JP2003284381A - Method of instantaneously interrupting and restarting induction motor and inverter control apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of restarting an induction motor safely and quickly by preventing an overcurrent impressed thereon through the estimation of an accurate speed and the phase of a magnetic flux vector. <P>SOLUTION: A method of restarting an induction motor after a power supply has been shut off temporarily, wherein when a voltage of an inverter is lower than a specified value, a connection between the inverter and the induction motor is released and a residual voltage generated by the free run of the induction motor and the phase of a voltage vector and detected. By the use of the phase of the detected voltage vector, the phase of the flux vector of the induction motor and the angular speed of magnetic flux and estimated. The detection of the phase of the voltage vector, the detection of the angular speed of the magnetic flux, and the estimation of the phase of the flux vector are repeatedly performed until the voltage of the inverter increases up to the specified value by the recovery of the power supply. When the voltage of the inverter increases up to the specified value, the inverter and the induction motor are connected, and then restarting is performed taking the estimated value of the angular speed of the flux and the estimated value of the phase of flux vector which have been estimated at this time as an initial value. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction motor, and more particularly to a method for restarting an instantaneous interruption of an inverter-driven induction motor and an inverter control device.

[0002]

2. Description of the Related Art Generally, in an inverter-driven induction motor, an overcurrent may flow due to an error in the frequency and phase of the magnetic flux vector at the time of restarting after the momentary power failure, that is, after a temporary power failure. is there. In such a case, the control may be stopped by the protection function of the inverter.

As a conventional method or device for restarting an instantaneous interruption of an induction motor, for example, JP-A-7-274588 (hereinafter, referred to as
Japanese Patent Laid-Open No. 9-9400 (hereinafter referred to as a second example) has been proposed.

The first example discloses a method of detecting the residual voltage of the induction motor in the free running state, calculating the speed, and restarting.

The second example discloses a method of estimating the magnitude and phase of the residual magnetic flux and the rotational speed by detecting the current due to the residual voltage of the induction motor in the free running state.

[0006]

However, in the first example, if there is an error in the magnetic flux vector phase, there is a possibility that a shock will occur when restarting or an overcurrent will result. In addition, since the transformer is used to detect the residual voltage, there is a problem that the residual voltage decreases faster or the voltage cannot be detected at a low speed.

On the other hand, in the second example, since the winding of the induction motor is short-circuited in order to detect the current as in the first example, the residual voltage decreases rapidly and the rotational speed cannot be calculated accurately. There is.

Therefore, an object of the present invention is to provide a method capable of safely and promptly restarting the induction motor by preventing the shock and overcurrent at restarting by accurately estimating the phase of the velocity and magnetic flux vector. .

Another object of the present invention is to provide an inverter control device for an induction motor having the above functions.

[0010]

SUMMARY OF THE INVENTION The present invention provides a method for restarting an inverter control device for driving an induction motor after the power supply is temporarily cut off, when the DC voltage of the inverter becomes lower than a specified value. The induction motor magnetic flux angular velocity is estimated by opening the space between the induction motors, detecting the residual voltage caused by the free running of the induction motors, detecting the phase of the voltage vector, and using the detected phase of the voltage vector. And the phase of the magnetic flux vector is estimated, the phase detection of the voltage vector, the estimation of the magnetic flux angular velocity, and the phase estimation of the magnetic flux vector are repeated until the DC voltage of the inverter rises to a specified value due to the restoration of power supply, and the inverter When the voltage of rises to the specified value, the inverter and the induction motor are connected and at that time And performing restart estimation value of the magnetic flux angular velocity is constant and the phase estimate of the flux vector as an initial value.

