KR20030073418A - The booster cylinder of two-platen type injection molder - Google Patents

Abstract

PURPOSE: A structure of a movable cylinder for a two-platen type injection molding machine is provided to reduce working hours of injection molding by quickly and smoothly performing a mold stripping process. CONSTITUTION: An outer oil hydraulic cylinder(1) is fixed to a fixed template(12). Oil inlets(5a,5b) are formed at both ends of the outer oil hydraulic cylinder. An oil feeding tube(2) is formed at the inside of the outer oil hydraulic cylinder. A piston(3) coincides with the section of a cavity between the outer oil hydraulic cylinder and the oil feeding tube. An inner oil hydraulic cylinder(4) is fixed to a movable template(11) and the piston. The inside diameter of the inner oil hydraulic cylinder coincides with the outside diameter of the oil feeding tube.

Description

The moving cylinder structure of a very large injection molding machine {The booster cylinder of two-platen type injection molder}

The present invention is an extra-large injection molding machine, the external hydraulic cylinder is fixed to the fixed plate and the oil inlet is formed at both ends and the oil transfer pipe formed in the longitudinal direction inside the external hydraulic cylinder and the external hydraulic cylinder and oil transfer pipe In the mold demoulding process of injection molding, it consists of a piston that slides along the cavity between and one end fixed to the moving die, the other end fixed to the piston, and an internal hydraulic cylinder whose inner diameter matches the outer diameter of the oil feed pipe. The mold release force forcibly separating the molds mounted on the stationary plate and the movable plate, and the mold opening speed for demolding the mold by rapidly reversing the moving plate after the mold separation are simultaneously provided continuously and smoothly to facilitate the mold demolding process. A moving cylinder structure to carry out.

The super-large injection molding machine is a structure in which a mold is mounted on a fixed template and a mobile template, respectively, and the injection mold is configured to advance the mobile template to combine the molds to perform injection molding, and to retract the mobile template to demould the mold. It is a molding machine. Out of the mold in the design of these super large injection molding machines. The closing speed, the clamping force of the mold, and the separation force of the mold are very important factors. It is closely related to the reverse speed and the working cycle time of the injection molding.

Among the above mentioned elements, a predetermined mold separation force is required, which is forcibly separating the mold at the beginning of demoulding. Therefore, in the conventional super-large injection molding machine, as shown in FIG. 1, the large-diameter mold cylinder 15 providing the separation force of the mold 13 and the small-diameter moving cylinder 14 providing the mold 13 opening speed are provided. It is configured separately. When the mold 13 of the injection molding is demolded, oil is first injected into the mold cylinder 15 to forcibly separate the mold 13 by a predetermined amount, and then the movable template 11 by the action of the movable cylinder 14. ), The mold 13 is completely demolded.

In the conventional super large injection molding machine, a large mold cylinder 15 and a hydraulic circuit for controlling the mold cylinder 15 must be separately configured in addition to the moving cylinder 14, so that the injection molder is expensive in size and has a large cross-sectional mold cylinder. Since the piston of (15) moves at a low speed, the retraction speed of the moving template 11 is lowered, which leads to an increase in the work cycle time of the injection molding operation and a decrease in productivity. In addition, there is a problem that an impact is generated in the injection molding machine due to an imbalance in the movements of the mold cylinder 15 and the moving cylinder 14 during the operation switching process of the mold cylinder 15 and the moving cylinder 14.

An object of the present invention is a cavity between an external hydraulic cylinder fixed to a stationary template and an oil inlet is formed at both ends and an oil conveying tube formed in the longitudinal direction inside the external hydraulic cylinder and the external hydraulic cylinder and the oil conveying tube. It consists of an internal hydraulic cylinder whose one end is fixed to the moving plate and the other end is fixed to the piston and whose inner diameter matches the outer diameter of the oil conveying pipe. The present invention provides a moving cylinder structure which continuously and simultaneously provides a mold separation force for forcibly separating each mounted mold and a mold opening speed for rapidly reversing the moving template after mold release.

