JP2839480B2 - Feedback control method of force in injection molding machine - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling an electric injection molding machine using an electric servomotor as a drive source for mold clamping, injection and the like. 2. Description of the Related Art In a conventional electric injection molding machine, a servo circuit composed of hardware of a position control unit and a speed control unit responds to a movement command issued to each servomotor. The motor position, speed, and torque were controlled. For example, FIG. 2 shows an example of a conventional control system. Numeral 100 denotes a numerical controller (hereinafter, referred to as an NC device) for controlling an injection molding machine. The NC device 100 includes a microprocessor (hereinafter, referred to as a CPU) 101 for an NC and a CPU 102 for a programmable machine controller (hereinafter, referred to as a PMC). CPU1 for PMC
02 is connected to a ROM 105 storing a sequence program for controlling a sequence operation of the injection molding machine, and the like.
Also, a RAM 112 used for temporary storage of data and the like is connected. A ROM 10 in which a management program for controlling the entire injection molding machine is stored in the NC CPU 101
4 and a servo circuit for driving and controlling a servomotor for each axis for injection, clamping, screw rotation, ejector, etc., are connected via a servo interface 106. 2, only the servomotor 2 for injection and the servo circuit 107 of the servomotor 2 are shown. Reference numeral 108 denotes a non-volatile shared RAM constituted by a bubble memory or a CMOS memory, and a memory section for storing an NC program for controlling each operation of the injection molding machine and various setting values and parameters by macro variables. It has a memory section for storing macro variables. Reference numeral 103 denotes a bus arbiter controller (hereinafter, referred to as BAC).
3 includes a CPU 101 for NC and a CPU 102 for PMC,
Each bus 115 of the shared RAM 108, the input circuit 109, and the output circuit 110 is connected, and the bus used is controlled by the BAC 103. [0005] Reference numeral 114 denotes a manual data input device with a CRT display device (hereinafter referred to as CRT / MDI) connected to the BAC 103 via the operator panel controller 113. A RAM 111 is bus-connected to the NC CPU 101 and is used for temporarily storing data. In the example shown in FIG. 2, an injection shaft of an injection molding machine, that is, an injection servomotor 2 for driving and injecting a screw 1 is attached to the injection servomotor, and the rotation of the servomotor is controlled. A pulse coder 3 for detecting and detecting the screw position, and a rotation of the injection servomotor 2 are converted into a linear motion, and are disposed on a thrust bearing portion of a screw shaft of a pusher plate for moving the screw 1 in the screw axis direction. 1 shows a pressure sensor 4 for detecting a pressure applied to a screw 1 from a resin, and other mold clamping shafts, screw rotation shafts, ejector shafts and the like are omitted. Therefore, only the servo circuit 107 in the NC device 100 for the injection servomotor is shown, and the servo circuits for the other axes are omitted. [0007] The servo circuit 107 is connected to the injection servomotor 2, and outputs of the pulse coder 3 and the pressure sensor 4 are also input to the servo circuit 107. Further, a torque limit value for controlling the output torque of the injection servomotor 2 is output from the output circuit 110 to the servo circuit 107. In the above configuration, the NC device 10
0 is a PMC CPU based on the NC program for controlling each operation of the injection molding machine stored in the shared RAM 108 and the sequence program stored in the ROM 105.
