WO2008004316A1 - Appareil de commande vectorielle, procédé de commande vectorielle et appareil de commande d'entraînement pour moteur à induction - Google Patents
Appareil de commande vectorielle, procédé de commande vectorielle et appareil de commande d'entraînement pour moteur à induction Download PDFInfo
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- WO2008004316A1 WO2008004316A1 PCT/JP2006/315397 JP2006315397W WO2008004316A1 WO 2008004316 A1 WO2008004316 A1 WO 2008004316A1 JP 2006315397 W JP2006315397 W JP 2006315397W WO 2008004316 A1 WO2008004316 A1 WO 2008004316A1
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- inverter
- command
- magnetic flux
- induction motor
- voltage
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Classifications
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/04—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation specially adapted for very low speeds
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/12—Stator flux based control involving the use of rotor position or rotor speed sensors
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/02—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation specially adapted for optimising the efficiency at low load
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/06—Rotor flux based control involving the use of rotor position or rotor speed sensors
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/24—Vector control not involving the use of rotor position or rotor speed sensors
- H02P21/26—Rotor flux based control
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/36—Arrangements for braking or slowing; Four quadrant control
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P27/00—Arrangements or methods for the control of AC motors characterised by the kind of supply voltage
- H02P27/04—Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage
Definitions
- Vector control device for induction motor vector control method for induction motor
- drive control device for induction motor drive control device for induction motor
- the present invention relates to an induction motor vector control device, an induction motor vector control method, and an induction motor drive control device connected to an inverter that converts a DC voltage into an AC voltage of an arbitrary frequency and outputs the same. .
- This vector control of induction motors is a technology that has come to be used in recent electric railways.
- the inverter for driving electric vehicles should use the multi-pulse PWM mode that is commonly used in the low-speed range, and use the 1-pulse mode in the medium- and high-speed range where the inverter output voltage is saturated and fixed at the maximum value. Another feature is that the switching mode of the inverter is switched.
- the multi-pulse PWM (pulse width modulation) mode is a well-known PWM method, which generates a PWM signal by comparing a triangular wave with a frequency of about 1kHz with a voltage command. is there.
- the 1-pulse mode means that the inverter output line voltage has a rectangular wave energization waveform of 120 degrees, and that the fundamental effective value of the inverter output voltage can be maximized, and that the half-cycle of the output voltage fundamental wave Since the minimum number of pulses can be set to 1, the characteristic is that a small and light inverter can be obtained by minimizing the cooling device and minimizing the switching loss of the inverter.
- a 120-degree rectangular wave energization waveform means that the line voltage of the inverter is one parameter per half cycle. This is a voltage waveform that has a pulse width of 120 degrees in electrical angle.
- Inverters for electric vehicles are stable in the entire range from the multi-pulse PWM mode in the low-speed range to the 1-pulse mode in which the output voltage of the inverter in the medium- and high-speed range is saturated and fixed to the maximum value. It is essential to be able to perform accurate vector control, and vector control technology and pulse mode switching technology in the output voltage saturation region of the inverter are important factors. In particular, in the inverter output voltage saturation region, the magnitude of the inverter output voltage is fixed to the maximum value according to the input voltage of the inverter.
- the inverter may output the voltage as the inverter output voltage command. become unable.
- Non-Patent Document 1 shown below shows a vector control method for solving the above-described problems.
- Non-Patent Document 1 if the inverter output voltage command calculated by the vector controller exceeds the maximum voltage that can be output by the inverter, the difference between the inverter output voltage command and the voltage that can actually be output by the inverter is determined as the magnetic flux.
- the inverter output voltage command is corrected to match the maximum voltage that the inverter can actually output by adopting a configuration in which the secondary magnetic flux command is reduced and adjusted by the input to the correction controller and the output of the magnetic flux correction controller. It is shown that vector control is possible even in the output voltage saturation region of the inverter.
- Non-Patent Document 1 “Vector control of induction motor in fixed voltage mode”, 1998 IEEJ Transaction D, No. 118 ⁇ 9
- the magnetic flux correction controller operates after the inverter output voltage command deviates from the voltage that can be actually output by the inverter. Then, the secondary magnetic flux command is adjusted, the inverter output voltage command is decreased, and the inverter output voltage command operates so as to match the maximum voltage that the inverter can actually output.
- Non-Patent Document 1 the vector control of the induction motor shown in Non-Patent Document 1 is a configuration in which the inverter output voltage command is corrected by a so-called feedback loop.
- the present invention has been made in order to solve such problems, and performs stable vector control in the entire range up to the high speed range of the induction motor without using a feedback loop.
- Vector control device for induction motor vector control method for induction motor
- drive control device for induction motor drive control device for induction motor
- An induction motor vector control device is a vector control device that drives and controls an induction motor via an inverter
- the maximum voltage that can be generated by the inverter is taken into consideration for the induction motor.
