JP2005135060A5 - - Google Patents

Description

Servo control device and adjustment method thereof

The present invention moves along the shape contour, servo controller for the trajectory tracking control and a method of adjusting.

In the conventional control device to move along the conventional shape contour to the trajectory tracking control, adjusts the position loop gain of the position control section by measuring the amount of overshoot or vibration, the shape error of a circular arc locus The moving speed is adjusted to be within a preset target arc radius reduction amount. For example, in Japanese Patent Laid-Open No. 8-137536, when the speed control is IP control, the moving speed is limited using the expression ( 1 ) from the allowable radius reduction amount, the position control gain, and the speed control integration time constant.

Where ΔR: arc radius reduction amount [mm], R: arc radius [mm], V: feed rate [mm / s], Kp: position control loop gain [1 / s], Ti: speed control loop integration time constant [Sec]

FIG. 5 is a block diagram showing a configuration of a conventional numerical controller .
In FIG. 5 , 31 is a machining program analysis unit that analyzes a machining program and determines whether or not it is a circular interpolation command, 32 is a circular interpolation command radius, an allowable radius reduction amount, and a servo control device analyzed by the machining program analysis unit. The maximum movement speed calculation unit 33 calculates the maximum movement speed from the position control loop gain and the integral time constant of the speed control loop using the equation ( 1 ), 33 is a command speed analyzed by the machining program analysis unit, and 32 is calculated. A final command speed selection unit 34 that compares the maximum movement speeds that are set and sets the smaller one as the final command speed, and 34 is an interpolation unit that performs interpolation calculation of the machining locus of the machining program based on the final command speed.

FIG. 6 is a flowchart showing the processing procedure of the conventional method .
In FIG. 6 , first, the machining program analysis unit determines whether or not the analyzed machining program is a circular interpolation command (step 1). Next, when it is determined that circular interpolation is performed by the machining program analysis unit, the maximum movement speed is calculated based on the equation ( 1 ) (step 2). Here, when the machining program analysis unit determines that the command is not the circular interpolation command, the maximum moving speed is not calculated. Next, the command speed by the machining program is compared with the maximum movement speed, and the smaller one is set as the final movement speed (steps 3 to 5). Next, an interpolation calculation of the machining program is performed based on the final movement speed, and a movement command for each control axis is calculated (step 6). Then, a movement command for each control axis is output to the servo control device (step 7).
JP-A-8-137536 (page 4-5, FIG. 1)

However, in the control apparatus and adjustment method moves along the conventional shape contour to the trajectory tracking control, moving speed only circular interpolation command is limited, if not circular interpolation, the moving speed is not limited, for example, minute continuous In the case of a circular arc shape command in a straight line, the moving speed is not limited, and there is a problem that the shape error increases because the machining is performed at the command speed.
In addition, the formula ( 1 ) does not take into account the speed feedforward that is normally used to reduce the shape error, so that when the speed feedforward is used, servo adjustment that reduces the shape error cannot be performed. There was also.
The present invention relates to a servo control device that can be easily adjusted so that the shape error becomes the target arc radius reduction amount, regardless of the command program or the moving speed, and even when the speed feedforward is used. It aims to provide a method .

In order to solve the above problems, the servo controller adjustment method according to the present invention has a position command and position feedback as inputs, a position control unit that outputs a speed command, a speed command, a speed feedback value, and a speed feed forward value as inputs. And adjusting a speed feedforward gain while measuring overshoot in a servo controller having a speed control unit that outputs a torque command and a drive unit that inputs the torque command and rotates the servo motor, and a target Obtaining a position control loop gain of the position controller by calculation from an arc radius reduction amount and the speed feedforward gain; adjusting the speed feedforward gain until the overshoot reaches an allowable value; and the position control Obtaining a position control loop gain of the It is characterized in further comprising a step of repeating.
In addition, the servo control device of the present invention has a position control unit that receives a position command and position feedback and outputs a speed command, a speed that outputs a torque command by inputting a speed command, a speed feedback value, and a speed feedforward value. A position for obtaining a position control loop gain of the position control unit by calculation from a target arc radius reduction amount and a speed feedforward gain in a servo control device having a control unit and a drive unit that inputs a torque command and rotates a servo motor A control loop gain calculation unit is provided.

