JPH11285288A - Motor control device and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the fluctuations of a torque, when performing switching between sinusoidal wave control and rectangular wave control. SOLUTION: The phase and amplitude of a sinusoidal wave a1, that is the voltage waveform of current PWM sinusoidal wave control, are obtained. Also, the phase of a rectangular wave c1 for generating a torque that is equivalent to a current motor torque is obtained. The rectangular wave c1 may be regarded as a sinusoidal wave with a calculated phase and a limitless amplitude. Therefore, the phase and amplitude are simultaneously and continuously changed from a sinusoidal wave a1 into a rectangular wave c1. A PWM processing is performed to a sinusoidal wave signal with the phase and amplitude that are changing to generate the control signal of an inverter, thus obtaining a voltage waveform b1 with the middle phase and amplitude between moments before and after switching. A motor torque corresponding to the voltage waveform b1 is equal to or close to the motor torques before and after the switching.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a motor control device and a control method, and more particularly, to a method for switching between sine wave control and rectangular wave control according to the state of a motor.

[0002]

2. Description of the Related Art Conventionally, electric vehicles have attracted attention from the viewpoint of low pollution. A typical electric vehicle has a battery,
Equipped with inverter and motor. An inverter is a type of a power conversion device, and converts power obtained from a battery into power supplied to a motor by switching operation of a plurality of semiconductor elements. The motor is driven by the supplied electric power to generate a propulsive force of the vehicle. The motor control device controls the output of the motor in accordance with a driver's accelerator operation, and controls the motor by sending a switching signal instructing a switching operation to the inverter. Hereinafter, a signal that controls the conversion operation of the power conversion device, such as the switching signal, is referred to as a conversion control signal.

In motor control, sine wave control is widely and generally performed. The sine wave control is a control to make the voltage waveform of the power supplied to the motor a sine wave. The sine wave control is realized by, for example, vector control and PWM control.
In FIG. 1A, a sine wave signal of a solid line is compared with a PWM carrier of a dotted line to generate a switching signal. When the inverter performs power conversion according to the switching signal, the output voltage waveform to the motor becomes substantially a sine wave.
Although FIG. 1 shows only one-phase voltage waveform,
Actually, there are a plurality of voltage waveforms according to the configuration of the motor (the same applies hereinafter). Such sine wave control is widely used because high motor efficiency can be obtained.

[0004]

FIG. 2 shows the operating range of the motor. The horizontal axis represents the number of revolutions, and the vertical axis represents the torque. The motor can theoretically be used in the area enclosed by the dotted line. However, the back electromotive voltage of the motor is high in a high rotation and high torque region indicated by oblique lines. In this region, the back electromotive voltage is sharply increased due to a disturbance factor and easily exceeds the battery voltage. In the sine wave control, it is not easy to deal with such a back electromotive voltage. Therefore, in the conventional motor control, only an area surrounded by a solid line, that is, an area excluding a hatched portion has been used.

However, an increase in the output of the motor is required, and it is desired to use the motor even in a high rotation and high torque region. To respond to such a demand, it is conceivable to use rectangular wave control.

The rectangular wave control is a known control different from the sine wave control, and uses a rectangular wave as shown in FIG.
The peak value (voltage value) of the rectangular wave is constant. The switching signal to the inverter is generated such that the voltage waveform of the power supplied to the motor becomes this rectangular wave.

[0007] According to the rectangular wave control, the motor can be easily controlled even in a high rotation and high torque region where sine wave control is difficult.
Therefore, high efficiency sine wave control is usually performed,
It is considered that a motor having both high efficiency and high output can be realized by performing rectangular wave control in the high torque region.

However, when switching between the sine wave control mode and the rectangular wave control mode is performed, the problem of torque fluctuation at the time of mode switching occurs as described below. As an example, consider a case where mode switching is performed at point x2 in the process of changing the operating state from point x1 to point x3 in FIG. At point x2, a switch from sine wave control to rectangular wave control that generates equivalent torque should occur. FIG. 3 shows the voltage command value before the triangular wave comparison. In FIG. 3A, the sine wave a and the rectangular wave c generate the same torque, and the two waveforms have different phases.

