JP2022081313A - Motor control device - Google Patents

Abstract

To provide a motor control technique that can make both improvement in torque characteristics and noise reduction compatible.SOLUTION: A motor control device, which controls driving of a polyphase SR motor by switching electricity distributions to a coil corresponding to each phase of the SR motor, comprises a current command value generation part that generates a maximum current command value that is a maximum value of a target value for currents which are carried to the coil corresponding to each phase from loads required, and a current control part that controls the currents to be carried to the coil corresponding to each phase on the basis of a sinusoidal wave. The current control part comprises a waveform correction part that corrects the sinusoidal wave in accordance with the maximum current command value. The waveform correction part corrects the sinusoidal wave so that an angle of energization of the wave becomes smaller.SELECTED DRAWING: Figure 4

Description

The present invention relates to a motor control technique. In particular, the present invention relates to a control technique for a switched reluctance motor (SR motor).

Regarding SR motors that do not require permanent magnets or windings in the rotor, control techniques that can change the motor characteristics according to the usage conditions are known. For example, in Patent Document 1, "when switching the energizing phase from one phase to the other phase, an energization timing output unit provided with an overlap section in which both the one phase and the other phase are energized is provided. And a current control unit that gradually changes the current flowing through at least one of the one phase and at least one of the other phases in at least a part of the overlap section (summary excerpt). " The motor control device is disclosed.

Japanese Unexamined Patent Publication No. 2020-10576

In the technique disclosed in Patent Document 1, since the square wave energization control is performed in which the current flowing through the coils of each phase of the SR motor is controlled based on the square wave, the torque characteristics are good, but there remains a problem in terms of noise.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a motor control technique that achieves both improvement in torque characteristics and noise reduction.

The present invention is a motor control device that controls the drive of the SR motor by switching the energization of the coils corresponding to each phase of the multi-phase SR motor, and the current flowing from the required load to the coils of the respective phases. The current control unit includes a current command value generation unit that generates a maximum current command value that is the maximum value of the target value, and a current control unit that controls the current flowing through the coils of the respective phases based on a sine wave. A waveform correction unit for correcting the sine wave according to the maximum current command value is provided, and the waveform correction unit corrects the energization angle of the sine wave to be small.

According to the present invention, it is possible to provide a motor control technique that achieves both improvement in torque characteristics and noise reduction.

(A) and (b) are explanatory views for demonstrating the outline of embodiment of this invention. (A) is an explanatory diagram for explaining a vehicle control system to which the motor control device of the embodiment of the present invention is applied, and (b) is an explanatory diagram for explaining the SR motor of the embodiment of the present invention. It is a block diagram of the motor control device of embodiment of this invention. It is a block diagram of the current control unit and the map storage unit of the embodiment of the present invention. (A) to (c) are explanatory views for explaining the energization angle correction process of embodiment of this invention. (A) is an explanatory diagram for explaining another example of the offset value map of the embodiment of the present invention, and (b) is an explanatory diagram for explaining the out-of-range removal process of the embodiment of the present invention. Is. It is a flowchart of the current control processing of embodiment of this invention. It is a block diagram of the motor control device when vector control is applied. It is a block diagram of the motor control apparatus to which the vector control of the modification of the embodiment of this invention is applied. It is a flowchart of the motor control processing of the modification of the embodiment of this invention. (A) and (b) are explanatory views for explaining the energization angle correction of the modification of the embodiment of this invention. (A)-(d) are explanatory views for demonstrating another modification of embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Hereinafter, in the present embodiment, a three-phase SR motor will be described as an example. However, the number of phases of the SR motor is not limited to this.

The motor control device of the present embodiment drives and controls the SR motor by a sine wave drive method. In the sine-wave drive method, a sine-wave current whose current command value changes in a sine-wave shape according to the rotation position (rotor electric angle) of the rotor is passed through a three-phase excitation coil to drive the rotor (rotational drive). It is a method. According to the sine and cosine drive method, the change in current is smooth and the torque pulsation is small, so that noise can be reduced.

Further, the motor control device of the present embodiment controls the energization angle of the sinusoidal current according to the required load (torque). This is to realize a high torque, and the motor control device of the present embodiment is realized by reducing the region where the torque generated by overlapping the sections in which the currents of the respective phases flow is a negative value. ..

Specifically, the motor control device corrects the frequency of the sinusoidal current shown in FIG. 1 (a) to be increased and the energization angle to be reduced as shown in FIG. 1 (b). In order to reduce the energization angle, the motor control device corrects the phase difference of each phase to the reference phase difference determined by the number of phases of the SR motor with respect to the corrected sinusoidal current. Further, the motor control device sets the phase current value in a region other than the energized region to 0.

[Vehicle control system]
Hereinafter, the present embodiment will be described by exemplifying a case where the SR motor is used as a prime mover of an electric vehicle (hereinafter, referred to as a vehicle). First, the vehicle control system 100 to which the motor control device of the present embodiment is applied will be described with reference to FIG. 2A.

The vehicle control system 100 controls the driving force of the SR motor according to the operation amount and the operation state of the operator for operating the vehicle. The operator is, for example, an operation object for the driver to give various behaviors to the vehicle, and selects a range of vehicle conditions such as an accelerator pedal for adjusting the speed of the vehicle, drive, reverse, neutral, and parking. Includes a shift lever for These controls are provided with, for example, a sensor that outputs an electrical output value in conjunction with the operation amount and operation state of the controls. The output value of each sensor is input to the motor control device. Hereinafter, the vehicle control system 100 of the present embodiment uses an output value from a sensor attached to the accelerator pedal as an operator.

