TW201509112A - Motor controller - Google Patents

Abstract

Provided is a motor control device capable of identifying supply voltage abnormity and regeneration abnormity. The motor control device comprises: a convertor for converting a DC voltage into an AC voltage and driving a motor in a power operation mode, and converting the AC voltage from the motor into the DC voltage and supplying the DC voltage to a regeneration resistor in a regeneration mode; a switching part for connecting the regeneration resistor with the convertor in the case that the DC voltage exceeds a threshold value; an on-off time detection part for detecting switch-on time and switch-off time of the switching part; and an abnormity judging part which uses different threshold values in the power operation mode and the regeneration mode, wherein, in the power operation mode, the case that accumulated conduction time of the switching part exceeds the threshold value of the power operation mode is judged to be supply voltage abnormity, in the regeneration mode, the case that accumulated conduction time of the switching part exceeds the threshold value of the regeneration mode is judged to be regeneration abnormity.

Description

Motor control unit Field of invention

The present invention relates to a motor control device that can recognize abnormalities in power supply voltage and abnormal regeneration.

Background of the invention

The general motor control device rectifies the power supply voltage with a rectifying diode, and the inverter converts the rectified power supply voltage to control the position, speed and torque of the motor.

Fig. 6 is a schematic configuration diagram of a conventional motor control device. The power supply 10 is connected to the rectifying diode 14 via the electromagnetic contactor 12. The motor 18 is connected to the inverter 16. The rectifying diode 14 rectifies the voltage of the power source 10, and the inverter 16 switches the voltage rectified by the rectifying diode 14 to the motor 18.

A capacitor 20, a regenerative resistor 22, and a regenerative transistor 24 are connected between the rectifying diode 14 and the inverter 16. The regenerative transistor 24 is controlled by a regenerative transistor drive block 30. The regeneration abnormality caused by the regenerative transistor 24 is detected by the regeneration abnormality detecting block 40.

The motor 18 is coupled to an encoder 50 that detects its rotational speed. The encoder 50 is connected to the speed detecting unit 52. Speed control unit 54 is by speed The torque command is outputted by the difference between the speed detection values detected by the command and speed detecting unit 52. The torque control unit 56 switches the inverter 16 based on the torque command to control the rotational position, speed, and torque of the motor 18.

When the drive of the motor 18 is viewed from the side of power supply and demand, there is a power operation mode in which electric power is supplied to the motor 18, and a regeneration mode in which electric power is returned from the motor 18. In the power operation mode, electric power is supplied from the power source 10 to the rectifying diode 14, the inverter 16, and the motor 18. In the regeneration mode, electric power is supplied from the motor 18 to the inverter 16 and the regenerative resistor 22. In the power running mode, the motor 18 becomes a motor, and in the regeneration mode, the motor 18 becomes a generator, and the electric power generated by the motor 18 in the regeneration mode is consumed by the regenerative resistor 22. The energization control of the regenerative resistor 22 is performed by the regenerative transistor driving block 30.

Fig. 7 is a view showing the relationship between the DC voltage of the main circuit, the regenerative transistor, and the integrated value of the regenerative resistance energization time. As shown in the figure, when the main circuit DC voltage detecting unit 32 detects the main circuit DC voltage (the voltage of the capacitor 20) reaches the reference voltage 1 compared with the reference value comparing unit 34, the regenerative transistor driving unit 36 causes the regenerative transistor 24 to regenerate the transistor 24. Open. On the other hand, when the main circuit DC voltage is lowered to the reference voltage 2 which is compared with the reference value comparing unit 34, the regenerative transistor driving unit 36 turns off the regenerative transistor 24.

When the capacity of the regenerative resistor 22 is small and the frequency of regeneration is high due to severe operating conditions, the average power exceeding the allowable power of the regenerative resistor 22 is supplied to the regenerative resistor 22, which causes overheating and burning of the regenerative resistor 22. Bad. The regeneration abnormality detection of the regenerative resistor 22 is performed by the regeneration abnormality detecting block 40.

In order to protect the regenerative resistor 22, the turn-off time detecting portion 42 is turned on. It is to detect the turn-on and turn-off time of the regenerative transistor 24. As shown in FIG. 7, the integrated processing unit 44 integrates the time during which the regenerative transistor 24 is turned on when a current flows through the regenerative resistor 22, and turns off the regenerative transistor 24 when the current does not flow through the regenerative resistor 22. The time is reduced. The threshold comparison unit 46 determines that the regeneration abnormality has occurred when the integrated value of the time when the regenerative transistor 24 is turned on exceeds the allowable value, and forcibly stops the inverter 16 to prevent overheating and burn-out of the regenerative resistor 22.

