KR20090008944A - Apparatus and method for driving bldc motor - Google Patents

Abstract

An apparatus for operating a brushless DC motor and a method thereof are provided to prevent surge current from generating in advance by switching-controlling a motor driving device at high speed in the high speed rotation of a brushless DC motor. A smoothing circuit part(120) flats AC voltage applied from an AC power supply(110) into DC voltage. A motor driver(130) is switched according to a PWM(Pulse Width Modulation) control signal in order to provide DC output of the smoothing circuit part as a motor driving power. The brushless DC motor(140) is driven with the approval of the motor driving power. A position detection sensor(150) detects position of the rotator of the brushless DC motor and outputs the position information of the rotator. A base R PM storage(170) stores the RPM value which is possible to generate the surge current in the high speed rotation of the brushless DC motor as a base RPM value. According to comparison result of the base RPM value with the RPM value of the brushless DC motor calculated based on the position information of the rotator, a PWM controller provides a PWM control signal.

Description

A device and method for a non-commutator DC motor {APPARATUS AND METHOD FOR DRIVING BLDC MOTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the driving of a brushless direct current (BLDC) motor, and more particularly, to a driving apparatus and a driving method thereof capable of preventing the generation of surge current when a high speed operation of the non-commutator direct current motor is performed.

In the products that need to implement high efficiency variable speed operation such as compressors and washing machines for refrigerators and air conditioners, non-commutator DC motors are currently used the most.

In general, a non-commutator DC motor uses an armature, which is formed by flowing current through a coil, as a stator, and a rotor uses a permanent magnet formed by repeating the N pole and the S pole. If permanent magnets are formed in a cylindrical shape on the entire surface of the rotor, they are driven in a single phase manner. If three permanent magnets are formed on the surface of the rotor with a symmetric angle of 120 °, they are driven in a three phase manner.

In order to continuously rotate such a non-commutator DC motor, it is necessary to form a continuous rotating magnetic field, and to form a continuous rotor field, a commutation of current flowing through the armature coil must be performed at an appropriate time. In order to accurately recognize the position of the rotor. The changeover here is to change the current direction of the motor stator coils so that the rotor can rotate.

For smooth operation of the non-commutator DC motor, it is necessary to precisely match the position of the rotor and the transition point of the phase current, and for this, a device for detecting the position of the rotor is required. For this purpose, a position detection sensor such as a Hall sensor, a resolver element, or an encoder is used.

Figure 1 is a block diagram of a drive device for a non-commutator DC motor according to the prior art, an example using a Hall sensor as a position detection sensor.

Referring to FIG. 1, a conventional motor driving apparatus includes an AC power source 10 that is an energy source for driving a motor, a smoothing circuit unit 20 that smoothes an AC voltage applied from the AC power source 10 to a DC voltage, and a pulse width. A motor driving unit 30 which is switched in accordance with a modulation (PWM) control signal to provide a DC output of the smoothing circuit unit 20 to the motor driving power source, and a non-commutator DC motor 40 which is rotationally driven by application of the motor driving power source; And the hall sensor 50 for detecting the rotor position of the non-commutator DC motor 40 and outputting the rotor position information, and inputting the rotor position information by the hall sensor 50 to the motor drive unit 30. And a pulse width modulation controller 60 for controlling the rotational speed of the non-commutator DC motor 40 by adjusting the duty of the applied pulse width modulation control signal.

Referring to FIGS. 1 and 2, a motor driving process by the driving apparatus for a non-commutator DC motor according to the related art is as follows.

First, the smoothing circuit unit 20 smoothes the AC voltage applied from the AC power source 10 to a DC voltage.

The voltage smoothed by the smoothing circuit unit 20 is supplied to the motor driving unit 30, and the motor driving unit 30 provides a pulse width modulation control signal provided from the pulse width modulation control unit 60 (see the PWM signal waveform in FIG. 2). By switching according to the DC output of the smoothing circuit unit 20 to generate a motor drive power supply to the non-commutator DC motor 40.

