KR19980059928A - Inrush current prevention circuit and control method - Google Patents

Abstract

The present invention relates to a circuit for preventing inrush current generated in a multiphase motor driving apparatus by an inverter method and a control method thereof. In an inverter circuit for driving a multiphase motor in which an inrush current limiting resistor and a phototriac and a triac are connected in parallel, Sensing a power supply state to a circuit consisting of a transistor configured to switch the phototriac to operate, a microcomputer controlling the transistor, and preventing the inrush current, and outputting a control signal by delaying a predetermined time after the detection The damage caused by the impact power is not caused to the system by the algorithm comprising the step of supplying the normal main power by the control signal, thereby extending the life of the system and reducing the malfunction to improve performance.

Description

Inrush current prevention circuit and control method

The present invention relates to a prevention circuit for removing inrush current generated in a multiphase motor driving apparatus by an inverter method and a control method thereof.

In general, the multi-phase motor driving device of the inverter system is driven by converting the commercial power into the driving power in the form of PWN signal, thereby making it safer and improving performance.

Hereinafter, an inrush current prevention circuit and a control method thereof according to the related art will be described with reference to the accompanying drawings.

1 is a block diagram showing a rush current prevention circuit according to the prior art, Figure 2 is a waveform diagram showing the operation of the rush current prevention circuit according to the prior art.

According to the prior art, as shown in Figure 1, the filter unit 1 for removing noise included in the 60Hz commercial power source, and the system microcomputer by detecting the frequency of the commercial power removed from the filter unit 1 (not shown) A sensing unit 2 for outputting a power source, a rectifying unit 3 for rectifying commercial power of the filter unit 1 to output a DC power source, and a smoothing unit for accumulating and discharging power to reduce DC ripple of the rectified power source. (4), a control power supply unit 5 for receiving the smoothed rectified power and supplying power to a control unit (not shown) and outputting a power control signal, and between the rectifying unit 3 and the smoothing unit 4. A removal unit 6 installed at one end and filtering and removing the inrush current by the power control signal, a discharge unit 7 for discharging the power accumulated in the smoothing unit 4, and the smoothing unit 4 Inverter unit for driving by PWM signal by applying power to BLDC motor (8 )

A power switch 9 is connected between the power source and the filter unit 1.

In the operation and method according to the prior art configured as described above, as shown in FIG. 2, when commercial power is first applied to the system from the power switch 9, AC power of 60 Hz is introduced into the system.

At this time, the noise component among the introduced power is removed from the filter unit 1.

The detection unit 2 detects the frequency of the power output from the filter unit 1 to inform the system microcomputer that commercial power is currently being applied.

In addition, the power passing through the filter unit 1 is input to the rectifying unit 3 converts the DC power of the commercial power supply voltage and supplies a stable DC power.

The power supplied in this way outputs a high quality constant voltage with a low ripple rate in the smoothing part 4 which consists of a capacitor Cd.

At this time, the smoothing unit 4 starts charging from the initial voltage OV of the DC power supply. Subsequently, the inrush current Ii generated at the initial voltage is removed from the inrush current limiting resistor Rf of the removal unit 6 to output the smoothing unit 4.

Then, the smoothing unit 4 continues to be charged, and as shown in FIG. 2A, the power supply control unit 5 detects the arrival time Tc at which Vm becomes Vc and outputs a start signal Vs to the microcomputer.

The start signal Vs is transmitted to the amplifier of the removing unit 6 via a microcomputer, which is charged in the capacitor C of the removing unit 6, and by this charging, time delay is possible for a predetermined time.

After this time delay, the phototriac of the removal unit 6 is operated by the amplifier to drive the triac, thereby inducing a current applied to the resistor Rf to the triac.

That is, after the power including the inrush current flows through the resistor Rf for a predetermined time as shown in FIGS. 2B, 2C, and 2D, the normal main power is supplied.

On the other hand, when the power is cut off, the power switch 9 is first cut off to stop the commercial power being supplied to the system.