- the secondary magnetic flux command calculation means for calculating the secondary magnetic flux command, the torque command and the secondary magnetic flux command, Q-axis current command and d-axis current command on the dq-axis rotating coordinate system based on the secondary magnetic flux of the induction motor q-axis Zd-axis current command generation means, the q-axis current command, d Based on a shaft current command and a circuit constant of the induction motor, output voltage calculation means for calculating an output voltage to be output by the inverter, and a voltage command ZPWM for controlling the inverter so that the inverter outputs the output voltage Signal generating means.
- a vector control method for an induction motor is a vector control method for driving and controlling an induction motor via an inverter
- the maximum voltage that can be generated by the inverter is taken into consideration for the induction motor.
- an induction motor drive control device includes an inverter for driving and controlling an induction motor, an external force torque command, a DC voltage input to the inverter, and an AC voltage output by the inverter.
- a secondary magnetic flux command calculating means for calculating a secondary magnetic flux command for the induction motor in consideration of a maximum voltage that can be generated by the inverter, the torque command and the secondary magnetic flux
- a q-axis current command generating means for generating a q-axis current command and a d-axis current command on the dq-axis rotating coordinate system based on the secondary magnetic flux of the induction motor based on the command, and the q-axis current command
- Output voltage calculating means for calculating an output voltage to be output by the inverter based on the d-axis current command and the circuit constants of the induction motor; and the inverter Is obtained by a voltage command ZP
- the secondary magnetic flux command for the induction motor is generated in a feed-forward manner regardless of the output voltage saturation state of the inverter, so that a feedback loop is generated to generate the secondary magnetic flux command.
- stable vector control can be performed in the entire low speed range of the induction motor up to the high speed range.
- FIG. 1 is a block diagram showing a configuration of a vector control device for an induction motor according to Embodiment 1 of the present invention.
- FIG. 2 is a block diagram showing a configuration example of a secondary magnetic flux command calculation unit in the first embodiment.
- FIG. 3 is a diagram for explaining the behavior of an internal signal of a secondary magnetic flux command calculation unit in the first embodiment.
- FIG. 4 is a block diagram showing a configuration example of a voltage command ZPWM signal generation unit in the first embodiment.
- FIG. 5 is a diagram for explaining the operation of the vector control apparatus for an induction motor according to the first embodiment.
- FIG. 6 shows a simulation waveform in the first embodiment.
- FIG. 7 is a diagram showing a torque response simulation waveform in the first embodiment.
- Capacitor 4 Inverter
- Switch 60 Pulse mode switching processor
- FIG. 1 is a block diagram showing a configuration example of a vector control device for an induction motor according to Embodiment 1 of the present invention.
- the main circuit consists of a DC power source 1, an LC filter circuit consisting of a rear tuttle 2 and a capacitor 3 for suppressing the harmonic current from flowing out to the power source side, and the DC voltage Efc of the capacitor 3 to an arbitrary
- It has a vector control device 100 that vector-controls an inverter 4 that converts frequency AC voltage and an induction motor (hereinafter simply referred to as “motor”) 6.
- the inverter 4 and the vector control device 100 constitute a drive control device that controls the drive of the electric motor 6 by vector control.
- the vector control device 100 includes a signal from the speed detector 7 that detects the rotational speed of the electric motor 6, a signal from the current detectors 5a to 5c that detect current, and a voltage Efc of the capacitor 3 (ie, a DC power supply).
- the DC voltage applied to the inverter 4 from 1 is smoothed by the capacitor 3) and the torque command Tm * is input from an external control device (for example, system control unit)
- the torque Tm generated by the electric motor 6 is controlled so as to coincide with the torque command Tm *. If a current detector is provided for at least two phases, the remaining one-phase current can be calculated and calculated.
- the “speed sensorless vector control method” that calculates and calculates the rotational speed of the electric motor 6 without providing the speed detector 7 has been put into practical use. In this case, the speed detector 7 is not necessary. .
- the vector controller 100 controls the motor on the dq axis rotation coordinate system in which the axis that coincides with the secondary magnetic flux axis of the motor 6 is defined as the d axis and the axis orthogonal to the d axis is defined as the q axis. Therefore, it is configured to perform so-called vector control.
- the q-axis current command generation unit 8 and the d-axis current command generation unit 9 are external control units. From the torque command Tm * input from the device (not shown), the secondary magnetic flux command ⁇ 2 * generated by the secondary magnetic flux command calculation unit 40, and the circuit constants of the motor 6, the following equation (1), Calculate d-axis (excitation) current command Id * and q-axis (torque) current command Iq * based on equation (2)
- Id * 0> 2 * / M + L2 / (M * R2) 's0> 2 * (2)
- M is the mutual inductance
- 12 is the secondary leakage inductance
- s is the differential operator
- PP is the number of pole pairs of the motor 6
- R2 is the secondary resistance of the motor 6.
