KR20030061115A - Method for sensorless rotary velocity control of synchronous reluctance motor - Google Patents

Abstract

PURPOSE: A sensor-less speed control method is provided to be capable of improving an accurate degree of sensor-less speed control. CONSTITUTION: A sensor-less speed control method includes a step of removing an offset component of a detected current of a synchronous reluctance motor, a step of outputting estimated position and rotary speed of a rotator according to an offset component-removed current, and a step of reducing and controlling an error based on the estimated position and rotary speed of the rotator. The step of removing an offset component includes a step of detecting an average value by integrating a current of a previous period of the detected current, and a step of outputting the offset-removed current by subtracting the average value from the detected current.

Description

METHOD FOR SENSORLESS ROTARY VELOCITY CONTROL OF SYNCHRONOUS RELUCTANCE MOTOR}

The present invention relates to a method for controlling the sensorless speed of a synchronous reluctance motor. In particular, the DC offset of the current is removed by using a current average value during one cycle to reduce the error of the estimated position of the rotor or the estimated rotation speed, thereby improving accuracy. A sensorless speed control method of a synchronous reluctance motor is provided.

In general, the speed control device of a synchronous reluctance motor requires speed information or magnetic flux information of the instantaneous torque control. Generally, a speed information sensor or a flux sensor such as a taco generator, resolver, or pulse encoder is required. As sensors are difficult to mount and sensitive to the installation environment, they are not only susceptible to noise-like environments, but also economically cause the price to rise. Therefore, the vector control method without the speed sensor is used for speed and compensation without the speed error correction of the secondary resistance change of the motor. Torque control

FIG. 1 is an exemplary view showing a structure of a general synchronous reluctance motor, and is divided into a rotor and a stator as shown in the drawing. The d-axis and the cue-axis (q-) according to the strength of magnetic flux are shown in FIG. axis).

In order to control the speed of the synchronous reluctance motor, the position of the rotor must be known. Therefore, the position of the rotor can be directly detected as a rotor position detector such as an encoder, but the sensorless control method without the rotor position detector is used because it is difficult to mount the detector in a compressor or air conditioner compressor. This conventional technique will be described with reference to the accompanying drawings.

2 is an exemplary view illustrating a sensorless speed control apparatus of a conventional synchronous reluctance motor. As shown in FIG. 2, the magnetic flux is observed and estimated by receiving a voltage, a current, and an estimated rotor position of the detected synchronous reluctance motor. A magnetic flux observation unit 21; The rotor position / speed estimator 22 is configured to receive the observed and estimated magnetic flux and calculate a predetermined position to estimate the position and speed of the rotor.

First, the magnetic flux observer 21 is as shown in FIG. 3.

A first comparator 31 for comparing the voltage obtained by the product of the stationary coordinate system with the product of the current and the phase resistance and outputting an error thereof as an induced voltage; The induced voltage Offset correction value and the induced voltage A second comparison unit 32 that adds) and compares it with a gain and outputs an error according thereto; An integrator (33) for integrating the output of the second comparator (32) to output the observed magnetic flux of the fixed coordinate system; A first stop / synchronous coordinate converter 34 for converting the output magnetic flux of the integrator 33 into the magnetic flux of the synchronous coordinate system; A second stop / synchronous coordinate conversion unit 37 for converting a current in the still coordinate system into a current in the synchronous coordinate system; A magnetic flux converter 38 for outputting an estimated magnetic flux for the output current of the second stop / synchronous coordinate converter 37; A synchronization / stop coordinate converter 39 for converting and outputting the output of the magnetic flux converter 38 into the estimated magnetic flux of the stop coordinate system; A third comparator 35 for comparing the integrator 33 and the output of the sync / stop coordinate converter 39 and outputting an error according thereto; And a gain generator 36 for outputting a gain of which the error is '0'.

The magnetic flux observer 21 obtains the observed magnetic flux from the detected voltage and current and the estimated magnetic flux as shown in Equation (1) below.

here, Is the observed flux in the static coordinate system, S is the derivative operator, g is the gain Is phase resistance, Is the current in the static coordinate system, Denotes the estimated magnetic flux of the static coordinate system.

From the magnetic fluxes, the rotor position estimator 22 calculates the position of the rotor as shown in equation (2).

As a result, the rotor position / speed estimator 22 estimates the rotational speed of the synchronous reluctance motor using Equation (3) below according to the output of the magnetic flux observer 21.

here, Is the k-th rotor position, Is the k-1 th rotor position Indicates a cycle.

Further, Equation (2) can be expressed as Equation (4) below from a vector diagram for sensorless control of the synchronous reluctance motor of FIG. 4 by a user-defined equation, and by Equation (4) The sinθ and cosθ are derived through Equation (5).

θ represents the phase difference between the di-axis and the alpha axis, and δ represents the phase difference between the magnetic flux and the di-axis.

However, in the conventional apparatus operating as described above, the magnetic flux observer used in the conventional sensorless method of estimating the position of the rotor from the magnetic flux has a direct current offset to the current detected by the offset of the current sensor or op amp and the switching dead time. This did not take into account the case.

As a result, when the current includes a DC offset, the estimated flux includes a DC offset and the observed flux includes an AC component error. As a result, an error occurs in the estimated position or estimated rotation speed of the rotor. There was a problem that the precision of the speed control is reduced.