Then, when the Vm voltage charged in the smoothing unit 4 starts to discharge, when the Vm reaches Vc as shown in FIG. 2A, the application of the start signal Vs of the power control unit 5 flowing into the microcomputer is stopped. The voltage charged in the capacitor C of the removing unit 6 discharges from the resistor connected to the capacitor.

If commercial power is again applied as the power switch 9, the above process should be repeated one time.

Hereinafter, the description of the operation of driving the motor with the PWM signal is omitted because it is less relevant to the present invention.

In the prior art, the inrush current generated when the power supply is sufficiently prevented, but there is a problem that the incomplete operation is performed as well as the damage of the system because there is no measure against the inrush current generated when re-supply after interruption.

The present invention has been made to solve the above problems, the inrush current prevention circuit and its control method to completely remove the inrush current generated in the system by dividing the control signal generated in the microcomputer into the power supply and the interruption The purpose is to provide.

1 is a block diagram showing a inrush current prevention circuit according to the prior art

2a to 2d is a waveform diagram showing the operation of the inrush current prevention circuit according to the prior art

3 is a block diagram showing an inrush current prevention circuit according to the present invention

4A to 4D are waveform diagrams showing the operation of the inrush current preventing circuit during power supply according to the present invention.

5A to 5D are waveform diagrams illustrating an operation of an inrush current preventing circuit when power is supplied again according to the present invention.

6 is a flow chart showing a control method of the inrush current prevention circuit according to the present invention.

Explanation of symbols for main parts of the drawings

20: power switch 21: filter

22: detection part 23: rectification part

24: smooth part 25: discharge part

26: power control unit 27: drive unit

28: motor 29: removal unit

In the inverter circuit for driving a multi-phase motor in which the inrush current limiting resistor and the photo triac and the triac are connected in parallel, the phototriac is operated so that the switching circuit is composed of a switching circuit and a microcom circuit for controlling the transistor. Detecting an inrush current to prevent an inrush current, outputting a control signal by delaying a predetermined time after the detection, and supplying the normal main power by the control signal. No damage is caused by this, which extends the life of the system and reduces the malfunction, thereby improving performance.

Hereinafter, the inrush current preventing circuit and its control method according to the present invention with reference to the accompanying drawings in detail as follows.

Figure 3 is a block diagram showing the inrush current prevention circuit according to the present invention, Figures 4a to 4d is a waveform diagram showing the operation of the inrush current prevention circuit when the power supply according to the present invention, Figures 5a to 5d FIG. 6 is a waveform diagram illustrating an operation of an inrush current preventing circuit when power is supplied again. FIG. 6 is a flowchart illustrating a control method of an inrush current preventing circuit according to the present invention.

According to the present invention, as shown in Figure 3, the filter unit 21 for removing the noise included in the 60Hz commercial power source and the system microcomputer by detecting the frequency of the commercial power removed from the filter unit 21 (not shown) Sensor 22 for outputting the output, rectifier 23 for rectifying the commercial power of the filter unit 21 to output a DC power, and smoothing to accumulate and discharge the power to reduce the DC ripple of the rectified power The control unit 24, a control power supply unit 26 for receiving the smoothed rectified power and supplying power to a control unit (not shown) and outputting a power control signal, between the rectifying unit 23 and the smoothing unit 24. A removal unit 29 installed at one end of the power supply control signal to remove the inrush current by the limiting resistor; a discharge unit 25 for discharging the power stored in the smoothing unit 24; and the smoothing unit. PWM is applied by applying the power of the unit 24 to the BLDC motor 28 Fenugreek comprises a drive unit 27 for driving.

A power switch 20 is connected between the commercial power supply and the filter unit 21.

The removal unit 29 includes a resistor Rf for limiting the inrush current, a transistor TR for receiving and controlling a control signal of the microcomputer, and a phototriac driven by a switching signal of the transistor TR. P / T) and a triac T _Rm which cuts off power flowing to the resistor Rf by the phototriac P / T.

