KR20020009294A - The control circuit of high voltage part by brightness of monitor in video display appliance - Google Patents

Abstract

PURPOSE: A circuit for controlling a high-voltage output part according to screen brightness of an image display device is provided, the circuit which controls drive conditions of a high-voltage output transistor according to brightness of screen to allow the high-voltage output transistor to perform optimum switching operation by beam current of a CRT. CONSTITUTION: A circuit for controlling a high-voltage output part according to screen brightness of an image display device includes a horizontal drive circuit for receiving a horizontal drive signal to output the signal to a horizontal output part, and a horizontal deflection yoke for accepting a signal output when the horizontal output part is on to perform horizontal deflection. The circuit further has a high-voltage drive circuit(4) for receiving a control signal from a drive controller to output the control signal to a high-voltage output part(5), an FBT(6) for accepting voltage of a power supply when the high-voltage output part is on and for boosting the voltage to provide boosted voltage to the anode of a CRT, and a current detector(8) for detecting beam current of the CRT. The circuit also has a drive controller(9) for receiving the detected beam current signal to control the high-voltage output transistor to have optimum operation conditions in case of switching operation.

Description

The control circuit of high voltage part by brightness of monitor in video display appliance}

The present invention relates to a high-voltage output control circuit according to the screen brightness of the image display device, by controlling the drive conditions of the high-voltage output transistor in accordance with the brightness of the screen, the high-voltage output transistor is the optimum switching operation by the beam current of the CRT To do it.

Referring to FIGS. 1 and 2, a configuration and an operation of a control circuit of a high voltage output unit according to a screen brightness of a conventional video display device are as follows.

1 is a block diagram of a circuit in which a conventional horizontal output unit and a high voltage output unit are separated.

A horizontal drive circuit unit 1 for receiving a horizontal drive signal HD from a deflection drive IC (not shown) to drive the horizontal output unit 2;

A horizontal output unit 2 for supplying a deflection current to the deflection yoke 3 by performing an on / off switching operation according to a driving pulse output from the horizontal drive circuit unit 1;

A high voltage drive circuit part 4 for receiving a horizontal drive signal HD from a deflection drive IC to drive the high voltage output part 5;

A high voltage output unit 5 for performing on / off switching operation by a signal output by a driving pulse of the high voltage drive circuit unit 4;

It is composed of FBT (Fly back trans) 6 which receives a voltage applied according to the switching operation of the high voltage output unit 5 and generates a high pressure by a predetermined turn ratio.

The unexplained CRT 7 is a CRT.

In order to drive the horizontal deflection yoke 3, the horizontal drive circuit 1 supplied with the horizontal drive signal HD from the deflection drive IC supplies the drive signal required by the horizontal output unit 2.

The horizontal output unit 2 performs a horizontal deflection by supplying a signal to the horizontal deflection yoke 3 during the on / off switching operation and the on operation by the drive signal output from the horizontal drive circuit 1.

In addition, the high voltage drive circuit 4 that receives the horizontal drive signal HD from the deflection drive IC to supply the high pressure to the CRT 7 supplies the driving signal required by the high voltage output unit 5.

The high voltage output unit 5 supplies a signal to the primary side of the FBT 6 during the on / off switching operation and the on operation by the drive signal output from the high voltage drive circuit 6.

In the FBT 6, the signal input to the primary side is boosted to a high pressure by a predetermined number of turns ratio and applied to the anode of the CRT 7.

In general, the high-voltage drive circuit 4 includes the in-phase drive system in which the output stage is turned on when the drive stage is on, and the reverse phase drive system in which the output stage is turned off when the drive stage is on. Uses a lot of anti-phase drive,

Detailed configuration and operation of the high voltage drive circuit 4 and the high voltage output unit 5 will be described below with reference to the circuit diagram of FIG. 2.

2 is a circuit diagram of a conventional high voltage drive and a high voltage output unit.

