KR0143276B1 - Circuit for soft starting of a monitor - Google Patents

Abstract

The present invention relates to a soft-starting circuit of a monitor that prevents overshoot occurring when the power switch is switched on. The present invention relates to a resistor, a transistor, a capacitor, and a zener diode between a bridge diode and a smoothing unit and a power circuit controller. When the power switch is turned on, the voltage applied to the power circuit controller does not increase suddenly but gradually increases so that the operating speed of the power circuit controller is slowed down to lower the leveling frequency applied to the transistor. do.

As the leveling frequency applied to the transistor is gradually increased, the voltage of the output part is also gradually increased to prevent the occurrence of overshoot.

Description

Soft starting circuit of the monitor

1 is a soft start circuit diagram of a conventional monitor

2 is a soft starting circuit diagram of a monitor according to the present invention.

3 is an output waveform diagram of each part according to the present invention

* Explanation of symbols for the main parts of the drawings

10: smoothing part 12: output part

14: water leveling unit 16: power supply circuit control unit

18: Soft starting part 20: Feedback control part

30: operation power supply

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitor, and more particularly, to a soft starting circuit of a monitor which prevents over shoot phenomenon occurring when the power switch is switched on.

As shown in FIG. 1, a general soft starting circuit includes a bridge diode BD for full-wave rectifying the input AC power AC and a capacitor C1 for smoothing the voltage output from the bridge diode BD. A smoothed part 10, a transformer T1 for outputting a voltage excited to the secondary coil by the voltage smoothed by the smoothed part 10, a diode Do and a capacitor Co. An output unit 12 for rectifying the excited voltage of the transformer T1 and outputting it to a load, a switching unit 14 configured to drive the transformer T1 by the transistor Q1, and the output unit 12 A power supply circuit controller 16 for sensing a voltage output from the power supply unit and outputting a control signal for driving the switching unit 14 and a power start circuit controller 16 connected to the power circuit control unit 16 so as to perform a soft start. Soft starting circuit (18) It is configured.

In the general soft starting circuit made in this manner, the input AC power is full-wave rectified by the bridge diode BD, and the full-wave rectified voltage is smoothed by the capacitor C1 of the smoothing unit 10.

The smoothed voltage of the smoothing unit 10 is applied to the transformer T1 to be excited to the secondary coil of the transformer T1, and the excited secondary voltage of the transformer T1 is diode (Do) of the output unit 12. Rectified by), the output voltage of the rectified diode (Do) is output after smoothed by the capacitor (Co).

At this time, the voltage Vo output from the output unit 12 is generated in proportion to the duty ratio determined by the switching frequency applied to the transistor Q1 of the switching unit 14, so that the voltage Vo The stabilization of can be achieved by the stable variation of the switching frequency applied to the transistor Q1.

However, since the switching frequency is generated, the power circuit controller 16 is operated by the voltage Vcc applied through the bridge diode BD to generate the switching frequency and is applied to the switching unit 14 to operate the transistor Q1. Let's do it.

When the transistor Q1 is operated by a flow rate proportional to the generation state of the switching frequency, and operates the transformer T1, the voltage Vo is generated at the output unit 12. At this time, the soft starting circuit 18 connected to the power circuit controller 16 is operated by the voltage Vcc applied to the power circuit controller 16 so that the power circuit controller 16 gradually increases the flow rate. In order to prevent the output voltage from rising, the voltage Vcc decreases until the output voltage reaches a normal value, thereby causing the operation of the controller 16 to be stopped again. At this time, if the capacity of the capacitor (C2) is large, the problem can be solved, but the starting time is too long, which is inconvenient to use. ), Overshoot is generated by sudden voltage application when the power switch is turned on or off, and the transistor is not damaged, and an overshoot is generated at the voltage Vo of the output unit 12. There was a problem of causing a breakage of the load connected to the portion 12.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a soft starting circuit of a monitor which enables a soft start by connecting a soft starting circuit having a soft starting function to a power supply circuit controller. .

In order to achieve the above object, the present invention provides a bridge diode for full-wave rectifying the input AC power, a smoothing part for smoothing the voltage output from the bridge diode, and a voltage excited on the secondary coil by the smoothed voltage of the smoothing part. A transformer for outputting a voltage, an output unit for rectifying the excited voltage of the transformer and outputting the voltage to a load, a water leveling unit for driving the transformer, and a water leveling unit, and applying a switching frequency to a stacking unit. A power circuit control unit for controlling the flow rate of the former, a soft starting circuit unit connected to the power circuit control unit and sensing an operation state of the power circuit control unit to control an increase in switching frequency so that the flow rate is gradually increased; It is connected between the control unit and the bridge diode and supplies power to the power circuit control unit. And a feedback control unit connected to the transformer and supplying a current generated from the transformer to the power circuit control unit.

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

2 shows a soft starting circuit according to the present invention, and includes a bridge diode BD for full-wave rectifying the input AC power, and a capacitor C1 to smooth the voltage output from the bridge diode BD. (10), a transformer (T1) for outputting the excitation voltage to the secondary coil by the smoothed voltage of the smoothing unit 10, and a diode (Do) and a capacitor (Co) is composed of the transformer (T1) An output unit 12 for rectifying the excited voltage of the excitation voltage and outputting it to a load, a switching unit 14 configured to drive a transformer T1 by a transistor Q1 and a resistor R4, and the switching unit 14 Is connected to the power supply circuit control unit 16 to control the flow rate of the transformer T1 by applying a switching frequency to the switching unit 14, and is connected to the power supply circuit control unit 16 and includes a resistor (R3) and a diode ( D1) (D2) and condenser (C2) to control power circuit A soft starting circuit unit 18 for sensing the operation state of the control unit 16 and controlling the increase of the switching frequency to gradually increase the flow rate, and is connected between the power supply circuit control unit 18 and the bridge diode BD. R1) (R2), Zener diode (ZD1), capacitor (C3), transistor (Q2) is connected to the operating power supply unit 30 for supplying power to the power circuit control unit 18, and the transformer T1 The feedback controller 20 is configured to apply the current generated from the transformer T1 to the power supply circuit controller 16 through the diode D3.