As described above, if the power supply voltage is normal, the motor control device can normally detect that the frequency of regeneration is high. However, when the power supply voltage is higher than normal, the following problems occur.

When the power supply voltage is higher than normal, the regenerative transistor driving block 30 cannot resolve the voltage and the voltage in the regenerative mode to turn on the regenerative transistor 24. Therefore, electric power is supplied from the power source 10 to the rectifying diode 14 and the regenerative resistor 22. The regeneration abnormality detecting block 40 determines that it is a regeneration abnormality at the time when the integrated value of the time when the regenerative transistor 24 is turned on exceeds the allowable value, and closes the electromagnetic contactor 12 through the upper controller (not shown).

As described above, the detected abnormality of regeneration is an abnormality including both the case where the power supply voltage is higher than normal and the case where the frequency of the reproduction is high. The motor control unit shown in Figure 6 cannot distinguish between these anomalies.

The motor control device that controls the servo motor is often used in production equipment such as production machinery. Therefore, in the event of a failure, if it cannot be repaired quickly, it will suffer a lot of damage. Therefore, it is required to subdivide the fault and detect it so that the fault can be grasped immediately.

In the motor control device of Fig. 6, in order to divide the two abnormal states For the detection, it is necessary to additionally provide a circuit that can detect a high power supply voltage. However, if this circuit is provided, not only will the circuit become complicated, but also the cost will increase. In the modernization of resource-saving, it is required to set up two abnormal states separately without a special circuit.

Regarding the technique for solving the above-described drawbacks, there is a technique shown in the following Patent Document 1. The technique disclosed in Patent Document 1 discloses a servo control device that determines whether or not power regeneration is performed by the acceleration/deceleration state of the motor to be controlled, and determines that the motor is abnormal when the motor is not in the deceleration state and the power regeneration is performed.

The servo control device determines whether there is an abnormality in view of the deceleration state of the motor. However, it is not known whether the motor is in the regeneration mode or the power operation mode only by looking at the deceleration state of the motor. For example, in the case where the vertical axis load is driven, the motor is wound by gravity, and even in a certain speed, the regeneration mode is also achieved. In this way, even if the motor is not in the deceleration state, the regeneration is performed. Therefore, even when the motor is not in the deceleration state and the power is regenerated, the power supply voltage is not necessarily abnormal. The correct regeneration mode needs to consider both the speed and torque of the motor.

[First technical literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open Publication No. 2000-23480

[Summary of the Invention]

In general, the detection of the regeneration abnormality is detected by the integrated value of the current flowing through the regenerative resistor 22 exceeding the allowable power of the regenerative resistor 22. Regenerative power When the capacity of the resistor 22 is small, since the allowable power is small, the time until the regeneration abnormality is detected is short, but when the capacity of the regenerative resistor 22 is large, the time until the regeneration abnormality is detected becomes long.

When the power supply voltage is higher than normal, it takes time from the detection of the abnormality to the transmission of the abnormal signal to the upper controller and the electromagnetic contactor is cut off. Therefore, it is necessary to detect that the power supply voltage is higher than normal as soon as possible.

However, since the conventional motor control device detects the regeneration abnormality until the current flows through the regenerative resistor and exceeds the allowable power of the regenerative resistor, the detection timing of the case where the power supply voltage is higher than normal is slow, and it is easy to cause overheating of the regenerative resistor. There is a problem with sex.

In general, the temperature rise of the regenerative resistor during motor control is set to a temperature sufficiently lower than the allowable temperature of the regenerative resistor. In addition, although a device for detecting overheating of the regenerative resistor is also provided, considering that the device for detecting overheating also fails, the temperature of the regenerative resistor does not become too high even when it is abnormal, which may improve safety. . In countries or regions where the power supply is poor, since the power supply voltage becomes high, it is necessary to make the temperature of the regenerative resistor not too high even when it is abnormal.

The present invention has been made to solve the above-described drawbacks of the conventional motor control device, and an object of the invention is to provide a motor control device capable of recognizing a power source voltage abnormality and a regeneration abnormality.