A high voltage drive transistor Q1 receiving a horizontal drive signal HD output from a deflection drive IC as a base and performing a selective on / off switching operation;

A horizontal drive transformer T1 for outputting a signal opposite to the signal applied to the primary side by the antiphase drive method to the secondary side;

The high voltage output transistor Q2 receives a signal supplied from the horizontal drive transformer T1 as a base and performs a selective on / off switching operation.

Reference numerals R1 to R3 denote resistors, D1 denotes diodes, C1 denotes capacitors, and Ic and Ib2 denote collector currents and base currents of the high voltage output transistor Q2, respectively.

When the transistor Q1 is turned on by the horizontal drive signal HD output from the deflection drive IC, the voltage dropped through the resistor R1 at the power supply voltage terminal B + is the primary side of the horizontal drive transformer T1. It is input through the collector terminal of the high voltage drive transistor Q1 and biased to the ground of the emitter terminal.

At this time, the ON signal is induced on the primary side of the horizontal drive transformer T1 by the ON operation of the high voltage drive transistor Q1. However, the OFF signal is applied to the secondary side of the horizontal drive transformer T1 because the reverse phase drive method is used. Become organic.

Therefore, the high voltage output transistor Q2 is also turned off so that the off signal is applied to the primary side of the FBT 6, so that the high voltage is not supplied to the anode end of the CRT 7.

In contrast, when the horizontal drive signal HD is not generated in the deflection drive IC, the transistor Q1 is turned off, and the ON signal is induced on the secondary side of the horizontal drive transformer T1.

Accordingly, the high voltage output transistor Q2 is turned on so that the power supply voltage from the power supply voltage terminal B + is input to the collector terminal of the transistor Q2 via the primary side of the FBT 6 and biased to the ground of the emitter terminal.

The ON signal is applied to the primary side of the FBT 6 by the ON operation of the high voltage output transistor Q2, and the voltage is boosted by the set number of turns. The output is supplied to the secondary side and the high voltage is supplied to the anode terminal of the CRT 7.

The high voltage output transistor Q2 generally uses a power transistor. Since the DC current gain varies with the change of the collector current, the high voltage output transistor Q2 maintains the optimal switching operation of the high voltage output transistor Q2. To do this, the base current Ib2 should be controlled when the collector current Ic changes, that is, when the beam current of the CRT 7 changes.

In the case where the horizontal output unit 2 and the high voltage output unit 5 are driven separately, the collector current Ic of the high voltage output transistor Q2 fluctuates greatly depending on the brightness of the screen. There is a problem in that the driving conditions of the high voltage output transistor Q2 must be reset according to the beam current.

Accordingly, in the present invention, it is possible to detect the beam current of the CRT and to control the driving conditions of the high voltage output transistor according to the detected beam current change, thereby improving the inconvenience of having to reset the driving conditions of the high voltage output transistor according to the beam current. In addition, the high voltage output transistor can maintain the optimum switching operation regardless of the change in the beam current.

1 is a block diagram of a circuit in which a conventional horizontal output unit and a high voltage output unit are separated.

2 is a circuit diagram of a conventional high voltage drive and a high voltage output unit.

3 is a graph showing the relationship between collector current and DC current gain of a horizontal output transistor;

4 is a block diagram of a circuit in which the horizontal output unit and the high voltage output unit of the present invention are separated.

5 is a circuit diagram showing an embodiment of a high voltage drive and a high voltage output circuit of the present invention.

The present invention outputs the drive signal of the high-voltage output transistor in accordance with the beam current of the CRT to have the optimum operating conditions during the switching operation of the high-voltage output transistor,

The configuration and operation of the present invention will be described with reference to the same reference numerals with reference to Figures 3 to 5 as follows.

4 is a block diagram of a circuit in which the horizontal output unit and the high voltage output unit of the present invention are separated.

