KR20010064562A - Reset prevention circuit of television set for plasma display panel - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reset prevention circuit of PDTV. In the related art, a reset phenomenon occurs when power-on immediately after power-off because the capacity of a capacitor connected to the output terminal of the power factor correction unit is large. By resetting, there is a problem that it takes time until the TV comes out normally. Therefore, in the panel driving circuit of PDTV, a diode and a transistor are connected between a fault input terminal of a control circuit unit receiving a panel driving voltage generated by the panel driving voltage generator and a driving input terminal receiving an input voltage of a relay switch. When the power-on immediately after the power-off, including a reset prevention means to prevent the reset by holding the level of the voltage input to the fault input stage to a low level, to prevent the occurrence of a reset phenomenon, It is intended to be applicable to large TVs.

Description

RESET PREVENTION CIRCUIT OF TELEVISION SET FOR PLASMA DISPLAY PANEL}

The present invention is to prevent the TV from being reset when the power-on immediately after the power-off in the PDP TV, especially the reset phenomenon caused by a capacitor having a large power factor correction (PFC) output capacity. The present invention relates to a reset prevention circuit of PDTV which can be applied to a TV that requires a large power.

FIG. 1 is a block diagram of a panel driving circuit of a conventional plasma display panel (PDP) TV. As shown in FIG. 1, a relay switch RL1 (RL2) that supplies or cuts input power when power is turned on or off. ), And corrects the power factor by receiving the first and second rectifiers 11 and 12 rectifying the input power and the power input through the relay switch into DC voltages, and the voltages rectified by the first rectifier 11. The power factor correcting unit 13 for outputting the power factor correcting voltage and the voltage rectified by the second rectifying unit 12 and supplying a driving voltage to the microcomputer 15 at power-on and power-off. A power supply control unit 14 for supplying a standby voltage, a panel driving voltage generation unit 16 for receiving a power factor correction voltage from the power factor correction unit 13 to generate a panel driving voltage for driving the panel, and the panel Ball as drive voltage and relay switch In response to the input voltage, it is determined whether there is an abnormal operation, and the resonance voltages of Va and Vs are determined by the first and second control circuit units 17 and 18 that provide the resonance driving voltage and the resonance driving voltage outputted above. Resonant power supply unit 19 and 20 to be supplied, the DC-DC converter 21 to receive the Va voltage supplied from the above converted to V1 voltage and output, and receives the Va, Vs, V1 voltage output from the It consists of a PD panel 22 for driving a PD panel.

Referring to the prior art configured as described above is as follows.

As the first relay switch RL1 is turned off and the second relay switch RL2 is turned on at power-on, the input power is supplied to the first rectifier 11 through the resistor R1 and the second relay switch RL2. Delivered.

Accordingly, the first and second rectifiers 11 and 12 rectify the input power to a DC voltage and supply the rectified power to the power factor corrector 13 and the power controller 14, respectively.

At this time, since the power control unit 14 is in a power-on state, it supplies a driving voltage to the microcomputer 15 to make an operable state.

The power factor correction unit 13 receives the DC voltage and supplies the power factor correction voltage generated by performing the power factor correction to the panel driving voltage generator 16.

Accordingly, the panel driving voltage generation unit 16 generates a VCC voltage of 17 V to drive the panel and provides it to the fault input terminal of the first and second control circuit units 17 and 18. The 12V voltage supplied to the relay input terminal is supplied to another driving (drv) input terminal of the second control circuit unit 17 (18).

Then, when the voltage input to the fault input terminal is 17V, the first and second control circuit units 17 and 18 determine that it is normal and resonate the power supply unit 19 by the voltage input to the driving (drv) input terminal. 20). When a voltage below a predetermined voltage is input, it is determined to be abnormal and the protection operation is performed without providing a voltage to the resonance type power supply units 19 and 20.

Then, the resonance type power supply unit 19 generates Va voltage, and the resonance type power supply unit 20 generates Vs voltage.

The Va voltage among the generated voltages is input from the DC converter 21 to generate V1 voltage.

In this case, the PDP panel 22 receives the V1, Va, and Vs voltages, respectively, to drive the panel normally.