As shown in FIG. 2A, the vehicle control system 100 includes a motor control device 200, an SR motor 120, a resolver 121, and an accelerator operation detection unit 112.

The accelerator operation detection unit 112 detects the accelerator signal and outputs it to the motor control device 200. The accelerator signal is an output value from the throttle position sensor. The throttle position sensor is provided on the accelerator pedal 111 and is a sensor that detects a rotation angle that changes depending on the amount of depression of the accelerator pedal (accelerator opening degree). The throttle position sensor is, for example, a potentiometer, which is provided on the rotation axis of the accelerator pedal 111 and the like, and the resistance value changes according to the rotation angle of the accelerator pedal 111. The output value from the throttle position sensor is proportional to the accelerator opening. The accelerator operation detection unit 112 applies a voltage to the throttle position sensor and detects this resistance value. Then, the accelerator operation detection unit 112 AD-converts the detected resistance value and outputs it to the motor control device 200.

The SR motor 120 is a multi-phase drive motor that drives the rear wheels 115 via the rear gear 114. For example, as shown in FIG. 2B, the SR motor 120 includes a stator 122 having a plurality of exciting coils and a rotor 123 rotatably arranged in the stator 122. The rotor 123 includes four salient poles. Each salient pole portion is formed so as to project radially outward from the rotation shaft 124. The stator 122 is provided concentrically with the rotating shaft 124 of the rotor 123 so as to cover the periphery of the rotor 123, and includes six salient poles. Each salient pole is formed so as to project radially inward toward the rotation axis 124 of the rotor 123.

A conducting wire is wound around each of the six salient poles of the stator 122 to form an exciting coil. Of the six salient poles, the exciting coils Lu, Lv, and Lw are formed with the opposing salient poles as a pair. The rotation position of the rotor 123 is detected by the resolver 121.

The resolver 121 is a rotation angle sensor that detects the position (rotor rotation angle) of the rotor 123 of the SR motor 120. The resolver 121 outputs the detection result as a rotation angle signal to the motor control device 200.

The motor control device 200 controls the drive of the SR motor 120. In the present embodiment, the motor control device 200 controls the drive of the SR motor 120 based on the accelerator signal acquired from the accelerator operation detection unit 112 and the rotation angle signal acquired from the resolver 121. Specifically, the motor control device 200 calculates the maximum current command value, which is the maximum value of the target value of the current flowing through the SR motor 120, based on the accelerator signal. Then, the motor control device 200 performs feedback control so that the current value flowing through the SR motor 120 becomes a current command value determined by the maximum current command value and the rotor rotation angle corresponding to the rotation angle signal.

Further, the motor control device 200 drives the SR motor 120 by switching the energization of the excitation coils Lu, Lv, and Lw. Here, the motor control device 200 obtains a rotor rotation angle based on the detection result of the resolver 121, and controls to selectively and sequentially energize each pair of exciting coils Lu, Lv, and Lw accordingly. .. As a result, the salient pole of the rotor 123 is repeatedly rotated while being magnetically attracted to the salient pole of the stator 122, a rotational torque is generated in the rotor 123, and a rotational driving force is generated in the SR motor 120.

In addition, the vehicle control system 100 may include a shift position sensor and the like. The shift lever is provided with a shift position sensor, and detects the switching position of the range of the shift lever. The shift position sensor detects, for example, in which range the shift lever is located by a switch provided in each range. The shift position sensor detects the position of the shift lever and outputs the detected detection value to the motor control device 200. The shift position sensor outputs a different resistance value to the motor control device 200 according to the range of the shift lever.

[Motor control device]
Next, the configuration of the motor control device 200 will be described. As shown in FIG. 3, the motor control device 200 includes a drive circuit 210 and a drive circuit control device 240.

The drive circuit 210 switches the electric power input from the battery 113 to the SR motor 120 and supplies it to the exciting coils Lu, Lv, Lw of each phase. Switching is performed according to a gate signal (drive signal) from the drive circuit control device 240.

The drive circuit control device 240 controls energization and switching of the excitation coils Lu, Lv, and Lw of each phase of the stator 122. In this embodiment, the drive circuit control device 240 generates a gate signal and outputs it to the drive circuit 210.

[Drive circuit]
The drive circuit 210 performs a switching operation based on the gate signal output from the drive circuit control device 240, and excites the power supply voltage of the battery 113 as an AC voltage of three phases (U phase, V phase, W phase). It is supplied to the coils Lu, Lv, and Lw as an energization signal.

The drive circuit 210 is connected to, for example, the battery 113. The drive circuit 210 includes capacitors 211, switching elements 221 to 226, and diodes 231 to 236. The switching elements 221 to 226 are, for example, n-type channel FETs. For example, the switching elements 221 to 226 may be composed of any one of an IGBT (Insulated Gate Bipolar Transistor), a FET (Field Effect Transistor), and a BJT (bipolar junction transistor).

One end of the capacitor 211 is connected to the positive electrode of the battery 113, and the other end is connected to the negative electrode of the battery 113. The capacitor 211 is a smoothing capacitor and stabilizes the power supply against voltage fluctuations of the battery 113.