Then, the non-commutator DC motor 40 is driven to rotate the motor driving power supplied from the motor drive unit 30, the rotational driving force of the non-commutator DC motor 40 is provided to the load connected to the non-commutator DC motor 40. .

Here, the hall sensor 50 detects the rotor position of the non-commutator DC motor 40 and provides the rotor position information to the pulse width modulation control unit 60.

Then, the pulse width modulation controller 60 calculates the rotation speed of the non-commutator DC motor 40 by inputting the rotor position information by the Hall sensor 50, and compares the calculated rotation speed with the target speed. Based on the result, the duty of the pulse width modulation control signal is adjusted.

Accordingly, the voltage level of the motor driving power applied by the motor driver 30 to the non-commutator DC motor 40 is changed so that the rotation speed of the non-commutator DC motor 40 is changed to or close to the target speed. .

On the other hand, Figure 2 is a signal waveform diagram according to the drive method for a non-commutator DC motor according to the prior art, the PWM signal waveform is a pulse width modulation control signal applied from the pulse width modulation control unit 60 to the motor driver 30. , I _M signal waveform is a current applied to the non-commutator DC motor 40.

As described above, the driving method for the non-commutator DC motor according to the related art has a problem in that a surge current occurs when the non-commutator DC motor is rotated at high speed. The surge current increases almost in proportion to the speed. At low speeds, the current flows to a degree that the motor driving element can withstand sufficiently, and at high speeds, excessive surge current S occurs as shown in the I _M signal waveform shown in FIG. In this case, it may adversely affect or fail the motor drive element. In this case, using a motor driving element with high breakdown voltage and high current will not be a problem, but this will not only increase the cost, but also allow the motor to be rotated at a constant speed during normal operation to control using high cost components. If there is a problem that efficiency falls.

The present invention prevents the generation of the surge current by switching the motor drive element at a high speed at a speed at which the surge current may be generated during the high speed rotation of the non-commutator DC motor.

In one aspect of the present invention, a non-commutator DC motor driving device includes a smoothing circuit section for smoothing an AC voltage applied from an AC power supply to a DC voltage, and a DC output of the smoothing circuit section by switching according to a pulse width modulation control signal. A motor drive unit provided by the controller, a non-commutator DC motor that rotates by applying a motor drive power source, a position detection sensor for detecting rotor position of the non-commutator DC motor, and outputting rotor position information, and a non-commutator DC motor. Comparison between the RPM value and the reference RPM value of the non-commutator DC motor calculated by inputting the rotor position information with the reference RPM storage unit where the RPM value that may generate a surge current at high speed rotation of the reference RPM value According to the result, the pulse width modulation control signal is provided to drive or drive the motor drive at a normal speed. And a pulse width modulation control such that.

According to another aspect of the present invention, there is provided a method for driving a non-commutator DC motor, the method comprising: (a) detecting rotor position of a non-commutator DC motor to generate rotor position information; and (b) no rotor based on rotor position information. Calculating the RPM value of the commutator DC motor, (c) comparing the RPM value of the non-commutator DC motor with a preset reference RPM value, and (d) normalizing the non-commutator DC motor according to the comparison result of the RPM values. Switching driving at regular speed or switching driving at high speed.

According to the present invention, at a speed in which surge current may be generated during a high speed rotation of a non-commutator DC motor, the switching control of the motor drive element is performed at high speed so that on / off is repeated within a short time, thereby preventing the generation of surge current in advance. .

Therefore, it does not adversely affect or fail the motor driving element, and it is possible to use a relatively low unit cost, thereby reducing costs and increasing control efficiency.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

3 is a block diagram of a drive device for a non-commutator DC motor according to an embodiment of the present invention, in which an Hall sensor is used as a position detection sensor for detecting a position of a motor rotor.

