KR19980028176A - Power Factor Correction Circuit Using Inverse Sawtooth Wave - Google Patents

Abstract

The present invention relates to a power factor correction circuit using a reverse sawtooth wave, particularly a circuit for compensating the power factor of a boost converter, the voltage divider for distributing the output voltage of the boost converter to a predetermined voltage and an output signal of the voltage divider. An error amplifier for detecting an error signal proportional to a change in output voltage by comparing with a reference signal, a multiplier for multiplying an output signal and an inverse sawtooth signal by the output signal of the error amplifier, and corresponding to a turn-on current of the switching transistor A current detector for detecting an input current, a comparator for determining a turn-off time of the switching transistor by comparing an output signal of the current detector and an output signal of the multiplier, and a clock signal and an inverse sawtooth signal synchronized with the clock signal. The switching transistor in response to the generated oscillator and the clock signal of the oscillator. And a driving unit configured to drive the pulse period of the input current.

Therefore, in the present invention, since the input current can be controlled in the form of an input voltage using an inverse sawtooth signal, the circuit can be easily configured to obtain a high power factor close to the unit power factor.

Description

Power Factor Correction Circuit Using Inverse Sawtooth Wave

The present invention relates to a power factor correction circuit for a boost converter, and more particularly, to a power factor correction circuit using a reverse sawtooth wave capable of achieving a high power factor by controlling a slope of an input current using a reverse sawtooth wave.

DC power is used in a wide range of fields from commercial to home use. In order to obtain this DC power supply from a commercial AC power supply, a rectifier circuit of a capacitor input type having a simple circuit configuration is generally used. However, this circuit becomes a pulse type because the input current flows only at the peak part of the input alternating voltage, and the power factor becomes worse. Since various electric devices are combined with resistance, inductance, and capacitance components, the current phase from the power source is the power supply voltage. And the voltage appears distorted.

Therefore, the Continuous Current Mode (CCM) method is known as the closest control method to obtain the unit power factor among the methods of improving the power factor by suppressing voltage distortion in driving the converter system. .

CCM control methods include peak current detection, variable hysteresis control, and average current. These individual approaches have the advantages of obtaining high power factor, but also have disadvantages, so it is important to consider whether the circuits used in the selected system are economical and suitable.

Among the CCM control methods, the average current control method automatically controls the input current in the form of a mixture of continuous current mode (CCM) and discontinus current mode (DCM). Since the proportional sinusoidal current waveform can be obtained, the line current distortion is very low, which is the most suitable control method for the high power factor correction circuit.

However, since the average current control method has a technically complicated control structure, it is difficult to understand, and there is a problem in that manufacturing cost increases due to an increase in the number of external components for circuit implementation.

An object of the present invention is to implement a power factor correction circuit having the same operating characteristics as the concept of the average current control method, it is possible to obtain a high power factor by controlling the slope of the input current using a reverse sawtooth signal, and also simplify the circuit configuration Therefore, to provide an economical low cost power factor correction circuit.

In order to achieve the above object, a device of the present invention accumulates a voltage in an inductor in a turn-on state of a switching transistor, and compensates the power factor of a boost converter that outputs the voltage accumulated in the inductor by overlapping an input voltage. A voltage divider for dividing an output voltage of the boost converter to a predetermined voltage, an error amplifier for detecting an operation signal proportional to a change in an output voltage by comparing an output signal of the voltage divider with a reference signal, and the error A multiplier for obtaining a constant gain by multiplying the output signal of the amplifier by the inverse sawtooth signal, a current sensing unit for detecting an input current corresponding to the turn-on current of the switching transistor, and comparing the output signal of the current sensing unit with the output signal of the multiplier unit A comparator for determining a turn-off time of the switching transistor, a clock signal and the clock The switching transistor is turned on in response to an oscillator generating a reverse sawtooth wave signal synchronized with a clock signal and a clock signal of the oscillator, and the switching transistor is turned off in response to an output signal of the comparator to increase the pulse period of the input current. Characterized in that the drive unit is determined.

1 is a circuit diagram showing a power factor correction circuit using a reverse sawtooth wave according to the present invention.

2 is a waveform diagram illustrating control voltages of the power factor correction circuit according to the present invention.

3 is a waveform diagram of input currents having different gains according to the present invention.

* Explanation of symbols for the main parts of the drawings

100: boost converter 110: rectifier

200: power factor correction circuit 210: voltage divider

220: error amplifier 230: multiplier

240: current detection unit 250: comparison unit

260: oscillator 270: drive unit

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an embodiment of a power factor correction circuit using a reverse sawtooth wave according to the present invention, the boost converter 100 is a rectifier (110) for rectifying the AC signal, the smoothing capacitance (C1) to smooth the rectified signal, An inductance L accumulating the smoothed signal in response to a switching transistor T1, a diode D controlling the signal passing through the inductance L from being reversed, and an output of the conducted diode D It consists of a charging capacitance C3 for charging the signal.

The power factor correction circuit 200 divides the output signal of the boost converter 100 into a predetermined voltage by the resistors R2 and R3 and the output signal of the voltage divider 210. An error amplifier 220 including an operational amplifier AMP1, a capacitance C4, and a reference voltage Vref in order to detect an error signal Ve according to a change in the output voltage Vo compared to the reference signal Vref. ) Is multiplied by the error signal Ve of the error amplifier 220 and the reverse sawtooth wave signal Vsw to obtain a constant gain to obtain a reference voltage Vmo for controlling the input current according to the change in the output voltage Vo. A current detector 240 including a multiplier 230 and a sensing resistor Rs, a resistor R, and a capacitance C2 to generate an input current corresponding to the turn-on current of the switching transistor T1. And the switching signal by comparing the output signal Vcs of the current sensing unit 240 with the reference voltage Vmo of the multiplier 230. A comparator 250 for determining a turn-off time of the jitter T1, an oscillator 260 for generating a clock signal Clock and an inverse sawtooth signal Vsw synchronized with the clock signal Clock, and the oscillator A flip for turning on the switching transistor T1 in response to a clock signal Clock of 260 and turning off the switching transistor T1 in response to an output signal of the comparator 250 to control an input current. The driver 270 includes a flop 272, a negative-OR gate 274, and a driver 276.