In the switching element 221 the drain is connected to the positive electrode of the battery 113 and the source is connected to the cathode of the diode 231. The anode of the diode 231 is connected to the negative electrode of the battery 113. In the diode 232, the cathode is connected to the positive electrode of the battery 113 and the anode is connected to the drain of the switching element 222. The source of the switching element 222 is connected to the negative electrode of the battery 113.

In the switching element 223, the drain is connected to the positive electrode of the battery 113 and the source is connected to the cathode of the diode 233. The anode of the diode 233 is connected to the negative electrode of the battery 113. The diode 234 has a cathode connected to the positive electrode of the battery 113 and an anode connected to the drain of the switching element 224. The source of the switching element 224 is connected to the negative electrode of the battery 113.

In the switching element 225, the drain is connected to the positive electrode of the battery 113 and the source is connected to the cathode of the diode 235. The anode of the diode 235 is connected to the negative electrode of the battery 113. The diode 236 has a cathode connected to the positive electrode of the battery 113 and an anode connected to the drain of the switching element 226. The source of the switching element 226 is connected to the negative electrode of the battery 113.

That is, the capacitor 211, the switching element 221 and the diode 231 connected in series, the switching element 222 and the diode 232 connected in series, and the switching element 223 and the diode 233 connected in series were connected in series. The switching element 224 and the diode 234, the switching element 225 and the diode 235 connected in series, and the switching element 226 and the diode 236 connected in series are connected in parallel to the battery 113, respectively.

Further, one end of the exciting coil Lu of the SR motor 120 is connected to the connection point between the switching element 221 and the diode 231 and the other end of the exciting coil Lu is connected to the connection point between the switching element 222 and the diode 232. To. One end of the excitation coil Lv of the SR motor 120 is connected to the connection point between the switching element 223 and the diode 233, and the other end of the excitation coil Lw is connected to the connection point between the switching element 224 and the diode 234. One end of the excitation coil Lw of the SR motor 120 is connected to the connection point between the switching element 225 and the diode 235, and the other end of the excitation coil Lw is connected to the connection point between the switching element 226 and the diode 236.

An H-bridge circuit is composed of switching elements 221 and 222 and diodes 231 and 232, and magnetism can be generated in the exciting coil Lu by turning on and off the switching elements 221 and 222. An H-bridge circuit is composed of switching elements 223 and 224 and diodes 233 and 234, and magnetism can be generated in the exciting coil Lv by turning on and off the switching elements 223 and 224. An H-bridge circuit is composed of switching elements 225 and 226 and diodes 235 and 236, and magnetism can be generated in the exciting coil Lw by turning on and off the switching elements 225 and 226.

As described above, the drive circuit 210 is composed of three H-bridge circuits. Then, the gate signal output from the drive circuit control device 240 is input to the gates of the switching elements 221 to 226, and the switching elements 221 to 226 are switched on and off according to the input control signal. As a result, the current from the battery 113 is energized to each of the exciting coils Lu, Lv, and Lw of the SR motor 120. When the switching elements 221 to 226 are turned off, the diodes 231 to 236 prevent the currents of the exciting coils Lu, Lv, and Lw from flowing back.

The current sensor 212 detects the current flowing through each of the exciting coils Lu, Lv, and Lw of the SR motor 120 and outputs the current to the drive circuit control device 240. In response to this, the drive circuit control device 240 outputs a gate signal to the drive circuit 210, controls the switching elements 221 to 226, and rotates in the rotation direction of the rotor 123 depending on the timing of energizing the excitation coils Lu, Lv, and Lw, respectively. Control speed and torque.

[Drive circuit controller]
The drive circuit control device 240 controls the drive of the SR motor by switching the energization of the excitation coils Lu, Lv, and Lw corresponding to each phase of the multi-phase SR motor 120. By outputting the gate signal to the drive circuit 210, the drive circuit control device 240 energizes the excitation coils Lu, Lv, Lw by the energization signal and drives the rotor 123 of the SR motor 120.

The drive circuit control device 240 of the present embodiment performs a sinusoidal drive driven by a sinusoidal current. Then, the drive circuit control device 240 controls the energization angle of the sinusoidal current according to the required load. Specifically, the energization angle is reduced from 360 ° as the required load increases. Hereinafter, in the present specification, the waveform of the current used for driving the rotor 123 of the SR motor 120 is referred to as a “drive current waveform”.

Hereinafter, the drive circuit control device 240 according to the present embodiment will be described. As shown in FIG. 3, the drive circuit control device 240 includes a current command value generation unit 241, a current detection unit 242, a position detection unit 243, a rotation speed detection unit 244, a current control unit 245, and a PWM (Pulse). It includes a Windth Modulation) output unit 246, an advance angle setting unit 247, an energization timing output unit 248, a gate drive unit 249, and a map storage unit 250.

The current command value generation unit 241 generates the maximum value (hereinafter, “maximum current command value”) of the target value of the current flowing from the required load to the exciting coils Lu, Lv, Lw of each phase of the SR motor 120. Specifically, the current command value generation unit 241 acquires the accelerator signal output from the accelerator operation detection unit 112, and generates the maximum current command value according to the value of the accelerator signal. Then, the current command value generation unit 241 outputs the generated maximum current command value to the current control unit 245 and the advance angle setting unit 247.

For example, the current command value generation unit 241 includes a table in which the operation amount of the accelerator pedal 111 and the maximum current command value are associated with each other, and the operation amount of the accelerator pedal 111 indicated by the accelerator signal output from the accelerator operation detection unit 112 can be used. The maximum current command value is generated by reading the corresponding maximum current command value from the table. Further, the current command value generation unit 241 may experimentally determine the maximum current command value from the operation amount of the accelerator pedal 111 indicated by the accelerator signal output from the accelerator operation detection unit 112.