Accordingly, the present invention has been devised to solve the above problems, a method of removing the DC offset of the current generated by the offset of the current sensor or op amp and switching dead time using the current average value for one cycle. Synchronous reluctance motor to improve the precision of sensorless speed control by reducing the error of estimated position or estimated rotation speed of rotor caused by DC offset of current in the conventional sensorless method Its purpose is to provide a sensorless speed control method.

1 is an exemplary view showing a structure of a general synchronous reluctance motor.

Figure 2 is an exemplary view showing a sensorless speed control device of a conventional synchronous reluctance motor.

3 is an exemplary view showing a device configuration of the magnetic flux observation unit of FIG.

4 is a vector diagram for sensorless control of a typical synchronous reluctance motor.

5 is an exemplary view showing a configuration of the present invention magnetic flux observation unit.

Figure 6 is a current waveform diagram of the offset remover of the present invention.

*** Explanation of symbols for main parts of drawing ***

30: offset remover 31: first comparator

32: second comparator 33: integrator

34: first stop / synchronous coordinate conversion unit 35: third comparison unit

36: gain generator 37: second stop / synchronous coordinate converter

38: flux converter 39: sync / stop coordinate converter

100: magnetic flux observer

The present invention for achieving the above object comprises the steps of: removing the offset component of the detected current of the synchronous reluctance motor in controlling the speed by observing the magnetic flux of the synchronous reluctance motor; Outputting an estimated position and estimated rotational speed of the rotor according to the current from which the offset component is removed; And a third step of controlling the error by reducing the estimated position and the estimated rotation speed of the rotor.

Hereinafter, the operation and effect of the sensorless speed control method of the synchronous reluctance motor according to the present invention will be described in detail with reference to the accompanying drawings.

5 is an exemplary view showing the configuration of the magnetic flux measuring unit of the present invention, and as shown therein, an offset removing unit 30 for outputting a current of a static coordinate system from which a DC offset is removed; A first comparator 31 which compares the voltage obtained by multiplying the output current of the offset remover 30 by the phase resistance and the voltage of the static coordinate system and outputs another error as an induced voltage; The induced voltage Offset correction value and the induced voltage A second comparison unit 32 that adds) and compares it with a gain and outputs an error according thereto; An integrator (33) for integrating the output of the second comparator (32) to output the observed magnetic flux of the fixed coordinate system; A first stop / synchronous coordinate converter 34 for converting the output magnetic flux of the integrator 33 into the magnetic flux of the synchronous coordinate system; A second stop / synchronous coordinate converter 37 for converting an output current of the still coordinate system of the offset remover 30 into a current of a synchronous coordinate system; A magnetic flux converter 38 for outputting an estimated magnetic flux for the output current of the second stop / synchronous coordinate converter 37; A synchronization / stop coordinate converter 39 for converting and outputting the output of the magnetic flux converter 38 into the estimated magnetic flux of the stop coordinate system; A third comparator 35 for comparing the integrator 33 and the output of the sync / stop coordinate converter 39 and outputting an error according thereto; And a gain generator 36 for outputting a gain of which the error is '0'.

In the description of the operation of the present invention, the device configuration and operation except for the magnetic flux observation portion are the same as in the prior art.

Accordingly, the description of the operation and operation of the same configuration as in the related art may obscure the gist of the present invention, and thus description of the operation of the configuration except for the magnetic flux observation unit 100 will be omitted.

First, the magnetic flux observer 100 of the present invention removes the DC offset included in the current by using the average value of the current for one period, and then generates the observation speed and the estimated speed. Solves the problem of reduced precision.

That is, the DC offset current (the result obtained by integrating and averaging the detected currents for one period) ) And the detected current ( In the DC offset current ( Current with the dc offset removed by subtracting ).

In general low pass filter (LPF), it is difficult to set the cut off frequency due to the change of the current frequency by the variable speed control of the synchronous reluctance motor. It is difficult to remove the dc offset of the current.

The principle of the offset remover 30 for removing the DC offset will be described with reference to the current waveform diagram of the offset remover of the present invention shown in FIG. 6.

In the case of a normal AC waveform that does not include a DC offset in the detected current as in a, if the average of one period is electrically conducted, the value becomes 0, and the detected current as in B includes a DC offset as much as C. In this case, the average current value for one cycle becomes C.

The period T represents one period of electrical power and the estimated rotational speed estimated by the sensorless method ( Is obtained through

Therefore, the present invention uses this principle to detect the current ( ) Is the average value obtained by integrating the current electrically for one period ( By removing the DC offset included in the current by subtracting), the precision of the sensorless speed control of the synchronous reluctance motor can be reduced by reducing the error between the estimated position of the rotor and the estimated rotational speed which can be caused by the DC offset included in the current. Improved.

As described in detail above, the present invention uses a current average value for one cycle to include a new magnetic flux including a method of removing a DC offset of a current generated by an offset of a current sensor or an op amp, and a switching dead time. By using an observer, it is possible to improve the precision of the sensorless speed control by reducing the error of the estimated position of the rotor or the estimated rotation speed caused by the DC offset of the current in the conventional sensorless method.

Claims (2)

Controlling the speed by observing the magnetic flux of the synchronous reluctance motor, the first step of removing the offset component of the detected current of the synchronous reluctance motor; Outputting an estimated position and estimated rotational speed of the rotor according to the current from which the offset component is removed; And a third step of reducing and controlling the error by the estimated position and the estimated rotation speed of the rotor. The method of claim 1, wherein the first step comprises: integrating the current of a previous period of the detected current to detect an average value; And subtracting an average value to the detected current to output a current from which an offset is removed.