- the secondary magnetic flux command calculation unit 40 is a central part of the present invention, and a detailed configuration and operation will be described later.
- the slip angular frequency command generation unit 19 calculates the motor 6 based on the following equation (3) from the d-axis current command Id *, the q-axis current command Iq *, and the circuit constant of the motor 6.
- the angular frequency command ⁇ s * is calculated.
- R2 is the secondary resistance of the motor.
- Secondary resistance correction unit 20 performs proportional integral control of the difference between q-axis current command Iq * and q-axis current Iq.
- the secondary resistance error correction value PFS is obtained based on the following equation (4).
- the purpose of this configuration is to compensate for “change in secondary resistance R2 due to temperature”, which has a large effect on torque control performance among the constants of electric motor 6.
- This secondary resistance correction value PFS is output based on the following equation (4) only in the control mode 2 described later, and is zero in the control mode 1 described later.
- s is the differential operator
- K3 is the proportional gain
- K4 is the integral gain
- the proportional gain K3 is a coefficient that depends on the deviation between Iq * and Iq
- the integral gain K4 is It is a coefficient for the integral term of the deviation of Iq * and Iq.
- the three-phase dq axis coordinate converter 23 calculates the U-phase current Iu, V-phase current Iv, and W-phase current Iw detected by the current detectors 5a to 5c based on the following equation (5). Convert to upper d-axis current I d and q-axis current Iq.
- the subtracter 10 takes the difference between the q-axis current command Iq * and the q-axis current Iq, and the result (ie, the difference between I q * and Iq) is used as the q-axis current controller 12 in the next stage. To enter.
- the q-axis current controller 12 performs proportional-integral control on the input value (that is, the difference between Iq * and Id) and outputs a q-axis voltage compensation value qe.
- the subtractor 11 calculates the difference between the d-axis current command Id * and the d-axis current Id and inputs the result (that is, the difference between I d * and Id) to the d-axis current controller 13 in the next stage.
- the d-axis current controller 13 performs proportional-integral control on the input value (i.e., the difference between Id * and Id) Outputs the voltage compensation value de.
- Equation (6) and (7) s is a differential operator, K1 is a proportional gain, and K2 is an integral gain.
- the voltage non-interference calculation unit 14 uses the d-axis current command Id *, the q-axis current command Iq *, and the circuit constants of the motor 6 based on the following equations (8) and (9). D-axis feed forward voltage Ed * and q-axis feed forward voltage Eq *.
- R1 is the primary resistance of motor 6
- L1 is the primary self-inductance of motor 6
- the q-axis voltage compensation value qe and the q-axis feedforward voltage Eq * are calorically calculated as the q-axis voltage command Vq *, and the d-axis voltage compensation value de and d-axis Feed forward voltage
- Ed * is input to the voltage command ZPWM signal generator 50 as the d-axis voltage command Vd *.
- q-axis voltage command Vq * and d-axis voltage command Vd * are expressed by the following formulas (10) and (11).
- Vq * Eq * + qe (10)
- VM * represents the magnitude of the inverter output voltage command vector.
- the voltage non-interference calculation unit 14 and the adders 17 and 18 constitute output voltage calculation means for calculating the output voltage to be output from the inverter 4.
- the inverter 4 is a voltage-type PWM inverter that is already known, and a detailed description of the configuration is omitted. However, to supplement a part of the description, the switching elements U, V, and W are the U of the upper arm of the inverter 4. The switching elements X, Y, and ⁇ are switching elements that are placed in the U, V, and W phases of the lower arm of inverter 4, respectively.
- the configuration of the ZPWM signal generation unit 50 will be described.
- FIG. 2 is a diagram illustrating a configuration example of the secondary magnetic flux command calculation unit 40 in the present embodiment.
- the secondary magnetic flux command calculation unit 40 includes a capacitor voltage Efc, a torque command T m *, an inverter angular frequency ⁇ , a secondary secondary magnetic flux command ⁇ 2P *, and a brake secondary magnetic flux command ⁇ 2 ⁇ . * Is entered.
- the output voltage maximum value calculation unit 41 calculates the maximum value VMmax of the inverter output voltage VM from the capacitor voltage Efc based on the following equation (13).
- VMmax is the maximum voltage that the inverter can output at the capacitor voltage Efc. This is the value when operating in the luth mode.
- Equation (13) can be obtained as a fundamental wave component if a square wave having a force of 120 degrees, which is the equation described in Non-Patent Document 1, is expanded by Fourier series.
- equation (14) is an important equation for constituting the present invention, the derivation process will be briefly described below.
- the transient term is determined on the condition that the time change of the d-axis secondary magnetic flux is gradual. If neglected, the d-axis voltage of the electric motor 6 is obtained based on the following equation (15), and the q-axis voltage Vq of the electric motor 6 is obtained based on the following equation (16).
