KR200145246Y1 - Plasma display device - Google Patents

Abstract

According to the present invention, the phosphors 55 are uniformly applied to each pixel of the plasma display device so that the phosphors 4 are uniformly coated on the lower panel 50 to improve color purity by accurately adjusting the back balance during discharge. In addition, the scan electrode 1 and the data electrode 2 are vertically formed, and the pixels are formed so as to face each other. The color purity can be improved by connecting the transparent electrodes 3 to each other.

Description

Plasma display device

1 is a schematic plan view showing a plasma display device according to the present invention, in which (a) is an overall configuration, (b) is a data electrode, and (c) is an arrangement of scan electrodes.

2 is a partially enlarged cross-sectional view showing the main part of the present invention.

3 is a partially enlarged cross-sectional view showing a typical plasma display device.

* Explanation of symbols for main parts of the drawings

1: Stan electrode 2: Data electrode

3,31,32: transparent electrode 4: phosphor

The present invention relates to a plasma display device, and more particularly, to a plasma display device capable of improving color purity by making the luminous efficiency uniform for each pixel.

In general, a flat panel display device is classified into a liquid crystal display (LCD) device, a fluorescent display device (Vaccum Fluorecent Device), a plasma display device (Plasma Display Panel), an electroluminescent device (Electro Luminescence Panel), etc. The plasma display device is a device utilizing the gas discharge effect.

The plasma display device includes a matrix type electrode disposed between upper and lower panels, inert gas is injected therebetween, and then sealed.

Here, the driving method of the plasma display device is classified into a direct current driving method and an alternating current driving method. In the direct current driving method, an electrode is exposed to a gas, and the alternating current driving method is covered with a dielectric.

In particular, the configuration of the DC display plasma display device includes a plurality of scan electrodes 51 sequentially formed at a predetermined interval on the lower panel 50 as shown in FIG. The partition wall 52 formed to separate the electrodes 51 to form pixels, and the data formed on the bottom surface of the upper panel 53 so as to be orthogonal to be spaced apart by the scan electrode 51 and the partition wall 52. (Data) An electrode 54 is provided.

Of course, the scan electrode 51 becomes the cathode, the data electrode 54 becomes the anode, and the phosphor 55 is coated on the side surface of the partition 52.

In the above-described DC driving plasma display device, one pixel is selectively emitted when the data electrode 54 is selected when the scan electrode 51 is sequentially selected. Transition to low current and townsend regions, which cause dielectric breakdown and increase exponential ionization.

In addition, the exponential increase in ionization generates secondary electrons, ionizes them again, and transitions to a subnormal glow region where space charges are formed when more than one ion is generated.

After the sub normal glow region, the ionization is further enhanced to expand to the normal glow region where the light emitting region is enlarged without increasing the voltage, and to move to the abnormal glow to emit light. If it is increased, the discharge tube is broken by the transition to the arc region, so that the current limiting resistor is connected to prevent the discharge tube.

Of course, the plasma display device uses a discharge color of a gas in the case of a single color, and emits phosphor by using a vacuum ultraviolet ray generated at the discharge in the case of a color, thereby using the color generated here.

In other words, the phosphor 55 applied to the partition wall 52 emits light by the discharge generated by the scan electrode 51 and the data electrode 54.

Here, the monochromatic plasma display device uses a PWM (Pulse Width Modulation) method for adjusting the time width of the waveform and PAM (Pulse Amplitude Modulation) method for adjusting the waveform width height for gray scale display. do.

In particular, in the color plasma display device, a memory driving method is used to increase luminance, which means that a pixel discharged by a voltage higher than the discharge start voltage is continuously supplied in one field or one subfield by continuously supplying a minimum discharge sustain voltage. By increasing the luminance.

However, as described above, the scan electrodes 51 and the data electrodes 54 are disposed to face each other at right angles to each other, and the phosphor 55 is applied to the partition walls 52 forming one pixel to drive the pixels. 52 is not uniformly applied to each pixel, so that it is impossible to accurately adjust the back balance, and thus, color purity is deteriorated.

Accordingly, an object of the present invention is to provide a plasma display device which can improve color purity by precisely adjusting the back balance during discharge by uniformly applying phosphors for each pixel of the plasma display device.

In order to achieve the above object, the present invention provides a plasma display device including a scan electrode and a data electrode that are overturned by transparent electrodes drawn from the scan electrode driver and the data electrode driver, respectively, and arranged on the upper panel and the lower panel, respectively. The scan electrode and the data electrode are each formed in a wall shape standing upright between the upper panel and the lower panel, and the scan electrode and the data electrode are alternately withdrawn from the transparent electrode in the XY axis direction. The pixel cells facing each other are formed.

Hereinafter, with reference to the accompanying drawings illustrating a preferred embodiment of the present invention.

