KR20050050377A - Plasma display panel including driving device - Google Patents

Abstract

The present invention relates to a plasma display panel including a driving device. The driving apparatus included in the present invention includes: 1) an X electrode driver for forming a wall voltage in the pixel cell by applying a data pulse to the X electrode, and 2) applying a reset pulse to the Y electrode to remove the remaining charges and removing the scan pulse. A Y-electrode driver for maintaining the discharge of the pixel cell by applying a sustain pulse to the Y electrode after forming a wall voltage in the selected pixel cell according to the data pulse by applying to the Y electrode, and 3) alternating with the sustain pulse applied by the Y electrode driver. 4) an X electrode driver for maintaining the discharge of the pixel cell by applying a sustain pulse to the Z electrode; and 4) an X electrode driver, a Y electrode driver, and a Z electrode driver are electrically connected to each other through a signal line. It includes a main control unit for transmitting a, characterized in that at least one of the signal line is shielded.

As described above, the at least one signal line between the main control unit and each electrode driver may be covered with a shielding conductor to minimize noise due to the enlargement of the plasma display panel.

Description

Plasma Display Panel Including Driving Device

The present invention relates to a plasma display panel including a driving device, and more particularly, to a plasma display panel including a driving device capable of reducing noise due to high voltage.

Cathode ray tubes, which have been the mainstay of the display means, have a large distance between the fluorescent surface and the electron gun because the electron beam is scanned through the entire fluorescent surface with one electron gun. Due to the characteristics of the cathode ray tube, the cathode ray tube has various problems, such as being bulky, heavy, difficult to realize a flat screen, and difficult to implement a large screen.

Accordingly, in order to overcome the problems of the cathode ray tube as described above, various display technologies such as LCDs and plasma display panels, which are thin and light, and which can realize a large screen, have been actively studied.

In the plasma display panel, a discharge gas is injected between a thin front substrate and a rear substrate on which a plurality of transparent electrodes are formed. When voltage is applied to such a transparent electrode, a discharge occurs, and ultraviolet rays generated by the discharge emit the phosphor coated on the surface of the rear substrate.

Each light emitting element consisting of a transparent electrode and a phosphor is formed of pixel cells separated by barrier ribs and driven independently of each other. In addition, since the plasma display panel has a thin and wide matrix structure as a whole, it is light in weight, easy to flatten a screen and a large screen, and can prevent color bleeding and deterioration of focus. Due to these advantages, the plasma display panel is emerging as a new display means that can overcome the limitations of the cathode ray tube.

However, since the plasma display panel uses discharge, a high voltage must be applied to the electrode. In addition, as the size of the plasma display panel gradually increases, the transmission distance of the image signal transmitted from the board on which the main controller is formed to the board on which the X electrode driver is formed is gradually increasing.

1 is a block diagram of a driving apparatus included in a general plasma display panel. The X electrode driver 110 receives an image signal from the main controller 120, converts the image signal into a data pulse, and then forms a wall voltage in the pixel cell by applying the data pulse to the X electrode. The process of converting such an image signal into a data pulse signal is usually performed by a chip on film (COF) in which four data driver ICs (not shown) are packaged.

The Y electrode driver 130 applies a reset pulse to the Y electrode under the control of the main controller 120 to remove charges remaining before the pixel voltage is formed in the pixel cell, and applies a scan pulse to the Y electrode according to the data pulse. After the wall voltage is formed in the selected pixel cell, a sustain pulse is applied to the Y electrode to maintain the discharge of the pixel cell in which the wall voltage is formed.

The Z electrode driver 140 applies a sustain pulse alternately with the sustain pulse applied by the Y electrode driver 130 to the Z electrode to maintain the discharge of the pixel cell in which the wall voltage is formed.

The high voltage supply unit 150 supplies high voltages necessary for generating and maintaining a discharge of the plasma display panel to each electrode driver.

At this time, the reference numeral 160 is a heat sink made of aluminum for dissipating heat generated during operation of the drive device, each component is on the top of the heat sink.

As shown in FIG. 1, as the screen of the plasma display panel grows, the COFs for applying the data pulses must also be aligned in a long line. Accordingly, the transmission distance of the video signal transmitted from the main control unit 120 to the COF also increases.

Since the transmission distance of the image signal is increased in this manner, the conductive wires electrically connecting the main control unit 120 and the X electrode driving unit 110 are excessively around the high voltage supply unit 150 for applying the high voltage. At this time, the video signal transmitted through the wire is usually transmitted as a high frequency signal of 5V or less level.

Therefore, noise is generated in the image signal due to the electromagnetic wave generated by the high voltage supply unit 150. Such noise is a factor that degrades the image quality of the plasma display panel.

The present invention has been made to solve the above problems, and to provide a plasma display panel including a driving device that can reduce the influence of noise due to electromagnetic waves generated by the high voltage supply.

In order to achieve the above object, the driving apparatus according to the present invention includes an X electrode driver, a Y electrode driver, a Z electrode driver, and a main controller.

