KR20210010047A - System for control sensorless blushless direct current motor and method therefor - Google Patents

Abstract

The present invention relates to a sensorless BLDC motor control system and a method thereof. The sensorless BLDC motor control system comprises: a BLDC motor; an inverter supplying a power source to the BLDC motor; a current detection unit detecting current supplied to the motor by the inverter; a control unit providing a rotating speed control signal of the BLDC motor based on the current information detected by the current detection unit; and a PWM controller generating a PWM signal according to a control signal of the control unit to turn on or turn off power transistors within the inverter. The control unit performs the following steps: applying initial current with a predetermined size to the BLDC motor for arrangement of a rotor; then arithmetically converting a current ripple detected by the current detection unit to determine whether the converted current ripple value is over a preset value; if the current ripple is determined to be over a set value, increasing the initial current by a predetermined size for a set time and supplying the increased current; after increasing the initial current and supplying the increased current, again repeating the step of determining whether the current ripple value detected by the current detection unit is over the preset value; and if the current ripple value arrives at a preset value or less after the set time, supplying a preset maximum limit value as forced driving current to the BLDC to switch to a sensorless mode. Therefore, the present invention remarkably reduces a driving failure state by checking the arrangement state by the current ripple of the motor, thereby ensuring driving reliability.

Description

Sensorless BLDC motor control system and its method TECHNICAL FIELD {SYSTEM FOR CONTROL SENSORLESS BLUSHLESS DIRECT CURRENT MOTOR AND METHOD THEREFOR}

The present invention relates to a sensorless BLDC motor control system and method thereof, and more particularly, to a sensorless BLDC motor control system and method for stably performing rotor alignment.

The present invention relates to a control of a brushless direct current ("BLDC") motor, and more particularly, to a control method of a BLDC motor in which a rotor position is forcibly aligned during the initial operation of the BLDC motor.

Currently, BLDC motors are widely used in products that require high-efficiency variable speed operation, such as compressors for refrigerators and air conditioners, and washing machines.

In general, a stator of a BLDC motor uses an armature formed by passing an electric current through a coil, and a permanent magnet formed by repeating the N and S poles is used for the rotor. In order for the BLDC motor to rotate continuously, the formation of a continuous rotating magnetic field of the BLDC motor is necessary, and in order to form a continuous rotating magnetic field, the commutation of the current flowing through the coils of each phase of the armature must be performed at an appropriate time. For conversion, the position of the rotor must be accurately recognized. Here, the conversion is to change the current direction of the motor stator coil so that the rotor can rotate.

For smooth operation of the BLDC motor, the position of the rotor and the switching point of the phase current must be precisely matched. For this, a device for detecting the position of the rotor is required. In general, a hole is used to detect the position of the rotor. A position detection sensor such as a Hallsensor, a resolver element, or an encoder was used.

Since such a position detection sensor is expensive to manufacture, and the compressor cannot be used due to environmental problems such as temperature inside the compressor, it is a sensorless sensor that indirectly detects the position of the rotor using the voltage and current information of the BLDC motor. sensorless) control was sought.

In this way, an operation mode in which the position of the rotor is detected using an electric circuit instead of a position detection sensor is called a sensorless operation mode.

On the other hand, in the operation control of the BLDC motor including the sensorless operation mode, since information on the position of the rotor is not recognized during stop, a forced initial starting method is selected before driving in the sensorless operation mode. This is to align the rotor position by passing current through the three-phase windings of the BLDC motor for a certain period of time during initial start-up.

Usually, sensorless logic has voltage information and back electromotive force information, and it is essential to find out the position of the magnet (rotor).Stable sensorless control is achieved only when the speed of the motor increases and the back electromotive force information rises to a level of confidence. . Therefore, for a back EMF-based sensorless control algorithm, the important thing is to raise the speed of the motor to a certain level through open-loop control during initial operation.

The rotor alignment of a conventional sensorless motor is performed as follows.

1 is a flow chart of a conventional sensorless BLDC motor control method.

First, (Ids: 10A or Vds=0.2V) is supplied to the D-axis of the rotor as an initial current (S101). The rotor waits for an arbitrary alignment time (2 seconds) or more (S102). After providing the initial current, the current is applied until the rotor stops rotating. Although different for each application, the fan cooling motor usually stops within 2 seconds.