Further, an object of the present invention is to provide a motor control device that can speed up the detection of an abnormality when the power supply voltage is abnormal.

Motor control related to the present invention for achieving the above object The device includes an inverter, a switch unit, an opening and closing time detecting unit, and a determining unit.

In the power operation mode, the inverter converts the DC voltage into an AC voltage to drive the motor. In the regeneration mode, the AC voltage from the motor is converted to a DC voltage and supplied to the regenerative resistor. The switch unit connects the regenerative resistor to the inverter when the DC voltage exceeds the threshold. The opening and closing time detecting unit detects the opening time and the closing time of the switch unit. The determination unit is a threshold value that is different between the power operation mode and the regeneration mode. When the cumulative energization time of the switch unit exceeds the threshold value of the power operation mode in the power operation mode, the determination is that the power supply voltage is abnormal, and on the other hand, the switch is in the regeneration mode. When the cumulative energization time of the unit exceeds the threshold of the regeneration mode, it is determined that the regeneration is abnormal.

When it is determined that the power supply voltage is abnormal when the cumulative energization time of the switch unit exceeds the threshold value of the power operation mode in the power operation mode, the regeneration abnormality is determined when the cumulative energization time of the switch unit exceeds the threshold value of the regeneration mode in the regeneration mode. Therefore, the power supply voltage abnormality and the regeneration abnormality can be detected and detected.

10, 110, 210‧‧‧ power supply

12, 112, 212‧‧ ‧ electromagnetic contactor

14, 114, 214‧ ‧ rectifying diode

20‧‧‧ capacitor

16, 116, 216‧‧‧ Inverter

18, 118, 218‧ ‧ motor

22, 122, 222‧‧‧ Regeneration resistors

24, 124, 224‧‧‧ regenerative crystal

30, 130, 230‧‧‧ Regeneration transistor drive block

32, 132, 232‧‧‧ main circuit DC voltage detection department

34, 134, 234‧‧‧ Reference Value Comparison Department

36, 136, 236‧‧‧ Regeneration transistor drive unit

40‧‧‧Regeneration abnormality detection block

42, 141, 241‧‧‧ Turn off the closing time detection department

44, 142, 242‧‧‧ Total Processing Department

46‧‧‧Threshold Comparison Department

50, 150, 250‧ ‧ encoder

52, 152, 252‧ ‧ speed detection department

54, 154, 254‧‧ ‧ Speed Control Department

56, 156, 256‧‧‧ Torque Control Department

100, 200‧‧‧ motor control unit

120, 220‧‧‧ smoothing capacitor

140, 240‧‧‧ anomaly detection block

143, 243‧‧‧1st threshold comparison unit

144, 244‧‧‧Continuous power detection department

145, 245‧‧‧ second threshold comparison unit

146‧‧‧Motor Drive Status Judgment Department

147, 247‧‧‧ Anomaly Identification Department

246‧‧"Motor Drive Status Detection Department

248‧‧‧Threshold value calculation unit for torque determination for power operation regeneration

TC, TCB‧‧‧ torque command

ωm‧‧‧Rotation speed and speed detection value

Fig. 1 is a schematic configuration diagram of a motor control device according to a first embodiment.

2 is a graph for determining the power operation mode and the regeneration mode.

3 is a view for explaining an operation of power running and regeneration mode determination when the motor is accelerated or decelerated when the power supply voltage is normal.

4 is a view for explaining an operation of determining a power operation and a regeneration mode in a case where a power supply voltage abnormality occurs in the regeneration mode.

Fig. 5 is a schematic configuration diagram of a motor control device according to a second embodiment.

Fig. 6 is a schematic configuration diagram of a conventional motor control device.

Fig. 7 is a view showing the relationship between the DC voltage of the main circuit, the regenerative transistor, and the integrated value of the regenerative resistance energization time.

[Formation for implementing the invention]

Hereinafter, embodiments of the motor control device according to the present invention will be described in terms of [Embodiment 1] and [Embodiment 2].

[Embodiment 1]

Fig. 1 is a schematic configuration diagram of a motor control device according to a first embodiment.

[Configuration of Motor Control Device 100]

The power supply 110 is connected to the rectifying diode 114 via the electromagnetic contactor 112. The power source 110 is a three-phase commercial AC power source. The electromagnetic contactor 112 connects and disconnects the power source 110 from the rectifying diode 114. The rectifying diode 114 rectifies the alternating current of the power source 110 and converts it into a direct current.

