JPH0549450B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention is an injection molding machine equipped with a shaft-off nozzle, a screw head with a backflow prevention valve, etc., which prevents the backflow of molten resin during injection operation. The present invention relates to an injection control method and apparatus that can realize stable molding of good products.

[Conventional technology]

Conventionally, as this type of injection control method, there are methods 1 and 2 described below.

(1) As shown in Fig. 5, the nozzle hole closing device 31
The nozzle hole is closed in advance, and after completion of metering, the screw 32 is moved forward to temporarily apply the required pressure to the accumulated material at the front of the cylinder, thereby closing the check valve 30 and preventing the backflow that has occurred there. When the screw 32 reaches a position that does not affect the injection, that position is detected by a timer and is used as a reference point for the injection process, and the nozzle hole is opened and the injection speed, injection pressure, etc. are controlled step by step. , to ensure the filling of material into the mold (Japanese Patent Publication No. 10815/1981 No. 2)
(See left column of page).

(2) Using an injection molding machine similar to the conventional example shown in Fig. 5, the nozzle hole is closed in advance, and after measurement is completed, a predetermined amount of material is measured into the front of the cylinder by rotating and retracting the screw. Move the screw forward and apply pressure to completely close the non-return valve, then remove the pressure and stop it, then use the screw position after the required time as a reference point, close the mold, open the nozzle hole and close the screw. Move forward and apply injection pressure to the material to inject it into the mold. Changes in the position of the screw back and forth are detected electrically or mechanically, and the screw is automatically controlled when the screw position reaches a predetermined secondary injection pressure switching position or stop position. (Special Publication No. 62-20010 No. 2
(See left column of page).

[Problems to be Solved by the Invention] The above-mentioned conventional techniques (1) and (2) do not check whether the check valve is closed or not. There is a time loss involved in applying a predetermined pressure to the screw. In addition, if the backflow of molten resin is significant due to abnormalities such as cracks or wear in the check valve, applying a predetermined pressure for a certain period of time will cause the screw to move further forward without reducing its forward speed. There is a problem that when injection starts, the screw advances further than the injection stroke and exceeds the forward limit position.

The present invention has been made in view of the above-mentioned problems of the conventional technology, and by performing the injection process immediately after detecting the closing of the check valve, time loss is prevented, and It is an object of the present invention to provide an injection control method for an injection molding machine and a device therefor, in which the screw does not exceed the forward limit position during injection.

[Means to solve the problem]

In order to achieve the above object, an injection control method for an injection molding machine of the present invention uses an injection molding machine equipped with a shut-off nozzle that can open and close the nozzle hole and a screw having a check valve, and the nozzle hole is closed. After performing the plasticizing operation in the closed state, pressure is applied to the molten resin in front of the screw by moving the screw forward, and then, after opening the nozzle hole, the injection process is performed by moving the screw forward. In the injection molding method, the speed of the screw immediately after the check valve closes due to the advance of the screw before the start of injection is set in advance, and the speed of the screw is advanced at a constant pressure before the start of injection, and the speed of the screw is set in advance before the start of injection. Detect the forward speed of the screw at , and when the detected value of the forward speed exceeds the set value once and then decreases to match the set value, stop the screw, use the stopped position as the injection start reference position, and then start the injection. It is characterized in that the injection pressure and injection speed in the injection process are controlled by the movement position of the screw from the starting reference position.

Further, the injection control device for the injection molding machine of the present invention includes:
A screw having a shut-off nozzle that can open and close a nozzle hole and a check valve is provided, and after a plasticizing drive device performs plasticizing operation with the nozzle hole closed, the screw is advanced by an injection drive device. By applying pressure to the molten resin in front of the screw, and then opening the nozzle hole,
In an injection molding machine in which an injection process is performed by advancing a screw by an injection drive device, there is provided a pressure setting device for setting a constant pressure for advancing the screw before starting injection, and a pressure setting device for setting a constant pressure for advancing the screw before starting injection. and a speed setting device for presetting the speed of the screw immediately after the check valve closes due to forward movement, and the injection drive device operates the screw at a constant pressure set in the pressure setting device before starting injection. A speed detector for detecting the forward speed of the screw before the start of injection, a position detector for detecting the moving position of the screw during the injection process, and a detection value by the speed detector once When the set value of the speed setter is exceeded and then decreases to match the set value of the speed setter, a command to stop the screw is output to the injection drive device, and a detected value is sent from the position detector. and a controller that outputs commands to the injection drive device for controlling the injection pressure and injection speed in the injection process according to the movement position of the screw from the injection start reference position where the screw is stopped. [Operation] During injection molding, first, a plasticizing operation is performed with the nozzle hole closed. At this time, the backflow prevention valve is opened by the resin pressure during plasticization of the screw, and the molten resin flows forward and is stored in front of the screw.

