JP5429576B2 - Synchronous control device - Google Patents

Description

The present invention relates to a synchronous control device that drives a plurality of mechanically coupled motors in synchronization.

The first conventional synchronous control device includes a positional deviation which is a difference between a command from a host controller for a spindle motor and a detected value of the spindle motor fed back from a detector provided in the spindle motor, The position deviation of the feed motor is corrected based on the synchronization error that is the difference between the command from the host controller and the position deviation that is the difference between the detected values of the feed motor fed back from the detector provided in the feed motor. It is described that a correction data calculation means for calculating correction data to be calculated is provided, and the correction data is added to the position deviation of the feed motor to control the synchronization error close to zero (for example, refer to Patent Document 1).

The second conventional synchronous control device includes a position control unit that outputs a speed command at predetermined intervals based on a position deviation between a position command and a position feedback from the position detector, and a speed command and a speed detector. A control device that drives and controls a servo motor by a speed control unit that outputs a torque command at predetermined intervals based on speed feedback, and controls the two servo motors that drive the same controlled object synchronously. It describes that a synchronization correction processing unit is provided that reduces the force acting between two servo motors based on the force acting between the motors (see, for example, Patent Document 2).

The third prior art synchronous control device detects the current position of each of the master axis and the slave axis, and based on the detected position of the master axis, sets the theoretical position corresponding to the position of the master axis for each slave axis. It is described that, for each slave axis, the synchronization error between the calculated theoretical position and the detected actual position is calculated, and the gain of the slave axis is changed based on the calculated synchronization error. (For example, see Patent Document 3).

Japanese Patent Laying-Open No. 2007-04268 (page 5-7, FIG. 1) JP 2004-288164 A (page 5-11, FIG. 2) Japanese Patent Laying-Open No. 2003-131712 (page 3-6, FIG. 2)

The problem will be described using a synchronization mechanism driven by the first to third conventional synchronization control devices. FIG. 6 is a diagram showing a first synchronization mechanism (gantry structure) driven by the synchronization control device. The first synchronization mechanism (gantry structure) is a configuration used for a mounter for mounting a semiconductor component on a substrate, a bonding machine for soldering the semiconductor component to the substrate, an industrial machine such as a coating apparatus, a semiconductor or a liquid crystal manufacturing apparatus. .
The first to third conventional synchronous control devices, when driving such a first synchronous mechanism (gantry structure), are identical from the commander 14 to the servo amplifiers 15 and 16 having the same position control configuration. Are transmitted via the position information transmission path 126 to synchronously control the two axes (X1 axis, X2 axis).

However, in the first synchronization mechanism (gantry structure) in which the shafts are fastened by the mechanical coupling portion 9, as the rigidity of the mechanical coupling portion 9 increases, one shaft moves to the other shaft and from the other shaft. A torsional reaction force (hereinafter referred to as an ineffective reaction force) applied to one shaft increases.
This reactive reaction force is caused by variations in the production of the linear scale 12, an error in attachment to the mechanism, the assembly accuracy of the mechanism itself, and the like, and it affects both position control systems as a disturbance to the servo amplifiers 15 and 16. To give. That is, this reactive reaction force becomes a thrust having an opposite sign to the thrust command value of the servo amplifiers 15 and 16, and the servo amplifiers 15 and 16 need to further increase the thrust command value in order to cancel this invalid reaction force. As a result (due to an increase in the load factor), there was a problem that the energy efficiency was remarkably deteriorated. Further, when this reactive reaction force is large, there is a possibility that the upper limit value of the thrust that can be output by the servo amplifiers 15 and 16 may be exceeded, and when it exceeds, there is a problem that normal position control operation and synchronous control cannot be performed.

The first to third conventional synchronous control devices require a transmission line other than the position information transmission line between the servo amplifier shafts. That is, the first conventional synchronous control device requires a position deviation transmission line, and the second and third conventional synchronous control devices require a torque command transmission line between the servo amplifier shafts. Since these new transmission lines do not normally exist in general-purpose products of servo amplifiers, the first to third prior art synchronous control devices must be configured as dedicated products, and cost and maintainability are reduced. There were also problems such as delivery time.

Further, in N-axis synchronous control (N is the number of axes and N> 1 is a natural number), one detection position may be a master position and the remaining (N-1) -axis positions may be slave positions. For example, in FIG. 6, the detected position of the X1 axis is the master position, and the detected position of the X2 axis is the slave position. In the case of a synchronization mechanism (gantry structure) as shown in FIG. 6, there are Y axes orthogonal to the X1 and X2 axes, and a work position (work center) often exists on these XY axis coordinate systems. Since the Y-axis coordinate is a coordinate that moves between the X1 axis and the X2 axis, the work position does not necessarily exist on the master position (on the X1 axis), and synchronization control with respect to the work position cannot be performed. There was also.

The present invention has been made in view of such problems, and uses a general-purpose electrical product (motor, servo amplifier, commander, etc.) for a machine that drives coordinate axes in the same direction by a plurality of motors. A synchronous control device that suppresses the reactive reaction force applied between the axes and performs the synchronous control on the work position with high accuracy is provided.

