KR0120713Y1 - High voltage generator for power supply - Google Patents

Abstract

The present invention relates to a power supply, in particular, by using a transistor to output a high voltage applied to the load stably to extend the life of the power supply, the high voltage of the power supply that can improve the reliability of the power supply It relates to a generation circuit. The power detector 10 of the present invention has a power limiting unit 11 for detecting and limiting an output voltage of the power output unit 2, and an error amplifying unit 12 driven according to the output signal of the power limiting unit 110. And the high voltage control unit 13 which drives the error amplifier unit 12 to vary the output signal applied to the control unit 4 according to the output signal of the power limiting unit 11.

Description

High Voltage Generation Circuit of Power Supply

1 is a view showing the configuration of a general power supply.

2 is a view showing the configuration of a high-voltage generating circuit of the power supply according to the present invention.

* Explanation of symbols for main parts of the drawings

1: power input 2: power output

4 control unit 10 power detection unit

11: power limiter 12: error amplifier

13: high pressure control unit R11, R12, R31-R33: resistance

ZD11: Zener Diode Q11, Q31: Transistor

PD: Photodiode

The present invention relates to a power supply, and in particular, it is possible to extend the life of the power supply by stably outputting a high voltage applied to a load by using a transistor, and to improve the reliability of the power supply. It relates to a high pressure generating circuit.

As shown in FIG. 1, a general monitor has an electric power input unit 1 for full-wave rectifying and smoothing the input AC power AC and applying it to the transformer T, and the excitation of the secondary coil of the transformer T. Is applied to the load LD, the power output unit 2 for detecting the power applied to the load LD, the output signal of the power detection unit 3, and the output signal of the power detection unit 3 are applied. The controller 4 is configured to control the driving of the transformer T according to the generated control signal.

Here, the power input unit 1 includes a bridge diode BD for full-wave storage of the AC power AC input, a resistor Rin for removing an inrush current of an output signal of the bridge diode BD, and a resistor Rin. It consists of a capacitor (Cin) for smoothing the output signal.

Also, the power output unit 2 includes a diode Do for rectifying the current induced in the secondary coil of the transformer T, and a capacitor Co for smoothing the output signal of the diode Do.

The power detector 3 includes a resistor R31 for biasing the output voltage of the power output unit 2, an error amplifier Emp driven according to the resistor R31, and an error amplifier Eamp. And a resistor R32 and a photodiode PD for varying the output signal.

In addition, the controller 4 receives the output signal of the photodiode PD of the power detector 3 and controls the current flowing through the primary coil of the transformer T to adjust the output voltage of the power output unit 3. Configured to remain constant.

In the power supply device as described above, the AC power input is full-wave rectified by the bridge diode BD of the power input unit 1, and the full-wave rectified signal is driven by the resistor Rin. The current is removed.

The output signal of the resistor (Rin) is smoothed by the capacitor (Cin) and then applied to the primary coil of the transformer (T).

At this time, the current flowing through the primary coil of the transformer T is induced to the secondary coil of the transformer T according to the switching state of the controller 4, and the induced current is diode (Do) of the power output unit 2. Half-wave rectified by The output signal of the diode Do is smoothed by the capacitor Co and applied to the load LD.

In addition, the voltage applied to the load LD is applied to the error amplifier Eamp through the resistor R31 of the power detector 3 so that the error amplifier Eamp is driven and the error amplifier Eamp is driven. The current flowing through the resistor R32 and the photodiode PD is varied according to the current flowing through the resistor R31. That is, the amount of current flowing through the photodiode PD is determined by the resistors R31 and R32.

The output signal of the photodiode PD, which is the amount of current flowing through the photodiode PD, is applied to the control unit 4 so that the duty of the control signal generated according to the output signal is varied, and the transformer The current flowing in the primary side coil of T) is controlled.

When the amount of current flowing through the photodiode PD is small in the power supply device as described above, the time for switching the control signal of the control unit 40 to the turn-on state becomes longer, and the energy accumulated in the primary coil of the transformer T is increased. Since much is induced into the secondary coil, the high voltage is output from the power output unit (2).

However, if the size of the resistors R31 and R32 is increased to reduce the current flowing through the photodiode PD, the voltage applied to the error amplifier Emp becomes higher than the rated voltage, thereby causing the error amplifier Emp to be damaged. The lifespan of the power supply is shortened, and the heat generated from the resistor R1 results in a desired high pressure, thereby reducing the reliability of the power supply.

The present invention limits the voltage applied to the error amplifier to solve the above problems, and the amount of current flowing through the photodiode is limited according to the limited voltage to obtain the desired high voltage, thereby extending the life of the power supply. It is an object of the present invention to provide a high voltage generating circuit of a power supply that can improve the reliability.

The present invention for achieving the above object is the power input unit applied to the transformer by smoothing and then smoothing the AC power input to the transformer, and the power output that is applied to the load by smoothing after half-wave rectifying the excitation of the secondary coil of the transformer And a power supply unit for detecting power applied to a load, and a control unit for switching according to a control signal generated for driving a transformer according to an output signal of the power detection unit. A high voltage limiting output voltage applied to the control part in accordance with an output signal of the power limiting part by driving the power limiting part for limiting the output voltage of the output part; It is made with a control unit.

Hereinafter, described in detail by the accompanying drawings as follows.