In the actual mode switching, first, the sine wave a is
Switching to rectangular waves b having the same phase. This is because the phase of the supply voltage to the motor cannot be changed instantaneously.
Then, the phase adjustment under the rectangular wave control mode is performed, and the rectangular wave b is changed to the rectangular wave c after switching.

However, when such a switching process is performed,
A torque fluctuation occurs at the time of switching. This is because, for a sine wave a and a rectangular wave b having the same phase, the rectangular wave b generates a larger torque.

Referring to FIG. 3B, as shown by the phase-torque line (solid line) in the figure, the motor torque of the rectangular wave control is determined by the phase of the rectangular wave. This is because the wave height of the rectangular wave is constant. It is assumed that the mode switching is performed while the sine wave control is being performed in the state of the point a. As described above, since the phase of the power supplied to the motor cannot be changed instantaneously, the operation state first moves from point a to point b. Then, by adjusting the phase of the rectangular wave, the state of the motor changes along the phase-torque line. When the operating state reaches the point c, the same torque as before switching is obtained. In the above switching process, a torque fluctuation corresponding to the torque difference between the points a and b occurs.

The same applies to the case where switching from rectangular wave control to sine wave control is performed. In FIG. 3B, first, the phase of the rectangular wave moves from the starting point c to the point b by the phase adjustment in the rectangular wave control mode. Then, after the operation state reaches the point b, switching from the rectangular wave control to the sine wave control is performed. In this switching process, a torque fluctuation corresponding to the torque difference between the point b and the point a occurs.

As described above, when the mode switching between the sine wave control and the rectangular wave control is performed, torque fluctuation occurs during the switching process.
This torque variation affects the behavior of the vehicle, and is transmitted to the driver as uncomfortable. Therefore, it is desired to prevent such a torque fluctuation from occurring.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to provide a motor control device and a control method capable of smoothly switching between sine wave control and rectangular wave control with small torque fluctuation. It is in.

[0015]

SUMMARY OF THE INVENTION The present invention relates to a motor control device for controlling a motor by sending a conversion control signal to a power conversion unit for converting power obtained from a power supply into power supplied to the motor. A sine wave control unit for generating a conversion control signal for converting the voltage waveform of the supplied power into a sine wave; a rectangular wave control unit for generating a conversion control signal for converting the voltage waveform to a rectangular wave; According to at least one, a mode switching unit that switches between the sine wave control mode and the rectangular wave control mode, and at the time of mode switching, from the sine wave before switching to the square wave after switching, or from the sine wave before switching. A switching intermediate control unit that generates a conversion control signal that continuously changes the voltage waveform toward the switched rectangular wave, wherein the switching intermediate control unit makes the square wave infinite or sufficiently large. It is regarded as a sine wave having an amplitude, the phase and amplitude simultaneously and continuously changes in a sinusoidal voltage waveform, characterized in that the pre-switching voltage waveform goes close to the voltage waveform after switching.

Preferably, the sine wave control unit performs a PWM process based on a sine wave signal to generate a conversion control signal, and the switching intermediate control unit has an intermediate phase and amplitude between voltage waveforms before and after switching. A conversion control signal is generated by performing a PWM process based on the modified sine wave signal.

As described above, a rectangular wave can be regarded as a sine wave having an infinite or sufficiently large amplitude. As a result, the voltage waveform before switching and the voltage waveform after switching are regarded as two sine waves having different phases and amplitudes. Therefore, the voltage waveform before switching is made closer to the voltage waveform after switching by simultaneously and continuously changing the phase and amplitude of the sine voltage waveform. In switching from a sine wave to a square wave, the phase of the sine wave before switching is continuously brought close to the phase of the square wave after switching, and at the same time, the amplitude of the sine wave before switching is infinite or sufficiently large. Continually. The reverse process is performed when switching from a rectangular wave to a sine wave. As described above, unlike the conventional case where the phase adjustment of the rectangular wave is performed during the switching, the phase and amplitude of the sine wave are changed simultaneously and continuously during the switching according to the present invention. The voltage waveform before the switching shifts to the voltage waveform after the switching without any fluctuation. As a result, the mode can be smoothly switched with little influence on the vehicle behavior, and it is possible to prevent the driver from feeling uncomfortable.