The inverter control device according to the present invention comprises a magnetic flux angular velocity command creating means for generating a magnetic flux angular velocity command based on a rotational angular velocity command and a magnetic flux vector phase for computing a magnetic flux vector phase based on the magnetic flux angular velocity command. An inverter control device for driving an induction motor, including an arithmetic means, further comprising: a control means for opening the inverter and the induction motor when the DC voltage of the inverter becomes lower than a specified value; A residual voltage vector phase calculating means for detecting the residual voltage generated by the run and for detecting the phase of the voltage vector, and a magnetic flux for estimating the magnetic flux angular velocity of the induction motor using the detected phase of the voltage vector. A residual for estimating the phase of the magnetic flux vector using the angular velocity estimation means and the phase of the detected voltage vector. Magnetic flux vector phase estimation means, the control means repeats the phase detection of the voltage vector, the estimation of the magnetic flux angular velocity, and the phase estimation of the magnetic flux vector until the DC voltage of the inverter rises to a specified value due to the restoration of the power supply. When the DC voltage of the inverter rises to a specified value, the inverter and the induction motor are connected to each other, and the estimated value of the magnetic flux angular velocity and the estimated value of the phase of the magnetic flux vector are respectively estimated at that time. The magnetic flux angular velocity command creating means and the magnetic flux vector phase computing means are given as initial values.

The control means connects a first switch means for turning on and off the connection between the inverter and the induction motor, and a connection between the magnetic flux angular velocity estimating means and the magnetic flux angular velocity command creating means. In accordance with the DC voltage of the inverter, the second switch means for turning on and off, the third switch means for turning on and off the connection between the residual magnetic flux vector phase estimating means and the magnetic flux vector phase calculating means. And a control unit for controlling ON / OFF of the first to third switch means, and the control section turns off the first switch means when the DC voltage of the inverter becomes lower than a specified value, and the power is turned on. When the voltage of the inverter rises to a specified value due to restoration of supply, the second and third switch means are turned on for a certain period of time, and the first switch means is turned on. It is characterized in.

Further, the residual voltage vector phase calculating means detects the residual voltage through an insulating amplifier.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a control device for an induction motor according to the present invention will be described with reference to FIG. The present control device includes a magnetic flux angular velocity command pattern generator 1 that generates a ramp-shaped magnetic flux angular velocity command ω based on a rotational velocity command ω ^* , a d-axis and q-axis voltage v _sd from the magnetic flux angular velocity command ω,
v / f voltage command generator 2 for generating v _sq , d-axis and q-axis voltages v _sd , v _sq for three-phase voltage command v _u ^* ,
_v v ^*, v ^{w *} is converted into 2-phase / 3-phase converter 3, the voltage command _{^{v u *, v v *,}} v w * on the basis of U-phase voltage _v u, V
P that outputs the phase voltage v _v and the W phase voltage v _w to the induction motor 5
The WM inverter 4 is provided. The PWM inverter 4
Is connected to a smoothing capacitor 10 and is provided with a detector (not shown) for detecting this DC voltage. Further, a switch S0 (first switch means) for opening and closing the three-phase line is provided between the PWM inverter 4 and the induction motor 5.

In the present embodiment, the residual voltage vector / phase calculator 6 includes a voltage detection circuit (not shown) including an insulation amplifier connected to the three-phase input line of the induction motor 5 so that the residual voltage is consumed. And the problem at low frequencies disappears.
The present embodiment further includes a magnetic flux angular velocity estimator 7 and a residual magnetic flux vector phase estimator 8 connected to the output side of the residual voltage vector phase calculator 6, and a magnetic flux vector phase calculator 9. The output of the magnetic flux angular velocity estimator 7 is connected to the magnetic flux angular velocity command pattern generator 1 via a switch S1 (second switch means), and the output of the residual magnetic flux vector phase estimator 8 is a switch S2 (third switch means). Is connected to the magnetic flux vector phase calculator 9. The magnetic flux vector phase calculator 9 calculates the magnetic flux angular velocity command ω from the magnetic flux angular velocity command pattern generator 1 and the residual magnetic flux vector phase estimator 8
2 phase / 3 for the 2-phase / 3-phase converter 3 based on the output of
The phase information θ _φ for phase conversion is given. The functions of the residual voltage vector phase calculator 6, the magnetic flux angular velocity estimator 7, and the residual magnetic flux vector phase estimator 8 will be described later. Further, a control unit (not shown) for controlling ON / OFF of the switches S0 to S2 is provided, and its operation will also be described later.