When a shift position sensor is provided and a shift signal is input, the current command value generation unit 241 has the shift position of the shift lever in the reverse range based on the shift signal, and is in the reverse running position. When it is determined, it is determined that the rotation direction of the SR motor 120 is reverse rotation. Then, the current command value generation unit 241 may output a rotation direction command signal indicating that the rotation direction of the SR motor 120 is reverse rotation to the current control unit 245.

The current detection unit 242 detects the current value flowing through each of the exciting coils Lu, Lv, and Lw of the SR motor 120 output from the current sensor 212, and outputs the current value to the current control unit 245 as the current detection value. The current detection unit 242 detects, for example, the phase current energized in the SR motor 120 based on the detection signal of each phase current (winding current) output from each current sensor 212, and detects the phase current. Is output to the current control unit 245.

The position detection unit 243 detects the rotor electric angle based on the signal output by the resolver 121, and outputs the rotation speed detection unit 244, the current control unit 245, and the energization timing output unit 248.

The rotation speed detection unit 244 calculates the rotation speed (rotor rotation speed) of the rotor 123 and outputs it to the current control unit 245 and the advance angle setting unit 247. In the present embodiment, the rotation speed detection unit 244 detects the amount of change in the rotor electric angle output by the position detection unit 243 per unit time, and calculates the rotor rotation speed (rotation speed) from the detected change amount.

The current control unit 245 performs energization control that controls the current flowing through the exciting coils Lu, Lv, and Lw of each phase of the SR motor 120 based on a predetermined waveform (drive current waveform). The current control unit 245 detects the maximum current command value output from the current command value generation unit 241, the rotor electric angle detected by the position detection unit 243, the rotor rotation speed output from the rotation speed detection unit 244, and the current detection. The current difference value is calculated using the current detection values of the excitation coils Lu, Lv, and Lw detected by the unit 242. The calculated current difference value is output to the PWM output unit 246. The current difference value calculated here is a deviation between the current command value and the current detection value determined by the maximum current command value, the drive current waveform, and the rotor electric angle.

Further, the current control unit 245 of the present embodiment performs energization control based on the sinusoidal current. However, the current control unit 245 changes the energization angle of the sinusoidal current according to the maximum current command value. The current control unit 245 of the present embodiment realizes this by making corrections such as changing the frequency of the sine wave which is the drive current waveform. Therefore, the current control unit 245 of the present embodiment includes the waveform correction unit 255 as shown in FIG.

The waveform correction unit 255 performs an energization angle correction process for correcting a sine wave, which is a drive current waveform (predetermined waveform) used by the current control unit 245 for control, according to the maximum current command value. In the present embodiment, the larger the required load, the smaller the energization angle of the basic sine wave (basic sine wave) prepared in advance. The correction is performed every predetermined current control cycle (for example, 25 μs) using the frequency correction coefficient and the offset value, which are the correction terms stored in the map storage unit 250. The details of the energization angle correction process will be described later.

In the present embodiment, the current control cycle is set shorter than the maximum current command value generation cycle by the current command value generation unit 241. The current control unit 245 temporarily stores the maximum current command value output from the current command value generation unit 241 and uses the latest value at the time of processing.

The PWM output unit 246 determines the duty ratio of the switching elements 221 to 226 so that the current difference value generated by the current control unit 245 is reduced. The PWM output unit 246 outputs the calculated duty ratio to the gate drive unit 249. The PWM output unit 246 may calculate the above-mentioned duty ratio based on the current difference value by using a known PI (Proportional Integral) control, PID (Proportional Integral Dynamic) control, or the like.

The advance angle setting unit 247 determines the advance angle according to the maximum current command value output from the current command value generation unit 241 and the rotor rotation speed output from the rotation speed detection unit 244, and outputs the energization timing. Output to unit 248. The advance angle is acquired from the map storage unit 250.

The energization timing output unit 248 has, based on the rotor electric angle output from the position detection unit 243 and the advance angle output from the advance angle setting unit 247, each exciting coil Lu, Lv, of each phase of the SR motor 120. The energization timing for energizing each Lw is determined. Then, the energization timing output unit 248 outputs the determined energization timing to the gate drive unit 249.

The gate drive unit 249 turns on the switching elements 221 to 226 included in the drive circuit 210 based on the timing signal output from the energization timing output unit 248 and the duty ratio output from the PWM output unit 246. The control signal (PWM signal) to be turned off is output to the gates of the switching elements 221 to 226.

The map storage unit 250 stores an advance angle map 251, a frequency correction coefficient map 252, and an offset value map 253.

The advance angle map 251 is a map in which the advance angle values are associated with each combination of the maximum current command value and the rotor rotation speed. Here, the advance angle is such that the energization start phase and the energization end phase for each of the exciting coils Lu, Lv, Lw of each phase of the SR motor 120 are set to predetermined positions according to the inductance change of each phase (for example, the increase start phase of the inductance and the increase start phase). Represents the angle at which the energization angle is changed to the advance angle side from the decrease start phase, etc.). The advance angle tends to increase with respect to the increase in the maximum current command value and the rotor rotation speed. The advance map 251 is set, for example, based on the result of the simulation. The advance map 251 may be set based not only on the result of the simulation but also on the measurement result obtained by measuring the actual machine.