While the CPU 102 performs the sequence control, the NC CPU 1
In order to control each operation of the injection molding machine, a pulse is distributed to a servo circuit 107 of each axis of the injection molding machine via the servo interface 106 to control the injection molding machine. The servo circuit of each axis subtracts the pulse from the pulse coder 3 from the distribution pulse received via the servo interface 106, and outputs an error register for outputting the current error amount with respect to the commanded position and an output of the error register to D / D. A position control unit composed of a D / A converter for A-converting and outputting as a speed command; receiving a speed command from the position control unit; The current speed is detected from the output thus obtained, or a tach generator may be provided to detect the current speed using the output of the tach generator.) Speed controller, current servo motor 2
Hardware such as a current controller for controlling the output torque by controlling the current flowing to the servomotor 2 by comparing the current flowing through the motor with the current command output from the speed controller, and a speed control unit composed of a power amplifier It has a configuration. Further, as in the case of the injection shaft, the injection pressure, the holding pressure,
In order to control the back pressure and the like, the current command output from the speed controller to control the output torque of the servomotor 2 is limited to a predetermined value or less in order to control the torque. Torque limit means is inserted between the speed controller and the current controller, and the output from the output circuit 110 controls the torque limit value. Further, in the example of FIG. 2, the pressure sensor 4 detects the pressure applied to the resin (the pressure applied to the resin is applied to the screw 1 as a reaction), and it is possible to select a case in which pressure feedback control is performed during injection and pressure holding. In this case, the pressure detected by the pressure sensor 4 is compared with the torque limit value output from the output circuit 110, and the output torque of the servomotor is controlled according to the difference. I have. As described above, in a conventional electric injection molding machine, a servo circuit for controlling a servomotor of each axis of the injection molding machine includes a position control unit and a speed control unit. Further, since the torque limit means and the pressure feedback control means are also configured by hardware, a servo circuit of this hardware is required for each servo motor for each axis. Further, when changing the characteristics of the servo control method or the pressure feedback control means, it is necessary to change the circuit constants (resistance value, etc.) and the circuit itself. Since the torque limit value is also input to the servo circuit 107 via the output circuit 110, the resolution of the torque limit value (the minimum unit size) is also the resolution of the output circuit 110 (the number of bits of the output signal).
Therefore, the control unit of the pressure control is naturally limited. SUMMARY OF THE INVENTION It is an object of the present invention to provide a control method for an electric injection molding machine that can accurately execute force feedback control by an electric servomotor and can easily change a feedback control characteristic. [0013] The present invention relates to an injection molding machine.
The drive source that drives the movable part is composed of an electric servomotor
In the electric injection molding machine, the first
A processor, and the first processor and the shared RAM are connected to a bus.
A controller for controlling the drive of the connected electric servomotor.
And a second processor for controlling the servo. Furthermore, on
A force sensor for detecting a force applied to the movable portion is provided. Soshi
And the second processor is the first processor.
Controls the position and speed based on the movement command output from the
When controlling pressure, replace the above
The detection signal from the force sensor is fed to the second processor.
And the force commanded by the first processor
And the force detected by the force sensor
Feedback control is performed. FIG. 1 is a block diagram showing a main part of an embodiment of the present invention. Similar to FIG. 2, an injection shaft of an injection molding machine is illustrated. Not shown. 1 is a screw, 2 is an injection servomotor for injecting the resin by moving the screw in the axial direction, 3 is a pulse coder attached to the injection servomotor 2, 4 is a pressure sensor for detecting the pressure applied to the resin, 5 Are cylinders, which are the same as in FIG. Numeral 10 denotes N for controlling the injection molding machine.
C device, the NC device 10 is an NC CPU 11, a PMC
A ROM 17 storing a control program and a RAM 18 used for temporary storage of data are connected to the NC CPU 11 by a bus 25.
The MC CPU 12 has a ROM 19 storing a sequence program, and a RAM 2 used for temporarily storing data.
0 are connected by a bus 25. 14 is BAC, NC
The shared RAM 15 for storing programs and various set values, the NC CPU 11 and the PMC CPU 12 are connected by a bus 25, and control the bus used by the BAC 14. A CRT / MDI 22 is connected to the BAC 14 via an operator panel controller 21. The above configuration is the same as that of the conventional NC apparatus for controlling an injection molding machine shown in FIG.
11 differs in the method and configuration for driving the servomotors of each axis. Reference numeral 13 denotes a CPU for controlling the output torque, speed, and position of the servo motor of each axis of the injection molding machine, that is, a CPU for servo control. Servo shared RAM 1 for storing an output circuit 24 and a control program for servo control, etc.
6 is connected, and the CP for NC is
It is bus-connected to U11. The input / output circuit 24 has a driver (D / A)
A power amplifier 6 is connected via a converter (including a converter) 7, and the output of the power amplifier 6 drives the injection servomotor 2. The output of the power amplifier 6, that is, the drive current of the injection servomotor 2 is supplied to the input / output circuit 24 by A.