Then, the screw is advanced at a constant pressure to pressurize the molten resin in front of the screw. During this time, the forward speed of the screw is increased, and the detected value once exceeds the set value determined from experience. Due to the increased pressure of the molten resin in front of the screw, the check valve is pushed back to the rear and closed. The forward speed of the screw is decelerated from the moment the valve is closed, and when the detected value decreases and matches the set value determined from experience, that is, the screw is stopped immediately after the check valve closes. The nozzle hole is opened and the injection process is performed using the stopping position of this screw as the reference position.
The injection pressure and the injection speed are controlled by the position of the screw from the stop position of the screw, that is, the injection start reference position.

Further, if the backflow of the molten resin is significant due to an abnormality in the check valve, the forward speed of the screw does not decrease, so the detected value does not match the set value and the subsequent injection process is not performed.

〔Example〕

Next, embodiments of the present invention will be described with reference to the drawings.

First, the configuration of an injection molding machine according to the present invention will be explained with reference to FIG.

The heating cylinder 1 is equipped with a shaft-off nozzle 3 at its tip and a hopper 4 at its rear portion. The shut-off nozzle 3 has a shut-off valve 2 that can open and close a nozzle hole. A screw 6 is inserted into the heating cylinder 1 and is provided with a screw head of the backflowing type, ie with a known non-return valve 5 in the form of a ring. Further, the rear end portion of the screw 6 is provided with a spline shaft 7 and a ball screw shaft 8 in which a spline groove is formed. A spline nut 9 integrally provided with a first pulley 10 is spline-coupled to the spline shaft 7, and the spline nut 9 rotates integrally with the spline shaft 7.

Reference numeral 11 indicates a first servo motor for plasticizing, and this first servo motor 11 is equipped with a first rotational speed detector 12, and a second pulley 13 is fixed to its output shaft. A first belt 14 is stretched between the second pulley 13 and the first pulley 10. The first servo motor 11 is driven and controlled by a first driver amplifier 15 to be described later, and with these configurations, the first servo motor 11
When the output shaft of the first servo motor 11 is started, the rotation of the output shaft of the first servo motor 11 is caused by the rotation of the second pulley 13, the first belt 14, and the first
The screw 6 is rotated by being transmitted to the screw 6 via the pulley 10 and the spline nut 9, and the rotation of the screw 6 performs a plasticizing operation.
As is clear from the above description, the spline shaft 7,
Spline nut 9, first pulley 10, first servo motor 11, second pulley 13, first belt 14
A plasticizing drive device A is constituted by the first driver amplifier 15 and the first driver amplifier 15 .

A ball nut 16 is screwed onto the ball screw shaft 8. The large diameter portion of the two-step cylindrical rotating member 17 is fixed to the ball nut 16, and the third pulley 18 is fixed to the small diameter portion of the rotating member 17.

Reference numeral 19 indicates a second servo motor for injection, and this second servo motor 19 is equipped with a second rotational speed detector 20 and has a fourth pulley 2 on its output shaft.
A second belt 22 is stretched between the fourth pulley 21 and the third pulley 18. The second servo motor 19 is driven and controlled by a second driver amplifier 23 to be described later, and with these configurations, the second servo motor 1
9, the rotation of the output shaft of the second servo motor 19 is caused by the fourth pulley 21, second belt 22,
The ball nut 16 is rotated by being transmitted to the ball nut 16 via the third pulley 18 and the rotating member 17, and as the ball nut 16 rotates, the screw 6 moves forward and an injection operation is performed. The second rotational speed detector 20 is connected to the second servo motor 19
By detecting the rotational speed of the screw 6, the forward speed of the screw 6 is detected. As is clear from the above description, the ball screw shaft 8, the ball nut 1
6, the rotating member 17, the third pulley 18, the second servo motor 19, the fourth pulley 21, the second belt 22, and the second driver amplifier 23 constitute an injection drive device B.

A constant pressure for advancing the screw 6 before the start of injection is set in the pressure setting device 24, and the advance of the screw 6 is controlled by the injection drive device B at the constant pressure based on a command from a controller 26, which will be described later. It is done under pressure.

The speed setting device 25 has the following values determined from experience:
Before the start of injection, the speed of the screw 6 immediately after the backflow prevention valve 5 closes due to the advance of the screw 6 is set in advance.

