KR20000001444A - SINGLE PHASE ACTIVE RECTIFIER FOR power FACTOR CONTROL - Google Patents

Abstract

PURPOSE: A single phase active rectifier is provided to improve power factor and to simplify the circuit for reducing hardware size. CONSTITUTION: The single phase active rectifier comprises an inductor(L), a rectifying part(100), a capacitor(C0), a current detector(200), an input voltage detector(300), an output voltage detector(400) and a power factor controller(500). The rectifying part(100) rectifies input common power from the inductor(L) with improvement of power factor by switching. The capacitor(C0) performs a filtering the output voltage from the rectifying part(100), and applies the filtered voltage to a load. The current detector(200) detects current of the common power. The input voltage detector(300) detects voltage of the input common power. The output voltage detector(400) detects output voltage when the load operates. The power factor controller(500) generates a switching signal for power factor control according to the detected current, input and output voltages, and outputs the switching signal to the rectifying part(100).

Description

Single Phase Active Rectifier for Power Factor Control

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a single-phase active rectifier for power factor control for preventing the efficiency from dropping due to the loss of a switch generated by current flow through a plurality of semiconductor devices. It is possible to prevent the phenomenon of biased detection and to detect the correct voltage without ripple by receiving commercial power through the transformer, and to increase the switching frequency by reducing the loss by reducing the number of semiconductor elements through which current flows. The present invention relates to a single-phase active rectifier for power factor control, which can reduce the size of an inductor, increase efficiency, and reduce the size of an entire circuit.

As shown in FIG. 1, the power supply circuit having no power factor control function includes a rectifier 10 for rectifying an input commercial power and outputting the rectified pulse voltage, and a DC voltage output from the rectifier 10. It is composed of a filter capacitor (C) for filtering the supply to the load (12).

As shown in FIG. 3, the circuit configuration of the conventional power factor control boost converter includes a rectifying unit 10 for rectifying the input commercial power and outputting the rectified voltage of the rectified voltage, and outputting from the rectifying unit 10. Step-up converter section 11 for performing an operation for improving the power factor with respect to the voltage, and a filter capacitor (C) for filtering the voltage output from the step-up converter section 11 to supply to the load 12 ), A current detector 13 for detecting an input current, an input voltage detector 14 for detecting an input voltage, and an output voltage detector 15 for detecting an output voltage generated when the load 12 is operated. And a power factor controller 16 for outputting a switching signal for power factor control to the boost converter 11 using the current and voltage values detected by the detectors 13 to 15.

Looking at the prior art configured in this way in detail as follows.

First, referring to FIG. 1 and FIG. 2 for a power supply circuit without a power factor control function, the commercial power through the power supply stage and the commercial current as shown in FIG. I _AC ) Is supplied to the rectifier 10.

Then, the rectifier 10 rectifies the input commercial power using a bridge diode to make a DC voltage, and outputs the rectified DC voltage to the filter capacitor C.

At this time, the input current I _IN supplied to the filter capacitor C is as shown in FIG.

The filter capacitor C receiving the input current I _IN and the DC voltage as described above is filtered, and the filtered voltage, that is, the output voltage Vo as shown in FIG. ) To operate.

The power factor of a circuit operating as described above usually has a value between 0.4 and 0.7.

In addition, the harmonics component is too large to meet the international standard IEC 1000-3.

When the power factor is low, the effective power is also reduced, which reduces the power available in the home.

Therefore, a power factor control circuit is inserted to reduce power factor and harmonics.

If such a circuit is shown in FIG. 3, it will be described with reference to FIG. 3.

When supplying commercial power to the rectifier 10, the rectifier 10 rectifies the input voltage and outputs the rectified voltage (V _IN ) to the boost converter 11, the rectified voltage (V _IN ) is A voltage with twice the frequency of the input supply frequency (50/60 Hz) comes out.

When this voltage (V _IN ) is input and output to the boost converter 11, a current in phase with the input voltage (V _IN ) flows through the inductor (L). The in-phase sine wave current flows and the power factor is nearly 1.0.

At this time, the output voltage Vo that is filtered through the diode D and the filter capacitor C and supplied to the load 12 becomes a voltage larger than the peak value of the input voltage V _IN .

When the output voltage Vo is detected by the output voltage detector 15 and output to the power factor controller 16, the power factor controller 16 controls the output voltage to operate stably.

The power factor controller 16 controls the current of the inductor L to follow the input voltage V _IN , which is an input voltage detected by the input voltage detector 14 and an input current detected by the current detector 13. Control by using.

Since the switching element S1 operates at a high frequency of 20 KHz or more, the current of the inductor L serves as a current source during each switching.