Forced starting current (Open-Loop current: Ide 20A) is applied to the motor (S103). At this time, the acceleration of the rotor is 200 rpm/s (minimum speed for sensorless control). When the speed of the rotor is 500 rpm or more (S104), since back electromotive force is sufficiently generated, it is switched to the sensorless control mode (S105).

At this time, to drive in the sensorless control mode, it is determined by looking at the back EMF information.

Such a conventional algorithm is an algorithm that rotates the motor with the voltage and current values tuned during development, and is suitable for situations that deviate from the development situation (e.g., the instantaneously changing rotor (windmill) state and the inertia distribution of the fan and motor, etc.). If placed, drive failure may occur.

In particular, if the rotor of the motor in step S102 goes to step S103 in the state that the N-pole is not aligned, as shown in the graph of Fig. 2, a phenomenon in which the drive fails with a very high probability occurs, and step S103 is also always a constant current. As is applied, the step S104 cannot be reached stably.

In addition, the rotational force of the motor varies according to the current value according to the ambient temperature (minus 40 degrees, image 110 degrees) even after alignment.The developer designates a forced starting current value (eg: 20A) through various experiments, and the alignment waiting time is also Specify. In addition, the conventional motor alignment method is a control without feedback that restarts when a failure occurs in the middle.

In addition, depending on the initial position of the rotor, the alignment of the rotor can be performed in just 0.1 seconds. As in the prior art, supplying the same starting current for alignment at all times supplies unnecessarily large currents, thereby reducing unnecessary power. It may be consumed.

Accordingly, the present invention was devised to solve the above problems, and is to provide a sensorless BLDC motor control system and method capable of remarkably reducing the starting failure situation by grasping the alignment state by the current ripple of the motor.

In addition, the present invention monitors the current ripple of the motor to determine the alignment state, thereby reducing the alignment time and reducing the overall startup time, as well as increasing the power required for alignment according to the rotor state after initially consuming low power. Therefore, it is to provide a control system and method for a sensorless BLDC motor capable of reducing power consumption compared to a conventional algorithm for supplying and aligning a constant voltage.

The configuration according to the first aspect of the present invention for achieving the above object is a sensorless BLDC motor control system, comprising: a BLDC motor, an inverter supplying power to the BLDC motor, and detecting a current supplied to the motor from the inverter. A current detection unit and a control unit that provides a control signal for controlling the rotational speed of the BLDC motor based on current information detected by the current detection unit, and a PWM signal according to the control signal of the control unit to turn on the power transistors in the inverter unit Or a PWM controller that turns off; The control unit applies an initial current of a certain size to the BLDC motor for rotor alignment, and then arithmetically converts the current ripple detected by the current detection unit to determine whether the converted current ripple value exceeds a preset value. And, as a result of the determination, if the current ripple value exceeds the set value, the initial current is increased and supplied by a predetermined size for a certain period of time, the initial current is increased and supplied, and then the current ripple value detected by the current detector is a preset value. Repeats the process of determining whether it exceeds, and when the current ripple value becomes less than or equal to a preset value after a certain period of time, a forced starting current is supplied to the BLDC motor to a preset maximum limit value to switch to a sensorless mode. To do.

The control unit includes a Clarke unit that converts the three-phase current supplied to the motor into a two-phase current, a Park unit that outputs a current signal obtained by synchronously converting the two-phase current, and an absolute value that converts the synchronously converted current signal into an absolute value. A value conversion unit, a high frequency removal unit that removes a high frequency signal from the absolute value-converted current signal, and a rotor motion detection unit (ripple check unit) that determines whether the ripple of the current signal output from the high frequency removal unit is greater than or equal to a preset size. And a current value increasing unit receiving the comparison result of the rotor motion test unit and increasing the current value when the ripple value of the current signal is greater than or equal to a preset size.

In addition, the control unit is connected to the input terminal of the PWM controller, the reverse-park module and reverse-Clarke unit for converting the synchronous coordinates of the input current signal and converting the two-phase current signal into a three-phase current signal, and the reverse-park And a current controller for inputting a voltage signal to the reverse-Clarke unit, a speed controller for inputting a current signal for controlling the motor speed to the current controller, and the speed of the rotor by receiving a detection signal from the current detector. It is preferable to further include a sensorless module for outputting a speed control signal to the controller.

