JPH049149Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a spool lock structure for an injection mold.

[Conventional technology]

FIG. 3 is a longitudinal sectional view of a spool lock structure of a conventional injection mold.

In FIG. 3, 1 is an injection nozzle, 2 is an upper mounting plate, 3 is an upper mold, 4 is a lower mold, 5 is an ejector pin, 11 is an upper ejector plate, 12 is a lower ejector plate, 13 is a lower mounting plate, 14 is a stopper pin, 15 is an auxiliary rod, and 16 is a push rod. Also, 21 is a spool, 22 is a spool lock, 23 is a runner, 24 is a gate, 2
5 is a cavity.

The spool lock 22 in FIG. 3 is provided to accommodate the cold slug (not shown) injected from the injection nozzle 1.

Cold slag has the property that when the temperature of the injection mold is low, a large amount is formed, and when the temperature is high, only a small amount is formed.

In the conventional device shown in FIG. 3, the volume of the spool lock 22 was made large in order to allow the spool lock 22 to accommodate a sufficient amount of cold slag.

[Problem that the invention attempts to solve]

In the conventional device shown in FIG. 3, since the volume of the spool lock 22 is large, the cooling rate of the resin in the spool lock 22 is slow.
When opening the mold, the resin at the spool lock 22 may not be sufficiently hardened, and the ejector pin 5
There was a problem in that the ejector pin 5 sometimes penetrated through the resin even if it was pushed, and the resin at the spool lock 22 could not be pushed out.

However, if the volume of the spool lock 22 is reduced in order to increase the cooling rate of the resin, it will not be able to accommodate the large cold slag that is generated at low temperatures.

The present invention solves these problems of the conventional technology.

The technical problem of the present invention is to make it possible to sufficiently accommodate cold slag even at low temperatures, and to also be able to completely extrude the resin at the spool lock when the mold is opened.

[Means for solving problems]

In order to achieve this technical problem, the following measures are taken in the present invention.

That is, the spool lock structure of the injection mold according to the present invention consists of an upper mold that the injection nozzle contacts, and a lower mold that is provided with a spool lock for storing the cold slag injected from the injection nozzle. , a temperature sensor that detects and outputs the temperature of at least one of the upper and lower molds, an ejector pin that pushes out the resin in the spool lock when the mold is opened, and an ejector pin that protrudes into the spool lock to release the resin from the spool lock. It consists of a spool lock pin for making the volume variable, and a drive device that drives the spool lock pin in response to an output signal from a temperature sensor. The driving device drives the spool lock pin to increase the volume of the spool lock when the temperature detected by the temperature sensor is low, and when the temperature detected by the temperature sensor is high, the drive device drives the spool lock pin to increase the volume of the spool lock. Means is provided for driving the spool lock pin to reduce the volume of the spool lock.

[Effect]

When the temperature of the injection mold is low, the volume of the spool lock is increased by the spool lock pin.

When the temperature is low, a large amount of cold slag is generated, so in the present invention, as described above, the volume of the spool lock is increased to accommodate enough cold slag.

Note that when the temperature is low, even if the volume of the spool lock is large, the temperature of the resin in the spool lock is low and the temperature of the resin in the spool lock drops quickly after injection. Therefore, when the mold is opened, the resin in the spool lock is sufficiently pushed out by the ejector pin, so there is no problem.

When the temperature of the injection mold is high, the volume of the spool lock is reduced by the spool lock pin.

Since the volume of the spool lock is small, the resin in the spool lock quickly cools down after injection. Therefore, when the mold is opened, the resin in the spool lock is completely extruded by the ejector pin.

Note that when the temperature is high, the amount of cold slag generated is small, so there is no problem even if the volume of the spool lock is made small, as described above.

As can be seen from the above explanation, according to the present invention,
While being able to accommodate enough cold slag at low temperatures, it is also possible to completely extrude the resin at the spool lock when the mold is opened.

〔Example〕

FIG. 1 is a longitudinal sectional view of a spool lock structure of an injection mold according to an embodiment of the present invention.

