KR20140096948A - Single Power Stage Power Factor Correction Circuit - Google Patents

Abstract

A power factor enhancement circuit for a single power stage given in the present invention includes a power unit which rectifies AC power in full wave and provides input voltage; a voltage distribution unit which is connected to the output of the power unit, receives the input voltage, and generates a distributed voltage; a power factor enhancement converter unit which is connected to the output of the power unit, receives the input voltage, and accumulates energy or provides charging current by delivering the accumulated energy according to the on/off operation; an output filter unit which is connected to the output of the power factor enhancement converter unit, receives the charging current, removes ripple components, and provides output voltage; a light emitting unit which receives output current corresponding to the output voltage and emits light; and a control unit which is connected to the voltage distribution unit, power factor enhancement converter unit, and light emitting unit, generates a control signal to control the on/off operation of the power factor enhancement converter unit, and controls the power factor enhancement converter unit.

Description

{Single Power Stage Power Factor Correction Circuit}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power factor improving circuit, and more particularly, to a single power factor correction circuit applied to an illumination power source device using a light emitting diode.

A light emitting diode (LED) is a semiconductor device that generates light by flowing a current in a forward direction to a PN junction. The light emitting diode has been attracting attention as a next generation illumination device because it has high efficiency of converting electric energy into light energy, has a long lifetime, low power consumption, and can greatly reduce maintenance and repair cost.

Since such a light emitting diode is generally driven by a direct current, unlike a conventional lighting, a converter for converting an alternating current into a direct current is required for a lighting power source apparatus using a light emitting diode. Since the converter is connected to a commercial power supply, an electrical isolation circuit between a commercial power supply and a load and a power factor improving circuit for maximizing energy efficiency are indispensably required.

In particular, a flyback converter can be easily changed in output voltage by using a transformer, and can electrically isolate a commercial power supply and a load, thereby being widely used in an illumination power supply apparatus using a light emitting diode. In addition, a single power factor improvement method is often used for power factor improvement in an illumination power supply device using a light emitting diode.

Conventional single power factor improvement flyback converters use capacitors at the output stage to remove the ripple components contained in the output voltage. Large capacity electrolytic capacitors are used for such output stage capacitors. However, the electrolytic capacitor has a very short life span as that of the light emitting diode, which hinders long life, which is a great advantage of light using a light emitting diode.

In addition, the single power factor improvement flyback converter uses a small capacity capacitor in the output stage capacitor, and the capacity of the capacitor is insufficient, so that the output voltage includes a ripple component, especially a frequency corresponding to twice the commercial power supply frequency, . Such a ripple component is included in the output current, which causes a flicker phenomenon in the light emitting diode.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art. That is, it is an object of the present invention to provide a single power factor improvement circuit capable of realizing a large-capacity electrolytic capacitor having a short life at the output end with a film capacitor having a very long life. In addition, one of the objects of the present invention is to provide a single power factor correction circuit capable of eliminating ripple components generated by using a small-capacity capacitor.

A single power factor correction circuit according to the present invention includes a power unit for full-wave rectification of an AC power source to provide an input voltage, a voltage distribution unit connected to an output of the power source unit and generating a distribution voltage by receiving the input voltage, A power factor improving converter unit connected to the output of the power factor improving converter unit and provided with the input voltage and storing energy according to on / off operation or providing charge current through transfer of the accumulated energy, An output filter unit for receiving the charging current to remove the ripple component to provide an output voltage, a light emitting unit for receiving an output current corresponding to the output voltage to perform a light emitting operation, And a control unit coupled to the light emitting unit to generate a control signal for controlling on / off operation of the power factor improving converter unit, And a control section for controlling line converter unit.

In one embodiment, the output filter section includes an output smoothing capacitor and an LC filter connected in parallel with the output smoothing capacitor, the output filter inductor and the output filter capacitor being cascaded.

In one embodiment, the capacitance of the output filter inductor and the output filter capacitor is calculated such that the resonant frequency based on the transfer function of the output voltage for the charge current is the frequency of the ripple component to be removed.

In one embodiment, the frequency of the ripple component is twice the frequency of the AC power source.

