JPH10337754A - Injection unit for injection molding machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent leakage of plastic plasticized without unevenness of an injection amount by rotatably arranging a plasticizing screw in a plasticizing cylinder, and slidably assembling a rotatable injection plunger having an end shape of a screw with an axial center of the screw. SOLUTION: A rear end of an injection plunger 4 is mounted at a rotary shaft 17 contained in a crosshead 16. The crosshead 16 is coupled to a piston head 21. Further, the head 21 slides in a hydraulic cylinder 22 of a driver case 12. This rod 21 is driven to forwafd or reverse the plunger 4. A plasticizing cylinder holder 7 and driver case 12 are coupled and fixed on a frame 24. Accordingly, the plunger 4 is rotated at twice or more rotating speed as fast as a plasticizing screw 2 in the same direction by an injection plunger driving wheel 29 via a movable key 30 and slid in an axial direction.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an injection apparatus for an injection molding machine for plastics, and it is possible to mold a product with high precision and uniformity by obtaining a uniform temperature plasticization and a uniform injection amount. It is like that.

[0002]

2. Description of the Related Art Conventionally, an injection device of an injection molding machine has been equipped with one type.
A screw in-line type in which a screw is retreated by rotating a book according to the amount of plasticization in order to accumulate plasticized plastics at the tip by rotating the screw is often used.

[0003] Although this method has a simple structure, the length of the screw portion at the time of plasticization changes with the retreat of the screw, the plasticization time also changes, and a difference occurs in the temperature of the plasticized plastics. Furthermore, it is difficult to mold a highly accurate product because plasticized plastics may flow back inside the screw during injection.

[0004] In order to eliminate this drawback and perform uniform plasticization, the one described in Japanese Patent Publication No. 7-75859 has been invented. In this case, however, the distance between the plasticizing screw and the injection cylinder is reduced. The passage is only at the tip of the plasticizing screw, plasticized plastics can be passed only when the injection plunger is retracted, back pressure can not be applied when plasticizing with the plasticizing screw, Insufficient kneading is possible.

[0005] Further, air enters the injection cylinder, the injection amount cannot be measured by the injection plunger, and leakage from the gap between the plasticizing screw and the injection plunger cannot be prevented.

[0006]

In order to obtain plastics having a uniform temperature during plasticization, the length of the plasticized screw is kept constant, and the plasticized plastic is pressed by a plunger separate from the plasticized screw. It is necessary to eliminate the variation of the injection amount by putting out.

Further, in order to perform sufficient kneading, it is necessary to apply a back pressure to the plasticized plastics. In order to make the heat history of the plasticized plastics the same, the inside of the injection cylinder is required. Plastics must be filled in a plasticized order. Furthermore, if plasticized plastics leaks from the gap between the injection plunger and the center hole of the plasticizing screw, various troubles must be prevented.

[0008]

In order to solve these problems, a plasticizing cylinder has an inner diameter of two stages, a plasticizing screw is disposed at a large diameter portion, and a screw-shaped injection plunger is disposed at a small diameter portion. In other words, the plasticizing screw arranged in the large diameter portion rotates at the same position and plasticizes the plastics, so that the lengths of the plasticizing cylinder and the screw for plasticizing do not change during operation. And the temperature of the plasticized plastics is uniform.
Then, the plasticized plastics is extruded by a screw, stored in a small-diameter injection cylinder at the tip of the plasticizing cylinder, and extruded by a small-diameter plunger at the time of injection.

The tip of this injection plunger has a screw shape with a small depth, and the plastics plasticized and extruded by the plasticizing screw are supplied to the injection cylinder in the order of plasticization. By applying back pressure to the injection plunger, pressure is applied to the plasticized plastics, sufficient kneading is performed with the plasticizing screw, and the rotation speed of the injection plunger is made faster than that of the plasticizing screw. As a result, the plastics which is to leak from the gap between the center hole of the plasticizing screw and the injection plunger is pushed back toward the injection cylinder by the screw of the injection plunger, so that there is no fear of resin leakage.

[0010] Since the screw of the injection plunger has a high rotation speed, the feeding ability of the plastics is increased. Therefore, the depth of the screw groove is small, and the injection plunger is filled with the plasticized plastics. When the injection is performed while moving forward, the backflow of the plastics is small, and the variation in the injection amount is small.

If a screw groove in the direction opposite to the screw of the injection plunger is provided on the inner surface of the injection cylinder, the amount of plasticized plastics to be sent out increases and the resistance to backflow during injection increases. When a planetary gear mechanism is used to drive the rotation of the injection plunger, a higher rotation speed can be easily obtained in the same direction as the rotation of the plasticizing screw.