In FIG. 1, 1 is an injection nozzle, 2 is an upper mounting plate, 3 is an upper mold, and 4 is a lower mold. Also, 11
12 is an upper ejector plate, 12 is a lower ejector plate, 13 is a lower mounting plate, 14 is a stopper pin, 15 is an auxiliary rod, and 16 is an extrusion rod. Further, 21 is a spool, 22 is a spool lock, 23 is a runner, 24 is a gate, and 25 is a cavity. The injection nozzle 1 is in contact with the upper mold 3. The spool 21 is formed on the upper mold 3,
A spool lock 22 is formed on the lower mold 4.
The spool lock 22 is for storing the cold slug injected from the injection nozzle 1.

The mechanism for pushing out the resin from the spool lock 22 when the mold is opened will be explained.

This mechanism includes a first ejector pin 31 fixed to an upper ejector plate 11 and a lower ejector plate 12, and a first ejector pin 3
1 and a second ejector pin 32 fixed to the tip of the first ejector pin 32.

The lower die 4 is provided with a fitting hole 51, into which a first ejector pin 31 and a second ejector pin 32 are fitted.

The second ejector pin 32 is screwed to the first ejector pin 31 at a portion designated by reference numeral 34.

FIG. 2 is a perspective view of the first ejector pin and the second ejector pin.

As can be seen from FIG. 2, the first ejector pin 31 has a rectangular cross section, and the second ejector pin 32 is made of a hollow cylinder. 1st
The ejector pin 31 has a rectangular cavity 33 formed therein, and a spool lock volume variable mechanism to be described later is housed in this cavity 33.

Returning to FIG. 1, in the one shown in FIG. 1, the upper mold 3 is a fixed mold, and the lower mold 4 is a movable mold. When opening the mold, the extrusion rod 16 pushes the auxiliary rod 15 at the same time as the lower mold 4 moves downward (in the direction of arrow D).
The first ejector pin 31 and the second ejector pin 32 protrude upward (in the direction of arrow C) and push out the resin at the spool lock 22. The above is the mechanism for pushing out the resin of the spool lock 22.

Next, the spool lock volume variable mechanism that is characteristic of this embodiment will be explained.

The spool lock volume variable mechanism includes a spool lock pin 41, an operating core 42, and a hydraulic cylinder 4.
3, a temperature sensor 44 attached to the lower mold 4, and a control device 45 that controls the hydraulic cylinder 43 based on the output signal of the temperature sensor 44.

As can be seen from FIG. 1, the part of the insertion hole 51 marked with reference numeral 52 is a stepped part, and a hollow fixing block 53 is attached to the stepped part 52 by a hollow holding bush 54. It is fixed. The presser bush 54 is screwed to the lower die 4 at a portion designated by reference numeral 55. Note that the first ejector pin 31 passes through the presser bush 54.

As can be seen from FIG. 1, the spool lock pin 41 is composed of a spool lock pin body 61 and a spring receiver 62, and the spool lock pin body 61 is slidable into the second ejector pin 32. It is located. The spring receiving portion 62 is arranged inside the fixed block 53.

The spring receiving portion 62 and the operating core 42 are in contact with each other. The contact surface 63 of the spring receiving portion 62 and the operating core 4
The contact surface 64 of No. 2 is oblique.

A hydraulic cylinder 43 is attached to the lower die 4, and a rod 65 extends horizontally from the hydraulic cylinder 43 into the lower die 4, and an operating core 42 is attached to the tip of the rod 65.

The spool lock pin 4 is located between the fixing block 53 and the spring receiving portion 62 of the spool lock pin 41.
A compression coil spring 71 is arranged to press 1 in the direction of arrow D.

The operation of this embodiment will be explained.

If the temperature of the lower mold 4 is low, the temperature sensor 4
In response to the output signal No. 4, the control device 45 controls the hydraulic cylinder 43 to retract the rod 65 in the direction of arrow F.

Therefore, since the operating core 42 is also displaced in the direction of arrow F, the spool lock pin 41 is lowered in the direction of arrow D by the compression coil spring 71.
The volume of the spool lock 22 is increased.