When the converted current ripple value exceeds a preset value, the control unit increases the initial current by a preset size at every predetermined time and compares the ripple current of the motor with a preset value within a predetermined time. It is effective to repeat until the initial current becomes the limit value of the forced start current.

On the other hand, the configuration according to the second aspect of the present invention for achieving the above object is a sensorless BLDC motor control method, comprising: a first step of applying an initial current of a predetermined size to the motor for rotor alignment; A second step of arithmetically converting the ripple of the current detected by the BLDC motor after applying the initial current; A third step of determining whether the ripple value of the arithmetically converted current exceeds a preset value; A fourth step of increasing and supplying an initial current by a predetermined size for a predetermined time when the ripple value exceeds the set value as a result of the determination in the second step; A fifth step of determining whether the ripple value of the current supplied to the motor again exceeds a preset value after increasing and supplying the initial current; A sixth step of supplying a forced starting current to the motor up to a preset maximum limit value if the ripple value supplied to the motor is less than or equal to a preset value as a result of the determination in the fifth step; And a seventh step of switching to the sensorless mode when the rotor speed becomes a speed switchable to the preset sensorless mode.

Here, the second step includes a Clarke conversion step of converting a three-phase current supplied to the BLDC motor into a two-phase current; A Park conversion step of outputting a current signal obtained by synchronously converting the two-phase current; An absolute value conversion step of converting the synchronously converted Q-axis current signal into an absolute value; It is preferable to include a high frequency removal step of removing the high frequency signal from the absolute value converted Q-axis current signal.

In the fourth and fifth steps, a process of increasing the initial current by a preset size at every predetermined time and comparing the ripple current of the motor with a preset value within a predetermined time, the increased initial current is the forced start current limit. It is preferable to repeat until the value is reached.

The configuration according to the third aspect of the present invention for achieving the above object is a computer-readable recording medium in which a program for performing a sensorless BLDC motor control method is recorded, and a motor for aligning a rotor to a sensorless BLDC motor A first step of applying an initial current of a predetermined size to the device; A second step of arithmetically converting the ripple of the current supplied to the BLDC motor after applying the initial current; A third step of determining whether the ripple value of the arithmetically converted current exceeds a preset value; A fourth step of increasing and supplying an initial current by a predetermined size for a predetermined time when the ripple value exceeds a set value as a result of the determination in the second step; A fifth step of determining whether the ripple value of the current supplied to the BLDC motor exceeds a preset value after increasing and supplying the initial current; A sixth step of supplying a forced starting current to a motor up to a preset maximum limit value if the ripple value of the current is less than a preset value as a result of the determination in the fifth step; And a seventh step of switching to the sensorless mode when the rotor speed becomes a speed switchable to the preset sensorless mode.

Here, the second step includes a Clarke conversion step of converting a three-phase current supplied to the BLDC motor into a two-phase current; A Park conversion step of outputting a current signal obtained by synchronously converting the two-phase current; An absolute value conversion step of converting the synchronously converted Q-axis current signal into an absolute value; It is preferable to include a high frequency removal step of removing the high frequency signal from the absolute value converted Q-axis current signal.

According to the sensorless BLDC motor control system and method having the above configuration, it is possible to secure starting reliability by remarkably reducing the starting failure situation by identifying the alignment state by the current ripple of the motor.

In addition, by monitoring the current ripple of the motor and grasping the alignment state, the alignment time can be reduced and the overall start-up time can be reduced, and the power required for alignment is increased according to the rotor condition after initial low power consumption. It can reduce power consumption compared to an algorithm that supplies voltage to align.

1 is a flow chart of a conventional sensorless BLDC motor control method,
2 is a current waveform diagram of the rotor when the motor is aligned by a conventional sensorless BLDC motor control method,
3 is a configuration diagram of a control system of a sensorless BLDC motor according to the present invention,
Figure 4 is a flow chart of the control method of the sensorless BLDC motor of the present invention,
5 is a flow chart of a method of calculating the Q-axis power ripple of FIG. 4;
6A is a current waveform diagram of the rotor when the motor is normally aligned by the control method of the sensorless BLDC motor according to the present invention.
6B is a current waveform diagram of the rotor when the motor is abnormally aligned by the control method of the sensorless BLDC motor according to the present invention.

