Source: https://patents.google.com/patent/JP6068554B2/en
Timestamp: 2020-08-09 13:01:43
Document Index: 698076951

Matched Legal Cases: ['art 9', 'art 1', 'art 2', 'art 4', 'art 5', 'art 6', 'art 7', 'art 8', 'art 9', 'art 10', 'art 11']

JP6068554B2 - Servo control device with function to stop control without sensor - Google Patents
Servo control device with function to stop control without sensor Download PDF
JP6068554B2
JP6068554B2 JP2015096916A JP2015096916A JP6068554B2 JP 6068554 B2 JP6068554 B2 JP 6068554B2 JP 2015096916 A JP2015096916 A JP 2015096916A JP 2015096916 A JP2015096916 A JP 2015096916A JP 6068554 B2 JP6068554 B2 JP 6068554B2
JP2015096916A
JP2016213993A (en
幸季 亀田
2015-05-11 Application filed by ファナック株式会社 filed Critical ファナック株式会社
2015-05-11 Priority to JP2015096916A priority Critical patent/JP6068554B2/en
2016-12-15 Publication of JP2016213993A publication Critical patent/JP2016213993A/en
2017-01-25 Publication of JP6068554B2 publication Critical patent/JP6068554B2/en
The present invention relates to a servo control device for controlling a machine such as a machine tool using a servo motor, and in particular, when a sensor abnormality occurs during the operation of a motor, the servo control that can safely stop control without a sensor. It relates to the device.
In general, when an abnormality occurs in a sensor during operation of a servo motor (hereinafter also simply referred to as “motor”) used in a machine such as a machine tool, an alarm state occurs and power to the motor is cut off. When the power is cut off, the motor is stopped by dynamic brake (DB) resistance. However, when the inertia attached to the motor is large or when the motor is driven at a high speed, the stopping distance becomes long. As a result, there is a possibility of mechanical damage due to a collision, especially in the case of a linear shaft, which is dangerous.
On the other hand, control stop is effective for shortening the stop distance. Here, “control stop” means stopping while controlling the motor. However, since sensor information (position, speed, magnetic pole position) from the motor is required, control stop by the conventional method cannot be performed when the sensor is abnormal. Therefore, development of a method for stopping control without a sensor is desired. Here, “sensorless control” refers to feedback control of a motor based on estimated sensor information.
The sensor abnormality includes a case where the sensor itself detects the abnormality and a case where the servo control device that receives the sensor information detects the abnormality. For example, the sensor itself detects an abnormality such as a pulse count error that can be recognized by the internal circuit of the sensor. On the other hand, a pulse omission etc. that occurs after transmission of sensor information will cause the servo control device to detect an abnormality.
FIG. 1 is a configuration diagram of a general servo control device. The servo control device 1000 includes a position control unit 1004, a speed control unit 1005, a current control unit 1006, a first coordinate conversion unit 1015, a second coordinate conversion unit 1016, an amplifier 1002, a sensor unit 1001, and a magnetic pole. A position detection unit 1003. The position control unit 1004 outputs a speed command based on the position command and the position feedback (FB) from the host controller 1020. The position FB is obtained by integrating the motor speed (speed FB) detected by the sensor unit 1001 provided in the vicinity of the motor 1030 with the integrator 1014.
The speed control unit 1005 outputs a current command based on the speed command from the position control unit 1004 and the speed FB. The current control unit 1006 outputs a voltage command based on the current command from the speed control unit 1005 and the current FB. The current FB is output from the second coordinate conversion unit 1016 based on the current value fed back from the amplifier 1002 and the magnetic pole position detected by the magnetic pole position detection unit 1003. The amplifier 1002 drives the motor 1030 based on the voltage command converted by the first coordinate conversion unit 1015.
The sensor information of the motor 1030 detected by the sensor unit 1001 is fed back to the position control unit 1004 as position feedback (FB), fed back to the speed control unit 1005 as speed feedback (FB), and further as a magnetic pole position, the second coordinate conversion unit. The current FB is fed back to the current control unit 1006 via 1016 and used. When a scale is separately used, the position FB and the speed FB are based on sensor information from the scale.
