KR101216464B1 - Motor controlling aparatus and method of the same - Google Patents

Abstract

The present invention provides an inverter for applying a motor driving voltage to a motor based on a control signal, a current detecting unit disposed between the inverter and the motor, for detecting a motor driving current applied to the motor, and the motor driving current and speed. A motor comprising a control unit for generating the control signal based on any one of a plurality of pulse width modulation schemes and outputting the control signal to the inverter according to the voltage command calculated based on the command and the voltage modulation index calculated from the DC link voltage. The present invention relates to a control apparatus, and generates a control signal based on any one of a plurality of pulse width modulation schemes according to the calculated voltage modulation index, thereby reducing harmonic distortion caused by switching, thereby improving stability of the system.

Description

Motor control device and its control method {MOTOR CONTROLLING APARATUS AND METHOD OF THE SAME}

The present invention relates to a motor control apparatus and method, and more particularly, to a motor control apparatus and method for stably controlling the motor by reducing the loss of the motor through the control of the modulation method of the inverter.

Inverter is a power converter that generates AC voltage of variable voltage and variable frequency from a constant or variable DC power supply. It drives motors used in electric appliances such as washing machines, refrigerators, and air conditioners due to energy saving and ease of output control. Let's do it.

In order to efficiently control the motor using the inverter circuit, a method of detecting a phase current applied to the motor and controlling the current applied to the motor according to the pulse width modulation (PWM) method is used.

The conventional motor driving method uses only one of the voltage modulation methods to switch the power switching element so that the voltage command output from the current controller is applied to the motor. Therefore, it has inherent harmonic distortion factor (HDF) characteristics according to the set voltage modulation scheme, and the harmonic distortion factor increases as the voltage modulation index increases, thereby reducing the efficiency of the motor. Therefore, there is a problem that the stability of the system of the electrical appliances such as a washing machine, a refrigerator, an air conditioner employing the motor and the motor drive method.

An object of the present invention is to provide a motor control apparatus and a method of controlling the same, which improve the stability of the system when controlling the operation of the motor.

Another object of the present invention is to provide a motor control apparatus and a control method thereof for reducing a motor loss in controlling a motor using a sensorless algorithm.

Another object of the present invention is to provide a motor control apparatus and a control method thereof that reduce the loss of the motor in controlling the motor by using the position and speed information detected from the sensor.

In order to solve the above problems, the motor control apparatus according to an embodiment of the present invention is disposed between the inverter, the inverter and the motor for applying a motor driving voltage to the motor based on a control signal, the motor Based on any one of a plurality of pulse width modulation schemes according to a current detection unit for detecting an applied motor drive current, and a voltage command calculated based on the motor drive current and speed command and a voltage modulation index calculated from a DC link voltage. And a control unit for generating the control signal and outputting the control signal to the inverter. The plurality of pulse width modulation schemes are at least two selected from an optimal voltage modulation scheme, a sinusoidal voltage modulation scheme, a space vector pulse width modulation scheme, and a discontinuous pulse width modulation scheme.

The control unit may select the spatial vector pulse width modulation method when the voltage modulation index is smaller than a predetermined reference modulation index, and select the discontinuous pulse width modulation method when the voltage modulation index is larger than the reference modulation index. The reference modulation index is set as a modulation index of the point where the harmonic distortion curves for each modulation scheme intersect.

When the motor control device includes a sensor, the control unit receives the speed command and the speed of the motor or the position of the rotor provided in the motor and outputs a current command, the current command and the A pulse for generating the control signal and outputting the control signal to follow the voltage command by synthesizing a valid voltage vector that can be output from the inverter during a current control unit and a control period Ts that receives a detection current and outputs the voltage command. And a width modulation controller.

The control unit is connected to the current detection unit, the stop coordinate conversion unit for converting the current detected by the current detection unit to the stationary coordinate system current and the stop based on the phase value estimated from the calculated position of the rotor And a synchronous coordinate converter configured to convert a coordinate system current into a synchronous coordinate system current and feed back the synchronous coordinate system current to the current controller.

When the motor control device does not have a sensor, the control unit receives the motor driving current, and calculates the speed of the motor and the position of the rotor provided in the motor, the speed command and the calculation speed A speed control unit for receiving a current command, outputting a current command, a current control unit for receiving the current command and the detected current, and outputting the voltage command, and synthesizing effective voltage vectors output from the inverter during a control period Ts; And a pulse width modulation controller configured to generate the control signal to follow the voltage command and output the generated control signal to the inverter.