In order to solve the above problems, the representative invention of the present application is configured as follows.
The synchronous control device fastens N motors (N> 1 natural number), N position detectors that respectively detect position information of the N motors, and movable parts of the N motors to each other. A synchronous control device for synchronously controlling the N motors with respect to a control target including a machine coupling unit, wherein N motor controls are provided corresponding to the N position detectors. A position control system in which each motor control device performs position / speed control on the one motor based on the position information related to the one motor from the corresponding one of the position detectors. In addition to the N motor control devices and the N position control systems respectively configured by the N motor control devices, all the N position information from the N position detectors is included. Based on position control Another position control system is configured to output a common drive position command to all the N motor control devices, and based on all the N position information from the N position detectors, the machine have a, a command device for calculating the axial coordinate system position of the work position is a work center in the command device, the difference between the working position command axis coordinate system position of the working position, the position proportional-integral or position A position control unit that performs integration control and outputs the common drive position command ;

According to the representative invention of the present application, a general-purpose electrical product (motor, servo amplifier, command unit, etc.) is used for each machine to drive the coordinate axes in the same direction with multiple motors. While suppressing the reaction force, the synchronous control with respect to the work position can be performed with high accuracy. That is, the thrusts (torques) of a plurality of motors to be synchronized can be made substantially the same, and only during a positioning operation or a position information transmission path (using general-purpose serial communication, etc.) for exchanging position data, Synchronous operation with less reactive reaction force after completion of positioning can be realized.
Further, the deviation due to the rigidity of the mechanical coupling portion and the influence of viscous friction can be reduced, and the work position information in the command device can be made to exactly match the position command at the time of completion of positioning.

The block diagram of the synchronous control apparatus which concerns on the 1st Embodiment of this invention The figure which shows the simulation waveform of the speed and torque in 1st Embodiment. The block diagram of the synchronous control apparatus which concerns on the 2nd Embodiment of this invention. The block diagram of the synchronous control apparatus which concerns on the 3rd Embodiment of this invention. The figure which shows the simulation waveform of the speed and torque in 2nd Embodiment. The figure which shows the 1st synchronizing mechanism (gantry structure) which a synchronous control apparatus drives The figure which shows the 2nd synchronization mechanism (other gantry structure) which a synchronous control apparatus drives The figure which shows the 3rd synchronizing mechanism (arc linear) which a synchronous control apparatus drives The block diagram of the speed control part (proportional + incomplete integral) in the synchronous control apparatus which concerns on the 4th Embodiment of this invention. Block diagram of a first conventional synchronous control device The figure which shows the simulation waveform of the speed and torque in the synchronous control apparatus of 1st prior art. Block diagram of second prior art synchronous control device The figure which shows the simulation waveform of the speed and torque in the synchronous control apparatus of the 2nd prior art Block diagram of third conventional synchronous control device The figure which shows the simulation waveform of the speed and torque in the synchronous control apparatus of the 3rd prior art The figure which represented typically the 1st synchronizing mechanism (gantry structure) in FIG. Circular interpolation operation waveform diagram at the time of normal gain setting in the fifth embodiment of the present invention Circular interpolation operation waveform diagram at the time of gain setting according to the fifth embodiment of the present invention Circular interpolation operation waveform diagram at the time of normal gain setting in the sixth embodiment of the present invention Circular interpolation operation waveform diagram at the time of gain setting according to the sixth embodiment of the present invention Circular interpolation operation waveform diagram at the time of gain setting according to the fifth embodiment of the present invention when the delay is large Circular interpolation operation waveform diagram at the time of gain setting according to the seventh embodiment of the present invention The block diagram of the synchronous control apparatus which concerns on the 7th Embodiment of this invention Control block diagram of the position observer according to the seventh embodiment of the present invention Another control block diagram of the position observer according to the seventh embodiment of the present invention

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

First, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram of a synchronous control device according to the first embodiment of the present invention. In the figure, the synchronous control device 1 includes a command device 2 and servo amplifiers 3 and 4.
The command device 2 includes a position command generation unit 21, a position control unit 22, and a position information calculation unit 23. The position command generation unit 21 generates an internal position command 121 for driving the motors 5 and 6. Output to the position controller 22. The position information calculation unit 23 inputs the detected position information 131 and 141 detected by the encoders 7 and 8 from the servo amplifiers 3 and 4 through the position information transmission path 126, and outputs the work position information 122 by calculation described later. To do. The position control unit 22 inputs a deviation between the internal position command 121 and the work position information 122 to perform proportional integral control calculation, and outputs a new position command signal 125 to the servo amplifiers 3 and 4 via the position information transmission path 126. To do. The position information transmission path 126 may be a high-speed serial communication path, for example, and can communicate position information bidirectionally in synchronization with the servo amplifiers 3 and 4.
The work position information 122 is, for example, on the XY axis coordinate system when the mechanism system driven by the synchronous control device 1 is an XY axis coordinate system and the internal position command 121 is a position command in the XY axis coordinate system. Is the coordinates of the work position (work center) existing in.

The servo amplifier 3 includes a position control unit 31, a speed control unit 32, a speed calculation unit 33, and a current control unit 34. The servo amplifier 4 also has the same configuration (position control unit 41, speed control unit 42, speed calculation). Part 43 and current control part 44).
The position controllers 31 and 41 input a deviation between the new position command signal 125 and the detected position information 131 and 141, perform proportional control calculation, and output a speed command. The speed calculation units 33 and 34 receive the detected position information 131 and 141, perform differential calculation, and output a speed feedback signal. The speed control units 32 and 42 input a deviation between the speed command and the speed feedback signal, perform proportional control calculation, and output a command for driving the motor. Since electric power is supplied to the motor by applying a voltage to the motor winding and flowing a current, the command for driving the motor is a voltage or current command. Usually, current command is often used. That is, the current control units 34 and 44 control and calculate a current corresponding to the current command and supply it to the motors 5 and 6. The motor generates a force proportional to the supplied current. For example, torque is generated for a synchronous rotary motor, and thrust is generated for a linear motor.