A horizontal drive circuit unit 1 for receiving a horizontal drive signal HD from a deflection drive IC and outputting the horizontal drive signal HD to a horizontal output unit 2;

A horizontal output unit 2 performing on / off operation by a signal output from the horizontal drive circuit unit 1;

A horizontal deflection yoke (3) for receiving a signal output during the on operation of the horizontal output unit (2) and performing horizontal deflection;

A horizontal drive signal HD output from the deflection drive IC, a control signal output from the drive control section 9, and a high voltage drive circuit section 4 for outputting to the high voltage output section 5;

A high voltage output unit 5 for performing on / off operation by a signal output from the high voltage drive circuit unit 4;

During the on-operation of the high voltage output transistor Q2, the voltage of the power supply voltage terminal B + is input to the primary side, and the voltage is boosted by the predetermined number of turns ratio to be output to the secondary side, and supplied to the anode terminal of the CRT. Generator (FBT) 6,

A beam current detector 8 for detecting a beam current of the CRT 7,

The drive controller 9 is configured to receive the beam current signal sensed by the beam current detector 8 and to control an optimal operating condition during the switching operation of the high voltage output transistor Q2.

The high voltage drive circuit 4 includes a high voltage drive transistor Q1 that receives a horizontal drive signal HD supplied from a deflection drive IC as a base and performs a selective on / off switching operation.

It includes a horizontal drive transformer T1 for outputting a predetermined voltage to the secondary side by operating the power supply voltage B + applied to the primary side in reverse phase with respect to the switching operation of the high voltage drive transistor Q1.

The high voltage output unit 5 includes a high voltage output transistor Q2 that receives a signal supplied from the horizontal drive transformer T1 as a base and performs a selective on / off switching operation.

The beam current detector 8 is configured to supply the resistors R7, R8, and R9 for detecting the beam current flowing to the secondary side of the FBT 6 and the detected beam current as a detection signal DS. Resistors R5 and R6.

Reference numeral I denotes a current flowing in the primary side of the horizontal drive transformer T1, R1 to R4 are resistors, D1 is a diode, and C1 to C2 are capacitors.

In order to drive the horizontal deflection yoke 3, the horizontal drive circuit 1 supplied with the horizontal drive signal HD from the horizontal drive IC supplies the drive signal required by the horizontal output unit 2.

The horizontal output unit 2 supplies a signal to the horizontal deflection yoke 3 during the on / off operation and the on operation by the drive signal output from the horizontal drive circuit 1 so that horizontal deflection is achieved.

In addition, the high voltage drive circuit 4 that receives the horizontal drive signal HD from the horizontal drive IC in order to supply the high pressure to the CRT 7 supplies the driving signal required by the high voltage output unit 5.

The high voltage output unit 5 supplies a signal to the FBT 6 during the on / off operation and the on operation by the drive signal output from the high voltage drive circuit 6.

In the FBT 6, the signal input by the predetermined number of turns ratio is boosted to a high pressure and applied to the anode of the CRT 4.

The beam current detector 8 detects the beam current of the CRT 7 and supplies the detected signal to the drive controller 9.

The drive controller 9 receives the signal sensed by the beam current detector 8 to control to have an optimal operating condition during the switching operation of the high voltage output transistor Q2, and transmits a control signal to the high voltage drive circuit 4. Output

A detailed description of the high voltage drive circuit 4, the high voltage output unit 5, the beam current detection unit 8, and the drive control unit 9 will be described with reference to FIG. 5.

Detects the beam current of the CRT (7) and outputs a drive signal of the high voltage output transistor (Q2) in accordance with the beam current of the CRT (7) to have the optimum operating conditions during the switching operation of the high voltage output transistor (Q2),

An example will be described with reference to FIG. 3.

The formula for calculating the base current Ib2 of the high voltage output transistor Q2 is as follows.

Ib2 = Ic / Hfe (Hfe: DC current gain)

If the base current Ib2 is set when the collector current Ic of the high voltage output transistor Q2 is 2.5A, since the DC current gain Hfe is 10 in the graph of FIG. 3, the base current Ib2 is represented by Equation 1 above. Becomes 0.25A.

