KR20040091840A - Apparatus for Preventing Discharging Error of PDP Module - Google Patents

Abstract

PURPOSE: An apparatus for preventing the erroneous discharge of a plasma display panel(PDP) module is provided to prevent the erroneous discharge during an initial operation without depending on the model although the same control program is applied. CONSTITUTION: An apparatus for preventing the erroneous discharge of a plasma display panel(PDP) module includes a power unit(26), an X-board(21), an Y-board(22), a Z-board(23), a video scan board(25), a control board(24) and a timing board(27). The power unit(26) supplies the operational power to each component of the panel. The X board(21) outputs the address voltage to the X electrode of the PDP panel. The Y-board(22) outputs the scan voltage to the Y-electrode of the PDP panel. The Z-board(23) outputs the sustain voltage to the Z-electrode of the PDP panel. The video scan board(25) generates and outputs the time sequence to control the addressing and the scan timing in response to the previously stored control program. The control board(24) controls the power supplying timing of the X board, the Y-board and the Z-board. And, the timing board(27) delays the power supplying timing of the Y-board by a predetermined time in comparison with the power supplying timing of the X board.

Description

Apparatus for Preventing Discharging Error of PDP Module

The present invention relates to a PD module, and more particularly, to a device for preventing a discharge of a PD module.

PD forms a Y electrode and a Z electrode on the same surface of the front substrate, an X electrode on the rear substrate of the upper structure, and a partition wall to prevent crosstalk between adjacent cells between the X electrodes. And a substructure having a phosphor layer formed around the barrier ribs and the X electrode, so that an inert gas is enclosed between the space between the superstructure and the substructure to have a discharge region. When a driving voltage is applied between the X electrode and the Y electrode, a counter discharge occurs between the X electrode and the Y electrode, and wall charges are generated. The discharge voltages having opposite polarities are continuously applied to the Y electrode and the Z electrode, and the X electrode is continuously applied. When the driving voltage applied to the electric power source is cut off, a predetermined electric potential difference is maintained between the Y electrode and the Z electrode by wall charge, so that surface discharge occurs. As a result, ultraviolet rays are generated from the inert gas in the discharge region. The phosphor layer is excited by the ultraviolet rays, and color display is performed by the emitted phosphor layer.

Therefore, the PD module is provided with a circuit for driving the PD panel on the back of the PD panel as described above.

Such PD module can be manufactured considerably thinner than conventional CRT and its brightness is superior to LCD, and it is mainly used in computer monitors and TVs. have.

A general PD TV can be largely classified into a TV module that tunes to a PD module and a channel according to a user's selection, receives a broadcast signal, and transmits the broadcast signal to the PD module. A schematic configuration of the PD module will be described with reference to FIG. 1. Is as follows.

An X board 11 for outputting an address voltage to an X electrode of a PD panel (not shown), a Y board 12 for outputting a scan voltage to a Y electrode of the PD module, and a sustain voltage to the Z electrode of the PD module. Time sequence for controlling the addressing and scanning timing according to the control program so that the video signal R / G / B output from the Z board 13 and the TV module to be synchronized with the synchronization signal and can be implemented through PD The power supply timing of the X board 11, the Y board 12, and the Z board 13 according to the time sequence transmitted through the video scan board 15 generating the video scan board 15. Control board 14, and a power supply unit 16 for supplying operating power to the entire configuration.

The operation of the PDTV configured as described above is as follows.

When the user selects a predetermined channel, the TV module receives the broadcast signal of the corresponding channel and processes the video signal among the video signals so that the screen can be output from the PD module so that the video scan board 15 of the PD module together with the horizontal and vertical synchronization signals is provided. To send.

At this time, since the voice signal of the broadcast signal is processed and output by the TV module itself, detailed description thereof will be omitted.

Subsequently, the video scan board 15 generates a time sequence according to a control program and transmits the time signal to the control board 14 so that the video signal supplied from the TV module can be implemented on the PD screen in synchronization with the synchronization signal. 16 supplies driving power in each configuration.

The control board 14 controls the address voltage supply timing of the X board 11, the scan voltage supply timing of the Y board 12, and the sustain power supply timing of the Z board 13 in accordance with the time sequence.

Subsequently, the X board 11, the Y board 12, and the Z board 13 use a driving power supplied from the power supply unit 16 to control driving pulses suitable for image data according to timing control of the control board 14. It generates and outputs to the corresponding electrode of the PDP panel.

Therefore, as the electrode of the PD panel is driven, the above-described surface discharge occurs and accordingly, the fluorescent layer emits light to implement the screen.

At this time, there may be a difference between video scan boards by PD models, and even when each control configuration, especially video scan board, is changed by new module development or update, the control program for basic PD drive is not changed. Due to this, a difference occurs in the characteristics of the actual scan board, which causes a change in control timing, which may cause the PD to be discharged.

In other words, when the user turns on the power using the remote control during the initial PD startup, the 5V (module drive voltage), Va (address voltage), and Vs (scan voltage) signals become 'high' at regular intervals. Subsequently, the hardware Va and Vs voltages must also be generated at regular intervals. However, when the above-described actual power supply timing fluctuations occur, the voltages Va and Vs are generated at the same time, resulting in PD discharge, and in severe cases, overload may also cause component damage.