Note that the configurations of the motors 5 and 6, the encoders 7 and 8, and the mechanical coupling unit 9 simply represent the configuration of the first synchronization mechanism (gantry structure) described in FIG. 6. Disturbance torque (reaction force) 191 means an invalid reaction force, and this invalid reaction force corresponds to a negative thrust for the servo amplifier 3, for example, and a positive thrust for the servo amplifier 4. It will be. Further, the command device 14 and the servo amplifiers 15 and 16 in FIG. 6 correspond to the command device 2 and the servo amplifiers 3 and 4 in FIG.
As described above, the synchronous control device according to the first embodiment of the present invention includes the command device 2 and another position control system separately from the position control system configured in the servo amplifiers 3 and 4. Since the position control unit 22 in the command device 2 includes an integral operation, the work position information 122 can follow or position the internal position command 121 output from the position command generation unit 21 without any positional deviation.
The position control 22 can perform the same operation only by integral control.

Next, a method in which the position information calculation unit 23 calculates the work position information 122 from the detected position information 131 and 141 will be described.
The position information calculation unit 23 calculates the X coordinate of the work position information 122 using Expression (1). Note that m is 0 ≦ m ≦ 1, and is determined from a work position arbitrarily designated in advance (a method for calculating m is as described later).
(X coordinate of the work position information 122)
= M × (detection position information 131) + (1−m) × (detection position information 141) (1)

In the configuration of the first synchronization mechanism (gantry structure) shown in FIG. 6 (similar to FIG. 1) and the work position is at an arbitrary position between the X1 axis and the X2 axis, The work position information 122 at an arbitrary position between the position of the X1 axis (detected position information 131) and the position of the X2 axis (detected position information 141) can be calculated as an X coordinate. It is possible to follow or position the position command.
For example, if m in Equation (1) is 0.5, the center position between the X1 axis and the X2 axis can be calculated as the X coordinate of the work position information 122.
Thus, when the distance between the axes of the X1 axis and the X2 axis is L, the work position information in the X axis direction of mL can be calculated.

Further, in the case of the configuration of the first synchronization mechanism (gantry structure) shown in FIG. 6 (similar to FIG. 1), the Y axis orthogonal to the X1 axis and the X2 axis is configured, and the coordinates of the X1, X2, and Y axes There are many industrial machines, semiconductors, or liquid crystal manufacturing apparatuses in which work such as processing of objects is performed at the position determined by the above, that is, the work position.
Similarly to the X1 axis and the X2 axis, the Y axis includes another servo amplifier (for the Y axis) to form a position control system, and is based on another position command (for the Y axis) from the commander 2. The other motor (for the Y axis) is configured to be driven. In this case, as will be described later, the value of m can be calculated based on the coordinates of the Y axis orthogonal to the coordinates of the X1 axis and the X2 axis. That is, the position of the Y axis becomes the Y coordinate of the work position information 122, and the position calculated by the expression (1) using m becomes the X coordinate of the work position information 122.

Hereinafter, the calculation formula of m will be described.
FIG. 16 is a diagram schematically showing the first synchronization mechanism (gantry structure) in FIG. In the figure, both the X1 axis and the X2 axis are the positions of the linear scale, and the linear scale head is located at the detection positions 131 and 141. The Y axis is the stroke Ly. The offset distance from the Y-axis stroke end to the X1-axis encoder head is dY1, and the offset distance from the Y-axis origin (0 position) to the X2-axis is dY2.
The origin (0 position) of the Y axis is taken as the origin (0 position) of the Y coordinate (work coordinate), and the origin (0 position) of the X1 axis and X2 axis is taken as the origin (0 position) of the X coordinate (work coordinate). Let the position be (Px, Py).
In this case, m can be calculated by equation (2).
m = (Py + dY2) / (dY1 + Ly + dY2) (2)
In FIG. 16, although the Y-axis inclination is exaggerated, the difference between the detection position 131 and the detection position 141 is about several tens of μm with respect to the Y-axis stroke of about 1 m in an actual machine. The slope of is a negligible amount. Even if it is considered that the Y-axis direction is almost parallel to the Y-coordinate (working coordinate), there is no problem in calculation. Can be calculated.

Thus, the work position information in the X-axis direction can be calculated from the position of the Y-axis. In addition, when the working head 13 that moves the Y axis is attached to the mechanical coupling portion 9 shown in FIG. 6, if the mechanical coupling portion 9 between the X1 axis and the X2 axis is distorted, Depending on the position, there is a problem that the X coordinate position of the working head 13 causes a mechanical error with respect to the position command. The position of the head 13 in the X-axis direction can be positioned according to the position command.

FIG. 2 is a diagram illustrating simulation waveforms of speed and torque in the first embodiment. In the figure, this is a case where the work position information 122 = detected position information 131 in FIG. 1, wherein the upper stage is a speed waveform, the lower stage is a torque waveform, the vertical axis is each amplitude, and the horizontal axis is a time axis.
In this case, the thrust corresponding to the reactive reaction force when stopped after the positioning operation (after time axis 16) is about 0.05 [pp], and the maximum thrust during acceleration / deceleration (time axes 0 to 3). It is about 10% of the amplitude (about 0.5).