As a sensorless permanent magnet synchronous motor control method, a method using a stator voltage phase has been proposed (for example, Patent Document 1 or Non-Patent Document 1). By stably converging the stator voltage for the δ axis on the γδ coordinate (stator voltage γ-axis element V γ = 0), the rotational speed ω can be estimated from the stator voltage δ-axis element V δ and can be controlled without a sensor. Proposed. Patent Document 1 further proposes correction based on a current command for power factor improvement, but the control method for setting V γ = 0 is the same. Neither is intended to stop control when the sensor is abnormal.
Further, as a means for ensuring safety when a sensor abnormality occurs, a technique for detecting a sensor abnormality and shifting to sensorless control using a magnetic pole position estimator has been proposed (for example, Patent Document 2). The invention described in Patent Document 2 is intended for people, such as elevators and automobiles, and aims to keep moving without a sensor to a safe position while avoiding a sudden stop at the time of failure. However, in machines such as machine tools, it is desired to stop more quickly in order to avoid a collision.
JP 2011-015601 A JP 2001-112282 A
Kenji Yamanaka and Tokuo Onishi: "Phase Tracking Synchronous Sensorless Control System for Permanent Magnet Synchronous Motor", IEEJ Transactions Volume D, Vol.129, No.4, pp. 432-437 (2009-4)
In order to solve the above-described problems, an object of the present invention is to provide a servo control device that switches to a method that uses voltage information when a sensor malfunctions and simultaneously gives a stop position command or a deceleration command for stopping control. .
A servo control device according to an embodiment of the present invention is a servo control device that controls a servo motor in a machine tool or an industrial machine. The servo control device detects a speed of the servo motor and outputs it as speed feedback, and a servo motor. An amplifier that drives and feeds back the current flowing through the servo motor, a magnetic pole position detector that detects the magnetic pole position of the servo motor, and a speed based on the position command for the servo motor and the position of the servo motor calculated from the detected speed A position control unit that outputs a command, a speed control unit that outputs a current command based on the speed command and the detected speed, a current control unit that outputs a voltage command based on the current command and the detected current, and a voltage A speed estimation unit that calculates an estimated speed based on a command, and a magnetic pole position that calculates an estimated magnetic pole position from the estimated speed When a sensor abnormality is detected by the sensor abnormality detection unit, a sensor abnormality detection unit that detects an abnormality of the sensor unit, a stop position command generation unit that generates a stop position command for stopping the servo motor A first switch that switches the position command to a stop position command, a second switch that switches the magnetic pole position to the estimated magnetic pole position when the sensor abnormality detection unit detects an abnormality in the sensor unit, and a sensor abnormality detection unit. And a third switch for switching the speed feedback to the estimated speed when an abnormality of the sensor unit is detected.
According to the servo control device of one embodiment of the present invention, the motor speed is estimated from the voltage information even when the sensor is abnormal, and the value is used instead of the sensor information (position, speed, magnetic pole position). Thus, it is possible to provide a servo control device capable of stopping control. Since the stop follows the stop position command or the deceleration command, the stop distance can be shortened compared to the conventional stop by DB resistance, which can lead to the prevention of machine damage when the sensor is abnormal and the improvement of safety. it can.
It is a block diagram of the conventional servo control apparatus. It is a block diagram of the servo control apparatus which concerns on Example 1 of this invention. It is a flowchart for demonstrating the operation | movement procedure of the servo control apparatus which concerns on Example 1 of this invention. It is a block diagram of the servo control apparatus which concerns on Example 2 of this invention. It is a flowchart for demonstrating the operation | movement procedure of the servo control apparatus which concerns on Example 2 of this invention. It is a block diagram of the servo control apparatus which concerns on Example 3 of this invention. It is a figure showing the time change of the speed instruction | command in the case where it is based on the case where it is based on a prior art, and according to Example 3 of this invention. It is a figure showing the time change of the motor speed in the case where it is based on the case where it is based on a prior art, and according to Example 3 of this invention. It is a figure showing the time change of the difference of a motor phase and a presumed phase at the time of the case where it is based on a prior art, and when phase correction is performed according to Example 3 of this invention.
A servo control device according to the present invention will be described below with reference to the drawings.
