JPH06190889A - Feedback control method for injection molding machine - Google Patents

Abstract

PURPOSE:To change smoothly pressure and velocity without causing a transitory unstable phenomenon by setting an initial value with the determined internal variable of a feedback control value operating part which conducts next shift- control with the final output value of the feedback control value operating part at the time of shifting feedback control. CONSTITUTION:When an indication requiring shifting an injection process from the state in which, for example, velocity feedback control is being conducted to pressure feedback control comes to a feedback control part 1, an internal variable for the feedback control calculation is obtained which is used in a pressure feedback control value operating part 14 in a pressure feedback system which is to be shift controlled next by the final value from a velocity feedback control value operating part 13 in a velocity feedback system which has conducted control so far, and the internal variable is set as an initial value. A similar operation is conducted when the pressure feedback control is shifted to the velocity feedback control.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a feedback control method for an injection molding machine, and more particularly to a speed / pressure control in an injection stroke (a stroke consisting of a primary injection stroke and a pressure holding stroke, which is an injection / filling stroke). The present invention relates to a feedback control method.

[0002]

2. Description of the Related Art In an injection molding machine, the control conditions of the injection speed and the injection pressure are important factors for molding a good product, and an injection molding machine that controls the injection speed and the injection pressure by feedback control Various proposals have been made.

In a conventional injection molding machine that performs feedback control, generally, in a primary injection process in which a molten resin is injected and filled in a cavity of a mold, a measured speed value approaches a speed setting value. The injection speed feedback control (feedback control giving priority to the injection speed) is performed, and in the pressure-holding process in which the pressure-holding pressure is applied to the resin in the mold, the injection pressure is fed back so that the measured pressure value approaches the pressure setting value. Control (feedback control giving priority to injection pressure) is performed.

Alternatively, in the primary injection stroke and the pressure-holding stroke, it is not possible to arbitrarily switch from feedback control of injection speed to feedback control of injection pressure, or from feedback control of injection pressure to feedback control of injection speed. , Feedback control that prioritizes injection speed and feedback pressure that prioritizes injection pressure are automatically selected to suppress abnormal pressure rise and speed rise due to unexpected factors as much as possible. An injection molding machine taking a technique is also being developed (for this, if necessary, see Japanese Patent Application No. 4-283122 previously proposed by the applicant of the present application).

[0005]

By the way, when the feedback control of the injection speed and the feedback control of the injection pressure are switched during the injection stroke (primary injection and pressure holding stroke) as described above, the speed feedback control changes to the pressure feedback control. When switching to, or when switching from pressure feedback control to speed feedback control,
Since the feedback control is switched to one having a different property, there is a problem that an unstable state (a phenomenon such as a drop in speed or pressure or a shock) is likely to occur at the switching point.

In FIG. 3, the primary injection stroke is performed by speed feedback control along the stroke axis, and speed feedback control is switched from pressure feedback control at the pressure holding switching point to perform pressure feedback along the time axis. It is a graph figure which shows a speed actual measurement value and a pressure actual measurement value at the time of performing by control. As shown in the figure, the pressure drop phenomenon occurs in the portion A in the figure immediately after switching from the speed feedback control to the pressure feedback control. If a transient instability phenomenon such as a drop or shock at the switching point of the feedback control occurs (when the actual measurement value does not change smoothly and a gap is generated to show a sudden change), the angle feedback control is performed. There is a problem that it may cause a defective molded product even though the injection process is performed.

It should be noted that the control output value calculation processing for the pressure feedback control is executed even during the speed feedback control, and the speed feedback control is performed during the pressure feedback control. It is also conceivable that the control output value is calculated so that the feedback control can be instantaneously dealt with. However, even in this case, if feedback control based on PID (proportional / integral / derivative) operation, which is frequently used for precision control, is performed, the integral operation for the “I” operation starts from zero at the switching point. At first, it was undeniable that the value of the constant for integration became too large and the "I" operation was disturbed to cause a transient unstable phenomenon at the switching point of the feedback control.