Here, the reactive reaction force in the first to third conventional synchronous control devices will be described.
FIG. 10 is a block diagram of the first prior art synchronization control device, FIG. 12 is a block diagram of the second prior art synchronization control device, and FIG. 14 is a block diagram of the third prior art synchronization control device. FIG. 11 is a diagram showing simulation waveforms of speed and torque in the first conventional synchronous control device, FIG. 13 is a diagram showing simulation waveforms of speed and torque in the second conventional synchronous control device, and FIG. These are figures which show the simulation waveform of the speed and torque in the synchronous control apparatus of the 3rd prior art. 11, 13, and 15, the simulation conditions are the same as those in FIG. 2, the upper stage is the speed waveform, the lower stage is the torque waveform, the vertical axis is the amplitude, and the horizontal axis is the time axis.

The thrust corresponding to the reactive reaction force at the time of stopping after each positioning operation (after time axis 16) is about 0.1 [pp] (FIG. 11) by the first prior art synchronous control device. The conventional synchronous control device of the present invention is about 0.15 [pp] (FIG. 13), and the third prior art synchronous control device is about 0.3 [pp] (FIG. 15). These correspond to about 20%, about 30%, and about 60% of the maximum thrust amplitude (about 0.5) during acceleration / deceleration (time axis 0 to 3).

As described above, in the first to third conventional synchronous control devices, each servo amplifier tries to make the detected position follow the position command completely with respect to the same position command. Due to errors and machine errors (deviation between axes), an invalid reaction force is generated in each servo amplifier, especially after positioning stops. Although the misalignment between the axes is detected by a position deviation, a torque command, or the like and correction processing is performed between the axes, the reactive reaction force has not been reduced as compared with the embodiment of the present invention.

The synchronous control device according to the embodiment of the present invention (the first embodiment and the second, third and fourth embodiments described later) is N-axis synchronous control (N is the number of axes and N> 1 is a natural number). The encoder position for the number of axes and the mechanical position in the actual synchronization mechanism do not exactly match, the reactive reaction force is generated due to the rigidity of the coupling members that fasten the movable shafts of the motor for the number of axes, the number of axes The focus is on the fact that the displacement of the encoder position between the axes of the minute and the reactive reaction force conflict.
That is, the synchronous control device according to the embodiment of the present invention (the first embodiment and the second, third, and fourth embodiments described later) performs N-axis synchronous control (N is the number of axes and N> 1 is a natural number). ), The detection position to be matched with the position command is limited to one, not a plurality, and a position control system with a position control system for each servo amplifier and using one detection position for the position command is required. It is based on what is.

A typical invention of the present application is a configuration in which a work position is calculated from a plurality of encoder positions and the work position follows a position command in N-axis synchronous control (N is the number of axes and N> 1 is a natural number), Configuration that eliminates the integral calculation in each servo amplifier (The gain increases with the movement of the integral calculation at a lower frequency, so the reactive reaction force increases at the stop of positioning completion. In this configuration, one position control system is newly added to the outside of the servo amplifier, and an integral operation is provided only in this position control system.
As described above, the representative invention of the present application considers the accuracy of the machine to be controlled comprehensively and essentially.

The detected position information corresponds to the position information described in each claim, the internal position command corresponds to the position command, the work position information corresponds to the work position, the command device corresponds to the command device, and the servo amplifier corresponds to the motor control device.

Hereinafter, application examples of the synchronization control device according to the embodiment of the present invention will be sequentially described with respect to various synchronization mechanisms.
Next, a second embodiment of the present invention will be described with reference to the drawings.
FIG. 7 is a diagram showing a second synchronization mechanism (another gantry structure) driven by the synchronization control device. In the figure, a position measuring device using a laser interferometer 101 is attached in order to accurately measure the position in the X direction near the work position.
The laser interferometer 101 installs a reflection mirror on the mechanical coupling unit 9 and measures the position in a non-contact manner by the interference of the laser beam from the laser interferometer. For this reason, the work position of the mechanical coupling part 9 can be directly measured in the X-axis direction at a place where the linear scale 12 cannot be installed.

FIG. 3 is a block diagram of a synchronous control device according to the second embodiment of the present invention. In the figure, the synchronous control device 10 includes a command device 2 and servo amplifiers 3, 4, and 17.
The second embodiment is different from the first embodiment in that the synchronization control device 10 inputs the detected position information of the laser interferometer 101 to the servo amplifier 17 and detects the detected position information 171 via the position information transmission path 126. The position information calculation unit 23 uses the detection position information 171 of only the laser interferometer 101 and the detection position information 131 and the detection position from the servo amplifiers 3 and 4. The information 141 is not used. Therefore, the synchronous control device 10 uses the servo amplifier 17 as a data converter that transmits only the detected position information 171 of the laser interferometer 101 to the position information transmission path 126 without connecting a motor to the servo amplifier 17. . With this configuration, it can be configured with only general-purpose products.
If the detection resolution of the encoder (linear scale) 7 and the encoder 8 (length per pulse: eg 0.1 μm / 1 pulse) differs from the detection position resolution of the laser interferometer 101, the position information calculation unit It is only necessary to perform electronic gear calculation within 23 and match the resolution.

In the second embodiment, since the position in the vicinity of the work position is detected by the laser interferometer 101 and fed back to the position control system in the commander 2 as work position information 122 in the commander 2, work in the X direction is performed. The position can be made to follow the command position more accurately than in the first embodiment.

The laser interferometer corresponds to the position measuring device described in each claim.