Motor 118 is coupled to inverter 116. The motor 118 is an AC servo motor. The inverter 116 is an AC voltage (power operation mode) that converts a DC voltage output from the rectifying diode 114 into a predetermined frequency by operating an internal switching transistor switch. The motor 118 is rotated by the AC voltage output from the inverter 116. On the other hand, the inverter 116 is provided by The internal switching transistor switch operates to convert the AC voltage output from the motor 118 into a DC voltage (regeneration mode).

A smoothing capacitor 120, a regenerative resistor 122, and a regenerative transistor 124 are connected between the rectifying diode 114 and the inverter 116. The smoothing capacitor 120 removes the chopping of the DC voltage output from the rectifying diode 114 to form a smoothed DC voltage. When the regenerative resistor 122 is in the regeneration mode of the motor 118, the electric power generated by the motor 118 is converted into heat and consumed. The regenerative transistor 124 is turned on in the regeneration mode of the motor 118 and the regenerative resistor 122 is connected in parallel to the inverter 116. Incidentally, the regenerative transistor 124 is also turned on when the voltage of the power source 110 becomes higher than the normal voltage.

The turn-on and turn-off of the regenerative transistor 124 is controlled by the regenerative transistor drive block 130. The regenerative transistor driving block 130 includes a main circuit DC voltage detecting unit 132, a reference value comparing unit 134, and a regenerative transistor driving unit 136. Incidentally, the regenerative transistor 124 and the regenerative transistor driving block 130 constitute a switch portion. The abnormality detecting block 140 other than the opening and closing time detecting unit 141 constitutes a determining unit.

The main circuit DC voltage detecting unit 132 is a DC voltage that detects the output side (in the power operation mode) of the rectifying diode 114 and the output side (in the regenerative mode) of the inverter 116. The reference value comparing unit 134 stores the reference voltage 1 and the reference voltage 2 shown in FIG. 6 and compares the reference voltage 1 and the reference voltage 2 with the DC voltage detected by the main circuit DC voltage detecting unit 132. As shown in FIG. 6, the reference value comparing unit 134 outputs a signal to the reference voltage 2 after the DC voltage detected by the main circuit DC voltage detecting unit 132 exceeds the reference voltage 1. The regenerative transistor driving unit 136 compares the reference values Portion 134 turns regenerative transistor 124 on between the signal outputs.

The power supply voltage abnormality and the regeneration abnormality are detected by the abnormality detecting block 140. The abnormality detecting block 140 includes an open/close time detecting unit 141, an integrated processing unit 142, a first threshold comparing unit 143, a continuous energization detecting unit 144, a second threshold comparing unit 145, a motor driving state determining unit 146, and an abnormality determining unit 147.

The opening and closing time detecting unit 141 detects the opening time and the closing time of the regenerative transistor 124. The integrated processing unit 142 calculates the cumulative energization time of the regenerative transistor 124 by adding the turn-on time of the regenerative transistor 124 detected by the turn-on and turn-off detecting unit 141 and subtracting the turn-off time. The first threshold value comparison unit 143 compares the cumulative energization time of the regenerative transistor 124 calculated by the integration processing unit 142 in the power operation mode as a threshold value for the power operation mode. The regeneration mode is a threshold comparison of the regeneration mode. The threshold value of the regeneration mode (the accumulated energization time for detecting the regeneration abnormality in the regeneration mode) stored in the first threshold value comparison unit 143 is a time limit for preventing the overheating or burn-out of the regenerative resistor 124 in the regeneration mode. In addition, the threshold value of the power operation mode (the cumulative energization time for detecting the abnormality of the power source voltage in the power operation mode) stored in the first threshold value comparison unit 143 is for limiting the overheating and burnout of the regenerative resistor 124 in the power operation mode. time. The threshold value of the power running mode is smaller than the threshold of the regeneration mode. Because it is hoped that the abnormality of the power supply voltage can be detected faster than the regeneration abnormality.

