KR20010054858A - Circuit for protecting high voltage power supply in a monitor - Google Patents

Abstract

The present invention relates to a high voltage generator protection circuit of a monitor.

In the present invention, the main transformer 10 outputs a high-voltage generated power, the high-voltage generated power is rectified and boosted by the rectifier circuit 20 and the boost-up circuit 30 is applied to the primary side of the FBT 40, the horizontal output When the transistor TR4 is switched, in the high voltage generating portion of the monitor such that the high voltage generating power applied to the primary side of the FBT 40 is output through the secondary side, it is connected between the rectifying circuit 20 and the boost up circuit 30. When the shutdown on signal is input, the output is output from the main transformer 10 to shut down the high-voltage generated power applied to the FBT 40, and to be driven through the secondary side of the FBT 40. Malfunction detection unit 60 outputting a low signal when the power is detected as an overcurrent and overvoltage condition, and MCU outputting a shutdown on / off signal depending on whether a sink signal and a low signal output from the malfunction detection unit 60 are input. (70) And it characterized in that the arrangement,

Accordingly, it is possible to prevent breakdown of various circuit components from overvoltage or overcurrent due to malfunction of the high-voltage generator, and to improve product reliability.

Description

CIRCUIT FOR PROTECTING HIGH VOLTAGE POWER SUPPLY IN A MONITOR}

The present invention relates to a high pressure generating portion of the monitor, and more particularly to a high voltage generating portion protection circuit of the monitor.

In general, in a monitor, a conventional high voltage generator using a flyback transformer (hereinafter referred to as FBT) is configured to switch the secondary side of the FBT as the horizontal output transistor switches the power source B + applied to the primary side of the FBT. Through this, various power sources for driving the monitor are output.

Referring to FIG. 1, the main transformer 10 of the conventional monitor high voltage generation unit outputs a high voltage generation power as the main transformer FET TP1 is switched by a PWM signal output from the PWM IC 11.

The rectifier circuit 20 rectifies the output power of the main transformer 10 and includes a diode D1, a resistor R1, and a capacitor C1.

The boost up circuit 30 boosts the high voltage generating power. The boost up circuit 30 includes a boost up coil L1, a boost up FET TR3 driven by a boost up pulse, and a ground resistor R4 connected to a source, a boost up diode D2, and a boost up capacitor. It consists of C2.

The FBT 40 outputs various powers for driving the monitor through the secondary side as the horizontal output transistor TR4 connected to the primary side and switched by the horizontal output signal switches the high voltage generating power source B + applied to the primary side. do. Various driving powers output through the secondary side of the FBT 40 are rectified by the diode D3 and the capacitor C4.

The conventional high pressure generating unit configured as described above operates as follows.

When the main transformer 10 outputs a high voltage generation power as the main transformer FET TP1 is switched by the PWM signal output from the PWM IC 11, the rectifier circuit 20 and the boost up circuit 30 are connected to the rectifier circuit 20 and the boost up circuit 30. As a result, the high-voltage generated power is rectified and stepped up and applied to the primary side of the FBT 40.

Therefore, the high voltage generating power source B + applied to the primary side of the FBT 40 is switched by the horizontal output transistor TR4 connected to the primary side of the FBT 40 and switched by a horizontal output signal. Through the secondary side of the FBT 40, it is converted into various power sources required for driving the monitor and output.

However, there is a problem that the horizontal output transistor TR4 breaks down when an overcurrent or an overvoltage occurs on the secondary side of the FBT 40 due to a malfunction of the conventional monitor high voltage generator as described above. When the TR4 is shorted or opened, components included in the main transformer 10, the rectifier circuit 20, and the boost up circuit 30 are successively broken down.

Accordingly, the present invention is to overcome the above-mentioned conventional problems, an object of the present invention is to generate a high pressure is automatically applied to the primary side of the FBT when overcurrent or overvoltage occurs on the secondary side of the FBT as the monitor high pressure generating unit malfunctions It is to provide a high voltage generator protection circuit of the monitor which is intended to shut down the power supply.