Referring to FIG. 3, the motor driving apparatus of the present invention includes an AC power source 110 that is an energy source for driving a motor, a smoothing circuit unit 120 that smoothes an AC voltage applied from the AC power source 110 to a DC voltage, and a pulse. A motor driving unit 130 switched according to a width modulation (PWM) control signal to provide a DC output of the smoothing circuit unit 120 to the motor driving power, and a non-commutator DC motor 140 which is rotationally driven by application of the motor driving power. And a Hall sensor 150 which detects the rotor position of the non-commutator DC motor 140 and outputs the rotor position information, and RPM which may generate a surge current during the high speed rotation of the non-commutator DC motor 140. (Rpm) value of the pulse width modulation control signal applied to the motor drive unit 130 by inputting the rotor position information by the reference RPM storage unit 170 and the hall sensor 150 stored as a reference RPM value No rectifier by adjusting the duty While controlling the rotational speed of the flow motor 140, the RPM value of the non-commutator DC motor 140 calculated by inputting the rotor position information by the Hall sensor 150 and the reference RPM stored in the reference RPM storage unit 170 And a pulse width modulation control unit 160 for adjusting the pulse width modulation control signal applied to the motor driving unit 130 in order to switch the motor driving unit 130 at high speed according to the comparison result with the value.

Referring to FIGS. 3 and 4, a motor driving process by the driving apparatus for a non-commutator DC motor according to the present invention is as follows.

First, the smoothing circuit unit 120 smoothes the AC voltage applied from the AC power source 110 to a DC voltage.

The voltage smoothed by the smoothing circuit unit 120 is supplied to the motor driving unit 130, and the motor driving unit 130 provides a pulse width modulation control signal provided from the pulse width modulation control unit 160 (see the PWM signal waveform in FIG. 4). In accordance with the switching to generate a DC output of the smoothing circuit unit 120 as a motor driving power supply to the non-commutator DC motor 140.

Then, the non-commutator DC motor 140 is rotationally driven to the motor driving power supplied from the motor driver 130, and the rotational driving force of the non-commutator DC motor 140 is provided to the load connected to the non-commutator DC motor 140. .

Here, the hall sensor 150 detects the rotor position of the non-commutator DC motor 140 and provides the rotor position information to the pulse width modulation controller 160.

Then, the pulse width modulation control unit 160 calculates the rotation speed of the non-commutator DC motor 140 by inputting the rotor position information by the hall sensor 150, and compares the calculated rotation speed with the target speed. Based on the result, the duty of the pulse width modulation control signal is adjusted.

Accordingly, the voltage level of the motor driving power applied by the motor driver 130 to the non-commutator DC motor 140 is changed so that the rotation speed of the non-commutator DC motor 140 is changed to or close to the target speed. .

On the other hand, Figure 4 is a signal waveform diagram according to the drive method for the non-commutator DC motor according to an embodiment of the present invention, the PWM signal waveform is pulse width modulation applied to the motor driver 130 from the pulse width modulation control unit 160 The control signal, and the I _M signal waveform is a current applied to the non-commutator DC motor 140.

However, when the non- commutator DC motor 140 is rotated at a predetermined speed or more, excessive surge current (see S in FIG. 2) may occur as described above. In this case, the motor driving element may be adversely affected or failed. May cause.

Thus, in the present invention, the RPM value that may generate a surge current during the high speed rotation of the non-commutator DC motor 140 is stored in the reference RPM storage unit 170 as a reference RPM value. Here, the reference RPM value is determined by the current measurement by the oscilloscope to determine the RPM value when excessive surge current occurs as a control point and stored in the reference RPM storage unit 170.

Then, the PWM controller 160 may compare the RPM value of the non-commutator DC motor 140 calculated by inputting the rotor position information by the hall sensor 150 with the reference RPM value stored in the reference RPM storage unit 170. Based on the results of the comparison, the control points with the potential for excessive surge currents are extracted.

When the control point is extracted, the PWM controller 160 adjusts a pulse width modulation control signal applied to the motor driver 130 to switch the motor driver 130 at high speed. That is, a pulse width modulation control signal of a short period in which the high signal and the low signal are alternately applied to the motor driver 130 within a short time as in the H section of the PWM signal waveform of FIG. 4.

Then, the motor driver 130 is switched on and off at high speed by a short cycle in the H section of the PWM signal waveform, and the current applied to the non-commutator DC motor 140 is excessive surge as shown in the I _M signal waveform of FIG. 4. No current is generated.