Advantages and features of the present invention, and a method of achieving the same will be described through embodiments to be described later in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. However, these embodiments are provided to explain in detail enough to be able to easily implement the technical idea of the present invention to those of ordinary skill in the art.

In the drawings, embodiments of the present invention are not limited to the specific form shown, but are exaggerated for clarity. In addition, parts denoted by the same reference numerals throughout the specification represent the same elements. In the present specification, the expression "and/or" is used as a meaning including at least one of the elements listed before and after. In addition, the singular form includes the plural form unless specifically stated in the text. In addition, components, steps, actions and elements referred to as “comprising” or “comprising” as used in the specification mean the presence or addition of one or more other elements, steps, actions, elements and devices.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The present invention provides an algorithm that detects the alignment state when performing the forced alignment algorithm of the rotor and, if the alignment of the rotor is unstable, generates a higher magnetic flux to strengthen the forced alignment, thereby achieving rotor alignment. That is, the present invention is an algorithm that detects the alignment state when performing the forced alignment algorithm and, if necessary, generates a higher magnetic flux to make the forced alignment stronger, thereby achieving a stable state before forced start.

In addition, the present invention is a rotor d-axis alignment and starting algorithm for sensorless control of a BLDC motor, which determines the alignment state in a fast time and actively applies a higher electromagnetic force to perform stable alignment before forced starting.

3 is a block diagram of a sensorless BLDC motor control system according to the present invention.

The motor of this embodiment may include a Surface Mounted Permanent Magnet Synchronous Motor (SPMSM).

As shown in FIG. 3, the sensorless BLDC motor control system 1 receives the Vde Ref signal and the Vqe Ref signal output from the speed controller 11, the current controller 12, and the current controller 12, and receives the synchronous coordinate system. Inverse-Park and Inverse-Clarke that converts 2-phase voltage to 2-phase stop coordinate system voltage (Inverse park) and then converts 2-phase voltage to 3-phase voltage (Inverse Clarke) and outputs Vus_Ref, Vvs_ Ref, and Vws_Ref signals. The unit 13, a PWM controller 14 that receives Vus_Ref, Vvs_Ref, and Vws_Ref signals and converts them into Vun, Vvn, and Vwn signals and outputs them, an inverter 30 connected to the output terminal of the PWM controller 14, and an inverter ( A motor 40 connected to 30), an analog to digital converter (ADC) unit 16 that senses the current at the output terminal of the inverter 30, and a sensorless module 17 that receives an output signal from the ADC unit 16 , After applying the initial current, the control unit 10 receives the output signal of the ADC unit 16 and performs rotor alignment using the ripple current of the output signal of the ADC unit 16.

In the speed controller 14, a speed command is input to the input terminal of the speed controller 14, and the estimated speed (Wm) estimated by the sensorless algorithm of the sensorless module 17 is input, and the speed command and the estimated speed (Wm) are input. ), the speed controller is performed and the output of the speed controller 14 becomes a current command. The operation of the speed controller 14 is largely divided into two. First, before the sensorless operation, the speed controller 14 is not operated, and is forcibly driven (Align, openloop step) at a speed (500 rpm) specified by a user (initial developer). Second, when the sensorless operation starts, the speed command input by the user and the Wm estimated by the sensorless algorithm are input to the input terminal of the speed controller 14, and the speed controller 14 controls the speed command by the difference between the speed command and Wm. And the output of the speed controller 14 becomes a current command.

According to the present invention, the control unit 10, the Clarke & Park unit 21 for Clarke conversion and Park conversion of the output signal of the ADC unit 16, the two-phase current signal Ide converted by the Clarke & Park unit 21 , An absolute value conversion unit 22 that converts Iqe) to an absolute value, a high frequency removal unit 23 that removes high frequencies from a signal converted to an absolute value, and the ripple value of the output signal Iqe of the high frequency removal unit 23 A current increasing unit that increases and outputs a current value to the current controller 12 according to the test results of the rotor movement (ripple) inspection unit 24 and the rotor movement (ripple) inspection unit 24 to check whether this value is above a certain value ( 25).