The present invention may be applied to both switching from sine wave control to rectangular wave control and vice versa. Further, it may be applied to only one of the switching.

Another aspect of the present invention is a motor control method for controlling a motor by adjusting the power supplied to the motor, the method comprising: A mode switching step of switching the voltage waveform to a rectangular wave control mode according to the state of the motor, in which the rectangular waveform is a sine wave having an infinite or sufficiently large amplitude. The voltage waveform is changed from a sine wave before switching to a square wave after switching, or from a square wave before switching to a sine wave after switching by a continuous change in the phase and amplitude of the sine voltage waveform. It is characterized by approaching. According to this aspect,
The above effects of the present invention can be obtained in the form of a motor control method.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention (hereinafter, referred to as embodiments) will be described below with reference to the drawings.

First, the principle of mode switching of the present embodiment will be described with reference to FIG. Here, switching processing from the sine wave control mode to the rectangular wave control mode will be described. However, the reverse mode switching processing is almost the same except that the switching direction is different.

In FIG. 4A, a sine wave a1 is a voltage waveform before mode switching, and a rectangular wave c1 is a voltage waveform after mode switching. The sine wave a1 and the rectangular wave c1 have different phases, and both voltage waveforms generate the same torque.

In the present embodiment, it is considered that "the rectangular wave c1 is a sine wave having infinite or sufficiently large amplitude, and its peak value is limited by the voltage upper limit value (maximum battery voltage)". Thus, the voltage waveforms at the start and end of switching are both sine waves, and the two sine waves can be considered to have different phases and amplitudes.

Before starting the mode switching, the phase and amplitude of the sine wave a1 are set to the switching initial values. Also, a square wave c
The phase of 1 is set as the switching target phase, and the infinite amplitude is set as the switching target amplitude.

When the mode switching is started, the phase and the amplitude of the voltage waveform are changed simultaneously and continuously from the switching initial value to the switching target value. That is, the phase of the sine wave is continuously changed from the initial phase to the target phase, and at the same time, the amplitude of the sine wave is continuously changed from the initial amplitude to the infinite amplitude.

The voltage waveform b1 in FIG. 4 is a voltage waveform during switching. This voltage waveform b1 is a sine wave having an intermediate phase and amplitude between the initial stage of switching and the target of switching. Since the voltage value is limited at the maximum battery voltage as in the case of the rectangular wave, a part of the waveform is flat. The voltage waveform b1 in the course of such a change includes a sine wave a1 and a square wave c1 before and after switching.
And produce a motor torque equal to or close to them. Therefore, it is possible to change the voltage waveform from the sine wave a1 to the rectangular wave c1 without causing a large torque fluctuation.

Referring to FIG. 4B, a point a1 is an operation state in the sine wave control mode before switching. Point c1 is
This is an operation state in the rectangular wave control mode after switching. Point a1
And at point c1, the torques are equal but the phases are different. In the conventional mode switching, switching from the sine wave control to the rectangular wave control is first performed, and the operating state moves from the point a1 to the point b1 by this switching. Then the phase is adjusted by the square wave control,
The operating state moves from point b1 to point c1 along the phase-torque line. Conventionally, a torque fluctuation due to such a trajectory of the operating state occurs.

On the other hand, in the present embodiment, the rectangular wave in the state of the point c1 is regarded as a sine wave having an infinite amplitude. Then, due to the continuous change of the phase and the amplitude of the voltage waveform as shown in FIG. 4A, the operating state shifts from point a1 to point c1 by drawing a locus that is almost a straight line as shown by a dotted line. . During this time, the voltage waveform is a sine wave until immediately before the operating state reaches the point c1. As is clear from FIG. 4B, according to the present embodiment, it is possible to reduce torque fluctuation at the time of mode switching.