The continuous energization detecting unit 144 detects the continuous energization time of the regenerative transistor 124 detected by the opening and closing time detecting unit 141 (the time during which the regenerative transistor 124 is continuously turned on). The second threshold comparison unit 145 is to continuously energize The continuous energization time of the regenerative transistor 124 detected by the detecting unit 144 is compared with a threshold value (a threshold value for detecting a power source voltage abnormality during regeneration). The threshold value stored by the second threshold value comparing unit 145 is a time (size) longer than the ON time of the regenerative transistor 124 when the regenerative mode is repeatedly turned on and off. The motor drive state determination unit 146 determines the power operation mode and the regeneration mode of the motor 118 from the torque command TC of the motor 118 and the rotation speed ωm. Incidentally, the motor drive state determination unit 146 detects the regeneration mode for a certain period of time after detecting that it is the regeneration mode. This is to prevent erroneous detection of the power supply overvoltage in the case where the motor is frequently switched between the determination of the regeneration mode and the power operation mode. In addition, the case of the regeneration mode is performed by the detection of the retrigger type, and when the detection of the power operation mode and the regeneration mode is repeated for a short time, it is regarded as the regeneration mode. In addition, the threshold value set by the motor drive state determination unit 146 for determining the power operation mode and the regeneration mode is a predetermined value, but may be changed stepwise or continuously depending on the magnitude of the rotation speed ωm. The abnormality determination unit 147 is a comparison between the power operation mode and the regeneration mode of the motor 118 determined by the motor drive state determination unit 146, the first threshold value comparison unit 143, and the second threshold value comparison unit 145 to cause abnormality of the power supply voltage and regeneration abnormality. The two sides are judged separately.

An encoder 150 is attached to the motor 118, and the encoder 150 is a connection speed detecting unit 152. The speed detecting unit 152 is a connection speed control unit 154, and the speed control unit 154 is a connection torque control unit 156. The torque control unit 156 is connected to the inverter 116.

The encoder 150 is for detecting the rotational position of the motor 118. The speed detecting unit 152 detects the rotational position of the motor 118 detected by the encoder 150. The rotational speed ωm of the motor 118 is measured. The speed control unit 154 outputs a torque command TC by a deviation between the speed command and the rotational speed ωm. The rotational speed ωm detected by the speed detecting unit 152 and the torque command TC outputted by the speed control unit 154 are also output to the motor drive state determining unit 146. The torque controller 156 controls the current of the motor 118 based on the torque command TC outputted by the speed control unit 154 to generate a PWM signal, and outputs the PWM signal to the inverter 116. The inverter 116 is based on a PWM signal to cause an internal transistor switch to supply a voltage of a predetermined frequency to the motor 116.

[Operation of Motor Control Device 100]

First, the speed control unit 154 outputs the torque command TC from the deviation between the speed command and the rotational speed ωm. The torque control unit 156 inputs a torque command TC to control the current of the motor 118, generates a PWM signal, and outputs it to the inverter 116. The inverter 116 supplies a voltage of a predetermined frequency to the motor 118 by the PWM signal output from the torque control unit 156. The motor 118 is a torque that outputs the power supplied in response thereto.

The output voltage of the rectifying diode 114 (in the power operation mode) and the output voltage of the inverter 116 (in the regenerative mode) are detected by the main circuit DC voltage detecting unit 132. When the detected voltage is larger than the threshold value of the reference value comparing unit 134, the regenerative transistor driving unit 136 turns on the regenerative transistor 124. The regenerative transistor 124 is connected in parallel to the photocoupler element to detect energization of the regenerative resistor 122.

The integrated processing unit 142 adds the turn-on time of turning on the regenerative transistor 124, and subtracts the turn-off time during the turn-off from the accumulated time of the turn-on time. The continuous energization detecting portion 144 is the time during which the regenerative transistor 124 is turned on. Detected as a continuous turn-on time. The integrated processing unit 142 and the continuous energization detecting unit 144 are provided to detect a power source voltage abnormality separately from the regeneration abnormality during reproduction. The first threshold value comparison unit 143 is a threshold value for storing a threshold value of a regeneration mode for detecting a regeneration abnormality in the regeneration mode and a power operation mode for detecting a power source voltage abnormality in the power operation mode. Further, the second threshold comparison unit 145 stores a threshold value for detecting a power source voltage abnormality in the regeneration mode. The threshold value stored by the first threshold value comparing unit 143 is an appropriate value for protecting the regenerative resistor 122 even if a regeneration abnormality or a power supply voltage abnormality occurs. The first threshold comparison unit 143 stores, for example, 0.5 seconds as a threshold of the regeneration mode, and stores 0.01 seconds as a threshold value of the power operation mode. The threshold value stored by the second threshold value comparing unit 145 is a threshold value for detecting the power source abnormal voltage in the regeneration mode, and is a time longer than the ON time of the regenerative transistor 124 when the regeneration mode is repeatedly turned on and off. This is to identify abnormal power supply voltage (overvoltage) and regeneration abnormality in the regeneration mode.

