KR20020008732A - Alternative current plasma display panel apparatus of a symmetrical barrier rib structure - Google Patents

Abstract

PURPOSE: An alternating-current plasma display panel having symmetrical barrier rib structure is provided to improve color temperature, increase whole luminance, and prevent erroneous discharge due to plasma particle diffusion into adjacent cells, by varying appliance areas of phosphor by auxiliary barrier ribs. CONSTITUTION: An alternating-current plasma display panel(PDP) having symmetrical wall structure includes barrier ribs(303) for partitioning charge spaces between the front substrate and the back substrate of the PDP, and auxiliary barrier ribs(313,314,315). The auxiliary barrier ribs(313,314,315) are orthogonal to the barrier ribs(303) and are provided from the border of the barrier ribs(303) toward the center. The areas of the auxiliary barrier ribs(313,314,315) are varied cell by cell so as to make appliance area of blue phosphor material largest and appliance area of green phosphor material smallest among blue, red and green phosphor material.

Description

Alternating current plasma display panel apparatus of a symmetrical barrier rib structure

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel (PDP). In particular, the cell pitches of R, G and B coated barrier ribs using the grooved auxiliary barrier ribs are the same, but the total application area of the auxiliary barrier ribs is different. The present invention relates to an AC-type plasma display panel having a symmetrical partition wall structure that achieves an improvement in white purity due to an increase in brightness and a relative increase in brightness of a blue phosphor, and also varies an area of an auxiliary partition wall to prevent erroneous discharge between adjacent cells.

1 is an exploded perspective view of a front and rear substrates of a conventional surface discharge plasma display panel.

This shows a structure of a general three-electrode surface discharge PDP. Looking at the structure, the front substrate 101, which is the display surface of the image, and the rear substrate disposed in parallel with a predetermined distance from the front substrate 101 ( 102, wherein the front substrate 101 has a plurality of sustain electrode lines 108 and 109 formed on the opposite surface of the rear substrate 102 at predetermined intervals and formed on the plurality of sustain electrode lines 108 and 109 to be discharged. A transparent dielectric 110 for limiting a current, and a protective layer 111 formed on the transparent dielectric 110 and protecting the sustain electrode lines 108 and 109. The rear substrate 102 includes a plurality of discharges. A plurality of barrier ribs 103 having a stripe shape to form a space, a plurality of address electrode lines 104 formed to be orthogonal to the sustain electrode lines 108 and 109 between the barrier ribs 103, and An address electrode White dielectric 112 which protects the discharge current of phosphorus 104 and reflects visible light generated inside the discharge cell, and is applied to both of the partition 103 surface and the rear substrate 102 surface of the inner surface of each discharge space. And a red phosphor 105, a green phosphor 106, and a blue phosphor 107 that emit visible light upon discharge. The pair of sustain electrode lines 108 and 109 have a width of about 300 μm, and are composed of a transparent electrode line 108 and a bus electrode line 109, and the transparent electrode line 108 is supplied with discharge voltage at both ends. When the inter-surface discharge is generated in the corresponding discharge space, the bus electrode line 109 is formed of a metal material having a width of about 50 to 100 μm and formed on the transparent electrode line 108, respectively. To prevent the voltage drop caused by resistance.

2 is a cross-sectional view of a discharge space of a conventional plasma display panel.

FIG. 2 is a cross-sectional view of the plasma display panel apparatus after the front and rear substrates of FIG. 1 are combined, and the upper substrate is rotated by 90 ° for clarity. The image display process of any cell in the PDP according to the related art thus constructed is as follows. First, when the discharge start voltage of about 150V to 300V is supplied to the transparent electrode line 208 and the address electrode 204, wall charges are formed on the inner surface of the discharge space.

Thereafter, when an address discharge voltage is supplied to the transparent electrode line 208 and the address electrode line 204, an address discharge occurs between the transparent electrode line 208 and the address electrode line 204, that is, a cell. An electric field is generated inside, and the electrons in the discharge gas are accelerated, and the accelerated electrons and neutral particles in the gas collide with each other and are ionized to electrons and ions. The particles are ionized into electrons and ions at a rapid rate, and the discharge gas is brought into a plasma state and vacuum ultraviolet rays are generated. The generated ultraviolet light excites the red phosphor layer 205, the green phosphor layer (not shown, corresponds to 106 in FIG. 1), and the blue phosphor layer (not shown, corresponds to 107 in FIG. 1) to generate visible light and generate the visible light. When the visible light is emitted to the outside through the front substrate 201, light emission, that is, image display, of any cell can be recognized from the outside. Thereafter, when the sustain discharge voltage of about 150V or more is supplied to the transparent electrode line 208, the sustain discharge occurs between the transparent electrode lines 208 so that light emission of any cell is maintained for a predetermined time.

However, the PDP barrier ribs have a stripe type, and R, G, and B phosphors are coated with the same area, but the white phosphor is degraded due to the strong emission intensity of the green phosphor and the low emission intensity of the blue phosphor. have.

