CN108075707B - Asynchronous motor restarting method and system based on V/f control mode - Google Patents

Abstract

The invention discloses an asynchronous motor restarting method and system based on a V/f control mode, wherein in the V/f control mode, the synchronous frequency is continuously swept from the highest frequency to the lowest frequency, based on an equivalent circuit of an asynchronous motor, the stator voltage under the current frequency close to the open circuit condition of an excitation branch is given, the voltage is treated to be a given stator voltage, and whether the synchronous frequency is close to the actual operation frequency of the motor is judged according to the change condition of output current. When the stator current is obviously reduced, the synchronous frequency is judged to be close to the actual running speed of the motor, then the given voltage is gradually increased to the control voltage of the normal V/f through the voltage gradual change mode, and then the normal V/f control mode is switched to enter, the whole starting process is stable, and no current overshoot exists. The method does not need a hardware circuit, does not need to additionally increase a current closed-loop PI controller, has stronger universality, is easy to realize, and has better application prospect.

Description

Asynchronous motor restarting method and system based on V/f control mode

Technical Field

The invention relates to the asynchronous motor control technology, in particular to a restarting method and a restarting system of an asynchronous motor based on a V/f control mode.

Background

In the field of asynchronous motor control, there may be occasions where the motor is started under a free rotation condition, such as a fan that rotates freely under the action of external wind power, and a free-sliding electric locomotive. Since the rotation speed of the controlled object is unknown at this time, if the controlled object is directly started, the rotation difference is too large, so that the overcurrent is caused, and the starting failure is caused.

For the motor with the speed sensor, the real rotating speed of the motor can be directly obtained through the speed sensor, and the motor is directly started under the condition that the rotating speed corresponds to the synchronous frequency. For a motor without a speed sensor, the real rotating speed of the motor needs to be indirectly acquired by a certain method, so that the running slip of the motor under a given frequency is in a controllable range, and then the normal control flow is switched, and the process is generally called rotating speed capturing restart in asynchronous motor control (called asynchronous motor restart for short).

Currently there are two main approaches to restart asynchronous motors:

one method is to add a hardware voltage capture circuit, a rotating motor can generate counter electromotive force at a stator port under the action of residual magnetism during short-time shutdown or residual magnetism generated by external given excitation, and the frequency of the counter electromotive force is judged through the hardware voltage capture circuit so as to acquire the current rotating speed of the motor. The method needs to add a hardware circuit, and the hardware cost of the system is increased.

One method is a software processing method, and is based on the operating characteristics of the asynchronous motor, namely the characteristic that the impedance of a rotor branch in an equivalent circuit of the asynchronous motor is remarkably increased when the synchronous speed of the motor is close to the rotating speed of the motor. By introducing a current closed-loop controller and adopting a frequency sweeping method, namely, the given synchronous frequency is swept step by step from large to small, when the synchronous frequency corresponding to the synchronous speed approaches to the actual rotating speed of the motor, the current is rapidly reduced, and the given frequency is judged to finish the capture of the motor speed. The method needs to add a current closed-loop PI regulator, and because of different motors of the control object and different change rates of the sweep frequency, the fixed PI value is difficult to ensure to adapt to all occasions.

Disclosure of Invention

In view of the above, it is desirable to provide a method and a system for restarting an asynchronous motor, which are highly versatile and easy to implement.

The invention provides an asynchronous motor restarting method based on a V/f control mode, which comprises the following steps:

s1, continuously sweeping the frequency of the synchronization from the highest frequency to a small frequency in a V/f control mode;

s2, calculating the stator voltage close to the open circuit condition of the excitation branch circuit under the current sweep frequency based on the model and the operating characteristics of the asynchronous motor;

s3, taking the stator voltage as a stator given voltage, and judging and obtaining the actual rotating speed of the motor according to the change condition of the output current;

and S4, gradually increasing the given voltage to the control voltage of the normal V/f through the voltage gradient mode, and switching into the normal V/f control mode.