The position detector 28 detects the position of the screw 6 at the time of injection.
The detected value is input to a controller 26, which will be described later.

The controller 26 is the first drive amplifier 1
5 and the second driver amplifier 23, and this controller 26 is set with the rotational speed of the screw 6 during plasticizing operation, and also with the first movement amount and the first movement of the screw 6 during injection. 2 movement amount is also set. Further, the controller 26 detects that the second driver amplifier 23 detects that the detected value of the second rotational speed detector 20 once exceeds the set value of the speed setter 25 and then decreases to match the set value of the speed setter 25. When detected by the position detector 28, a command to stop the screw 6 is input to the second driver amplifier 23, and the position of the screw 6 detected by the position detector 28 is input. , the screw 6 from the injection start reference position where the screw 6 stopped.
The injection pressure and injection speed in the injection process are controlled by the moving position of. A predetermined time period from when the screw 6 moves forward is preset in the timer 27 before the start of injection.

Next, the operation of this embodiment will be explained.

A desired pellet material is previously supplied to the hopper 4, and the nozzle hole of the shut-off nozzle 3 is closed by the shut-off valve 2.

The first driver amplifier 15 drives and controls the first servo motor 11 according to a command from the controller 26, so that the screw 6 rotates at a rotational speed set in the controller 26. Then, the pellet material in the hopper 4 is plasticized and transferred to the front of the screw 6 as a molten resin, and the screw 6 is pushed rearward by the pressure of the molten resin. During this time, as shown in FIG. 2, the pressure P ₀ of the upstream molten resin D is greater than the pressure P ₁ of the downstream molten resin C, so the check valve 5 is opened and the downstream molten resin C is The second servo motor 19 for injection is driven via the second driver amplifier 23 in accordance with the back pressure command from the controller 26 in order to counter the pressure (plasticizing back pressure) and prevent the screw 6 from retreating. By applying an appropriate torque to the ball nut 16, the screw 6 is pressed forward.

After a predetermined period of time has elapsed, the first driver amplifier 15 and the second driver amplifier 23 stop the first servo motor 11 and the second servo motor 19 according to a command from the controller 26, and the plasticizing operation ends.

Next, the controller 26 outputs a command to the second driver amplifier 23, so that the second driver amplifier 23 drives and controls the second servo motor 19 so that the screw 6 moves forward at a constant pressure set in the pressure setting device 24. do.

During this time, the forward speed of the screw 6 is increased and pressure is applied to the molten resin in front of the screw 6, so that the pressure of the molten resin C on the downstream side is increased, as shown in FIG.
Since P ₁ ' becomes larger than the pressure P ₀ ' of the upstream molten resin D, the downstream molten resin C pushes back the check valve 5, and the check valve 5 is closed.

Further, the forward speed of the screw 6 is detected by the second rotational speed detector 20, and after a predetermined time set in the timer 27 after the forward movement of the screw 6 has elapsed, the detected value of the forward speed of the screw 26 is detected by the speed setting device 20. After the detected value exceeds the set value of the speed setter 25, the second driver amplifier 23 compares the detected value with the set value of the speed setter 25.

Since the forward speed of the screw 6 decelerates from the moment of the valve closing, the detected value and the set value match,
At this time, the second driver amplifier 23 outputs a notification to that effect to the controller 26. Then, the controller 26 outputs a command to the second driver amplifier 23 to stop the second servo motor 19, so that the screw 6 is stopped and held at the injection start reference position.

Next, the nozzle hole of the shut-off nozzle 3 is opened, and the controller 26 turns off the second driver amplifier 23.
By outputting an injection start command to , the screw 6 moves forward by the first movement amount at high speed and then moves forward by the second movement amount at low speed, that is, switching the injection speed and switching to holding pressure in the injection process. is automatically controlled.

Furthermore, if the backflow of molten resin is significant due to an abnormality in the check valve 5 before the start of injection, the forward speed of the screw 6 will not decrease, so the detected value will not match the set value, and the subsequent injection No process is performed.

According to this embodiment, injection is started with the check valve 5 closed before injection, and the injection speed is controlled by the movement position of the screw 6 from the injection start reference position, so that after the start of injection, the molten resin is No backflow occurs, and stable molding can be performed. Also,
In the unlikely event that the screw 6 advances to the injection stroke position, a method such as generating an alarm is used to reliably prevent the screw 6 from exceeding the forward limit position during injection.

In the above embodiment, the screw 6 is provided with a back-flooring type screw head, but the present invention is not limited thereto.As shown in FIG. may be used.