[0012]

The plastics put into the plasticizing cylinder is sent to the tip by the rotation of the plasticizing screw and is plasticized. The plasticized plastics passes through the tapered portion at the tip of the plasticizing screw and is sent to the resin reservoir at the tip of the plasticizing cylinder. At the start of operation, the tip of the injection plunger is located at the tip of the plasticizing cylinder. Recedes due to the resin pressure. At that time, by controlling the pressure of the hydraulic cylinder connected to the rear end of the injection plunger, the plasticizing back pressure can be controlled, and the degree of kneading can be controlled.

When the amount of plasticized plastics reaches a predetermined amount, the rotation of the plasticizing screw is stopped to stop the supply, and the injection is performed by pushing out the injection plunger. At this time, since the plasticizing screw rotates at the same place to plasticize the plastics, there is no difference during operation between the external heat from the plasticizing cylinder and the self-heating due to the screw rotation. Can be obtained. Injection is performed by a small diameter injection plunger.
Since the stroke is relatively large, the measurement accuracy is high, the influence of the backflow is small, and the variation in the injection amount is small.
A highly accurate molded product can be obtained.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an injection apparatus for an injection molding machine according to the present invention will be described in detail with reference to FIGS.

FIGS. 1, 2 and 3 show an embodiment of an injection apparatus for carrying out the present invention. FIG. 1 is a plan view, FIG. 2 is a longitudinal sectional view, and FIG. It is a rear view. FIG. 4 is a diagram showing a resin flow when the inner surface of the injection cylinder is a screw, and FIG. 5 is a diagram showing a rotational speed of the planetary transmission.

Reference numeral 1 denotes a plasticizing cylinder, 2 denotes a plasticizing screw, 3 denotes an injection cylinder, 4 denotes an injection plunger, 5 denotes a plasticizing cylinder cap, 6 denotes a nozzle, and 7 denotes a plasticizing cylinder holder. Plasticized screw 2 has rotating shaft 8 with bearing 1
Attached to the drive case 12 via 0, 11;
The rotation shaft 8 is driven by transmitting the power from the motor 13 to the pinion 14 and the gear 15. Reference numeral 9 denotes a gear case.

The rear end of the injection plunger 4 is a crosshead 16
Is mounted on a rotating shaft 17 incorporated therein via bearings 18 and 19. The crosshead 16 is connected to a piston head 21 by two piston rods 20. In addition, the piston head 21 is
The injection plunger 4 is moved forward and backward by driving the piston rod 21.

The plasticizing cylinder holder 7 and the drive device case 12 are connected by a tie bar 23 and fixed on a frame 24. Therefore, the crosshead 16 is configured to slide on the frame 24. On the other hand, a planetary transmission is formed by the internal gear 25 and the planetary gear 26 fitted into the drive device case 12, the injection plunger drive wheel 29 having teeth on the outer periphery, the planetary gear support pin 27 and the pin support plate 28. The injection plunger drive wheel 29 is driven by the planetary gear support pin 27 inserted into the gear 15 and rotates at twice or more the rotation speed in the same direction as the gear 15.

Accordingly, the injection plunger 4 is rotated by the injection plunger driving wheel 29 via the floating key 30 in the same direction as the plasticizing screw 2 at a rotation speed more than twice as much as the plasticizing screw 2 and slides in the axial direction.

Next, the operation of the injection device configured as described above will be described.

The plastics supplied from the raw material inlet 31 enters a space 32 formed between the plasticizing cylinder 1 and the plasticizing screw 2 and is plasticized by the rotation of the plasticizing screw 2 and advances.

At this time, the outer periphery of the plasticizing cylinder 1 is surrounded by a heater (not shown) and maintains a specified temperature.
While being heated and plasticized by the shear friction caused by screw rotation. At that time, the positions of the plasticizing cylinder 1 and the plasticizing screw 2 are fixed, the amount of heating is constant, and uniform plasticization is performed even with a relatively short screw length.

The plasticized plastics passes through the gap 33 at the tip of the plasticizing screw 2 and further flows into the tip 35 of the injection cylinder 2 through the screw groove 34 of the injection plunger 4 inserted into the injection cylinder 3. At this time, since the injection plunger 4 rotates at a rotation speed twice or more as high as the rotation speed of the plasticizing screw 2, the injection plunger 4 has a large feeding capability even in a groove having a small gap.

In addition, since the plasticized plastics has pressure, the injection plunger 4 moves backward. The pressure at that time can be adjusted by controlling the pressure in the chamber 36 on the rod side of the hydraulic cylinder 22. When an amount of plasticized plastics necessary for injection is accumulated in the injection cylinder tip 35, the rotation of the plasticizing screw 2 and the injection plunger 4 is stopped, and the force of the hydraulic cylinder 22 causes the injection plunger 4 to rotate.
To extrude.