The high voltage generator protection circuit of the monitor for achieving the object of the present invention is that the main transformer outputs a high voltage power supply when the main transformer FET is switched by a PWM signal of the PWM IC, the high voltage by the rectifier circuit and the boost-up circuit The generated power is rectified and stepped up and applied to the primary side of the FBT. When the horizontal output transistor connected to the primary side of the FBT is switched by a horizontal output signal, the high voltage generated power applied to the primary side of the FBT is monitored through the secondary side. A high voltage generator of a monitor which is converted to a power required for driving and outputted, the high voltage generator being connected between a rectifier circuit and a boost up circuit, and outputting from the main transformer when the shutdown on signal is input to the FBT. Shutdown circuit for shutting down the circuit and driving output through the secondary side of the FBT A malfunction detection unit for outputting a low signal when the power is detected as an overcurrent and an overvoltage state, and a MCU for outputting a shutdown on / off signal depending on whether a sink signal and a low signal output from the malfunction detection unit are input. It is done.

Accordingly, the high voltage generator protection circuit of the monitor of the present invention can prevent breakdown of various circuit components from overvoltage or overcurrent due to malfunction of the high voltage generator, and improve the reliability of the product.

1 is a configuration diagram showing a high pressure generating portion of a conventional monitor;

2 is a configuration diagram showing a high-voltage generator protection circuit of the monitor according to the present invention;

3 is a flowchart showing an operating state of the MCU.

<Explanation of symbols for the main parts of the drawings>

10: main transformer 11: PWM IC

20: rectifier circuit 30: boost up circuit

40: FBT 50: shutdown circuit

60: malfunction detection unit 70: MCU

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

Referring to FIG. 2, the main transformer 10 outputs a high voltage generation power as the main transformer FET TP1 is switched by a PWM signal output from the PWM IC 11.

The rectifier circuit 20 rectifies the output power of the main transformer 10 and includes a diode D1, a resistor R1, and a capacitor C1.

The boost up circuit 30 boosts the high voltage generating power. The boost up circuit 30 includes a boost up coil L1, a boost up FET TR3 driven by a boost up pulse, and a ground resistor R4 connected to a source, a boost up diode D2, and a boost up capacitor. It consists of C2.

The FBT 40 outputs various powers for driving the monitor through the secondary side as the horizontal output transistor TR4 connected to the primary side and switched by the horizontal output signal switches the high voltage generating power source B + applied to the primary side. do.

Various driving powers output through the secondary side of the FBT 40 are rectified by the diode D3 and the capacitor C4.

The shutdown circuit 50 is connected between the rectifier circuit 20 and the boost up circuit 30, and when a shutdown on signal is input, a high voltage is generated from the main transformer 10 and applied to the FBT 40. Shut down the power supply.

The shutdown circuit 50 has an emitter connected to an output terminal of the rectifier circuit 20, a collector connected to an input terminal of the boost up circuit 30, and a resistor R2 connected between the emitter and the base. The collector is connected to the first transistor TR1 and the bias resistor R3 connected to the base of the first transistor TR1, the emitter is grounded, and the shutdown on / off signal of the MCU 70. Is composed of a second transistor TR2 applied as a base.

The malfunction detection unit 60 outputs a low signal when the driving power output through the secondary side of the FBT 40 is detected as an overcurrent and an overvoltage state.

The malfunction detection unit 60 has two series resistors in which the contacts of the series resistors R5 and R6 for reference voltages are connected to the inverting terminal (-), and are connected in parallel to the secondary output terminal of the FBT 40. The contacts of (R7, R8) are constituted by the OP amplifier OP1 connected to the non-inverting terminal (+).

The MCU 70 outputs a shutdown on / off signal depending on whether a sink signal and a low signal output from the malfunction detection unit 60 are input.

When the sink signal is not input or the low signal output from the malfunction detection unit 60 is input, the MCU 70 outputs a shutdown on signal to turn off the second transistor TR2, and the sink signal is input. When the low signal output from the malfunction detection unit 60 is not input, a shutdown off signal is output to turn on the second transistor TR2.

By the above configuration, the high-voltage generator protection circuit of the monitor according to the present invention operates as follows.

Referring to FIG. 3, the MCU 70 first determines whether a sync signal indicating whether the monitor is started is input (S10).

If the sink signal is not input to the MCU 70, since the monitor does not start, the MCU 70 outputs a shutdown on signal to turn off the second transistor TR2 of the shutdown circuit 50. The high voltage generating power output from the main transformer 10 and rectified by the rectifier circuit 20 is blocked from being applied to the primary side of the FBT 40 via the boost up circuit 30 (S11). .

On the other hand, since the monitor starts when the sink signal is input to the MCU 70, the MCU 70 outputs a shutdown off signal to turn on the second transistor TR2 of the shutdown circuit 50 (S12).

When the second transistor TR2 is turned on, the first transistor TR1 is also turned on, so that the high-voltage generated power output from the main transformer 10 and rectified by the rectifier circuit 20 is passed through the boost-up circuit 30. Is applied to the primary side of the FBT 40.