When the switching element S1 of the boost converter 11 is turned on by the power factor controller 16 by the operation as described above, the inductor L receives the voltage V _IN rectified through the rectifier 10, The inductor current I _L rises linearly.

The reverse voltage is applied to the diode D so that the diode D is turned off, and the charged energy of the filter capacitor C is supplied to the load.

When the switching element S1 of the boost converter 11 is turned off by the power factor controller 16, the diode D is turned on so that the inductor L receives the (Vo-V _IN ) voltage and the inductor current I _L ) decreases linearly.

In this case, power is supplied from the input to the output to charge the filter capacitor (C) and supply energy to the load.

By repeating the above operation, the power factor is improved so that the inductor current I _L follows the shape of the input voltage.

However, in the prior art as described above, since the current always flows through three semiconductor elements (two diodes and a switch), the loss becomes large and thus the efficiency is considerably lowered. There was a problem of using a fan with a large amount of air flow, and the current detection unit simply detected current through the current detection element, which caused the input current to be biased to one side, and directly received commercial power to rectify the sensing resistance. When detected through the detection voltage is not the rectified form of the input power source, the output voltage including the ripple voltage is detected by the switching operation of the switch.

Therefore, the present invention has been created to solve the above-mentioned conventional problems, by resetting the residual magnetic flux remaining in the current detection element to prevent the current from being detected to one side, and receives the commercial power through the transformer Therefore, an object of the present invention is to provide a single-phase active rectifier for power factor control that detects an accurate voltage from which a ripple voltage has been removed and increases efficiency by reducing the number of semiconductor devices through which current flows.

1 is a power supply circuit diagram without a conventional power factor control.

2 is an operating waveform diagram of an output voltage and an input current of FIG. 1.

3 is a circuit diagram of a conventional power factor-type boost converter.

Figure 4 is a block diagram showing the configuration of a single-phase active rectifier for power factor control according to the present invention.

FIG. 5 is a circuit diagram illustrating a configuration of a current detector in FIG. 4. FIG.

FIG. 6 is a circuit diagram illustrating a configuration of an input voltage detector in FIG. 4. FIG.

*** Description of the symbols for the main parts of the drawings ***

100: single phase active rectifier 200: current detector

300: input voltage detector 400: output voltage detector

500: power factor controller L: inductor

S1, S2: Switch D _F1 , D _F2 : Diode

CT: current detection element VT: transformer

The configuration of the present invention for achieving the above object, and an inductor for power factor control; A single-phase active rectifier for rectifying the power factor by switching operation of the commercial power input through the inductor; A filter capacitor for filtering and supplying a voltage output from the single phase active rectifier to a load; A current detector for detecting a current of a commercial power supply input by the current detector; An input voltage detector for detecting a voltage of an input commercial power supply; An output voltage detector for detecting an output voltage generated during the load operation; It is achieved by configuring a power factor controller for outputting a switching signal for power factor control to the single-phase active rectifier by using the current and voltage values detected by the current and the input and output voltage detectors. When described in detail with reference to the drawings as follows.

Fig. 4 is a circuit diagram showing an embodiment of a single-phase active rectifier for power factor control of the present invention, and as shown therein, an inductor L for power factor control; A single-phase active rectifier 100 for rectifying the power factor by switching operation of the commercial power input through the inductor L; A filter capacitor C0 for filtering the voltage output from the single-phase active rectifier 100 and supplying it to the load 12; A current detector 200 which detects a current of a commercial power supply input by the current detector CT; An input voltage detector 300 detecting a voltage of an input commercial power supply; An output voltage detector 400 for detecting an output voltage generated when the load 12 is operated; The power factor controller 500 outputs a switching signal for power factor control to the single phase active rectifier 100 by using the current and voltage values detected by the current and the input and output voltage detectors 200 to 400.

The single-phase active rectifier 100 connects the diode D1 in series with a connection point of the first switching element S1 and the auxiliary diode D _F1 connected in parallel, and connects the output of the inductor L to a common connection point thereof. The diode D2 is connected in series to the connection point of the second switching element S2 and the auxiliary diode D _F2 connected in parallel, and the commercial power is input to the common connection point to supply the first switching element S1 and the diode D1. ) In parallel.

The current detection unit 200, as shown in Figure 5, the primary terminal is connected in series to the commercial power source, and detects the current to output the current by the turn ratio (CT); Two reset resistors RS1 and RS2 having one side applied with a power supply voltage VCC in common, and the other side connected in parallel with a secondary terminal of the current detection element CT to perform a reset operation; A rectifying unit (200a) for rectifying the current detected by the current detecting element (CT) and outputting the rectified current; The current output from the rectifier 200a is converted into a voltage and configured as a sensing resistor Rsen for supplying the power factor controller 500.