The X electrode driver forms a wall voltage in the pixel cell by applying a data pulse to the X electrode.

The Y electrode driving unit applies a reset pulse to the Y electrode to remove the remaining charges, applies a scan pulse to the Y electrode to form a wall voltage in the selected pixel cell according to the data pulse, and then applies a sustain pulse to the Y electrode. Maintain a discharge of the cell.

The Z electrode driver applies sustain pulses alternated to the sustain pulses applied by the Y electrode driver to the Z electrodes to maintain discharge of the pixel cells.

The main controller is electrically connected to the X electrode driver, the Y electrode driver, and the Z electrode driver through a signal line, and transmits a control signal and an image signal through the signal line.

In this case, at least one of the signal lines may be shielded.

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

2 is a block diagram of a plasma display panel including a driving device according to the present invention. As shown in FIG. 2, the driving apparatus according to the present invention includes an X electrode driver 210, a Y electrode driver 220, a Z electrode driver 230, a main controller 240, and a high voltage supply unit 250.

<X electrode drive part>

The X electrode driver 210 forms a wall voltage in the pixel cell by applying a data pulse to the X electrode. This data pulse application process is usually performed by a COF packaged with four data driver ICs (not shown).

<Y electrode drive part>

The Y electrode driver 220 applies a reset pulse to the Y electrode to remove charges remaining before the pixel voltage of the pixel cell is formed, and applies a scan pulse to the Y electrode to form a wall voltage in the selected pixel cell according to the data pulse. Then, a sustain pulse is applied to the Y electrode to maintain the discharge of the pixel cell in which the wall voltage is formed.

<Z electrode drive part>

The Z electrode driver 230 applies a sustain pulse alternately with the sustain pulse applied by the Y electrode driver 220 to the Z electrode to maintain the discharge of the pixel cell in which the wall voltage is formed.

<Main control section>

The main controller 240 controls the operations of the X electrode driver 210, the Y electrode driver 220, and the Z electrode driver 230 and transmits an image signal to the X electrode driver 210.

〈High Voltage Supply Part〉

The high voltage supply unit 250 supplies a high voltage necessary for generating and maintaining a discharge of the plasma display panel to each electrode driver.

At this time, reference numeral 260 is a heat sink made of aluminum for dissipating heat generated during operation of the driving device, each component is on the top of the heat sink.

Since the transmission path of the image signal transmitted from the main controller 240 to the X electrode driver 210 passes through the periphery of the high voltage supply unit 250, electromagnetic waves generated by the high voltage supply unit 250 affect the transmitted image signal. Get mad.

In order to minimize the influence of electromagnetic waves, the driving apparatus according to the present invention shields the signal line 270 which is a transmission medium for the image signal transmitted from the main controller 240 to the X electrode driver 210 as shown in FIG. 2. It is shielded with the conductive conductor 280. At this time, the signal line is covered.

That is, since the shielding conductor 270 overlaid on the signal line 280 is electrically connected to the heat sink 260 made of aluminum bonded to the plasma display panel, the shielding conductor 270 is electrically connected to the ground. Connected.

Therefore, electromagnetic waves generated by the high voltage supply unit 250 are removed by the shielding conductor 270 and the heat sink 260.

The shielding conductor 270 may include a signal line between the X electrode driver 210 and the main controller 240, a signal line between the Y electrode driver 220 and the main controller 240, and a Z electrode driver 230. Applicable to the signal line between the main control unit 240.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive.

The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

As described above, the present invention can minimize noise due to the enlargement of the plasma display panel by covering at least one signal line between the main control unit and each electrode driving unit with a shielding conductor.

1 is a block diagram of a driving apparatus included in a general plasma display panel.

2 is a block diagram of a plasma display panel including a driving device according to the present invention.

Claims (4)

A plasma display panel comprising a driving device electrically connected to an X electrode, a Y electrode, and a Z electrode. The drive device, An X electrode driver for forming a wall voltage in the pixel cell by applying a data pulse to the X electrode; A reset pulse is applied to the Y electrode to remove the remaining charges, a scan pulse is applied to the Y electrode to form a wall voltage in the selected pixel cell according to the data pulse, and then a sustain pulse is applied to the Y electrode to A Y electrode driver for maintaining a discharge of the; A Z electrode driver for applying a sustain pulse alternately with the sustain pulse applied by the Y electrode driver to a Z electrode to maintain discharge of the pixel cell; And A main controller electrically connected to the X electrode driver, the Y electrode driver, and the Z electrode driver through a signal line, and transmitting a control signal and an image signal through the signal line; At least one of the signal lines is shielded. The method of claim 1, And the shielding of the signal line covers the signal line with a shielding conductor. The method of claim 2, And the shielding conductor is grounded. The method according to claim 1 or 3, A heat dissipation plate made of a conductor material for dissipating heat due to the operation of the driving device is attached to the rear surface of the plasma display panel, and the shielding conductor is electrically connected to the heat dissipation plate. panel.