The motor drive state determining unit 146 inputs the rotational speed ωm output from the speed detecting unit 152 and the torque command TC output from the speed control unit 154. The motor drive state determination unit 146 is a speed chopping factor in consideration of the loss of the motor 118 and the quantization error of the encoder 150, and the rotational speed ωm and the torque command TC are used to determine the power operation mode using the threshold values ωA and TCA as shown in FIG. 2 . And regeneration mode.

As shown in Fig. 2, the value of the rotational speed ωm and the torque command TC is ωm ωA and TC -TCA or ωm -ωA and TC In the case of TCA, it is determined as the regeneration mode, and the values of the rotational speed ωm and the torque command TC are determined to be the power operation mode in addition to the above.

Incidentally, ωA is determined in consideration of the quantization error of the encoder 150, and the power running regeneration determination is not chattered during the no-load operation of the motor 118. Further, the TCA is determined in consideration of the loss of the motor 118, and is set to a value when the regenerative electric power of the motor 118 and the motor loss are equal. In addition, the regeneration mode detection is detected as a regeneration state for a certain period of time once it is in the regeneration mode, and a re-trigger type is adopted, and the reciprocating force is reciprocated due to the vibration of the torque generated by the mechanical system or the control parameter which is composed of multiple inertias. In the case of the operation and regeneration mode, it is detected as a regeneration mode to prevent erroneous detection of the power supply overvoltage.

3 is a view for explaining an operation of power running and regeneration mode determination when the motor is accelerated or decelerated when the power supply voltage is normal. 4 is a view for explaining an operation of determining a power operation and a regeneration mode in a case where a power supply voltage abnormality occurs in the regeneration mode when the motor is accelerated or decelerated.

When the power supply voltage is normal, the rotational speed ωm changes with time as shown in the uppermost speed map of FIG. 3, and the torque command Tc changes with time as the torque command map below the speed map. At this time, the determination of the power running and the regeneration mode is performed by the motor driving state determining unit 146 shown in FIG. 1 as shown in the lowermost power running/reproduction determination map of FIG.

When the motor 118 enters the regeneration mode, the regenerative transistor 124 is turned on. As shown in the diagram of the regenerative resistor current of FIG. 3, the regenerative current supplied from the inverter 116 flows to the regenerative resistor 122. At this time, as shown in the graph of the DC voltage of the main circuit of FIG. 3, the DC voltage of the main circuit fluctuates.

In the regeneration mode, when the energization time of the regenerative resistor 122 exceeds the threshold of the regeneration mode, the regeneration abnormality is output from the abnormality determination unit 147.

The rotational speed ωm changes with time as shown in the top speed diagram of FIG. 4, and the torque command TC changes with time as the torque command map below the speed map. At this time, the determination of the power running and the regeneration mode is performed by the motor driving state determining unit 146 shown in FIG. 1 as shown in the lowermost power running/reproduction determination map of FIG.

When the power supply voltage becomes abnormaler than the normal power supply voltage abnormality, even if the motor 118 is turned on in the power running mode regenerative transistor 124, a current flows to the regenerative resistor 122. The time during which the current flows through the regenerative resistor 122 is detected by the integration processing unit 142. When the accumulated time of the regenerative transistor 124 exceeds the threshold value of the power operation mode, the abnormality determining unit 147 outputs a power source voltage abnormality. Since the threshold value in this case is taken to be a very small value, the abnormality of the power supply voltage can be detected immediately to prevent damage to the parts.

When the motor 118 enters the regeneration mode, the regenerative transistor 124 is turned on. As shown in the diagram of the regenerative resistor current of FIG. 4, the regenerative current supplied from the inverter 116 flows to the regenerative resistor 122. At this time, as shown in the graph of the DC voltage of the main circuit of FIG. 4, the DC voltage of the main circuit fluctuates.

In the regeneration mode, as shown in FIG. 4, when the power supply voltage abnormality occurs temporarily (at 0.7 seconds), since the continuous energization time of the regenerative resistor 122 exceeds the threshold value, the abnormality determination unit 147 outputs a voltage detection abnormality.