The control unit is connected to the current detection unit, a stop coordinate converter for converting the current detected by the current detection unit into the stationary coordinate system current and the stationary coordinate system current to the synchronous coordinate system current, and converts the synchronous coordinate system current to the It may include a synchronous coordinate converter for feeding back to the current control unit, the input to the calculator.

The control unit is disposed between the current detection unit and the pulse width modulation control unit, and further includes a synchronous coordinate inverse transform unit for converting a synchronous coordinate system voltage command into a stationary coordinate system voltage command based on the phase value.

The current detection unit may be a current transducer connected between the inverter and the motor to continuously detect the motor driving current.

In order to solve the above problems, a converter for converting commercial AC power to output a DC voltage, a smoothing unit for smoothing the DC voltage, and an inverter for converting the smoothed DC voltage to apply a motor driving voltage to the motor. The control method of the motor control apparatus according to an embodiment of the present invention includes detecting a motor driving current applied to the motor, receiving a speed command, based on the motor driving current and the speed command. Calculating the voltage command, generating a control signal based on any one of a plurality of modulation schemes according to the voltage command and the voltage modulation index calculated from the DC link voltage, and outputting the control signal to the inverter. It includes.

The calculating of the voltage command may include detecting a speed of the motor or a position of a rotor provided in the motor, calculating a current command based on the speed command and the detection speed, and the current command and the detection. And calculating the voltage command based on the current.

The calculating of the voltage command may include calculating a speed of the motor and a position of the rotor provided in the motor, calculating a current command based on the speed command and the calculation speed, and the current command and the detection. And calculating the voltage command based on the current.

The generating of the control signal may include calculating the voltage modulation index from the voltage command and the DC link voltage of the inverter, comparing the calculated voltage modulation index with a preset reference modulation index, and the comparison result. The method may include selecting one of a plurality of modulation schemes and generating the control signal according to the selected modulation scheme.

The motor control apparatus and control method according to the present invention generates a control signal based on any one of a plurality of pulse width modulation schemes according to the calculated voltage modulation index, thereby reducing the harmonic distortion caused by switching to improve the stability of the system. Let's do it.

The motor control apparatus and control method according to the present invention calculates the speed of the motor and the position of the rotor provided in the motor, and controls the speed and current of the motor from the detected position of the rotor, respectively, to provide current and voltage commands. Outputs and generates a control signal to follow the voltage command, thereby reducing the loss of the motor.

Motor control apparatus and control method according to the present invention, by controlling the speed and current of the motor from the detected position of the rotor to output current and voltage command, respectively, and generates a control signal to follow the voltage command, the motor Reduces the loss.

1 is a block diagram schematically showing a configuration of a general motor control apparatus to which the present invention is applied;
2 is a result diagram showing harmonic distortion rate according to a voltage modulation index in a space vector voltage modulation method and a discontinuous voltage modulation method.
3 is a detailed block diagram of a control unit according to an embodiment of the present invention;
4 is a detailed block diagram of a control unit according to another embodiment of the present invention;
5 is a flowchart of a control method of the motor control apparatus according to FIG. 3,
6 is a flowchart of a control method of the motor control apparatus according to FIG. 4.

Hereinafter, a motor control apparatus and a control method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing a configuration of a general motor control apparatus to which the present invention is applied. The motor control apparatus includes a converter 200 for converting a commercial AC power supply 100 to output a DC voltage, and the DC A smoothing unit 300 for smoothing a voltage, an inverter 400 for converting the smoothed DC voltage to apply a motor driving voltage to the motor 500, and detecting a motor driving current applied to the motor 500; And a control unit 700 for outputting a control signal to the inverter 400 to drive the motor 500.

In the motor control apparatus according to the present invention, the control unit 700 is a plurality of pulse width modulation scheme in accordance with the voltage modulation index calculated from the voltage command and the DC link voltage calculated based on the motor driving current and the speed command. The control signal is generated based on any one of the control signals and output to the inverter. The plurality of pulse width modulation methods include an optimal voltage modulation (Optimal Volatge Modulation) method, a sinusoidal ulse width modulation (SPWM) method, a space vector pulse width modulation (SVPWM) method, and a discontinuous pulse width method. Two or more of the modulation (DPWM: Discrete Pulse Width Modulation) methods are selected.