In this way, the time sequence and magnitude of the voltage supplied to the PDP panel unit 22 at power-on are as shown in FIG.

In addition, when power-off, a voltage of 12 V supplied to the second relay is cut off, and accordingly, the second relay switch RL2 is turned off to cut off the input power supplied to the power factor correction unit 13.

At this time, the AC power supply control unit 14 supplies standby power to the microcomputer 15, so that the microcomputer 15 performs the necessary control operation during the standby.

As the power supplied to the power factor correction unit 13 is cut off, the voltage output through the output terminal thereof is also cut off so that the panel driving voltage generator 16 does not generate the panel driving voltage.

Then, the first and second control circuit units 17 and 18 detect the absence of a voltage input through the fault input terminal of the first and second control circuit units 17 and 18 to recognize the power-off state, and cut off the resonance type power supply units 19 and 20. Supply the signal.

Accordingly, the resonant power supply units 19 and 20 generate negative Va and Vs voltages, and the DC-DC converter 21 receives the negative Va voltages to generate V1 voltages.

Therefore, the PD panel 22 is supplied with the voltages Va, Vs and V1 as shown in FIG. 2B to drive the PD panel.

The TV operating in this manner is a PD 60 "TV.

However, in the prior art as described above, since the capacity of the capacitor connected to the output terminal of the power factor correction at the time of power-off is large, it takes about 11 seconds as shown in FIG. 4 (a). When the power-on is turned on, the fault input terminal of the control circuit unit operates to detect an abnormal operation at power-on and resets the TV to perform a circuit protection operation. Therefore, it takes a long time for the TV to come out normally. .

Accordingly, an object of the present invention for solving the conventional problems as described above is to provide a reset prevention circuit of PDTV to improve the phenomenon that is reset when the power-on immediately after the power-off.

1 is a block diagram of a panel driving circuit of a conventional PDP TV.

FIG. 2 is a waveform diagram showing a time sequence at power on / off in FIG.

Figure 3 is a block diagram of a reset prevention circuit of the present invention PDTV.

FIG. 4 is a waveform diagram showing a time sequence before and after a reset improvement in FIG. 3. FIG.

***** Explanation of symbols for the main parts of the drawing *****

11,12 Rectification Department 13: Power Factor Correction

14: power control unit 15: microcomputer

16: panel drive voltage generation unit 17, 18: control circuit unit

19,20: resonant power supply 21: DC-DC converter

22: PD Panel

The present invention for achieving the above object is a relay switch for supplying or cutting off the input power to the power factor correction unit, and the panel drive voltage and the relay switch output from the panel drive voltage generator receiving the power factor correction voltage of the power factor correction unit. Panel driving circuit of PDTV comprising a control circuit unit for receiving an input voltage input to determine whether there is an abnormality of the resonant voltage, and a resonant power supply unit for supplying a resonant voltage to the PDP panel unit according to the control of the control circuit unit. In the furnace, a voltage inputted to a fault input stage when a power is turned on immediately after power-off by connecting a diode and a transistor between a fault input stage of a control circuit unit that receives the panel driving voltage and a drive input stage that receives an input voltage of a relay switch. To keep the level low to prevent reset It characterized by including a set of blocking means.

Hereinafter, with reference to the accompanying drawings in detail as follows.

FIG. 3 is a block diagram of a reset prevention circuit of a PDTV according to the present invention. As shown therein, a relay switch RL1 RL2 for supplying or interrupting input power at power on / off, and the relay switch And a power factor correcting unit 13 for outputting a power factor correction voltage for performing power factor correction by receiving the DC voltage rectified through the first rectifying unit 11, and receiving a voltage of the second rectifying unit 12 for rectifying the input power. A power supply control unit 14 for supplying a driving voltage to the microcomputer 15 when on, and a standby voltage for power-off, and a power factor correction voltage from the power factor correction unit 13 for driving the panel. First and second control for determining whether there is an abnormal operation by receiving the panel driving voltage generator 16 generating the panel driving voltage and the input voltage supplied to the panel driving voltage and the relay switch, and providing a resonance driving voltage. Circuit part (1 7) 18 and a reset prevention unit 23 connected to the two input terminals of the control circuit unit 17 and 18 to prevent the reset when the power-on immediately after the power-off, and the resonance output from the A resonant power supply unit 19 and 20 for supplying a resonant voltage of Va and Vs by a driving voltage, a DC-DC converter 21 for converting and outputting the supplied Va voltage into a V1 voltage; It receives a Va, Vs, V1 output from the PDP panel 22 for driving the PDP panel.

