KR100959530B1 - Apparatus for Controling Pan of PDP Module - Google Patents

Abstract

The present invention relates to a fan control device of a PD module that protects the IPM from overheating by operating a fan by recognizing whether the IPM, which is an intelligent power supply, is overheated. Or a fan control unit driven at a second RPM, an X, Y and Z drive board for driving the X, Y and Z electrodes of the PD module, and an intelligent power supply for switching the power supply from the Y drive board to the Y electrode, Video scan boards that generate a time sequence to control the addressing and scan timings of PDPs, and the timing of powering up the X and Y drive boards Control board to control, overheat judging unit for judging whether the intelligent power supply is overheated according to Y drive board control output of the control board, video By controlling the time sequence generation operation of the can board and outputting a control signal to the fan control unit according to the determination result of the overheat judging unit, the microcomputer can prevent the deterioration and damage of the intelligent power supply and ultimately improve the performance of the PD module. have.

Fan / Y Drive Board / IPM

Description

App Control Device for PDP Module {Apparatus for Controling Pan of PDP Module}

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

3 is a diagram illustrating a configuration of an overheat determination unit of FIG. 2.

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

11: fan 13: temperature sensor

14: power supply 15: VSC

17: control board 18: Y drive board

19: IPM 21: Overheat Judgment Unit

22: microcomputer 23: fan control unit

The present invention relates to a PD module, and more particularly to a fan control device of the 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.

The PD module is provided with various circuits for driving the PD on the back of the PD.

That is, as shown in Figure 1, the PD 10, and consists of a variety of circuits provided on the rear of the PD 10, looking at the configuration of the various circuits are as follows.

Each component of the fan 11 for cooling the PD module, the fan control unit 12 for driving the fan 11 at the first or second RPM according to the ambient temperature detected through the temperature sensor 13, and the PD module The power supply unit 14 for supplying power to the field, the X driving board for driving the X electrode (not shown), the Y driving board 18 for driving the Y electrode of the PD module, and the Z electrode of the PD module. Intelligent driving device for switching the power supply to each electrode by the Y driving board (18), which is composed of switching elements such as a Z driving board (not shown) and a transistor, using the power supplied from the power supply unit 14. IPM (INTELLIGENT POWER MODULE) 19, a time sequence for controlling addressing and scanning timing according to a control program so that an externally input video signal (R / G / B) is synchronized with a synchronous signal and can be implemented through a PD. (Time Sequence) The X drive board (not shown) according to the generated video scan board 15, the microcomputer 16 controlling the time sequence generation operation of the video scan board 15, and the time sequence transmitted through the video scan board 15. And a control board 17 for controlling the power supply timing of the Y drive board 18 and the Z drive board (not shown).

At this time, in the description of the prior art configuration, the illustration of the X drive board and Z drive board is omitted, and thus the control line connection of the X drive board and Z drive board in the control board 17 is also omitted.

The operation of the PD module configured as described above is as follows.

First, an example in which a PD module is applied to a TV, that is, an example of PD TV will be described.

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 17 so that the video signal supplied from the TV module can be synchronized with the synchronous signal to be implemented on the PD screen. 14) supplies driving power to each configuration.

The control board 17 controls the voltage supply timing of the X driving board, the voltage supply timing of the Y driving board 18, and the power supply timing of the Z driving board in accordance with the time sequence.

Subsequently, the X driving board, the Y driving board 18, and the Z driving board generate driving pulses suitable for the image data using the driving power supplied from the power supply unit 14 according to the timing control of the control board 17. Output 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.

Meanwhile, the fan operation in the conventional PD module will be described.

The fan controller 12 causes the fan 11 to operate at a first RPM, that is, at a low speed when the ambient temperature detection value through the temperature sensor 13 is lower than the reference temperature, and the ambient temperature detection value through the temperature sensor 13 is increased. When the reference temperature is exceeded, the fan 11 operates at a second RPM, that is, at a high speed.

At this time, when the contrast and luminance of PD are 10 to 30%, especially when 20%, the number of sustain is the largest and the discharge area is small, and thus the number of discharge is increased.

That is, the control board 17 sends a signal for driving all of the Y electrodes to the Y driving board 18, for example, a signal in which all 8 bits (2 ⁸ = 256) of signal lines are '1'. Will output

Therefore, the number of switching of the transistors of the IPM 19 increases, and eventually, the IPM 19 becomes overheated.

However, as described above, the fan 11 operates only in accordance with the ambient temperature of the fan control unit 12 regardless of the overheating of the IPM 19. Since the fan 11 operates at a low speed because it is not high, there is a problem that the reliability of the IPM 19 is lowered and may be broken if the overheated state continues.

Accordingly, the present invention has been made to solve the above-mentioned problems, and provides a fan control device of the PD module to protect the IPM from overheating by operating the fan by recognizing whether the intelligent power supply is overheated. The purpose is.

The present invention provides a fan for cooling a PD module, a fan controller for driving a fan at a first or second RPM according to a control signal, and an X, Y and Z drive board for driving X, Y, and Z electrodes of the PD module, respectively. Intelligent power supply for switching power supply from Y drive board to Y electrode, video scan board to generate time sequence for controlling PD addressing and scan timing, time transmitted through video scan board Control board that controls the power supply timing of X drive board, Y drive board and Z drive board according to sequence, Overheat judging unit to judge whether intelligent power supply is overheated according to Y drive board control output of control board, Video scan board And a microcomputer for controlling the time sequence generation operation of the control unit and outputting a control signal to the fan control unit according to the determination result of the overheat determination unit. It shall be.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the fan control device of the PD module according to the present invention will be described in detail.