The optimal voltage modulation method calculates in advance a PWM switching pattern for generating an output voltage having a fundamental wave size and stores it in a memory, and reads the PWM switching pattern according to an operation state of a motor to perform on / off of a switching device. . The optimum voltage modulation method can optimize the control of the fundamental wave output voltage and the desired performance index, so that the utilization of the input DC voltage is good and the switching frequency can be optimized. However, since the optimal voltage modulation method calculates and uses the switching pattern in a steady state in advance, it is difficult to apply the system in which fast dynamic characteristics are required because the DC output voltage does not change or the desired output voltage cannot be generated accurately in the transient state.

The sinusoidal voltage modulation method performs on / off of each phase switch in an inverter by comparing a voltage reference of each phase with a triangular carrier wave in real time. In the sinusoidal voltage modulation scheme, since the switching frequency of the inverter is the same as the frequency of the triangular carrier, the harmonic distribution of the voltage generated by the switching is constant, so that it is easy to design a low pass filter for removing the harmonics. In addition, the sinusoidal voltage modulation method is excellent in dynamic characteristics because it is controlled in units of sampling time unlike the optimum voltage modulation method. However, the sinusoidal voltage modulation method has a disadvantage in that the maximum fundamental wave voltage that can be linearly obtained is small as Vdc / 2.

The space vector voltage modulation scheme expresses a voltage command as a space vector in a complex space and modulates the voltage represented by the space vector. The space vector voltage modulation method obtains the largest AC voltage for a given DC voltage, and when the modulated voltage is applied to the motor, harmonics included in the output current or torque are smaller than other modulation methods.

The discontinuous voltage modulation scheme is a kind of space vector voltage modulation scheme, and switches only two switching elements of the three-phase switching element within one period. The discontinuous voltage modulation method can reduce the switching loss of the inverter, but the disadvantage is that the amount of harmonics included in the current is increased when the voltage modulation index is small.

Hereinafter, the control unit 700 generating a control signal based on one of the space vector voltage modulation method and the discrete voltage modulation method among the plurality of modulation methods according to the calculated voltage modulation index. However, the present invention is not limited to the space vector voltage modulation method and the discontinuous voltage modulation method, but includes all of the plurality of modulation methods.

2 is a result diagram showing harmonic distortion rate according to a voltage modulation index in a space vector voltage modulation method and a discontinuous voltage modulation method. The modulation method is a space vector pulse width modulation method and a discontinuous pulse width modulation method. The voltage modulation index m is given by Equation 1 below.

Referring to Figure 1, V _{s , rms} ^peak at the voltage modulation index (m) Is the peak value of the root mean squqre (rms) of the voltage command Vs , and V _DC is the voltage across the DC link capacitor in the smoothing unit 300. As shown in FIG. 2, when the voltage modulation index is smaller than the reference modulation index, the spatial vector pulse width modulation method has a smaller harmonic distortion rate. On the other hand, when the voltage modulation index is higher than the reference modulation index, the discontinuous pulse width modulation method has a smaller harmonic distortion factor (HDF).

The control unit 700 selects the spatial vector pulse width modulation method when the voltage modulation index is smaller than a preset reference modulation index, and selects the discontinuous pulse width modulation method when the voltage modulation index is larger than the reference modulation index. The reference modulation index is set to a modulation index of the point where the harmonic distortion curves cross each modulation method.

The current detection unit 600 is a current transducer connected between the inverter 400 and the motor 500 to continuously detect the motor driving current. The current transducer detects the motor driving current, converts the motor driving current into a voltage signal, and outputs the converted voltage signal to the control unit 700. In addition, the current transducer detects the motor driving current in the entire section of the pulse width modulation. For example, in the case of a three-phase motor, the current detection unit 600 detects and outputs the currents Ia, Ib, and Ic applied to the three phases to the control unit 700. The control unit 700 generates an interrupt signal to sample a voltage signal according to the detected motor driving current.

3 is a detailed block diagram of a control unit according to an embodiment of the present invention. The control unit 700 of the control device for driving the motor controls the driving of the motor by using a sensorless algorithm. This is because the motor provided in the compressor used in the electrical appliance such as a refrigerator and an air conditioner does not include a sensor due to difficulty in mounting. The sensorless algorithm calculates the position of the rotor to allow the user to drive the motor at a desired speed.

