KR20070028817A - Feedback terminal circuit - Google Patents

Abstract

A feedback terminal circuit is provided to improve efficiency of an output voltage by not breaking a power supply for an instantaneous surge current when a load is applied to an output terminal. A feedback terminal circuit includes a feedback voltage control unit(310), a feedback voltage rising delay unit(320), and an IC(Integrated Circuit)(330). The feedback voltage control unit(310) detects a voltage which is fed back from a second side to a first side of a transformer, and controls the detected feedback voltage. The feedback voltage control unit(310) raises a feedback voltage when a surge current flows on the second side of the transformer. The feedback voltage rising delay unit(320) delays rising time of the outputted feedback voltage when the feedback voltage outputted from the feedback voltage control unit(310) is raised by a flow of the surge current on the second side. The IC(330) controls a switching operation of a transistor by comparing a driving voltage of the IC(330) and the feedback voltage raised through the feedback voltage control unit(310) and the feedback voltage rising delay unit(320).

Description

Feedback terminal circuit {FEEDBACK TERMINAL CIRCUIT}

1 is a circuit diagram of a feedback terminal circuit according to the prior art.

2 is a graph showing waveforms of output current and output voltage generated when a load is applied when using the related art.

3 is a circuit diagram of a feedback terminal circuit according to the present invention;

Figure 4 is a graph showing the waveform of the output current and output voltage generated when the load is applied when using the present invention

<Description of Major Symbols in Drawing>

300: feedback terminal circuit 310: feedback voltage control unit

311: photo coupler 312: feedback voltage riser

312a: first resistor 312b: first capacitor

320: feedback voltage rise delay unit 321: switch

322: second capacitor 323: second resistor

330: IC V _fb : feedback voltage

Isur: Surge Current

The present invention relates to a feedback terminal circuit, which can delay the rise time of the feedback voltage with only a small number of elements without a separate time delay circuit, so that the circuit can be designed even at a low manufacturing cost, and the rise time of the feedback voltage can be reduced. The present invention relates to a feedback terminal circuit capable of increasing the efficiency of the output voltage by not interrupting the power supply with respect to the instantaneous surge current generated when the load is applied to the output terminal according to the delay.

In general, the SMPS (Switching Mode Power Supply) power circuit of the PWM (Pulse Width Modulation) control method has been widely used because it is easy to obtain a desired voltage and easy to control the power.

However, there is a need for a method for protecting the power supply circuit from such a situation since a secondary power supply may be shorted or a surge current flows due to external causes, resulting in damage to the circuit.

The most basic circuit protection method is to cut off the power supply by opening a fuse or electronic fuse when the secondary power is shorted or an abnormal surge current flows. However, the above method is inconvenient to replace the fuse or to turn on the power from the beginning when the cause of short circuit or surge current flow in the secondary side is removed.

In addition, as another circuit protection method, the secondary power supply short circuit or surge current flow can be detected without opening the fuse to cut off the power supply through the switching operation, and when the cause of failure is eliminated, the secondary power supply can be supplied again without any operation. There is a method, such a method has been used most recently.

However, in the above method, even when a load is applied to the output terminal to generate an instantaneous surge current, the power supply may be cut off, thereby reducing the efficiency of the output voltage.

FIG. 1 is a circuit diagram of a feedback terminal circuit 100 according to the prior art, and as shown in FIG. 1, an SMPS for supplying secondary power to an output terminal of a transformer (not shown) according to a switching operation of a transistor (not shown). In the power supply circuit, the feedback terminal circuit 100 according to the prior art is composed of the feedback voltage control unit 110 and the IC 120.

Here, the feedback voltage controller 110 includes a photo coupler 111, a feedback voltage rising including a resistor 112a connected in series with the photo coupler 111 and a capacitor 112b connected in parallel with the resistor 112a. And a feedback unit 110. The feedback voltage controller 110 detects the voltage V _fb fed back from the secondary side of the transformer to the primary side, and controls the detected feedback voltage V _fb to control the secondary side. When a surge current flows through the circuit, the feedback voltage V _fb increases.

In addition, the IC 120 uses an IC consisting of a single chip and a PWM.

On the other hand, the operation of the feedback terminal circuit 100 having the configuration as described above is as follows.

