KR19980024488U - CRT protection circuit in monitor - Google Patents

Abstract

The present invention relates to a circuit for protecting a CRT from excessive beam current (ie, anode current) in a monitor. The circuit of the present invention applies the high voltage induced through FBT to the anode of the CRT by switching the B + voltage according to the driving signal provided from the horizontal oscillator to the anode of the CRT, and when the X-ray signal is input, the horizontal An anode current detecting means 230 for detecting an increase in the anode current in the monitor in which the oscillation unit stops oscillation and thus the switching of the B + voltage is stopped to stop the high voltage generation; And an X-ray signal generating means 220 for providing an X-ray signal to the horizontal oscillator according to the detection voltage of the anode current detecting means. To prevent the build-up or X-rays.

Description

Circuit for protecting CRT from overcurrent in a monitor

The present invention relates to a circuit for protecting a CRT from excessive beam current (ie, anode current) in a monitor, and more particularly, to a CRT protection circuit configured to stop the operation of the CRT when excessive beam current is detected.

In general, a color display device (CRT) focuses and accelerates hot electrons emitted from R, G, and B guns, and collides with R, G, and B fluorescent surfaces through a point on a shadow mask to form pixels, and vertical and horizontal deflection coils. Sawtooth current flows to form a two-dimensional screen.

In order to operate the color display device (CRT), a heater voltage of about 6.3 V is applied to the heater, and a focus grid voltage, a screen grid voltage, etc. are required for focusing the emitted hot electrons. High pressure of about 20KV is applied.

1 is a circuit diagram showing a general automatic luminance limiting (ABL) circuit for protecting a CRT from overcurrent.

Referring to FIG. 1, a main power supply (SMPS) 100 receives an AC power and provides various DC voltages required by a monitor, and the DC-DC converter 130 stabilizes a high voltage while stabilizing a high voltage. Provides the B + voltage required by high voltage generator 140.

The horizontal deflection unit 150 drives the oscillation pulse locked to the horizontal synchronizing frequency (H.sync) input from the computer main body in the internal driving unit, and then turns on and off the horizontal output transistor according to this driving signal to the horizontal deflection coil. The sawtooth current flows, and the magnetic field formed by the current flowing in the horizontal deflection coil deflects the hot electrons emitted from the cathode of the CRT to display the screen.

The high voltage generation unit (FBT) 140 generates the anode voltage (HV), focus voltage, and screen voltage required by the CRT, and the current flowing through the anode (also referred to as anode current and beam current) increases and decreases according to the brightness of the screen. However, if the screen is too bright, harmful electromagnetic waves are generated, which may harm the user and shorten the life of the CRT. Therefore, an automatic brightness limit (ABL) circuit for limiting this properly is placed on the secondary winding side of the FBT. It is connected.

As such, the automatic luminance limiting (ABL) circuit for protecting the CRT is a resistor (R7, R8) connected to a winding that provides a high voltage to the CRT anode and detects a voltage according to the variation of the anode current. It increases as it increases, and as it decreases as the anode current decreases.

That is, referring to FIG. 1, the resistor R7 connected to the high voltage winding is about 4.7K ohm and the resistor R8 is about 120K ohm, and the PNP transistor (R6) is connected to the common connection point of the resistors. Q2) is connected. The base of the NPN transistor Q1 is connected to the collector side of the transistor Q2 through resistors R4 and R3, and the contrast control terminal of the video preamplifier 110 is connected to the collector of the transistor Q1. contrast is connected.

In addition, the PWM control terminal of the microcomputer 100 is connected to the contrast control terminal of the video preamplifier 110 through the variable resistor VR1 and the RC filters R1 and C1. Therefore, the microcomputer can generate the corresponding PWM pulse to adjust the contrast of the video signal.