The frequency correction coefficient map 252 is a map that stores the frequency correction coefficient in association with the maximum current command value determined by the accelerator opening degree. The frequency correction coefficient is a correction term used by the waveform correction unit 255 when correcting the energization angle, and is used to change the frequency of the waveform to be corrected. This frequency correction coefficient is set so that an optimum energization angle can be obtained with respect to an increase in the maximum current command value. The optimum energization angle is the energization angle at which the torque is highest. When the basic sine wave is used as it is, 1 is stored as the frequency correction coefficient.

The offset value map 253 is a map that stores the offset value in association with the frequency correction coefficient. The offset value is a correction term used by the waveform correction unit 255 when correcting the energization angle, and is used to change the phase of the waveform to be corrected. This offset value is set according to the frequency correction coefficient. Specifically, even if the frequency changes, the value of the difference between the rotor electric angles at which the current command value of each phase is maximized is set to be maintained. When the basic sine wave is used as it is, 0 is stored as the offset value.

[Energization angle correction processing]
Next, the energization angle correction process by the waveform correction unit 255 according to the present embodiment will be described with reference to figures and equations. As shown in FIG. 5A, the U-phase, V-phase, and W-phase current command values output from the drive circuit control device 240 each have a phase difference of 120 °. In this figure, the U-phase current command value is shown by a solid line, the V-phase current command value is shown by a broken line, and the W-phase current command value is shown by a alternate long and short dash line.

The current command value shown in FIG. 5A is a current command value of each phase according to the rotor electric angle when the drive current waveform is a fundamental sine wave. These are expressed by equations as follows.
Iu_ref = (Imax × SINθ + Imax) / 2
Iv_ref = (Imax × SIN (θ + (120 × (π / 180))) + Imax) / 2
Iw_ref = (Imax × SIN (θ-(120 × (π / 180))) + Imax) / 2
... (1)
Here, Iu_ref, Iv_ref, Iw_ref, Imax, and θ represent the following, respectively.
Iu_ref: U-phase current command value [A],
Iv_ref: V-phase current command value [A],
Iw_ref: W phase current command value [A],
Imax: Maximum current command value [A],
θ: Rotor electrical angle [rad]

First, as shown in FIG. 5B, the waveform correction unit 255 performs frequency correction to increase the frequency of the current command value (sine wave current) of each phase. The waveform correction unit 255 uses the frequency correction coefficient associated with the maximum current command value stored in the map storage unit 250 for this frequency correction.

Here, the rotor electric angle θ is corrected by multiplying it by a frequency correction coefficient. The corrected sine wave current (current command value for each rotor electric angle θ) of each phase is expressed by the following equation (2).
Iu_ref = (Imax × SIN (fa × θ) + Imax) / 2
Iv_ref = (Imax × SIN (fa × (θ + (120 × (π / 180)))) + Imax) / 2
Iw_ref = (Imax × SIN (fa × (θ-(120 × (π / 180)))) + Imax) / 2
... (2)
Here, fa is a frequency correction coefficient. For example, if the frequency of lu_ref is 50 Hz when fa = 1, it will be 100 Hz when fa = 2.

Next, the waveform correction unit 255 performs phase difference correction so that the phase difference of the sinusoidal current of each phase (difference in the rotor electric angle of the same current command value) is the same as before the correction. The phase difference (basic phase difference) before correction is determined by the number of phases of the SR motor 120. For example, in the three-phase SR motor 120, the basic phase difference is 120 ° as shown in FIG. 5 (a).

When frequency correction is performed using the frequency correction coefficient fa, the phase difference becomes small as shown in FIG. 5 (b). Here, as an example, a case where the phase difference between the sinusoidal currents of each phase is 80 ° is shown.

The waveform correction unit 255 corrects the phase difference of the sinusoidal current of each phase to be the fundamental phase difference (120 °). In this case, the corrected sine wave current (current command value for each rotor electric angle θ) of each phase is expressed by the following equation.
Iu_ref = (Imax × SIN ((fa × θ) + fo_u) + Imax) / 2
Iv_ref = (Imax × SIN ((fa × θ) + (120 × (π / 180)) + fo_v) + Imax) / 2
Iw_ref = (Imax × SIN ((fa × θ)-(120 × (π / 180)) + fo_w) + Imax) / 2
・ ・ ・ ・ (3)
Here, fo_u, fo_v, and fo_w are offset values of each phase, and are determined by the frequency correction coefficient fa and the number of phases of the SR motor 120. For example, the rotor electric angle at which the current command value of the U phase is maximized is specified, and then the rotor electric angle at which the current command value of each phase is maximum is determined.

The rotor electric angle (center of energization angle; θu_max) at which the current command value of the U phase is maximized can be calculated as the rotor electric angle satisfying the following equation (4).
Imax = (Imax × SIN (fa × θu_max) + Imax) / 2 ・ ・ ・ (4)
The rotor electric angle (θv_max) at which the V-phase current command value is maximum and the rotor electric angle (θw_max) at which the W-phase current command value is maximum are calculated by the following equations.
θv_max = θu_max + (120 × (π180))) ・ ・ ・ (5)

When the energization angle is smaller than the basic waveform (energization angle 180 °), there are two or more solutions at the center of the energization angle. In such a case, the value closest to the center of the energization angle before frequency correction is adopted.

Further, as shown in FIG. 6A, the waveform correction unit 255 may obtain an offset value by creating a map of the offset value (fo) for each energization angle.