First, the servo control device according to the first embodiment of the present invention will be described. FIG. 2 shows a configuration diagram of the servo control apparatus according to the first embodiment of the present invention. A servo control device 101 according to the first embodiment of the present invention is a servo control device that controls a servo motor in a machine tool or an industrial machine, and includes a sensor unit 1, an amplifier 2, a magnetic pole position detection unit 3, and a position control. Unit 4, speed control unit 5, current control unit 6, speed estimation unit 7, magnetic pole position estimation unit 8, sensor abnormality detection unit 9, stop position command creation unit 10, first switch 11 , A second switcher 12 and a third switcher 13.
The sensor unit 1 is provided in the vicinity of a servo motor 30 (hereinafter also referred to as “motor”), detects the speed of the servo motor 30 and outputs it as speed feedback. An angle sensor (resolver, optical type, magnetic type) can be used for the sensor unit 1, and the rotation speed can be calculated from the change in angle.
The amplifier 2 drives the servo motor 30 and feeds back the current flowing through the servo motor 30. The magnetic pole position detector 3 detects the magnetic pole position of the servo motor 30.
The position control unit 4 outputs a speed command based on the position command of the servo motor 30 from the host controller 20 and the position of the servo motor calculated from the speed detected by the sensor unit 1. The speed controller 5 outputs a current command based on the speed command from the position controller 4 and the speed detected by the sensor unit 1.
The current control unit 6 outputs a voltage command based on the current command from the speed control unit 5 and the current fed back by the amplifier 2. The speed estimation unit 7 calculates the estimated speed based on the voltage command from the current control unit 6. The magnetic pole position estimation unit 8 calculates an estimated magnetic pole position based on the estimated speed from the speed estimation unit 7.
The sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. Possible abnormalities of the sensor unit 1 include a case where the wiring of the sensor unit 1 is disconnected and a detection signal cannot be received. Alternatively, when the sensor unit itself has a function of detecting an abnormality, the abnormality detection signal can be received directly from the sensor unit 1.
The stop position command creating unit 10 creates a stop position command for stopping the servo motor 30. The stop position command may be stored in advance in a storage unit (not shown) provided in the stop position command creating unit 10.
The servo control device according to the first embodiment of the present invention is characterized in that the position command is switched to the stop position command when an abnormality of the sensor unit is detected. That is, the first switch 11 switches the position command to the stop position command when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. The second switch 12 switches the magnetic pole position to the estimated magnetic pole position when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. Further, the third switch 13 switches the speed feedback to the estimated speed when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. The sensor abnormality detection unit 9 outputs an abnormality detection signal when detecting an abnormality of the sensor unit 1. The first switch 11, the second switch 12, and the third switch 13 can detect an abnormality in the sensor unit 1 by receiving the abnormality detection signal output from the sensor abnormality detection unit 9.
Thus, if the sensor abnormality detection part 9 detects abnormality of the sensor part 1, each switch 11-11 will take the following structures.
(1) The magnetic pole position estimation unit 8 calculates the estimated magnetic pole position based on the estimated speed, and uses the estimated magnetic pole position instead of the detected magnetic pole position included in the sensor information by switching with the second switch 12.
(2) In the 3rd switching device 13, instead of the speed contained in the sensor information detected by the sensor unit 1, the estimated speed is used as the speed FB, and the integration is used as the position FB.
(3) The first switch 11 uses the stop position command created by the stop position command creating unit 10 instead of the position command from the host controller 20.
At the time of switching, there may be a difference between the phase θ 1 from the sensor information and the phase θ 2 from the estimated speed. Therefore, at the same time as switching to the estimated speed, the value of the phase θ 1 is changed to the initial value of the estimated phase. It is preferable to use as.
Next, the operation procedure of the servo control apparatus according to the first embodiment of the present invention will be described with reference to the flowchart shown in FIG.
First, in step S101, the sensor abnormality detection unit 9 (see FIG. 2) determines whether or not an abnormality has occurred in the sensor unit 1. If there is no abnormality in the sensor unit 1, normal servo control (normal control) is performed in steps S102 to S110. On the other hand, if an abnormality has occurred in the sensor unit 1, sensorless control is performed in steps S111 to S119.
First, normal control will be described. In step S <b> 102, the sensor unit 1 detects the speed of the motor 30. The detected speed is input to the third switch 13. Here, in the case of normal control, since the sensor abnormality detection unit 9 has not detected an abnormality of the sensor unit 1, in step S103, the third switcher 13 sets the detected speed as the speed FB as the speed control unit 5. Output to. In step S109, the speed control unit 5 executes speed control.