- Vd Rl-Id- W -Ll- ⁇ -Iq (15)
- Vq Rl-Iq + W -Ll- ⁇ -Id
- Vd is the d-axis voltage of the electric motor 6
- Vq is the q-axis voltage of the electric motor 6.
- Equation (17) ⁇ 2 is the d-axis secondary magnetic flux of the electric motor 6.
- ⁇ 2 is the d-axis secondary magnetic flux of the electric motor 6.
- Equation (18) which is the relationship between d-axis current Id and d-axis secondary magnetic flux ⁇ 2
- Equation (20) which is the relationship between q-axis current Iq and torque Tm
- Vd R1- ( ⁇ 2 / ⁇ )
- Vq Rl- (Tm-L2) / (2-M)
- Equation (23) the following Equation (2 3) is obtained.
- VM indicates the voltage of the electric motor 6.
- the voltage of the electric motor 6 is equal to the output voltage of the inverter 4, it will be referred to as an inverter output voltage VM in the following description.
- Equation (23) Multiplying both sides of Equation (23) by ⁇ 2 2 and rearranging gives the quadratic equation for the d-axis secondary magnetic flux ⁇ 2 of the motor 6.
- Equation (24) is expressed as follows: d-axis secondary magnetic flux ⁇ 2 of motor 6, inverter output voltage VM, inverter angular frequency ⁇ , torque Tm of motor 6, and constants of motor 6 (Rl, Ll, L2 , M).
- the equation (24) shows the relationship between the generated torque Tm of the motor 6 at VMmax, the d-axis secondary magnetic flux ⁇ 2, and the inverter angular frequency ⁇ . It will be.
- the maximum voltage secondary magnetic flux command ⁇ 2 ⁇ * obtained by the equation (14) is the inverter output under the condition that the motor 6 is operated with the torque command Tm * and the inverter angular frequency ⁇ .
- the voltage VM coincides with the maximum value VMmax that can be output by the inverter, it is just a secondary magnetic flux command that is necessary.
- the inverter output voltage command VM * calculated by the vector controller 100 using the maximum voltage secondary magnetic flux command ⁇ 2H * matches the inverter output voltage VM with the maximum value VMmax that the inverter can output. Therefore, the inverter output voltage command VM * force S does not deviate from the maximum value VMmax that can be output by the inverter.
- the rated secondary magnetic flux should be as large as possible under the condition that the iron core of the motor 6 is not magnetically saturated. It is common.
- the lower priority unit 44 selects the smaller of the maximum voltage secondary magnetic flux command ⁇ 2 ⁇ * and the rated secondary magnetic flux command 0> 2C *, and finally uses the secondary magnetic flux used for vector control.
- the command ⁇ 2 * is generated.
- FIG. 3 is a diagram for explaining the behavior of the internal signal of the secondary magnetic flux command calculation unit 40 in the embodiment of the present invention.
- the secondary magnetic flux command ⁇ 2 * used for vector control is the rated secondary magnetic flux command ⁇ 2C * until the inverter reaches the output voltage saturation (region left of S in Fig. 3). Is selected, and the maximum voltage secondary flux command ⁇ 2H * is selected in the output voltage saturation region of the inverter (region to the right of S in Fig. 3).
- the secondary magnetic flux command ⁇ 2 * force that is just necessary to make the inverter output voltage VM coincide with the maximum value VMmax in the output voltage saturation region of the inverter is obtained in real time.
- the secondary magnetic flux command ⁇ 2 * is instantly determined from the motor constant and the known amount without any time delay based on the above formula (14) without feedback elements. Magnetic flux command ⁇ 2 * can be obtained in feed-forward in real time.
- FIG. 4 is a diagram illustrating a configuration example of the voltage command ZPWM signal generation unit 50 in the present embodiment.
- the modulation rate calculation unit 51 and the voltage phase angle calculation unit 52 use the inverter output voltage command VM * shown in equation (12) and the maximum value VMmax of the inverter output voltage VM shown in equation (13).
- the modulation factor PMF and voltage phase angle THV are calculated from the d-axis voltage command Vd * and q-axis voltage command Vq *, respectively.
- the modulation factor calculation unit 51 and the voltage phase angle calculation unit 52 perform calculations of the following equations (25) and (26), respectively.
- the voltage phase angle THV is summed with the basic phase angle ⁇ by the adder 56 and input to the voltage command calculation unit 55 and the synchronous three-pulse carrier signal generation unit 58 as the control phase angle ⁇ 1.
- the modulation factor PMF is the ratio of the inverter output voltage command VM * to the maximum voltage VMmax that can be output by the inverter VMmax (defined by the above equation (13)).
- PMF 1.0
- the inverter The output voltage command VM * indicates that it is equal to the maximum value VM max of the inverter output voltage.
