KR100377224B1 - Method and circuit for power supply to cdt electron gun - Google Patents

Abstract

The present invention relates to a power supply circuit and a power supply method of a CDT electron gun. The power supply circuit according to the present invention includes a primary coil to which power is applied, a plurality of secondary coils for boosting a voltage applied to the primary coil to a desired high voltage, and a voltage applied to the secondary coil. A tertiary coil into which voltage is induced, a high voltage distribution resistor for dividing the voltage applied to the secondary coil, a focus voltage output terminal for supplying a voltage divided from the high voltage distribution resistor to a focus electrode of the electron gun, and the tertiary coil A power supply circuit for a CDT electron gun including an acceleration voltage output stage for supplying a voltage induced in the electron gun to an acceleration electrode of the electron gun. The power supply circuit of the CDT electron gun according to the present invention includes a focus voltage sensing unit for detecting a focus voltage of the focus electrode output terminal; An acceleration voltage sensing unit sensing an acceleration voltage of the acceleration electrode output terminal; And a voltage drop unit for lowering the acceleration voltage of the acceleration electrode output terminal when the focus voltage from the focus voltage detection unit is lower than the acceleration voltage from the acceleration voltage detection unit. As a result, leakage current generated in the CDT electron gun can be eliminated.

Description

Power supply circuit and power supply method of CDT gun {METHOD AND CIRCUIT FOR POWER SUPPLY TO CDT ELECTRON GUN}

The present invention relates to a power supply circuit and a power supply method of a CDT electron gun, and more particularly, to a power supply circuit and a power supply method of a CDT electron gun for removing the leakage current generated in the CDT electron gun.

CDT is an image reproducing apparatus that matches the time-signed synchronizing signal from the signal source with the image signal from the signal source, and emits the phosphor on the cathode ray tube surface to reproduce the image. In general CDT, electrons from three electron guns are accelerated by the high voltage (HV +) applied to the shadow mask according to the color to be displayed and collide with the fluorescent surface through the shadow mask to reproduce a predetermined image.

Here, the electron gun is provided with a control electrode for controlling the emitted electrons, an acceleration electrode for accelerating the electron beam controlled by the control electrode, and a focus electrode for accurately collecting the electron beam at one point.

A flyback transformer (FBT) for supplying a high pressure to the electron gun of the CDT and a circuit around the same are shown in FIG. 2.

In the circuit diagram shown in FIG. 2, a block indicated by a thick line is a circuit representing the FBT 110, a circuit at the upper left of the FBT 110 is an FBT driving circuit, and a lower left is a control electrode of the electron gun from the FBT 110. This circuit supplies power to G2).

The FBT driving circuit at the upper left of the FBT 110 allows the B + voltage to be applied to the FBT 110 by the on / off switching operation of the high voltage driving transistor 118. When the high voltage driving transistor 118 performs an on / off switching operation and the power is resonated by the resonant capacitor 120, the power is induced to the primary side coil 112, so that power is applied to the FBT 110. Accordingly, high voltage is induced in the secondary side coil 114 of the FBT 110 against the primary side coil 112 by electromotive force due to the power induced in the primary side coil 112.

The high voltage induced in the secondary side coil 114 is divided by a plurality of high voltage distribution resistors 122 to apply voltages to the first focus electrode G3 and the second focus electrode G4 of the electron gun, respectively.

On the other hand, due to the high pressure induced in the secondary side coil 114, the high pressure is induced in the tertiary side coil 116 facing the secondary side coil 114, and the voltage induced in the tertiary side coil 116. Is applied to the accelerating electrode G2 of the electron gun.

However, when a discharge phenomenon occurs in the CDT electron gun due to a foreign material such as dust, and a leakage current band is generated, the voltage applied to the electron gun fluctuates. In particular, the voltage applied to the focus electrodes G3 and G4 is interrupted. The voltage is likely to drop. When the voltage applied to the focus electrodes G3 and G4 drops, the screen becomes blurred and in severe cases, a rainbow-like phenomenon may be seen on the screen.

Therefore, it is an object of the present invention to eliminate the leakage current generated in the CDT electron gun.

1 is a power supply circuit of a CDT electron gun according to the present invention,

2 is a power supply circuit of a conventional CDT electron gun.