Therefore, in order to prevent mis-discharge, the control program itself must be modified to match the characteristics of the video scan board, and eventually, the program must be changed or newly created for each model.

The PD module according to the prior art has the following problems.

First, even if the control program is the same due to the difference in the characteristics of the scan board, the actual power supply timing is fluctuated, which causes an erroneous discharge.

Second, it is inefficient in terms of time, manpower, and cost because the control program must be modified or newly created for each model to prevent mis-discharge.

Accordingly, the present invention has been made to solve the above-mentioned problems, and the object of the present invention is to provide a device for preventing a mis-discharge of a PD module so that no mis-discharge occurs during initial operation even when the same control program is applied regardless of the model. have.

1 is a block diagram showing the configuration of a PD module according to the prior art

2 is a block diagram showing the configuration of a PD module according to the present invention

-Explanation of symbols for the main parts of the drawings-

21: X board 22: Y board

23: Z board 24: control board

25: video scan board 26: power supply

27: timing controller

The present invention provides a power supply unit, an X board, a Y board, a Z board, and an externally input image signal for controlling addressing and scanning timing according to a pre-stored control program so as to be implemented on a PD screen in synchronization with a synchronization signal. A video scan board that generates and outputs a time sequence, a control board that controls the power supply timing of each of the X board, Y board, and Z board to match the time sequence transmitted from the video scan board, and And a timing controller configured to delay the power supply timing of the Y board during the power supply timing by a predetermined time compared to the power supply timing of the X board.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the apparatus for preventing the discharge of the PD according to the present invention in detail.

As shown in FIG. 2, the apparatus for preventing mis-discharge of a PD module according to the present invention includes a power supply unit 26 for supplying operation power to each component of the panel, and an X board for outputting an address voltage to the X electrode of the PD panel. (21), the Y board 22 for outputting the scan voltage to the Y electrode of the PD module, the Z board 23 for outputting the sustain voltage to the Z electrode of the PD module, and controlling the addressing and scan timing according to the control program A video scan board 25 generating a time sequence for performing the operation, and the X board 21 and the Y board 22 and the Z board 23 to match the time sequence transmitted from the video scan board 25. The control board 24 which controls each power supply timing, and the power supply timing (scan voltage output) of the Y board 22 among the power supply timings of the control board 24 is the power of the X board 21. Supply Timing (Before Address And a timing controller 27 for delaying a predetermined time as compared with the pressure output).

At this time, the timing controller 27 is configured in the control board 24, and is composed of a delay element for delaying a signal for a predetermined time.

When the user 'turns on' the power using the remote control of PDTV, the TV module receives the broadcast signal of the corresponding channel and the image is processed so that the screen can be output from the PD module and transmits it to the PD module together with the horizontal and vertical synchronization signals. do.

At the same time, the video scan board 25 generates a time sequence for controlling addressing and scanning timing according to a pre-stored control program so that the video signal is synchronized with the synchronous signal and implemented on the PDPI screen. 24).

The control board 24 controls the power supply timing of each of the X board 21, the Y board 22, and the Z board 23 to match the time sequence transmitted from the video scan board 25. In other words, the control board 24 performs timing control by the time sequence, that is, the signal control according to the program.

At this time, the timing controller 27 in the control board 24 sets the power supply timing (scan voltage output) of the Y board 22 among the power supply timings of the control board 24 to the power supply timing of the X board 21. It delays for a certain time compared to (address voltage output) In other words, the timing controller 27 supplies the power supply timing (scan voltage output) of the Y board 22 to the power supply of the X board 21 by using an actual hardware delay element separate from the control board 24. It delays for a certain time compared to the timing (address voltage output).

Therefore, after the address voltage Va is supplied by the forced delay operation of the timing controller 27 of the control board 24, that is, the hardware delay operation, the scan is performed at a sufficient time interval not to affect the screen reproduction. The voltage Vs is supplied.

Subsequently, the X board 21, the Y board 22, and the Z board 23 generate pulse driving voltages according to the timing control of the control board 24 and the timing controller 27, and apply them to the corresponding electrodes of the PDP panel. Output

Therefore, as the electrode of the PD panel is driven, the above-described surface discharge occurs, and thus, the fluorescent layer emits light to implement the screen.

The apparatus for preventing mis-discharge of the PD module according to the present invention can prevent the mis-discharge at the initial stage of operation by allowing the scan voltage to be supplied to the corresponding configuration at a predetermined time interval compared to the address voltage in hardware, as well as a model. Irrespective of false discharge protection, the same control program can be used, which is very efficient in terms of cost, manpower and time.

Claims (2)

A power supply unit for supplying operation power to each component of the panel; An X board for outputting an address voltage to an X electrode of the PD panel; A Y board for outputting a scan voltage to the Y electrode of the PD module; A Z board for outputting a sustain voltage to the Z electrode of the PD module; A video scan board generating and outputting a time sequence for controlling addressing and scanning timing according to a pre-stored control program such that an externally input image signal is synchronized with a synchronous signal to be implemented on a PDP screen; A control board controlling power supply timing of each of the X board, the Y board, and the Z board to match the time sequence transmitted from the video scan board; And a timing controller configured to delay the power supply timing of the Y board from the power supply timing of the control board for a predetermined time compared to the power supply timing of the X board. According to claim 1, And the timing controller is configured in the control board.