In addition, in the case of injection feedback control of an injection molding machine, although PID is often not used, even in feedback control that does not use PID, the integral element corresponding to "I" becomes large and the same. There was such an unstable phenomenon.

The present invention has been made in view of the above points,
The purpose of this is to ensure that, in an injection molding machine that selectively switches between speed feedback control and pressure feedback control, transient instability does not occur even when feedback control is switched, and the speed and pressure are smoothly changed. To provide a variable feedback control method.

[0010]

In order to achieve the above-mentioned object, the present invention measures speed and pressure, compares the measured actual value with a set value, and the measured value approaches the set value.
In a feedback control method for an injection molding machine, which is capable of performing speed feedback control or pressure feedback control and arbitrarily switching from speed feedback control to pressure feedback control or from pressure feedback control to speed feedback control. At the switching of feedback control, the final output value from the feedback control value calculation unit of the feedback system that has been controlled up to now is used to calculate the feedback control used in the feedback control value calculation unit in the feedback system to be switched next time. It asks for an internal variable and sets it as an initial value.

[0011]

For example, when an instruction requesting to switch to the pressure feedback control from the state in which the injection stroke is being executed by the speed feedback control arrives at the feedback control unit, the feedback control unit causes the speed feedback control value calculation unit to operate. of using the final control output value y _1, the output conversion output conversion equation y ₂ = g ₂ of the manipulated variable value u ₂ → control output value y ₂ according to the pressure feedback control value calculation unit (u ₂₎ function g ₂ () Using the inverse function g ₂ to ¹ () of, the operation amount value u ₂ by the pressure feedback control value calculation unit is obtained by the following equation: u ₂ = g ₂ to ¹ (y ₁ ). Then, the following equation for calculating the manipulated variable value u ₂ used in the PID calculator in the pressure feedback control value calculator next

[0012]

[Equation 1]

The value of ∫e ₂ dt in the above is obtained by the following equation, and this is set as the initial value.

[0014]

[Equation 2]

When the pressure feedback control value calculation unit calculates using the initial value of ∫e ₂ dt (internal variable of the integral term) obtained as described above, it is output from the pressure feedback control value calculation unit. The initial control output value y ₂ is the final control output value y from the speed feedback control value calculation unit.
It becomes the same value as _1, and the control output value y ₂ from the pressure feedback control value calculation unit thereafter changes smoothly.

Also, when switching from the state in which the injection stroke is being executed by the pressure feedback control to the speed feedback control, the final control output value y ₂ from the pressure feedback control value calculation unit is used in the same manner as above. The manipulated variable value u ₁ by the velocity feedback control value calculation unit → the output conversion formula of the control output value y ₁ y ₁ = g ₁ (u ₁ ) output conversion function g ₁ () inverse function g ₁ to ¹ () is used Then, u ₁ = g ₁ to ¹ (y ₂ ) The manipulated variable value u ₁ by the speed feedback control value calculation unit is obtained by the following equation. Then, the following equation for calculating the manipulated variable value u ₁ used in the PID calculator in the speed feedback control value calculator next

[0017]

[Equation 3]

The value of ∫e ₁ dt in the above is obtained by the following equation, and this is used as an initial value.

[0019]

[Equation 4]

When the speed feedback control value calculation unit calculates using the initial value of ∫e ₁ dt (internal variable of the integral term) obtained as described above, it is output from the speed feedback control value calculation unit. The initial control output value y ₁ is the final control output value y from the pressure feedback control value calculation unit.
It becomes the same value as _2, and the control output value y ₁ from the speed feedback control value calculation unit thereafter changes smoothly.

By doing so, the feedback control in which the speed and the pressure can be smoothly changed is realized without causing a transient instability phenomenon even at the transition of the speed → pressure or the pressure → speed feedback control. it can.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a block diagram showing a main configuration of a feedback control system of an injection molding machine according to this embodiment, and FIG.
FIG. 6 is a graph showing an example of measured speed values and measured pressure values when the feedback control switching method according to the present embodiment is used.

