KR20030005786A - Snubber circuit - Google Patents

Abstract

PURPOSE: A snubber circuit is provided to reduce overshoot noise due to counter electromotive force generated from an inductor by using a damping capacitor. CONSTITUTION: A snubber circuit is formed with a damping portion(202), a comparison portion(204), and a counter electromotive force storage/feedback portion(206). The damping portion(202) generates snubber current for damping an increasing speed of DC voltage applied between both end portions of the first wire(N1) of a transformer(200). The damping portion(202) includes a damping capacitor(C21) and an inverse current retardation FET(Field Effect Transistor)(Q2). The damping capacitor(C21) is connected to the first wire(N1) of the transformer(200). The comparison portion(204) includes the first voltage divider(208), the second voltage divider(210), and an operation amplifier(212). The counter electromotive force storage/feedback portion(206) includes a photocoupler(214) and a switching portion(216).

Description

Snubber Circuits {SNUBBER CIRCUIT}

The present invention relates to a snubber circuit, and more particularly, to an energy accumulation time delay feedback snubber circuit which simultaneously performs an overshoot damping action and an energy accumulation action using a damping capacitor.

In general, a switching mode power supply circuit rectifies and filters a commercial AC voltage to obtain a DC voltage, converts the DC voltage into a high frequency square wave using a power semiconductor device in a switching mode, and then converts the voltage of the square wave to a constant voltage. By applying to a transformer having a turns ratio, there is a constant voltage method for rectifying, filtering, and converting a voltage waveform shown in the secondary, into a DC power source, and converting an AC current into a DC current through a constant current power supply.

1 shows a circuit diagram of a conventional DC-DC converter. Conventional DC-DC converters include an AC input 102, a rectifier 104, and a transformer 106.

The AC input unit 102 receives an AC voltage from the outside and applies it to the rectifier 104. The rectifier 104 rectifies the AC voltage applied from the AC input unit 102 into a DC voltage, and outputs the DC voltage to the primary coil 108 of the transformer 106. The transformer 106 receives a DC voltage from the rectifier 104 and is switched in accordance with a control signal applied from a switching transistor to be predetermined in the secondary coil 110 having a turns ratio different from that of the primary coil 108. Induce voltage.

According to the conventional DC-DC converter, excessive loss occurs due to overshoot noise due to back EMF generated when the switching transistor is turned off.

Accordingly, an object of the present invention is to provide a snubber circuit capable of reducing overshoot noise caused by back EMF generated in a general inductor device by using a damping capacitor.

In order to achieve the above object, the present invention includes a damping unit for generating a snubber current to damp the increase rate of the DC voltage across the first winding of the transformer; A comparator for comparing a DC voltage across the first winding of the transformer with an input DC voltage and outputting a comparison result signal; The counter electromotive force corresponding to the difference between the DC voltage across the first winding of the transformer and the input DC voltage is stored in the damping unit according to the comparison result signal from the comparing unit, and the counter electromotive force accumulated in the damping unit Provided is a snubber circuit comprising a back EMF energy accumulation / feedback for feeding back energy to a power capacitor.

A damping capacitor having one end connected to a first winding of the transformer; And a reverse current prevention field effect transistor connected between the first winding of the transformer and the damping capacitor to prevent a snubber current flowing from the first winding of the transformer to the damping capacitor in a reverse direction. The comparator comprises: a first voltage divider having a pair of first resistors connected in parallel to each other and distributing the input DC voltage to output a first divided voltage; A second voltage divider having a pair of second resistors connected in parallel and distributing a DC voltage across the first winding of the transformer to output a second divided voltage; And an operational amplifier for comparing the second divided voltage from the second voltage divider with the second divided voltage from the first voltage divider. The back EMF energy accumulation / feedback unit may switch a photo coupler for switching an output current in response to the comparison result signal from the comparator and the back EMF energy accumulated in the damping unit in response to the output current from the photo coupler as a power capacitor. Most preferably, it includes a switching unit for switching the feedback current for feeding back.

1 is a circuit diagram of a conventional DC-DC converter.

2 is a circuit diagram illustrating a snubber circuit according to an exemplary embodiment of the present invention.

FIG. 3 is a timing diagram for describing an operation of the snubber circuit shown in FIG. 2.

<Description of the code | symbol about the principal part of drawing>

200: transformer 202: damping unit

206: comparison unit 206: back EMF energy accumulation / feedback unit

208, 210: voltage divider 212: operational amplifier

214: photo coupler C1: power capacitor

C21: damping capacitor DZ21: Zener diode

PD1: photodiode PT1: phototransistor

Q2, Q3: field effect transistors R21, R22, R23, R24: resistors

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

2 is a circuit diagram illustrating a snubber circuit according to an embodiment of the present invention. The snubber circuit includes a damping unit 202, a comparator 204, and a back EMF accumulation / feedback unit 206. Damping unit 202 generates a snubber current I _snubber to a first damping rate of increase in the DC voltage across the winding (N1) of said transformer (200).