4 and 5, the operation according to the present invention configured as described above, if the commercial power of AC is first supplied to the system through the power switch 20 and the filter unit 21 as shown in Figure 4a At 22, the 60Hz frequency of the commercial power is sensed and a signal as shown in FIG. 4B is output to the microcomputer.

The commercial power source through the filter unit 21 is rectified DC to be a power source for driving the BLDG motor 28 via the rectifying unit 23.

The rectified power is started from the initial voltage OV to the capacitor Cd of the smoothing part 24.

At this time, an inrush current as shown in FIG. 4D is generated from the initial voltage point, and the inrush current is filtered out of the resistor Rf of the removal unit 29 and removed.

Subsequently, the smoothing unit 24 is continuously charged with power, and as shown in FIG. 4B, the power control unit 5 senses the time Tc at which Vm reaches Vc and outputs a start signal Vs to the microcomputer.

By the start signal, the microcomputer receives the frequency pulse detected by the branch 22 and sends a control signal to the removal unit 29 after a predetermined time, that is, after a delay time Td as shown in FIG. 4C.

Then, the removal unit 29 switches the power flowing to the inrush current limiting resistor Rf to the normal supply by the operation of the pot triac and the triac.

Hereinafter, the operation route of the BLDC motor 28 is omitted.

On the other hand, when the commercial power is cut off at the power switch 20, the Vm charged in the capacitor Cd of the smoothing unit 24 is discharged, and the microcomputer detects that there is no frequency signal from the sensing unit 22.

At this time, the micom blocks the control signal to the removal unit 29 to stop the _triak (T _Rm ) function of the removal unit 29, whereby the inrush current to the resistance (Rf) of the removal unit 29 Flow.

If the inrush current generated during the interruption is not completely removed as shown in FIG. 5D, when the power switch 20 is operated again as shown in FIG. 5A, the commercial power rectified by DC is recharged in the smoothing unit 24.

At the same time, the microcomputer detects the frequency of the commercial power source as shown in FIG. 5B and outputs a control signal to the removal unit 29 after a delay for a predetermined time Td as shown in FIG. 5C.

Then, the inrush current as shown in FIG. 5D is removed by filtering in the resistance Rf of the removal unit 29 during the time Td is generated.

Subsequently, when the transistor TR of the removal unit 29 is switched by the control signal of the microcomputer, the normal main power supplies the power flowing to the resistor at the root of the _phototriac P / T and triac T _Rm . To be supplied.

In the flow of the microcomputer to achieve the above-described present invention, as shown in FIG. 6, when power is first applied, an inrush current prevention subroutine is performed (S10).

Then, the microcomputer determines whether the frequency pulse of the commercial power is sensed by the detector 22 (S20), and determines whether the control signal is output from the microcomputer (S40).

When the frequency pulse is present and the control signal is output, the microcomputer executes a normal operation program of the system (S60). When the frequency pulse is not detected, the microcomputer blocks the control signal to supply power from the removal unit 29. Alternatively, if the inrush current generated during blocking is removed (S30), and only the control signal of the microcomputer is blocked, the microcomputer delays for a predetermined time and then outputs the control signal to the removal unit 29 to prevent the inrush current (S50). ).

Subsequently, after preventing the inrush current, the microcomputer performs a normal operation program of the system (S60).

The present invention prevents inrush current generated during power supply as well as inrush current generated during interruption or resupply, thereby preventing damage to the system due to impact power, thereby extending the life of the system and reducing malfunction. Has the effect of improving.

Claims (2)

Inverter circuit for driving a multi-phase motor connected in parallel with the inrush current limiting resistor and phototriac and triac; A transistor for switching the phototriac to operate; Inrush current preventing circuit comprising a micom for controlling the transistor. A control method for preventing inrush current from a power supply; Sensing the power supply state to prevent inrush current; Outputting a control signal by delaying a predetermined time after the detection; And supplying the normal main power by the control signal.