In addition, the input voltage detector 300 includes a transformer (VT) for receiving commercial power to the primary terminal, and outputs the voltage induced in the secondary terminal as shown in FIG. A rectifier 300a for rectifying the voltage output from the transformer VT; It is composed of a filter unit 300b for removing a noise component from the voltage output from the rectifying unit 300a and outputting a clean voltage. The operation and operation of the present invention configured as described above will be described.

In FIG. 4, when commercial power is supplied, it is rectified through the transformer VT of the input voltage detector 300 of FIG. 6, and the rectified DC voltage is output to the power factor controller 500.

In addition, the current detecting unit 200 of FIG. 5 detects the current flowing to the load side through the current detecting element CT and outputs it to the power factor controller 500, and removes the residual magnetic flux by the reset resistors RS1 and RS2. In addition, the output voltage detector 400 is supplied to the load 12 detects the output voltage generated during operation and outputs it to the power factor controller 500.

Accordingly, the power factor controller 500 outputs a control signal for switching the switching elements S1 and S2 of the single-phase active rectifier 100 using the current and the voltage supplied from each of the detectors 200 to 400.

Therefore, when the switch S1 is turned on when the input power is in a positive phase, a current path of S1-D _F2 -CT-AC Source is formed in the inductor L so that the input current rises linearly, and the switch S1 When is turned off, a current path of L-D1-C0-D _F2 -CT-AC Source is formed, and the inductor L is subjected to a voltage of (output voltage-input voltage) to generate a linearly decreasing current.

In addition, when the input power source is in a negative phase, the direction of the current flowing in the inductor L is reversed from the above, and the same in operation. That is, when the switch S2 is turned on, the inductor L has a current path of AC Source-CT-S2-D _F1 -L, and the input current rises linearly. When the switch S2 is turned off, the AC source is turned on. -The current path of CT-D2-C0-D _F1 -L is formed and the inductor L is subjected to a voltage of (output voltage-input voltage) so that a linearly decreasing current is generated.

When the above operation is performed at a frequency of several tens of KHz, the shape of the input current follows the shape of the input voltage, the current of the input voltage and the in-phase current flows, and the power factor approaches almost 1, and the harmonic current is reduced.

As described above, the single-phase active rectifier for power factor control according to the present invention resets the residual magnetic flux remaining in the current detecting element to prevent the current from being biased to one side and to remove the ripple by receiving the commercial power through the transformer. By detecting the voltage and reducing the number of semiconductor elements through which the current flows, the loss can be increased to increase the switching frequency, thereby reducing the size of the inductor, increasing efficiency, and reducing the overall circuit size. have.

Claims (4)

An inductor for power factor control; A single-phase active rectifier for rectifying the power factor by switching operation of the commercial power input through the inductor; A filter capacitor for filtering and supplying a voltage output from the single phase active rectifier to a load; A current detector for detecting a current of a commercial power supply input by the current detector; An input voltage detector for detecting a voltage of an input commercial power supply; An output voltage detector for detecting an output voltage generated during the load operation; And a power factor controller for outputting a switching signal for power factor control to the single phase active rectifier by using the current and voltage values detected by the current and the input and output voltage detectors. According to claim 1, wherein the single-phase active rectifier is connected in series with the diode D1 connected to the connection point of the first switching element and the auxiliary diode (D _F1 ) connected in parallel, the output of the inductor connected to the common connection point, ( ₂ ) The diode D2 is connected in series to the connection point of the switching element and the auxiliary diode D _F2 , and a commercial power source is input to the common connection point to connect the first switching element S1 and the diode D1 in parallel. Single phase active rectifier for power factor control. 2. The apparatus of claim 1, wherein the current detection unit comprises: a current detection element having a primary terminal connected in series to a commercial power source, for detecting a current and outputting a current by a turn ratio; Two reset resistors RS1 and RS2, one side of which is commonly applied with a power supply voltage VCC, and the other side of which is connected in parallel to a secondary terminal of the current detecting element to perform a reset operation; A rectifier for rectifying the current detected by the current detecting element and outputting the rectified current; A single-phase active rectifier for power factor control, characterized in that composed of a sensing resistor for converting the current output from the rectifier into a voltage to supply to the power factor controller. 2. The apparatus of claim 1, wherein the input voltage detector comprises: a transformer for receiving commercial power at a primary terminal and outputting a voltage induced at the secondary terminal; A rectifier for rectifying the voltage output from the transformer; Single-phase active rectifier for power factor control, characterized in that consisting of a filter for outputting a clean voltage by removing the noise component from the voltage output from the rectifier.