If the screen becomes bright and the anode current increases, the detection voltage of the ABL circuit is lowered, and thus the base voltage of the PNP transistor Q2 is lowered, thereby turning on the PNP transistor Q2. When the PNP transistor Q2 is turned on, 12V connected to the emitter terminal is divided through the resistors R5, R4, and R3 to apply a 'high' voltage to the base of the transistor. Accordingly, the NPN transistor Q2 is turned on to tie the contrast terminal of the video preamplifier 110 to a 'low' level to prevent the screen from being brightened.

However, in the ABL circuit, when the screen is bright, only the contrast level is lowered to limit the brightness of the CRT, and there is a fear that X-rays harmful to the human body may be generated in the CRT because the high voltage cannot be blocked.

Therefore, the present invention was devised to solve the above problems, and the purpose of the present invention is to provide a CRT protection circuit in a monitor that can protect the CRT and the user by operating the X-ray function when the anode current is increased to some extent. have.

In order to achieve the above object, in the circuit of the present invention, the horizontal output transistor switches the B + voltage according to the driving signal provided from the horizontal oscillator, and applies the high voltage induced through the FBT to the anode of the CRT, and the X-ray X- 10. A monitor in which the horizontal oscillator stops oscillating when a signal is input and stops switching of the B + voltage, thereby stopping the generation of high voltage, comprising: anode current detecting means for detecting an increase in anode current; And an X-ray signal generating means for providing the X-ray signal to the horizontal oscillator according to the detection voltage of the anode current detecting means, so that the anode current increases and the screen becomes excessively bright or X It is characterized in that the -ray is prevented from occurring.

1 is a circuit diagram showing a general automatic luminance limiting circuit for protecting the CRT from overcurrent,

2 is a circuit diagram illustrating a CRT protection circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

100: Micom 110: Video Preamplifier

120: main power supply 130: DC-DC converter

140: high pressure generating unit 150: horizontal deflection unit

210: horizontal and vertical IC 220: X-ray drive unit

230: anode current detection unit

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

2 is a circuit diagram illustrating a CRT protection circuit according to the present invention.

As shown in FIG. 2, the CRT protection circuit according to the present invention includes a main power supply (SMPS) 120, a DC-DC converter 130, a horizontal deflection unit 150, a high voltage generation unit 140, and an anode current detection unit ( R7, R8), an X-ray signal generator 220, and a horizontal vertical IC (210).

Referring to FIG. 2, the main power supply 120 receives various AC powers and provides various DC voltages required by the monitor. The DC-DC converter 220 is required for the horizontal deflection circuit and the high voltage generator while stabilizing the high pressure. Provide the B + voltage. In this case, when the DC-DC converter 130 is a buck converter type, a DC voltage of about 180V is input from the main power supply 120 to output an appropriate B + voltage according to a mode (ie, according to a horizontal synchronizing frequency). In the case of a boost up converter type, a DC voltage of about 50 V is input from the main power supply 120 to output an appropriate B + voltage according to a mode (ie, according to a horizontal synchronizing frequency).

The horizontal vertical IC 210 generates a horizontal drive pulse and a vertical drive pulse locked to the horizontal sync frequency and the vertical sync frequency input from the computer. At this time, the horizontal vertical IC 210 is provided with an x-ray function and stops oscillation when the X-ray signal is input to the X-ray terminal to block the output of the driving pulse. Therefore, when the X-ray function is activated, there is no driving pulse, and thus the output transistor of the horizontal deflection unit 150 does not switch and temporarily cuts off the high voltage.

The horizontal deflection unit 150 turns the horizontal output transistor on and off according to the horizontal drive pulse (H.drive) of the horizontal vertical IC to flow a sawtooth current through the horizontal deflection coil, and the magnetic field formed by the current flowing through the horizontal deflection coil is Display the screen by deflecting hot electrons emitted from the cathode of the CRT.