Before explaining the operation of the present control device, the principle will be described.

Assuming that the residual voltage when the induction motor is in the free-run state due to a momentary power failure or the like is detected, and the phase change for each control cycle T of the voltage vector is Δθ, the estimated angular velocity ω _e of the induction motor is It is expressed by the following equation (1).

Ω _e = Δθ / T (1) On the other hand, the residual magnetic flux can be obtained by the following equations (2) and (3).

Φ _α = ∫ (v _α −R _s i _α ) dt−L _σ i _α (2) φ _β = ∫ (v _β −R _s i _β ) dt−L _σ i _β (3) where: v _α , v _β , i _α , i _β , φ _α , and φ _β represent the α-axis and β-axis voltage, current, and magnetic flux on the fixed axis, respectively, and R _s and L _σ of the induction motor, respectively. Indicates the primary resistance and leakage inductance.

When the current becomes zero by opening the winding of the induction motor, the magnetic flux is expressed by the following equations (4) and (5).

Φ _α = ∫v _α dt (4) φ _β = ∫v _β dt (5) Since the residual voltage is slowly reduced by opening the winding,
The above equation can be regarded as a steady state, and in this case, the relationship between the magnetic flux and the voltage is represented by the following equation 1 [Equation (6)].

[0022]

[Equation 1]

From this relationship, the phase of the magnetic flux vector is delayed from the phase of the voltage vector by π / 2. Therefore, if the voltage vector phase is θ _ve , θ _ve is expressed by the following equation (7) and estimated. The magnetic flux vector phase θ _φe is expressed by the following equation (8) using θ _ve .

[0024] ^{_{θ ve = tan -1 (v sβ}} / v sα) (7) θ φe = θ ve - (π / 2) (8) Next, a description of the operation of the control device. When driving the induction motor 5, the switch S0 is turned on and the switch S is turned on.
1 and S2 are in the off state. When the voltage v _dc of the smoothing capacitor 10 becomes lower than the specified value due to a momentary power failure or the like, the control unit turns off the switch S0, and the PWM inverter 4
Stop the output of.

Even after the power failure is restored, the switch S0 remains in the off state, the residual voltage vector phase calculator 6 detects the residual voltage generated by the free run of the induction motor 5 through the isolation amplifier, and the expression (7) is used. Based on this, the phase θ _ve of the voltage vector is detected. Magnetic flux angular velocity estimator 7
Is the phase θ _ve of the detected voltage vector, (1)
The magnetic flux angular velocity ω _e (estimated magnetic flux angular velocity) is estimated based on the equation. On the other hand, the residual magnetic flux vector phase estimator 8 estimates the phase θ _{φe of the} magnetic flux vector based on the equation (8) using the phase θ _ve of the voltage vector.

The above operation is performed by the voltage v of the smoothing capacitor 10.
_It is repeated every control period T while _dc is lower than the specified value.

Then, the voltage v of the smoothing capacitor 10_dc
When the voltage rises to the specified value,
Magnetic flux angular velocity ω estimated by turning on_e, The position of the magnetic flux vector
Phase θ _φeMagnetic flux angular velocity command pattern generator
1. After passing to the magnetic flux vector phase calculator 9, switch S
The switches S1 and S2 are turned off and the switch S1 is turned on.

This control device uses the magnetic flux angular velocity ω _e from the magnetic flux angular velocity estimator 7 and the phase θ _φe of the magnetic flux vector from the residual magnetic flux vector phase estimator 8 as initial values.
Reboot. That is, the present control device turns on the switch S0 and restarts with the value estimated when the voltage v _dc of the smoothing capacitor 10 is low as an initial value.

