JPH0136583Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a mold device for injection molding, and is intended to prevent "sink marks" caused by uneven cooling rate due to uneven wall thickness of a molded product. .

Injection molded synthetic resin molded products are produced by injecting and filling a molten synthetic resin material into the cavity, which is the molding space formed between the cavity and the core. It is molded by cooling and solidifying molten resin.

The cooling and solidification of this synthetic resin injection molded product takes place in the cavity and core, but it goes without saying that the solidification by cooling occurs in order from the surface area that is in contact with the cavity and core to the inside. Therefore, a difference in cooling rate occurs between the surface portion and the internal portion of the molded product.

In this way, even if there is a difference in the cooling rate of the molten resin, which is the molding material, between the surface part and the internal part of the molded product, as long as the wall thickness of the molded product is uniform,
The entire molded product will be cooled at a uniform rate, and no problems will occur. If there is a part with a structure in which a short cylindrical body is integrated into the wall, the part where the short cylindrical body is integrated becomes a thick part, and this thick part is thicker than other parts with a uniform thickness. This will significantly slow down the cooling rate inside.

In this way, when a part of a molded product has a slow cooling rate, the delayed volume shrinkage of the part that cools and solidifies slowly causes "sink marks" on the surface of the molded product corresponding to this thick part. occurs.

“Sink” in this synthetic resin injection molded product
This not only significantly impairs the appearance of the molded product as a product, but also sometimes causes a large deviation in the molded dimensions.

As a means to prevent this "sink", after the molten resin is injected into the molding space, the mold clamping force between the cavity and the core is increased before the internal resin of the molded product has solidified. A method is known in which the volume is reduced by an amount larger than the volume that shrinks due to cooling of the internal resin.

The so-called mold clamping of the molding mold equipment is performed using low-pressure 1
This method is divided into a secondary mold clamping process and a high-pressure secondary mold clamping process.

Various types of mold equipment have been invented, devised, and put into practice to implement this method, but all of them require a special cylinder for secondary mold clamping, which is high-pressure mold clamping. However, since a toggle mechanism is provided, the mold apparatus not only becomes large in size, but also becomes complicated and expensive, and its operation is troublesome.

The present invention was devised to eliminate the drawbacks and dissatisfaction of the conventional example described above, and utilizes the elasticity of a spring and the mold clamping action.

An embodiment of the present invention will be described below with reference to the drawings.

The injection mold device according to the present invention includes a cavity block 6 on the fixed mold side, a core block 9 on the movable mold side, and a strut that is assembled to the core block 9 so as to be displaceable along the mold movement direction. This is an injection mold device in which the volume of a cavity as a molding space formed by a stripper plate 8 is variable, and is between the stripper plate 8 and a core plate 10 to which a core block 9 is assembled and fixed. A pressurizing spring 12 having an elasticity larger than the primary mold clamping force by the movable plate 11 to which the core plate 10 is assembled and fixed, but smaller than the secondary mold clamping force by the movable plate 11 is provided. ing.

In the case of the illustrated embodiment, the mold device comprises a fixed mold side by assembling a cavity plate 7 to which a cavity block 6 is fixed via a runner plate 2 to a fixed plate 1, and a core block to a movable plate 11. A stripper plate 8 is assembled between the core plate 10 and the above-mentioned cavity plate 7, and a stripper plate 8 is attached to the core block 9 so as to be movable in the mold movement direction. It is configured on the mold side.

A runner 4 is formed between the runner plate 2 on the fixed mold side and the cavity plate 7, and the runner 4 is located at a position facing the gate 5, which is the opening to the mold space. plate 2
A stripper pin 3 is assembled to the fixed plate 1 by penetrating through the runner 4 with its tip protruding into the runner 4.

This stripper pin 3 is used to reliably release the shaped runner from the cavity plate 7 side and allow it to fall and be discharged out of the mold apparatus.

The stripper plate 8 on the movable mold side is
Molded product 14 attached to core block 9 after mold opening
This is to release the strip from the core block 9, and it is assembled so that it can be displaced relative to the core block 9 along the direction of mold movement, but in the case of the present invention, the core block 9 and the strip The par plates 8 are configured to move relative to each other in the mold clamping state even when the molding operation shifts from the primary mold clamping molding state to the secondary mold clamping state.

Therefore, the hole surface where the stripper plate 8 is assembled with the core block 9 and the peripheral surface where the core block 9 is assembled with the stripper plate 8 are moved from the above-mentioned primary mold clamping state to the secondary mold clamping state. Displacement is possible, and in the primary and secondary mold clamping states, inconveniences such as the formation of a gap where molten resin may enter between the stripper plate 8 and the core block 9 are avoided. In addition, the movable mold has a tapered surface that is slightly inclined with respect to the moving direction of the movable mold, or a surface that is along the moving direction.