First, when a surge current is generated on the secondary side, the output voltage falls below a certain range. For example, when the output voltage is 5V, when a surge current is generated on the secondary side, the output voltage drops below the 4.75V to 5.25V range.

At this time, the photocoupler (not shown) on the secondary side feeds back the separated output voltage to the primary side, and accordingly, the feedback voltage controller 110 of the feedback terminal circuit 100 _feeds back the voltage V _fb from the secondary side. ) Is detected and the feedback voltage V _fb is controlled to increase the feedback voltage V _fb .

In addition, when the elevated feedback voltage V _fb is greater than the driving voltage of the IC 120, the IC 120 recognizes that an abnormal surge current is flowing to the secondary side and turns off the transistor to turn off the transistor. It cuts off the secondary side, so the output voltage does not rise again but falls.

However, the above-described feedback terminal circuit according to the related art has a problem in that the supply of the secondary power is cut off by incorrectly recognizing the instantaneous surge current generated when the load is applied to the output terminal as an abnormal surge current.

That is, FIG. 2 is a graph showing waveforms of an output current Iout and an output voltage Vout generated when a load is applied in the prior art. As shown in FIG. Isur) disappears within a short time (typically within 10 μs; T).

However, as the instantaneous surge current Isur is incorrectly recognized as an abnormal surge current and the supply of the secondary power is cut off, the output voltage Vout does not rise again even after the surge current Isur is extinguished. As a result, there is a problem that the efficiency of the output voltage (Vout) is lowered.

Accordingly, the present invention has been made to solve the above problems, and since it is possible to delay the rise time of the feedback voltage with only a small number of elements without a separate time delay circuit, the circuit can be designed even at a low manufacturing cost. The present invention provides a feedback terminal circuit capable of increasing the efficiency of the output voltage by not interrupting the power supply to the instantaneous surge current generated when the load is applied to the output terminal by delaying the rise time of the circuit.

The feedback terminal circuit according to the present invention for achieving the above object is a SMPS power supply circuit for supplying the secondary power to the output terminal of the transformer in accordance with the switching operation of the transistor, the voltage fed back from the secondary side to the primary side of the transformer A feedback voltage controller configured to detect and control the detected feedback voltage to increase the feedback voltage when a surge current flows in the secondary side; A feedback voltage rising delay unit delaying a time at which the output feedback voltage rises when a surge current flows to the secondary side and the feedback voltage output from the feedback voltage controller increases; And an IC configured to control the switching operation of the transistor by comparing the feedback voltage raised through the feedback voltage controller and the feedback voltage rising delay unit with the driving voltage of the IC.

Here, the feedback voltage control unit, the photo coupler for detecting the feedback voltage; And a first capacitor connected in series with the photocoupler and a first capacitor connected in parallel with the first resistor, and controlling the detected feedback voltage to increase the feedback voltage when a surge current flows in the secondary side. Feedback voltage riser; characterized in that it comprises a.

On the other hand, the feedback voltage rise delay unit, a switch for flowing a current when a voltage of a predetermined magnitude is applied; A second capacitor connected to the switch and delaying a time at which the feedback voltage rises to charge a predetermined magnitude of the feedback voltages so that the feedback voltage rise time becomes a predetermined time; And a second resistor connected in parallel with the second capacitor and discharging a feedback voltage charged in the second capacitor.

In this case, the predetermined voltage may be smaller than the driving voltage of the IC.

The switch may be a zener diode.

The voltage having a predetermined magnitude among the feedback voltages is a voltage obtained by subtracting the voltage having the predetermined magnitude from the driving voltage of the IC.

In addition, the feedback voltage rise time is characterized in that more than 10 kHz.

In addition, the second capacitor is characterized by using a capacitor having a capacity of 5 kHz or more.

On the other hand, the IC, after the surge voltage flows even after the feedback voltage rise time, when the rising feedback voltage is greater than the driving voltage of the IC, the transistor is turned off to cut off the secondary side of the transformer

In the IC, when the surge current disappears within the feedback voltage rising time and the feedback voltage falls, the IC maintains the transistor in a turned-on state and supplies secondary power to the output terminal of the transformer.

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

3 is a circuit diagram of a feedback terminal circuit 300 according to the present invention. As shown in FIG. 3, an SMPS for supplying secondary power to an output terminal of a transformer (not shown) according to a switching operation of a transistor (not shown) is shown. In the power supply circuit, the feedback terminal circuit 300 according to the present invention includes a feedback voltage control unit 310, a feedback voltage rise delay unit 320, and an IC 330.