Referring to the operation and effect of the present invention configured as described in detail as follows.

During power-off, the relay switch RL2 is cut off to cut off the voltage supplied to the power factor correction unit 13, and standby power is supplied to the microcomputer 15 by the power control unit 14. Only 15) works.

At power-on, the relay switch RL2 is turned on and the power factor correction unit 13 receives the DC voltage rectified by the first rectifier 11 to perform the power factor operation.

The panel driving voltage generation unit 16 receiving the power factor correction voltage generated by the power factor correction unit 13 generates a VCC voltage of 17 V for driving the panel to control the first control circuit 17 and the second control. It is provided to the circuit part 18, respectively.

The VCC voltage of 17V provided above is accepted as a fault input terminal, and a 12V voltage input to a relay switch is input to a driving (drv) input terminal.

The control circuits 17 and 18 that receive the respective voltages to the two input terminals are judged to be in normal operation as the voltage of 17 V is input to the fault input terminal, and the voltage of the 12 V input to the driving input terminal is resonant. Supply to (20).

Therefore, the resonant power supply unit 19 supplies Va resonant voltage to the DC-DC converter 21 and the PD panel 22, and the resonant power supply unit 20 supplies the Vs resonant voltage to the PD panel 22. To supply.

The DC-DC converter 21 converts the input Va resonance voltage into a V1 voltage and supplies the Va resonance voltage to the PD panel 22.

Accordingly, the PDP panel 22 receives the Va, Vs, V1 resonant voltages input from the resonant power supply units 19 and 20 and the DC-DC converter 21 to operate the control board normally.

In this manner, during power-off, discharge is caused by the capacitor C1 connected to the output terminal of the power factor correction unit 13 gradually, and the discharge voltage is inputted to the panel driving voltage generator 16 to be driven. It takes some time to discharge to a voltage that does not operate the panel drive voltage generation unit 16.

Then, the control circuits 17 and 18 drive the resonant power supply units 19 and 20 by a voltage of 17V input to the fault input terminal of the control circuit units 17 and 18.

At this time, when the power is turned on again, 12V is input to the driving (drv) input terminal of the control circuit units 17 and 18, and accordingly, the transistor Q1 of the reset protection unit 23 is turned on to input the voltage to the fault input terminal. It is bypassed to the ground side through the diode D1 and the transistor Q1.

Therefore, by holding the voltage input to the fault input terminal of the control circuit unit 17 (18) to a low level (normal level) to perform a normal operation.

In other words, the transistor Q1 of the reset prevention unit 23 immediately discharges the voltage gradually discharged by the capacitor C1 of the power factor correcting unit 13 at power-on again within 11 sec after power-off. As in (b) of the power-on operation is made within a few seconds can be seen immediately TV.

As described in detail above, in the present invention, since the capacitance of the capacitor connected to the output terminal of the power factor correcting means is large, it is not discharged immediately by using a transistor and a diode, so that the reset phenomenon occurs even when power-on immediately after power-off. There is an effect that can be applied to large TVs that do not occur, and also requires a large power.

Claims (1)

A relay switch for supplying or blocking input power to the power factor correction unit, a panel driving voltage output from the panel drive voltage generation unit that receives the power factor correction voltage of the power factor correction unit, and an input voltage input to the relay switch In the panel driving circuit of PDTV comprising a control circuit unit for determining the abnormality of the circuit and a resonant power supply unit for supplying a resonant voltage to the PDP panel unit under the control of the control circuit unit, and a DC-DC converter. Connect the diode and the transistor between the fault input terminal of the control circuit part to be accepted and the drive input terminal to receive the input voltage of the relay switch. When powering on immediately after power-off, the voltage level input to the fault input terminal is set to low level and reset. Characterized in that it comprises a reset prevention means for preventing Reset protection circuit for the PDP TV.