KR100267554B1 - 3-electrode surface discharge plasma display panel - Google Patents

Abstract

PURPOSE: A three-electrode surface discharge type plasma display panel is provided to increase luminance by enlarging an interval between a scan electrode and a sustain electrode. CONSTITUTION: A surface of a three-electrode surface discharge type plasma display panel is formed by an upper glass(410). A scan electrode(420) is formed on a lower surface of the upper glass(410). An insulating material(430) is applied on a surface of the upper glass. A sustain electrode layer(450) including a sustain electrode(440) is formed on the insulating material(430). And, the scan electrode(420) and the sustain electrode(440) are formed on the same plane with parallel each other. A magnesium oxide thin film(460) is formed on the sustain electrode layer(450). A lower glass(470) is located parallel to the upper glass(410). The first and the second address electrodes(480,490) are adhered on an upper face of the lower glass(470). A barrier rib(500) is laminated on the lower glass(470). A fluorescent material(510) is formed on a part of the barrier rib(500) and a surface of the lower glass(470). A discharge space(520) is formed by the fluorescent material(510), the barrier rib(500), and the magnesium oxide thin film(460).

Description

3-electrode surface discharge plasma display panel

The present invention relates to a three-electrode surface discharge PDP, and more particularly, to a three-electrode surface discharge PDP in which a cell structure is modified to reduce intercell interference and improve color purity.

The CRT (Cathode Ray Tube), which has been the mainstay of the display means, scans the electron beam through the entire fluorescent surface with a single electron gun, so the distance between the fluorescent surface and the electron gun must be large.

Due to the above characteristics, CRT is bulky, heavy, difficult to implement a flat screen, and difficult to realize a large screen.

In order to overcome the problems of the CRT as described above, various display technologies such as LCD, flat vision panel, and plasma display panel (PDP) are thin and light and enable large screen realization.

Among them, the PDP is applied to the surface of the rear substrate by ultraviolet rays generated when a discharge gas is injected between the thin front substrate and the rear substrate on which the plurality of transparent electrodes are formed, and discharged by applying a voltage between the transparent electrodes. The phosphor emits light, and each of the light emitting elements composed of the electrode and the phosphor is formed of cells separated by partition walls, and each of them is driven independently. Not only is it easy to implement a large screen, but also has the advantage of eliminating color bleeding and deterioration of focus, so it has become a focus of attention as a new display means that can overcome the limitation of CRT.

The PDP is classified into a DC PDP driven by a DC voltage and an AC PDP driven by a sine wave AC voltage or a pulse voltage according to the type of driving voltage. In this paper, only the AC PDP will be discussed.

1 is a diagram showing a cell structure of a typical three-electrode surface discharge PDP.

Referring to the drawings, an upper plate glass 10 forming a surface of a three-electrode surface discharge PDP, a scanning electrode (or Y electrode) 20 attached to a lower surface of the upper plate glass 10, and the scanning On the sustain electrode (or Z electrode) 30 and the scan electrode 20 and the sustain electrode 30 formed on the lower surface of the upper plate glass 10 in parallel with the electrode 20 at a small interval. And a dielectric 40 formed thereon, a magnesium oxide (MgO) protective film 50 coated on the dielectric, a lower plate glass 60 forming a back surface of a three-electrode surface discharge PDP, and an upper surface of the lower plate glass 60. An address electrode 70 formed at the upper surface of the lower plate glass 60, a partition wall 80 which is printed on the surface of the lower plate glass 60 to form a boundary between cells, a phosphor 90 formed on the address electrode 70 and a part of the partition wall; The discharge gas is formed into the space formed by the barrier rib 80, the phosphor 90, and the magnesium oxide protective film 50. It consists of the discharge space 100 which is the space injected.

However, in the conventional PDP having the above cell structure, since the height of the partition wall is not constant and isolation between cells is incomplete, there are problems such as misdischarge due to crosstalk between adjacent cells and inter-cell mixing.

In addition, the phosphor used in the PDP is generally used as a CRT phosphor, as the phosphor for CRT is not suitable for PDP, such as a weak blue color and a strong green color. There is a difficulty in generating color coordinates.