In addition, a plasticizing drive device including an oil motor,
Injection drives including fluid pressure sources, fluid pressure cylinders, flow control valves, and the like may be used.

〔Effect of the invention〕

Since the present invention is configured as described above, it produces the effects described below.

In the invention described in claim 1, since the injection process is performed immediately after the detection of the closing of the check valve before the start of injection, no time loss occurs. In addition, if there is a significant backflow of molten resin due to an abnormality in the check valve, etc., the forward speed of the screw will not decrease, so the abnormality can be detected, injection will not start, and the screw will be at the forward limit position at the time of injection. It cannot be surpassed.

In the invention set forth in claim 2, the injection control method described above can be carried out easily and reliably.

[Brief explanation of drawings]

FIG. 1 is an overall configuration diagram of an injection molding machine according to the present invention, and FIG. 2 is a cross-sectional view of the screw head after plasticization by the injection molding machine shown in FIG. 1 and a graph showing the pressure distribution inside the heating cylinder. Third
The figure shows a cross-sectional view of the screw head just before the start of injection by the injection molding machine shown in Figure 1, and a graph showing the pressure distribution inside the heating cylinder, Figure 4 is a cross-sectional view of another example of the screw head, and Figure 5 is a conventional technique. FIG. 2 is a sectional view of a main part of an injection molding machine. 1... Heating cylinder, 2... Shut-off valve,
3...Shut-off nozzle, 4...Hopper, 5,
5'...Return prevention valve, 6,6'...Screw, 7...
... Spline shaft, 8 ... Ball screw shaft, 9 ... Spline nut, 10 ... First pulley, 11 ...
First servo motor, 12...first rotation speed detector, 13...second pulley, 14...first belt,
15...First driver amplifier, 16...Ball nut, 17...Rotating member, 18...Third pulley,
19...Second servo motor, 20...Second rotation speed detector, 21...Fourth pulley, 22...Second belt, 23...Second driver amplifier, 24...Pressure setting device, 25... Speed setting device, 26...Controller, 27...Timer, 28...Position detector, A...Plasticization drive device, B...Injection drive device, C...Downstream melting resin, D...Upstream melting resin.

Claims (1)

[Claims] 1. Shut-off nozzle 3 whose nozzle hole can be opened and closed.
Using an injection molding machine equipped with a screw 6 having a non-return valve 5, after performing a plasticizing operation with the nozzle hole closed, the screw 6 is moved forward to prevent melting in front of the screw 6. In an injection molding method in which the injection process is performed by applying pressure to the resin, then opening a nozzle hole, and then moving the screw 6 forward, the backflow prevention valve 5 is closed by the advancement of the screw 6 before injection starts. The speed of the screw 6 immediately after is set in advance, the screw 6 is advanced at a constant pressure before the start of injection, the forward speed of the screw 6 is detected before the start of injection, and the detected value of the forward speed is once set to the set value. When the value exceeds and then decreases to match the set value, the screw 6 is stopped and the stopped position is set as the injection start reference position, and the injection pressure and An injection control method for an injection molding machine, the method comprising controlling injection speed. 2 Shut-off nozzle 3 that can open and close the nozzle hole
and a screw 6 having a check valve 5, and after the plasticizing operation is performed by the plasticizing drive device A with the nozzle hole closed, the injection drive device B
The screw 6 is advanced by the screw 6, which applies pressure to the molten resin in front of the screw 6. After opening the nozzle hole, the screw 6 is advanced by the injection drive device B to perform the injection process. In the molding machine, there is a pressure setting device 24 in which a constant pressure for advancing the screw 6 is set before the start of injection, and a pressure setting device 24 for setting the constant pressure for advancing the screw 6 before the start of injection, and a pressure setting device 24 for setting the screw 6 immediately after the check valve 5 closes due to the advance of the screw 6 before the start of injection. The injection drive device B is provided with a speed setting device 25 for setting the speed in advance, and the injection drive device B advances the screw 6 at a constant pressure set in the pressure setting device 24 before the start of injection. a speed detector 20 for detecting the forward speed of the screw 6 during the injection process; a position detector 28 for detecting the moving position of the screw 6 during the injection process; When the set value of the speed setter 25 is exceeded and then decreases to match the set value of the speed setter 25, a command to stop the screw 6 is sent to the injection drive device B.
, and also inputs the detected value from the position detector 28, and injects a command for controlling the injection pressure and injection speed in the injection process based on the movement position of the screw 6 from the injection start reference position where the screw 6 has stopped. Controller 26 outputting to drive device B
An injection control device for an injection molding machine, comprising: