KR20080019131A - Electric motor using a voltage control device and method for controlling thereof - Google Patents

Abstract

An induction motor using a voltage control device and a method for controlling the same are provided to perform maximum torque operation with a stator magnetic flux reference control method in a field weakening region of a system with variable battery voltage such as an electric forklift. An induction motor(160) includes a current generating unit(100), a magnetic flux compensating unit(110), and a voltage control device(130). The current generating unit generates q axis current of the induction motor. The magnetic flux compensating unit generates d axis current of the induction motor and controls a stator magnetic flux reference. The voltage control device receives q axis voltage and d axis voltage corresponding to the q axis current and the d axis current and outputs reference voltage for generating the maximum torque of the induction motor. The magnetic flux compensating unit controls battery voltage to follow the reference voltage to apply the controlled battery voltage to the induction motor.

Description

Induction motor using voltage controller and its control method {ELECTRIC MOTOR USING A VOLTAGE CONTROL DEVICE AND METHOD FOR CONTROLLING THEREOF}

1 is an overall block diagram of a stator flux reference induction motor according to a preferred embodiment of the present invention.

2 is a voltage waveform diagram of a voltage controller showing that the actual speed is normally driven even when the maximum voltage of the induction motor is changed in a certain torque region according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings

100: current generating unit 110: magnetic flux control unit

130: voltage controller 140: two-phase / three-phase conversion unit

150: PWM inverter 160: induction motor

170: encoder

The present invention relates to an induction motor, and more particularly, an induction motor that follows a reference voltage (V _{s - ref} ) in a field weakening region so that maximum torque can be generated based on a stator flux. An induction motor using a controller and a control method thereof.

As is well known, induction motor control in the field weakening region refers to extending the operating speed range of the motor while driving along the maximum torque operating point in a voltage and current limited environment.

In order to obtain the maximum torque in the field weakening area of the conventional induction motor, it is important to select a reference magnetic flux. In order to obtain the maximum torque, the conventional stator flux reference control method first calculates the reference speed and uses a method of reducing the reference flux (1 / ωr) so as to be inversely proportional to the rotor speed in the field weakening area. This is because the stator flux changes depending on the accuracy of the stator resistance, but in general, the stator resistance can be obtained relatively accurately and has little change with temperature. That is, the stator flux reference control has an advantage in that all variables can be conveniently expressed using the stator flux as a reference axis.

As a method of estimating magnetic flux according to the stator flux reference control, there are a rotor flux reference control and a void flux reference control method. However, the rotor flux reference control method and the void flux reference control method are less accurate than the stator flux reference control method due to leakage inductance. In particular, the rotor resistance has a large variation in temperature and skin effect. There is a problem in that the loss of orthogonality between the overcurrent vector and the loss of control performance of the induction motor. Accordingly, the stator flux reference control was able to effectively control the control performance of the motor compared to the rotor flux reference control and the air gap flux reference control.

However, the stator flux reference control method simply reduces the reference magnetic flux only, and uses a reference flux that does not consider the voltage limiting condition and the torque control condition of the induction motor.

In order to solve this problem, a new reference flux estimator considering the voltage and torque constraints is proposed to enable maximum torque generation. The method is based on the method of selecting the optimal reference flux for stator flux reference control of induction motors in the field weakening area. (July, 2000.7.19 ~ 22. Has been announced.

However, the reference flux estimator was inefficient in equipment using a battery (Vdc) power source such as an electric forklift. Equipment such as the electric forklift should be operated normally by applying the optimal reference voltage for a certain time even when the charging rate of the battery power is reduced, or even if it is to accelerate or decelerate momentarily. However, according to the reference flux estimator, the equipment which continuously changes the battery voltage could not apply the optimal reference voltage for the load variation.

In this way, the proposed reference flux estimator could not obtain the maximum torque in the field weakening area in the equipment where power is not kept constant, such as an electric forklift truck that requires a large torque at a moment or changes the driving speed.

Therefore, the present invention has been made to solve the above problems, induction motor using a voltage controller for controlling the maximum torque operation by the optimum reference voltage in the field weakening field in the environment where information on the motor constant is not provided And a control method thereof.

According to a feature of the present invention for achieving the above object, a current generating unit for generating a q-axis current of the induction motor, a magnetic flux compensation unit for generating a d-axis current of the induction motor and stator flux reference control, the q-axis current and and a voltage controller configured to receive a q-axis voltage and a d-axis voltage corresponding to a d-axis current, respectively, and output a reference voltage (V _{s - ref} ) for generating the maximum torque of the induction motor, wherein the magnetic flux compensating unit includes the reference voltage Its technical feature is to control the battery voltage to follow (V _{s - ref} ) and apply it to the induction motor.

The current generator includes a first subtractor for outputting a speed error value by subtracting the command speed ωr * and the rotational speed ωr of the actual induction motor, and performing a proportional integration to compensate for the speed error value, thereby performing q-axis synchronization coordinates. a first proportional-integral (PI) controller and the q-axis synchronous coordinate current (i ^e qs) and preset condition value q-axis synchronous coordinate reference current (i ^e qs *) by outputting a current (i ^e qs) A torque limiter for outputting, a second subtractor for outputting a speed error value by subtracting the q-axis synchronous coordinate reference current i ^e qs * and the q-axis synchronous coordinate current i ^e qs, and compensating for the speed error value And a adder for outputting the q-axis current by adding the value of equation (1) to the output value of the second PI controller.

ω _e λ ^e ds --- Equation (1) (ω _e : synchronous angular frequency, λ ^e ds: magnetic flux)

The condition value includes a maximum current value Is_max, d-axis synchronous coordinate flux information λ ^e ds, a q-axis synchronous coordinate current i ^e q, and a slip frequency ω _sl .

The flux controller may generate the d-axis current, and been provided with the reference voltage _{(V-s ref)} from the voltage controller and the reference _{voltage-controls} the voltage applied to the induction motor so as to follow the (V _{s ref).} Such a magnetic flux control section includes a third subtractor for outputting a voltage error value by subtracting the battery voltage and the reference voltage (V _{s - ref} ), and correcting the voltage error value to generate the d-axis synchronous coordinate reference flux (λ ^{e *} ds). And a fourth subtractor for outputting a voltage error value by subtracting the d-axis synchronous coordinate reference flux λ ^{e *} ds and the d-axis synchronous coordinate flux λ ^e ds. A fourth PI controller that proportionally integrates the voltage error value to correct the voltage error value of the subtractor, and d / q-axis currents to compensate for the error of the stator flux reference control with respect to the output value of the fourth PI controller. i _dq) for compensation and the d-axis synchronous coordinate reference current (i ^{e *} d) the fifth subtracter and the d-axis synchronous coordinate reference current (i ^{e *} d) and the d-axis synchronous coordinate current and outputting a (i ^e d) A sixth subtractor for subtracting?, A fifth PI controller for controlling the output of the sixth subtractor, and a fifth PI controller And a seventh subtractor which generates the d-axis current with reference to the output information.

(V^*2 _d :d축 전압, V^*2 _q: q축 전압)이다.The reference voltage (V _{s - ref} ) is

(V ^* _2d : d-axis voltage, V ^* _2q : q-axis voltage).

In addition, according to another feature of the present invention for achieving the above object, the first step of receiving the q-axis voltage and the d-axis voltage of the induction motor to generate a reference voltage (V _{s - ref} ) for generating the maximum torque, the A second step of comparing a reference voltage (V _{s - ref} ) with a battery voltage, a third step of compensating an error of stator flux control such that the battery voltage follows the reference voltage (V _{s - ref} ), and the error compensated And a fourth step of supplying a battery voltage to the induction motor.

The q-axis current, the reference speed (ωr *) and the actual induction rotation speed (ωr) step, proportionally integrating the speed error value that is output from the subtraction step the q-axis synchronous coordinate current (i ^e qs) for subtracting the electric motor Outputting the q-axis synchronous coordinate reference current i ^e qs * according to the q-axis synchronous coordinate current i ^e qs and a preset condition value, and outputting the q-axis synchronous coordinate reference current i ^e qs *) and subtracting the q-axis synchronous coordinate current (i ^e qs) to output a speed error value, proportionally integrate the speed error value, and then omega _e λ ^e ds (ω _e : synchronous angular frequency, λ ^e ds : Magnetic flux) is added and output. As the condition value, the maximum current value Is_max, the d-axis synchronous coordinate flux information λ ^e ds, the q-axis synchronous coordinate current i ^e q, and the slip frequency ω _sl are applied.

The error compensating step may include comparing an error between the reference voltage V _{s - ref} and a battery voltage, generating a d-axis magnetic flux component as a result of the comparison, and converting the d-axis magnetic flux component to a d-axis / q-axis current ( i _dq ).

The error compensating step may include outputting a voltage error value by subtracting a battery voltage and a reference voltage (V _{s - ref} ), and correcting the voltage error value to output a d-axis synchronous coordinate reference flux (λ ^{e *} ds). After subtracting the d-axis synchronous coordinate flux (λ ^e ds) and outputting the magnetic flux error value, the d-axis / q-axis current (i to compensate for the error in the stator flux reference control after proportionally integrating the magnetic flux error value compensating the _dq) and subtracting the d-axis synchronous coordinate reference current (i ^{e *} d) step, the d-axis synchronous coordinate reference current (i ^{e *} d) and the d-axis synchronous coordinate current (i ^e d) for outputting and that And controlling the error value outputted as a result of the subtraction to follow the battery voltage to the reference voltage V _{s - ref} .

According to the present invention having such a configuration, it can be seen that the maximum torque operation is possible in the field weakening region because the applied voltage controlled to follow the optimal reference voltage for generating the maximum torque is supplied to the induction motor. In addition, since the applied voltage is supplied following the reference voltage, the control of the device / system using the battery voltage which varies according to the operation control can be normally performed.

Hereinafter, an induction motor and a method of controlling the same using a voltage controller according to the present invention will be described in detail with reference to a preferred embodiment shown in the accompanying drawings.

FIG. 1 is a block diagram illustrating an entire stator flux reference induction motor according to a preferred embodiment of the present invention.

It should be noted that the present embodiment is provided with a voltage controller for controlling the applied voltage of the motor to follow the optimal reference voltage for generating the maximum torque. In addition, the experiment was conducted to drive the maximum speed of 3,000rpm for the 7.5 ㎾ spindle induction motor with a rated speed of 1,500rpm.

Referring to the drawings, a current generator 100 is provided which receives the command speed ωr * and generates q-axis current (related to speed / torque) of the induction motor. The current generator 100 includes a first subtractor 101 for outputting a speed error value by subtracting the command speed ωr * and the actual rotation speed ωr of the induction motor. A first proportional integral (PI) controller 102 for proportionally integrating and outputting the q-axis synchronous coordinate current i ^e qs to compensate for the speed error value is provided. A torque limiter 104 for outputting the q-axis synchronous coordinate reference current i ^e qs * based on the q-axis synchronous coordinate current i ^e qs and a preset condition value is provided. The condition value applied to the torque limiter 104 includes a maximum current value Is_max, d-axis synchronous coordinate flux information λ ^e ds, q-axis synchronous coordinate current i ^e q, and slip frequency ω _sl . It includes. And a second subtractor 106 for outputting a speed error value by subtracting the q-axis synchronous coordinate reference current i ^e qs * and the q-axis synchronous coordinate current i ^e qs, and compensating for the speed error value. A second PI controller 108 that is proportionally integrated. A first adder 109 is added to output the q-axis current by adding ω _e λ ^e ds (ω _e : synchronous angular frequency, λ ^e ds: magnetic flux) to the output value of the second PI controller 108.

A magnetic flux controller for generating a d-axis current (related to magnetic flux) of the induction motor and compensating a magnetic flux component to receive a reference voltage from the voltage controller 130 to be described later and control the voltage applied to the induction motor 160. 110 is provided. The magnetic flux controller 110 includes one or more subtractors and PI controllers for controlling the battery voltage to be supplied to the induction motor by following the reference voltage V _{s - ref} applied from the voltage controller 130.

이다(τr :회전자시정수, ω_sl:슬립각속도, i^eqs*:q축 동기좌표기준전류). 즉, 종래 고정자 자속 기준 제어로 사용된 디커플링(decoupling) 성분을 보상 전류로 보상하는 것이다. 계속해서, 상기 d축 동기좌표기준전류(i^{e *}d)와 d축 동기좌표전류(i^ed)를 감산하는 제 6 감산기(116)와, 상기 제 6 감산기(116) 제어하는 제 5 PI 제어기(117)가 구비된다. 그리고 상기 제 5 PI 제어기(117)의 출력정보를 참조하여 d축 전류를 생성하는 제 7 감산기(118)를 포함하여 구성된다. 이때 상기 제 7 감산기(118)에는 상기 제 5 PI 제어기(117)의 출력정보에 '(λ^eds/τr) +σL_sω_sli^eqs'정보가 가산된다. 여기서, τr :회전자시정수, σ:누설계수, Ls:고정자자기인덕턴스, ω_sl:슬립각속도를 나타낸다.Specifically, a third subtractor 111 for outputting a voltage error value by subtracting the battery voltage and the reference voltage V _{s - ref} is provided. A third PI controller 112 for correcting the voltage error value output from the third subtractor 111 and outputting a d-axis synchronous coordinate reference flux λ ^{e *} ds, and the third PI controller 112. And a fourth subtractor 113 for outputting a voltage error value by subtracting the d-axis synchronous coordinate reference flux λ ^{e *} ds and the d-axis synchronous coordinate flux λ ^e ds. In order to correct the voltage error value of the fourth subtractor 113, the stator flux reference control is performed on the fourth PI controller 114 which proportionally integrates the voltage error value and the output value of the fourth PI controller 114. A fifth subtractor 115 is provided to compensate the d-axis / q-axis current (i _dq ) and output the d-axis synchronous coordinate reference current (i ^{e *} d) to compensate for the error. The d-axis / q-axis current (i _dq ) is

(Τr: rotor time constant, ω _sl : slip angular velocity, i ^e qs *: q-axis synchronous coordinate reference current) That is, the decoupling component used in the stator flux reference control is compensated by the compensation current. Subsequently, a sixth subtractor 116 subtracts the d-axis synchronous coordinate reference current i ^{e *} d and the d-axis synchronous coordinate current i ^e d, and a fifth PI to control the sixth subtractor 116. The controller 117 is provided. And a seventh subtractor 118 that generates a d-axis current with reference to the output information of the fifth PI controller 117. In this case, '(λ ^e ds / τr) + σL _s ω _sl i ^e qs' information is added to the seventh subtractor 118 to the output information of the fifth PI controller 117. Where τr is the rotor time constant, sigma is the design factor, Ls is the fixed magnetic inductance, and _{sl is the} slip angular velocity.

(V^*2 _d :d축 전압, V^*2 _q: q축 전압)이다.The voltage controller 130 receives the q-axis voltage and the d-axis voltage corresponding to the q-axis current and the d-axis current to generate a reference voltage (V _{s - ref} ), and generates the reference voltage (V _{s - ref} ). Provided to the flux control unit 110 serves to supply the battery voltage to the induction motor 160 while following the reference voltage. The reference voltage (V _{s - ref} ) is

(V ^* _2d : d-axis voltage, V ^* _2q : q-axis voltage).

On the other hand, the voltage applied to the d-axis magnetic flux component current generated by following the q-axis torque component current output by the current generator 100 and the reference voltage (V _{s - ref} ) of the voltage controller 130, respectively. Receiving and converting the two-phase / three-phase voltage converter 140 and the three-phase voltage output from the two-phase / three-phase voltage converter 140 to drive the induction motor 160. PWM inverter 150 for converting the pulse width modulation signal is provided for.

And, the encoder 170 for calculating the rotational speed of the induction motor 160 is provided. A second adder 172 for outputting a synchronous angular frequency ω _e by adding the rotational speed calculated by the encoder 170 and a slip frequency ω _sl , and an angle output from the second adder 172. An integrator 174 is provided which integrates the frequency ω _e to output the magnetic flux phase θ _e . In addition, the q-axis current and d-axis current generated by the current generation unit 100 and the magnetic flux control unit 110, the q-axis synchronous coordinate current (i ^e qs) and the d-axis synchronous coordinate current (i ^e ds) is applied And a stator flux estimator 180 for outputting the d-axis synchronous coordinate magnetic flux lambda ^e ds. Here, since the second adder 172, the integrator 174, and the stator flux measuring unit 180 are not related to the operation description of the present embodiment, detailed description thereof will be omitted.

Hereinafter, an induction motor control method using a voltage controller according to an embodiment of the present invention having the configuration as described above will be described in detail.

The present embodiment is to control the optimal reference voltage for generating the maximum torque by using a voltage controller, so that the battery voltage is applied to the induction motor following the reference voltage.

Induction motor 160 is driven by a control operation of a control unit (CPU) (not shown) when a drive signal is applied from the outside, wherein the q-axis generated by referring to the speed feedback from the induction motor 160 And a driving speed is changed by receiving a voltage for the d-axis current. The q-axis current is related to the torque of the induction motor and the d-axis current is related to the magnetic flux of the induction motor. The torque and the magnetic flux are controlled by the current generation unit 100 and the magnetic flux control unit 110 of the present embodiment and will be described separately.

First, when the induction motor 160 operates, the encoder 170 detects the actual rotational speed ωr of the induction motor 160. The current generator 100 provides the q-axis voltage for the generated q-axis current to the induction motor 160 and the voltage controller 130 with reference to the detected rotational speed ωr.

Specifically, it is as follows. The rotational speed ωr of the induction motor 160 detected by the encoder 170 is provided to the first subtractor 101. Then, the first subtractor 101 subtracts the rotation speed ωr from the command speed ωr * applied from the outside to output a speed error and then provides the speed error to the first PI controller 102. The first PI controller 102 proportionally integrates and outputs the q-axis synchronous coordinate current i ^e qs to the torque limiter 104 to compensate for the speed error output from the first subtractor 101. .

Then, the torque limiter 104 outputs the q-axis current synchronous coordinates (i qs ^e) and with a preset reference condition value and the q-axis synchronous coordinate reference current (i qs ^e *) a. The condition value refers to the maximum current value Is_max, the d-axis synchronous coordinate flux information λ ^e ds, the q-axis synchronous coordinate current i ^e q, and the slip frequency ω _sl .

The q-axis synchronous coordinate reference current i ^e qs * output from the torque limiter 104 is input to the second subtractor 106 by the condition value. The second subtracter 106 outputs a current error value by subtracting the q-axis current synchronous coordinates (i qs ^e) from the q-axis synchronous coordinate reference current (i qs ^e *).

The output current error value is input to the second PI controller 108. The second PI controller 108 forwards the proportional integration to the first adder 109 to compensate for the current error value. The first adder 109 adds " ω _e (synchronous angular frequency) * lambda ^e ds (magnetic flux) " to the proportionally integrated value.

In this manner, the current generator 100 generates a q-axis current related to torque / speed.

Next, a process of controlling an applied voltage for enabling maximum torque operation in the field weakening region according to the stator flux reference control method together with the q-axis current will be described with reference to the magnetic flux controller 110.

Provides _{- (ref} V _s) to the third subtractor 111 is guided under the q-axis current and the q-voltage axis voltage and the d-axis voltage controller 130 for the d-axis current of the motor 160 is applied to a reference voltage . The reference voltage V _{s - ref} is a voltage that allows the induction motor 160 to operate at the maximum torque in the field weakening area.

The battery voltage is applied to the third subtractor 111. Therefore, the third subtractor 111 is the battery voltage and the reference voltage _- as compared to the (V _{ref s),} it provides a voltage error value according to the comparison result to the third PI controller 112.

The third PI controller 112 generates a d-axis synchronous coordinate reference magnetic flux lambda ^e ds * after proportional integration to compensate for the first voltage error value. The d-axis synchronous coordinate reference magnetic flux λ ^e ds * is provided to the fourth subtractor 113. The fourth subtracter 113 is the output the d-axis synchronous coordinates based on magnetic flux (λ ^e ds *), the d-axis synchronous coordinate flux (λ ^e ds) is subtracted, and the fourth PI controller the output values to compensate for the magnetic flux error a in Provided at 114.

When the fourth PI controller 114 outputs the magnetic flux error value compensated through proportional integration and provides it to the fifth subtractor 115, the fifth subtractor 115 d / q axis in the magnetic flux error value. The current i _dq is compensated to compensate for the error in the stator flux reference control. Accordingly, the fifth subtractor 115 outputs the d-axis synchronous coordinate reference current i ^e d * and provides it to the sixth subtractor 116.

Then, the sixth subtracter 116 subtracts the d-axis current synchronous coordinates (i ^e d) in the d-axis synchronous coordinate reference current (i d * ^e). In order to compensate for the current error output from the sixth subtractor 116, the fifth PI controller 117 compensates the current error by proportional integration and then transfers the current error to the seventh subtractor 118. The seventh subtractor 118 subtracts a value of "(λ ^e ds / τr) + σL _s ω _sl i ^e qs" from the output value of the fifth PI controller 117, thereby reducing the reference voltage (V _{s - ref} ). Outputs the d-axis current following.