2 is a view showing the configuration of the high-voltage generating circuit of the power supply device according to the present invention, as shown in this, the power supply unit for smoothing and applying the AC power input to the transformer (T) (1) and the power output unit 2 for half-wave rectifying the excitation of the secondary coil of the transformer T and smoothing it to the load LD are configured in the same manner as in FIG. 1, but the power detection unit 10 The power limiter 11 detects and restricts an output voltage of the power output unit 2, an error amplifier 12 that drives in accordance with the output signal of the power limiter 11, and an error amplifier 12. Is driven by the high voltage control unit 13 which varies the output signal applied to the control unit 4 according to the output signal of the power supply limiting unit 11.

Here, the power limiting unit 11 includes a resistor R11 (R12) for distributing the output voltage of the power output unit 2, and a transistor Q11 for switching by the divider voltage of the resistors R11 (R12); And a zener diode ZD11 for limiting the output signal of the transistor Q11.

In addition, the high voltage control unit 13 driven by the error amplifier unit 12 drives the resistors R31 and R32 for biasing the output voltage of the power output unit 2, and the resistors R31 and R32. The amount of current flowing through the resistor R32 in accordance with the transistor Q31 switching by the output signal, the resistor R33 keeping the output signal of the transistor Q31 constant, and the divider voltages of the resistors R31 and R33 is measured. It consists of a photodiode (PD) for remotely transmitting to the control unit (4) as an output signal.

In the high voltage straight circuit of the power supply device of the present invention configured as described above, the AC power input is full-wave rectified by the bridge diode BD of the power input unit 1, and the full-wave rectified signal is a resistor (Rin). ), The inrush current of the signal is eliminated.

The output signal of the resistor (Rin) is smoothed by the capacitor (Cin) and then applied to the primary coil of the transformer (T).

At this time, the current flowing in the primary coil of the transformer T is induced to the secondary coil of the transformer T according to the switching state of the controller 4, and the induced current is converted into the diode of the power output unit 2 ( Half-wave rectified by Do). The output signal of the diode Do is smoothed by the capacitor Co and applied to the load LD.

At this time, the output voltage of the power output unit 2 is distributed by the resistors R11 and R12 of the power limiting unit 11 of the power detecting unit 10, and the divided voltage is applied to the transistor Q11 to supply the transistor ( Q11) is switched to the on state.

The output signal of the transistor Q11 is varied according to the distribution voltage of the resistors R11 and R12, and the variable output signal is limited by the zener diode ZD11.

Then, the error amplifier 12 is driven by the output signal of the zener diode ZD11, that is, the output of the zener diode ZD11 applied to the error amplifier 12 by the error amplifier 12 is driven. The magnitude of the output signal of the high voltage controller 13 is determined according to the signal.

When the error amplifier 12 is driven, the output voltage of the power output unit 2 is biased by the resistors R31 and R32 of the high voltage control unit 13 and then applied to the base side of the transistor Q31. The output signal of the resistor R31 is applied to the emitter side of the transistor Q31.

That is, the transistor Q31 is switched on by the output signal of the resistor R32, and the output signal of the transistor Q31 is kept constant by the resistor R33.

Since the divided voltages of the resistors R31 and R33 are applied to the resistor R32 and the photodiode PD by the turn-on state of the transistor Q31, the amount of current flowing through both ends of the photodiode PD is small. Value.

The output signal of the photodiode PD is applied to the control unit 4 so that the duty of the control signal varies according to the output signal, and the current flowing through the primary coil of the transformer T is controlled by the trigger of the control signal. do.

That is, when the output signal which is the amount of current flowing through the resistor R32 is small and the time for which the control signal of the controller 4 is switched to turn-on state becomes long, the energy accumulated in the primary coil of the transformer T is increased. Because a lot of is induced into the secondary coil, the high voltage is output from the power output unit (2).

As described above, the high voltage generation circuit of the power supply device according to the present invention is applied to the error amplifier by limiting the output voltage of the power output unit, and the output signal of the power detector is reduced by the applied voltage of the limited error amplifier. By stably outputting this, the life of the power supply can be extended, and the reliability of the power supply can be improved.

Claims (3)

The AC power input AC is rectified and smoothed to be applied to the transformer T, and the excitation of the secondary coil of the transformer T is half-wave rectified and then smoothed to load LD. Control generated for driving the transformer T according to the output signal of the power output unit 2 to be applied to the power source, the power detector 10 to detect the power to be applied to the load LD, and the power detector 10. In the power supply device provided with a control unit (4) for switching in accordance with the signal, the power detector 10 includes a power warner limiting unit (11) for limiting the output voltage of the power output unit (2), the power limit An error amplifier 12 for driving in accordance with the output signal of the unit 11 and a high voltage for varying the output signal applied to the control unit 40 in accordance with the output signal of the power limiter 11 by driving the error amplifier 12 High pressure generating circuit of the power supply characterized in that the control unit 13 is provided. 2. The power supply limiting unit (11) according to claim 1, wherein the power limiting unit (11) is switched by a divider (R11) (R12) for distributing the output voltage of the power output unit (2) and the divider voltage of the resistors (R11) (R12). And a zener diode (ZD11) for limiting an output signal of the transistor (Q11). The voltage regulator of claim 1, wherein the high voltage controller 13 is configured to switch by the resistors R31 and R32 for biasing the output voltage of the power output unit 2 and the output signals of the resistors R31 and R32. The transistor Q31, the resistor R33 for keeping the output signal of the transistor Q31 constant, and the amount of current flowing through the resistor R32 according to the divided voltage of the resistors R31 and R33 are controlled as output signals. A high voltage generation circuit of a power supply device, characterized in that consisting of a photodiode (PD) for remote transmission to (4).