JP2006262636A - Multi-axial servo driver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cost-effective, small-sized, and multi-axial servo driver that controls a plurality of servomotors. <P>SOLUTION: In the multiple-axial servo driver that controls a plurality of the servomotors, a plurality of servo amplifiers are provided, that are made up of a CPU 4 that carries out the processing of at least the position control or the speed control; a number-of-control-axes setting means 11 that stores the number of servomotors to be controlled as the number of control axes; a control-period setting means that stores the control period that carries out the position control or speed control; a control-period generating circuit 8 that outputs control-period signal, based on the control period set to the control-period setting means; a current control means 23; and a motor drive power portion 9. When the control-period signal is inputted into the CPU, a position control unit or a speed control unit controls the position or the speed with the CPU by the number of control axes set by the number-of-control-axes setting means sequentially for first-axial position control, first-axial speed control, second-axial position control, and second-axial speed control. Based on the output from the speed control unit, the current is controlled by the current control means at an independent timing from the CPU. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a multi-axis servo driver that controls a plurality of servo motors.

  A conventional multi-axis servo driver has a plurality of servo motors installed in one device and is equipped with a plurality of control units for controlling one servo motor. This control unit has an individual CPU for controlling one servo motor. Provided in the control unit. FIG. 3 shows a configuration diagram of a conventional multi-axis servo driver. A multi-axis servo driver 1 is equipped with a plurality of control units 2 that control one servo motor. Each control unit 2 includes a CPU 4 and a motor drive power unit 9 to control one servo motor, and a servo motor 10 and an encoder 7 are connected thereto. A servo motor 10 is connected to an encoder 7 for performing feedback control.

  FIG. 4 is a block diagram of the control unit 2 of FIG. In FIG. 4, the control unit 2 includes a position control unit 21, a speed control unit 22, a current control unit 23, and a motor drive power unit 9. The position control unit 21 performs position control based on the position command value input by the host device, the external pulse train signal, and the like and the feedback signal (position feedback signal) from the encoder 7, and sends the speed command value to the speed control unit 22. Output. The speed control unit 22 performs speed control based on the speed command value input from the position control unit 21 and the feedback signal (speed feedback signal) from the encoder 7, and outputs the torque command value to the current control unit 23. The current control unit 23 performs current control based on the torque command value input from the speed control unit 22 and a current feedback signal such as an AD converter, and outputs a PWM command to the motor drive power unit 9. The motor drive power unit 9 causes a current to flow through the servo motor 10 to rotate the servo motor 10.

In this way, the conventional multi-axis servo driver has a plurality of servo motors installed in one device, and is equipped with a plurality of control units composed of a CPU and a motor drive power unit to control each servo motor. (For example, refer to Patent Document 1).
Normally, NC machine tools, robots, and the like require at least 2 to 3 servo motors, and many have 6 or more servo motors. Further, as represented by humanoid robots, servo drivers tend to be miniaturized so that they can be installed inside the robot.
Japanese Unexamined Patent Publication No. 2000-60181 (FIG. 1)

However, generally, when a CPU is added, a peripheral IC such as a RAM or a ROM and a circuit such as a data bus connected to the peripheral IC are required. As the number of CPUs increases, the space and cost increase. The control unit described above requires a CPU, which increases the cost and space of one control unit. Therefore, it cannot be said that a conventional multi-axis servo driver composed of a plurality of control units described above is inexpensive. There is also a problem that the multi-axis servo driver becomes large.
The present invention has been made in view of such problems, and an object thereof is to provide an inexpensive and small-sized multi-axis servo driver.

In order to solve the above problem, the invention according to claim 1 is a multi-axis servo driver that controls a plurality of servo motors, and at least one CPU that executes processing of position control or speed control, and the plurality of control. Control axis number setting means for storing the number of servo motors as the number of control axes, control cycle setting means for storing a control cycle for executing position control or speed control, and a control cycle set in the control cycle setting means A control cycle generating circuit that outputs a control cycle signal, a position control unit that performs position control, a speed control unit that performs speed control, and current control at a timing independent of the CPU to control one servo motor. A plurality of servo amplifiers each including a current control means having a function to perform and a motor drive power unit for supplying a current to the servo motor. When a periodic signal is input to the CPU, the position control unit or the speed control unit performs the first axis position control, the first axis speed control, the second axis position control, the second axis speed control, The position control or speed control is executed by the CPU for the number of control axes set in the control axis number setting means in order, and the current control means is independent of the CPU based on the output from the speed control unit. The current control is performed by
According to a second aspect of the present invention, in the first aspect, the number of control axes and the control cycle are set via communication from a parameter setting device, and the set number of control axes and the control cycle are the control values. It is stored in the number-of-axis setting means and the control cycle setting means.
According to a third aspect of the present invention, in the first aspect, the control cycle is calculated based on the number of control axes, position control, and speed control processing time, and is stored in the control cycle setting means. .
According to a fourth aspect of the present invention, in the first aspect, the current control means is a current control LSI.