Next, a third embodiment of the present invention will be described with reference to the drawings.
FIG. 8 is a diagram showing a third synchronization mechanism (circular linear) driven by the synchronization control device. FIG. 4 is a block diagram of a synchronous control device according to the third embodiment of the present invention. In FIG. 4, the synchronous control device 11 includes a command device 2 and servo amplifiers 3, 4, and 17. Since the control configuration of the servo amplifiers 4 and 17 is the same as that of the servo amplifier 3, detailed description thereof is omitted.
The synchronous control device according to the third embodiment of the present invention supplies electric power to the arc-shaped linear motors 5, 6, and 18 in FIG. 8 to provide a plurality of linear motor movable elements (for example, linear motor movable elements 53). Synchronous control is performed. A linear scale position reading head is attached to each linear motor mover. By using a tape-type linear scale, the scale can be attached in an arc shape, and one linear scale can be positioned with three heads. A linear scale may be attached to each detection or each head.
The third embodiment is different from the first embodiment in that the synchronization control device 11 synchronously controls a synchronization mechanism (for example, FIG. 8) configured with three axes. In addition, since the effect which the component which attached | subjected the code | symbol same as FIG. 1 which is a typical figure of 1st Embodiment has the same effect, it abbreviate | omits detailed description.

The configuration of the motors 5, 6, 18, encoders 7, 8, 19 and mechanical coupling units 9, 105, 106 in FIG. 4 simply represents the configuration of the third synchronization mechanism (circular linear) described in FIG. 8. Is. The turntable (9, 105, 106) in FIG. 8 is mechanically coupled in FIG. 4 because the motors 5, 6, 18 are mechanically coupled via the turntable (9, 105, 106). Parts 9, 105, and 106. Further, since each shaft is mechanically coupled by the mechanical coupling portions 9, 105, 106 as in the first embodiment, an invalid reaction force (disturbance torque 191) is applied to each shaft.
The position information calculation unit 23 in the command device 2 calculates work position information 122 based on the detected position information 131, 141, 171 from the servo amplifiers 3, 4, 17. For example, the biaxial calculation method using the equation (1) described in the first embodiment may be expanded to three axes (see equations (3) and (4)).

Further, in FIG. 8, there may be an N-cycle error (N is a natural number) in one rotation due to a linear scale attachment error. For example, in FIG. 8, a linear scale is attached to a thin cylindrical member, but in the case of a large arc-shaped turntable having a diameter of about 2 m, the cylindrical member may be damaged due to machining errors or attachment. May cause distortion in the diameter direction. In this case, an N-cycle error occurs (N is a natural number) in one turn of the turntable, which is a mechanical coupling unit. This error becomes an error of N cycles because it returns to the original when the turntable rotates once.

For example, when three linear scale heads are attached to one linear scale to detect the position, the true value of the detected position information X1 detected from the linear scale via the servo amplifier 3 is θ [rad], which corresponds to an error. Assuming that a minute value is δ and an error of one cycle appears in the linear scale, X1 = θ + δsin (θ).
Further, if linear scale heads are arranged on the circumference of the linear scale every 120 degrees (2π / 3), the detected position information X2 of the servo amplifier 4 and the detected position information X3 of the servo amplifier 17 are X2 = θ + δsin ( θ−2π / 3) and X3 = θ + δsin (θ−4π / 3). Here, the three linear scale heads are misaligned by 120 degrees, but if the origin position is made common to the three motors, the true value θ can be made the same, so that there is an error of one cycle. Depends on the physical position, and is a value shifted by 120 degrees and 240 degrees from θ.

The position information calculation unit 23 in the synchronous control device according to the third embodiment of the present invention averages the work position information 122 using Expression (3).
(Working position information 122)
= ((Detection position information 131) + (Detection position information 141) + (Detection position information 171)) / 3 (3)
Moreover, Formula (3) is represented by Formula (4).
(Working position information 122)
= Θ + δ (sin (θ) + sin (θ−2π / 3) + sin (θ−4π / 3)) (4)
Here, since sin (θ) + sin (θ−2π / 3) + sin (θ−4π / 3) = 0, (work position information 122) = θ, and the work position information 122 is a true value without error. Desired.
When the number of arc-shaped linear motors is m, a linear scale head may be arranged every 360 / m degrees = 2π / m, and the position information calculation unit 23 may perform m averaging calculations.

As described above, the synchronous control device according to the third embodiment of the present invention is provided with another position control system in the command unit 2 separately from the position control system configured in the servo amplifiers 3, 4, and 17. is there. Since the position control unit 22 in the command device 2 includes an integral operation, the work position information 122 can follow or position the internal position command 121 output from the position command generation unit 21 without any positional deviation. In addition, the averaging calculation of the position information calculation unit 23 can reduce an error of N cycles (N is a natural number) in one rotation generated due to a mounting error of the linear scale.

FIG. 5 is a diagram showing simulation waveforms of speed and torque in the third embodiment. In the figure, the upper stage is a speed waveform, the lower stage is a torque waveform, the vertical axis is each amplitude, and the horizontal axis is a time axis. In this case, the thrust corresponding to the reactive reaction force when stopped after the positioning operation (after time axis 16) is about 0.1 [pp], and the maximum thrust during acceleration / deceleration (time axis 0 to 3). It is about 20% of the amplitude (about 0.5). It can be seen that the reactive reaction force is small even in the case of three axes.

Thus, according to the third embodiment, the number of axes to be synchronously controlled can be easily increased, and the reactive reaction force of each axis can be reduced. In the first to third conventional synchronous control devices, as the number of axes to be synchronously controlled increases, the control configuration between the axes becomes complicated, and the adjustment of the control gain and the like becomes complicated. On the other hand, according to the third embodiment, when configuring a synchronous control system for the N-axis (N is a natural number of N> 1), servo amplifiers (for example, general-purpose servo amplifiers) of the same control system for the N-axis are used. Just prepare.