In one embodiment, the power factor improving converter unit includes a switching unit for performing an on / off operation in accordance with the control signal, an energy storage unit for storing energy or providing the stored energy according to the on / off operation of the switching unit, A transformer connected to the secondary winding of the transformer, for controlling a path of the accumulated energy to provide a charging current, and a secondary winding connected between the primary winding and the secondary winding, And a sensing resistor connected between the switching unit and the first ground.

In one embodiment, the controller is configured to control the power factor improving converter to operate in one of a current conduction mode (BCM), a current continuous mode (CCM), and a current discontinuous conduction mode (DCM) .

According to the embodiment of the present invention, the life of the lighting using the light emitting diode is extended by realizing the film capacitor having a very long lifetime in the output stage capacitor. According to an embodiment of the present invention, an LC filter having an output filter inductor and an output filter capacitor connected in series to an output terminal is used to convert a ripple component included in an output voltage, in particular, a frequency corresponding to twice the commercial power supply frequency The flicker phenomenon generated in the light emitting diode can be remarkably reduced. The LC filter may be used not only for a single power factor improvement converter operating in a boundary conduction mode (BCM), a continuous conduction mode (CCM), or a discontinuous conduction mode (DCM) It is possible to apply the present invention to any circuit requiring removal of the ripple component.

However, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a circuit diagram showing a single power factor correction circuit according to an embodiment of the present invention.
FIG. 2 is a graph showing the partial current and voltage characteristics of a single power factor improvement circuit according to an embodiment of the present invention, which is composed of an output smoothing capacitor Co and an LC filter 410 at an output end.
3 is a graph showing current and voltage characteristics of each of the conventional single power factor improvement circuits including only the output smoothing capacitor Co at the output end.

The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Hereinafter, a single power factor correction circuit according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a circuit diagram showing a single power factor correction circuit according to an embodiment of the present invention.

Referring to FIG. 1, a single power factor circuit according to an embodiment of the present invention includes a power supply 100, a voltage divider 200, a power factor improving converter 300, an output filter 400, 500 and a control unit 600.

The power supply unit 100 performs full-wave rectification of the AC power supply Vs to provide an input voltage Vin. The power supply unit 100 may include an AC power source Vs, an input filter unit 110, a full wave rectification unit 120, and an input smoothing capacitor Cin.

The AC power source (Vs) may be a general household power source having an RMS value of 220 V and a frequency of 60 Hz, and may be a power source having a predetermined period and pulsating in a different phase.

The input filter unit 110 may be connected to the output of the AC power source Vs. Specifically, the input filter unit 110 may be connected between the AC power source Vs and a full-wave rectification unit 120 to be described later. The input filter 110 receives the AC power Vs and removes a noise component included in the AC power Vs. As shown in FIG. 1, the input filter unit 110 may be an LC filter including an input filter inductor L1 and an input filter capacitor C1.

The full-wave rectification unit 120 may be connected to the output of the input filter unit 110. The full-wave rectification part 120 receives the AC power Vs supplied through the input filter part 110, performs full wave rectification, and provides a full-wave rectified DC power. The full-wave rectification section 120 may use any rectifier or rectification circuit as long as it is capable of full-wave rectification of the AC power source (Vs). In one example, the full-wave rectification section 120 may use a diode rectifier. The diode rectifier may be a bridge rectifier as shown in the figure, but may be a rectifier using a center tapped transformer. In another example, full wave rectifier 120 may use a controlled rectifier. The control rectifier may be a thyristor, such as a silicon controlled rectifier.

The input smoothing capacitor (Cin) may be connected to the output of the full wave rectifier (120). The input smoothing capacitor Cin receives and smoothes the direct current power of the full wave rectifying unit 120 and provides the input voltage Vin which is a smoothed direct current power.

The voltage divider 200 may be connected to the output of the power supply 100. Specifically, the voltage distribution unit 200 may be connected between the power supply unit 100 and a power factor improving converter unit 300 described later. The voltage distribution unit 200 receives the input voltage Vin provided from the power supply unit 100 and generates the distribution voltage Vr by distributing the supplied input voltage Vin. The generated distribution voltage Vr is provided to the control unit 600 to be described later.