* Explanation of symbols for the main parts of the drawings

10: FBT 12: Primary side coil

14: secondary side coil 16: tertiary side coil

18: high voltage driving transistor 20: resonant capacitor

22: high pressure distribution resistance 24: rectification means

26: smoothing means G2: acceleration electrode

G3, G4: Focus electrode R1: Focus voltage detection resistor

R2: Acceleration voltage protection resistor D1, D2: Diode

The object is, according to the present invention, a primary coil to which power is applied, a plurality of secondary coils for boosting the voltage applied to the primary coil to a desired high pressure, and a voltage applied to the secondary coil. A tertiary coil into which voltage is induced, a high voltage distribution resistor for dividing the voltage applied to the secondary coil, a focus voltage output terminal for supplying a voltage divided from the high voltage distribution resistor to a focus electrode of the electron gun, and the tertiary coil A power supply circuit of a CDT electron gun including an acceleration voltage output terminal for supplying a voltage induced in the electron gun to an acceleration electrode of the electron gun, the power supply circuit comprising: a focus voltage sensing unit for detecting a focus voltage of the focus voltage output terminal; An acceleration voltage sensing unit sensing an acceleration voltage of the acceleration voltage output terminal; And a voltage drop for dropping the acceleration voltage of the acceleration electrode output terminal when the focus voltage from the focus voltage detection unit is lower than the acceleration voltage from the acceleration voltage detection unit. Achieved by the circuit.

Here, the focus voltage detecting unit can be a resistor provided in series with the high voltage distribution resistor.

The voltage drop unit is interposed between the acceleration electrode output terminal and the focus voltage detection unit, and is turned on when the focus voltage from the focus voltage detection unit is lower than the acceleration voltage from the acceleration voltage detection unit. It is preferable to simplify the circuit by using switching means for supplying the power of the voltage output stage to the focus voltage detection resistor.

Here, the switching means may use a diode.

In addition, it is preferable that an acceleration voltage protection resistor is provided at the acceleration voltage output terminal to protect the voltage output to the acceleration electrode.

On the other hand, according to another aspect of the present invention, a method for preventing leakage current of a CDT electron gun, the method comprising: detecting a focus voltage applied to a focus electrode of the CDT electron gun; Sensing an acceleration voltage applied to an acceleration electrode of the CDT electron gun; When the focus voltage is lower than the acceleration voltage, it is also achieved by the power supply method of the CDT electron gun, comprising the step of lowering the acceleration voltage of the acceleration electrode.

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

1 is a circuit diagram of an FBT and a peripheral circuit of a boost circuit of a CDT electron gun power supply circuit according to the present invention. In the circuit diagram shown in FIG. 1, a block indicated by a thick line is a circuit representing the FBT 10, a circuit at the upper left of the FBT 10 is an FBT driving circuit, and a lower left is a control electrode of the electron gun from the FBT 10. This circuit supplies power to G2).

The FBT driving circuit at the upper left of the FBT 10 causes the B + voltage to be applied to the FBT 10 by the on / off switching operation of the high voltage driving transistor 18. Since the high voltage driving transistor 18 performs on / off switching operation, the power is resonated by the resonant capacitor 20, and power is induced to the primary coil 12 so that power is applied to the FBT 10. Accordingly, high pressure is induced in the secondary side coil 14 of the FBT 10 against the primary side coil 12 by electromotive force due to the power induced in the primary side coil 12.

The high pressure induced in the secondary coil 14 of the FBT 10 is divided by a plurality of high voltage distribution resistors 22 and applied to the first focus electrode G3 and the second focus electrode G4 of the electron gun, respectively. do.

Further, due to the high pressure induced in the secondary side coil 14, the high pressure is also induced in the tertiary side coil 16 facing the secondary side coil 14, and the tertiary side coil 16 of the FBT 10. Induced voltage is applied to the acceleration electrode G2 of the electron gun via the rectifying means 24 for rectifying the high pressure pulse and the smoothing means 26 for converting the rectified high pressure pulse to DC. An acceleration voltage protection resistor R2 is interposed at the output terminal for applying power to the acceleration electrode G2 to protect the power applied to the acceleration electrode G2. At this time, the voltage applied to the acceleration electrode G2 is about 540V.

On the other hand, the secondary side of the FBT (10) is connected to the high-pressure distribution resistor 22 in series to apply a voltage to the focus electrodes (G3, G4) to divide the high voltage, power to each of the focus electrodes (G3, G4) To supply. At the end of the line where the high voltage distribution resistor 22 is connected in series, a focus voltage detection resistor R1 for detecting a voltage applied to the focus electrodes G3 and G4 is connected in series and connected to the focus voltage detection resistor R1. By measuring the voltage applied, the voltage applied to the focus electrodes G3 and G4 can be detected. When a normal voltage is applied, the voltage detected from the focus voltage detection resistor R1 is about 600V.