Here, the Clarke transformation is for outputting a quadrature-axis current amount and a direct-axis current amount in a stationary coordinate system after the stator current is subjected to coordinate transformation. The Park transformation is for converting the horizontal axis current quantity and the rectangular current quantity in the stationary coordinate system into the horizontal axis current quantity and the rectangular current quantity in the rotating coordinate system.

It is preferable that each of the components of the control unit 10 of the present invention described above is implemented as a program module.

Figure 4 is a flow chart of the sensorless BLDC motor control method of the present invention. As shown in Fig. 4, an initial current (10A) is supplied to the D-axis of the rotor to align the rotor (S1). Wait longer than the random alignment time (eg, 1 second) of the rotor (S2). Arbitrary alignment time is a time set to 1 second until rotation of the rotor stops after the initial current is supplied, that is, until the rotor is aligned. At this time, the rotor can be stopped in just 0.5 seconds, but the arbitrary alignment time is set to the maximum value.

The control unit 10 of FIG. 3 receives the Q-axis current of the rotor from the ADC unit 16 and converts the ripple (Iqe-Ripple) of the Q-axis current into an arithmetic value (S3). Here, a process of converting the ripple (Iqe-Ripple) of the Q-axis current into an arithmetic value will be described later.

The control unit 10 of FIG. 3 determines whether the ripple value of the rotor Q-axis current is less than or equal to a preset ripple limit value (S4). Here, the ripple limit value will be the maximum value of the current ripple occurring in the Q-axis current during normal alignment of the motor.

As a result of the determination in step S4, if the ripple value of the Q-axis current is less than or equal to the set value, the control unit 10 waits for a certain time (eg, 100 ms) to stabilize the rotor (S5).

The control unit 10 of FIG. 3 supplies a current value (Ide: a current value sensed when the rotor is aligned by adding the current magnitude) for forced start (S6).

The sensorless module 17 of FIG. 3 determines whether the rotor speed is in the range of the maximum limit value or the minimum limit value based on the current value sensed by the ADC unit 16 (S7). For example, the sensorless module 17 fixes the Ide value at, for example, 20A, and increases the speed of the rotor from 200 rpm to 500 rpm, and determines whether or not back EMF information is sufficiently displayed.

The sensorless module 17 determines whether the rotor speed is 500rpm or more (S8), and if it is 500rpm or more, it switches to the sensorless mode (S9).

On the other hand, as a result of the determination in step S4, if the ripple of the Q-axis current is greater than or equal to the set value, since the rotor is moving without being aligned, the starting current of the D-axis is increased by, for example, 0.5A/s (S10).

It is determined whether the applied time by increasing the starting current of the D-axis is more than a certain time (eg, about 5 seconds) (S11). If the application time of the starting current of the D-axis is less than a certain time, the process returns to step S3 of arithmetically converting the ripple of the Q-axis current again, and the process after step S4 of determining whether the Iqe ripple value is less than or equal to the set value is performed.

After that, if the Iqe ripple value is more than the set value, the initial current supplied to the D axis of the motor is increased by 0.5A/s and the process of checking the Iqe ripple value generated in the Q axis of the motor is repeated. This increases the starting current of the D-axis by a certain amount (for example, 0.5A) every certain time (for example, 1 second) until the Iqe ripple value becomes smaller than the set value, that is, until the rotor is stably aligned. To check the rotor movement.

FIG. 5 shows a step of arithmetically converting the ripple of the Q-axis current of FIG. 3. As shown in Fig. 4, 10A is applied as an initial current to the D-axis of the rotor (T1).

The ADC unit 16 of FIG. 3 measures the three-phase current (Ius, Ivs, Iws) of the inverter output terminal (T2).

The Clarke & Park unit 18 of FIG. 3 performs Clarke transformation for converting a three-phase current into two phases and outputs Ids and Iqs (T3).

Then, the Clarke & Park unit 18 converts Ids and Iqs into Ide and Iqe by performing Park transformation for synchronous coordinate transformation (T4).