 The control unit 700 includes a calculator 710, a speed controller 720, a current controller 730, and a pulse width modulation controller (hereinafter, referred to as a PWM controller) 740. The control unit 700 may further include a synchronous coordinate phase converter 750 and a synchronous coordinate reverse return unit 760.

The calculation unit 710 receives the motor driving current from the synchronous coordinate phase conversion unit 750, and calculates the speed ω of the motor and the position of the rotor provided in the motor.

The speed control unit 720 receives the speed command and the operation speed and outputs a current command. The speed controller 720 may include a comparator (not shown) for comparing a speed command ω ^* desired by the user with an estimated speed ω calculated by the calculator 710, and a first proportional integral controller ( Proportional Integral Controller; PI) (having a not shown), and the difference between the speed reference (ω ^*) and receiving the estimated input speed (ω), the speed reference (ω ^*) and the estimated speed (ω), that is the speed The error is proportionally integrated to generate a q-axis current command I ^* q, and output it to the current controller 730.

The current controller 730 receives the current command and the detected current and outputs the voltage command. The current controller 730 receives the q-axis current command I ^* q and the d-axis current command I ^* d generated by the speed controller 720 to generate and output a voltage command. The current controller 730 is the q-axis current command (I ^* q) a second PI controller and filters a through q-axis synchronous coordinate system voltage command (V ^{e *} q) outputting the synchronization coordinates inverse transformation unit 740 do. That is, the current controller 730 compares the q-axis current command I ^* q and the q-axis output current I ^e q by axially converting the motor driving current detected through the current detection unit 600. and it outputs the difference thereof, that is, the current error to the second PI controller and filter the synchronization coordinate reverse conversion to the q-axis voltage command (V ^{* e} q) after section 760. On the other hand, to the current controller 730 is the d-axis current command (Id ^*), the third proportional integral controller and filters a through d-axis synchronous coordinate system voltage command (V ^{e *} d) the synchronization coordinates inverse transformation unit (760) Output That is, the current controller 730 compares the d-axis current command (I ^* d) and the d-axis output current (I ^e d) by axially converting the motor driving current detected through the current detection unit (600). The difference, that is, the current error, is output to the PWM controller 740 via the third proportional integration controller and a filter, and the d-axis stop coordinate system voltage command V ^s d ^* . Here, e represents a synchronous coordinate system and s represents a static coordinate system.

The PWM controller 740 generates the control signal so as to follow the voltage command by synthesizing the valid voltage vectors output from the inverter 400 during the control period Ts and outputs the control signal to the inverter 400. When the inverter is a switching element such as an insulated gate bipolar transistor (IGBT), the control signal becomes a gate input signal. The PWM controller 740 calculates a voltage modulation index from the voltage command and the DC link voltage V _DC , and compares the calculated voltage modulation index with a preset reference modulation index. In addition, the PWM controller 740 selects one of a plurality of modulation schemes according to the comparison result, and generates the control signal according to the selected modulation scheme.

The synchronous coordinate phase converter 750 converts the currents Ia, Ib, and Ic detected by the current detection unit 600 into synchronous d-axis current I ^e d and synchronous q-axis current I ^e q. .

The synchronous coordinate image converter 750 includes a still coordinate converter 751 and a synchronous coordinate converter 752. The stop coordinate converter 751 is connected to the current detection unit 600, and the currents Ia, Ib, and Ic detected by the current detection unit 600 stop the current of the coordinate system I ^s d, I ^s q. To). The synchronous coordinate converter 752 converts the stationary coordinate currents I ^s d and I ^s q into synchronous coordinate currents I ^e d and I ^e q, and the synchronous coordinate currents I ^e d and I ^e. q) is fed back to the current controller 730 and input to the calculator 710. Here, e represents a synchronous coordinate system and s represents a static coordinate system.

The synchronous coordinate inverse converter 760 is disposed between the current controller 720 and the PWM controller 740 and is based on a phase value θe estimated from the position of the rotor calculated by the calculator 710. To convert the synchronous coordinate system voltage commands (V ^{e *} d, V ^{e *} q) into (V ^{s *} d, V ^{s *} q), which is the static coordinate system voltage command (V ^{s *} ). Here, e represents a synchronous coordinate system and s represents a static coordinate system.