The synchronous control device according to the third embodiment of the present invention that synchronously controls the N-axis (in the case of two axes, the synchronous control device according to the first embodiment of the present invention) is, for example, a press machine or an injection molding machine. It can be applied to other industrial machines.
In the case of an industrial machine such as a press machine or an injection molding machine with a mechanism in which two motors and one drive gear are coupled, if this coupling is a rigid body, only the motor on one shaft is controlled. Even if the other motor is rotated, the encoder rotation angles of both motors coincide with each other. Therefore, the synchronous control device according to the first or third embodiment of the present invention can be applied.
On the other hand, when the rigidity of the coupling is low, the rotation angle of the drive gear does not necessarily match the rotation angle of the two-axis motor, so the position information calculation unit in the command unit performs the calculation of Expression (5).
Drive gear rotation angle = 1st axis motor rotation angle + (torsion moment ÷ torsional rigidity x 1st axis encoder to drive gear) (5)
If the rotation angle of the drive gear is used as the work position information in this way, the rotation angle of the drive gear can be made to follow the command position. Therefore, the synchronous control device according to the first or third embodiment of the present invention is applied. it can.
The torsional moment is given by the torque of the first axis motor, and the torsional rigidity is given by the material and shape of the coupling. The distance from the first axis encoder to the drive gear is geometrically determined when the motor is assembled to the machine.

Further, the synchronous control device according to the third embodiment of the present invention for synchronously controlling the N-axis (in the case of two axes, the synchronous control device according to the first embodiment of the present invention) includes, for example, a wire saw delivery shaft and a wire saw Synchronous control of the take-up shaft (Measure the feed amount from the reference position of the wire saw with an external sensor, and use this measured value as the feedback position to the commander), Synchronous control of the film feed shaft and the film take-up shaft (film The present invention is also applicable to a method in which the amount of feed from the reference position is measured by an external sensor, and this measured value is used as a feedback position to the command device.

Next, a fourth embodiment of the present invention will be described with reference to the drawings.
In the synchronous control device according to the first embodiment of the present invention, since the speed control units 32 and 42 in the servo amplifiers 3 and 4 are only in proportional control, the detected position information 131 and 132 of the servo amplifiers 3 and 4 are positioned. There may be a difference from the new position command 125 at the time of completion.
In the first embodiment of the present invention, for the purpose of positioning the work position information 122, that is, to make the internal position command 121 and the work position information 122 coincide with each other, the detected position information 131, 132 of the servo amplifiers 3, 4 There is no problem with the difference from the new position command 125 when the positioning is completed. However, this difference becomes large when the rigidity of the mechanical coupling portion 9 is low or when the viscous friction is large. In this case, this difference can be reduced by changing the control system of the speed control units 32 and 42 in the servo amplifiers 3 and 4 to incomplete integration.

FIG. 9 is a block diagram of the speed control unit (proportional + incomplete integration) in the synchronous control device according to the fourth embodiment of the present invention. The synchronous control device according to the fourth embodiment of the present invention includes the speed control units 32 and 42 in the servo amplifiers 3 and 4 in the synchronous control device according to the first embodiment of the present invention. It replaces the part.
In the case of incomplete integration, increasing the incomplete integration rate approaches proportional control, and decreasing it approaches the integration control. For this reason, when the mechanical rigidity is low, the reactive reaction component in the motor torque and thrust is small. Therefore, the incomplete integration rate should be adjusted within the allowable range. (The reaction force decreases, but the reactive reaction force increases. Increasing the incomplete integration rate reverses the operation.)

Furthermore, the synchronous control device according to the first to third embodiments of the present invention has the above-described configuration, so that the N-axis synchronous control (N is the number of axes and N> 1 is a natural number) during acceleration / deceleration. The torque (thrust) of each axis in can be balanced. 2 and 5 (speed and torque simulation waveforms in the first and third embodiments) and FIGS. 10, 12, and 14 (speed and torque simulations in the first to third conventional synchronous control devices). Comparing with (waveform).
Moreover, the synchronous control apparatus which concerns on the 1st thru | or 3rd embodiment of this invention can make an actual working position of a machine follow a position command by setting it as the structure mentioned above.

In addition, although the synchronous control device according to the first to fourth embodiments of the present invention has exemplified the configuration having the position control system in each of the command device and the servo amplifier, it is a device in which the command device and the servo amplifier are integrated. Even if it exists, there exists the same effect.
Moreover, it is an apparatus which inputs the position command from the outside, Comprising: The apparatus which has the same two position control systems may be sufficient.

Next, a fifth embodiment of the present invention will be described with reference to the drawings.
In a machine tool or the like equipped with a gantry mechanism as shown in FIG. 6, not only a single positioning operation in the X and Y directions but also a trajectory can be controlled by circular interpolation between the X and Y axes. For example, circular interpolation can be performed by setting the X axis to a sine waveform and the Y axis to a cosine waveform.
In many cases, the control system of the synchronous control device for machine tool applications is a position proportional / speed integral proportional control system. Here, since the Y-axis in FIG. 6 is single-axis drive, this control system (position proportional / velocity integral proportional control) is used, and the X-axis is twin drive, so that it is the same as in the first embodiment of the present invention. The synchronization control device shown in the block diagram of FIG. 1 may be applied. However, in order to balance the control system, the position control unit 22 in FIG. 1 on the twin drive X-axis inputs the deviation between the internal position command 121 and the work position information 122 and performs integral control calculation to obtain a new position. By adopting a configuration in which the command signal 125 is output to the servo amplifiers 3 and 4 via the position information transmission path 126, a position integral proportional / velocity proportional control system is obtained.