This stripper plate 8 and movable plate 1
A pressure spring 12 is provided between the core plate 10 fixed to the core plate 1, and the pressure spring 12 is clamped when a movable mold is assembled to the fixed mold, and is used for primary mold clamping. When the condition is reached, the stripper plate 8 is placed on the cavity plate 7 with a predetermined distance 13 value α between the stripper plate 8 and the core plate 10, and the primary mold clamping is required. mold clamping force, i.e. 200Kg/cm ²
It is set to have enough elasticity to press it with a certain degree.

The value α of the interval 13 formed by the pressure spring 12 between the stripper plate 8 and the core plate 10 during this primary mold clamping is approximately equal to the value of the molded product 1.
It is a value determined according to the thickness along the mold clamping direction of 4, and is the volume due to cooling and solidification of the molten resin inside the molded product 14, which is cooled with a delay due to the difference in cooling rate. This value is equal to the amount of shrinkage along the mold clamping direction due to shrinkage.

That is, the pressurizing spring 12 is applied when the mold apparatus is in the primary mold clamping state, that is, when the mold is clamped and the stripper plate 8 and the core plate 10
At the position where the distance 13 between the
The spring force is set so that it can be pressed with a force of about cm ² .

Since the mold device according to the present invention has the above-described configuration, the molten resin is injected into the molding space from the primary mold clamping state shown in FIG. 1, and the molten resin injected into the molding space is Although the surface portion of the resin molded product 14 has been cooled and solidified, the inside has not yet been cooled and solidified. As shown in FIG. 2, the movable plate 11 is moved to the fixed mold side and the core is Secondary mold clamping is performed by pressing the plate 10 against the stripper plate 8 with a predetermined pressing force.

The pressure in this secondary mold clamping is 400-800Kg/cm ²
That's about it.

In this way, in the mold device according to the present invention, since the elasticity of the pressure spring 12 is set in advance,
By moving the movable mold toward the fixed mold and setting the distance 13 between the stripper plate 8 and the core plate 10 to the value α, primary mold clamping of the mold apparatus is automatically achieved. After a certain period of time after the injection of the molten resin into the molding space, the final mold clamping is performed by the movable plate 11, thereby achieving secondary mold clamping.

That is, due to the action of the pressure spring 12,
The primary mold clamping and secondary mold clamping of the mold device are automatically performed only by the movement of the movable plate 11.

This moving operation of the movable plate 11 is exactly the same as the moving operation of the movable plate in a conventional general mold device, and therefore, the movable plate 11
There is no need for a new drive source for one movement.

Further, since the value α of the interval 13 is inevitably determined by the thickness of the molded product 14 along the mold clamping direction, it can be easily known in advance before molding, and this allows the setting to be adjusted. It's easy to do.

As is clear from the above explanation, the mold device according to the present invention does not require separate pressure sources for primary mold clamping and secondary mold clamping, and simply connects the stripper plate and core. The configuration is extremely simple as all that is required is to install a pressure spring between the mold device and the mold device, and the settings for the primary mold clamping and secondary mold clamping of the mold device can be set only by the moving position of the movable plate. The operation is extremely easy, and since the structure is simply a pressure spring placed between the stripper plate and the core plate, it is easy to install a pressure source for primary mold clamping. Moreover, it does not require a large amount of space for assembly, and it has many excellent effects, such as being able to be easily applied to existing mold equipment.

[Brief explanation of the drawing]

The drawings are longitudinal sectional views showing the structure of an embodiment of the present invention, with FIG. 1 showing the primary mold clamping state and FIG. 2 showing the secondary mold clamping state. Explanation of symbols, 1: Fixed plate, 2: Runner
Plate, 6: Cavity block, 7: Cavity plate, 8: Stripper plate, 9:
Core block, 10: Core plate, 11: Movable plate, 12: Pressure spring, 13: Interval,
14: Molded product.

Claims (1)

[Scope of utility model registration request] It is formed from a cavity block on the fixed mold side, a core block on the movable mold side, and a stripper plate that is assembled to the core block so as to be displaceable along the mold movement direction and releases the molded product. The injection mold device has a variable cavity volume in which a secondary mold clamping force is applied between the core plate to which the core block is fixed and the stripper plate, which is greater than the primary mold clamping force. An injection mold device comprising a pressure spring having elasticity smaller than force.