- a value obtained by multiplying the modulation factor PMF by the output of the adjustment gain table 54 by the multiplier 53 is set as a voltage command amplitude PMFM and is input to the voltage command calculation unit 55.
- the adjustment gain table 54 is for correcting the difference in the relationship of the inverter output voltage VM with respect to the modulation rate PMF in the multi-pulse PWM mode and the synchronous three-pulse PWM mode.
- the outline is as follows.
- the maximum voltage (effective value) that can be output without distortion by the inverter 4 is 0.612'Efc. In the force-synchronized 3-noless PWM mode, it is 0.79797'Efc. In other words, in the multi-pulse PWM mode, the output voltage of the inverter with respect to the modulation rate P MF is 1Z1.274 compared to the synchronous 3-pulse PWM mode.
- the modulation factor PMF is multiplied by 1.274 and input to the voltage command calculation unit 55 as the voltage command amplitude PMFM.
- the U-phase voltage command Vu *, V-phase voltage command Vv *, W are calculated from the modulation factor PMF and the control phase angle ⁇ 1 using the following equations (27) to (29). Generate phase voltage command Vw *.
- Vu * PMFM ⁇ ⁇ ⁇ 1 (27)
- the carrier signal CAR is a multi-pulse (generally around 1 kHz) carrier signal A generated by the multi-pulse carrier signal generation unit 57 by the pulse mode switching processing unit 60, and a synchronous three-pulse carrier signal generated by the synchronous three-pulse carrier signal generation unit 58.
- B, Zero value C selected in 1-pulse mode is the signal selected by switch 59.
- the pulse mode switching processing unit 60 has a modulation rate PMF of 0.78 in the region where the modulation rate PMF is low (0.785 or less) according to the modulation rate PMF and the control phase angle ⁇ 1.
- the pulse mode can be switched to the 1-pulse mode at a timing when the modulation factor PMF is 1.0, that is, the inverter output voltage VM is equal to the maximum value VMmax.
- each calculation formula shown above is SZW processed by a microcomputer, but if the calculation precision (number of bits) is reduced for the purpose of reducing the calculation load of the microcomputer, the inverter When the output voltage VM reaches the maximum value VMmax, the modulation rate PMF In some cases, it does not reach 1.0 accurately, but is less than that, for example, 0. 999.
- FIG. 5 is a diagram for explaining the inverter angular frequency ⁇ , the modulation rate PMF, the transition of the pulse mode, the operation of the switch 59 for switching the control pulse mode, and the transition of the control mode in the present embodiment.
- FIG. 5 is a diagram for explaining the inverter angular frequency ⁇ , the modulation rate PMF, the transition of the pulse mode, the operation of the switch 59 for switching the control pulse mode, and the transition of the control mode in the present embodiment.
- the modulation mode PMF is small
- the pulse mode is the multi-pulse PWM mode
- switch 59 is selected as shown in Fig. 4 Yes.
- the control mode is control mode 1, and the q-axis current controller 12 and the d-axis current controller 13 operate according to the above equations (6) and (7).
- the synchronous 3-pulse mode is a mode necessary for outputting a voltage with a modulation factor PMF of 0.785 or more.
- control mode 2 is selected as the control mode, the computation of the q-axis current controller 12 and the d-axis current controller 13 is stopped, and the output is reduced to zero.
- the reason for limiting the output to zero is that in the synchronous 3-pulse PWM mode, the number of pulses in the inverter output voltage half cycle decreases from 10 or more in the multi-pulse PWM mode to 3, so the control delay increases and q-axis current control This is because there is a concern that the calculation of the controller 12 and the d-axis current controller 13 will be unstable, and the calculation of the q-axis current controller 12 and the d-axis current controller 13 stops.
- the secondary resistance correction unit 20 starts operation, and the secondary resistance correction value PFS is calculated based on the equation (4).
- switch 59 is switched to C. Change the pulse mode to 1 pulse mode.
- the control mode is still control mode 2.
- the pulse mode is synchronized from the 1 pulse mode to the 3 pulse PWM mode and the multi-pulse PWM mode in the reverse order of the above.
- the switch 59 switches to C, B, A (see Fig. 4), and the control mode changes from control mode 2 to control mode 1.
- FIG. 6 is a diagram showing simulation waveforms in the present embodiment.
- the multi-pulse PWM mode and control mode 1 are selected, and the secondary magnetic flux command ⁇ 2 * is selected from the rated secondary magnetic flux 0> 2C *
- the motor 6 is excited with a constant magnetic flux.
- the magnitude of the q-axis voltage command Vq * and the d-axis voltage command Vd * increases in proportion to the acceleration of the motor, so the inverter output voltage command VM * also increases, and the modulation factor PM F also increases accordingly.
- the U-phase voltage command Vu * increases.
- the torque Tm of the motor 6 follows the Tm * stably and accelerates.
- the mode is switched to the synchronous 3-pulse mode, and the mode is switched to the control mode 2.