Therefore, the high voltage generating power applied to the primary side of the FBT 40 is switched by the horizontal output transistor TR4 and then converted into various kinds of power required for driving the monitor through the secondary side of the FBT 40 and output. .

At this time, the MCU 70 determines the output signal state of the malfunction detection unit 50 for detecting the abnormality of the power output through the secondary side of the FBT (40) (S13).

If the rectified power output through the secondary side of the FBT 40 is in a normal state, the OP amplifier OP1 of the malfunction detection unit 50 outputs a high signal.

When the high signal of the malfunction detection unit 50 is input, the MCU 70 outputs a shutdown off signal to continuously turn on the second transistor TR2 (S14).

However, when a predetermined monitor driving power is normally output through the secondary side of the FBT 40 as described above, if the monitor high voltage generator according to the present invention malfunctions and an overcurrent or an overvoltage occurs on the secondary side of the FBT 40. The OP amplifier OP1 of the malfunction detection unit 50 outputs a low signal.

When the low signal of the malfunction detection unit 50 is input, the MCU 70 outputs a shutdown on signal to turn off the second transistor TR2, thereby outputting from the main transformer 10 and outputting the rectifier circuit 20. The high-voltage generated power rectified by the block is blocked from being applied to the primary side of the FBT 40 via the boost up circuit 30 (S11).

As described above, the high-voltage generator protection circuit of the monitor according to the present invention automatically shuts down the high-voltage generated power applied to the primary side of the FBT when an overcurrent or an overvoltage occurs on the secondary side of the FBT as the monitor high-pressure generator malfunctions. Since it is possible to prevent breakdown of various circuit components from voltage rise or overcurrent caused by malfunction of the high-voltage generator, it is effective to improve the reliability of the product.

What has been described above is only one embodiment for implementing the high-voltage generator protection circuit of the monitor according to the present invention, the present invention is not limited to the above-described embodiment, the present invention claimed in the following claims Various changes can be made by those skilled in the art without departing from the gist of the present invention.

Claims (4)

When the main transformer FET TP1 is switched by the PWM signal of the PWM IC 11, the main transformer 10 outputs a high voltage generating power, and the rectifying circuit 20 and the boost up circuit 30 generate the high voltage generating power. The rectified and stepped up voltage is applied to the primary side of the FBT 40, and when the horizontal output transistor TR4 connected to the primary side of the FBT 40 is switched by the horizontal output signal, it is applied to the primary side of the FBT 40. In the high pressure generating portion of the monitor that the high-voltage generated power is converted to the power required for driving the monitor through the secondary side and outputted, Shutdown that is connected between the rectifier circuit 20 and the boost-up circuit 30, and shuts down the high-voltage generated power output from the main transformer 10 when the shutdown on signal is input to the FBT 40 Circuit 50, Malfunction detection unit 60 for outputting a low signal when the drive power output through the secondary side of the FBT 40 is detected as an overcurrent and overvoltage state, and The MCU 70 outputs a shutdown on / off signal according to whether a sink signal and a low signal output from the malfunction detection unit 60 are input. High-voltage generator protection circuit of the monitor, characterized in that consisting of. The method of claim 1, wherein the shutdown circuit 50 A first transistor TR1 having an emitter connected to an output terminal of the rectifier circuit 20, a collector connected to an input terminal of the boost up circuit 30, and a resistor R2 connected between the emitter and the base. , And The second transistor is connected to the bias resistor R3 connected to the base of the first transistor TR1, the emitter is grounded, and the shutdown on / off signal of the MCU 70 is applied to the base. TR2) High-voltage generator protection circuit of the monitor, characterized in that consisting of. According to claim 1, wherein the malfunction detection unit 60 The contacts of the series resistors R5 and R6 for the two reference voltages are connected to the inverting terminal (-), and the contacts of the two series resistors R7 and R8 connected in parallel to the secondary output terminal of the FBT 40 are connected. A protection circuit for a high voltage generating part of a monitor, comprising: an OP amplifier (OP1) connected to a non-inverting terminal (+). The method of claim 1 or 2, wherein the MCU (70) When the sink signal is not input or a low signal output from the malfunction detection unit 60 is input, a shutdown on signal is output to turn off the second transistor TR2, and the sink signal is input and the malfunction detection unit 60 is output. And outputting a shutdown off signal to turn on the second transistor TR2 when the low signal outputted from the input signal is not input.