In general, PDP luminance improves light emission luminance as the area of application of phosphor is larger. In the conventional PDP, barrier ribs have a stripe type, and R, G, and B phosphors are applied with the same area, but the intensity of green phosphor and the intensity of blue phosphor are low. There was a problem that the white purity is lowered due to the luminous intensity. To solve this problem, the white purity is improved by an asymmetric bulkhead structure that increases the coating area of the blue phosphor only, but this asymmetric structure is discharged by changing the discharge space of the R, G and B phosphor cells driven by the same electrode. There is a disadvantage of lowering the efficiency. In addition, the existing stripe-type barrier rib structure, whether symmetrical or asymmetrical, still has a problem in that the generated plasma particles are diffused into other cells so that misdischarge between adjacent cells occurs.

The present invention is to solve the problems of the prior art as described above, by forming an auxiliary partition having grooves in both partitions in the direction intersecting the partitions in each discharge space boundary between the main partitions, the application area of the phosphor to each cell Increase it differently. In particular, since the luminance of the blue phosphor is relatively low, the area of the auxiliary bulkhead for the blue phosphor is increased as much as possible, and then the color temperature is maintained by minimizing the area of the auxiliary electrode in the order of the red phosphor auxiliary bulkhead and the green phosphor bulkhead to maintain the white balance. In addition, the total brightness is increased, and at the same time, erroneous discharge due to diffusion of plasma particles between adjacent cells is prevented.

1 is an exploded perspective view of a front and rear substrates of a conventional surface discharge plasma display panel.

2 is a cross-sectional view of a discharge space of a conventional plasma display panel.

3 is a symmetrical partition structure having different areas of the auxiliary partition wall according to the present invention.

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

3 is a symmetrical partition structure having different areas of the auxiliary partition wall according to the present invention. This is in accordance with the present invention shows the structure of the secondary partitions (313,314,315) in the vertical direction of the partition wall 303 at the boundary between the partition wall 303 and the direction of the center portion in the partition wall 303.

The auxiliary barrier ribs 313, 314 and 315 are positioned at the boundary of the discharge space formed by the discharge between the pair of sustain electrode lines (not shown, corresponding to 208 and 209 of FIG. 2) and the red phosphor 305, Green phosphor 306 and blue phosphor 307 are applied thereon. At this time, the phosphors of R, G, and B are similarly applied to the portions indicated by R, G, and B in FIG. The secondary barrier ribs 313, 314, 315 of the present invention have different areas for each cell, so that the area of application of the red, green, and blue phosphors applied to each cell is in the order of blue, red, and green, thereby increasing the luminance due to the increase of the total area. White purity is improved due to the relative increase in blue.

In addition, the diffusion of the plasma particles into the adjacent cells due to the auxiliary partition wall is significantly reduced, thereby reducing the false discharge. At this time, in the boundary between the barrier ribs, there is a groove vacated in the center of the barrier cell in order to facilitate gas exhaust and injection during the PDP manufacturing process in the vertical direction of the barrier rib and the barrier rib toward the center portion. In the process, the flow of gas inside the panel is desired.

The present invention relates to a new bulkhead structure having a grooved auxiliary bulkhead in an AC plasma display panel (PDP), wherein the main bulkhead is red (R), green (G), and blue (blue). B) The discharge space of each cell to which the phosphor is applied has the same symmetrical structure, and the area of the auxiliary partition wall with grooves is changed according to the R, G, and B phosphors, thereby changing the application area of the entire R, G, and B phosphors. On the discharge side, in the state where stable driving of symmetrical structure is possible, the brightness of blue is relatively increased to achieve white balance, thereby improving the image quality by improving color temperature, and also increasing the overall phosphor coating area due to the addition of auxiliary partitions. By doing so, it is possible to prevent an increase in overall luminance and an erroneous discharge between adjacent cells.

As described above, the present invention compensates the relative luminance of the blue phosphor while maintaining the symmetrical structure in the discharge structure of the R, G, and B cells by varying the area of the auxiliary partition between unit cells as compared with the conventional stripe type barrier rib structure. Therefore, it is possible to improve the color temperature while maintaining stable discharge of the R, G, and B cells, and to increase the overall brightness to improve the PDP efficiency, thereby improving the image quality. In addition, due to the auxiliary barrier ribs, it is possible to prevent mis-discharge between adjacent cells, and since the central portion of the auxiliary barrier ribs is empty, there is no problem in the flow of gas during the exhaust and injection of the gas in the PDP production.

Claims (3)

A storage electrode line, a dielectric layer, and a protective layer are sequentially formed on a front substrate of two substrates coupled in parallel, and an address electrode is arranged on a rear substrate in a direction crossing the storage electrode line, and the front substrate and the rear substrate are formed. In the AC plasma display panel device in which a stripe-shaped partition wall is formed between the discharge spaces, Formation of an auxiliary partition wall in a vertical direction of the partition wall at a boundary between the partition walls and in a direction from the partition wall to a center part; AC plasma display panel device having a symmetric partition wall structure including a The method of claim 1, Varying the formation area of the auxiliary barrier ribs while the spacing between the cells of the R, G, and B phosphors is constant so that the barrier ribs control the coating area of the R, G, and B phosphors between the cells; AC plasma display panel device having a symmetrical partition structure The method of claim 1, A groove is formed in the center of the partition cell so that gas is exhausted and injected during the PDP fabrication process in the vertical direction of the partition wall and the partition wall at the boundary between the partition walls; AC plasma display panel device of the symmetrical partition wall structure further comprising