The feedback voltage controller 310 may include a first resistor 312a connected in series with the photo coupler 311 and the photo coupler 311 and a first capacitor 312b connected in parallel with the first resistor 312a. And a voltage fed back from the secondary side of the transformer (V _fb ) by the photo coupler 311 of the feedback voltage controller 310. The feedback voltage V _fb is controlled by the feedback voltage raising unit 312 to increase the feedback voltage V _fb when a surge current flows in the secondary side.

In addition, the feedback voltage rising delay unit 320 includes a switch 321, a second capacitor 322 connected to the switch 321, and a second resistor 323 connected in parallel with the second capacitor 322. When the surge current flows to the secondary side and the feedback voltage V _fb output from the feedback voltage controller 310 is increased, the output voltage of the feedback voltage V _fb is delayed.

At this time, the switch 321 allows a current to flow when a voltage of a predetermined magnitude is applied. Here, the voltage of the predetermined magnitude is smaller than the driving voltage of the IC 330, and since the zener diode is generally used as the switch 321, the zener diode is mainly used as a switch in the following description. I will explain. However, the concept and scope of the present invention is not limited to the zener diode.

In addition, the second capacitor 322 delays the time at which the feedback voltage V _fb rises and charges a voltage having a predetermined magnitude among the feedback voltages V _fb such that the feedback voltage rise time becomes a predetermined time. Do it.

In this case, the voltage having a predetermined magnitude among the feedback voltages V _fb refers to a voltage obtained by subtracting the predetermined voltage from the driving voltage of the IC 330. Accordingly, the second capacitor 322 charges a voltage obtained by subtracting the voltage of the predetermined magnitude from the driving voltage of the IC 330 to delay the feedback voltage rise time, thereby increasing the feedback voltage rise time by 10. ㎲ Make it ideal.

As described above, the reason for delaying the feedback voltage rise time so that the feedback voltage rise time is 10 kΩ or more is because the surge current generated when the load is applied is typically dissipated within 10 kW. In order to prevent the secondary power supply from being cut off by misrecognizing the instantaneous surge current generated when the load is applied as an abnormal surge current. At this time, in order to make the feedback voltage rise time to be 10 ㎲ or more, the capacity of the second capacitor 322 must be adjusted, and a capacitor having a capacity of at least 5 적어도 must be used to delay the feedback voltage rise time to 10 ㎲ or more. Can be.

In addition, the second resistor 323 serves to discharge the feedback voltage charged in the second capacitor 322. This is to prepare for the instantaneous surge current that may occur next, so that the second resistor 323 is connected in parallel to the second capacitor 322.

Meanwhile, the IC 330 compares the feedback voltage V _fb raised through the feedback voltage controller 310 and the feedback voltage rise delay unit 320 with the driving voltage of the IC 330 to switch the transistor. Serves to control.

Thus, when the IC (330), said feedback voltage rising period surge feedback voltage (V _fb) the current flows increases even after the greater than the drive voltage of the IC (330), by turning off the transistor of the secondary side of the transformer If the surge current disappears within the feedback voltage rising time and the feedback voltage _Vfb falls, the transistor is turned on to supply the secondary power to the output terminal of the transformer.

On the other hand, the operation of the feedback terminal circuit 300 having the configuration as described above is as follows.

First, when a surge current is generated on the secondary side, the output voltage falls below a predetermined range as in the prior art.

At this time, the secondary photo coupler (not shown) feeds back the separated output voltage to the primary side, and accordingly, the feedback voltage controller 310 of the feedback terminal circuit 300 _feeds back the voltage V _fb from the secondary side. ) Is detected and the feedback voltage V _fb is controlled to increase the feedback voltage V _fb .

Next, the zener diode 321 of the feedback voltage rising delay unit 320 selects a voltage smaller than the driving voltage of the IC 330 as a zener voltage to flow a current when the zener voltage is applied. The voltage obtained by subtracting the Zener voltage from the driving voltage of the IC 330 is charged in the second capacitor 322. Accordingly, any delay in the rise time of the feedback voltage (V _fb) the rise time of the feedback voltage (V _fb) is at least 10 ㎲.