The system for restarting the asynchronous motor based on the V/f control mode comprises the following functional modules:

the frequency sweeping module is used for continuously sweeping the frequency of the synchronous frequency from the highest frequency to a small frequency in a V/f control mode;

the open-circuit voltage determination module is used for calculating the stator voltage when the current sweep frequency is close to the open-circuit condition of the excitation branch circuit based on the model and the operating characteristics of the asynchronous motor;

the motor rotating speed acquisition module is used for judging and acquiring the actual rotating speed of the motor according to the change condition of the output current by taking the stator voltage as the stator given voltage;

and the voltage switching module is used for gradually increasing the given voltage to the control voltage of the normal V/f through the voltage gradient mode and then switching into the normal V/f control mode.

The invention relates to an asynchronous motor restarting method and system based on a V/f control mode, which continuously sweep frequency from maximum frequency to small in the V/f control mode, give stator voltage under the current frequency close to the open circuit condition of an excitation branch circuit based on an asynchronous motor equivalent circuit, use the voltage as stator given voltage after certain processing, and judge whether the synchronous frequency is close to the actual operation frequency of a motor according to the change condition of output current. When the stator current is obviously reduced, the synchronous frequency is judged to be close to the actual running speed of the motor, then the given voltage is gradually increased to the control voltage of the normal V/f through the voltage gradual change mode, and then the normal V/f control mode is switched to enter, the whole starting process is stable, and no current overshoot exists. The method does not need a hardware circuit, does not need to additionally increase a current closed-loop PI controller, has stronger universality, is easy to realize, and has better application prospect.

Drawings

FIG. 1 is a block flow diagram of a method for restarting an asynchronous motor based on a V/f control mode according to the present invention;

FIG. 2 is an equivalent circuit of a T-type asynchronous motor;

FIG. 3 is a flow chart illustrating the steps of a method for restarting an asynchronous motor based on a V/f control mode according to the present invention;

fig. 4 is a waveform of restart of the asynchronous motor at each speed stage.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the accompanying drawings and embodiments, it being understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

The invention provides an asynchronous motor restarting method based on a V/f control mode, as shown in figure 1, the asynchronous motor restarting method based on the V/f control mode comprises the following steps:

s1, continuously sweeping the frequency of the synchronization from the highest frequency to a small frequency in a V/f control mode;

s2, calculating the stator voltage close to the open circuit condition of the excitation branch circuit under the current sweep frequency based on the model and the operating characteristics of the asynchronous motor;

s3, taking the stator voltage as a stator given voltage, and judging and obtaining the actual rotating speed of the motor according to the change condition of the output current;

and S4, gradually increasing the given voltage to the control voltage of the normal V/f through the voltage gradient mode, and switching into the normal V/f control mode.

Wherein, the step S3 further includes the following sub-steps:

s31, correcting the stator voltage close to the open circuit condition of the excitation branch circuit to be used as the stator voltage given value under the current sweep frequency;

s32, when the rotating speed of the motor is close to the real rotating speed of the motor, the rotor branch impedance is increased and the stator current is obviously reduced due to the fact that the slip is reduced;

and S33, when the stator current value is smaller than the judgment threshold value, the synchronous frequency is considered to be close to the actual rotating speed of the motor, and rotating speed capture is further completed.

Specifically, the basic principle of the rotation speed capture of the asynchronous motor applied by the invention is analyzed as follows:

in an asynchronous motor control system without a speed sensor, the rotating speed of a motor cannot be directly obtained, and accurate obtaining of the real running speed of the motor is a premise for realizing normal restarting, so that the rotating speed of the motor needs to be indirectly obtained based on a model and running characteristics of the asynchronous motor.

The T-shaped equivalent circuit of the asynchronous motor is shown in figure 2: in the figure, the position of the upper end of the main shaft,

is a voltage of a stator phase and is,

is a stator phase current, R_sIs stator resistance, R_rIs rotor resistance, L_sσFor stator leakage inductance, L_rσFor rotor leakage inductance, L_mIs an excitation inductance, s is the slip ratio of the asynchronous motor,

n₁the synchronous speed of the motor is shown, and n is the actual rotating speed of the rotor of the motor.