The damping unit 202 includes a damping capacitor C21 and a reverse current prevention field effect transistor Q2. One end of the damping capacitor C21 is connected to the first winding N1 of the transformer 200. The reverse current prevention field effect transistor Q2 is connected between the first winding N1 of the transformer 200 and the damping capacitor C21 and is connected to the damping capacitor from the first winding N1 of the transformer 200. Snubber current I flowing to C21) Prevents the _snubber from flowing in the opposite direction.

The comparator 204 compares the DC voltage across the first winding N1 of the transformer 200 with the input DC voltage and outputs a comparison result signal CR. The comparator 204 includes a first voltage divider 208, a second voltage divider 210, and an operational amplifier 212. The first voltage divider 208 is a pair of first resistors connected in parallel with each other. (R21, R22) to divide the input DC voltage to output a first divided voltage. According to an embodiment of the present invention, the resistances of the first resistors R21 and R22 are preferably 100 kΩ and 1 kΩ, respectively. The second voltage divider 210 has a pair of second resistors R23 and R24 connected in parallel to each other and distributes a DC voltage across both ends of the first winding N1 of the transformer 200 to divide the second divided voltage. Output Preferably, the resistances of the second resistors R23 and R24 are 50 kΩ and 1 kΩ, respectively. An operational amplifier 212 compares the second divided voltage from the second voltage divider 208 with the second divided voltage from the first voltage divider 208. Reference number R _p is a pull-up resistor.

The counter electromotive force energy accumulation / feedback unit 206 is connected to the difference between the DC voltage across the first winding N1 of the transformer 200 and the input DC voltage according to the comparison result signal from the comparison unit 202. The counter electromotive force energy is accumulated in the damping unit 202, and the back electromotive force energy stored in the damping unit 202 is fed back to the power capacitor C1. The back EMF energy accumulation / feedback unit 206 includes a port coupler 214 and a switching unit 216.

The port coupler 214 switches the output current in response to the comparison result signal from the comparator 204. The photo coupler 214 includes a photodiode PD1 and a photo transistor PT1. The photodiode PD1 outputs a light emission signal according to the comparison result signal from the comparison unit 204. The anode of the photodiode PD1 is connected to a power source and the cathode is connected to the output of the comparator 204. The photo transistor PT1 switches the output current according to the light emission signal from the photodiode PD1. An emitter of a photo transistor PT1 is connected to the switching unit 216, a base receives the light emission signal from the photodiode PD1, and a collector is connected to the power capacitor C1. The switching unit 216 switches the feedback current I _feedback for feeding back electromotive force energy accumulated in the damping unit 202 to the power capacitor C1 in response to the output current from the port coupler 214. . The switching unit 206 includes a field effect transistor Q3 and a zener diode DZ21. The source terminal of the field effect transistor Q3 is connected to one end of the first winding N1 of the transformer 200 and the common contact of the photo coupler 214, and the drain terminal is connected to the power capacitor C1 and the transformer ( It is connected to the common contact of the other end of the first winding N1 of 200, and the gate terminal is connected to the common contact of the power capacitor C1 and the photo coupler 214. Zener diode DZ21 supplies a predetermined constant voltage to the photo coupler 214 to generate a DC voltage across the first winding N1 of the transformer 200 to generate a gate voltage of the field effect transistor Q3. to provide. The cathode terminal of the Zener diode DZ21 is connected to the common contact of the power capacitor C1 and the source terminal of the field effect transistor Q3, and the anode terminal of the drain terminal of the field effect transistor Q3 and the photo coupler ( 214 is connected to the common contact of the first winding N1 of the transformer 200.

FIG. 3 is a timing diagram for describing an operation of the snubber circuit shown in FIG. 2. As shown in FIG. 3A, ST is applied to the gate terminal of the switching transistor Q1 as a signal for controlling the operation of the switching transistor Q1. As shown in FIG. 3B, I _D is a current flowing in the first winding N1 of the transformer 200. As shown in FIG. 3C, V _DC is an input DC voltage, V _SS is a voltage applied to an input inverting terminal of the operational amplifier 212, Is the voltage across the first winding N2 of the transformer 200, and V _DS is the voltage generated by the voltage across the second winding N2 of the transformer 200 to the DC voltage V _DC ( ) By adding ) Is a voltage across the first winding N1 of the transformer 200 and has the same value as the voltage between the drain and source of the switching transistor Q1.

Hereinafter, the operation of the snubber circuit according to the embodiment of the present invention will be described with reference to FIGS. 2 and 3.