The voltage divider 200 includes a first distribution resistor R1 and a second distribution resistor R2 and the first distribution resistor R1 and the second distribution resistor R2 can be connected in series. have. One end of the first distribution resistor R1 is connected to the first node and one end of the second distribution resistor R2 is connected to the first ground GND1 and the first distribution resistor R1 and the second distribution The other ends of the resistor R2 are connected to each other. Accordingly, the voltage divider 200 can generate the divided voltage Vr from the center points of the first distribution resistor R1 and the second distribution resistor R2.

The power factor improving converter unit 300 may be connected to the output of the power source unit 100. The power factor improving converter 300 receives the input voltage Vin provided from the power supply unit 100 and accumulates energy according to the on / off operation or provides the charging current Ic through transfer of the accumulated energy . The power factor improving converter unit 300 may include a switching unit 320, a transformer 310, a control diode D, and a sensing resistor R3.

The switching unit 320 may be connected between a transformer 310 and a sensing resistor R3, which will be described later. The switching unit 320 receives a control signal Vcon provided from the controller 600 and performs an on / off operation according to the control signal Vcon. The switching unit 320 may be any device as long as it can perform the on / off operation according to the control signal Vcon of the controller 600. In one example, the switching unit 320 may use an NMOS transistor Q. In another example, the switching unit 320 may include a plurality of NMOS transistors Q connected in series. The control signal Vcon may be commonly applied to the gate terminals of the NMOS transistors Q connected in series.

The transformer 310 is connected to the switching unit 320 and accumulates energy or provides the stored energy in accordance with the on / off operation of the switching unit 320. In one example, the transformer 310 may be a high frequency transformer. The transformer 310 may also include a primary winding 312 connected between the first node and the switching unit 320 and a secondary winding 314 coupled to the primary winding 312.

The control diode (D) may be connected to the output of the transformer (310). Specifically, the control diode D is connected to the secondary winding 314 of the transformer to control the path of accumulated energy provided by the transformer 310 to provide the charging current Ic.

The sensing resistor R3 may be connected between the switching unit 320 and the first ground GND1. In particular, the sensing voltage Vq sensed between the switching unit 320 and the sensing resistor R3 is provided to the controller 600. [

1, one end of the transformer primary winding 312 is connected to the first node in the direction of the black point, and the other end of the transformer primary winding 312 is connected to the first node. And is connected to the drain of the NMOS transistor (Q). In addition, the gate of the NMOS transistor Q is connected to the control unit 600, and the source is connected to the first ground GND1 through the sense resistor. One end of the transformer secondary winding 314 is connected to the anode of the control diode D and the other end of the transformer secondary winding 314 is connected to the second ground GND2 in the direction of the black point.

When the NMOS transistor Q is turned on by the control signal Vcon provided from the control unit 600, the input current Iin corresponding to the input voltage Vin flows through the primary winding 312 of the transformer. At this time, a voltage is induced in the transformer primary winding 312 in accordance with the input current Iin, and a reverse bias is induced in the secondary winding 314 of the transformer by the direction of the black point. Therefore, energy is accumulated only in the primary winding 312 of the transformer. When the NMOS transistor Q is turned off by the control signal Vcon provided from the controller 600, a voltage of the opposite polarity to the previous state is induced in the secondary winding 314 of the transformer, Turn on. Thus, the accumulated energy provides the charging current Ic through the control diodes D.

The charge current Ic may include a ripple component of an AC component that shortens the lifetime of the light emitting portion 500 and causes a flicker phenomenon. The ripple component may be a low frequency ripple component. The low frequency ripple component may be twice the frequency of the alternating current power supply (Vs). In one example, if the alternating current power supply (Vs) frequency is 60 Hz, the low frequency ripple component may be 120 Hz. Accordingly, the output filter unit 400 may be included to remove the ripple component included in the charge current Ic.

1, the output filter unit 400 may be connected to the output of the power factor improving converter unit 300. The output filter unit 400 receives the charge current Ic provided by the power factor improving converter unit 300 and removes the ripple component of the supplied charge current Ic to generate an output voltage Vo, And provides the output voltage Vo to the light emitting unit 500 to be described later.