In step S107, the detected speed is input to the integrator 14 and output as position feedback. Further, in step S <b> 106, the host controller 20 outputs a position command to the first switch 11. Here, in the case of normal control, since the sensor abnormality detection unit 9 has not detected an abnormality in the sensor unit 1, the first switch 11 outputs a position command from the host control device 20 to the position control unit 4. In step S108, the position control unit 4 executes position control based on the position command and the position FB.
In step S104, the magnetic pole position detection unit 3 detects the magnetic pole position from the speed detected by the sensor unit 1. The detected magnetic pole position is input to the second switch 12. Here, in the case of normal control, since the sensor abnormality detection unit 9 has not detected an abnormality in the sensor unit 1, the second switch 12 outputs the detected magnetic pole position to the second coordinate conversion unit 16. Next, in step S105, the second coordinate conversion unit 16 performs coordinate conversion from the three-phase current to the dq current. In step S <b> 110, the current after coordinate conversion is input to the current control unit 6 as a current FB, and the current control unit 6 executes current control. Normal control is performed as described above.
Next, sensorless control in the servo control device according to the first embodiment of the present invention will be described. First, in step S111, the speed estimation unit 7 estimates a speed from a voltage command that is voltage information, and outputs the estimated speed. The output estimated speed is input to the third switch 13. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1, in step S112, the third switch 13 outputs the estimated speed to the speed control unit 5 as the speed FB. To do.
In step S116, the estimated speed is input to the integrator 14 as the speed FB and output as the position FB. Further, in step S115, the stop position command generation unit 10 outputs a stop position command to the first switch 11. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1, the first switch 11 sends the stop position command from the stop position command creation unit 10 to the position control unit 4. Output. In step S117, the position control unit 4 executes position control based on the stop position command and the position FB. In step S118, the speed control unit 5 executes speed control with the estimated speed as the speed FB.
In step S113, the magnetic pole position estimation unit 8 calculates an estimated magnetic pole position based on the estimated speed. The calculated estimated magnetic pole position is input to the second switch 12. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1, the second switch 12 outputs the estimated magnetic pole position to the second coordinate conversion unit 16. Next, in step S114, the second coordinate conversion unit 16 performs coordinate conversion from the three-phase current to the dq current. In step S119, the current after coordinate conversion is input to the current control unit 6 as current FB, and current control is executed. As described above, sensorless control is performed.
As described above, according to the servo control device according to the first embodiment of the present invention, the motor speed is estimated from the voltage information even when the sensor is abnormal, and the value is obtained as sensor information (position, speed, magnetic pole position). Since the position command is switched to the stop position command, the servo control device capable of performing the control stop without a sensor can be provided.
Next, a servo control apparatus according to Embodiment 2 of the present invention will be described. FIG. 4 shows a configuration diagram of a servo control apparatus according to the second embodiment of the present invention. A servo control device 102 according to the second embodiment of the present invention is a servo control device that controls a servo motor in a machine tool or an industrial machine, and detects the speed of the servo motor 30 and outputs it as a speed feedback. It is calculated from the amplifier 2 that drives the servo motor 30 and feeds back the current flowing through the servo motor 30, the magnetic pole position detector 3 that detects the magnetic pole position of the servo motor 30, the position command for the servo motor 30, and the detected speed. A position control unit 4 that outputs a speed command based on the position of the servo motor 30; a speed control unit 5 that outputs a current command based on the speed command and the detected speed; and a current command based on the detected current. A current control unit 6 that outputs a voltage command and a speed estimation unit 7 that calculates an estimated speed based on the voltage command; A magnetic pole position estimating unit 8 for calculating an estimated magnetic pole position from the estimated speed, a sensor abnormality detecting unit 9 for detecting an abnormality of the sensor unit 1, and a deceleration command generating unit 17 for generating a deceleration command for decelerating the servo motor 30; When the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1, the fourth switch 18 that switches the speed command to the deceleration command, and when the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1, the magnetic pole A second switch 12 for switching the position to the estimated magnetic pole position, and a third switch 13 for switching the speed feedback to the estimated speed when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. Features.