- the secondary magnetic flux command ⁇ 2 * remains at the rated secondary magnetic flux ⁇ 2C *, and the motor 6 is excited with a constant magnetic flux.
- the torque Tm of the electric motor 6 follows Tm * stably and accelerates. It should be noted that the force near time 3.5 (s) is the force at which ripple is seen in torque Tm for a while. This is because the current ripple of motor 6 increases because the number of pulses is small in synchronous 3-pulse PWM mode. When driving an electric vehicle with a large inertia, there is no problem.
- the average value of the torque Tm is consistent with the torque command Tm * and is controlled stably.
- the secondary magnetic flux command calculation unit 40 sets the secondary magnetic flux command ⁇ 2 * as The maximum voltage secondary magnetic flux command ⁇ 2H * calculated based on 14) is selected.
- the torque command Tm * is throttled in inverse proportion to the rotational speed in order to operate the motor 6 at a constant output, but it can be seen that the torque Tm of the motor 6 is accelerating stably following Tm *.
- FIG. 7 is a diagram showing a torque response simulation waveform in the present embodiment.
- FIG. 7 shows the torque of the motor 6 when the torque command Tm * is decreased or increased stepwise in the 1-pulse mode region (time 5.3 (s) to 5.9 (s)) in FIG. This is the response waveform of Tm.
- the inverter output voltage command VM * can be output in the inverter voltage saturation region regardless of fluctuations in the torque command Tm * and the capacitor voltage Efc.
- the secondary magnetic flux command ⁇ 2 * that can always match the maximum voltage VMmax can also be calculated in real time in a feed-forward manner.
- the inverter output voltage command VM * does not deviate from the maximum output voltage VM max of the inverter, and a feedback loop such as a magnetic flux correction controller. Therefore, it is possible to obtain a vector control method in the voltage saturation region that eliminates the need to add a control constant and eliminates the need to set a control constant.
- the pulse mode can be switched to the 1-pulse mode at the timing when the modulation rate PMF reaches 1.0 through the synchronized 3-pulse PWM mode from the multi-pulse PWM mode, that is, at the timing when the inverter output voltage reaches the maximum value VMmax. It becomes.
- the multi-pulse PWM mode force in the low speed range The inverter control system for induction motors that enables stable vector control in the entire range up to the single pulse mode in the medium to high speed range, which is the output voltage saturation range of the inverter Can be obtained.
- the q-axis current controller and the d-axis current controller are operated in the multi-pulse mode, and the q-axis current controller and the d-axis current controller are stopped in the mode of 3 pulses or less.
- the secondary resistance correction unit was operated to correct the inverter angular frequency from the deviation between the current command and q-axis current.
- the q-axis current controller and d-axis current controller are operated, or the q-axis current controller and d-axis current controller are not provided, and the secondary resistance correction unit is installed regardless of the pulse mode.
- Feedback control such as magnetic flux correction control to obtain secondary magnetic flux command even if it is operated or force is applied to any of q-axis current controller, d-axis current controller and secondary resistance correction unit
- the induction motor vector control device is a vector control device that drives and controls the induction motor (6) via the inverter (4), and includes a torque command from the outside,
- an output voltage calculation means (comprising a voltage non-interference calculation unit 14, an adder 17 and an adder 18) for calculating the output voltage to be output by the inverter (4)
- a voltage command ZP WM signal generating means (50) for controlling the inverter (4) so that the barter (4) outputs the output voltage.
- the secondary magnetic flux command for the induction motor is generated in a feedforward manner regardless of the output voltage saturation state of the inverter, so that it is stable in the entire range from the low speed range to the high speed range of the induction motor without using the feedback loop.
- Vector control can be performed.
- the secondary magnetic flux command calculation means (40) of the vector control device of the induction motor provides a secondary magnetic flux command in which the maximum voltage that can be generated by the inverter (4) matches the magnitude of the output voltage.
- the maximum voltage secondary magnetic flux command calculation unit (42) for calculating the maximum voltage secondary magnetic flux command is selected, and the smaller one of the maximum voltage secondary magnetic flux command and the preset rated secondary magnetic flux command is selected as the secondary And a low priority part (44) for outputting as a magnetic flux command.
- the maximum voltage secondary magnetic flux command can generate an inverter output voltage command that matches the maximum voltage that the inverter can output, and the inverter output voltage command In response, the rated secondary magnetic flux command and maximum voltage secondary magnetic flux command can be switched automatically.
- the maximum voltage secondary magnetic flux command calculation unit (42) of the vector control device for the induction motor calculates the maximum voltage secondary magnetic flux command based on the torque command and the inverter angular frequency.
- the maximum voltage secondary magnetic flux command is calculated by the above-described equation (14).