This is because the off section of the motor driver 130 increases in time as the low section of the pulse width modulation control signal increases in time, thereby suppressing an abnormal increase in current.

According to an embodiment, the RPM value of the non-commutator DC motor 140 calculated by the PWM controller 160 as the input of the rotor position information by the hall sensor 150 and the reference RPM stored in the reference RPM storage unit 170 The pulse width modulation control signal applied to the motor driver 130 is adjusted according to the comparison result with the value. When the RPM value of the non-commutator DC motor 140 is smaller than the reference RPM value stored in the reference RPM storage unit 170, It is judged that there is no fear of generating a surge current, and a normal pulse width modulation control signal in which a high signal or a low signal is maintained for a long time, such as before or after the H section of the PWM signal waveform shown in FIG. 4, is applied to the motor driver 130. To drive the motor drive unit 130 at a normal speed. However, when the RPM value of the non-commutator DC motor 140 is greater than (or equal to) the reference RPM value stored in the reference RPM storage unit 170, there is a fear of generating a surge current. There 4, a short period pulse width modulation control signal in which a high signal and a low signal are alternately applied to the motor driver 130 within a short time, such as the H section of the PWM signal waveform shown in FIG. To drive the switching.

It has been described so far limited to one embodiment of the present invention, it is obvious that the technology of the present invention can be easily modified by those skilled in the art. Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

1 is a block diagram of a drive device for a non-commutator DC motor according to the prior art,

2 is a signal waveform diagram according to a driving method for a non-commutator DC motor according to the prior art;

Figure 3 is a block diagram of a drive device for a non-commutator DC motor according to an embodiment of the present invention,

4 is a signal waveform diagram according to a driving method for a non-commutator DC motor according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: AC power supply 120: smoothing circuit

130: motor drive unit 140: non-commutator DC motor

150: Hall sensor 160: pulse width modulation control unit

170: reference RPM storage unit

Claims (6)

Smoothing circuit part which smoothes AC voltage applied from AC power supply to DC voltage, A motor driving unit which switches according to a pulse width modulation (PWM) control signal to provide a DC output of the smoothing circuit unit to a motor driving power source; A non-commutator DC motor that rotates by application of the motor driving power source, A position detection sensor for detecting a rotor position of the non-commutator DC motor and outputting rotor position information; A reference RPM storage unit for storing a RPM value at which a surge current may be generated during a high speed rotation of the non-commutator DC motor as a reference RPM value; According to a comparison result between the RPM value of the non-commutator DC motor calculated by inputting the rotor position information and the reference RPM value, the pulse width modulation control signal is provided to switch and drive the motor drive at a normal speed. Pulse width modulation control unit to drive at high speed The drive device for a non-commutator DC motor comprising a. The method of claim 1, The position detection sensor uses any one of a Hall sensor, a resolver element, and an encoder. Drive device for non-commutator DC motor. The method of claim 1, The pulse width modulation control unit controls pulse width modulation in a period in which a high signal and a low signal alternate within a shorter time than a pulse width modulation control signal when switching driving at the normal speed to drive the motor driving unit at high speed. To apply a signal to the motor driver. Drive device for non-commutator DC motor. (a) detecting rotor position of the non-commutator DC motor to generate rotor position information; (b) calculating RPM values of the non-commutator DC motor based on the rotor position information; (c) comparing the RPM value of the non-commutator DC motor with a preset reference RPM value; (d) switching the non-commutator DC motor at a normal speed or switching driving at a high speed according to a comparison result of the RPM values; Driving method for a non-commutator DC motor comprising a. The method of claim 4, wherein In the step (a), the rotor position information is generated using the rotor position value detected by any one of a Hall sensor, a resolver element, and an encoder. Driving method for non-commutator DC motor. The method of claim 4, wherein In the step (c), the reference RPM value used for the comparison is an RPM value that may generate a surge current during the high speed rotation of the non-commutator DC motor, In the step (d), when the RPM value calculated in the step (b) is greater than (or equal to) the reference RPM value, the non-commutator DC motor is switched at high speed. Driving method for non-commutator DC motor.

Images