1 is a structural diagram of a template of a conventional injection molding machine

2 is a structural diagram of a template of an injection molding machine of the present invention

3 is a structural diagram of a moving cylinder of the present invention

* Explanation of symbols for the main parts of the drawings

1: external hydraulic cylinder

2: oil transfer pipe

3: piston

4: internal hydraulic cylinder

5: oil inlet (a, b, c)

11: moving template

12: fixed template

13: mold

14: moving cylinder

15: shaped cylinder

The moving cylinder structure of the super-large injection molding machine of the present invention is fixed to the stationary template 12 and has an external hydraulic cylinder 1 having oil inlets 5a and 5b formed at both ends thereof, and inside the external hydraulic cylinder 1. An oil feed pipe 2 formed in the longitudinal direction, a piston 3 corresponding to the cross section of the cavity between the external hydraulic cylinder 1 and the oil feed pipe 2, and one end of the movable die 11 It is characterized in that it consists of an internal hydraulic cylinder (4) fixed at the other end and fixed at the piston (3) and whose inner diameter matches the outer diameter of the oil conveying pipe (2).

The present invention will be described in detail with reference to the drawings and examples.

1 illustrates the structure of a template of a conventional super large injection molding machine, FIG. 2 illustrates a structure of a template of a super large injection molding machine according to the present invention, and FIG. 3 illustrates a structure of a moving cylinder according to the present invention.

A part of the side of the external hydraulic cylinder 1 having a cylindrical shape having a constant diameter and length is fixedly fixed to the stationary template 12 on which the mold 13 is mounted. Oil injection ports 5a and 5b through which oil is injected or discharged into the external hydraulic cylinder 1 are formed at both ends of the external hydraulic cylinder 1 or a position adjacent thereto. When oil is injected into the oil inlet 5a in the direction of the moving template 11 among the plurality of oil inlets 5a and 5b, the piston 3 embedded in the external hydraulic cylinder 1 is connected to the piston 3. The moving die 11 moves forward simultaneously to close the mold 13, and when oil is injected into the oil inlet 5b toward the fixed die 12, the piston 3 and the moving die 11 retreat simultaneously. It is configured to separate the mold 13.

An oil feed pipe 2 having a predetermined length and diameter in the longitudinal direction is formed inside the external hydraulic cylinder 1. The outer diameter of the oil conveying pipe 2 and the inner diameter of the inner hydraulic cylinder 4 coincide so that the inner hydraulic cylinder 4 slides in a constant section along the outer diameter of the oil conveying pipe 2. An oil inlet 5c through which oil is injected or discharged is formed at an end portion in the direction of the fixed plate 12 of the oil transfer pipe 2, and an inlet in the direction of the moving plate 11 of the oil transfer pipe 2 is It is connected to the cavity of the internal hydraulic cylinder 4. When oil is injected into the oil inlet 5c, oil is supplied to the cavity of the internal hydraulic cylinder 4 through the oil transfer pipe 2, so that the internal hydraulic cylinder 4 moves in the direction of the moving template 11. It is configured to retract quickly at high pressure and low pressure.

A piston 3 is formed to conform to the cross section of the cavity between the external hydraulic cylinder 1 and the oil transfer pipe 2 and to slide a predetermined section along the longitudinal direction of the cavity. When oil is injected into the oil inlet 5a in the direction of the movable template 11 of the external hydraulic cylinder 1, the piston 3, the internal hydraulic cylinder 4, and the movable template 11 are advanced simultaneously by hydraulic pressure. When oil is injected into the oil inlet 5b in the direction of the stationary template 12 of the external hydraulic cylinder 1, the piston 3, the internal hydraulic cylinder 4, and the movable template 11 are simultaneously retracted by hydraulic pressure. Is configured to.

The piston (3) advances the moving template (11) at low speed and high pressure because the cross section of the piston (3) formed inside the outer hydraulic cylinder (1) is much wider than the inner diameter cross-sectional area of the inner hydraulic cylinder (4). Configured to perform the retracting action. The piston 3 having a large cross-sectional area retracts the movable template 11 at low speed and high pressure, thereby providing a strong mold separation force to the movable template 11.

An internal hydraulic cylinder 4 of constant length and diameter is formed in which one end is fixed to the moving template 11 and the other end is fixed to the piston 3 and the inner diameter matches the outer diameter of the oil feed pipe 2. . The inner diameter of the inner hydraulic cylinder 4 coincides with the outer diameter of the oil conveying pipe 2 so that the inner hydraulic cylinder 4 slides in a constant section along the outer diameter of the oil conveying pipe 2. When oil is injected into the oil inlet 5c of the oil feed pipe 2, oil is supplied to the cavity of the internal hydraulic cylinder 4 through the oil feed pipe 2 so that the internal hydraulic cylinder 4 is closed. It is configured to retreat at high speed and low pressure in the direction of the movable template 11.

