KR200159231Y1 - Beam current control circuit in crt - Google Patents

Abstract

In the present invention, in the CRT of the video reproducing apparatus, when the vertical drive stage is defective, the beam current flows excessively to the deflection coil, thereby preventing damage to the neck of the CRT. To control.

The present invention is a vertical drive IC that selectively generates a vertical synchronization signal according to the abnormality of the vertical circuit,

A detector for detecting a vertical synchronization signal;

A smoothing unit for smoothing the vertical synchronization signal detected by the detecting unit;

The signal smoothed in the smoothing unit is made by providing a drive unit for generating a control signal of the sand castle for controlling the beam current.

Description

CRT's Beam Current Control Circuit

In the present invention, in the CRT of the video reproducing apparatus, when the vertical drive stage is defective, the beam current flows excessively to the deflection coil, thereby preventing damage to the neck of the CRT. The present invention relates to a beam current control circuit of a CRT.

As shown in FIG. 1, the vertical drive IC LA7845 using the positive power supply and the BTL method displays the beam current generated by the RGB drive IC 3 when the vertical drive IC 2 fails. There was a problem that the neck of the CRT 1 was damaged by maintaining the deflection concentrated at the top or bottom of the neck portion.

In other words, if a defect occurs in the vertical drive IC 2, the vertical deflection is maintained at the top or the bottom, and the CRT beam current is concentrated at the neck area, causing damage.

In the conventional vertical drive IC 2, when the normal deflection is made, as shown in FIG. 2, the upper deflection of the vertical deflection controls the current flowing through the transistor Q1, so that the transistor Q1 and the deflection coil DY at + 13.5V. ) To ground (GND) to deflect.

At this time, no current flows through the transistor Q2.

The lower screen deflection controls the current flowing through the transistor Q2. At this time, -13.5 V flows from the ground GND to the transistor Q2 through the deflection coil DY, and normal deflection is performed.

However, when the + side reference voltage of the op amp 4 changes, the DC of the vertical synchronous signal input on the negative side changes, or a failure of the op amp 4 occurs, a constant voltage is applied to the base of the transistors Q1 and Q2. The current I1 or the electric current I2 flows in a constant manner.

If the current I1 flows constantly, the beam current is concentrated in the upper part of the neck of the CRT 1 to damage the neck part.

When the current I2 flows constantly, the beam current is concentrated under the neck of the CRT 1 to damage the neck portion.

As such, the vertical circuit using the bi-electric power supply method or the BTL method damages the neck portion of the CRT when an abnormality occurs.

However, in the vertical circuit configured as shown in FIG. 3 and using a single power supply, the CRT neck portion is not damaged.

This is because the deflection coil DY and the condenser C are connected in series so that a constant current, that is, DC does not flow even when the DC or reference voltage of the vertical synchronous signal is changed or the op amp 5 is defective. .

This is because the vertical circuit used by both power supplies can control the vertical movement being used by the microcomputer control, even though the neck portion of the CRT can be damaged compared to the single power supply method.

The present invention eliminates the problem of damaging the neck part of the CRT by concentrating the beam current by determining whether there is a vertical synchronizing signal in a vertical circuit using both power sources. If no sync signal is detected, the beam current is blocked to prevent damage to the CRT neck.

In addition, the present invention is the image to the top If it is moved abnormally, the image is blanked as much as possible to prevent damage of the CRT neck.

The present invention is a vertical drive IC that selectively generates a vertical synchronous signal according to the abnormality of the vertical circuit,

A detector for detecting a vertical synchronization signal;

A smoothing unit for smoothing the vertical synchronization signal detected by the detecting unit;

The signal smoothed in the smoothing unit is made by providing a drive unit for generating a control signal of the sand castle for controlling the beam current.

In addition, the present invention provides a phase shift detector for detecting phase shift by inputting a vertical synchronization signal generated from a vertical drive IC;

And a blanking signal generator for generating a blanking signal according to the detection signal of the phase shift detector and applying a sandcastle control signal for controlling the beam current.

1 is an explanatory diagram of a CRT failure state of the present invention

2 is a circuit diagram of a conventional vertical drive IC.

3 is a conventional vertical power supply vertical circuit diagram

4 is a beam current control circuit diagram of the present invention;

5 is a waveform diagram of each part of FIG. 4.

6 is a beam current control circuit diagram of the present invention;

7 is a waveform diagram of each part of FIG. 6.

8 is an implementation circuit diagram of the present invention.

Explanation of symbols for main parts of the drawings

1: CRT 2: Vertical Drive IC

4,5 op amp 10: detector

20: smoothing part 30: drive circuit

40: phase shift detection unit 50: blanking signal generation unit

4 is a beam current control circuit diagram of the present invention,

A detection unit 10 for detecting the presence of a vertical synchronization signal,

Smoothing unit 20 for smoothing the vertical synchronization signal to a DC voltage,

The smoothed DC voltage is composed of a drive circuit 30 for applying a sandcastle voltage, and a vertical synchronization signal applied to the detector 10 is generated by the vertical drive IC LA7845.