In FIG. 2, color mixing due to interference occurs over a partition wall between three adjacent cells having red (R), green (G), and blue (B) colors, respectively.

On the other hand, the longer the discharge path, which is the distance between the scan electrode and the sustain electrode, the luminance increases due to the discharge characteristics. As shown in FIG. 3, the scan electrodes Y ₁ , Y ₂ ,..., Y ₄₈₀ and the sustain electrode Z are shown in FIG. _In the conventional three-electrode surface discharge PDP in which ₁ , Z ₂ ,..., Z ₄₈₀ ) are formed parallel to the lower side of the upper glass with a small distance therebetween, the space between the scan electrode and the sustain electrode is increased. If the distance between them is closer to the distance between the other electrodes formed below the probability of malfunction increases, there is a limit to widening the distance between the electrodes.

The present invention has been made to solve the above problems of the prior art, the upper plate glass is formed only a scanning electrode (Y electrode), a thin transparent film having a sustain electrode (Z electrode) formed thereon, the lower electrode address electrode A cell of a three-electrode surface discharge PDP is formed so as to form two

Since the distance between the scan electrode and the sustain electrode is widened, the brightness is increased and the wall charges are easily generated during discharge, and the gap between the cells is reduced to reduce the interference between adjacent cells and to turn on / off two address electrodes. It is an object of the present invention to provide a three-electrode surface discharge PDP in which the brightness and color coordinates of each cell can be adjusted by adjusting OFF).

1 is a cross-sectional view showing a cell structure of a conventional three-electrode surface discharge plasma display panel (hereinafter referred to as a three-electrode surface discharge PDP);

2 is a diagram illustrating interference between adjacent cells;

3 is a view for explaining the influence of the distance between the scan electrode and the sustain electrode;

4 is a cross-sectional view showing a cell structure of a three-electrode surface discharge PDP according to the present invention;

5 is a view showing an electrode structure of a three-electrode surface discharge PDP according to the present invention.

<Description of the reference numerals for the main parts of the drawings>

410: top glass 420: scanning electrode

430: insulator 440: sustain electrode

450: sustain electrode layer 460: MgO thin film

470: lower glass 480: first address electrode

490: second address electrode 500: partition wall

510: phosphor 520: discharge space

The three-electrode surface discharge PDP of the present invention for solving the above object,

A top plate glass forming a surface of a three-electrode surface discharge PDP, a scan electrode attached to a lower surface of the top plate glass, an insulator layer coated on a surface of the top glass to cover the scan electrode, and the insulator A sustain electrode layer formed of a transparent material or a mesh structure on the layer to pass light and including a sustain electrode, a magnesium oxide (MgO) thin film formed on the sustain electrode layer, and the components of the upper plate; A lower plate glass disposed in parallel with a predetermined space therebetween; a first address electrode and a second address electrode formed on a top surface of the lower plate glass at a right angle with the scan electrode and the sustain electrode; And a barrier rib stacked on the lower pane and used as a boundary between cells, and a portion of the barrier rib and a surface of the lower pane. Phosphor and the discharge space formed by the fluorescent material and the partition wall and the magnesium oxide film formed to cover the scan electrode, characterized by comprising a structure in which discharge gas is injected.

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

4 is a view showing a cell structure of a three-electrode surface discharge PDP according to the present invention.

Looking at the cell structure of the PDP according to the present invention with reference to the drawings, the upper plate glass 410 to form the surface of the three-electrode surface discharge PDP, and the scanning electrode 420 attached to the lower surface of the upper plate glass 410 And an insulator 430 applied to the surface of the upper plate glass so as to cover the scan electrode 420, and formed of a transparent material or a mesh structure on the insulator 430 to pass light, as shown in the drawing. A sustain electrode layer 450 including a sustain electrode 440 in a portion, a magnesium oxide (MgO) thin film 460 formed on the sustain electrode layer 450, and a predetermined space between the upper plate components On the lower plate glass 470, the first address electrode 480 and the second address electrode 490 formed on the upper surface of the lower plate glass 470, and on the lower plate glass 470. A barrier rib 500 that is stacked and printed and serves as a boundary between cells; Phosphor 510 formed on a portion of the barrier rib 500 and the surface of the lower plate glass 470 to cover the address electrodes 480 and 490, and oxidation of the phosphor 510 and the barrier rib 500 and the upper plate structure. It is made of a discharge space 520 into which the discharge gas is injected into the space formed by the magnesium thin film 460.