When the collector current Ic is 3.5A, the DC current gain Hfe is 6, so the base current Ib2 is 0.58A.

When the collector current Ic is 3.5A, that is, when the beam current of the CRT 7 increases and the screen is bright, the resistance R1 is adjusted so that the base current Ib2 becomes 0.58A. If the current I flowing in the primary side of the horizontal drive transformer T1 is set, the resistors R5 and R6 are set such that the level of the detection signal DS output from the beam current sensing unit 8 becomes low. Set.

When the level of the sense signal is low, transistor Q3 is turned off to increase the current at the primary side of horizontal drive transformer T1 and increase the current Ib2 at the base end of high voltage output transistor Q2 to output a high voltage. The transistor Q2 is prevented from underdrive.

On the contrary, when the collector current (Ic = 2.5A), that is, when the screen is dark, the beam current detection signal DS is divided by the set resistors R5 and R6 and then applied to the base terminal of the transistor Q3. When a high signal is applied, the transistor Q3 is turned on, which reduces the current on the primary side of the horizontal drive transformer T1 and reduces the base current of the high voltage output transistor Q2 on the secondary side of the horizontal drive transformer T1. This reduces the voltage to prevent the high voltage output transistor Q2 from being overdriven.

6 is another embodiment of the present invention, in which the transistor Q3 of FIG. 5 senses a current flowing in the secondary side of the FBT 6 and is operated when the current flows over a predetermined current, thereby operating on the primary side of the horizontal drive transformer T1. It can be replaced by a switch (S / W) that increases the current and operates off when less than any current flows, reducing the current on the primary side of the horizontal drive transformer T1.

As described above, a means for detecting the beam current of the CRT and a drive signal control means is provided to supply the detected beam current to the drive signal controller, and outputs the drive signal of the high voltage output transistor according to the beam current of the CRT to output the high voltage output transistor. To have an optimal operating condition during the switching operation.

Claims (4)

A horizontal drive circuit unit for receiving a horizontal drive signal from a deflection drive IC and outputting the horizontal drive signal to a horizontal output unit, a horizontal output unit performing an on / off operation by a signal output from the horizontal drive circuit unit, and the horizontal output unit On / off by a horizontal deflection yoke that receives a signal output during the on operation and performs a horizontal deflection, a high voltage drive circuit part that receives a control signal output from the drive controller and outputs it to a high voltage output part, and a signal output from the high voltage drive circuit part. FBT which turns off the high voltage output unit which performs the off operation and the voltage of the power supply voltage terminal to the primary side during the on operation of the high voltage output transistor, boosts it by the predetermined turn ratio and outputs it to the secondary side, and supplies it to the anode end of the CRT. A beam current detector for detecting a beam current of the CRT, and a beam detected by the beam current detector Receiving the input current signal according to the brightness of the screen of video display devices, characterized by consisting of a drive control unit for controlling so as to have the best operating conditions when the switching operation of the high-voltage output transistor high voltage output control circuit. The method of claim 1, wherein the beam current detector comprises resistors R7, R8, and R9 for detecting beam current flowing to the secondary side of the FBT, and resistors for supplying the detected beam current as a detection signal DS. R5, R6) comprising a high voltage output control circuit according to the screen brightness of the video display device. The control unit of claim 1, wherein the drive controller includes a transistor Q3 that receives the detection signal DS at a base end and performs an on / off switching operation. Circuit. 2. The drive controller of claim 1, wherein the drive controller senses a current flowing in the secondary side of the FBT to operate when the current flows above a predetermined current to increase the current at the primary side of the horizontal drive transformer and to operate when the current flows less than the current to the horizontal. High voltage output control circuit according to the screen brightness of the video display device including a switch (Switch) to reduce the current on the primary side of the drive transformer.