In addition, the synchronous coordinate inverse converter 760 converts and outputs the voltage command of the stationary coordinate system according to the type of motor to be driven. For example, in the case of a three-phase motor, the synchronous coordinate inverse converter 750 converts the voltage command of the stationary coordinate system into a three-phase voltage command (Va ^* , Vb ^* , Vc ^* ) to the PWM control unit 740. Output

4 is a detailed block diagram of a control unit according to another embodiment of the present invention. When the detection unit 510 such as a sensor is included in the motor 500, the control unit 800 receives the position of the rotor provided in the motor 500 detected through the detection unit 510 to receive the inverter ( A control signal for controlling 400 is generated and output to the inverter 400. The detector 510 receives a motor driving current and detects the speed? Of the motor 500 or the position of the rotor provided in the motor 500.

The detector 510 measures the position and the speed of the motor 500 to control the position and the speed of the motor 500. As a method of measuring the position and speed of the motor 500, there are a method using an analog sensor and a method using a digital sensor. In the analog method, the measuring device measures a position and a speed from a displacement amount of the rotor converted into an analog amount using a synchro, a resolver, or a taco-generator. In the digital method, the measuring device measures a position and a velocity from a displacement amount converted into a digital form by using a rotary encoder.

In an induction motor, for example, the position of the rotor is detected using a digital encoder. The encoder is a device that outputs a change in the rotation angle of the rotor as a pulse train. The pulse train has a frequency that varies in proportion to the rotational speed of the rotor. The type of encoder includes an absolute encoder and an incremental encoder. The absolute encoder can detect absolute position information of the rotor, but an incremental encoder can detect only a change of the rotor.

For example, in the BLDC motor, the detector 510 needs to know the position of the rotor in order to implement the functions of the commutator and the brush as a power semiconductor switch. Since the rotor is a permanent magnet, the rotor is located using a magnetic flux detection sensor such as a Hall element.

The control unit 800 includes a speed controller 820, a current controller 730, and a PWM controller 740. The control unit 800 may further include a synchronous coordinate phase converter 850 and a synchronous coordinate reverse return unit 760.

The speed controller 820 receives a speed command ω ^* and a detection speed ω desired by the user, and outputs the current command. The speed control unit 820 may include a comparator (not shown) for comparing the speed command ω ^* and the detection speed ω detected by the detection unit 510, and a first proportional integral controller; having a PI) (not shown), the speed reference (ω ^*) accept and input the detected speed (ω), proportional to the difference, i.e. the speed error of the detected velocity (ω) and the speed command (ω ^*) integral Q to generate a q-axis current command (I ^* q), and outputs it to the current control unit 730.

The synchronous coordinate image converter 850 includes a still coordinate converter 751 and a synchronous coordinate converter 852. The synchronous coordinate converter 852 adjusts the static coordinate currents I ^s d and I ^s q based on the phase value θ e estimated from the position of the rotor input from the detector 510. Convert to currents I ^e d and I ^e q. The synchronous coordinate converter 852 feeds back the synchronous coordinate currents I ^e d and I ^e q to the current controller 730. Here, s denotes a static coordinate system and e denotes a synchronous coordinate system.

5 is a flowchart of a control method of the motor control apparatus according to FIG. 3. The control method is a motor control apparatus which does not include a sensor in a motor, wherein the motor is controlled using a sensorless algorithm.

Referring to FIG. 5, a control method of a motor control apparatus according to the present invention includes a converter for converting a commercial AC power to output a DC voltage, a smoothing unit for smoothing the DC voltage, and converting the smoothed DC voltage. In the control method of the motor control apparatus having an inverter for applying a motor driving voltage to the motor, the method comprising: detecting a motor driving current applied to the motor (S100), receiving a speed command (S300), and Calculating the voltage command based on the motor driving current and the speed command (S500); and controlling the control signal based on any one of a plurality of modulation schemes according to the voltage modulation index calculated from the voltage command and the DC link voltage. Generating (S600) and outputting the control signal to the inverter (S700).

The step of calculating the voltage command (S500), the step of calculating the speed of the motor and the position of the rotor provided in the motor (S200), and calculating the current command based on the speed command and the calculation speed. In step S400, the voltage command is calculated based on the current command and the detected current.