FIG. 5 shows a drive system of an electric vehicle equipped with the motor control device of the present embodiment. Battery 2 is connected to motor 6 via inverter 4. The motor 6 is a permanent magnet type three-phase AC motor. The motor 6 is connected to wheels 10 via a reduction gear 8. A direct current is supplied from the battery 2 to the inverter 4. This DC current is converted into an AC current by the inverter 4, and the motor 6 rotates with the power supplied from the inverter 4. Then, the output torque of the motor 6 is transmitted to the wheels 10 via the reduction gear 8, and the vehicle runs.

The motor ECU 12 is a device for controlling the torque of the motor 6 by sending switching signals (Su, Sv, Sw) to the inverter 4. Inverter 4
Is provided with a plurality of semiconductor elements, and power conversion is performed by a switching operation of the semiconductor elements. The switching signal is a signal for causing the semiconductor element to perform a necessary switching operation, that is, a signal for causing the inverter 4 to perform a necessary power conversion. In the present embodiment, this switching signal corresponds to the conversion control signal of the present invention.

A motor current (Iu, Iv, Iw) detected by the current sensor 14 is input to the motor ECU 12. The motor current is a current supplied from the inverter 4 to the motor 6. The rotation angle sensor 16 is connected to the motor 6.
(Θ: rotation angle (position) of the rotor with respect to the stator) is sent to the motor ECU 12.
The motor rotation speed is obtained from the rotor angle signal. further,
A signal indicating an accelerator operation amount is input from the accelerator 18 to the motor ECU 12.

In the motor ECU 12, a torque determining unit 20
Determines the torque to be output by the motor 6 based on the accelerator operation amount and the motor rotation speed (vehicle speed), and obtains a torque command T * corresponding to the output torque. Torque command T
* Indicates that the sine wave control unit 22 and the rectangular wave control unit 24
It is used for generating a switching signal to the inverter 4. In the present embodiment, as shown in FIG. 6, the sine wave control mode and the rectangular wave control mode are switched according to the motor speed N and the motor torque T.

In the sine wave control mode, the sine wave control unit 22
Generates a switching signal. Sine wave controller 2
2 is a known vector control unit 26 and a PWM control unit 2
8 to generate a switching signal pulse-width modulated by the vector control and the PWM control. This process
Since it is widely used for controlling an electric vehicle and is well known, detailed description is omitted. Schematically, the torque command T
The d-axis current command Id * and the q-axis current command Iq * on the dq-axis coordinates are obtained from *. On the other hand, the motor current Iu,
Excitation current Id and torque current Iq are obtained from Iv and Iw. Voltage commands Vd, Vq are obtained based on these command values and current values, and further, voltage commands Vd, Vq
Is performed. FIG. 1A shows the voltage signal at this stage. The voltage signal after the coordinate conversion is compared with a PWM carrier having a predetermined shape to generate pulse width modulated switching signals Su, Sv, and Sw. When the inverter 4 performs power conversion according to the switching signal, the voltage waveform of the motor current corresponds to a sine wave. Then, the torque determined by the torque determination unit 20 is output by the motor 6.

On the other hand, in the rectangular wave control mode, a switching signal is generated by the rectangular wave control unit 24. In the rectangular wave control, the wave height of the rectangular wave is constant, and the cycle is determined by the motor rotation speed (vehicle speed). Therefore, the phase of the rectangular wave is to be controlled, and the phase determines the torque. The reference of the phase of the rectangular wave is the rotor angle θ. In the rectangular wave control, the excitation current Id is calculated from the motor currents Iu, Iv, Iw.
And the torque current Iq. Then, the current torque T of the motor is obtained from these currents Id and Iq. The torque T is compared with the torque command T * to determine the phase of the rectangular wave. The phase of the rectangular wave is added to the rotor angle θ, and the switching signal Su,
Sv and Sw are generated. When the inverter 4 performs power conversion according to the switching signal, the voltage waveform of the motor current corresponds to a rectangular wave. Then, the torque determined by the torque determination unit 20 is output by the motor 6.