Finally, as shown in FIG. 6B, the waveform correction unit 255 performs the out-of-range removal process in which the current command value outside the energized region is set to 0. Here, as shown in this figure, the waveform correction unit 255 has the center of the energization angle as the center, and the width of the energization angle (here, 360 degrees) as the energization region. For each phase, the center of the energization angle is obtained, and this process is performed.

[Current control processing]
Next, the flow of the current control process by the current control unit 245, including the energization angle correction process by the waveform correction unit 255, will be described. This process is performed every predetermined current control cycle S. FIG. 7 is a processing flow of the current control processing of the present embodiment.

The current control unit 245 acquires the current detection values I_u ^* , I_v ^* , I_w ^* of each phase, the rotor electric angle θ ^* , and the latest maximum current command value Imax ^* (step S1101).

The waveform correction unit 255 associates the frequency correction coefficient fa (Imax ^* ) stored in the map storage unit 250 with the latest maximum current command value Imax ^* and the acquired frequency correction coefficient fa (Imax ^* ). The offset values (fo_u (fa), fo_v (fa), fo_w (fa)) stored in the map storage unit 250 are acquired (step S1102).

The waveform correction unit 255 uses the acquired frequency correction coefficient and offset value to perform frequency correction and phase difference correction for the current command value of each phase, respectively (step S1103). Here, the waveform correction unit 255 calculates the current command values Iu_ref, Iv_ref, and Iw_ref at the rotor electric angle θ ^* , respectively, based on the above equation (3) (step S1103).

Then, the waveform correction unit 255 determines whether or not the rotor electric angle θ ^* is within the energization range for each of the current command values of each phase (step S1104). Then, if it is within the energization range, it is left as it is, while if it is outside the energization range, the energization is turned off (step S1105). To turn off the energization means to set the current command value to 0.

Finally, the current control unit 245 calculates the difference between the current command value of each phase obtained by the waveform correction unit 255 and the current detection value as the current difference value (step S1106), and ends the process.

As described above, the motor control device 200 of the present embodiment drives the SR motor 120 by switching the energization of the coils (exciting coils Lu, Lv, Lw) corresponding to each phase of the three-phase SR motor 120. The motor control device 200 that controls the current, the current command value generation unit 241 that generates the maximum current command value that is the maximum value of the target value of the current that flows from the required load to the coil of each phase, and the current that flows through the coil of each phase. A current control unit 245 that controls the current based on a sinusoidal wave is provided. The current control unit 245 includes a waveform correction unit 255 that corrects a sine wave according to the maximum current command value. The waveform correction unit 255 corrects the energization angle of the sine wave so as to be small.

As described above, the waveform correction unit 255 of the present embodiment corrects the energization angle of the sinusoidal current according to the maximum current command value determined by the accelerator signal. Since the value of the accelerator signal changes in proportion to the required torque, in the present embodiment, the energization angle of the sinusoidal current can be changed according to the required torque. Therefore, in a high rotation and high load region where high torque is required, high torque characteristics can be obtained by reducing the energization angle.

Further, according to the present embodiment, the waveform correction unit 255 corrects the basic sine and cosine waveform by using the correction term stored in advance. Therefore, it can be corrected to a sinusoidal current having an energization angle according to the required torque only by calculation. That is, according to the present embodiment, it is possible to improve the torque characteristics while maintaining the sine and cosine drive method in which the drive noise is small, and it is possible to achieve both the improvement of the torque characteristics and the noise reduction.

[Vector control]
It is also possible to apply vector control to the SR motor control according to the above embodiment. Vector control is a method in which the current command value is divided into a magnetic flux generating component and a torque generating component, and each component is controlled independently. In vector control, in the case of three-phase drive, the motor control device first acquires the current command value of each phase of U, V, and W, and uses it as the current command value of another three axes (magnetic flux generation component: d). The shaft current Id and the torque generation component: q-axis current Iq and 0-axis current I0) are converted, and the same processing as the current control processing is performed on these three axes. Hereinafter, each phase of U, V, and W will be abbreviated as "each phase", and each axis of d, q, and 0 will be abbreviated as "each axis".

In vector control, the motor control device executes a series of vector operations at predetermined control cycles to drive the motor. In this modification, the above waveform correction is also performed within the current control cycle in which this vector operation is executed.

FIG. 8 is a block diagram showing a configuration of a motor control device 201 to which vector control is applied when the waveform correction process of the above embodiment is not performed. The motor control device 201 performs vector control on the three-phase SR motor 120, supplies a three-phase current having a sinusoidal waveform that is 120 ° out of phase with the electric angle, and drives the SR motor 120. The motor control device 201 vector-controls the SR motor 120 based on the rotation angle signal indicating the rotation angle of the rotor 123 detected by the resolver 121 and the current value supplied to each phase detected by the current sensor 212. ..

The motor control device 201 includes a coordinate conversion unit 311, a voltage command generation unit 312, a voltage command calculation unit 313, and a PWM output unit 314.

The coordinate conversion unit 311 converts the current value of each phase (U-phase current value Iu, V-phase current value Iv, W-phase current value Iw) detected by the current sensor 212 into the current of each axis (d-axis current Id, q-axis). Convert to current Iq, 0-axis current I0). The signal from the resolver 121 is used for the conversion.