Here, in the generating of the control signal (S600), the control signal is generated based on any one of a plurality of modulation schemes according to the voltage modulation index calculated from the voltage command and the DC link voltage. Hereinafter, the configuration of the apparatus will be described with reference to FIGS. 1 to 3.

The motor control apparatus detects a motor driving current applied to the motor using the current detection unit (S100), and estimates the speed of the motor and the position of the rotor using the detected motor driving current (S200). The current detection unit may be a current transducer connected between the inverter and the motor to continuously detect the motor driving current. The current transducer detects the motor driving current and converts the motor driving current into a voltage signal. The current transducer detects the motor driving current in all sections of the pulse width modulation. For example, in the case of a three-phase motor, the current detection unit detects the currents Ia, Ib, and Ic applied to the three phases and outputs them to the calculating unit of the control unit, and the calculating unit uses the sensorless algorithm therefrom. Estimation calculation of the speed of the motor and the position of the rotor (S210). The control unit generates an interrupt signal to sample the voltage signal according to the detected motor drive current.

The speed controller receives or calculates a speed command desired by the user, and calculates a q-axis current command by proportionally integrating a difference between the speed command and the calculation speed, that is, a speed error, by receiving the speed command and the calculation speed. (S400). The current controller receives the q-axis current command and the d-axis current command to generate and output a voltage command (S500). The current control unit compares the q-axis current command with the q-axis current command and the motor driving current, and calculates the q-axis voltage command through the difference, that is, the current error, through a second proportional integral controller and a filter. The d-axis current command and the d-axis operational current obtained by converting the motor driving current are compared with each other, and the difference, that is, the current error, is calculated through the third proportional integral controller and the filter (S500). The PWM control unit converts the voltage command of the synchronous coordinate system into voltage commands Vα and Vβ of the still coordinate system. The PWM controller converts and outputs the voltage command of the stationary coordinate system according to the type of motor to be driven. For example, in the case of a three-phase motor, the PWM control unit converts the voltage command of the stationary coordinate system into a three-phase voltage command and outputs it to the inverter. Referring to Fig. 3, the control device converts a synchronous coordinate system voltage command into a static coordinate system voltage command and converts it into a voltage command suitable for the motor type, for example, a three phase voltage command. The control device outputs a control signal for controlling the switch of the inverter to follow the voltage command by synthesizing the effective voltage vectors output from the inverter during the control period Ts and outputting the control signal to the inverter. In the case where the inverter is a switching element such as an IGBT, the control signal becomes a gate input signal.

Generating the control signal (S600) includes calculating the voltage modulation index from the voltage command and the DC link voltage (S610), and comparing the calculated voltage modulation index with a predetermined reference modulation index (S620). The method may include selecting any one of a plurality of modulation schemes according to the comparison result (S630) and generating the control signal according to the selected modulation scheme (S640).

6 is a flowchart of a control method of the motor control apparatus according to FIG. 4. The control method is a motor control apparatus including a sensor in a motor, the control of the motor by detecting the position of the rotor provided in the motor.

6, the control method of the motor control apparatus according to the present invention, the motor applied current detection step (S100), speed command input step (S300), voltage command calculation step (S500), control signal generation step (S600) And a control signal output step (S700).

The step of calculating the voltage command (S500), the step of detecting the speed of the motor or the position of the rotor provided in the motor (S220), and calculating the current command based on the speed command and the detection speed. In step S400, the voltage command is calculated based on the current command and the detected current.

In the rotor position detecting process S220, for example, the induction motor detects the position of the rotor using a digital encoder. The encoder is a device that outputs a change in the rotation angle of the rotor as a pulse train. The pulse train has a frequency that varies in proportion to the rotational speed of the rotor. The type of encoder includes an absolute encoder and an incremental encoder. The absolute encoder can detect absolute position information of the rotor, but an incremental encoder can detect only a change of the rotor.

In the rotor position detecting process S220, for example, the rotor is a permanent magnet in a BLDC motor, and thus the position of the rotor is detected by using a magnetic flux detection sensor such as a Hall element.

As described above, the motor control apparatus and control method thereof according to the present invention generates a control signal based on any one of the plurality of pulse width modulation schemes according to the calculated voltage modulation index, thereby reducing the harmonic distortion rate due to switching. This can improve the stability of the system.

