KR100312514B1 - Plasma Display - Google Patents

Abstract

The present invention relates to a plasma display device configured to increase luminous efficiency.

The plasma display device according to the present invention has a plurality of discharge cell spaces formed by a lower substrate, an upper substrate, and a partition wall formed between the substrates, and the discharge cells are formed on the upper substrate to generate an address discharge, the upper substrate and A sustain electrode pair formed on the lower substrate facing each other to cause sustain discharge; a dielectric layer formed on the sustain electrode pair; and a floating electrode formed on the dielectric layer and floating at a predetermined voltage level by charge generated by the discharge; A protective film formed on the floating electrode, it characterized in that it comprises a phosphor formed on the partition wall.

Accordingly, the plasma display device according to the present invention improves luminous efficiency and light transmittance.

Description

Plasma Display

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flat panel display, and more particularly, to a plasma display configured to increase luminous efficiency and light transmittance.

Recently, liquid crystal displays (hereinafter referred to as 'LCD'), field emission displays (hereinafter referred to as 'FED') and plasma display panels (hereinafter referred to as 'PDP') Flat display devices such as PDP have been actively developed. Among them, PDP is easy to manufacture due to its simple structure, high brightness and high luminous efficiency, memory function, and has a wide viewing angle of 160 ° or more, and realizes a large screen of 40 inches or more. It has the advantage of being able to.

Referring to FIG. 1, a conventional PDP has a lower substrate 14 on which an address electrode 2 is mounted, and a dielectric layer coated on the lower substrate 14 with a predetermined thickness to form a wall charge. (18), barrier ribs (8) formed on top of dielectric layer (18) for dividing respective discharge cells, phosphors (6) excited and emitted by light generated by plasma discharge, and upper substrate (16). A sustain electrode pair 4 formed transparently on top of the dielectric layer, a dielectric layer 12 applied on the upper substrate 16 and the sustain electrode pair 4 to a predetermined thickness to form wall charges, and a dielectric layer 12 And a protective film 10 having a high secondary electron emission coefficient and protecting the dielectric layer 12 from sputtering caused by discharge. When a predetermined discharge generation voltage (for example, 200 V) is applied to one of the address electrode 2 and the sustain electrode 4, a high electric field is formed inside the discharge cell, thereby causing plasma discharge. In detail, electrons emitted from an electrode collide with atoms of He + Xe gas or Ne + Xe gas enclosed in a discharge cell to ionize atoms of the gas and release secondary electrons by collision between ions and a protective film. When this happens, the secondary electrons ionize atoms in sequence while repeating collisions with atoms of gas. In other words, they enter the avalanche process, where electrons and ions double. The light generated in the avalanche process is excited to emit red (Red; 'R'), Green (hereinafter, 'G'), and Blue (hereinafter, 'B') phosphors. The light of R, G, and B emitted from the phosphor passes through the passivation layer 10, the dielectric layer 12, and the sustain electrode pair 4 to the upper substrate 16 to display characters or graphics. Meanwhile, the partition 8 is formed in a stripe shape to divide each discharge cell and to reflect the light emitted from the phosphor 6 toward the upper substrate 16. At this time, the bus electrodes 20 are formed to apply a stable driving voltage to the sustain electrode pair 4. The bus electrode 20 has a problem that the light transmittance is lowered by blocking visible light traveling to the upper substrate 16.

In addition, in the conventional PDP, the initial discharge occurs between the pair of sustain electrodes having a narrow interval, but the resistance value of these electrodes is high, so that the current flow is not smooth, and the discharge is maintained between the bus electrodes having a lower resistance value than the sustain electrode. Happens in In practice, the distance between the bus electrodes to be discharge sustained is about 500-600 mu m. At this time, if the distance is increased, the discharge area is increased, so that the intensity of visible light increases in response to the increase in the amount of vacuum ultraviolet rays. However, an increase in the distance between the electrodes leads to an increase in the discharge holding voltage, which leads to a problem in that the conventional PDP has a limit in increasing luminous efficiency. Accordingly, a new PDP is urgently needed to increase the luminous efficiency of the PDP.