When the stator gives the synchronous frequency f, known from the equivalent circuit of the asynchronous motor₁Corresponding to the synchronous speed n of the motor₁(

p is the number of pole pairs of the motor) and the actual rotating speed n of the motor are larger, because the slip is larger, the rotor resistance is far smaller than the excitation branch, the excitation branch is similar to an open circuit, and the relation between the stator voltage and the stator current is similar to the following:

wherein, U_sσFor stator phase voltage effective value, U, under the condition of excitation branch being approximately open-circuit_sIs the effective value of the stator phase voltage, I_sIs the effective value of stator phase current, omega₁For the electrical angular frequency (omega) of the motor₁＝2πf₁)。

When the synchronous frequency of the motor is close to the real rotating speed of the motor corresponding to the synchronous speed, the slip ratio is close to 0, the impedance of the rotor branch is obviously increased, the rotor branch is similar to an open circuit, and the relation between the stator winding voltage and the stator current of the asynchronous motor is similar to that:

wherein, U_smEffective value of stator phase voltage under condition of rotor branch approximate open circuit

In the asynchronous motor, the exciting inductance value is far larger than the leakage inductance value of the stator and the rotor. Generally, under the same current value, when the sweep frequency of the asynchronous motor is corresponding to the synchronous speed and is close to the real rotating speed of the motor, the required voltage value is far larger than the voltage value U when the rotating difference value is larger_sm＞＞U_sσ。

In other words, if the given voltage of the stator port is given according to the voltage value under the condition that the excitation branch is approximately open-circuit in the frequency sweeping stage, when the synchronous speed is close to the real rotating speed of the motor, the stator current of the motor can be greatly reduced.

The invention carries out the capture and restart of the rotating speed of the asynchronous motor based on the basic principle, namely, the voltage value of the port of the equivalent circuit is calculated when the excitation branch is approximately open-circuit under different sweep frequencies based on the resistance and the leakage inductance value of the stator and the rotor of the asynchronous motor. The value is used as a stator voltage given value under the current sweep frequency after correction, when the rotating speed of the motor is close to the real rotating speed of the motor, the rotor branch impedance is increased due to the fact that the slip is reduced, the stator current is obviously reduced, when the stator current value is smaller than a judgment threshold value, the synchronous frequency is considered to be close to the actual rotating speed of the motor, and then rotating speed capture is completed.

According to the basic principle of indirectly acquiring the rotating speed of the motor based on the model and the operating characteristics of the asynchronous motor, the method for realizing the restarting of the asynchronous motor comprises the following steps:

as shown in fig. 3, the whole process of restarting the asynchronous motor in the V/f control mode of the asynchronous motor is realized by the following stages:

stage 1: demagnetization waiting delay phase

The stage is to carry out a section of waiting time delay before wave generation, so that the overcurrent condition caused by the existence of the residual magnetism back electromotive force of the asynchronous motor is prevented when the controller is put into use. And after the time delay is finished, entering a sweep current rising stage.

And (2) stage: sweep voltage rise processing stage

In the phase, the initial value of current in the frequency sweep phase is set

(this value is preferably the motor rated field current value I_mNWhen the freely rotating motor speed may exceed the motor rated speed, this value may be suitably reduced) and the sweep start frequency f_{1_H}(corresponding to the electrical angular frequency ω_{1_H}＝2πf_{1_H}) And calculating the stator voltage value U under the condition that the expected excitation branch is approximately opened (the slip is large) at the current value by the formula (1)_{sσ_H}。

Gradually increasing the stator given voltage, observing the detected current value, and comparing the detected actual stator current value with the current initial value set in the frequency sweep stage

When the difference is less than a certain threshold (preferably 1% of the rated current of the motor), after a certain time delay, recording the actually given sweep frequency voltage at the moment

And entering a frequency sweeping phase.

The stator frequency and stator voltage at this stage are given by the following formula

Wherein the content of the first and second substances,

for stator voltage set-point in phase 2, τ_rIs a value of rotor time constant

L_rRotor inductance), K_tFor adjusting the voltage rise rate (preferably 2), T, in this phase by a time coefficient_sampleTo control the sampling time of the system.