Since the inner diameter cross-sectional area of the inner hydraulic cylinder 4 which slides along the outer diameter of the oil conveying pipe 2 is much narrower than the cross-sectional area of the piston 3, the inner hydraulic cylinder 4 advances the moving template 11 at high speed and low pressure. . Configured to perform the retracting action. The internal hydraulic cylinder 4 having a narrow cross-sectional area retracts the moving die 11 at high speed and low pressure, thereby providing a rapid mold opening speed to the moving die 11.

As described above, the moving cylinder 14 formed in a double structure by the external hydraulic cylinder 1 and the internal hydraulic cylinder 4 forces the mold 13 mounted on the stationary template 12 and the mobile template 11, respectively. It is configured to continuously control by the single hydraulic circuit the operation of separating the mold and the operation of demolding the mold 13 by rapidly reversing the moving die 11 after the separation of the mold (13).

The metal mold | die 13 is attached to the stationary template 12 and the movable template 11 of a super large injection molding machine, respectively. The oil is injected into the oil inlet 5a in the direction of the moving template 11 of the external hydraulic cylinder 1 to advance the piston 3, the internal hydraulic cylinder 4, and the moving template 11 to open the mold 13. To close. Injection molding of a synthetic resin melt is performed into the mold 13. When the injection molding is completed, the oil is injected into the oil inlet 5b in the direction of the fixed plate 12 of the external hydraulic cylinder 1 and the oil inlet 5c of the oil conveying pipe 2 at the same time, so that the piston 3 and the internal hydraulic pressure are Retraction of the cylinder 4 and the moving die 11 is started, and the die 13 is demolded. In the initial stage of the demolding process of the mold 13, the piston 3 having a large cross-sectional area retracts the movable die 11 at low speed and high pressure, so that the closed mold 13 is forcibly separated by a certain amount. When the mold 13 is forcibly separated by a predetermined amount, the oil injection to the oil inlet 5b in the direction of the fixed plate 12 of the external hydraulic cylinder 1 is stopped for rapid retraction of the moving template 11, and the oil feed pipe ( Oil is injected only into the oil inlet 5c of 2). Since the oil is injected only into the oil inlet 5c of the oil feed pipe 2, the internal hydraulic cylinder 4 having a narrow cross-sectional area retracts the moving template 11 at high speed and low pressure, so that the separated mold 13 is demoulded quickly. .

That is, since the forced separation and rapid demolding of the mold 13 proceed simultaneously at the same time by the moving piston 3 of the dual structure, no impact occurs on the injection molding machine when the mold 13 is separated and the operation of the demold is changed. Work cycle time is shortened.

When the mobile cylinder 14 having a dual structure as described above is configured in the super-large injection molding machine, the size and weight of the stationary template 12 are greatly reduced and the manufacturing cost of the injection molding machine is greatly lowered.

The moving cylinder structure of the super-large injection molding machine according to the present invention transfers an external hydraulic cylinder and a moving template to provide a mold separation force for forcibly separating the mold. An internal hydraulic cylinder providing a mold opening speed for demoulding and demoulding a mold is formed, and a moving cylinder that forms a double structure is formed so that a large-size injection molding machine can be reduced in size and weight, and manufacturing cost is reduced. The work cycle time of the molding is greatly shortened, and the impact of the injection molding machine occurring at the time of disconnection of the mold and the switching of the demolding operation is prevented.

Claims (1)

In two-platen injection molding machine, An external hydraulic cylinder 1 fixed to the stationary template 12 and having oil inlets 5a and 5b formed at both ends thereof, and an oil conveying tube 2 formed in the longitudinal direction inside the external hydraulic cylinder 1. And a piston (3) corresponding to the cross section of the cavity between the external hydraulic cylinder (1) and the oil transfer pipe (2), one end of which is fixed to the moving die (11), and the other end of the piston (3). The moving cylinder structure of the super large injection molding machine, characterized in that it consists of an internal hydraulic cylinder (4) fixed to the inner diameter is matched to the outer diameter of the oil transfer pipe (2).