On the other hand, the line between the focus voltage detection resistor R1 on the secondary side of the FBT 10 and the voltage output line of the acceleration electrode G2 on the tertiary side of the FBT 10 are connected, and the focus voltage detection resistor is connected. Diodes D1 and D2 are interposed between the line where R1 is interposed and the output line of the acceleration electrode G2. Therefore, since the voltage of the focus voltage detection resistor R1 is higher than the voltage of the voltage output terminal of the acceleration electrode G2, the diodes D1 and D2 remain unconducted, so that the acceleration electrode G2 of the secondary side is maintained. No power is applied between the output line and the focus voltage detection resistor R1 on the tertiary side.

However, when a discharge phenomenon occurs in the CDT electron gun and a leakage current is generated therein, the high voltage drops. In particular, the voltage of the line to which the focus voltage is applied drops significantly, so that the voltages of the focus electrodes G3 and G4 decrease at several KV. Drops to several hundred volts. Accordingly, since the focus voltage sensed by the focus voltage detection resistor R1 is lower than the voltage of the output line of the acceleration electrode G2, the output terminal and the tertiary side of the acceleration electrode G2 on the secondary side of the FBT 10 are reduced. The diode interposed in the line connecting the line interposed with the focus voltage detecting resistor R1 is conducted. Therefore, the power supply to the acceleration electrode G2 side is applied toward the focus voltage detection resistor R1, so that the voltage supplied to the acceleration electrode G2 drops.

When the voltage supplied to the acceleration electrode G2 drops, the force for accelerating the electrons is momentarily weakened so that the leakage current band disappears. When the leakage current band disappears, the voltage applied to the focus electrodes G3 and G4 rises to a normal state, so that the voltage of the focus voltage detection resistor R1 increases. Accordingly, the diodes D1 and D2 are turned off again to recover a state in which power is not applied between the output line of the acceleration electrode G2 on the secondary side and the focus voltage detection resistor R1 line on the tertiary side.

By such a configuration, the leakage current generated in the CDT electron gun can be eliminated by sensing the states of the focus voltages G3 and G4 and adjusting the voltage applied to the control electrode G2.

As described above, according to the present invention, leakage current generated in the CDT electron gun can be eliminated.

Claims (7)

A primary coil to which power is applied, a plurality of secondary coils for boosting the voltage applied to the primary coil to a desired high voltage, a tertiary coil whose voltage is induced by the voltage applied to the secondary coil, A high voltage distribution resistor for dividing the voltage applied to the secondary coil, a focus voltage output terminal for supplying a voltage divided from the high voltage distribution resistor to a focus electrode of the electron gun, and a voltage induced in the tertiary coil to accelerate the electron gun In the power supply circuit of the CDT electron gun including an acceleration voltage output terminal for supplying to the electrode, A focus voltage detector for detecting a focus voltage of the focus voltage output terminal; An acceleration voltage sensing unit sensing an acceleration voltage of the acceleration voltage output terminal; And a voltage drop unit for lowering the acceleration voltage of the acceleration voltage output terminal when the focus voltage from the focus voltage detector is lower than the acceleration voltage from the acceleration voltage detector. Circuit. The method of claim 1, The voltage drop unit is interposed between the acceleration voltage output terminal and the focus voltage sensing unit, and is turned on when the focus voltage from the focus voltage sensing unit is lower than the acceleration voltage from the acceleration voltage sensing unit. And a switching means for supplying power to the focus voltage detection unit. The method of claim 1, And the focus voltage sensing unit is a resistor provided in series with the high voltage distribution resistor. The method of claim 2, And said switching means is a diode. The method of claim 1, The acceleration voltage output stage, the power supply circuit of the CDT electron gun, characterized in that the acceleration voltage protection resistor for protecting the voltage applied to the acceleration electrode is provided. In the leakage current prevention method of the CDT electron gun, Detecting a focus voltage applied to a focus electrode of the CDT electron gun; Sensing an acceleration voltage applied to an acceleration electrode of the CDT electron gun; And dropping the acceleration voltage of the acceleration electrode when the focus voltage is lower than the acceleration voltage. The method of claim 6, Dropping the acceleration voltage, And supplying power to the acceleration electrode to a line to which the focus power is applied.