According to the first aspect of the present invention, the position control and the speed control are executed by one CPU, so that the total price can be reduced and the size can be reduced.
Further, according to the invention described in claim 2, since the control accuracy generally improves as the control cycle of position control and speed control is shorter, the number of mechanical systems to which the multi-axis servo drive is applied, that is, the number of servo motors to be connected. By setting the control cycle of the position control and the speed control according to the CPU performance can be utilized to the maximum, and as a result, the maximum control accuracy can be obtained according to the mechanical system.
According to the invention described in claim 3, since the control cycle is automatically set to the control cycle set value according to the number of control axes set to the control axis number set value, the labor for setting the control cycle is saved. As a result, the usability of the multi-axis servo driver can be improved.
According to the invention described in claim 4, since the current control means is a current control LSI, the multi-axis servo driver can be miniaturized.

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

  FIG. 1 is a configuration diagram of a multi-axis servo driver of the present invention. In the figure, reference numeral 1 denotes a multi-axis servo driver, which is a CPU 4 that executes processing such as position control and speed control, the number of servo motors to be controlled, that is, a control axis number setting value 11 that stores the number of control axes, and position control. And a control cycle setting value 12 that stores a control cycle for executing speed control, a control cycle generation circuit 8 that outputs a control cycle signal S1 according to the control cycle set in the control cycle setting value 12, and performs position control A position control unit 21, a speed control unit 22 for performing speed control, and a current control unit 23 for controlling one servo motor, and having a function of performing current control intelligently at a timing independent of the CPU 4 The servo amplifier 5 includes a plurality of servo amplifiers 5 each of which includes a motor driving power unit 9 that rotates by causing a current to flow through the LSI 6 and the servo motor 10. Reference numeral 3 denotes a parameter setting device that sets the number of servo motors to be controlled (the number of control axes) and a control cycle for executing position control and speed control. The set number of control axes is stored in the control axis number set value 11, and the set control cycle is stored in the control cycle set value 12. The control axis number setting value 11 and the control cycle setting value 12 are stored in a rewritable nonvolatile memory. A servo motor 10 is connected to an encoder 7 for performing feedback control.

  The present invention is different from Patent Document 1 in that the control axis number setting value 11 for storing the number of servo motors to be controlled, the control period setting value 12 for storing the period for executing position control and speed control, and the control period A control cycle generation circuit 8 that outputs a control cycle signal S1 according to a cycle set to the set value 12, a position control unit 21 for controlling a plurality of servo motors, and a CPU 4 that executes a speed control unit 22, A plurality of servo amplifiers 5 each including a current control LSI 6 that intelligently executes a current control unit 23 for controlling one servo motor and a motor driving power unit 9 that causes a current to flow through the one servo motor to rotate the servo motor are provided. Part.

  FIG. 2 is a timing diagram showing operations performed by the multi-axis servo driver of the present invention. In FIG. 2, when the control cycle signal S1 is input to the CPU 4, the position control unit is activated by the CPU and the position control of the first axis is executed. Specifically, as the position command for the first axis, the position command value input by the host device, the external pulse train signal, and the like, and the feedback signal (position feedback signal) from the encoder 7 connected to the servo motor for the first axis Position control is performed based on the above, and the speed command value for the first axis is output to the speed control unit 22. Next, the speed control unit 22 is activated by the CPU 4 and the speed control for the first axis is executed. Specifically, the speed control is performed based on the speed command value for the first axis input from the position control unit 21 and the feedback signal (speed feedback signal) from the encoder 7 connected to the servo motor for the first axis. Then, the torque command value for the first axis is output to the current control unit 23 of the current control LSI 6. Next, position control for the second axis, speed control, position control for the third axis, speed control,..., And the number of control axes set to the control axis number setting value 11 in advance by the parameter setting device 3 are repeated.