Generally, since the resistance value of the regenerative resistor 122 is the resistance value of the maximum output of the storable motor 118, the continuous energization time of the regenerative resistor 122 is a minute time as shown in the graph of the regenerative resistor current of FIG. . On the other hand, in the regenerative mode, when the power supply voltage rises, since the regenerative electric power of the motor 118 is also supplied, the power supply also flows. Since the resistor 122 is generated, the energization of the regenerative resistor 122 is continuous as shown in the graph of the regenerative resistor current of FIG.

In the regenerative mode, when continuous energization of the regenerative resistor 122 occurs, a voltage detection abnormality is detected. The threshold for detecting the continuous energization is smaller than the threshold for detecting the regeneration abnormality in the regeneration mode, and is a value longer than the continuous energization time of the regenerative resistor 122 of one return.

As described above, it is determined that the motor 118 is in the power operation mode or the regeneration mode, and the accumulated value of the energization time of the regenerative resistor 122 is used to detect that the power supply voltage is abnormal or the regeneration is abnormal. Therefore, it can be separately recognized that the frequency of regeneration is excessive or the power supply voltage is high. Further, even in the regenerative mode, the power supply voltage abnormality can be detected by whether or not the regenerative resistor 122 is continuously energized. Incidentally, the power running regeneration mode may be determined by detecting the torque instead of the torque command or estimating the torque.

[Embodiment 2]

Fig. 5 is a schematic configuration diagram of a motor control device according to a second embodiment. The motor control device 200 is a spindle drive for an induction motor.

[Configuration of Motor Control Device 200]

The configuration of the motor control device 200 is substantially the same as that of the motor control device 100 shown in FIG. The only point that is different from the motor control device 100 according to the first embodiment is the threshold value calculation unit 248 that includes the torque for determining the power operation regeneration.

The power source 210, the electromagnetic contactor 212, the rectifying diode 214, the inverter 216, the motor 218, the smoothing capacitor 220, the regenerative resistor 222, the regenerative transistor 224, the regenerative transistor driving block 230, and the power-removing device of FIG. The abnormality detecting block 240, the encoder 250, the speed detecting unit 252, the speed control unit 254, and the torque control unit 256 other than the threshold value calculating unit 248 for determining the torque for regeneration determination are the power source 110 and the electromagnetic contactor 112 of FIG. The rectifier diode 114, the inverter 116, the motor 118, the smoothing capacitor 120, the regenerative resistor 122, the regenerative transistor 124, the regenerative transistor driving block 130, the abnormality detecting block 140, the encoder 150, the speed detecting portion 152, and the speed control The portion 154 and the torque control unit 156 are the same.

[Operation of Motor Control Device 200]

The spindle drive of the induction motor is a field weakening control that reduces the rotational speed of the magnetic flux above (ie, not less than) the rotational speed of the substrate in inverse proportion to the rotational speed. Therefore, the motor control device 200 is provided with a field weakening portion in the torque control unit 256 that reduces the torque command in proportion to the rotation speed of the motor when the base speed is exceeded.

In the high speed range, the value of the torque TC in which the regenerative electric power of the motor 218 coincides with the motor loss becomes smaller as the rotational speed increases. The motor control device 200 lowers the threshold value in inverse proportion to the rotational speed, and determines the power operation and the regeneration mode of the motor 218 based on the threshold value. Incidentally, not only is the magnetic flux inversely proportional to the motor rotation speed, but is proportional to the rotation speed in proportion to the motor speed, and similarly, the threshold value is increased in proportion to the rotation speed. Decreased in inverse proportion to the speed of rotation. The other operations of the motor control device 200 are the same as those of the motor control device 100.

Incidentally, this embodiment is not only applicable to an induction motor, but can also be driven by a spindle drive using an IPM motor or a reluctance motor. The idea to apply.

As described above, according to the present invention, it is determined that the motor is in the power operation mode or the regeneration mode using the torque command and the motor speed, and the power supply voltage abnormality and the regeneration abnormality can be detected separately in consideration of the energization state of the regenerative resistor. Therefore, no special circuit is added, and the power supply overvoltage can be detected more quickly than in the conventional case, and the safety of the motor control device can be improved even in a poor power supply environment. In addition, when an alarm occurs, it can be recognized that there is an abnormality in the power supply or an abnormality in the frequency of regeneration, and the repair can be quickly performed when the alarm occurs.