When the switching transistor Q1 is switched from the switched-on state to the switched-off state by the low level control signal ST at time t2, the current I _D flowing through the first winding N1 of the transformer 200 decreases rapidly and switches. The voltage V _DS between the drain and source of the transistor Q1 is increased. Where V _DS is ( ), But overshoot occurs because of back EMF. When the voltage V _DS exceeds the sense voltage V _SS at time t3, a loop of the anti-current field effect transistor Q2 and the damping capacitor C21 of the damping unit 202 is formed so that the damping unit 202 is connected to the voltage V _DS. in order for the damping to increase the speed and generates a snubber current I _snubber. The comparator 204 compares the DC voltage across the first winding N1 of the transformer 200 with the input DC voltage and outputs a comparison result signal CR. At time t4, the counter electromotive force energy accumulation / feedback unit 206 is connected to the DC voltage across the first winding N1 of the transformer 200 and the input DC voltage according to the comparison result signal from the comparison unit 202. The counter electromotive force energy corresponding to the difference is stored in the damping capacitor C21. Even during the next cycle resonant overshoot (secondary back EMF) at time t5, the overshoot is cut off and abruptly decreases. That is, the energy at the time of cutting off the overshoot is accumulated in the power supply capacitor C1 without loss.

After a predetermined time delay, when the switching transistor Q1 is switched from the switched-off state to the switched-on state by the high level control signal ST at time t6, the drain-source voltage V _DS of the switching transistor Q1 reaches 0 volts. Decreases. When the voltage V _DS passes the sensing voltage V _SS at time t7, the comparison result signal of the comparator 202 is at the low level and the gate terminal of the field effect transistor Q3 is at the high level, and thus the field effect transistor Q3. ) Is switched on to form a damping capacitor C21 and a field effect transistor Q3 loop. Accordingly, the back EMF energy accumulated in the damping capacitor C21 is fed back to the source power source C1 to reduce the back EMF overshoot noise without loss.

As described above, according to the present invention, the overshoot damping action and the energy accumulation action are simultaneously performed by using a damping capacitor at the time of generating the counter electromotive force in order to reduce the overshoot noise caused by the counter electromotive force generated in the general inductor element, and delay time for a certain period of time. If the overshoot disappears later, losses can be minimized by feeding back the energy accumulated in the damping capacitor to the supply capacitor.

While the invention has been shown and described with respect to certain preferred embodiments thereof, the invention is not limited to the embodiments described above, but in the field to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Any person with ordinary knowledge will be able to make various modifications.

Claims (6)

A damping unit for generating a snubber current to damp the increase rate of the DC voltage across the first winding of the transformer; A comparator for comparing a DC voltage across the first winding of the transformer with an input DC voltage and outputting a comparison result signal; The counter electromotive force corresponding to the difference between the DC voltage across the first winding of the transformer and the input DC voltage is stored in the damping unit according to the comparison result signal from the comparing unit, and the counter electromotive force accumulated in the damping unit A snubber circuit comprising back EMF energy accumulation / feedback for feeding back energy to a power capacitor. The damper of claim 1, wherein the damping unit comprises: a damping capacitor having one end connected to a first winding of the transformer; And a reverse current prevention field effect transistor connected between the first winding of the transformer and the damping capacitor to prevent a snubber current flowing from the first winding of the transformer to the damping capacitor in a reverse direction. Snubber circuit. 2. The apparatus of claim 1, wherein the comparing unit comprises: a first voltage divider having a pair of first resistors connected in parallel to each other to divide the input DC voltage to output a first divided voltage; A second voltage divider having a pair of mutually connected second resistors and distributing a DC voltage across the first winding of the transformer to output a second divided voltage; And an operational amplifier for comparing the second divided voltage from the second voltage divider with the second divided voltage from the first voltage divider. The photocoupler of claim 1, wherein the back EMF energy accumulation / feedback unit is configured to store an output current in response to the comparison result signal from the comparison unit, and to accumulate in the damping unit in response to the output current from the photo coupler. A snubber circuit comprising a switching unit for switching a feedback current for feeding back electromotive force energy to a power capacitor. The photodiode of claim 4, wherein the photo coupler includes an anode connected to a power supply and a cathode connected to an output terminal of the comparator, and outputs a light emitting signal according to the comparison result signal from the comparator. And a photo transistor having a collector connected to the power supply capacitor and switching the output current according to the light emission signal from the photo diode received through the base. The switching terminal of claim 4, wherein the source terminal is connected to a common contact of one end of the first winding of the transformer and the photo coupler, and the drain terminal of the switching terminal is connected to the common contact of the power capacitor and the other end of the first winding of the transformer. A field effect transistor connected with the gate terminal connected to a common contact of the power capacitor and the photo coupler; And A cathode terminal is connected to a common contact of a power supply capacitor and a source terminal of the field effect transistor, an anode terminal is connected to a common contact of the drain terminal of the field effect transistor and the first winding of the transformer through the photocoupler, And a zener diode for providing a predetermined constant voltage to the photo coupler for generating a DC voltage across the first winding of the transformer to generate a gate voltage of the field effect transistor.