KR100239124B1 - Screen stabilizing circuit on generating over voltage - Google Patents

Abstract

The present invention relates to a screen stabilization circuit in the event of a high pressure of the monitor, in particular to stabilize the screen by removing the current beam concentration phenomenon (spot phenomenon) appearing on the monitor screen when the X-ray (X-ray) protection circuit is operated to prevent the high voltage rise It relates to a screen stabilization circuit when a high voltage of the monitor is generated.

However, in the conventional monitor screen stabilization circuit, when the X-ray emission state due to the high voltage rise occurs, the protection circuit operates to prevent the high pressure rise, which causes a problem of electron beam concentration (spot) phenomenon on the screen.

Accordingly, the present invention eliminates the spot phenomenon by suppressing the electron beam current by outputting a negative voltage to the grid terminal (G1) of the CRT by detecting the spot phenomenon generated by the high pressure to solve the conventional problems as described above Its main purpose is to allow users to improve the reliability of their products.

Description

Screen stabilization circuit in case of high voltage of monitor

The present invention relates to a screen stabilization circuit in the event of a high pressure of the monitor, in particular to stabilize the screen by removing the current beam concentration phenomenon (spot phenomenon) appearing on the monitor screen when the X-ray (X-ray) protection circuit is operated to prevent the high voltage rise It relates to a screen stabilization circuit when a high voltage of the monitor is generated.

As shown in FIG. 1, the conventional monitor screen stabilization circuit includes a video signal output unit 11 for outputting a video signal, and a cathode ray tube (CRT) (video signal output from the video signal output unit 11). Converts the buffer unit 12 output to the cathode terminal K of FIG. 13, the screen brightness adjusting unit 14 for adjusting the screen brightness of the CRT 13, and the input horizontal frequency f _h into voltage. A frequency (F) / voltage (V) converter 15, a comparator 16 for comparing the voltage output from the F / V converter 15 with a reference voltage, and the comparator 16 The differential terminal 17 which differentially outputs the output signal compared with the differential signal, and the negative voltage which is switched by the signal output from the differentiator 17 and output from the flyback transformer FBT are supplied to the grid terminal G1 of the CRT 13. It consists of a switching unit 18 for outputting to.

Reference numerals R1 to R8 are resistors, C1 to C3 are capacitors, and D1 is diodes.

Operation of the conventional monitor screen stabilization circuit configured as described above will be described with reference to FIG.

First, the horizontal frequency f _h is converted into a voltage by the frequency (F) / voltage (V) converter 15 and output to the comparator 16, and the comparator 16 has an F / V converter ( When the voltage output from 15) is higher than the reference voltage, the high signal is output to the differentiator 17 when the high signal is lower than the reference voltage.

At this time, when the high signal is output from the comparator 16, the differentiator 17 differentiates the high signal and outputs it to the transistor Q1 of the switching unit 18, and the transistor Q1 is the differentiator 17. The video signal is controlled by applying the negative voltage (-100V), which is turned on by the signal differentiated from and output from the flyback transformer (FBT), to the grid terminal G1 of the CRT 13 to adjust the grid voltage of the CRT 13. When the video signal output from the output unit 11 is displayed on the CRT 13, a mute phenomenon may be generated to prevent a transient phenomenon in which the synchronization of the screen is broken.

In addition, when the low signal is output from the comparator 16, the differentiator 17 differentiates the low signal and outputs it to the transistor Q1, and the transistor Q1 is differentiated by the signal differentiated from the differentiator 17. Since the negative voltage (-100V) which is turned off and output from the flyback transformer FBT is not output to the grid terminal G1 of the CRT 13, the video signal output from the video signal output unit 11 is normally a CRT ( 13) is displayed.

However, in the conventional monitor screen stabilization circuit, when the X-ray emission state due to the high pressure rises, the protection circuit operates to prevent the high pressure rise, which causes a problem of electron beam concentration (spot) phenomenon on the screen.

Accordingly, the present invention eliminates the spot phenomenon by suppressing the electron beam current by outputting a negative voltage to the grid terminal (G1) of the CRT by detecting the spot phenomenon generated by the high pressure to solve the conventional problems as described above Its main purpose is to allow users to improve the reliability of their products.