On the other hand, while the horizontal output transistor of the horizontal deflection portion is turned on, the B + voltage of the DC-DC converter 130 flows through the primary winding of the FBT, and when the horizontal output transistor is turned off, current flows in the secondary winding. Since the high voltage is induced to the secondary side according to the on-off duty ratio of the transistor, the voltage is rectified to generate the anode voltage, focus voltage, and screen voltage required by the CRT.

In addition, the current flowing through the anode (anode current) increases and decreases according to the brightness of the screen. If the screen becomes too bright, harmful electromagnetic waves are generated, causing harm to the user, and shortening the lifetime of the CRT. An automatic brightness limit (ABL) circuit is connected to the secondary winding of the FBT.

As such, the automatic luminance limiting (ABL) circuit for protecting the CRT is a resistor (R7, R8) connected to a winding that provides a high voltage to the CRT anode and detects a voltage according to the variation of the anode current. It increases as it increases, and as it decreases as the anode current decreases.

In addition, the anode current detector 230 according to the present invention detects a change in the anode current as a voltage by the resistor R7 and the resistor R8 connected to the high voltage winding. In this case, the resistor R7 is about 4.7K ohms and the resistor R8 is about 120K ohms. The X-ray signal generator 220 according to the present invention is connected to the common connection point of the resistor.

The X-ray signal generator 220 according to the present invention is a zener diode (ZD21) and a resistor (R23) connected in series, the emitter is connected to a 12V power supply, the collector is horizontal through the resistor (R21) The PNP transistor Q22 is connected to the X-ray terminal of the vertical IC 210.

If the screen is brightened and the anode current increases, the detection voltage of the ABL circuit is lowered. Accordingly, the base voltage of the PNP transistor Q22 is lowered to turn on the PNP transistor Q22. When the PNP transistor Q22 is turned on, 12V connected to the emitter terminal is connected to the X-ray terminal of the horizontal vertical IC 210 through the resistor R22 and the resistor R21. At this time, the anode current detection voltage should be able to conduct the zener diode ZD1. If the capacitance of the zener diode is properly selected, the X-ray operation point according to the detection voltage can be set.

When the X-ray signal is input, the horizontal vertical IC 210 cuts off the horizontal driving pulse. Accordingly, the output transistor of the horizontal deflection unit 150 is continuously turned off to stop the high voltage generation on the FBT. The horizontal vertical IC 210 can be easily purchased on the market in various forms. For example, the horizontal vertical IC 210 may be provided as an independent single chip, and may be divided into horizontal and vertical ICs, and may be integrated with a video preamplifier. .

In the embodiment of the present invention, the X-ray signal is activated when it is 'high' to block the output of the horizontal driving signal, but may be designed to be activated at a low level.

As described above, when the anode current increases above a certain value according to the present invention, after detecting it using an automatic luminance limiting (ABL) circuit, an X-ray signal is generated and a horizontal vertical IC 210 is applied. When the X-ray signal is input, the horizontal oscillation is stopped to activate the X-ray cutoff function to temporarily stop the operation of the CRT, thereby protecting the CRT from overcurrent.

Claims (2)

In response to the driving signal provided from the horizontal oscillator, the horizontal output transistor switches the B + voltage to apply the high voltage induced through the FBT to the anode of the CRT. When the X-ray signal is input, the horizontal oscillator stops oscillation. Accordingly, in the monitor in which switching of the B + voltage is stopped and high voltage generation is stopped, Anode current detecting means 230 for detecting an increase in anode current; And X-ray signal generating means 220 for providing an X-ray signal to the horizontal oscillator in accordance with the detection voltage of the anode current detection means CRT protection circuit in a monitor to increase the anode current to prevent the screen from becoming too bright or X-rays. The method of claim 1, wherein the X-ray signal generating means 220 is connected in series with a zener diode (ZD21) and a resistor (R23) is connected to the base, the emitter is connected to a 12V power supply, the collector is connected through a resistor (R21) CRT protection circuit for a monitor, characterized in that consisting of a PNP transistor (Q22) connected to the X-ray end of the horizontal vertical IC (210).