 is a mold provided in a molding station, 2 is an upper mold of the mold 1, and 3 is a blow tank. The upper mold 2 is held by a clamp member (not shown) on a support member 6 that can be raised and lowered by a cylinder device 4 and a guide rod 5. The blow tank 3 can be traversed between a molding station, a foundry sand supply station provided with a foundry sand tank 7 and a stage change station provided with a blow tank exchange device 8 on a rail 10 passed between these stations. Movable unit for dolly 11
Supported through 12. Also, in FIG. 1, 13
Is an air tank for supplying blow air.

 The structure of the blow tank 3 is shown in FIG.

The blow tank 3 of this example is an integrated body of a tank and a blow head having a blow hole 14, and three blow holes 14 are provided on each side (a total of six blow holes are shown in the drawing). Is provided). Further, a supply cylinder 16 for receiving the supply of air from the upper wall 15 of the blow tank 3 is provided upright, and a supply port 17 for foundry sand is inserted into the supply cylinder 16.

Then, in the blow tank 3, the pin guide cylinders 18 directed to the respective blow holes 14 are supported by penetrating the upper wall 15, and the eject pins 20 are inserted into the respective blow hole 14 in the respective pin guide cylinders 18. It is possible. The upper end of each eject pin 20 is fixed to the eject plate 21 fitted in the supply cylinder 16 so as to be able to move up and down, and is urged by the spring 22 provided in the pin guide cylinder 18 in the insertion direction with respect to the blow hole 14. . In addition, the lower end surface of each pin guide cylinder 18 is located slightly above the blow hole 14 of the blow tank 3,
It is formed in a pyramid shape so as to form an angle of repose of the foundry sand toward the blow hole 14 with the lower wall surface of the blow tank 3.

The structure of the movable unit 12 is shown in FIGS. 3 and 4.

First, as shown in FIG. 3, the carriage 11 is provided with lifting rods 25, 25 supporting an ejecting device 23 on an upper part and a blow tank supporting plate 24 on a lower end, and a lifting cylinder device 2
It is provided so that it can be raised and lowered at 6.

The eject device 23 is a base plate 27 fixed to the elevating rod 25 and connected to an elevating cylinder device 26.
A pipe 28 for connecting the supply cylinder 16 of the blow tank 3 is fixed to the base plate 27.
The sand supply pipe 17 is passed through. In this case, the outer periphery of the sand supply pipe 17 in the pipe 28 serves as an air passage. The cylinder body 30 is inserted into the pipe 28 by using the pipe 28 as a piston rod. On the other hand, the blow tank support plate 24 is provided with a clamp arm 31 which holds the upper wall 15 of the blow tank 3 on the support plate 24 so as to be rotatable by a cylinder device 32.

The structure of the eject device 23 is shown in cross section in FIG. That is, the piston 33 is fixed to the outer periphery of the pipe 28, and the cylinder body 30 is
It is divided by 33 into an upper chamber and a lower chamber. A clamp plate 35 is fixed to the lower end of the cylinder body 30 via a bracket 34, and a clamp arm 36 for holding the eject plate 21 on the clamp plate 35 is rotatably supported by the cylinder device 37 on the bracket 34. ing.

Further, as shown in FIG. 3, stopper rods 38, 38 are provided on the cylinder body 30. The stopper rods 38, 38 penetrate the cylindrical bodies 40, 40 fixed to the base plate 27 and project upward, and the pipe 28 is provided at the upper end thereof.
Locking bodies 42 that are locked from above are provided on the intermediate stoppers 41, 41 supported by the above. That is, as shown in FIG. 5, the pair of intermediate stoppers 41, 41 are provided so as to project laterally from the support cylinder 43 rotatably fitted to the pipe 28.
A cylinder device 44 is attached to the base plate 27 to rotate both the intermediate stoppers 41 between the locking position and the releasing position.

In the above mold making apparatus, the blow tank 3 is a support plate 24, and the eject plate 21 is a clamp plate.
While holding to 35 with clamp arms 31 and 36,
When air is supplied to the upper chamber of the cylinder body 30, the cylinder body 30 rises and lifts the eject plate 21, and the eject pin 20 has a tip end having a blow hole 14 as shown in FIG.
From the blow tank 3 to the blow position. Next, when air is supplied to the lower chamber of the cylinder body 30 with the intermediate stopper 41 set to the locking position with respect to the locking body 42, the locking of the locking body 42 with respect to the intermediate stopper 41 causes the cylinder body 30 to descend. Blocked midway, eject pin 20
Is inserted into the blow hole 14 as shown in FIG. 7, and its tip projects to an intermediate position approximately corresponding to the height of the upper surface of the upper mold 2. When the intermediate stopper 41 is released and air is supplied to the lower chamber, the eject pin 20 further projects from the intermediate position and its tip is inserted into the foundry sand supply hole 45 of the upper mold 2 as shown in FIG. The eject position is set.