- the maximum voltage secondary magnetic flux command is uniquely determined based on the calculation formula of Equation (14) without the feedback element, so that the control constant in the feedback loop can be adjusted compared to the case where the feedback loop is provided. It is not necessary and the maximum voltage secondary magnetic flux command can be calculated easily and instantaneously.
- the rated secondary magnetic flux command has at least two kinds of values, that is, a value applied when the induction motor (6) is driven and a value applied during regeneration. It can be switched according to the operating state of the induction motor (6).
- the induction motor can be controlled by applying the optimum rated secondary magnetic flux command.
- the rated secondary magnetic flux command is a value that is set in advance by using the calculation formula (14). Force Calculates the optimal rated secondary magnetic flux command easily.
- the pulse mode of the inverter (4) is determined according to the modulation factor of the inverter (4) calculated based on the secondary magnetic flux command and the torque command. Switch.
- the actual output voltage fundamental wave component of the inverter can be continuously changed according to the secondary magnetic flux command and the inverter output voltage command that changes according to the inverter frequency.
- the inverter (4) when the modulation factor of the inverter (4) calculated based on the secondary magnetic flux command is 0.95 or more, the inverter (4) is set to 1 pulse mode. Make it work.
- the output voltage of the inverter can be continuously changed to its maximum value.
- the current detectors (5a to 5c) for measuring the current flowing through the induction motor (6) and the current detectors (5a to 5c) Three-phase dq-axis coordinate converter (23) that converts current into q-axis current and d-axis current, which are values on the dq-axis rotating coordinate system, and to reduce the deviation between q-axis current command and q-axis current Q-axis current A control means (12), and a d-axis current control means (13) that operates so as to reduce the deviation between the d-axis current command and the d-axis current.
- the q-axis current control means (12) and the d-axis current The output of the control means (13) is used by the output voltage calculation means (consisting of the voltage non-interference calculation unit 14, the adder 17, and the adder 18) to calculate the output voltage, and the half cycle in which the inverter (4) is generated
- the output voltage calculation means Consisting of the voltage non-interference calculation unit 14, the adder 17, and the adder 18
- the output voltage calculation means consisting of the voltage non-interference calculation unit 14, the adder 17, and the adder 18
- the vector control apparatus for an induction motor when the number of pulses in the half cycle generated by the inverter (4) is 3 or less, the deviation between the q-axis current command and the q-axis current is determined.
- the inverter angular frequency is corrected, so that torque control accuracy can be ensured (that is, the error between the torque command and the actual torque can be minimized).
- the vector control device for an induction motor according to the present invention is applied to a motor control device for an electric vehicle, a vector control system capable of stably driving the electric vehicle up to a high speed at which the output voltage of the low-speed inverter is saturated is obtained.
- a vector control device for an induction motor suitable for an electric vehicle that can minimize the inverter loss and reduce the size and weight of the inverter.
- a vector control method for an induction motor is a vector control method for driving and controlling an induction motor (6) via an inverter (4),
- the maximum voltage that can be generated by the inverter (4) based on the torque command of the external force, the DC voltage input to the inverter (4), and the inverter angular frequency that is the angular frequency of the AC voltage output by the inverter (4) The step of calculating the secondary magnetic flux command for the induction motor (6) in consideration of the motor and the dq axis rotation coordinate system based on the secondary magnetic flux of the induction motor (6) based on the torque command and the secondary magnetic flux command Based on the q-axis current command and d-axis current command generation step above, and the q-axis current command, d-axis current command and the circuit constants of the induction motor, the output voltage to be output by the inverter (4) is calculated.
- the drive control device for an induction motor includes an inverter (4) for driving and controlling the induction motor (6), a torque command for an external force, a DC voltage input to the inverter (4), Based on the inverter angular frequency that is the angular frequency of the AC voltage output by the inverter (4), the secondary magnetic flux command for calculating the secondary magnetic flux command for the induction motor (6) in consideration of the maximum voltage that can be generated by the inverter (4) Based on the magnetic flux command calculation means (40), the torque command and the secondary magnetic flux command, the q-axis current command and the d-axis current on the dq-axis rotating coordinate system based on the secondary magnetic flux of the induction motor (6) Q-axis Zd-axis current command generation means (8, 9), q-axis current command, d-axis current command, and the output to be output by the inverter (4) based on the circuit constants of the induction motor (6) Output voltage calculation means
- an induction motor capable of performing stable vector control over the entire region from the low speed region to the high speed region of the induction motor without using a feedback loop to generate the secondary magnetic flux command. This is useful for realizing a vector control device for an electric motor.