The servo control device 102 according to the second embodiment is different from the servo control device 101 according to the first embodiment in that the position command is changed to the stop position command when the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1. Instead of the first switching device 11 (see FIG. 2) for switching, a fourth switching device 18 (see FIG. 4) that switches the speed command to the deceleration command when the sensor abnormality detecting unit 9 detects an abnormality in the sensor unit 1 is used. It is a point that is provided. Since the other configuration of the servo control apparatus 102 according to the second embodiment is the same as that of the servo control apparatus 101 according to the first embodiment, detailed description thereof is omitted.
The servo control device according to the second embodiment of the present invention is characterized in that when a sensor abnormality is detected, a speed command is switched to a deceleration command. That is, the fourth switch 18 switches the speed command to the deceleration command when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. The second switch 12 switches the magnetic pole position to the estimated magnetic pole position when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1. Further, the third switch 13 switches the speed feedback to the estimated speed when the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1.
As described above, when the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1, each of the switches 11, 12, and 18 has the following configuration.
(3) The fourth switch 18 uses the deceleration command created by the deceleration command creation unit 17 instead of the speed command from the position control unit 4.
Next, the operation procedure of the servo control apparatus according to the second embodiment of the present invention will be described with reference to the flowchart shown in FIG.
First, in step S201, the sensor abnormality detection unit 9 (see FIG. 4) determines whether or not an abnormality has occurred in the sensor unit 1. If no abnormality has occurred in the sensor unit 1, normal servo control (normal control) is performed in steps S202 to S210. On the other hand, if an abnormality has occurred in the sensor unit 1, sensorless control is performed in steps S211 to S219.
In the servo control device according to the second embodiment, the normal control executed in steps S202 to S210 is the same as the normal control executed in steps S102 to S110 (see FIG. 3) in the servo control device according to the first embodiment described above. Since it is the same, detailed description is abbreviate | omitted.
Next, sensorless control in the servo control apparatus according to the second embodiment of the present invention will be described. First, in step S211, the speed estimation unit 7 estimates a speed from a voltage command that is voltage information, and outputs the estimated speed. The output estimated speed is input to the third switch 13. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1, in step S212, the third switch 13 outputs the estimated speed to the speed control unit 5 as the speed FB. To do.
In step S216, the estimated speed is input to the integrator 14 as the speed FB and output as the position FB. In step S217, the position control unit 4 executes position control based on the position command and the position FB. Further, in step S 215, the deceleration command creation unit 17 outputs a deceleration command to the fourth switch 18. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality in the sensor unit 1, the fourth switch 18 outputs the deceleration command from the deceleration command creation unit 17 to the speed control unit 5. . In step S218, the speed control unit 5 executes speed control based on the deceleration command and the speed FB.
In step S213, the magnetic pole position estimation unit 8 calculates an estimated magnetic pole position based on the estimated speed. The calculated estimated magnetic pole position is input to the second switch 12. Here, in the case of sensorless control, since the sensor abnormality detection unit 9 detects an abnormality of the sensor unit 1, the second switch 12 outputs the estimated magnetic pole position to the second coordinate conversion unit 16. Next, in step S214, the second coordinate conversion unit 16 performs coordinate conversion from the three-phase current to the dq current. In step S219, the current after coordinate conversion is input to the current control unit 6 as current FB, and current control is executed. As described above, sensorless control is performed.
As described above, according to the servo control device according to the second embodiment of the present invention, the motor speed is estimated from the voltage information even when the sensor is abnormal, and the value is obtained as sensor information (position, speed, magnetic pole position). Since the speed command is switched to the deceleration command, a servo control device capable of stopping control without a sensor can be provided.
Next, a servo control apparatus according to Embodiment 3 of the present invention will be described. FIG. 6 shows a configuration diagram of a servo control apparatus according to the third embodiment of the present invention. The servo control device 103 according to the third embodiment of the present invention is different from the servo control device 101 according to the first embodiment in that the phase is based on the estimated speed, inductance, and Q-phase current in order to improve the power factor. The phase correction unit 19 further performs correction. The other configuration of the servo control apparatus 103 according to the third embodiment is the same as that of the servo control apparatus 101 according to the first embodiment, and thus detailed description thereof is omitted.