100: commercial AC power supply 200: converter
300: smoothing unit 400: inverter
500: motor 510: detector
600: current detection unit 700, 800: control unit 710: arithmetic unit 720: speed control unit 730: current control unit 740: pulse width modulation (PWM) control unit 750: synchronous coordinate phase conversion unit 751: static coordinate conversion unit 752, 852: synchronous coordinate conversion part
760: synchronous coordinate inverse transform unit

Claims (14)

An inverter for applying a motor driving voltage to the motor based on the control signal;
A current detecting unit disposed between the inverter and the motor, the current detecting unit detecting a motor driving current applied to the motor; And
Generating the control signal based on any one of a plurality of pulse width modulation schemes and outputting the control signal to the inverter according to a voltage command calculated based on the motor driving current and a speed command and a voltage modulation index calculated from a DC link voltage. Including a control unit,
The plurality of pulse width modulation scheme,
At least two selected from an optimal voltage modulation scheme, a sinusoidal voltage modulation scheme, a space vector pulse width modulation scheme, and a discrete pulse width modulation scheme,
The control unit includes:
And selecting the space vector pulse width modulation method when the voltage modulation index is smaller than a predetermined reference modulation index, and selecting the discrete pulse width modulation method when the voltage modulation index is larger than the reference modulation index. delete delete The method according to claim 1,
And the reference modulation index is set to a modulation index of a point at which a harmonic distortion curve according to each modulation scheme intersects. The method according to claim 1,
The control unit
A speed controller which receives the speed command and the speed of the motor or the position of the rotor provided in the motor and outputs a current command;
A current controller which receives the current command and the detected current and outputs the voltage command; And
And a pulse width modulation controller (PWM controller) for generating the control signal and synthesizing the effective voltage vectors output from the inverter during the control period Ts to follow the voltage command. The method according to claim 1,
The control unit
An operation unit configured to receive the motor driving current and calculate a speed of the motor and a position of the rotor provided in the motor;
A speed controller which receives the speed command and the calculation speed and outputs a current command;
A current controller which receives the current command and the detected current and outputs the voltage command; And
And a pulse width modulation controller (PWM controller) for generating the control signal and synthesizing the effective voltage vectors output from the inverter during the control period Ts to follow the voltage command. The method of claim 6,
The control unit
A stationary coordinate converter connected to the current detection unit and converting the current detected by the current detection unit into a stationary coordinate system current;
And a synchronous coordinate converter for converting the stationary coordinate system current into a synchronous coordinate system current, feeding back the synchronous coordinate system current to the current control unit, and inputting the current to the calculation unit. 6. The method of claim 5,
The control unit
A stationary coordinate converter connected to the current detection unit and converting the current detected by the current detection unit into a stationary coordinate system current;
And a synchronous coordinate converter converting the stationary coordinate system current into a synchronous coordinate system current based on a phase value estimated from the input position of the rotor, and feeding back the synchronous coordinate system current to the current controller. The method according to claim 7 or 8,
The control unit
Disposed between the current detector and the pulse width modulation controller (PWM controller),
And a synchronous coordinate inverse converting unit converting the synchronous coordinate system voltage command into the stationary coordinate system voltage command based on the phase value. The method according to claim 1,
The current detection unit
And a current transducer connected between the inverter and the motor to continuously detect the motor driving current. A control method of a motor control apparatus including a converter for converting commercial AC power to output a DC voltage, a smoothing unit for smoothing the DC voltage, and an inverter for converting the smoothed DC voltage to apply a motor driving voltage to the motor. To
Detecting a motor driving current applied to the motor;
Receiving a speed command;
Calculating a voltage command based on the motor driving current and the speed command;
Comparing the voltage modulation index calculated from the voltage command and the DC link voltage;
As a result of comparison, if the calculated voltage modulation index is smaller than the preset reference modulation index, the spatial vector pulse width modulation method is selected. If the calculated voltage modulation index is larger than the preset quasi modulation index, the discrete pulse width modulation method is selected. Generating a control signal; And
And outputting the control signal to the inverter. 12. The method of claim 11,
The step of calculating the voltage command
Detecting the speed of the motor or the position of the rotor provided in the motor;
Calculating a current command based on the speed command and the detection speed; And
And calculating the voltage command based on the current command and the detected current. 12. The method of claim 11,
The step of calculating the voltage command
Calculating a speed of the motor and a position of the rotor provided in the motor;
Calculating a current command based on the speed command and the calculation speed; And
And calculating the voltage command based on the current command and the detected current. delete

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