The vertical drive IC (LA7845) is provided with a pump up circuit for vertical return, and the pump up circuit is not operated when an error occurs in the vertical circuit and thus does not generate a vertical synchronization signal.

As a result, the vertical drive IC generates a vertical synchronization signal only when the vertical circuit is normal.

The vertical synchronization signal generated from the vertical drive IC is applied to the detection unit 10 including the capacitor C11, the resistors R11-R13, and the transistor Q11.

The normal vertical synchronization signal is applied as shown in (A) of FIG. 5, and the vertical synchronization signal is not applied as shown in FIG.

When the normal vertical synchronization signal is applied as shown in (A) of FIG. 5, the detection unit 10 outputs the detection signal as shown in FIG. 5B, and the vertical synchronization signal as shown in FIG. 5A is not applied. In this case, the signal is detected as shown in FIG.

The detection signal of the detection unit 10 is applied to the smoothing unit 20 composed of the resistors R21 (R22) and the capacitor C21, smoothed to a DC voltage, and applied to the transistor Q31 base of the drive circuit 30. do.

The smoothing unit 20 applies a DC voltage as shown in FIG. 5C when a normal vertical synchronous signal is input, and applies a voltage of 0 V as shown in FIG. 5C when a vertical synchronous signal is not applied.

The driving of the transistor Q31 is selected by the DC voltage of the smoothing unit 20, and the output of the transistor Q31 is applied as the sandcastle voltage of the control IC TDA4780.

The control IC TDA4780, when the sandcastle voltage applied from the transistor Q31 is H, blanks the RGB output as shown in FIG. 5 (d) so that electrons are not emitted from the cathode of the cathode tube, thereby concentrating on the neck portion of the cathode tube. This eliminates damage to the CRT neck.

Contrary to the above, the control IC TDA4780 normally outputs the R.G.B output as shown in FIG. 5 (D) when the sandcastle voltage applied from the transistor Q31 is L to allow normal screen display.

Therefore, when an abnormality occurs in the vertical circuit, the beam current may be blocked to prevent damage to the neck portion of the CRT.

On the other hand, burns up Since the neck portion of the CRT is damaged even when it is moved abnormally, the present invention reduces the neck portion damage of the CRT by providing a circuit as shown in FIG. 6 and blanking as much as the image is moved upward.

6 is a beam current control circuit diagram of the present invention, and comprises a phase shift detection unit 40 for detecting an image shift and a blanking signal generator 50 for generating a blanking signal for blanking by phase shift.

The vertical synchronization signal applied to the transistor Q41 base of the phase shift detection unit 50 is applied as shown in FIG. 7A when it is normal and as shown in FIG. 7A when the image is shifted upward.

As shown in (a) of FIG. 7, the phase shifting unit 40 detects an x portion, which is a phase shifting part, and is normally detected as shown in FIG. 7B and there is a phase shift in FIG. 7. detected as b).

At this time, the smaller the phase shift, the narrower the pulse width shown in FIG. 7B, and the larger the phase shift, the wider the pulse width.

The pulse detected by the phase shift detector 40 is applied as a sandcastle voltage through a blanking signal generator 50 composed of transistors Q51, resistors R51, R52, and diodes D51.

Therefore, the sandcastle voltage applied from the blanking signal generator 50 to the control IC TDA4780 is normally narrow in H voltage and wide in H voltage when there is phase shift. Therefore, blanking is performed to the part having phase shift in the control IC. By blocking the beam current concentrated on the neck part of the CRT, the neck part of the CRT is not damaged.

In other words, normal operation waveform is applied as shown in (C) of FIG. 7 and normal operation waveform is applied when there is phase shift, thereby blanking the phase shifting portion to reduce neck portion damage of the CRT. .

8 is an embodiment of the present invention,

When the vertical synchronous signal is not applied or the phase is moved upward by the abnormality of the vertical circuit, when the beam current is concentrated on the neck portion of the CRT, the vertical synchronous signal is sensed to cut off the beam current, thereby minimizing damage to the CRT neck portion.

The present invention significantly reduces the damage to the CRT neck due to the concentration of the beam current by eliminating the beam current concentrated on the neck portion of the CRT by interrupting the beam current in the event of vertical circuit failure or image skew.

Claims (3)

First beam current limiting means for detecting the presence of vertical synchronization applied from the vertical drive IC and applying the same to the sandcastle voltage for controlling the beam current; And a second beam current limiting means for detecting a vertical synchronous signal applied from the vertical drive IC and applying a vacant current to the sandcastle voltage blanking as much as the phase shift. In claim 1, The first beam current limiting means includes a detector 10 for detecting the presence or absence of a vertical synchronization signal of the vertical drive IC; A smoothing unit 20 for smoothing the signal detected by the detecting unit with a DC voltage; And a drive circuit (30) for limiting the beam current by applying the DC voltage of the smoothing portion to the sandcastle voltage. In claim 1, The second beam current limiting means includes a phase shift detector 40 which detects phase shift by inputting a vertical synchronization signal generated from the vertical drive IC 2; And a blanking signal generator (50) for generating a blanking signal according to the detection signal of the phase shift detector (40) to apply a sandcastle control signal for controlling the beam current.