In FIG. 6, current commands I γ and I δ are input to the first current control unit 61 and the second current control unit 62, respectively, and voltage commands V γ and V δ are output. The output V γ and V δ are respectively input as a d-phase voltage V d and a q-phase voltage V q to the first coordinate conversion unit 15 that performs dq-3 phase (dq-3p) conversion.
In the first coordinate conversion unit 15, the d-phase voltage V d and the q-phase voltage V q are the U-phase voltage V u , V-phase voltage V v , and W-phase voltage using the angle θ detected by the sensor unit 1. It is converted to V w. V u , V v , and V w are input to the PWM control unit 21 and input to the amplifier 2 that drives the motor 30.
The U-phase current I u , V-phase current I v , and W-phase current I w flowing in the amplifier 2 are input to the second coordinate conversion unit 16 that performs three-phase-dq (3p-dq) conversion, and I d , I converted to q . The converted I d and I q are input to the first adder 63 and the second adder 64 as current feedback, respectively. Further, I q is input to the phase correction unit 19 and phase correction is performed as follows.
Conventional sensorless control using certain voltage information is premised on controlling with V γ = 0 and I γ = 0. On the other hand, the steady-state voltage equation is expressed by the following equation.
Where L d is the d-phase inductance, L q is the q-phase inductance, K φ is the coefficient, and ω is the speed. The velocity omega, in the speed estimating section 7, and from ω = K G V δ voltage command V [delta] and the coefficient K G are calculated.
Considering the steady state, the following components depending on the q-phase current (I q ) are inherently left in V d .
In the control with V d = 0, the above component can be a factor for reducing the power factor. Therefore, if this component can be corrected, it can be said that the power factor is improved. Specifically, as shown in FIG. 6, a phase correction unit 19 is further provided to correct by adding −ωL q i q to V γ used to create the estimated speed. The value (−ωL q i q ) output from the phase correction unit 19 is input to the adder 22. The output of the adder 22 is input to the coefficient control unit 23 controls the coefficient K G.
Next, effects obtained when the servo control device according to the third embodiment of the present invention is used will be described. FIG. 7A shows the temporal change in the speed command when the sensor is used in accordance with the prior art, FIG. 8A shows the temporal change in the motor speed, and the temporal difference between the motor phase and the estimated phase. The change is shown in FIG. Further, by using the servo control device according to a third embodiment of the present invention, in the sensorless control corrected by -ωL q i q, the temporal change in the speed command shown in FIG. 7 (b), the temporal change in the motor speed Is shown in FIG. 8B, and the temporal change in the difference between the motor phase and the estimated phase is shown in FIG. 9B. In order to confirm the effect of the power factor improvement, the comparison is made assuming that the control at the estimated speed is performed even during the operation at a constant speed.
As shown in FIGS. 7A and 7B, an example is shown in which the speed command changes from 100 [m / min] to 0 [m / min] at time 1 [sec]. As a result, as shown in FIGS. 8A and 8B, the motor speed gradually decreases from 100 [m / min] to 0 [m / min] after time 1 [sec]. On the other hand, as can be seen by comparing FIG. 9 (a) and FIG. 9 (b), when the difference between the motor phase and the estimated phase is compared, it can be seen that the phase correction has a smaller phase difference. .
As described above, it is understood that the power factor can be improved by performing the phase correction in accordance with the servo control device according to the third embodiment of the present invention.
Note that the inductance L q is preferably estimated based on the speed, current, and voltage during constant speed operation before abnormality detection. Although it has been shown that the power factor can be improved by phase correction as described above, the value of the inductance L q which is a motor constant is required for this. Since the system is not limited to a system that knows the physical constants to be controlled, it is generally desirable that a robust system is not dependent on fluctuations in motor constants.
On the other hand, the inductance L q is expressed by the above-described equation (1). Therefore, the sensor captures state is constant speed operation when a normal voltage value at that time, current value, by observing the speed, it is possible to estimate in advance the inductance L q of the system. By using the estimated inductance L q , the above-described power factor improvement method can be used without specifying a physical constant.
Further, when the voltage information output by the current control unit is smaller than the set threshold value, even if the sensor abnormality detection unit detects an abnormality of the sensor unit 1, the control is not stopped and the dynamic brake ( DB) is preferably switched to stop.