In the formula (3), the increment of the stator voltage simultaneously considers the difference between the rotor time constant and the current and the given current, and the voltage rise can be combined with the current response of the motor by introducing the rotor time constant, so that the condition that the node voltage enters the next stage due to unstable voltage possibly caused by controlling the motor time constant to be different under fixed rising frequency is avoided. The introduction of the current difference value enables the closer the actual current is to the given current value, the smaller the voltage increment, and the situation of current overshoot is avoided.

And (3) stage: sweep frequency and rotation speed capturing stage

In the phase, the given frequency is swept from the starting high frequency of the phase 2 to the high frequency, the stator is given voltage, and the error of the motor parameter is considered, and the starting voltage of the actual sweep phase and the calculated voltage based on the equivalent circuit of the motor are combined to perform approximate geometric proportion.

The frequency and voltage of the sweep phase are given as follows:

wherein f is₁ ^*For the given value of the sweep frequency in the third stage,

for stator voltage set point in phase 3, U_sσIs calculated by formula (1)Obtaining the current sweep frequency f₁ ^*The lower desired excitation branch approximates the value of the stator voltage in the open circuit (greater slip) condition.

When the sweep frequency is close to the real rotation speed of the motor corresponding to the synchronous speed, the stator current is reduced rapidly, and when the stator current is smaller than the judgment threshold delta I_LWhen (Delta I)_LThe value range can be set to 50% -10%, and the sweep current initial value is preferred here

25%) of the current synchronous frequency is considered to be close to the real rotating speed of the motor, the speed capture is completed, and the normal process transition processing stage is jumped to.

At this stage, when the sweep frequency is lower than the capture lower limit frequency f_{1_L}(preferably 5% of the rated frequency of the motor), the motor is considered to be static, and the system directly jumps to the 0-frequency starting process.

And (4) stage: transition processing stage from capture process to normal operation process

In the stage, given frequency is not changed, and output voltage value U corresponding to the frequency of a normal V/f curve is calculated_sAnd taking the voltage value as a target value, and gradually changing the voltage value to the voltage value in the sweep frequency stage. The voltage ramp formula is as follows:

when in use

And then, finishing the transition process, jumping the system into a normal V/f control flow, and finishing the rotation speed capturing and restarting process of the asynchronous motor.

The restarting method of the asynchronous motor based on the V/F control mode is realized on a control platform taking a DSP control chip of TI company model F28335 as a main control chip, a 132kW three-phase alternating current asynchronous motor is adopted as a test platform, the rated voltage of the motor is 380V, the rated current 242A, 2 antipodes, the rated frequency is 50Hz, and the rated rotating speed is 1490 r/min. In the test, firstly, the motor is accelerated to a certain rotating speed and stably runs through a normal V/f control mode, then the controller is sealed to enable the controller to enter a free stop state, the motor is started in a rotating speed capturing and restarting mode, the actual rotating speed of the motor is observed through the encoder, and the actual current of the motor is obtained through the controller sampling circuit. The restart operation test is respectively carried out in three speed sections of high speed, middle speed and low speed of the motor, the given frequency, the motor speed, the motor current and the given voltage data in the whole process are recorded by the controller and are led into Matlab to draw process waveforms as shown in figure 4, wherein the speed base value is 1500r/min, and the frequency, the voltage and the current base value are rated values corresponding to the measured motor, wherein figure 4(a) shows a restart waveform diagram of the asynchronous motor in the high speed stage, figure 4(b) shows a restart waveform diagram of the asynchronous motor in the middle speed stage, and figure 4(c) shows a restart waveform diagram of the asynchronous motor in the low speed stage.

Test results show that the restarting method of the asynchronous motor based on the V/f control mode realizes normal restarting operation in high, middle and low frequency bands, the starting process is stable, and no current overshoot exists. The test results show the effectiveness of the method.

Based on the above method for restarting the asynchronous motor under the V/f control mode, the invention also provides a system for restarting the asynchronous motor under the V/f control mode, wherein the system for restarting the asynchronous motor under the V/f control mode comprises the following functional modules:

the frequency sweeping module is used for continuously sweeping the frequency of the synchronous frequency from the highest frequency to a small frequency in a V/f control mode;

the open-circuit voltage determination module is used for calculating the stator voltage when the current sweep frequency is close to the open-circuit condition of the excitation branch circuit based on the model and the operating characteristics of the asynchronous motor;

the motor rotating speed acquisition module is used for judging and acquiring the actual rotating speed of the motor according to the change condition of the output current by taking the stator voltage as the stator given voltage;

and the voltage switching module is used for gradually increasing the given voltage to the control voltage of the normal V/f through the voltage gradient mode and then switching into the normal V/f control mode.