  Further, the cycle of the control cycle signal S1, that is, the control cycle for executing the position control and the speed control is the time required for executing the position control and the speed control for the total number of control axes set in the control axis number setting value 11. The above values are set in advance as the control cycle setting value 12 by the parameter setting device 3. Specifically, assuming that the number of control axes is 3, and processing time of 70 μs is required for position control and speed control per one axis, the control cycle needs to be 3 × 70 = 210 μs or more, for example, 300 μs is set. Keep it. Further, the control cycle setting value 12 may be automatically set according to the control axis number set to the control axis number setting value 11. Specifically, assuming that a processing time of 70 μs is required for the position control and speed control per axis, allowance for a time for performing other processing such as self-diagnosis and alarm detection processing (for example, 30 μs) is considered. When the processing time for position control and speed control per axis is 100 μs and the number of control axes is 3, the control cycle is automatically set to the control cycle set value 12 of 3 × 100 = 300 μs.

  On the other hand, the current control is executed for each axis by a current control LSI 6 that has a function of performing current control intelligently at a timing independent of the CPU 4 with a built-in current control unit 23. That is, the current control LSI 6 for each axis intelligently controls current control for each current control period based on the torque command value input from the speed control unit 22 and the current feedback signal from the AD converter at a timing independent of the CPU 4. To run. For example, the current control LSI 6 is designed in advance so that the current control period is 30 μs.

  As described above, the position control and the speed control are executed by one CPU, and the current control is converted to an LSI, and is executed by a plurality of LSIs for each servo motor, thereby realizing a reduction in price and size as a whole. In general, the shorter the control cycle of position control and speed control, the better the control accuracy. Therefore, control of position control and speed control according to the number of servo systems connected to the multi-axis servo drive, that is, the number of servo motors to be connected. By setting the cycle, the CPU performance can be utilized to the maximum, and as a result, the maximum control accuracy can be obtained in accordance with the mechanical system. For example, when a multi-axis servo driver manufactured for 6 axes is applied to a mechanical system that actually uses only 4 axes of servo motors, the number of control axes and the control cycle are set according to the number of servo motors. By setting, the control cycle of the position control and the speed control can be set short, and the maximum control accuracy can be obtained according to the mechanical system.

  By executing position control, speed control, and current control of multiple servo motors with a single CPU and multiple LSIs, a multi-axis servo driver can be configured compactly and at a low price, so an NC that uses multiple servo motors The present invention can be applied to servo drivers for machine systems such as machine tools and robots, especially servo drivers used in narrow spaces and inexpensive machine systems.

The block diagram which shows the structure of the multi-axis servo driver of this invention Timing chart showing the operation of the multi-axis servo driver of the present invention Block diagram showing the configuration of a conventional multi-axis servo driver Block diagram showing the configuration of the control unit in the conventional multi-axis servo driver

Explanation of symbols

1 Multi-axis servo driver 2 Control unit 3 Parameter setting device 4 CPU
5 Servo amplifier 6 Current control LSI
7 Encoder 8 Control cycle generation circuit 9 Motor drive power unit 10 Servo motor 11 Control axis number set value 12 Control cycle set value 21 Position control unit 22 Speed control unit 23 Current control unit

Claims (4)

  In a multi-axis servo driver for controlling a plurality of servo motors, at least one CPU for executing position control or speed control processing, and a control axis number setting means for storing the number of the plurality of servo motors to be controlled as the number of control axes Control cycle setting means for storing a control cycle for executing position control or speed control, a control cycle generation circuit for outputting a control cycle signal according to the control cycle set in the control cycle setting means, and position control A position control unit, a speed control unit for performing speed control, a current control unit having a function of performing current control at a timing independent of the CPU to control one servo motor, and a motor drive for supplying current to the servo motor A plurality of servo amplifiers configured with a power unit, and when the control cycle signal is input to the CPU, The control unit or the speed control unit includes the first axis position control, the first axis speed control, the second axis position control, the second axis speed control, and the control axis number set in the control axis number setting means in this order. A multi-axis servo driver characterized in that position control or speed control is executed by the CPU by the amount, and current control is performed at a timing independent of the CPU by the current control means based on an output from the speed control unit. .   The number of control axes and the control cycle are set via communication from a parameter setting device, and the set number of control axes and the control cycle are stored in the control axis number setting means and the control cycle setting means. The multi-axis servo driver according to claim 1.   The multi-axis servo driver according to claim 1, wherein the control cycle is calculated based on the number of control axes, position control, and speed control processing time, and is stored in the control cycle setting means.   The multi-axis servo driver according to claim 1, wherein the current control means is a current control LSI.

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