The drive current value data converted by the / D converter 9, the pressure data obtained by converting the output of the pressure sensor 4 into a digital signal by the A / D converter 8, and the output of the pulse coder 3 are input. When other servomotors are used as drive sources for other shafts of the injection molding machine (mold clamping shaft, screw rotating shaft, ejector shaft, etc.), power amplifiers for the respective servomotors are used. , A driver, and an A / D converter for converting the drive current of the servomotor into a digital signal are provided. The input / output circuit 24 is connected to the driver, the A / D converter, and a pulse coder attached to each servomotor. ing. In the above-described configuration, when the injection molding machine is operated, the NC unit 10 performs sequence control according to the sequence program stored in the ROM 19, and the NC CPU 11 By the NC program stored in
It controls each operation of the injection molding machine and outputs a movement command to the servo motor of each axis.
Stored in AM16. The servo CPU 13 performs position control, speed control and torque control of the servo motor for each axis in response to the movement command for each axis. When input to the RAM 16, the servo CPU 13 subtracts a value of a counter provided in the input / output circuit 24 for counting feedback pulses from the pulse coder 3 from the movement command value at predetermined intervals, and obtains the current position deviation amount. From the difference between this position deviation amount and the current speed of the servo motor 2 obtained by the change in the value of the counter for counting the feedback pulse, a command current to the servo motor 2 is obtained. The difference between the current driving current value of the servo motor input through the A / D converter 9 and the input / output circuit 24 is determined by the input / output circuit 24 and the driver 7. And outputs to the power amplifier 6, and thus driving the injection servomotor 2. At this time, when the torque control is performed by limiting the output torque of the injection servomotor, the drive current command output to the driver 7 is kept below the value set by the program. When pressure feedback control is performed based on the detected resin pressure, the difference between the resin pressure signal obtained by converting the output of the pressure sensor 4 into a digital signal by the A / D converter 8 and the pressure value commanded by the program is output to the driver 7. Will be done. In the above example, the injection axis has been described, but the same processing is performed for the other axes. According to the present invention, since the feedback control of the force is performed by a processor different from the processor for controlling the injection molding machine, the response to the fluctuation of the force to be controlled is improved. Feedback control of optimal force can be performed. In addition, since the force feedback control is performed by software by the processor, it is easy to change the feedback characteristic (change of gain, etc.), and it is possible to optimize the feedback characteristics (resin pressure, back pressure, mold clamping pressure, etc.). Control becomes possible. Also, since the feedback control is performed by directly detecting the force applied to the movable part of the injection molding machine, the resolution of the torque limit value is affected compared to the case where the output torque of the servomotor is limited by the torque limit value to control the force. It is possible to perform optimal control. Further, since control is performed by the microprocessor, learning control can be performed according to the state of the previous injection molding cycle.

[Brief description of the drawings] FIG. 1 is a block diagram of a main part of an embodiment of the present invention. FIG. 2 is a main block diagram of a conventional system. [Explanation of symbols] 1 screw 2 Servo motor for injection 3 pulse coder 4 Pressure sensor 10 NC equipment 13 Servo microprocessor (servo CPU) 16 Servo shared RAM

Continuation of front page (56) References JP-A-62-127221 (JP, A) JP-A-61-154820 (JP, A) JP-A-61-235119 (JP, A) JP-A-55-39944 (JP, A) (A) JP-A-60-218113 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) B29C 45/00-45/84 B29C 33/20-33/54

Claims (1)

(57) [Claims] In an electric injection molding machine in which a driving source for driving a movable portion of the injection molding machine is an electric servomotor, a movement command is issued.
And a first processor for generating
The drive of the electric servomotor connected to the shared RAM via a bus
And a second processor for servo control for performing dynamic control.
And a force sensor for detecting the force applied to the movable part.
And the second processor is provided with the first processor.
Position and speed control based on movement commands output from the
When controlling pressure, instead of position and speed control,
The detection signal from the force sensor is sent to the second processor.
Feedback the command from the first processor.
Force to match the force detected by the force sensor.
A feedback control method of force in an injection molding machine, wherein the feedback control is performed.