100‧‧‧Motor control unit

110‧‧‧Power supply

112‧‧‧Electromagnetic contactors

114‧‧‧Rected diode

116‧‧‧Inverter

118‧‧‧Motor

120‧‧‧Smoothing capacitor

122‧‧‧Regeneration resistor

124‧‧‧Regeneration transistor

130‧‧‧Regeneration transistor drive block

132‧‧‧Main circuit DC voltage detection unit

134‧‧‧ Reference Value Comparison Department

136‧‧‧Regeneration transistor drive unit

140‧‧‧Anomaly detection block

141‧‧‧Open closing time detection unit

142‧‧‧Integrated Processing Department

143‧‧‧1st threshold comparison unit

144‧‧‧Continuous Power Detection Department

145‧‧‧2nd threshold comparison unit

146‧‧‧Motor Drive Status Judgment Department

147‧‧‧Anomaly Identification Department

150‧‧‧Encoder

152‧‧‧Speed Detection Department

154‧‧‧Speed Control Department

156‧‧‧Torque Control Department

TC‧‧‧Torque Command

Ωm‧‧‧ rotation speed

Claims (11)

A motor control device comprising: an inverter that converts a DC voltage into an AC voltage to drive a motor in a power operation mode, and converts an AC voltage from the motor to a DC voltage to a regenerative resistor in a regeneration mode a switching unit that connects the regenerative resistor to the inverter when the DC voltage exceeds a threshold value, opens and closes the time detecting unit, detects an opening time and a closing time of the switch unit, and determines a power running mode and a regeneration mode. When the cumulative energization time of the switch unit exceeds the threshold value of the power operation mode in the power operation mode, the power supply voltage is abnormal, and the cumulative energization time of the switch unit is exceeded in the regeneration mode. In the case of the threshold of the regeneration mode, it is determined that the regeneration is abnormal. The motor control device according to claim 1, wherein the determination unit includes an integration processing unit that adds an opening time of the switch unit detected by the opening/closing time detecting unit, and reduces a closing time of the switching unit. And calculating a cumulative energization time of the switch unit; the first threshold value comparison unit compares the cumulative energization time with a threshold value of the power operation mode and a threshold value of the regeneration mode; and the abnormality determination unit exceeds the power operation time by the cumulative energization time When the threshold value of the mode is determined, it is determined that the power supply voltage is abnormal, and when the accumulated energization time exceeds the threshold value of the regeneration mode, it is determined that the regeneration abnormality is abnormal. The motor control device according to claim 1, wherein the determination unit determines that the power supply voltage is abnormal when the continuous energization time of the switch unit exceeds a threshold value in the regeneration mode. The motor control device according to claim 3, wherein the determining unit includes: a continuous energization time detecting unit that detects a continuous energization time by an open state of the switch unit detected by the opening/closing time detecting unit; and a second threshold comparing unit The continuous energization time is compared with the threshold value, and the abnormality determining unit determines that the power supply voltage is abnormal when the continuous energization time exceeds the threshold value in the regeneration mode. The motor control device of claim 1, wherein the threshold value of the power operation mode is smaller than a threshold value of the regeneration mode. The motor control device of claim 3, wherein the threshold value for comparing the continuous energization time is greater than an opening time of the switching portion when the regenerative mode is repeatedly turned on and off. The motor control device according to claim 1 further includes a motor drive state determination unit that detects the power operation mode and the regeneration mode using a torque command and a rotation speed of the motor. The motor control device according to claim 7, wherein the motor drive state determining unit detects the regeneration mode after a certain period of time after detecting the regeneration mode. The motor control device according to claim 8, wherein the motor drive state determination unit performs the regeneration mode by the detection of the retrigger type, and the regeneration mode is adopted when the detection of the power operation mode and the regeneration mode is repeated. The motor control device of claim 7, wherein the motor is driven by the motor The state determination unit determines that the threshold values of the power operation mode and the regeneration mode are changed stepwise or continuously in response to the rotation speed of the motor. The motor control device according to claim 1, wherein the switch unit includes: a main circuit DC voltage detecting unit that detects the DC voltage; a reference value comparing unit that compares the detected DC voltage with a reference value; and regenerates the transistor to regenerate the And a regenerative transistor driving unit that turns on the regenerative transistor to turn on the regenerative resistor when the detected DC voltage exceeds a reference value.