At that time, especially at the final pressure which requires a high pressure, the injection plunger 4 is close to the tip and the groove 34 in the gap between the injection cylinder 3 and the injection plunger 4 is long, and the resistance is large and the plasticizing screw is large. The influence of the back pressure on No. 2 is small, there is almost no backflow, and there is little variation in the injection amount.

The plasticized plastics tends to leak due to pressure from the gap between the hole at the center of the plasticizing screw 2 and the outer periphery of the injection plunger 4, but the tip 35 of the injection plunger has a screw shape. Its rotation speed is more than twice that of the plasticizing screw 2, so it has a discharging capacity. The plastics that have entered during injection are sent out to the tip during plasticization, so that no resin leakage occurs.
It is safe without any trouble.

An injection plunger 4 is provided on the inner surface of the injection cylinder 3.
When the injection plunger 4 rotates as shown in FIG. 4, the plastics pressed by the screw flight 37 causes the injection cylinder 3 to rotate.
Of the screw flight 38, the two flights 37, 38 are resistant to backflow during injection, are easily sent out during plasticization, and can reduce the backflow during injection.

FIG. 5 is a diagram showing the rotational speed of the planetary transmission. The rotational speed N ₂ of the injection plunger 4 is
Is twice or more the rotation speed N ₁ of FIG. That is, the gear ratio of the planetary transmission is as follows. _{N 2 / N 1 = 2D 1} / D 2 = _{[2 (D 0 -d) / (} D 0
-2d)]> 2 where N ₁ is the rotation speed of the plasticizing screw N ₂ is the rotation speed of the injection plunger D ₀ is the pitch circle diameter of the mesh between the internal gear and the planetary gear D ₁ is the rotation orbit of the planetary gear The center circle diameter D ₂ is the meshing pitch circle diameter of the planetary gear and the injection plunger drive wheel, and d is the diameter of the planetary gear.

[0029]

As is apparent from the above description, in the present invention, the plasticizing cylinder and the screw for plasticizing the plastics can be obtained in a uniform and uniform plasticized state. Since the heat history when forming is small, there is little deterioration of the material, and by extruding plasticized plastics with a small-diameter injection plunger, it is possible to maintain an accurate injection amount at high pressure, and it is a strong molded product with strong strength Can be molded with less deformation. Further, since the injection plunger is rotated, it is possible to prevent resin leakage and it is safe.

[Brief description of the drawings]

FIG. 1 is a plan view showing one embodiment of the present invention.

FIG. 2 is a longitudinal sectional view taken along line BB of FIG.

FIG. 3 is a rear view of the screw driving device as viewed from CC in FIG. 2;

FIG. 4 is a view showing a resin flow when an inner surface of an injection cylinder is formed into a screw.

FIG. 5 is a diagram showing a rotation speed of a planetary transmission.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Plasticization cylinder 2 Plasticization screw 3 Injection cylinder 4 Injection plunger 5 Injection cylinder cap 6 Nozzle 7 Plastification cylinder holder 8 Rotating shaft 9 Gear case 10, 11, 18, 19 Bearing 12 Drive device case 13 Motor 14 Pinion 15 Gear 16 Cross head 17 Rotating shaft 20 Piston rod 21 Piston head 22 Hydraulic cylinder 23 Tiber 24 Frame 25 Internal gear 26 Planetary gear 27 Planetary gear support pin 28 Pin support plate 29 Injection plunger drive wheel 30 Floating key 31 Raw material inlet 32 Space 33 Gap 34 Screw groove 35 Tip of injection cylinder 36 Rod side of hydraulic cylinder 37 Screw flight of injection plunger 38 Screw flight of injection cylinder

Claims (4)

[Claims] 1. An injection molding machine in which a plasticized screw is rotatably disposed in a plasticizing cylinder, and a rotatable injection plunger having a tip shape of a screw is slidably mounted on the axis of the plasticizing screw. Injection device. 2. A plasticizing screw is rotatably arranged in a plasticizing cylinder, and a rotatable injection plunger having a tip shape of a screw is slidably incorporated into a shaft center of the plasticizing screw. An injection apparatus for an injection molding machine, wherein the number of rotations is greater than the number of rotations of a plasticizing screw to prevent resin leakage from the plunger. 3. An injection device for an injection molding machine according to claim 1, wherein a screw groove in a direction opposite to a screw of the injection plunger is machined on an inner surface of the plasticizing cylinder to facilitate feeding of the plasticized resin. . 4. The injection device for an injection molding machine according to claim 1, wherein the rotational speeds of the plasticizing screw and the injection plunger are changed by using a driving planetary gear device.