The purpose of selectively using the two control modes is to increase the motor output, as described above. In FIG. 6, in a region below the switching line m, it is preferable to control the motor in a highly efficient sine wave control mode. However, in a high rotation and high torque region beyond the switching line m, the back electromotive voltage of the motor is high. In this region, when the back electromotive voltage sharply rises due to a disturbance factor such as sudden operation of the accelerator, the back electromotive voltage exceeds the battery voltage, and the torque is likely to decrease. In the sine wave control, it is not easy to deal with such a back electromotive voltage. Therefore, in a region above the switching line m, the motor is controlled in the rectangular wave control mode. With square wave control, high rotation, which is difficult to control with sine wave,
The motor can be easily controlled even in the high torque range. In this manner, motor control having both high efficiency and high output is possible.

The above-described mode switching is performed by an instruction from the switching instruction section 30. As a feature of this embodiment, a mode transition period is provided at the time of mode switching, and the motor is controlled by the switching intermediate control unit 32 during the mode transition period,
The voltage waveform of the motor current is modified as shown in FIG. Hereinafter, the processing at the time of the mode transition will be described with reference to the flowcharts of FIGS.

FIG. 7 shows a switching process from the sine wave control mode to the rectangular wave control mode. The switching instruction unit 10
By monitoring the motor torque T and the motor speed N, FIG.
It is determined whether the torque T and the rotation speed N on the switching line m are detected (S10). Torque T on line m
The determination in S10 is continued until the rotation speed N is detected, and the sine wave control mode continues during this time. S10 is Y
When the status becomes ES, the switching instruction unit 30 turns on the switching flag (S12).

When the switching flag is turned on, both the sine wave control unit 22 and the rectangular wave control unit 24 perform calculation processing. The sine wave controller 22 calculates the phase and amplitude of the current motor current voltage waveform. In the normal sine wave control mode, the phase and amplitude of the sine voltage waveform are not determined. Here, the phase and amplitude are obtained for the following switching intermediate control. On the other hand, the rectangular wave controller 24 calculates the phase of the rectangular wave necessary to generate a torque having the same magnitude as the current motor torque T (S14). A sine wave and a rectangular wave that generate the same torque have different phases. Therefore, the phase calculated in S14 is different from the current sine wave phase. In order to easily obtain these values, it is also preferable to create a map representing the phase and amplitude of a sine wave or a rectangular wave on the switching line m in FIG. 6 in advance.

Next, in S16 to S20, the voltage waveform of the motor current is transformed from the current sine wave to a rectangular wave having the phase calculated in S14, as described with reference to FIG. First, the current phase and amplitude of the sine wave are set to the switching initial values. Further, the phase of the rectangular wave calculated in S14 is set as the switching target phase. Further, an infinite amplitude is set as the switching target amplitude. However, here, a sufficiently large amplitude that can be regarded as equivalent to infinity is set as the switching target value. That is, the target amplitude is set to be sufficiently large so that the sine wave having the target amplitude has substantially the same shape as the rectangular wave.

In S16, the phase of the switching intermediate control unit 32
The amplitude adjuster 34 brings both the amplitude and the phase closer by a predetermined width from the switching initial value to the switching target value. Then, a switching signal is generated based on the approached amplitude and phase (S18). Here, the phase / amplitude adjustment unit 34 generates a voltage signal having the phase and amplitude determined in S16. And this voltage signal is
The PWM control unit 36 compares the PWM signal with a PWM carrier having a predetermined shape, thereby generating switching signals Su, Sv, and Sw. It should be noted that the PWM control unit 36 may also be used as the PWM control unit 28 of the sine wave control unit 22.

The inverter 4 performs power conversion according to the switching signal. As a result, the voltage waveform of the motor current is as shown in the middle part of FIG.
Since the voltage value is limited at the maximum battery voltage, the voltage waveform b1 is a sine wave having a partially flat portion. This voltage waveform b1 generates a torque equal to or close to the sine wave a1.