Wherein, the motor speed acquisition module further comprises the following functional units:

the voltage correction unit is used for correcting the stator voltage close to the condition of an open circuit of the excitation branch circuit to be used as the given value of the stator voltage under the current sweep frequency;

the rotating speed pre-judging unit is used for enabling the rotor branch impedance to be increased and the stator current to be obviously reduced due to the fact that the slip is reduced when the rotating speed of the motor is close to the real rotating speed of the motor;

and the rotating speed determining unit is used for considering that the synchronous frequency is close to the actual rotating speed of the motor when the current value of the stator is smaller than the judgment threshold value, and further completing rotating speed capture.

The invention relates to an asynchronous motor restarting method and system based on a V/f control mode, which continuously sweep frequency from maximum frequency to small in the V/f control mode, give stator voltage under the current frequency close to the open circuit condition of an excitation branch circuit based on an asynchronous motor equivalent circuit, use the voltage as stator given voltage after certain processing, and judge whether the synchronous frequency is close to the actual operation frequency of a motor according to the change condition of output current. When the stator current is obviously reduced, the synchronous frequency is judged to be close to the actual running speed of the motor, then the given voltage is gradually increased to the control voltage of the normal V/f through the voltage gradual change mode, and then the normal V/f control mode is switched to enter, the whole starting process is stable, and no current overshoot exists. The method does not need a hardware circuit, does not need to additionally increase a current closed-loop PI controller, has stronger universality, is easy to realize, and has better application prospect.

The above apparatus embodiments and method embodiments are in one-to-one correspondence, and reference may be made to the method embodiments for a brief point of the apparatus embodiments.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative components and steps have been described above generally in terms of their functionality in order to clearly illustrate this interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. A software module may reside in random access memory, read only memory, electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

While the present invention has been described with reference to the embodiments shown in the drawings, the present invention is not limited to the embodiments, which are illustrative and not restrictive, and it will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (8)

1. A restarting method of an asynchronous motor based on a V/f control mode is characterized by comprising the following steps:

s1, demagnetization waiting delay stage; specifically, the method comprises the following steps of waiting for the completion of delay before wave sending, and entering the next step;

s2 sweep frequency voltage rising processing stage; specifically, the method comprises the steps of setting a current initial value and a sweep frequency starting frequency of a sweep frequency stage; calculating the stator voltage value under the condition that the current expected excitation branch of the asynchronous motor is approximately open-circuit; the sweep frequency starting frequency is a given frequency, the given frequency is unchanged, a given voltage value is gradually increased, and when the actual value of the detected stator current meets the requirement of a set threshold value, the actual given voltage at the moment is recorded;

s3, frequency sweeping and rotating speed capturing stages; continuously sweeping the given frequency from high to low, and finishing speed capture when the given frequency is close to the real rotating speed of the motor in the sweeping stage;

s4, transition processing stage from the capture process to the normal operation process; specifically, the frequency sweep stage given frequency is unchanged, the actual given voltage corresponding to the frequency sweep stage given frequency is gradually increased to the control voltage of normal V/f through a voltage gradient mode, and then the normal V/f control mode is switched into.

2. The V/f control mode-based asynchronous motor restarting method according to claim 1 wherein said step S3 further comprises the sub steps of:

s31, calculating the stator voltage value under the condition that the corresponding excitation branch is approximately open-circuit under the current given frequency;

and S32, observing and detecting the stator current, and when the stator current is smaller than a judgment threshold value, the given frequency of the current frequency sweep stage is close to the real rotating speed of the motor.