The voltage command generation unit 312 performs proportional calculation (P calculation) based on the difference (deviation) between the current command signal (Id_ref, Iq_ref, I0_ref) and the dq0 current (Id, Iq, I0), and performs proportional calculation (P calculation) on three axes (d). , Q, 0) voltage command values (d-axis voltage Vd, q-axis voltage Vq, 0-axis voltage V0) are calculated.

The voltage command calculation unit 313 is provided after the voltage command generation unit 312, and the voltage command value (Vd, Vq, V0) of each axis is set to the voltage signal of each phase (U-phase control voltage Vu, V-phase control voltage). Convert to Vv, W phase control voltage Vw). The rotation angle signal from the resolver 121 is used for the conversion.

The PWM output unit 314 is provided after the voltage command calculation unit 313, and calculates the PWM duty value of each phase from the control voltages Vu, Vv, Vw of each phase. Then, the PWM output unit 314 appropriately supplies electric power to each phase according to the PWMduty value of each phase.

As a result, the SR motor 120 is vector-controlled by the motor control device 201 while feeding back the current values of each phase.

FIG. 9 is a configuration diagram of the motor control device 202 when the energization angle correction process of the above embodiment is applied. Further, FIG. 10 is a processing flow for explaining the flow of the motor control processing by vector control including the energization angle correction processing. Here, the motor control device 202 performs energization angle correction processing (frequency correction, phase difference correction, and out-of-range removal processing) for each phase with respect to the d and q-axis values (Id_ref, Iq_ref) of the current command values. )I do. Then, the difference (deviation) between the processed value and the current (Id ^* , Iq ^* ) of each axis is calculated. For the value on the 0 axis (I0_ref), the deviation is calculated as it is.

The motor control device 202 includes a coordinate conversion unit 311, a voltage command generation unit 312a, a voltage command calculation unit 313a, a PWM output unit 314, and a waveform correction unit 315. The processing of each part will be described together with the processing flow.

First, the waveform correction unit 315 converts the current command value of the d-axis and the q-axis into the current values of the U phase, the V phase, and the W phase, respectively (step S2101), and performs frequency correction in each phase (step S2102). ..

Next, the waveform correction unit 315 performs phase difference correction for the current command value after frequency correction of each phase (step S2103).

The waveform correction unit 315 performs out-of-range removal processing for the current value after phase difference correction of each phase, and for each phase, the current command values (Id_u, Iq_u, Id_v, Iq_v, Id_w, Iq_w) of the d-axis and q-axis. ) Is calculated (step S2104). The waveform correction unit 315 uses I0_ref as it is for the current command value of the 0 axis.

Next, the waveform correction unit 315 converts the processed current command values (Id_u, Iq_u, Id_v, Iq_v, Id_w, Iq_w) of each phase and the current command values (I0_ref) of the 0 axis after conversion by the coordinate conversion unit 311. The deviation (current difference value) from the dq0 current (Id ^* , Iq ^* , I0 ^* ) of the above is calculated (step S2105).

After that, the voltage command generation unit 312a performs proportional calculation based on the deviation of each phase for the dq axis and based on the obtained deviation for the 0 axis (P control), and the three-phase two-axis A voltage command value (Vd_u ^* , Vq_u ^* , Vd_v ^* , Vq_v ^* , Vd_w ^* , Vq_w ^* ) and a 0-axis voltage command value V0 ^* are generated (step S2106).

The voltage command calculation unit 313a sets the voltage command value of each phase after processing by the voltage command generation unit 312a to the voltage signal of each phase (U-phase control voltage Vu ^* , V-phase control voltage Vv ^* , W-phase control voltage Vw. ^* ) (Step S2107). The rotation angle signal from the resolver 121 is used for the conversion.

The PWM output unit 314 calculates the PWMduty value of each phase from the voltage signals Vu ^* , Vv ^* , Vw ^* of each phase (step S2108). Then, power is supplied to each phase U, V, W according to the PWMduty value of each phase, and the process is terminated.

The equation for the energization angle correction process and the phase difference correction is as follows.
First, the following formula is used to convert the current command values (Iu_ref, Iv_ref, Iw_ref) of each of the U, V, and W phases into the current command values (Id_ref, Iq_ref, I0_ref) of each of the d, q, and 0 axes. It is shown in the formulas (6) to (11).
Id_ref = (Ia × cosθ) + (Ib × sinθ) ・ ・ ・ (6)
Iq_ref = (Ia × cosθ) + (Ib × sinθ) ・ ・ ・ (7)
I0_ref = Ic ・ ・ ・ (8)
Here, Ia, Ib, and Ic are expressed by the following equations.

In the present embodiment, when the current command values (Id_ref, Iq_ref, I0_ref) for each of the d, q, and 0 axes are calculated from the current command values (Iu_ref, Iv_ref, Iw_ref) of each phase, frequency correction and phase difference are performed at the same time. The correction is performed, and the current command values (Id_u, Iq_u, Id_v, Iq_v, Id_w, Iq_w) of the d-axis and q-axis are calculated. Frequency correction and phase difference correction are performed for each phase with respect to the current command value of each axis. The formula including both processes is as follows. Here, only the U phase is shown.
Id_u = (Ia × cos ((fa × θ) + fo_u)) + (Ib × sin ((fa × θ) + fo_u)) ・ ・ ・ (12)
Iq_u = (Ia × cos ((fa × θ) + fo_u))-(Ib × sin ((fa × θ) + fao_u)) ・ ・ ・ (13)
For example, when no correction is performed, that is, when the frequency correction coefficient fa is 1 and the offset value is 0, the current command values (Id_ref, Iq_ref, I0_ref) of the above equations (6) to (8) are set. As it is, it is used in the deviation calculation process as the current command value of each axis.