Next, the phase / amplitude adjustment unit 34 determines whether or not the current phase and amplitude obtained in S16 have reached the switching target value (S20). If S20 is NO, S1
6, the amplitude and the phase are made closer to the switching target value. In this way, the same processing is continued until the amplitude and the phase reach the switching target value.

Here, the transition period from the switching initial value to the switching target value should be a sufficiently short time.
About 100 msec is preferable. If the transition period is as long as this, it is considered that the accelerator operation amount does not significantly change. Therefore, it is considered that equivalent motor torque should be generated before and after the switching. In S16 described above, the phase and the amplitude are made closer to the target values at every control interval. Preferably, the change width of the phase and the amplitude in S16 is set so that the phase and the amplitude simultaneously reach the target values.

When the determination in S20 is YES in FIG. 7, the switching instruction unit 30 turns off the switching flag (S22). Then, the rectangular wave control mode is set (S24). Thereafter, motor control is performed by the rectangular wave control unit 24.

FIG. 8 is a time chart showing changes in the phase and amplitude of the voltage waveform when the processing of FIG. 7 is performed.
When the switching flag is turned on, the phase and amplitude of the voltage waveform are simultaneously and continuously changed toward the target value. Then, when the phase and the amplitude reach the target values simultaneously, the switching flag is turned off. Thereafter, rectangular wave control is performed.

Next, with reference to FIG. 9, a description will be given of a process of switching from the rectangular wave control mode to the sine wave control mode. The switching process in FIG. 9 is almost the same as the switching process from the sine wave to the rectangular wave described with reference to FIG. However, the directions of the phase and amplitude changes at the time of switching are opposite.

The switching instruction unit 30 monitors the motor torque T and the motor rotation speed N, and determines whether the torque T and the rotation speed N on the switching line m in FIG. 6 have been detected (S30). While the determination in S32 is NO, the rectangular wave control mode continues. If S30 is YES, the switching instruction unit 30 turns on the switching flag (S32).

When the switching flag is turned on, the rectangular wave controller 24 calculates the current rectangular wave phase and sends it to the switching intermediate controller 32. The sine wave control unit 22 calculates the phase and amplitude of the sine voltage waveform necessary to generate a torque equivalent to the current motor torque T (S34). Here, in order to easily obtain these values, it is preferable to create a map representing the phase and amplitude of the sine wave or the rectangular wave on the switching line m in FIG. 6 in advance.

Next, the current phase of the rectangular wave is set to the switching initial value. The switching initial value of the amplitude is set to a sufficiently large amplitude that can be regarded as equivalent to infinity. This amplitude value is also used at the time of switching control from the sine wave to the rectangular wave, and is used instead of infinity. Further, the phase and the amplitude of the sine wave obtained in S34 are respectively set as the switching target values.

In S36 to S40, the phase and the amplitude are sequentially changed from the above-mentioned initial switching value to the target switching value.
In S36, the phase and the amplitude are brought closer to the target values by a predetermined width. A voltage signal corresponding to the phase and the amplitude determined in S36 is obtained, and this voltage signal is compared with the PWM carrier to generate a switching signal (S38). The above control is continued until the phase and amplitude reach the target values. With such control, the voltage waveform changes in the same manner as in the above-described switching from the sine wave to the rectangular wave, but in the opposite direction. Therefore, also in this case, the torque fluctuation during the mode transition period is small.

When the phase / amplitude adjustment unit 34 determines that the phase and amplitude have reached the target values in S40, the switching instruction unit 30 turns off the switching flag in S42 (S42). Then, the sine wave control mode is set (S44). Thereafter, the sine wave control unit 22 controls the motor.

The preferred embodiment of the present invention has been described above. According to the present embodiment, during the mode switching, the PWM sine wave control is performed while simultaneously and continuously shifting the phase and the amplitude. On the other hand, conventionally, during the mode switching, the phase adjustment in the rectangular wave control mode is performed, which causes a torque fluctuation. According to the present embodiment, by performing control based on a sine wave as shown in FIG. 4 during the mode transition period, torque fluctuation at the time of mode switching can be reduced. As a result, the mode can be smoothly switched with little influence on the vehicle behavior, and it is possible to prevent the driver from feeling uncomfortable.