That is, for example, if the driving voltage of the IC 330 is 7V and the zener voltage is 5V, when 5V is applied to the zener diode 321, the zener diode 321 causes a current to flow, and the IC The voltage 2V obtained by subtracting the Zener voltage from the driving voltage of 330 is charged in the second capacitor 322 to delay the rise time of the feedback voltage V _fb .

Then, when the feedback voltage rise time of 10 ㎲ even after a surge feedback voltage (V _fb) the current flows rises past is greater than the driving voltage of the IC (330), the IC (330) is to turn off the transistor It will block the secondary side of the transformer.

On the other hand, if the surge current disappears within 10 ㎲, the feedback voltage (V _fb ) is lowered to perform normal operation. Accordingly, the transistor is turned on to supply the secondary power to the output terminal of the transformer. do.

Thereafter, the voltage charged in the second capacitor 322 is discharged by the second resistor 323 connected in parallel to prepare for an instantaneous surge current which may be generated next time.

On the other hand, Figure 4 is a graph showing the waveform of the output current (Iout) and the output voltage (Vout) generated when the load is applied when using the present invention, as shown in Figure 4, the feedback terminal circuit according to the present invention In this case, since the power supply is not cut off for the instantaneous (typically within 10 mA; T) surge current Isur generated when the load is applied, the output voltage Vout is increased after the surge current Isur is extinguished. It can be seen that the rising again, thereby increasing the efficiency of the output voltage (Vout).

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and various substitutions, modifications, and changes within the scope of the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It will be appreciated that such substitutions, changes, and the like should be considered to be within the scope of the following claims.

As described above, according to the feedback terminal circuit according to the present invention, since the rise time of the feedback voltage can be delayed with only a small number of elements without a separate time delay circuit, it is possible to design the circuit even at a low manufacturing cost. have.

In addition, the instantaneous surge current generated when the load is applied to the output terminal by delaying the rise time of the feedback voltage is not cut off from the power supply, thereby increasing the efficiency of the output voltage.

Claims (10)

In the SMPS power supply circuit for supplying secondary power to the output terminal of the transformer in accordance with the switching operation of the transistor, A feedback voltage controller configured to detect a voltage fed back from the secondary side of the transformer to the primary side, and control the detected feedback voltage to increase the feedback voltage when a surge current flows through the secondary side; A feedback voltage rising delay unit delaying a time at which the output feedback voltage rises when a surge current flows to the secondary side and the feedback voltage output from the feedback voltage controller increases; And And an IC controlling the switching operation of the transistor by comparing the feedback voltage raised through the feedback voltage controller and the feedback voltage rising delay unit with the driving voltage of the IC. The method of claim 1, wherein the feedback voltage control unit, A photo coupler detecting the feedback voltage; And A feedback capacitor configured to include a first resistor connected in series with the photocoupler and a first capacitor connected in parallel with the first resistor, and controlling the detected feedback voltage to increase the feedback voltage when a surge current flows in the secondary side. And a voltage riser. The method of claim 1, wherein the feedback voltage rise delay unit, A switch for flowing a current when a voltage of a predetermined magnitude is applied; A second capacitor connected to the switch and delaying a time at which the feedback voltage rises to charge a predetermined magnitude of the feedback voltages so that the feedback voltage rise time becomes a predetermined time; And And a second resistor connected in parallel with the second capacitor and discharging a feedback voltage charged in the second capacitor. The method of claim 3, And the voltage having the predetermined magnitude is smaller than the driving voltage of the IC. The method of claim 3, And said switch is a Zener diode. The method of claim 4, wherein The voltage of a predetermined magnitude among the feedback voltages is a voltage obtained by subtracting the predetermined magnitude of voltage from a driving voltage of the IC. The method of claim 3, And the feedback voltage rise time is 10 kHz or more. The method of claim 3, And said second capacitor uses a capacitor having a capacitance of 5 kHz or more. The method of claim 7, wherein the IC, And a surge current flows even after the feedback voltage rise time, and when the raised feedback voltage becomes larger than the driving voltage of the IC, the transistor is turned off to cut off the secondary side of the transformer. The method of claim 7, wherein the IC, And if the surge current disappears within the feedback voltage rising time and the feedback voltage falls, the feedback terminal circuit is supplied with the secondary side power supplied to the output terminal of the transformer while the transistor is turned on.

Images