<Modification example>
In the above embodiment, the maximum current command value is not changed when the energization angle is corrected. However, the maximum current command value may be changed. For example, as shown in FIG. 11A, the maximum current command value is increased so that the current density is maintained when the energization angle is decreased. As a result, as shown in FIG. 11B, high torque can be realized while maintaining the current density.

Generally, since the calorific value of each exciting coil changes depending on the current density, the maximum value (limit value) of the current that can be passed through the SR motor 120 is determined by the current density. As shown in FIG. 11A, by maintaining the current density and reducing the energization angle, the torque characteristics can be improved without changing the maximum value of the current flowing through the SR motor 120.

Further, as shown in FIGS. 12 (a) to 12 (d), the method of correcting the energization angle of the above embodiment (hereinafter referred to as the first method) and FIG. 11 (a) are shown according to the purpose. It may be configured to be used properly with the method of energization angle correction described above (hereinafter referred to as the second method).

For example, when the emphasis is on noise reduction, the energization angle correction is not performed. On the other hand, when aiming for higher torque, as shown in FIG. 12A, the energization angle is corrected by the second method. As a result, as shown in FIG. 12B, the torque characteristics can be improved by the sine wave drive method. Further, when it is desired to achieve both quietness and high torque, the energization angle is corrected by the first method as shown in FIG. 12 (c). As a result, as shown in FIG. 12 (d), the generation of negative torque is reduced, so that the efficiency of the SR motor 120 is improved. According to the first method, the torque characteristics are improved as compared with the case where the energization angle correction is not performed, and the noise can be reduced as compared with the case where the second method is used.

In this way, when each method is used properly, for example, a reception unit that accepts selection by the user is provided, and processing is performed by switching according to the selection by the user.

<Modification example>
In the above embodiment, the case where the motor control device 200 is applied to the control of the SR motor 120 has been described as an example, but the motor to be controlled is not limited to this. For example, it can be applied to a brushless motor.

Further, in the above-described embodiment, the diodes 231 to 236 may be replaced with switching elements such as IGBTs, FETs and BJTs.

Further, each part of the motor control devices 200 and 202 may be realized by hardware, may be realized by software, or may be realized by a combination of hardware and software. When realized by software, the motor control device 200 includes a CPU, a memory, and a storage device. Then, the CPU realizes each function by loading the program stored in the storage device in advance into the memory and executing the program. The program may be stored on a computer-readable medium or may be stored on a storage device connected to a network. The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, or a CD-ROM. Further, the above program may be realized by using a programmable logic device such as FPGA (Field Programmable Gate Array). The map storage unit 250 is built in the storage device.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

100: Vehicle control system, 111: Accelerator pedal, 112: Accelerator operation detector, 113: Battery, 114: Rear gear, 115: Rear wheel, 120: SR motor, 121: Resolver, 122: Stator, 123: Rotor, 124: Axis of rotation,
200: Motor control device, 201: Motor control device, 202: Motor control device, 210: Drive circuit, 211: Condenser, 212: Current sensor, 221: Switching element, 222: Switching element, 223: Switching element, 224: Switching Element, 225: Switching element, 226: Switching element, 231: Diode, 232: Diode, 233: Diode, 234: Diode, 235: Diode, 236: Diode,
240: Drive circuit control device, 241: Current command value generation unit, 242: Current detection unit, 243: Position detection unit, 244: Rotation speed detection unit, 245: Current control unit, 246: PWM output unit, 247: Advance angle Setting unit, 248: energization timing output unit, 249: gate drive unit, 250: map storage unit, 251: advance angle map, 252: frequency correction coefficient map, 253: offset value map, 255: waveform correction unit,
311: Coordinate conversion unit, 312: Voltage command generation unit, 312a: Voltage command generation unit, 313: Voltage command calculation unit, 313a: Voltage command calculation unit, 314: PWM output unit, 315: Waveform correction unit

Claims (4)

A motor control device that controls the drive of the SR motor by switching the energization of the coil corresponding to each phase of the multi-phase SR motor.
A current command value generator that generates a maximum current command value, which is the maximum value of the target value of the current flowing from the load required for the SR motor to the coils of each phase.
A current control unit that controls the current flowing through the coils of each phase is provided.
The current control unit corrects the current waveform so that the energization angle is smaller than 180 degrees when the current waveform flowing through the coils of the respective phases changes in a sinusoidal manner according to the maximum current command value. A motor control device characterized by being equipped with. The motor control device according to claim 1.
Further, a map storage unit for storing the frequency correction coefficient for each maximum current command value is provided.
The waveform correction unit corrects the frequency of the current waveform that changes in a sinusoidal shape by using the frequency correction coefficient corresponding to the generated maximum current command value, and causes the corrected coil of each phase to flow. A motor control device characterized in that the phase difference of a current that changes in a sinusoidal shape is corrected to a basic phase difference determined by the number of phases of the SR motor. The motor control device according to claim 2.
The waveform correction unit is a motor control device, characterized in that the waveform of the current waveform flowing through the coils of the respective phases after the phase difference correction, which is outside the energization range, is changed to a waveform having a current value of 0. The motor control device according to claim 2.
The SR motor is a three-phase SR motor provided with three phases of excitation coils.
A motor control device characterized in that the basic phase difference is 120 degrees.

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