According to the present invention , since the position control loop gain is obtained based on the mathematical expression, the servo adjustment of the trajectory tracking control in which the shape error becomes the target arc radius reduction amount is performed by adjusting the overshoot using the speed feed forward gain. You can easily do it. In addition, even when feedforward is used regardless of the command program and the moving speed, there is an effect that the shape error can be made the target arc radius reduction amount.

Hereinafter, specific examples of the present invention will be described with reference to FIG.

FIG. 1 is a control block diagram showing the configuration of the servo control device of the present invention. In the figure, reference numeral 20 denotes a position control unit which receives a position command and position feedback, multiplies a deviation value between the position command and position feedback by a position control loop gain 21, and outputs a speed command to the speed control unit 22. 22 is a speed controller for outputting a torque command receiving speed command, by differentiating the speed command from the position control unit 20, and a speed feedback value obtained by differentiating the differentiator 28 the position feedback, the position command A speed feed forward value multiplied by the speed feed forward gain 24 is input, a torque command is calculated and output to the drive unit 23. Drive unit 23 rotates the servo motor 26 enter a torque command. The configuration up to this point is the same as the conventional technology. In the present invention, a position control loop gain calculation unit 25 is added to this control block. The position control loop gain calculation unit 25 obtains a position control loop gain from the speed feedforward gain 24, a preset target arc radius reduction amount, a feed speed and an arc radius as the target values.

Here, an expression for calculating the position control loop will be described.
FIG. 2 shows a control block diagram when the speed control is PI control, and FIG. 3 shows a control block diagram when the speed control is IP control. When the speed control is PI control as shown in FIG. 2 , the transfer function from the position command to the position response is expressed by Equation ( 2 ).

Where, Kv: speed control loop gain [1 / s], Kp: position control loop gain [1 / s], _Vff : speed feedforward gain, Ti: speed control loop integration time constant [sec], s: Laplace calculation Child

Since the arc radius reduction amount ΔR is obtained by ΔR = (1− | G |) R, the equation ( 3 ) is obtained by obtaining | G | from the equation ( 2 ) and arranging it.

Where V: feed rate [mm / sec], R: arc radius [mm]

When equation ( 3 ) is solved for Kp, equation ( 4 ) is obtained.

When the speed control is the IP control as shown in FIG. 3 , the transfer function from the position command to the position response is expressed by Expression ( 5 ).

As in the case of PI control, when | G | is obtained from Expression ( 5 ) and substituted for ΔR = (1− | G |) R, the arc radius reduction amount ΔR becomes Expression ( 6 ).

When equation ( 6 ) is solved for Kp, equation ( 7 ) is obtained.

Therefore, the position loop gain that becomes the target arc radius reduction amount can be obtained by using the equations ( 4 ) and ( 7 ).

FIG. 4 is a flowchart showing the processing procedure of the method of the present invention. The details of the method of the present invention will be described below with reference to this figure.
In the present invention, when adjusting the servo in the machine setup or the like, if the overshoot is adjusted using the speed feed forward gain, the position control loop gain is automatically calculated from the target radius reduction amount.

First, it is determined whether or not the position control loop gain is to be obtained by automatic calculation using preset parameters (step 1). When automatically calculating the position control loop, the speed feedforward gain is adjusted while measuring overshoot (step 2). Next, it is determined whether the speed control is PI control or IP control (step 3). If the speed control is PI control, use Equation ( 4 ), and if IP control, use Equation ( 7 ). A position control loop gain is calculated from the set target arc radius reduction amount and speed feed forward gain (steps 4 and 5). Here, in order to determine the target arc radius reduction amount, the feed speed and the arc radius when realizing the target value are required. For example, the arc radius when circular interpolation is performed with a radius of 50 mm at a feed speed of 10000 mm / min. A value is set like a reduction amount, and a position control loop gain is calculated. The feed speed and the arc radius may be fixed values or may be set in advance by parameters. Then, step 2 to step 5 are repeated until the overshoot falls within the allowable value (step 6).