Sensorless control based on voltage information uses an electromotive voltage during motor rotation. However, it is expected that the electromotive voltage decreases at a low speed, making it difficult to estimate the correct magnetic pole position. In such a state where the speed is sufficiently lowered, the motion energy is also lowered. Therefore, it is considered that the stopping by the DB is a reliable and safe stopping method. Specifically, it is preferable to provide means for switching to DB stop when the estimated speed falls below a certain threshold.
DESCRIPTION OF SYMBOLS 1 Sensor part 2 Amplifier 3 Magnetic pole position detection part 4 Position control part 5 Speed control part 6 Current control part 7 Speed estimation part 8 Magnetic pole position estimation part 9 Sensor abnormality detection part 10 Stop position command creation part 11 1st switch 12 Second Switcher 13 Third switcher 14 Integrator 15 First coordinate converter 16 Second coordinate converter 17 Deceleration command generator 18 Fourth switcher 19 Phase corrector 20 Host controller 21 PWM controller 22 Adder 23 Coefficient control Unit 30 Servo motor 61 First current control unit 62 Second current control unit 63 First adder 64 Second adder
A servo control device for controlling a servo motor in a machine tool or industrial machine,
A sensor unit that detects the speed of the servo motor and outputs it as speed feedback;
An amplifier that drives the servo motor and feeds back the current flowing through the servo motor;
A magnetic pole position detector for detecting the magnetic pole position of the servo motor;
A position control unit that outputs a speed command based on the position of the servo motor calculated from the position command to the servo motor and the detected speed;
A speed controller that outputs a current command based on the speed command and the detected speed;
A current controller that outputs a voltage command based on the current command and the detected current;
A speed estimation unit that calculates an estimated speed based on the voltage command;
A magnetic pole position estimator that calculates an estimated magnetic pole position from the estimated speed;
A sensor abnormality detection unit for detecting an abnormality of the sensor unit;
A stop position command creation unit for creating a stop position command for stopping the servo motor;
A first switch that switches the position command to the stop position command when the sensor abnormality detection unit detects an abnormality of the sensor unit;
A second switch that switches the magnetic pole position to the estimated magnetic pole position when the sensor abnormality detection unit detects an abnormality of the sensor unit;
A third switch that switches the speed feedback to an estimated speed when the sensor abnormality detection unit detects an abnormality in the sensor unit;
In order to improve the power factor, a phase correction unit that performs phase correction based on the estimated speed, inductance, and Q-phase current is provided.
A servo control device characterized by that.
A deceleration command creation unit for creating a deceleration command for decelerating the servo motor;
A fourth switch for switching the speed command to the deceleration command when the sensor abnormality detection unit detects an abnormality of the sensor unit;
The inductance, the rate of constant speed during operation before the abnormality detection, is estimated based on current and voltage, the servo control device according to claim 1 or 2.
When the voltage information output by the current control unit is smaller than a set threshold value, even if the sensor abnormality detection unit detects an abnormality, the control is not stopped, and the dynamic brake is switched to the stop. The servo control device according to any one of claims 1 to 3 .
JP2015096916A 2015-05-11 2015-05-11 Servo control device with function to stop control without sensor Active JP6068554B2 (en)
JP2015096916A JP6068554B2 (en) 2015-05-11 2015-05-11 Servo control device with function to stop control without sensor
DE102016108263.5A DE102016108263B4 (en) 2015-05-11 2016-05-04 Servo control device with sensorless controlled stop function
US15/145,994 US9751178B2 (en) 2015-05-11 2016-05-04 Servo control apparatus having function of sensorless controlled stop
CN201610297890.6A CN106160619B (en) 2015-05-11 2016-05-06 Servocontrol device
US15/483,134 US9823647B2 (en) 2015-05-11 2017-04-10 Servo control apparatus having function of sensorless controlled stop
JP2016213993A JP2016213993A (en) 2016-12-15
JP6068554B2 true JP6068554B2 (en) 2017-01-25
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JP2015096916A Active JP6068554B2 (en) 2015-05-11 2015-05-11 Servo control device with function to stop control without sensor
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JP (1) JP6068554B2 (en)
CN (1) CN106160619B (en)
DE (1) DE102016108263B4 (en)
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