In FIG. 1, reference numeral 1 is a feedback control unit for injection, which is a main component for executing feedback control of injection speed or feedback control of injection pressure, 2 is a D / A converter functioning as a valve driver, and 3 is injection. The flow rate control valves 4 provided in the injection hydraulic circuit system including the hydraulic cylinder are, for example, a known in-line screw type injection mechanism driven by the injection hydraulic cylinder. In this embodiment, the output of the feedback control unit 1 is passed through the D / A converter 2 and the flow control valve 3
And the flow rate (speed) of the pressure oil supplied to the injection hydraulic cylinder is feedback-controlled, or the pressure of the pressure oil is feedback-controlled.

The feedback control unit 1 is actually embodied by the processing of a microcomputer (microcomputer) executed based on a program created in advance, but here, for convenience of explanation, the deviation detection unit is used. 11, 12, a speed feedback calculation unit (speed feedback control value calculation unit) 13 having a PID calculation unit 13a and an output conversion unit 13b, and a pressure feedback calculation unit (pressure feedback control unit) having a PID calculation unit 14a and an output conversion unit 14b. The following description will be made on the assumption that the value calculation unit 14 and the feedback changeover switch unit 15 are provided.

In the deviation detecting section 11, the speed setting value V _O set along the stroke axis (distance axis) or the time axis and the measurement information of the stroke detection sensor (not shown) in the injection mechanism 4 are arithmetically processed. Measured speed value V obtained by
_m and _m are respectively supplied at appropriate sampling intervals.
The deviation detection unit 11 calculates a difference between the speed setting value V _O and the measured speed value V _m between the two V _O and V _m , and sets this as a deviation (deviation of speed) e ₁ and the speed feedback calculation unit 1
Output to 3. PID of speed feedback calculation unit 13
The calculation unit 13a uses the input deviation e ₁ to calculate PI
An operation amount u for performing feedback control based on D (proportional / integral / derivative) operation, that is, the computation process according to the following equation to match the measured speed value V _m with the set speed value V _o. Calculate ₁ . In the following equation, P ₁ , I ₁ and D ₁ are PID constants.

[0026]

[Equation 5]

In the output conversion unit 13b of the speed feedback calculation unit 13, the operation amount u ₁ output from the PID calculation unit 13a is converted into an output conversion formula of the operation amount value u ₁ → the control output value y ₁ y ₁ = g ₁ ( u ₁ ) is used to obtain the control output value y ₁ by performing arithmetic conversion processing, and this is output to the feedback changeover switch unit 15.

Further, the deviation detection unit 12 sets a pressure set value P _O set along the time axis or the stroke axis.
And the measured pressure value P _m obtained by appropriately converting the measurement information of the pressure detection sensor (not shown) in the injection mechanism 4 are supplied at appropriate sampling intervals. In the deviation detection unit 12, the pressure set value P _O and the pressure actual measurement value P _m
From the _above , the difference between the two P _O and P _m is calculated, and this is output to the pressure feedback calculation unit 14 as a deviation (deviation of speed) e ₂ . The PID calculator 14a of the pressure feedback calculator 14 uses the input deviation e ₂ to calculate the PID.
Processing for performing feedback control based on (proportional-integral-derivative) operation, i.e., executes the arithmetic processing by the following equation, the operation amount u ₂ for matching the pressure measurement P _m on the pressure setpoint P _O To calculate. In the following equation,
P ₂ , I ₂ and D ₂ are PID constants.

[0029]

[Equation 6]

In the output conversion unit 14b of the pressure feedback calculation unit 14, the operation amount u ₂ output from the PID calculation unit 14a is converted into an output conversion formula of the operation amount value u ₂ → the control output value y ₂ y ₂ = g ₂ ( u ₂ ) to obtain the control output value y _{2 by the} arithmetic conversion processing,
This is output to the feedback changeover switch unit 15.

