JPH04164621A - Injection molding device - Google Patents

Abstract

PURPOSE:To obviate removal of air from a molten material and injection molding is performed without changing a molding cycle time, by a method wherein a device capable of removing gas is connected with a hopper of a material feed part and an injection cylinder and mixing of the air is prevented at the time of material feed since the inside of a hopper and injection cylinder are made vacuous. CONSTITUTION:A screw 1-5 is in an injection cylinder 1-4, a material is fed within a groove of the screw 1-5 and melted. A molten material 1-8 is on the tip part of the inside of an injection cylinder 1-4 or sealing such as on O ring 1-9 is performed on a rear end part. With this construction, an entering of the air into the injection cylinder 1-4 is limited to a route through a hopper 1-6. The air in the injection cylinder 1-4 is removed by a vacuum pump 1-1 connected with the injection cylinder. Subsequently, the air ion the hopper 1-6 is removed. With this construction, the insides of the hopper 1-6 and injection cylinder 1-4 are made vacuous and at the time of material feed, a mixing of the air into the injection cylinder 1-4 from the hopper 1-6 can be prevented.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to the structure of an injection molding device.

[Prior Art] Air in the material in injection molding has a large effect on the quality and yield of the molded product, such as the generation of air bubbles, so it is necessary to minimize the amount of air contained in the material.

In conventional technology, air is mixed in with the material when the material is fed from the hopper to the screw. The air was separated from the material by a screw in the injection cylinder and returned to the hopper.

[Problems to be Solved by the Invention] However, in the conventional method, it is technically difficult to completely remove air that has entered the injection cylinder and mixed into the molten material. Furthermore, in order to remove air from the molten material, the molding cycle time becomes longer, resulting in deterioration of productivity.

Therefore, the present invention aims to perform injection molding without requiring the removal of air from the enemy material and without changing the molding cycle time.

[Means for solving the problem] In the present invention, a device capable of removing gas such as a vacuum pump is connected to the hopper and injection cylinder of the material supply section, and by evacuating the inside of the hopper and the injection cylinder, air is removed during material supply. It is characterized by preventing the contamination of

[Function] As shown in Fig. 1, there is a 1-5 screw in the injection cylinder, and material is supplied to the groove of this screw and melted.

There is a 1-8 molten material at the front end within the 1-4 injection cylinder or a seal such as a 1-90 ring at the rear end. As a result, the path for air to enter the 1-4 injection cylinder is limited to the 1-6 hopper.6 The air inside the 1-4 injection cylinder is removed by the 1-1 vacuum pump connected to the 1-4 injection cylinder. Ru. Subsequently, the air in hoppers 1-6 is removed. As a result, the inside of the 1-6 hopper and the 1-4 injection cylinder are evacuated, and it is possible to prevent air from entering the 1-4 injection cylinder from the 1-6 hopper during material supply.

[Example 1] An example of the present invention will be described below. FIG. 1 shows an injection section of an injection molding apparatus. A vacuum pump 1-1 for air removal is connected to an injection cylinder 1-4 by a connecting pipe 1-3 via a filter 1-2. The 1-1 vacuum pump is constantly operating to remove air within the 14 injection cylinder. The air inside 1-6 Ho Nno\- is granular 1-
It passes between 7 materials and is led to the 1-1 vacuum pump.

This completes the vacuuming of l-6 Ho-Jino<-.

The 1-8 g melted material weighed and melted in this state does not contain air from the material supply section, thereby reducing defects in the appearance of the molded product due to air bubbles.

Further, it is not necessary to lower the rotation speed of the 1-5 screw for the purpose of degassing when measuring and melting the 1-7 material, making it possible to shorten the molding cycle and improve productivity.

Since the material 1-7 cannot pass through the gap between the inner diameter of the 1-4 injection cylinder and the outer diameter of the 1-5 screw, it remains in the groove of the 1-5 screw. This also facilitates the supply of the 1-7 material into the 1-4 injection cylinder as well as evacuating the 1-6 chamber and the 1-4 injection cylinder.

Fine material passing through the gap between the injection cylinder 1-4 and the screw 1-5 is removed by the filter 1-2.

The 1-8 material at the tip of the 1-5 screw and the intermediate portion is in a molten state and has high viscosity, so it will not flow backwards when it is pulled by the 1-1 vacuum pump.

When supplying material to the 1-6 hopper, the 1-10 lid is removed. At this time, the vacuum is broken, but the vacuum is restored by the action of the 1-1 vacuum pump. The vacuum state can be confirmed using a 1-11 gauge.

If the air in the 1-6 hopper and 1-4 injection cylinder can be removed, 1-1 can be directly removed from the 1-6 hopper.
It is also possible to connect a vacuum pump.

[Embodiment 2] FIG. 2 shows a case where an automatic material supply device is connected to the material supply section.

Normally, the 2-10 valve is fully closed, and the 2-9 valve B is in an intermediate state. 2-1 The vacuum pump is always in operation 2-
The air in the 2-11 hopper 1 and the 2-6 hopper 2 is removed by the 2-3 connecting pipe through the 2-filter.

When the material in the 2-6 hopper 2 is low (when the material is supplied to the 2-11 hopper 1 by the automatic material feeding device), the 2-9 valve B is fully open and the 2-10 valve A is fully open. This state In this case, the vacuum of the 2-6 hopper 2 is maintained.

When a certain amount of material is supplied to the 2-11 hopper 1, the supply of material is stopped and the 2-1-valve A is fully opened.

When the 2-11 hopper 1 is completely evacuated, the 2-9 valve B is fully opened and material is supplied to the 2-6 hopper 2.

At this time, the hopper 2-6 and the injection cylinder 2-4 are in a vacuum state. Since the material 2-7 is measured and melted in this state, the molten material 2-8 does not contain air. This can reduce defects such as poor appearance due to air bubbles in the molded product.

The 2-7 material in the hopper is left in the hopper by the 2-12 shield and only air is directed to the 2-1 vacuum pump. The fine material passing through the 2-12 shielding plate is removed by the 2-2 filter.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an injection section of an injection molding apparatus according to an embodiment of the present invention.6 FIG. FIG. 1-1... Vacuum pump 1-2... Filter 1-3... Connecting pipe 1-4... Injection cylinder 1-5... Screw 1-6... Hopper 1-7... Material 1- 8... Melt material 1-9... O-ring 1-10... Lid 1-11... Gauge 2-1... Vacuum pump 2-2... Filter 2-3... Connection pipe 2-4. Injection cylinder 2-5...Screw 2-6...Hopper 2 2-7...Material 2-8...Melted material 2-9...Valve B 2-10... Valve A 2-11... Hopper 1 2-12... Shielding plate 2-13... 0 ring 2-14... Gauge or higher Applicant: Seiko Epson Co., Ltd. Representative Patent attorney Kizobe Suzuki (1 person) Figure 2

Claims (1)

[Claims] An injection molding device characterized by forcibly creating a vacuum inside the material supply section and injection cylinder of the injection molding device to prevent air from entering the device and improve the quality and productivity of molded products.