When the AC power is applied from the external power supply unit (not shown), the present invention is configured and converted to DC power through the bridge diode BD and the smoothing unit 10 to the operating power supply unit 30 and the transformer T1. The feedback control unit 20, which is initially connected to the transformer T1, has a low voltage to the power supply circuit controller 16 through the diode D3 because the transistor Q1 of the switching unit 14 does not operate normally. Is applied. In addition, when the voltage applied from the feedback control unit 20 is lower than the threshold voltage of the zener diode ZD1 of the operation power supply unit 30, the transistor Q2 conducts the voltage Vcc to the power circuit control unit 16. When the conduction state of the transistor Q2 is applied, the voltage Vcc applied to the power supply circuit control unit 16 increases, and when the power supply circuit control unit 16 reaches a constant voltage, it starts to operate normally. The circuit unit 18 is operated.

When the power circuit control unit 30 operates normally, the soft start circuit unit 18 charges the voltage Vc2 to the capacitor C2 through the resistor R3, and when the voltage Vc2 is low, the power circuit control unit. Since the leveling frequency applied to the transistor Q1 of the switching unit 14 is small at 16, the transistor Q1 has a low flow rate, so that the voltage Vo of the output unit 12 is low.

When the voltage Vc2 gradually increases, the switching frequency applied from the power circuit controller 16 to the transistor Q1 increases, so that the flow rate of the transistor Q1 increases to generate the voltage Vo generated by the output unit 12. ) Will gradually increase.

When the operation signal applied from the power supply circuit controller 16 to the transistor Q1 of the switching unit 14 increases, the flow rate of the transformer T1 increases, and when the flow rate of the transformer T1 increases, feed The high voltage is generated in the back controller 20 and applied to the power circuit controller 16.

When the voltage applied from the feedback control unit 20 is higher than the threshold voltage of the zener diode ZD1 of the operation power supply unit 30, the transistor Q2 is turned off, and the power supply control unit 16 supplies the feedback agent. A voltage is applied from the fisherman 20.

3 is a waveform diagram generated in the soft starting circuit according to the present invention, (a) is an output waveform diagram of a voltage Vcc, and (a) is an AC voltage initially inputted from an external power supply to a bridge diode (BD). Is a waveform diagram gradually applied through the smoothing unit 10, and (b) shows a voltage state applied from the transistor Q2 when the voltage Vo of the output unit 12 does not reach a normal voltage. The region (C) is a waveform showing the voltage state of the voltage applied through the feedback control unit when the voltage Vo of the output unit 12 reaches the normal voltage and the transistor Q2 is turned off. It is also.

(b) is an output waveform diagram of the voltage Vref. When the voltage Vcc becomes a constant voltage, it is in a high state to operate the soft starting unit 18.

(c) is an output waveform diagram of the voltage Vc2. When the voltage Vref becomes high, it gradually increases and increases to the magnitude of the voltage Vref, thereby increasing the flow rate of the transistor Q1 of the switching unit 14. To increase the voltage Vo at the output.

(d) is an output waveform diagram of the power supply circuit controller 16. When the voltage Vc2 increases, the interval between waveforms applied to the transistor Q1 of the switching unit 14 gradually increases, and the flow rate of the transistor Q1 is increased. To increase.

(e) is an output waveform diagram of the voltage Vo. When the voltage ref becomes high, the flow rate of the transistor Q1 increases, and the state of the voltage Vo gradually increases.

As can be seen from the above description, the present invention provides a voltage applied to the power circuit control unit 16 when the power switch is switched on by connecting the operation power supply unit 30 between the bridge diode and the smoothing unit and the power circuit control unit. (Vcc) does not increase rapidly, but gradually increases, thereby slowing the operating speed of the power circuit control unit 16 to lower the switching frequency applied to the transistor. As a result, the voltage Vo of the output portion also gradually increases to prevent overshoot. There is an effect that can prevent the occurrence.

Claims (1)

A bridge diode for full-wave rectifying the input AC power, a smoothing unit 10 for smoothing the voltage output from the bridge diode, and a smoothed voltage of the smoothing unit 10 to output an excited voltage to the secondary coil Transformer T1, an output unit 12 for rectifying the excited voltage of the transformer T1 and outputting it to a load, a switching unit 14 for driving the transformer T1, and the switching unit 14 A power supply circuit control unit 16 connected to the power supply circuit control unit 16 for controlling a flow rate of the transformer T1 by applying a switching frequency to the switching unit 14 and an operation of the power supply circuit control unit 16. A soft starting circuit unit 18 for sensing a state and controlling an increase in switching frequency to gradually increase the flow rate, and is connected between the power circuit control unit 18 and the bridge diode and supplies power to the power circuit control unit 18. It is characterized in that it is made of a feedback control unit 20 is connected to the transformer (T1) and the operating power supply unit for supplying a current to the power circuit control unit 16 to the current generated from the transformer through a diode Soft starting circuit of the monitor.