The output filter unit 400 includes an output smoothing capacitor Co and an LC filter 410. The output smoothing capacitor Co and the LC filter 410 may be connected in parallel. The LC filter 410 may include an output filter inductor L2 and an output filter capacitor C2 and the output filter inductor L2 and the output filter capacitor C2 may be connected in series.

The capacitances of the output filter inductor L2 and the output filter capacitor C2 can be calculated so that the resonance frequency based on the transfer function of the output voltage Vo with respect to the charge current Ic becomes the frequency of the ripple component to be removed have.

That is, the transfer function of the output voltage Vo with respect to the charge current Ic in the output filter unit 400 is expressed by the following equation (1). In particular, the charging current Ic and the output voltage Vo may be an average value.

The resonance frequency based on the formula (1) is given by the following equation (2).

The capacitance of the output filter inductor L2 and the capacitance of the output filter capacitor C2 can be calculated so that the resonance frequency of Equation (2) becomes the frequency of the ripple component to be removed. That is, if the AC power source Vs is 60 Hz and the ripple component to be removed is 120 Hz which is twice the AC power source Vs, the following equation (3) can be obtained.

Therefore, by designing the LC filter 410 using the output filter inductor L2 and the output filter capacitor C2 having the capacity calculated by Equation 3, the output filter unit 400 is included in the charge current Ic The 120Hz ripple component can be removed.

The light emitting unit 500 may be connected to the output of the output filter unit 400. The light emitting unit 500 receives the output current Io corresponding to the output voltage Vo from the output filter unit 400 and performs the light emitting operation. Further, the light emitting portion 500 has at least one light emitting diode.

The control unit 600 may be connected to the voltage distributor 200, the power factor improving converter 300, and the light emitting unit 500. The control unit 600 generates a control signal Vcon for controlling the on / off operation of the power factor improving converter unit 300 and provides the generated control signal Vcon to the power factor improving converter unit 300, And controls the power factor improving converter unit 300 according to the control signal Vcon.

The controller 600 may control the power factor improving converter 300 such that the power factor improving converter 300 operates in either one of a boundary conduction mode (BCM), a continuous conduction mode (CCM), and a discontinuous conduction mode (DCM) An operation can be performed in one mode. That is, the current boundary mode means that the switching unit 320 of the power factor improving converter unit 300 performs ON or OFF operation when the charging current Ic becomes zero. The current continuous mode means that the switching unit 320 of the power factor improving converter unit 300 is turned on or off before the charging current Ic becomes zero. The current discontinuity mode means that the switching unit 320 of the power factor improving converter unit 300 performs the ON or OFF operation after the charging current Ic becomes zero.

The controller 600 may include a power factor controller 610, an optocoupler 620, and a current controller 630. The power factor controller 610 may include any one of a BCM controller that operates the power factor improving converter unit 300 in the current boundary mode, a CCM controller that operates in the current continuous mode, and a DCM controller that operates in the current discontinuous mode.

The power factor controller 610 controls the power of the light emitting unit 500 and the sensing voltage Vq sensed between the switching unit 320 and the sensing resistor R3 and the distribution voltage Vr generated in the voltage distributor 200. [ And receives the feedback voltage Vfb generated through the current controller 630 and the optocoupler 620. [ The power factor controller 610 generates the control signal Vcon provided to the switching unit 320 of the power factor improving converter unit 300 using the supplied voltages.

FIG. 2 is a graph showing the partial current and voltage characteristics of a single power factor improvement circuit according to an embodiment of the present invention, which is composed of an output smoothing capacitor Co and an LC filter 410 at an output end.

3 is a graph showing current and voltage characteristics of each of the conventional single power factor improvement circuits including only the output smoothing capacitor Co at the output end.