When the induction motor starts to be driven as described above, the voltage controller 130 refers to the q-axis and d-axis voltages for the q-axis current and the d-axis current generated by the current generator 100 and the magnetic flux controller 110. The reference voltage V _{s - ref} is generated and the battery voltage is controlled to follow the reference voltage V _{s - ref} .

The d-axis voltage followed and controlled by the reference voltage V _{s - ref} and the q-axis voltage by the current generation unit 100 are provided to the two-phase / three-phase conversion unit 140 to provide three-phase voltage. Is converted into output and provided to the PWM inverter 150. The PWM inverter 150 converts the three-phase voltage into a pulse width modulated signal and then applies the driving to the induction motor 160.

According to such a control scheme, even if the battery charging voltage is not sufficient in the field weakening region, the reference voltage may be added and the controlled applied voltage may be supplied to the induction motor. Accordingly, even when the battery charging voltage is insufficient as shown in FIG. 2 can be driven. 2 is a diagram showing speed, maximum voltage, and voltage controller voltage waveforms in a constant torque region according to simulation results. According to the simulation result, it can be seen that the rotational speed ωr of the induction motor is driven close to the command speed ωr * even when the maximum voltage V _s and the voltage controller voltage V ^* _s decrease. That is, in the prior art, since the induction motor control could not be stably performed when the battery voltage was not sufficient, equipment such as an electric forklift using the battery voltage was not able to operate normally.

Although described with reference to the illustrated embodiment of the present invention as described above, this is merely exemplary, those skilled in the art to which the present invention pertains various modifications without departing from the spirit and scope of the present invention. It will be apparent that other embodiments may be modified and equivalent. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the present invention generates a reference voltage for generating the maximum torque by receiving the q-axis voltage and the d-axis voltage generated when the induction motor is driven, and compares the reference voltage with the battery voltage while the battery voltage Since the induction motor is applied while being followed, the induction motor mounted in the battery / powered device / system has the effect of enabling maximum torque operation in the field weakening area.

Therefore, even in the case of an electric forklift, a device / system with a variable battery voltage can operate at maximum torque according to the stator flux reference control method in the field weakening area. Operation control is possible.

Claims (14)

A current generator for generating q-axis current of the induction motor, Magnetic flux compensation unit for generating stator flux reference and generating d-axis current of induction motor, And a voltage controller configured to receive the q-axis voltage and the d-axis voltage corresponding to the q-axis current and the d-axis current, respectively, and output a reference voltage (V _{s - ref} ) for generating the maximum torque of the induction motor. The magnetic flux compensating unit controls the battery voltage to follow the reference voltage (V _{s - ref} ) and applies the induction motor to the induction motor. The method of claim 1, The current generator, A first subtractor for outputting a speed error value by subtracting the command speed ωr * and the actual rotation speed ωr of the induction motor, A first proportional integral (PI) controller that outputs q-axis synchronous coordinate current i ^e qs by proportionally integrating to compensate for the speed error value, A torque limiter for outputting the q-axis synchronous coordinate reference current i ^e qs * based on the q-axis synchronous coordinate current i ^e qs and a preset condition value; A second subtractor configured to subtract the q-axis synchronous coordinate reference current i ^e qs * and q-axis synchronous coordinate current i ^e qs to output a speed error value; A second PI controller proportionally integrated to compensate for the speed error value; An induction motor using a voltage controller comprising an adder for outputting the q-axis current by adding the value of equation (1) to the output value of the second PI controller. ω _e λ ^e ds --- Equation (1) (ω _e : synchronous angular frequency, λ ^e ds: magnetic flux) The method of claim 2, The condition value includes a maximum current value Is_max, d-axis synchronous coordinate flux information λ ^e ds, q-axis synchronous coordinate current i ^e q, and a slip frequency ω _sl . Induction motor used. The method of claim 1, The magnetic flux control unit, a voltage controller for generating a d-axis current and receiving a reference voltage (V _{s - ref} ) from the voltage controller and controlling the battery voltage such that the battery voltage follows the reference voltage (V _{s - ref} ). Induction motor used. The method of claim 4, wherein The magnetic flux control unit, A third subtractor for outputting a voltage error value by subtracting the battery voltage and the reference voltage V _{s - ref} , A third PI controller for correcting the voltage error value and outputting a d-axis synchronous reference magnetic flux lambda ^{e *} ds; A fourth subtractor for outputting a voltage error value by subtracting the d-axis synchronous coordinate reference flux λ ^{e *} ds and the d-axis synchronous coordinate flux λ ^e ds; A fourth PI controller which proportionally integrates the voltage error value to correct the voltage error value of the fourth subtractor, A fifth subtractor which compensates the d-axis / q-axis current i _dq and outputs the d-axis synchronous coordinate reference current i ^{e *} d to compensate for the error in the stator flux reference control with respect to the output value of the fourth PI controller. , A sixth subtractor which subtracts the d-axis synchronous coordinate reference current i ^{e *} d from the d-axis synchronous coordinate current i ^e d; A fifth PI controller for controlling the output of the sixth subtractor, And a seventh subtractor configured to generate a d-axis current with reference to the output information of the fifth PI controller. The method of claim 5, The d-axis / q-axis current (i _dq ) is