3. The V/f control mode-based asynchronous motor restarting method according to claim 1 wherein in steps S3, S4 the frequency and voltage of the frequency sweep phase are given as follows:

f₁ ^*for a given value of the frequency of the sweep in the sweep phase, f_NTsample is the sampling time of the control system, N is the number of beats of program discretization operation, N is the current beat, N +1 is the next beat, τ r is the value of the rotor time constant,

for stator voltage set-point in sweep-frequency phase, U_sσFor the current frequency f of the sweep₁ ^*Stator voltage value in the case of an approximately open circuit of the lower desired excitation branch, f₁ ^*The initial value of (N) is the initial frequency f of the sweep frequency_1H,

To sweep the initial frequency f_1HNext, the actual output steady-state current of the system is close to the initial value of the current in the set frequency sweep stage

Given voltage value U of time_{sσ_H}The voltage under the condition of an approximate open circuit of the excitation branch is calculated by a formula:

where ω 1 Is an electrical angular frequency (ω 1 ═ 2 pi f1) Rs of the motor, Rr Is a rotor resistance, Ls σ Is a stator leakage inductance, Lr σ Is a rotor leakage inductance, and Is an effective value of a stator phase current.

4. The V/f control mode-based restart method for an asynchronous motor according to claim 1, wherein the voltage gradient formula in step S4 is as follows:

KI is a time coefficient used for adjusting the voltage rising speed in the phase.

5. An asynchronous motor restart system based on a V/f control mode, comprising:

the demagnetization waiting module is used for inserting a section of waiting time delay before the wave sending of the controller; the sweep frequency voltage rise processing module is used for setting a current initial value and a sweep frequency initial frequency of a sweep frequency stage; calculating the stator voltage value under the condition that the current expected excitation branch of the asynchronous motor is approximately open-circuit; the sweep frequency starting frequency is a given frequency, the given frequency is unchanged, a given voltage value is gradually increased, and when the actual value of the detected stator current meets the requirement of a set threshold value, the actual given voltage at the moment is recorded;

the motor rotating speed acquisition module is used for continuously sweeping the given frequency from high to low, and the speed capture is completed when the given frequency is close to the real rotating speed of the motor in the sweeping stage; and the voltage switching module is used for gradually increasing the actual given voltage corresponding to the given frequency of the frequency sweeping stage to the control voltage of the normal V/f through a voltage gradient mode without changing the given frequency of the frequency sweeping stage, and then switching into the normal V/f control mode.

6. The V/f control mode-based asynchronous motor restarting system according to claim 5 wherein the motor speed acquisition module further comprises the following functional units:

the voltage correction unit is used for calculating the stator voltage value under the condition that the corresponding excitation branch is approximately open-circuit at the current given frequency;

and the rotating speed capturing and judging unit is used for observing and detecting the stator current, and when the stator current is smaller than a judging threshold value, the given frequency of the current frequency sweeping stage is close to the real rotating speed of the motor.

7. The V/f control mode-based asynchronous motor restarting system according to claim 5 wherein the frequency and voltage of the frequency sweep stage in the motor speed acquisition module is given by:

f₁ ^*for a given value of the frequency of the sweep in the sweep phase, f_NTsample is the sampling time of the control system, and N isThe number of beats of program discretization operation, N is the current beat, N +1 is the next beat, τ r is the value of rotor time constant,

for stator voltage set-point in sweep-frequency phase, U_sσFor the current frequency f of the sweep₁ ^*Stator voltage value in the case of an approximately open circuit of the lower desired excitation branch, f₁ ^*The initial value of (N) is the initial frequency f of the sweep frequency_1H,

To sweep the initial frequency f_1HNext, the actual output steady-state current of the system is close to the initial value of the current in the set frequency sweep stage

Given voltage value U of time_{sσ_H}The voltage under the condition of an approximate open circuit of the excitation branch is calculated by a formula:

where ω 1 Is an electrical angular frequency (ω 1 ═ 2 pi f1) Rs of the motor, Rr Is a rotor resistance, Ls σ Is a stator leakage inductance, Lr σ Is a rotor leakage inductance, and Is an effective value of a stator phase current.

8. The system for restarting the asynchronous motor under the V/f control mode according to claim 5, wherein a voltage gradient formula in the motor speed obtaining module is as follows:

KI is a time coefficient used for adjusting the voltage rising speed in the phase.

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