FIG. 17 is a circular interpolation operation waveform diagram at the time of normal gain setting according to the fifth embodiment of the present invention, and FIG. 18 is a circular interpolation operation waveform diagram at the time of gain setting according to the fifth embodiment of the present invention. In the figure, the position command and the detected position information are plotted when the position command of the sin function is input in the X-axis direction and the position command of the cos function is input in the Y-axis direction. The vertical axis is the Y axis, the solid line is the detected position information, and the alternate long and short dash line is the position command.
When performing circular interpolation operation, if the corresponding gain settings of the X-axis and Y-axis control systems are made the same as usual, there is a problem that the trajectory is distorted and becomes an ellipse that is long in the X-axis direction as shown in FIG. . That is, the detected position information does not follow the position command.

In order to solve this problem, it is necessary to derive a gain setting equation.
For the twin drive X-axis, the transfer function from the position command of the position integral proportional / velocity proportional control system to the detected position information is expressed by the following equation (6).

On the other hand, the transfer function from the position command of the position proportional / velocity integral proportional control system to the detected position information on the Y axis of the single axis drive is expressed by Expression (7).

If the equations (6) and (7) coincide with each other, the detected position information coincides with the position command in the circular interpolation operation. In particular, since the response characteristic of the transfer function is determined by a denominator of the transfer function called a characteristic polynomial, if the gain setting value is determined so that the coefficients in the denominators of Expression (6) and Expression (7) match. It is only necessary to satisfy the expressions (8) and (9).
Kp1Kv = Kv / Ti (8)
Kp1Kv / Tir = KpKv / Ti (9)

That is, from equation (8), Kp1 = 1 / Ti (10)
And substituting equation (10) into equation (9),
Tir = 1 / Kp (11)
It is. At this time, the numerators of the formulas (6) and (7) also coincide.

In this way, when the gain setting values obtained from the equations (10) and (11) are used, as shown in FIG. 18, the distortion of the trajectory shown in FIG. You can see that it is following.

Next, a sixth embodiment of the present invention will be described with reference to the drawings.
In the fifth embodiment, the position control unit 22 in FIG. 1 is a position integral proportional / velocity proportional control system in the X axis of twin drive, but the same effect can be obtained even in a position proportional integral / velocity proportional control system. It is possible. In that case, it is necessary to use a gain setting expression different from Expression (10) and Expression (11).

The transfer function from the position command of the position proportional integration / speed proportional control system to the detected position information on the X axis of twin drive is expressed by Expression (12).

On the other hand, the transfer function from the position command of the position proportional / velocity proportional integral control system to the detected position information on the Y axis of the single axis drive is expressed by Expression (13).

If the expressions (12) and (13) match, the detected position information matches the position command in the circular interpolation operation. In particular, since the response characteristic of the transfer function is determined by a denominator of a transfer function called a characteristic polynomial, if the gain setting value is determined so that the coefficients in the denominators of Expression (12) and Expression (13) match. It is sufficient that the expressions (14) and (15) are satisfied.
2Kp1Kv = Kv / Ti + KpKv (14)
Kp1Kv / Tir = KpKv / Ti (15)

That is, from the equation (14), Kp1 = 1 / (2Ti) + Kp / 2 (16)
Substituting equation (16) into equation (15),
Tir = 1 / (2Kp) + Ti / 2 (17)
It is.

However, unlike the fifth embodiment, the numerators of the formula (12) and the formula (13) do not match only by satisfying the formula (16) and the formula (17), and the X and Y axes are slightly. The detected position information for the position command does not match. In order to match the transfer function including the numerator, it is necessary to satisfy the following equation (18) in addition to the equations (16) and (17).
Ti = 1 / Kp (18)

19 is a circular interpolation operation waveform diagram at the time of normal gain setting according to the sixth embodiment of the present invention, and FIG. 20 is a circular interpolation operation waveform diagram at the time of gain setting according to the sixth embodiment of the present invention. In the figure, the position command and the detected position information are plotted when the position command of the sin function is input in the X-axis direction and the position command of the cos function is input in the Y-axis direction. The vertical axis is the Y axis, the solid line is the detected position information, and the alternate long and short dash line is the position command.
In this way, when the gain setting values obtained from the equations (10) and (11) are used, as shown in FIG. 18, the distortion of the trajectory shown in FIG. You can see that it is following.
In this way, when the gain setting values obtained from the equations (16) to (18) are used, the distortion of the locus shown in FIG. 19 (the ellipse long in the X-axis direction) shown in FIG. It can be seen that the detected position information follows the command.

Next, a seventh embodiment of the present invention will be described with reference to the drawings.
When the detection delays of the detected position information 131 and 141 with respect to the new position command 125 in FIG. 1 are as small as several ms, as shown in FIG. 18 of the fifth embodiment, from the expressions (10) and (11) If the gain setting value obtained is used, the distortion of the locus shown in FIG. 17 is improved and the detected position information follows the position command.