 Next, the operation of the above embodiment will be described.

In the molding station shown in FIG. 1, the upper mold 2 is aligned with the mold 1 as shown in FIG. The blow tank 3 is moved from the changing device 8 of the changing station to the carriage 11
Blow tank 3 picked up by movable unit 12 supported by
The supply cylinder 16 and the pipe are connected. Then, the foundry sand is supplied from the foundry sand tank 7 at the foundry sand supply station and conveyed to the molding station. In this case, as shown in FIG. 3, the blow tank 3 holds and conveys the upper wall 15 of the blow tank 3 to the support plate 24 by the clamp arm 31. The eject pin 20 is urged by the spring 22 so that the blow hole 14
, And the molding sand does not drop from the blow hole 14 during the transportation of the blow tank 3.

Then, in the molding station, first, the blow tank 3 is lowered by the operation of the lifting cylinder device 26 so that the blow hole 14 is aligned with the sand supply hole 45 of the upper mold 2 as shown in FIG. Then, the eject plate 21 is held on the clamp plate 35 by the clamp arm 36 by the operation of the cylinder device 37.

Then, the eject plate 21 is raised by the cylinder body 30 by supplying air to the upper chamber of the cylinder body 30, and the eject pin 20 is brought to the blow position shown in FIG. In this state, since the pin guide cylinder 18 and the bottom surface of the blow tank 3 form an angle of repose, the molding sand has a blow hole 14
Does not fall from Then, in the above state, air is sent into the blow tank 3 by the pipe 28, and the molding sand is pressure-supplied from the molding sand supply hole 45 of the upper mold 2 into the mold.

After the molding sand is supplied to the mold 1, the intermediate stopper 41
With the cylinder main body 30 lowered by supplying air to the upper chamber and the eject pin 20 is set to the intermediate position, the molding sand 46 has its upper end at the upper surface height of the upper mold 2 as shown in FIG. Pressurize until This allows
The upper end height of the foundry sand 46 in each foundry sand supply hole 45 of the upper mold 2 becomes uniform.

Next, with the eject pin 20 in the intermediate position, the blow-up cylinder device 26 raises both the blow tank 3 and the eject device 23, and the blow tank 3 and the eject device 23 are conveyed from the molding station to the casting sand supply station to receive the supply of the casting sand. Meanwhile, the molding sand is fired on the side of the mold 1. Then, the blow tank 3 and the ejecting device 23 are returned to the molding station again and lowered to be combined with the upper mold 2.

Then, the intermediate stopper 41 is released, and the lifting cylinder device 4 for the upper die and the lifting cylinder device for the movable unit 12 are lifted.
26 is operated in synchronism with the upper mold 2 and the blow tank 3 to be raised, while the cylinder body 30 is relatively lowered by supplying air to the lower chamber, and the eject pin 20 is set to the eject position. As shown in FIG. 5, the mold 47 molded from the upper mold 2 is released.

Incidentally, in the above-mentioned embodiment, the supply pipe of the foundry sand was inserted into the pipe for supplying air, but the air supply pipe and the foundry sand supply pipe were separated, and either the air supply pipe or the foundry sand supply pipe was used. A piston rod for actuating the eject plate may be configured.

[Brief description of drawings]

The drawings show an embodiment of the present invention, FIG. 1 is a front view of a mold making apparatus, FIG. 2 is a side view with a partial cross section showing the relationship between a blow tank, an eject pin and a mold for molding, and FIG. Is a longitudinal sectional view showing the movable unit, FIG. 4 is a side view showing the movable unit in a partial cross section, FIG. 5 is a plan view in a partial cross section showing the intermediate stopper, and FIGS. 6 to 8 are ejects. It is a longitudinal section showing each mode of operation of a pin. 1 ... Mold, 2 ... Upper mold, 3 ... Blow tank, 4 ...
Elevating cylinder device, 7 ... Casting sand tank, 12 ... Movable unit, 14 ... Blow hole, 16 ... Supply cylinder, 20 ... Eject pin, 21 ... Eject plate, 28 ... Pipe, 30 ... Cylinder body, 33 …… Piston, 35 …… Clamp plate, 36 …… Clamp arm, 37 …… Cylinder device, 41 …… Intermediate stopper,, 45 …… Mold sand supply hole, 46
…… Molding sand, 47 …… Mold.

Claims (1)

(57) [Claims] 1. A blow tank for supplying the molding sand stored in a mold for molding a mold, and a pipe connected to the blow tank for supplying at least one of the molding sand and air. A piston is fixed to the outer periphery, and a cylinder body is fitted into this pipe so that the pipe is used as a piston rod to be divided into two chambers by the piston, and a plurality of eject pins are supported by the cylinder body. A mold making apparatus characterized in that a holding means for the eject plate is provided.