Accordingly, an object of the present invention is to provide a plasma display device configured to increase luminous efficiency and light transmittance.

1 is a cross-sectional view showing the structure of a conventional plasma display device.

2 is a cross-sectional view showing the structure of a plasma display device according to the present invention;

3 is a plan view showing a structure viewed from the top of FIG.

4 is a view for explaining and comparing the conventional and the plasma display device of the present invention.

<Description of Symbols for Main Parts of Drawings>

2,32 address electrode 4,34 transparent electrode

6,36 phosphor Phosphor 8,38 partition wall

10: protective layer 12, 18, 42, 48: dielectric layer

14,44: Lower board 16,46: Upper board

20,50: bus electrode 52: floating electrode

In order to achieve the above object, a plasma display device according to the present invention has a plurality of discharge cell spaces formed by barriers formed between a lower substrate, an upper substrate, and a substrate, and the discharge cells are formed on the upper substrate to generate an address discharge. A predetermined voltage level by a sustain electrode pair formed on the electrode and a lower substrate facing the upper substrate to cause sustain discharge, a dielectric layer formed on the sustain electrode pair, and a charge formed on the dielectric layer by the discharge. And a phosphor formed on the floating electrode, a protective film formed on the floating electrode, and a partition wall.

Other objects and features of the present invention other than the above object will become apparent from the description of the embodiments with reference to the accompanying drawings.

With reference to Figures 2 to 4 will be described a preferred embodiment of the present invention.

Referring to FIG. 2, a plasma display device according to the present invention includes a lower substrate 44 on which a sustain electrode pair 34 is mounted, a bus electrode 50 formed on the sustain electrode pair 34, and the lower substrate 44. The dielectric layer 48 is coated on the substrate 44 to have a predetermined thickness to form a wall charge, and the dielectric layer 48 is mounted on the dielectric layer 48 to accumulate electric charges generated by plasma discharge. A floating electrode 52 which is floated on and a protective film 40 which is applied on the dielectric layer 48 to protect the dielectric layer 48 from sputtering due to discharge and emits secondary electrons, and a protective film A barrier rib formed on the upper portion of the 40 to divide each discharge cell, and a phosphor 36 applied to the inner wall of the partition 38 to be excited by light generated by the discharge and emit light. And an upper substrate 46 on which the address electrode 32 is mounted, and an upper substrate 46. A dielectric layer 42 is applied to the upper portion of the N-type to form a wall charge. Plasma discharge is generated by applying a predetermined discharge generating voltage between the sustain electrode pair 34 and the address electrode 32. At this time, wall charges are accumulated in the dielectric 48 of the pixel to be turned on. In this case, a predetermined charge is also accumulated in the floating electrode 52 mounted on the dielectric 48. That is, since the floating electrode 52 is a conductor mounted on the dielectric 48 and does not have a separate discharge path, the charge accumulated by the plasma discharge is floated at a predetermined voltage level. At this time, the charging conditions of the dielectric layer of the charge and the floating electrode are different according to the on / off of the plasma discharge of each cell, so that the floating electrode 52 has an island type separated from each cell as shown in FIG. Will be. The isolation of the floating electrode is performed by a protective film, and the protective film has a function of emitting secondary electrons by ion collision in addition to the function of isolating the floating electrode, thereby enabling generation and maintenance of discharge at a lower voltage.