Induction motor using a voltage controller, characterized in that. The method according to claim 1 or 4, The reference voltage (V _{s - ref} ) is

Induction motor using a voltage controller, characterized in that (V ^* _2d : d-axis voltage, V ^{* 2} _q : q-axis voltage). A first step of receiving a q-axis voltage and a d-axis voltage for the q-axis current and the d-axis current of the induction motor, respectively, and generating a reference voltage (V _{s - ref} ) for maximum torque generation; A second step of comparing the reference voltage V _{s - ref} with a battery voltage; A third step of compensating for an error in stator flux control such that the battery voltage follows the reference voltage V _{s - ref} , And a fourth step of supplying the error compensated battery voltage to the induction motor. The method of claim 8, The q-axis current is, Subtracting the command speed (ωr *) and the actual rotation speed (ωr) of the induction motor, Outputting the q-axis synchronous coordinate current i ^e qs by proportionally integrating the speed error value output in the subtraction step, Outputting the q-axis synchronous coordinate reference current i ^e qs * based on the q-axis synchronous coordinate current i ^e qs and a preset condition value; Outputting a speed error value by subtracting the q-axis synchronous coordinate reference current (i ^e qs *) and the q-axis synchronous coordinate current (i ^e qs); And proportionally integrating the speed error value and adding and outputting ω _e λ ^e ds (ω _e : synchronous angular frequency, λ ^e ds: magnetic flux). The method of claim 9, The condition value is a maximum current value Is_max, d-axis synchronous coordinate flux information (λ ^e ds), q-axis synchronous coordinate current (i ^e q), induction using a voltage controller, characterized in that the slip frequency (ω _sl ) Motor control method. The method of claim 8, The error compensation step, Comparing the error between the reference voltage (V _{s - ref} ) and a battery voltage, Generating a d-axis magnetic flux component as a result of the comparison; Compensating the d-axis magnetic flux component with a d-axis / q-axis current (i _dq ) comprising the step of controlling the induction motor using a voltage controller. The method of claim 8, The error compensation step, Outputting a voltage error value by subtracting the battery voltage and the reference voltage (V _{s - ref} ), Correcting the voltage error value to output a d-axis synchronous coordinate reference flux λ ^{e *} ds and subtracting the d-axis synchronous coordinate flux λ ^e ds to output a magnetic flux error value; Compensating for d-axis / q-axis current (i _dq ) and outputting d-axis synchronous coordinate reference current (i ^{e *} d) to compensate the error of stator flux reference control after proportionally integrating the magnetic flux error value; Subtract the d-axis synchronous coordinate reference current (i ^{e *} d) and the d-axis synchronous coordinate current (i ^e d) and control the error value that is output as a result of subtracting the battery voltage to the reference voltage (V _{s - ref} ). Induction motor control method using a voltage controller, characterized in that comprising the step of controlling to follow. The method of claim 11 or 12, The d-axis / q-axis current (i _dq ) is

Induction motor control method using a voltage controller, characterized in that. The method according to any one of claims 8 or 11 or 12, The reference voltage Vs_ref is

Induction motor control method using a voltage controller, characterized in that (V ^{* 2} _d : d-axis voltage, V ^{* 2} _q : q-axis voltage).

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