When the temperature is low, a large amount of cold slag is generated, so as mentioned above, the spool lock 2
The volume of 2 is increased to be able to accommodate enough cold slag.

In addition, when the temperature is low, the spool lock 22
Even if the volume of the spool lock 22 is large, since the temperature is low, the temperature of the resin in the spool lock 22 quickly decreases and hardens after injection. Therefore, when the mold is opened, the resin in the spool lock 22 is sufficiently pushed out by the second ejector pin 32, so there is no problem.

If the temperature of the lower mold 4 is high, the temperature sensor 4
In response to the output signal No. 4, the control device 45 controls the hydraulic cylinder 43 to project the rod 65 in the direction of arrow E.

Therefore, since the operating core 42 is also displaced in the direction of arrow E, the spool lock pin 41 protrudes in the direction of arrow C, and the volume of the spool lock 22 is reduced.

Since the volume of the spool lock 22 is small, the resin in the spool lock 22 quickly cools and hardens after injection. Therefore, when the mold is opened, the resin in the spool lock 22 is completely extruded by the second ejector pin 32.

Note that when the temperature is high, the amount of cold slag generated is small, so there is no problem even if the volume of the spool lock 22 is made small, as described above.

As can be seen from the above description, according to this embodiment, it is possible to fully accommodate cold slag at low temperatures, and also to completely extrude the resin at the spool lock when opening the mold. .

Incidentally, when the temperature of the injection molds 3 and 4 is 10 to 20°C, the volume of the spool lock 22 is approximately 1.5 cm ³
When the temperature is 20 to 30°C, the volume of the spool lock 22 is preferably approximately 1.2 to 1.5 cm ³ or more, and when the temperature is 30 to 40°C, the volume of the spool lock 22 is approximately 1.0 to 1.5 cm 3 or more. It is recommended that it be approximately 1.2 cm ³ or more. Further, the drive device referred to in the present invention corresponds to the hydraulic cylinder 43 and the control device 45 of this embodiment.

In this embodiment, the volume of the spool lock 22 is made variable so that the cold slug can be completely accommodated. Therefore, there is no need to provide a slag reservoir in the injection molding molds 3, 4 other than the spool lock 22, resulting in cost reduction.

Although a specific embodiment of the present invention has been described above, the present invention is not limited to this embodiment, and includes various embodiments within the scope of the utility model registration claims. For example, the temperature sensor 44 may be attached to the upper mold 3 instead of the lower mold 4.

[Effects of the invention] According to the invention, the cold slag can be sufficiently accommodated even at low temperatures, and the resin at the spool lock can be completely extruded when the mold is opened.

Furthermore, according to the present invention, since the volume of the spool lock can be set to an optimal value for accommodating cold slag, there is no need to provide a slag reservoir in the injection mold. Therefore, the cost can be reduced accordingly.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of the spool lock structure of an injection mold according to an embodiment of the present invention, and FIG.
FIG. 1 is a perspective view of a first ejector pin and a second ejector pin, and FIG. 3 is a longitudinal cross-sectional view of a spool lock structure of a conventional injection mold. 1...Injection nozzle, 3...Upper mold, 4...Lower mold,
22... Spool lock, 31... First ejector pin, 32... Second ejector pin, 41
... Spool lock pin, 43, 45 ... (drive device), 43 ... hydraulic cylinder, 45 ... control device, 44 ... temperature sensor.

Claims (1)

[Scope of utility model registration request] The upper mold that the injection nozzle contacts, the lower mold that is provided with a spool lock for storing the cold slag injected from the injection nozzle, and the temperature of at least one of the upper mold and the lower mold. a temperature sensor that detects and outputs the temperature; an ejector pin for pushing out the resin in the spool lock when the mold is opened; a spool lock pin that protrudes into the spool lock to make the volume of the spool lock variable; and a drive device that drives the spool lock pin in response to an output signal from the temperature sensor, and the drive device drives the spool lock pin when the temperature detected by the temperature sensor is low. and increasing the volume of the spool lock, and driving the spool lock pin to reduce the volume of the spool lock when the temperature detected by the temperature sensor is high. Spool lock structure of injection mold.