2 and 3, Vs is an input AC power source, and Is is a current corresponding to the AC power source Vs. In particular, the AC power supply Vs has a commercial power supply voltage of 220 V and 60 Hz. Vo is the output voltage provided to the light emitting portion 500 and Io is the output current Io provided to the light emitting portion 500. [

As shown in FIG. 3, it can be seen that the output voltage Vo is stable only when the conventional single power factor correction circuit uses 1000 as the output smoothing capacitor Co. Also, in the conventional structure, the ripple component, in particular, the ripple component of 120 Hz appears in the output current Io although the output voltage Vo is stable. As shown in FIG. 2, the single power factor correction circuit according to an embodiment of the present invention uses a 100 as the output smoothing capacitor Co, but the output voltage Vo is more stable than the conventional structure . In addition, it can be seen that the structure according to an embodiment of the present invention removes the ripple component, especially 120 Hz ripple component, in the output current Io by using the LC filter 410 (L2 = 8 mH, C2 = 100) . Although the above-described characteristics are obtained by using a single power factor correction circuit operating in a current boundary mode, the single power factor correction circuit according to an embodiment of the present invention can be used in a current continuous mode or a current discontinuous mode .

Therefore, the present invention can be realized as a film capacitor having a very long lifetime in the output stage capacitor Co rather than a structure in which a large-capacity electrolytic capacitor is disposed in the output stage capacitor Co in order to remove the ripple component of the output voltage Vo. The illumination according to the embodiment provides the effect that the life span is further extended. The ripple component included in the output voltage Vo, in particular, the ripple component contained in the output voltage Vo, which is twice the frequency of the AC power supply (Vs), is obtained by using the LC filter 410 in which the output filter inductor L2 and the output filter capacitor C2 are connected in series, The flicker phenomenon occurring in the light emitting diode can be remarkably reduced. The LC filter 410 may be a single power factor improvement converter operating in a boundary conduction mode (BCM), a continuous conduction mode (CCM), or a discontinuous conduction mode (DCM) There is provided an effect that it is applicable not only to any circuit requiring removal of the ripple component.

100: power supply unit 110: input filter unit
120: Full wave rectification part 200: Voltage distribution part
300: Power Factor Correction Converter Unit 310: Transformer
312: transformer primary winding 314: transformer secondary winding
320: switching unit 400: output filter unit
410: LC filter 500:
600: controller 610: power factor controller
620: Optocoupler 630: Current controller

Claims (6)

A power supply for full-wave rectification of an AC power source to provide an input voltage;
A voltage distributor connected to an output of the power supply unit and generating a distribution voltage by receiving the input voltage;
A power factor improving converter connected to the output of the power unit and storing energy according to the on / off operation of the input voltage, or providing a charging current through transfer of the stored energy;
An output filter connected to an output of the power factor improving converter to receive the charge current to remove a ripple component to provide an output voltage;
A light emitting unit provided with an output current corresponding to the output voltage and performing a light emitting operation; And
And a control unit connected to the voltage distribution unit, the power factor improving converter unit, and the light emitting unit to generate a control signal for controlling the on / off operation of the power factor improving converter unit to control the power factor improving converter unit, As a remedy. The apparatus as claimed in claim 1,
Output smoothing capacitor; And
And an LC filter connected in parallel with the output smoothing capacitor and having an output filter inductor and an output filter capacitor connected in series. 3. The method of claim 2,
Wherein the capacitances of the output filter inductor and the output filter capacitor are calculated so that the resonant frequency based on the transfer function of the output voltage with respect to the charge current becomes the frequency of the ripple component to be removed. The method according to claim 1,
Wherein the frequency of the ripple component is twice the frequency of the AC power supply. The power factor improving converter according to claim 1,
A switching unit for performing an on / off operation according to the control signal;
A first winding connected between the first node and the switching unit, and a secondary winding coupled to the primary winding, wherein the first winding and the second winding are connected to each other, Transformers;
A control diode coupled to the secondary winding of the transformer and controlling the path of the stored energy to provide a charging current; And
And a sensing resistor connected between the switching unit and the first ground. The method according to claim 1,
The controller may operate the power factor improving converter to operate in one of a boundary conduction mode (BCM), a continuous conduction mode (CCM), and a discontinuous conduction mode (DCM) Single power stage power factor improvement circuit.

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