The absolute value conversion unit 19 of FIG. 3 converts the Iqe signal into an absolute value (T5). At this time, converting only the Iqe signal to an absolute value is for examining only the ripple value of the Q-axis current.

The high frequency removal unit 20 of FIG. 3 removes the high frequency signal of the absolute value converted Iqe signal (T6).

Thereafter, the ripple value of the Iqe signal from which the high-frequency signal has been removed in step S4 of FIG. 3 is input to the ripple inspection unit 21 of FIG. 2 to determine whether it is equal to or higher than the set value, and if it is higher than the set value, the starting current Ide is increased. .

6A is a current waveform diagram of the rotor when the motor is normally aligned by the control method of the sensorless BLDC motor according to the present invention, and FIG. 6B is the abnormal alignment of the motor by the control method of the sensorless BLDC motor according to the present invention. It is the current waveform diagram of the rotor.

Conventionally, after the starting voltage was input, a certain time was waited until the rotor was aligned. However, in the present invention, the alignment voltage is applied to the D-axis of the rotor, and the current ripple of the Q-axis is viewed to determine the alignment.

Referring to FIG. 6A, when the rotor is stably driven, the ripple of the Iqe current is reduced, and a forced starting current (OpenLoop current) may be applied to a minimum.

Referring to FIG. 6B, when the rotor is driven in an abnormal situation, the rotor is artificially shaken by an external factor, so that the ripple of the Iqe current increases. Accordingly, the forced starting current (OpenLoop current) peaks.

According to the present invention as described above, it is possible to secure start-up reliability by remarkably reducing the start-up failure situation by grasping the alignment state based on the ripple value of the current sensed by the motor compared to the prior art. In addition, the present invention can reduce the overall start-up time by reducing the alignment time by checking the additional alignment state, and increases the power required for alignment according to the state of the rotor after initially consuming low power. Compared to the algorithm that supplies power, it has the advantage of helping power consumption.

The above is an illustration of the present invention, and should not be interpreted limitedly. Although several exemplary embodiments of the present invention have been described, those skilled in the art will readily understand that many changes are possible in the exemplary embodiments without significantly departing from the novel teachings and advantages of the present invention. Accordingly, all such modifications are intended to be included within the scope of the present invention as defined in the claims. Therefore, the above is an illustration of the present invention, and should not be construed as being limited to specific embodiments in the disclosed or disclosed invention, and changes to the disclosed embodiments and other embodiments are disclosed in this specification. It is to be understood as being included within the scope of the invention to be.

1: sensorless BLDC motor control system
11: speed controller 12: current controller
13: Station-Park and Station-Clarke Department
14: PWM controller 16: ADC detection unit
17: sensorless control module 21: Clake and Park part
22: absolute value conversion unit 23: high frequency removal unit
24: rotor motion inspection unit (ripple inspection unit)
25: current value increase unit
30: inverter 40: BLDC motor

Claims (9)