When the power supply is cut off to stop the operation of the induction motor, the voltage v _dc of the smoothing capacitor 10 does not return to the specified value, so the switch S0
~ S2 is never turned on.

[0030]

According to the restarting method of the present invention, by preventing the winding of the induction motor from being short-circuited, it is possible to prevent the residual voltage from lowering and to detect the phase and speed of the magnetic flux vector more accurately, which is safe and smooth. Restart can be done.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a control device according to an embodiment of the present invention.

[Explanation of symbols] 1 Magnetic flux angular velocity command pattern generator 2 v / f voltage command generator 3 2 phase / 3 phase converter 4 PWM inverter 5 induction motor 6 Residual voltage vector phase calculator 7 Magnetic flux angular velocity estimator 8 Residual magnetic flux vector phase estimator 9 Magnetic flux vector phase calculator 10 Smoothing capacitor

Claims (4)

[Claims] 1. A method for restarting an inverter control device for driving an induction motor after power supply is temporarily cut off, wherein when the DC voltage of the inverter becomes lower than a specified value, the inverter and the induction motor are opened. The residual voltage generated by the free run of the induction motor is detected, the phase of the voltage vector is detected, and the magnetic flux angular velocity of the induction motor and the phase of the magnetic flux vector are estimated using the detected phase of the voltage vector. However, the phase detection of the voltage vector, the estimation of the magnetic flux angular velocity, and the phase estimation of the magnetic flux vector is repeated until the DC voltage of the inverter rises to a specified value due to restoration of power supply, and when the voltage of the inverter rises to a specified value. , The inverter and the induction motor are connected, and the magnetic flux angular velocity estimated at that time is connected. Estimates and instantaneous stop restart method for an induction motor and performs restart phase estimate of the flux vector as an initial value of. 2. A magnetic flux angular velocity command creating means for generating a magnetic flux angular velocity command based on a rotational angular velocity command and a magnetic flux vector phase computing means for computing a magnetic flux vector phase based on the magnetic flux angular velocity command. In an inverter control device for driving an induction motor, a control means for opening a space between the inverter and the induction motor when the DC voltage of the inverter becomes lower than a specified value, and a residual voltage generated by a free run of the induction motor are detected. A residual voltage vector phase calculating means for detecting the phase of the voltage vector, a magnetic flux angular velocity estimating means for estimating the magnetic flux angular velocity of the induction motor using the detected voltage vector phase, and the detected voltage The residual magnetic flux vector phase estimating means for estimating the magnetic flux vector phase using the vector phase is provided. The control means repeatedly performs the phase detection of the voltage vector, the estimation of the magnetic flux angular velocity, and the phase estimation of the magnetic flux vector until the DC voltage of the inverter rises to a specified value due to the restoration of the power supply, and the DC voltage of the inverter. Is increased to a specified value, the inverter and the induction motor are connected, and the estimated value of the magnetic flux angular velocity estimated at that time, the phase estimated value of the magnetic flux vector, respectively, the magnetic flux angular velocity command creating means, the An inverter control device characterized in that the magnetic flux vector phase calculation means is given as an initial value. 3. The inverter control device according to claim 2, wherein the control unit turns on and off a connection between the inverter and the induction motor, and the magnetic flux angular velocity estimation unit. A second switch means for turning on / off the connection with the magnetic flux angular velocity command creating means, and a third switch for turning on / off the connection between the residual magnetic flux vector phase estimating means and the magnetic flux vector phase calculating means. The switch means and the first to the first depending on the DC voltage of the inverter.
And a control unit for controlling ON / OFF of the third switch unit, the control unit turning off the first switch unit when the DC voltage of the inverter becomes lower than a specified value, and restoring the power supply to the inverter. The inverter control device is characterized in that when the voltage rises to a specified value, the second and third switch means are turned on for a certain period of time and the first switch means is turned on. 4. The inverter control device according to claim 2 or 3, wherein the residual voltage vector phase calculating means detects the residual voltage through an insulation amplifier.