In the feedback changeover switch section 15, a control output value y ₁ from the speed feedback calculation section 13 or a control output value y from the pressure feedback calculation section 14 is controlled by a switch changeover control signal (not shown).
Either one of _2, and outputs it to alternatively the D / A converter 2, whereby when the upper control unit (not shown) is instructed speed feedback control, from the speed feedback calculator 13 When the speed feedback control based on the control output value y ₁ is executed, and when the higher-order control unit (not shown) instructs the pressure feedback control, the pressure based on the control output value y ₂ from the pressure feedback calculation unit 14 Feedback control is executed. The switching timing from the speed feedback control to the pressure feedback control or the switching timing from the pressure feedback control to the speed feedback control is set in advance in this embodiment according to the injection stroke from the reference position or the time from the reference time point. It has been done.

The switching from the speed feedback control to the pressure feedback control or the switching from the pressure feedback control to the speed feedback control is performed, for example, by the applicant previously proposed in Japanese Patent Application No. 4-28.
As shown in No. 3122, the magnitude relationship between the measured pressure value P _m and the pressure set value P _O and the magnitude relationship between the measured speed value V _m and the speed set value V _O are constantly compared to each other, and the primary injection stroke is performed. When it is detected that P _m <P _O has changed to P _m > P _O , the speed feedback control is switched to the pressure feedback control, and the pressure feedback control is performed during the primary injection stroke. And V _m > V
_When it is detected that it becomes _O , it switches to the speed feedback control again, while V
_When it is detected that the state of _m <V _O has changed to V _m > V _O , the pressure feedback control is switched to the speed feedback control, and when the speed feedback control is performed during the pressure holding process, P _It may be configured to switch to the pressure feedback control again when it is detected that _m > P _O.

Here, the above-mentioned feedback control unit 1
The calculation process for the feedback control performed in (1) is for performing the feedback control based on the known PID (proportional / integral / derivative) operation. The output is assumed to be linearly increased / decreased by the integral action with respect to the unit step input in the (I) operation, and the time advance is caused by the differential action in the (D) operation, and these (P), (I), (D)
Feedback control is performed by simultaneously performing the operations. By performing such PID control, it is possible to perform feedback control that anticipates (covers) the hydraulic pressure response, and to suppress as much as possible overshoot and oscillation due to too sharp rising, and also to make the rising too dull. It is possible to eliminate the delay in the arrival time to the target due to, and it is possible to obtain a suitable rising characteristic.

Next, the operation when switching from the speed feedback control to the pressure feedback control and the operation when switching from the pressure feedback control to the speed feedback control will be described.

When the feedback control section 1 receives a command to switch to the pressure feedback control during execution of the speed feedback control, the feedback control section 1 causes the feedback control section 1 to output the final control output value y from the speed feedback calculation section 13. _{Using 1} , the output conversion function g ₂ () of the output conversion formula y ₂ = g ₂ (u ₂ ) of the manipulated variable value u ₂ → the control output value y ₂ in the output conversion unit 14b of the pressure feedback calculation unit 14 is used. Using the inverse function g ₂ ^-1 (), the following equation is given: u ₂ = g ₂ ^-1 (y ₁ ) PID calculator 14 of the pressure feedback calculator 14
The manipulated variable value u _{2 according} to a is obtained. Then, the following equation for calculating the manipulated variable value u ₂ used in the PID calculation unit 14a of the pressure feedback calculation unit 14 next.

[0036]

[Equation 7]

The value of ∫e ₂ dt in the above is obtained by the following formula, and this is set as the initial value.

[0038]

[Equation 8]

When the pressure feedback calculation unit 14 performs calculation using the initial value of ∫e ₂ dt (internal variable of the integral term) obtained as described above, the initial value output from the pressure feedback calculation unit 14 is calculated. The control output value y ₂ becomes the same value as the final control output value y ₁ from the speed feedback calculation unit 13, and the control output value y ₂ from the pressure feedback calculation unit 14 thereafter changes smoothly.