As a sensorless BLDC motor control system,
BLDC motor, an inverter that supplies power to the BLDC motor, a current detection unit that detects a current supplied to the motor from the inverter, and a control signal for controlling the rotation speed of the BLDC motor based on current information detected by the current detection unit And a PWM controller for turning on or off power transistors in the inverter unit by generating a PWM signal according to a control signal of the controller;
The control unit applies an initial current of a certain size to the BLDC motor for rotor alignment, and then arithmetically converts the current ripple detected by the current detection unit to determine whether the converted current ripple value exceeds a preset value. And, as a result of the determination, if the current ripple value exceeds the set value, the initial current is increased and supplied by a predetermined size for a certain period of time, the initial current is increased and supplied, and then the current ripple value detected by the current detector is a preset value. Repeats the process of determining whether it exceeds, and when the current ripple value becomes less than or equal to a preset value after a certain period of time, a forced starting current is supplied to the BLDC motor to a preset maximum limit value to switch to a sensorless mode. Sensorless BLDC motor control system. The method of claim 1,
The control unit includes a Clarke unit that converts the three-phase current supplied to the motor into a two-phase current, a Park unit that outputs a current signal obtained by synchronously converting the two-phase current, and an absolute value that converts the synchronously converted current signal into an absolute value. A value conversion unit, a high frequency removal unit that removes a high frequency signal from the absolute value-converted current signal, and a rotor motion detection unit (ripple check unit) that determines whether the ripple of the current signal output from the high frequency removal unit is greater than or equal to a preset size. And a current value increasing unit that receives the comparison result of the rotor motion test unit and increases the current value when the ripple value of the current signal is greater than or equal to a preset size. The method of claim 1,
The control unit is connected to the input terminal of the PWM controller and converts the synchronous coordinates of the input current signal and converts the two-phase current signal into a three-phase current signal. The reverse-park module and the reverse-Clarke part, the reverse-park and reverse -A current controller for inputting a voltage signal to the Clarke unit, a speed controller for inputting a current signal for controlling the motor speed to the current controller, and a detection signal of the current detection unit to detect the rotor speed to the speed controller. Sensorless BLDC motor control system, further comprising a sensorless module for outputting a speed control signal. The method of claim 1,
When the converted current ripple value exceeds a preset value, the control unit increases the initial current by a preset size at every predetermined time and compares the ripple current of the motor with a preset value within a predetermined time. The sensorless BLDC motor control system, characterized in that it repeats until the initial current becomes the limit value of the forced start current. As a sensorless BLDC motor control method,
A first step of applying an initial current of a predetermined size to the motor to align the rotor;
A second step of arithmetically converting the ripple of the current detected by the BLDC motor after applying the initial current;
A third step of determining whether the ripple value of the arithmetically converted current exceeds a preset value;
A fourth step of increasing and supplying an initial current by a predetermined size for a predetermined time when the ripple value exceeds a set value as a result of the determination in the second step;
A fifth step of determining whether the ripple value of the current supplied to the motor exceeds a preset value after increasing and supplying the initial current;
A sixth step of supplying a forced starting current to the motor up to a preset maximum limit value if the ripple value supplied to the motor is less than or equal to a preset value as a result of the determination in the fifth step;
And a seventh step of switching to a sensorless mode when the rotor speed becomes a speed switchable to a preset sensorless mode. The method of claim 1,
The second step,
Clarke conversion step of converting the three-phase current supplied to the BLDC motor into a two-phase current;
A Park conversion step of outputting a current signal obtained by synchronously converting the two-phase current;
An absolute value conversion step of converting the synchronously converted Q-axis current signal into an absolute value;
A sensorless BLDC motor control method comprising the step of removing a high frequency signal from the absolute value converted Q-axis current signal. The method of claim 6,
In the fourth and fifth steps, when the converted current ripple value exceeds a preset value, the controller increases the initial current by a preset amount every predetermined time and compares the ripple current of the motor with a preset value. A sensorless BLDC motor control method, characterized in that the process of repeating the process within a predetermined time until the increased initial current reaches a limit value of the forced start current. As a computer-readable recording medium in which a program for performing a sensorless BLDC motor control method is recorded,
A first step of applying an initial current of a predetermined size to the motor to align the rotor to the sensorless BLDC motor;
A second step of arithmetically converting the ripple of the current supplied to the BLDC motor after applying the initial current;
A third step of determining whether the ripple value of the arithmetically converted current exceeds a preset value;
A fourth step of increasing and supplying an initial current by a predetermined size for a predetermined time when the ripple value exceeds the set value as a result of the determination in the second step;
A fifth step of determining whether the ripple value of the current supplied to the BLDC motor exceeds a preset value after increasing and supplying the initial current;
A sixth step of supplying a forced starting current to a motor up to a preset maximum limit value if the ripple value of the current is equal to or less than a preset value as a result of the determination in the fifth step;
When the rotor speed reaches a speed that can be switched to a preset sensorless mode, a program that performs a sensorless BLDC motor control method comprising the seventh step of switching to a sensorless mode is recorded and can be read by a computer media. The method of claim 8,
The second step,
Clarke conversion step of converting the three-phase current supplied to the BLDC motor into a two-phase current;
A Park conversion step of outputting a current signal obtained by synchronously converting the two-phase current;
An absolute value conversion step of converting the synchronously converted Q-axis current signal into an absolute value;
A recording medium readable by a computer in which a program for performing a sensorless BLDC motor control method, comprising a step of removing a high frequency signal from the absolute value converted Q-axis current signal.

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