However, when the detection delay of the detected position information 131 and 141 with respect to the new position command 125 in FIG. 1 is as large as about several tens of ms, the detected position information is greatly distorted. In the case of the position proportional / velocity integral proportional control system in the Y-axis of the single-axis drive of the fifth embodiment, the detection delay of this detected position information enters only the position command, whereas the position integral in the X-axis of twin drive In the case of the proportional / velocity proportional control system, the position command 125 and the detected position information 131 and 141 are entered, so that the detection delay of the detected position information becomes large, and the error of the transfer function in the control loop becomes remarkable. This is because

FIG. 21 is a waveform diagram of circular interpolation operation when gain is set according to the fifth embodiment of the present invention when the delay is large, and FIG. 22 is a waveform diagram of circular interpolation operation according to the seventh embodiment of the present invention. .
FIG. 23 is a block diagram of a synchronous control device according to a seventh embodiment of the present invention, FIG. 24 is a control block diagram of a position observer according to the seventh embodiment of the present invention, and FIG. 25 is a seventh block diagram of the present invention. It is another control block diagram of the position observer according to the embodiment.
23 differs from the synchronous control device 1 in FIG. 1 in that the twin-drive X-axis servo amplifiers 3 and 4 are further single-axis drive Y-axis servo amplifiers 200 and motors. 211, the part to which the configuration of the encoder 212 is added, and the part to which the configuration of the position observer 24 in the command device 2 is added. In addition, since the effect which the component which attached | subjected the code | symbol same as FIG. 1 is the same, detailed description is abbreviate | omitted.

The problem that the detection delay of the detection position information becomes large can be avoided by inputting the position deviation 124 and the work position information 122, and creating the position observer 24 that outputs the new detection position information 123 that compensates for the delay, The position observer 24 can be configured as shown in FIGS. 24 and 25, for example. FIG. 22 shows a circular interpolation operation waveform diagram in this case. As in the fifth embodiment, the locus distortion shown in FIG. 21 is improved and the detected position information follows the position command. Recognize.

It should be noted that the position observer 24 exhibits the same effect even in the sixth embodiment.
In the fifth to seventh embodiments, the machine tool is described as having a gantry mechanism in which the X axis is twin-driven. However, the X axis has three or more axes as in a very large machine having a wide movable table. The same effects can be achieved with the multi-axis drive.
In particular, the position observer 24 in the seventh embodiment inputs the work position information 122 and the position deviation 124 obtained by calculating the detected position information of a plurality of axes by the position information calculation unit 23 to the position observer 24 and inputs the work position information 122. As a result, the design change is unnecessary even if the twin axis is changed to multiple axes. Furthermore, the same effects can be obtained when feedback is performed using the laser interferometer shown in the second embodiment (FIG. 3) of the present invention.

10, 11, 12 Synchronous control device 2, 14 Command device 21 Position command generation unit 22 Position control unit 23 Position information calculation unit 24 Position observer 3, 4, 15, 16, 17, 200 Servo amplifiers 31, 41, 201 Position Control unit 32, 42, 202 Speed control unit 33, 43, 203 Speed calculation unit 34, 44, 204 Current control unit 5, 6, 18, 211 Motor 7, 8, 19, 212 Encoder 9, 105, 106 Mechanical coupling unit 121 Internal position command 122 Work position information 123 New work position information 124 Position deviation 125 New position command 126 Position information transmission path 131, 141, 171, 251 Detected position information 191 Disturbance torque (reaction force)
10, 11 Guide 12 Linear scale 13 Head 51, 52 Motor stator (magnet)
53, 54 Motor movable element 101 Laser interferometer 102 Serial converter 103 SIN / COS signal 104 Serial communication

Claims (5)

N motors (natural number of N> 1), N position detectors that respectively detect position information of the N motors, and a mechanical coupling unit that fastens movable parts of the N motors to each other. A synchronous control device that synchronously controls the N motors with respect to a control target having a machine,
N motor control devices provided corresponding to the N position detectors, wherein each motor control device is based on the position information relating to one motor from one corresponding position detector. The N motor control devices, each constituting one position control system for performing position / speed control for the one motor;
In addition to the N position control systems by the N motor control devices, a single position control system that performs position control based on all the N position information from the N position detectors is configured. A common drive position command is output to all of the N motor control devices, and an axis of a work position which is a work center in the machine based on all of the N position information from the N position detectors. A command device for calculating a coordinate system position;
I have a,
The command device is:
A synchronization unit comprising: a position control unit that outputs a common drive position command by performing position proportional integration or position integration control on a difference between an axial coordinate system position of the work position and a work position command. Control device. When the control object has the machine that is a gantry mechanism,
The command device is
When the distance between the axes of the two motors with N = 2 is 1, the position information from one of the two position detectors at a certain ratio m within the range of the distance between the axes. And a value obtained by multiplying the remaining ratio (1-m) by the position information from the other position detector of the two position detectors, and adding the first ratio at the working position. A position information calculation unit that calculates the position of the axis coordinate system of
The position controller is
The difference between the working position command to the first axis coordinate system position, it outputs the common driving position command position proportional integral or position integral control to
Synchronous control device according to claim 1, wherein the this. When the control object has the machine that is a circular orbit mechanism,
The command device is
A position information calculation unit that calculates the second axis coordinate system position at the work position by averaging the position information from all N position detectors ;
The position controller is
The difference between the working position command and a second-axis coordinate system position, it outputs the common driving position command position proportional integral or position integral control to
Synchronous control device according to claim 1, wherein the this. A position measuring device for measuring a position near the work position;
A single other motor control device that has the same configuration as the N motor control devices and that inputs the third axis coordinate system position and outputs it to the command device;
Further comprising
The command device is
A position information calculation unit that calculates a third axis coordinate system position at the work position;
The position controller is
The difference between the working position command and the three-axis coordinate system position of, it outputs the common driving position command position proportional integral or position integral control to
Synchronous control device according to claim 1, wherein the this. The N motor control devices are
A speed calculator that calculates speed information of the motor corresponding to each based on the position information from the position detector corresponding to each;
A position controller that proportionally controls the difference between the common drive position command and the position information to calculate a speed command;
A speed control unit that proportionally controls the difference between the speed command and the speed information;
Synchronous control device according to any one of claims 1 to 4, characterized in that it has a.