Subsequently, when a discharge holding voltage having a predetermined voltage level is applied between the sustain electrode pairs 34, the sustain discharge is generated. This will be described in detail. During sustain discharge, the discharge sustain voltage corresponding to the floated voltage level is lowered by the floating electrode 52 floated to a predetermined voltage level. Accordingly, the discharge sustain voltage is lowered by using the memory voltage accumulated in the floating electrode 52. In addition, when the voltage is lowered, the discharge area may be increased by increasing the distance between the bus electrodes, thereby generating brighter visible light at a conventional power consumption level. That is, since the PDP according to the present invention is driven by lowering the sustain driving voltage, the luminous efficiency is increased. On the other hand, in the PDP according to the present invention, since the conventional upper and lower plate structures are reversed, the phosphor 36 is not applied to the lower plate surface but is applied only to the inner wall of the partition wall 38, thereby reducing the coating area than the conventional PDP. Accordingly, the PDP according to the present invention preferably increases the height of the partition wall so as to increase the coating area and the discharge volume of the phosphor. On the other hand, since the distance between the bus electrodes and the floating electrode is maximized to increase the discharge area, crosstalk may occur. Accordingly, it is preferable to configure the partition wall in a lattice form so as to limit the discharge performed in each discharge cell to prevent crosstalk and to increase the coating area of the phosphor.

4, there is shown a structure of a conventional PDP and a PDP according to the present invention. In the conventional PDP, as shown in Fig. 4A, a vacuum type ultraviolet ray generated by plasma discharge excites phosphors coated on the inner wall of the partition and the dielectric and generates visible light. On the other hand, the PDP according to the present invention uses a transmission type in which the vacuum ultraviolet rays generated by the plasma discharge excite the phosphor coated on the inner wall of the partition as shown in Fig. 4 (b) to generate visible light. If the phosphor is not applied to the upper or lower plate, the brightness of visible light decreases due to the reduction of the coating area. Accordingly, after the barrier ribs are formed in a lattice shape, the discharge area can be increased by coating phosphors on the inner wall of the barrier ribs, and the discharge barriers have a larger discharge area. Accordingly, it is preferable that the barrier height of the present invention be formed at least higher than the barrier height (for example, 150-200 mu m) of the conventional PDP to increase the phosphor coating area. In addition, the PDP according to the present invention uses a multi-layer panel having a complicated structure including the floating electrode 52 on the lower substrate 44 to be used as a lower plate, and includes an address electrode having a relatively simple structure. By using the upper substrate as a top plate, the transmittance of visible light is increased. In addition, by applying a transmission type of vacuum ultraviolet (Vacuum UV) or visible light is short, the light loss is reduced. In addition, the lower plate structure used in the PDP according to the present invention was used as the upper plate structure in the conventional PDP, but as the floating electrode is added, it is used as the lower plate in consideration of the ease of the process and the transmittance of visible light. As described above, in the plasma display device of the present invention, the height of the barrier rib is increased to increase the coating area of the phosphor, and thus the barrier rib is formed into a grid to prevent crosstalk. Accordingly, in the plasma display device according to the present invention, the discharge sustaining voltage is lowered by arranging the floating electrode to improve the light emitting efficiency, and to improve the light transmittance by adopting a top and bottom plate structure that is inverted.

As described above, the plasma display device according to the present invention has an advantage of improving luminous efficiency and light transmittance.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (6)

A lower electrode, an upper substrate, and a plurality of discharge cell spaces formed by barrier ribs formed between the substrates, wherein the discharge cells are formed on the upper substrate to generate an address discharge; A pair of sustain electrodes formed on the lower substrate facing the upper substrate to cause sustain discharge; A dielectric layer formed on the sustain electrode pairs; A floating electrode formed on the dielectric layer and floating at a predetermined voltage level by charge generated by the discharge; And a protective film formed on the floating electrode, and a phosphor formed on the partition wall. The method of claim 1, And a bus electrode is formed on each of the sustain electrode pairs in the discharge space. The method of claim 2, And the height of the barrier rib is at least 200 μm. The method of claim 3, wherein And the barrier rib is formed in a lattice shape to prevent crosstalk. The method of claim 1, And the floating electrode is island type separated for each cell. The method of claim 2, And the distance between the sustain electrode and the bus electrode pair is maximized in the discharge cell.