  In this way, in order to obtain the position control loop gain based on the mathematical expression, the servo adjustment of the trajectory tracking control in which the shape error becomes the target arc radius reduction amount adjusts the overshoot using the speed feedforward gain. Just can be done easily. In addition, the shape error can be made the target arc radius reduction amount even when the feed forward is used regardless of the command program and the moving speed.

Control block diagram showing the configuration of the servo control device of the present invention Control block diagram when speed control is PI control Control block diagram when speed control is IP control The flowchart which shows the process sequence of the method of this invention. Block diagram showing the configuration of a conventional numerical controller The flowchart which shows the process sequence of the conventional method

Explanation of symbols

20 Position control unit 21, 53, 63 Position control loop gain 22 Speed control unit 23 Servo motor drive unit 24, 52, 62 Speed feed forward gain 25 Position control loop gain calculation unit 26 Servo motor 27 Position detectors 28, 51, 61 Differentiator 29 Speed feedforward unit 31 Machining program analysis unit 32 Maximum moving speed calculation unit 33 Final command speed selection unit 34 Interpolation unit 54, 65 Speed control loop gain 55, 64 Speed loop integrators 56, 57, 66, 67 Integrator

Claims (6)

A position control unit that receives a position command and position feedback and outputs a speed command;
A speed control unit that receives a speed command, a speed feedback value, and a speed feed forward value and outputs a torque command;
In a servo control device having a drive unit that inputs a torque command and rotates a servo motor ,
Adjusting the speed feed forward gain while measuring overshoot;
Obtaining a position control loop gain of the position control unit by calculation from a target arc radius reduction amount and the speed feedforward gain ;
A method of adjusting a servo control device comprising: a step of adjusting the speed feedforward gain until the overshoot reaches an allowable value; and a step of obtaining a position control loop gain of the position control unit. . Wherein the position control loop gain K _P, when the speed control and PI control, a method of adjusting a servo control apparatus according to claim 1, characterized in that determined by Equation (1).

However, ΔR: arc radius reduction amount [mm], R: arc radius [mm], V: feed speed [mm / s], V _ff : speed feed forward gain, Kp: position control loop gain [1 / s] Wherein the position control loop gain K _P, when the IP controls the speed control adjustment method for a servo controller according to claim 1, wherein the determination by the equation (2).

Where ΔR: arc radius reduction amount [mm], R: arc radius [mm], V: feed speed [mm / s], V _ff : speed feed forward gain, Kp: position control loop gain [1 / s], Ti: Speed control loop integration time constant [sec] A position control unit that receives a position command and position feedback and outputs a speed command;
A speed control unit that receives a speed command, a speed feedback value, and a speed feed forward value and outputs a torque command;
In a servo control device having a drive unit that inputs a torque command and rotates a servo motor,
  A servo control device comprising: a position control loop gain calculation unit that calculates a position control loop gain of the position control unit by calculation from a target arc radius reduction amount and a speed feedforward gain.   The position control loop gain K _P 5. The servo control device according to claim 4, wherein when the speed control is PI control, the speed control is obtained by equation (3).

Where ΔR: arc radius reduction amount [mm], R: arc radius [mm], V: feed rate [mm / s], V _ff : Speed feed forward gain, Kp: Position control loop gain [1 / s]   The position control loop gain K _P 5. The servo control device according to claim 4, wherein when the speed control is set to IP control, the speed control is obtained by equation (4).

Where ΔR: arc radius reduction amount [mm], R: arc radius [mm], V: feed rate [mm / s], V _ff : Speed feed forward gain, Kp: Position control loop gain [1 / s], Ti: Speed control loop integration time constant [sec]