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Control Of Ac Motors In General (AREA)
Description
Claims
Priority Applications (8)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US12/306,833 US7723944B2 (en) | 2006-07-06 | 2006-08-03 | Vector control device of induction motor, vector control method of induction motor, and drive control device of induction motor |
KR1020087027607A KR101046042B1 (ko) | 2006-07-06 | 2006-08-03 | 유도 전동기의 벡터 제어 장치, 유도 전동기의 벡터 제어 방법 및 유도 전동기의 구동 제어 장치 |
CN2006800551690A CN101479925B (zh) | 2006-07-06 | 2006-08-03 | 感应电动机的矢量控制装置、感应电动机的矢量控制方法及感应电动机的驱动控制装置 |
JP2007533304A JP4065903B2 (ja) | 2006-07-06 | 2006-08-03 | 誘導電動機のベクトル制御装置、誘導電動機のベクトル制御方法および誘導電動機の駆動制御装置 |
ES06782257T ES2423946T3 (es) | 2006-07-06 | 2006-08-03 | Aparato de control vectorial para motor de inducción, método de control vectorial para motor de inducción, y aparato de control de accionamiento para motor de inducción |
EP06782257.7A EP2040371B1 (en) | 2006-07-06 | 2006-08-03 | Vector control apparatus for induction motor, vector control method for induction motor, and drive control apparatus for induction motor |
CA2654277A CA2654277C (en) | 2006-07-06 | 2006-08-03 | Vector control device of induction motor, vector control method of induction motor, and drive control device of induction motor |
HK09110273.8A HK1132588A1 (en) | 2006-07-06 | 2009-11-05 | Vector control apparatus for induction motor, vector control method for induction motor, and drive control apparatus for induction motor |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/JP2006/313478 WO2008004294A1 (fr) | 2006-07-06 | 2006-07-06 | Dispositif de commande de vecteur de moteur à induction, procédé de commande de vecteur de moteur à induction, et dispositif de commande d'entraînement de moteur à induction |
JPPCT/JP2006/313478 | 2006-07-06 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2008004316A1 true WO2008004316A1 (fr) | 2008-01-10 |
Family
ID=38894272
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/JP2006/313478 WO2008004294A1 (fr) | 2006-07-06 | 2006-07-06 | Dispositif de commande de vecteur de moteur à induction, procédé de commande de vecteur de moteur à induction, et dispositif de commande d'entraînement de moteur à induction |
PCT/JP2006/315397 WO2008004316A1 (fr) | 2006-07-06 | 2006-08-03 | Appareil de commande vectorielle, procédé de commande vectorielle et appareil de commande d'entraînement pour moteur à induction |
Family Applications Before (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/JP2006/313478 WO2008004294A1 (fr) | 2006-07-06 | 2006-07-06 | Dispositif de commande de vecteur de moteur à induction, procédé de commande de vecteur de moteur à induction, et dispositif de commande d'entraînement de moteur à induction |
Country Status (10)
Country | Link |
---|---|
US (1) | US7723944B2 (ja) |
EP (1) | EP2040371B1 (ja) |
JP (1) | JP4065903B2 (ja) |
KR (1) | KR101046042B1 (ja) |
CN (1) | CN101479925B (ja) |
CA (1) | CA2654277C (ja) |
ES (1) | ES2423946T3 (ja) |
HK (1) | HK1132588A1 (ja) |
RU (1) | RU2392732C1 (ja) |
WO (2) | WO2008004294A1 (ja) |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2010093931A (ja) * | 2008-10-07 | 2010-04-22 | Mitsubishi Heavy Ind Ltd | 永久磁石型同期モータの制御装置及び制御方法 |
JP2017189087A (ja) * | 2016-04-01 | 2017-10-12 | エルエス産電株式会社Lsis Co., Ltd. | 電流指令補正装置 |
US10014811B2 (en) | 2016-04-01 | 2018-07-03 | Lsis Co., Ltd. | Apparatus for correcting current reference |
JP6328280B1 (ja) * | 2017-01-25 | 2018-05-23 | 三菱電機株式会社 | 2重巻線型回転電機の制御装置 |
JP2018121428A (ja) * | 2017-01-25 | 2018-08-02 | 三菱電機株式会社 | 2重巻線型回転電機の制御装置 |
Also Published As
Publication number | Publication date |
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KR101046042B1 (ko) | 2011-07-01 |
HK1132588A1 (en) | 2010-02-26 |
ES2423946T3 (es) | 2013-09-25 |
WO2008004294A1 (fr) | 2008-01-10 |
CN101479925A (zh) | 2009-07-08 |
KR20080110669A (ko) | 2008-12-18 |
JPWO2008004316A1 (ja) | 2009-12-03 |
CA2654277C (en) | 2012-05-15 |
US7723944B2 (en) | 2010-05-25 |
CA2654277A1 (en) | 2008-01-10 |
US20090256518A1 (en) | 2009-10-15 |
CN101479925B (zh) | 2011-05-25 |
EP2040371B1 (en) | 2013-05-01 |
RU2392732C1 (ru) | 2010-06-20 |
EP2040371A4 (en) | 2012-04-25 |
JP4065903B2 (ja) | 2008-03-26 |
EP2040371A1 (en) | 2009-03-25 |
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