Operation of the present invention configured as described above is as follows with reference to FIG.

In the turn-on state of the switching transistor T1, energy is accumulated in the inductor L, and in the turn-off state of the switching transistor T1, the accumulated energy is superimposed on the input voltage Vin to output a boost converter ( The output voltage Vo higher than the input voltage Vin can be obtained through 100.

The output voltage Vo of the boost converter 100 is divided by a voltage divider 210 to a predetermined voltage to form a stable input current according to an input voltage Vi and an output load variation. The output signal of the voltage divider 210 is compared with the reference voltage Vref of the error amplifier 220 to detect an error of the input voltage Vi and the output voltage Vo in proportion to the variation of the output voltage Vo. In order to output the error signal Ve.

The error signal Ve and the reverse sawtooth wave signal Vsw of the oscillator 262 are multiplied by the two signals through the multiplier 230 to obtain a constant gain to control the input current according to the change in the output voltage Vo. A reference voltage Vmo is generated.

In addition, when the switching transistor T1 is turned on, a current stored in the inductance flows to the current sensing unit 240 to generate a signal Vcs for forming an input current.

The output signal Vcs of the current sensing unit 240 is compared with the reference voltage Vmo through the comparator 250 so as to control the input current according to the variation of the output voltage Vo. Generates a control signal for resetting.

The flip-flop 272 is set by a clock signal Clock synchronized with the rising edge of the reverse sawtooth wave signal Vsw output from the oscillator 260, and the flip-flop 272 is synchronized with the clock signal. The flip-flop 272 is reset by a control signal.

Negative-OR gate 274 is generated only when the two signals are high by the clock signal Clock synchronized with the rising edge of the output signal of the flip-flop 272 and the reverse sawtooth wave signal Vsw outputting the oscillator 260. Generates a drive signal in a low state.

In response to the driving signal, the driving unit 276 turns off the switching transistor T1 at a low level, and turns on the switching transistor T1 at a high level.

Therefore, since the pulse width modulation is possible through the switching transistor T1 by the control signal of the comparator 250, the input current of the current sensing unit 240 may be controlled in the form of an input voltage.

FIG. 2 is a waveform diagram illustrating control voltages of a power factor correction circuit according to an embodiment of the present invention. Referring to FIG. 2, an instantaneous inductance current when the switching transistor T1 is turned off corresponds to a turn-on state of the switching transistor T1. The turn off state is the same.

only, The time when the switching transistor T1 is turned on, Vi is an input voltage, Vo is an output voltage of the boost converter 100, and T is a function of time.

Input voltage Ramen Denotes an input peak voltage, and the moment when the switching transistor T1 is turned off, an inverse sawtooth signal ( ) And the reference voltage of the multiplier 230 It is like the moment when it becomes equal to).

only, Is the output voltage of the current sensing unit 240, Is the reference voltage of the multiplier 230, Is the error voltage of the error amplifier 220, Denotes a gain voltage of the multiplier 230, and denotes a constant.

Substituting Equation 1 into Equation 2 above, Inducing the inductance (L) current contained in it is as follows.

In Equation 3, the inductance current as a function of time Input voltage Proportional and constant gain ( It can be seen that the magnitude of the input voltage is determined by) and has an in-phase.

3 is a waveform diagram of input currents having different magnitudes of gain GM according to the present invention. Since the magnitude of the gain GM is multiplied by the input voltage Vi, the waveform of the input current is naturally input. It does not deviate from the sinusoidal waveform of the voltage Vi.

If the input voltage (Vi) increases or the output load fluctuates little, the input current is controlled low, so it automatically takes the form of a control that combines the continuous current mode (CCM) and the discontinuous current mode (DCM).

Therefore, the present invention controls the input current in the form of the input voltage in the same concept as the operating characteristic of the average current control method, so that a high power factor close to the unit power factor can be obtained, and the circuit of the average current control method The complexity of the configuration can be solved.

In the present invention, the input current can be controlled with respect to a large change in the input voltage or the output load by using the reverse sawtooth signal, so that a high power factor close to the unit power factor can be obtained, and the circuit configuration is simple, so that the economic efficiency is high. The power factor correction circuit can be implemented.

Claims (1)

A circuit for compensating a power factor of a boost converter that accumulates a voltage in an inductor in a turn-on state of a switching transistor and superimposes and outputs a voltage accumulated in the inductor in a turn-off state with an input voltage. A voltage divider for distributing a predetermined voltage, an error amplifier for detecting an error signal proportional to a change in the output voltage by comparing the output signal of the voltage divider with a reference signal, and multiplying the output signal with the reverse sawtooth signal by the error amplifier A multiplier for obtaining a gain, a current sensing unit for sensing an input current corresponding to the turn-on current of the switching transistor, a comparison for determining the turn-off time of the switching transistor by comparing an output signal of the current sensing unit and an output signal of the multiplier unit Oscillation to generate negative clock signal and inverse sawtooth signal synchronized with the clock signal And a driving unit which turns on the switching transistor in response to a clock signal of the oscillator and turns off the switching transistor in response to an output signal of the comparator to determine a pulse period of the input current. Power factor correction circuit using sawtooth wave.