2 is a block diagram showing the configuration of the PD module according to the present invention, Figure 3 is a view showing the configuration of the overheat determination unit of FIG.

The configuration of a fan control device of a PD module according to the present invention will be described with reference to FIG.

Fan 11 for cooling the PD module, a fan control unit 12 for driving the fan 11 at a first or second RPM according to a control signal, a power supply unit for supplying power to each component of the PD module ( 14), an X drive board (not shown) for driving the X electrode, a Y drive board 18 for driving the Y electrode of the PD module, a Z drive board (not shown) for driving the Z electrode of the PD module, IPM (INTELLIGENT POWER MODULE), which is an intelligent power supply device for switching the power supply to each electrode by the Y driving board 18 by using a power source supplied from the power supply unit 14, such as a transistor. ), A video scan for generating a time sequence for controlling addressing and scanning timing according to a control program such that an externally input image signal R / G / B is synchronized with a synchronous signal and can be implemented through a PD. Bo 15, a control board for controlling the power supply timing of the X drive board (not shown), the Y drive board 18 and the Z drive board (not shown) according to the time sequence transmitted through the video scan board 15. (17), the overheat determination unit 21 for determining whether the IPM 19 is overheated according to the control output of the Y drive board 18 of the control board 17, the time sequence generation of the video scan board 15 The microcomputer 22 controls an operation and outputs a control signal to the fan controller 23 according to the determination result of the overheat determination unit 21.

At this time, in the description of the configuration of the present invention, the illustration of the X drive board and Z drive board is omitted, and thus the control line connection of the X drive board and Z drive board in the control board 17 is also omitted.

And look at the membership of the overheat determination unit 21 of the present invention.

As described above, when at least one of the contrast and luminance values of the PD, that is, the contrast and the luminance, is about 20%, the number of sustains is the largest and the discharge area is small, resulting in a large number of discharges and IPM overheating.

At this time, when at least one of the contrast and the luminance is about 20%, the control board 17 signals the Y drive board 18 to drive all the Y electrodes, that is, all 8 bits of the signal line (2 ⁸ = 256) are '1'. The output signal is output to the Y drive board 18.

Accordingly, when the outputs from the control board 17 to the Y driving board 18 are all '1', the IPM 19 may be determined as a reference for overheating, thereby configuring the overheat determining unit 21.

According to the above-described principle, in FIG. 3, when the control output from the control board 17 to the Y drive board 18 is all input (for example, 8 bits) and all 8 bits are '1 (high)', '1 ( The overheat judging unit 21 configured as an end gate to output high) 'to the microcomputer 22 is shown.

Referring to the operation of the fan control device of the PD module according to the present invention configured as described above in detail.

Since the screen display operation of the PD module is the same as in the prior art, the fan control operation will be omitted.

First, the AND gate of the overheat determination unit 21 receives 8 bits of the control output from the control board 17 to the Y driving board 18 in a state where normal screen display is performed.

Subsequently, the AND gate outputs' 0 '(low)' to the microcomputer 22 when any one of 8 bits of the control output from the control board 17 to the Y drive board 18 is not '1'.

Accordingly, the microcomputer 22 recognizes that the IPM 19 is not overheated according to '0' output from the overheat judging unit 21 and drives the fan 11 at a first RPM (low speed) by the fan control unit 23. Outputs a control signal, and the fan control unit 23 drives the fan 11 at low speed.

On the other hand, the AND gate outputs '1 (high)' to the microcomputer 22 when all 8 bits of the control output from the control board 17 to the Y drive board 18 are '1'.                     

Subsequently, the microcomputer 22 recognizes that the IPM 19 is overheated according to the '1' outputted from the overheat judging unit 21 and requests the fan controller 23 to drive the fan 11 at a second RPM (high speed). The control signal is output, and the fan control unit 23 drives the fan 11 at high speed.

The fan control device of the PD module according to the present invention prevents overheating by judging overheating conditions of the intelligent power supply that may actually cause overheating, thereby preventing overheating by preventing the overheating of the intelligent power supply. This has the effect of improving the performance of the module.

Claims (2)

A fan for cooling the PD module; A fan controller configured to drive the fan at a first RPM or a second RPM according to a control signal; X, Y and Z drive boards for driving the X, Y and Z electrodes of the PD module, respectively; An intelligent power supply for switching a power supply from the Y drive board to a Y electrode; A video scan board for generating a time sequence for controlling addressing and scan timing of the PDP; A control board controlling power supply timing of the X driving board, the Y driving board, and the Z driving board according to the time sequence transmitted through the video scan board; An overheat determination unit determining whether the intelligent power supply is overheated according to the Y drive board control output of the control board; A microcomputer controlling a time sequence generation operation of the video scan board and outputting a control signal to the fan control unit according to a determination result of the overheat determination unit, The Y driving board control output is a fan control device of the PD module, characterized in that the signal for determining whether the drive of the Y electrode of the PD module. According to claim 1, And the overheat determining unit includes an AND gate configured to receive and logically multiply the Y driving board control output of the control board and output the result to the microcomputer.

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