1 is a block diagram showing the configuration of a conventional monitor screen stabilization circuit

Figure 2 is a block diagram showing the configuration of the screen stabilization circuit when the high pressure of the monitor of the present invention

Figure 3 (a) to (e) is the output waveform diagram of each part in the present invention

As shown in FIG. 2, the configuration of the screen stabilization circuit in the high voltage generation of the monitor according to the present invention for achieving the above object includes a flyback pulse generator 21 for generating a flyback pulse and the flyback pulse generator 21. The flyback pulse generated by the high voltage detector 22 is raised due to the abnormal high pressure, and the deflection circuit unit 23 generates a mute signal by the high voltage detected by the high voltage detector 22 to stop the deflection. And a high pressure detection and mute generation unit 24 for generating a mute signal by recognizing the horizontal synchronous signal input by the high voltage detected by the high voltage detection unit 22 as a power saving mode (DPM), and the high pressure detection and muting generation. The grid control unit 25 is configured to output a negative voltage to the grid terminal G1 of the CRT 26 by the mute signal generated by the unit 24 to eliminate spot phenomenon.

The high pressure detector 22 includes a diode D1 and a capacitor C1 for smoothing the flyback pulses generated by the flyback pulse generator 20, a voltage divider resistor R1, and a rectifier. A diode D2, a zener diode ZD2 for detecting whether a high voltage is detected, a capacitor C3, and a resistor R4 are configured, and the deflection circuit section 23 is configured to generate a mute signal. And a vertical signal processor 23a and a horizontal / vertical deflection circuit 23b for deflecting the electron beam. The high pressure detection and mute generator 24 includes a zener diode ZD1 for detecting whether the high pressure is detected and a condenser. (C2), the resistor (R3) and the transistor (Q1) to be turned on or off depending on whether the high voltage is detected to convert the horizontal signal into a low signal, and the horizontal signal converted into a low signal by the transistor (Q1) power saving The microcomputer 24a includes a microcomputer 24a that recognizes the mode signal and generates a mute signal.

The operation and effect of the screen stabilization circuit when the high pressure of the monitor of the present invention configured as described above will be described with reference to FIGS. 2 and 3.

First, a flyback pulse is generated in the flyback pulse generator 21, and the flyback pulse is divided by the resistors R1 and R2 through the diode D1. When the X-ray emission condition occurs, the flyback pulse rises as shown in (a) waveform of FIG.

That is, the flyback pulses raised to the abnormal high voltage are smoothed through the diode D1 and the condenser C1, and the smoothed DC voltage is divided by the resistors R1 and R2 to pass through the diode D2. High voltage such as (b) is output.

At this time, when the high voltage detected by the high voltage detector 22 rises above the set parameter value of the zener diode ZD2, the horizontal / vertical deflection circuit is operated by the high pressure detection (X-ray) terminal in the horizontal / vertical processor 23a. A mute signal as shown in Fig. 3C is output to 23b to stop the deflection of the horizontal / vertical deflection circuit 23b.

In addition, when the high voltage detected by the high voltage detector 22 rises above the set integer value of the control diode ZD1, the high voltage is applied to the base of the transistor Q1 through the resistor R3, and thus the transistor Q1 is used. Is turned on and the horizontal signal H-sync is converted into a low signal as shown in FIG.

Here, the set values of the zener diodes ZD1 and ZD2 should be set to a voltage value capable of driving the transistor Q1 at a voltage at which the high voltage detection terminal of the horizontal / vertical processor 23a starts to operate.

On the other hand, when the microcomputer 24a receives the horizontal signal converted into the low signal and recognizes it as the power saving mode (DPM) and outputs a mute signal as shown in FIG. 3C to the grid G1 controller 25, The grid control unit 25 applies a DC voltage of about -120 to -200V to the grid terminal G1 of the CRT 26 by a mute signal, as shown in FIG. By suppressing the current, spot phenomenon appearing on the screen during the operation of the high voltage protection circuit can be eliminated.

When the high voltage of the monitor of the present invention acts as described above, the screen stabilization circuit detects the high voltage detected by the high voltage detector by applying a negative voltage to the grid electrode of the CRT, thereby eliminating a spot phenomenon appearing on the screen. There is an effect that can improve the reliability.

Claims (1)

A flyback pulse generator 21 for generating a flyback pulse, a high pressure detector 22 for raising a flyback pulse generated by the flyback pulse generator 21 due to an abnormal high pressure and detecting a high voltage; The deflection circuit unit 23 generates a mute signal by the high voltage detected by the high voltage detector 22 to stop the deflection, and a horizontal synchronous signal input by the high voltage detected by the high voltage detector 22 to save power. The negative voltage is generated by the high voltage detection and muting generator 24 for generating a mute signal and the mute signal generated by the high voltage detection and muting generator 24 to the grid terminal G1 of the CRT. Screen stabilization circuit during high pressure generation of the monitor, characterized in that the output consisting of a grid control unit 25 for removing spots.

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