(A) to (c) are schematic plan views of the plasma display device according to the present invention, and either one of the upper panel 50 or the lower panel 53 has a scan electrode as shown in FIG. The scan electrode 1 connected to the transparent electrode 31 from the driver D1 is arranged, and the other is connected to the transparent electrode 31 drawn out from the data electrode driver D2 as shown in FIG. The data electrodes 2 are arranged.

Here, in the cell P forming each pixel formed by the scan electrode 1 and the data electrode 2, the two electrodes 1, 2 face each other instead of intersecting as in the prior art.

The scan electrode 1 and the data electrode 2 connected to the transparent electrodes 3, 31, and 32 which are drawn out from both driving units D1 and D2 and cross each other in a matrix form are connected to each pixel cell P. FIG. In order to face each other, the scan electrode 1 and the data electrode 2 are alternately drawn out from the transparent electrodes 3, 31 and 32 in the XY axis direction. For example, looking at the uppermost data electrode 2, the top pixel is drawn in the X-axis direction, the next pixel is drawn in the Y-axis direction, and the next pixel is drawn in the X-axis direction.

The scanning electrode 1 corresponding thereto is drawn out in the X-axis direction with respect to the transparent electrode 31 for the top pixel, in the Y-axis direction for the next pixel, and again in the X-axis direction for the next pixel. In each cell P, the scan electrode 1 and the data electrode 2 face each other.

As such, when the two electrodes 1 and 2 facing each other are arranged on the upper panel 50 and the lower panel 53, plasma discharge may occur even if the thin electrode is formed as in the prior art.

In this case, however, in order to prevent interference such as crosstalk between adjacent cells, a partition (52 in FIG. 3) must be provided to restrict the movement of charged particles between cells.

In order to separate the operation of each cell without a partition, in the present invention, as illustrated in FIG. 2, the scan electrode 1 and the data electrode 2 are erected in a wall form between the upper and lower panels 50 and 53. Was formed.

The configuration of the electrodes 1 and 2 should be made by a lamination printing method, but this replaces the conventional printing of the partition wall 52, and thus there is no difficulty in manufacturing or addition of labor.

According to such a configuration, each cell P forms a rectangular space surrounded by the scan electrode 1 and the data electrode 2 of the corresponding cell and the scan electrode and the data electrode of both adjacent cells.

For example, the cell P, which is indicated by a dotted circle in FIG. 1 (a), extends in the X direction up and down to face each other and the data electrode 2 and the scan electrode 1, and the Y-direction scan electrode in the left adjacent cell. It is surrounded by the Y-direction data electrode of the right adjacent cell.

Here, the crosstalk is generated when discharge is induced in the corresponding cell P when at least one of the left and right adjacent cells is selected.

First, although the Y-direction scan electrode of the left adjacent cell and the Y-direction data electrode of the right adjacent cell face each other, the distance between them is the distance between the two electrodes 1, 2 of the corresponding cell (this distance is the minimum for rapid discharge). Formed by a discharge gap of) so that there is no fear of a discharge occurring therefrom.

Next, the X-direction scan electrode 1 of the cell P, the Y-direction data electrode of the right adjacent cell, and the X-direction data electrode 2 of the cell P and the Y-direction scan electrode of the left adjacent cell Although adjacent to each other, the opposite area is small, so that no discharge occurs.

On the other hand, when discharge occurs in the corresponding cell P, the charged particles filled in this space are moved to adjacent cells by the gap between the electrodes at the edge of the space. By designing and manufacturing by adjusting the gap between electrodes so that the amount of movement does not cause a discharge, these moving charged particles are possible as priming particles which induce a rapid discharge.

Therefore, when the device of the present invention is sequentially scanned by a general matrix driving method, an image can be displayed. Preferably, the lower panel 50 is coated with a phosphor 4 such as an ultraviolet-excited phosphor to display a desired color image.

Since the phosphor 4 that emits light is in a uniform state for each pixel, the luminous efficiency of each pixel becomes uniform, thereby improving the color purity of the overall plasma display device.

As described above, since the scan electrode 1 and the data electrode 2 are vertically formed to face each other, the pixel can be formed without the partition wall.

As described above, the present invention is applied to the lower panel with a uniform thickness, the scan electrode and the data electrode are formed vertically, and are formed so as to be opposed to each other, and to form a color purity by connecting them to each transparent electrode There is an advantage that can be improved.

Claims (1)

10. A plasma display device comprising a scan electrode and a data electrode connected by transparent electrodes drawn out from a scan electrode driver and a data electrode driver, respectively, arranged on an upper panel and a lower panel, wherein each of the scan electrode and the data electrode is the same. The pixel is formed in a wall shape upright between the upper panel and the lower panel, and the scan electrode and the data electrode are alternately withdrawn from the transparent electrode in the XY axis direction, so that the wall scan electrode and the data electrode face each other. A plasma display device, characterized in that the cell is formed.