A modification of the embodiment will be described. Although the power converter is an inverter in the present embodiment, it goes without saying that a power converter other than the inverter can be similarly applied to the present invention. Further, the motor may be a motor other than the permanent magnet type synchronous motor. Further, another control not using the PWM control may be performed. In addition, it is preferable that the control of the present invention is also performed during regenerative braking.

The present invention is also suitably applied to a hybrid vehicle. A hybrid vehicle is a type of electric vehicle and has both an electric motor and an internal combustion engine. The present invention can be suitably applied to the control of the motor of this hybrid system. In addition, the present invention is applicable to control of any motor not for electric vehicles.

[Brief description of the drawings]

FIG. 1 is a diagram showing a voltage waveform of a motor current by sine wave control and rectangular wave control.

FIG. 2 is a diagram showing an operation range of motor control of a conventional electric vehicle.

FIG. 3 is a diagram showing switching from conventional sine wave control to rectangular wave control.

FIG. 4 is a diagram illustrating switching processing from sine wave control to rectangular wave control in the embodiment of the present invention.

FIG. 5 is a diagram illustrating a configuration of a motor control device according to an embodiment of the present invention.

FIG. 6 is a diagram showing an operation region in which a sine wave control mode and a rectangular wave control mode are set.

FIG. 7 is a diagram showing a switching process from a sine wave control mode to a rectangular wave control mode in the system of FIG. 5;

8 is a time chart showing a process of changing a phase and an amplitude of a voltage waveform when the processing of FIG. 7 is performed.

FIG. 9 is a diagram showing a switching process from a rectangular wave control mode to a sine wave control mode in the system of FIG. 5;

[Explanation of symbols]

2 battery, 4 inverters, 6 motors, 12 motor ECU, 14 current sensor, 16 rotation angle sensor,
Reference Signs List 20 torque determination unit, 22 sine wave control unit, 24 rectangular wave control unit, 26 vector control unit, 28, 36 PWM
Control unit, 30 switching instruction unit, 32 switching intermediate control unit, 34
Phase / amplitude adjustment unit.

Claims (3)

[Claims] 1. A motor control device for controlling a motor by transmitting a conversion control signal to a power converter for converting power obtained from a power supply into power supplied to the motor, wherein a voltage waveform of the power supplied to the motor is represented by A sine wave control unit for generating a conversion control signal for converting the voltage waveform into a rectangular wave; a rectangular wave control unit for generating a conversion control signal for converting the voltage waveform into a rectangular wave; and a sine wave according to at least one of the motor speed and the motor torque. A mode switching unit for switching between the control mode and the rectangular wave control mode, and in switching the mode, from a sine wave before switching to a square wave after switching, or from a sine wave before switching to a square wave after switching. A switching intermediate control unit that generates a conversion control signal for continuously changing the voltage waveform, wherein the switching intermediate control unit is a sine wave having an infinite or sufficiently large amplitude of the rectangular wave. A motor control device characterized in that the voltage waveform before switching is made closer to the voltage waveform after switching by simultaneously and continuously changing the phase and amplitude of the sine voltage waveform. 2. The apparatus according to claim 1, wherein the sine wave control unit performs a PWM process based on a sine wave signal to generate a conversion control signal, and the switching intermediate control unit includes a voltage waveform before and after switching. A motor control device that generates a conversion control signal by performing a PWM process based on a modified sine wave signal having an intermediate phase and amplitude. 3. A motor control method for controlling a motor by adjusting power supplied to a motor, comprising: a sine wave control mode in which a voltage waveform of the power supplied to the motor is a sine wave; And a mode switching step of switching the rectangular wave control mode according to the state of the motor. In this mode switching step, the rectangular wave is regarded as a sine wave having infinity or a sufficiently large amplitude, and a sine voltage waveform By continuously changing the phase and amplitude of the above, the voltage waveform is brought closer from the sine wave before switching to the square wave after switching, or from the square wave before switching to the sine wave after switching. Motor control method.