In the present invention as described above, since the distance between the scan electrode 420 and the sustain electrode 440 is longer than in the case of the present invention, the discharge characteristics of the three-electrode surface discharge PDP whose luminance increases as the discharge path becomes longer The luminance can be increased by the thickness of the sustain electrode layer 450, and the gap between the upper plate structure and the partition wall becomes narrower, so that the isolation between adjacent cells becomes more secure. Unlike the conventional PDP in which the electrode is formed, the electrode is disposed toward the cell center space so that wall charges are evenly formed on the front of the panel during priming discharge, and reduce crosstalk and mis-discharge between adjacent cells. There is.

In addition, by controlling ON / OFF of the first address electrode and the second address electrode, brightness and color coordinates of each cell can be freely adjusted, and a priming pulse is supplied to every subfield. The contrast can be improved by supplying only once per frame.

5 is a view showing the electrode structure of the three-electrode surface discharge PDP according to the present invention as described above.

The solid line shown is a scan electrode formed on the lower surface of the upper glass and driven independently of each other, and the dotted line represents the sustain electrode of the sustain electrode layer formed on the dielectric formed on the scan electrode.

According to the present invention, unlike the conventional PDP in which the scan electrode and the sustain electrode are horizontally formed on the plane of the same substrate, the discharge path is short, the luminance is low, and there is interference between adjacent cells. By keeping the discharge path long, the discharge path is increased, and the brightness is increased. When priming discharges, wall charges are evenly formed on the front of the panel, and crosstalk and mis-discharge between adjacent cells are reduced.

In addition, by selectively turning on / off two address electrodes, the brightness and color coordinates of each cell can be adjusted freely, and without supplying a priming pulse to each subfield. Contrast can be improved by supplying only once per frame.

Claims (2)

An upper plate glass forming a surface of a three-electrode surface discharge plasma display panel (hereinafter referred to as a three-electrode surface discharge PDP), a scan electrode attached to a lower surface of the upper plate glass, and the upper plate to cover the scan electrode. An insulator layer coated on the surface of the glass, a sustain electrode layer formed on the insulator layer and including a sustain electrode, a magnesium oxide (MgO) thin film formed on the sustain electrode layer, and a component of the upper plate The lower plate glass positioned parallel to each other with a predetermined space therebetween, an address electrode formed on the upper surface of the lower plate glass so as to vertically intersect the scan electrode and the sustain electrode with a predetermined space therebetween, and the lower plate A partition wall formed as a boundary between cells on glass, a phosphor formed to cover the address electrode on a part of the partition wall and the lower plate glass, and the fluorescent lamp And it has a three-electrode surface discharge gas, characterized in a structure in which the injection discharge PDP discharge space formed by the partition and the magnesium oxide film. A top plate glass forming a surface of a three-electrode surface discharge plasma display panel (hereinafter referred to as a three-electrode surface discharge PDP), a scan electrode and a sustain electrode attached to a lower surface of the top plate glass, and the scan electrode and the sustain electrode An insulator layer applied on the surface of the top glass so as to cover the top, a magnesium oxide (MgO) thin film formed on the insulator layer, and parallel to the above-described components of the top plate with a predetermined space therebetween The lower plate glass positioned on the upper surface of the lower plate glass, the first and second address electrodes formed on the upper surface of the lower plate glass so as to vertically intersect with the scan electrode and the sustain electrode, and a boundary between cells on the lower plate glass. A barrier rib to be formed, a phosphor formed to cover the first and second address electrodes on a part of the barrier rib and the surface of the lower plate glass, the phosphor, the barrier rib, and the A three-electrode surface discharge PDP characterized by a structure in which a discharge gas is injected into a discharge space formed by a magnesium oxide thin film.