When a command for switching to the speed feedback control arrives at the feedback control unit 1 while the pressure feedback control is being executed, the final control output value y ₂ from the pressure feedback calculation unit 14 is used to determine the speed. The manipulated variable value u ₁ in the output conversion unit 13b of the feedback calculation unit 13 → the output conversion function of the control output value y ₁ y ₁ = g ₁ (u ₁ ) The inverse function g ₁ to ¹ () of the output conversion function g ₁ () of ) Is used to obtain the manipulated variable value u ₁ by the PID calculator 13a of the velocity feedback calculator 13 according to the following equation: u ₁ = g ₁ to ¹ (y ₂ ). Then, the following equation for calculating the manipulated variable value u ₁ used in the PID calculation unit 13a of the speed feedback calculation unit 13 next

[0041]

[Equation 9]

The value of ∫e ₁ dt in the above is obtained by the following equation, and this is set as the initial value.

[0043]

[Equation 10]

Using the initial value of ∫e ₁ dt (internal variable of the integral term) obtained as described above, when the speed feedback calculation unit 13 performs calculation, the initial value output from the speed feedback calculation unit 13 The control output value y ₁ becomes the same value as the final control output value y ₂ from the pressure feedback calculation unit 14, and the control output value y ₁ from the speed feedback calculation unit 13 thereafter changes smoothly.

By doing so, the feedback control in which the speed and the pressure can be smoothly transitioned is realized without causing a transient instability phenomenon even at the transition of the speed → pressure or the pressure → speed feedback control. it can.

FIG. 2 shows one of the measured speed value and the measured pressure value when the feedback control switching method according to this embodiment is used.
FIG. 4 is a graph showing an example, and similarly to FIG. 3 described above, the primary injection stroke is performed by speed feedback control along the stroke axis, and the speed feedback control is switched to the pressure feedback control at the pressure holding switching point to hold pressure. The figure shows a measured speed value and a measured pressure value when the process is performed by pressure feedback control along the time axis. As shown in the figure, when the present invention is applied, even after switching from the speed feedback control to the pressure feedback control, a transient instability phenomenon such as pressure drop or shock does not occur, It draws a smooth pressure curve.

In the above description of the embodiment, the feedback control for performing the PID operation has been described, but the present invention is applicable regardless of whether the PID is used or not, and the PID operation is not used. Also in the feedback control, it is possible to provide a feedback control method that does not cause a transient unstable phenomenon at the switching point of the speed / pressure feedback control.

[0048]

As described above, according to the present invention, in an injection molding machine in which speed feedback control and pressure feedback control are selectively switched to each other, a transient unstable phenomenon occurs even when the feedback control is switched. Without this, it is possible to provide a feedback control method capable of smoothly changing the speed and pressure, and its value is great.

[Brief description of drawings]

FIG. 1 is a block diagram showing a main configuration of a feedback control system of an injection molding machine according to an embodiment of the present invention.

FIG. 2 is a graph showing an example of measured speed values and measured pressure values when a feedback control switching method according to an embodiment of the present invention is used.

FIG. 3 is a graph showing an example of measured speed values and measured pressure values when a feedback control switching method according to the related art is used.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Feedback control unit 2 D / A converter 3 Flow control valve 4 Injection mechanism 11, 12 Deviation detection unit 13 Speed feedback calculation unit 13a PID calculation unit 13b Output conversion unit 14 Pressure feedback calculation unit 14a PID calculation unit 14b Output conversion unit 15 Feedback changeover switch unit 15

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical display location G05B 7/02 A 7531-3H 11/36 H 7531-3H

Claims (2)

[Claims] 1. The speed and pressure are measured, and the measured value measured and the set value are compared so that the measured value approaches the set value.
In an injection molding machine capable of performing speed feedback control or pressure feedback control and arbitrarily switching from speed feedback control to pressure feedback control or from pressure feedback control to speed feedback control, the feedback control The internal variable for feedback control calculation used in the feedback control value calculation unit in the feedback system to be switched next, according to the final output value from the feedback control value calculation unit in the feedback system that has been controlled until now. And a feedback control method for the injection molding machine, which is set as an initial value. 2. The use according to claim 1, wherein the feedback control value calculation unit of the feedback system to be switched next is used based on the final output value from the feedback control value calculation unit of the feedback system which has been controlled up to now. The feedback control method for an injection molding machine, wherein the internal variable calculated in (1) is a variable of a term that integrates the deviation.