KR20040006627A - Structure of electrode for plasma display panel - Google Patents

Abstract

PURPOSE: An electrode structure for a plasma display panel is provided to improve brightness and efficiency by reducing a power consumption. CONSTITUTION: An electrode structure for a plasma display panel comprise a pair of sustain electrodes(50,52) and an address electrode(71). The pair of sustain electrodes are patterned to include bridges face to each other by a discharge cell. The address electrode are patterned to be equal to the pair of sustain electrodes shape, and crosses to the sustain electrodes vertically.

Description

Electrode Structure of Plasma Display Panel {STRUCTURE OF ELECTRODE FOR PLASMA DISPLAY PANEL}

The present invention relates to a plasma display panel, and more particularly, to an electrode structure of a plasma display panel to improve efficiency and brightness.

Plasma Display Panels (hereinafter referred to as 'PDPs') typically display characters or graphics by emitting phosphors by 147 nm ultraviolet rays generated during gas discharge such as He + Xe, Ne + Xe, He + Ne + Xe. The included image is displayed. Such PDPs are attracting attention as large-area flat panel displays due to their ease of thinning and large size, as well as expanding the market with the recent commercial production of companies.

1 and 2, a structure of a PDP of a three-electrode alternating current (AC) type which is commonly used is shown.

As shown in FIGS. 1 and 2, the PDP includes sustain electrode pairs 14 and 16 periodically formed on the upper substrate 10, and upper dielectric layers 18 formed on the sustain electrode pairs 14 and 16. And a protective layer 20, an address electrode 22 periodically formed on the lower substrate 12, a lower dielectric layer 24 formed on the address electrode 22, and a partition wall formed on the lower dielectric layer 24. And a phosphor layer 28.

The upper substrate 10 and the lower substrate 12 are spaced in parallel by the partition wall 26. The partition wall 26 is formed in parallel with the address electrode 22 to prevent ultraviolet rays generated by the discharge from leaking to adjacent cells. The phosphor layer 28 is applied to the surfaces of the lower dielectric layer 24 and the partition wall 26 to generate visible light of any one of red, green, and blue. In addition, an inert gas for plasma discharge is injected into the discharge space formed by the partition 26 and the upper and lower substrates 10/12.

Each of the sustain electrode pairs 14 and 16 has a transparent electrode 14A and 16A made of transparent electrode material (ITO) having a light transmittance of 90% or more, and a metal electrode having a relatively narrower width than the transparent electrodes 14A and 16A. 14B, 16B). Here, the transparent electrode material (ITO) has a large resistance value and thus does not transmit power efficiently. Accordingly, the entirety of the sustain electrode pairs 14 and 16 is formed on the transparent electrodes 14A and 16A by forming metal electrodes 14B and 16B made of a highly conductive material, for example, silver (Ag) or copper (Cu). It will increase the conductivity. The sustain electrode pairs 14 and 16 are composed of a scan / sustain electrode and a sustain electrode. The scan signal for panel scanning and the sustain signal for sustaining discharge are mainly supplied to the scan / sustain electrode 14, and the sustain signal is mainly supplied to the sustain electrode 16.

The upper dielectric layer 18 and the lower dielectric layer 24 accumulate electric charges discharged from the sustain electrode pairs 14 and 16 and the address electrode 22 during discharge. The protective layer 20 serves to prevent damage to the upper dielectric layer 18 by sputtering of charged particles. This extends the lifetime of the PDP and increases the emission efficiency of secondary electrons. As the protective layer 20, magnesium oxide (MgO) is usually used.

The address electrode 22 is formed to intersect with the sustain electrode pairs 14 and 16. The address electrode 22 is supplied with a data signal for selecting cells to be displayed.

The PDP maintains the discharge by surface discharge between the pair of sustain electrodes 14 and 16 after the discharge cell is selected by the opposite discharge between the address electrode 22 and the scan / sustain electrode 14. In the discharge cell of the PDP, the fluorescent substance 28 emits light by ultraviolet rays generated during the sustain discharge, so that visible light is emitted outside the cell. As a result, the PDP displays an image in pixel units of discharge cells.

In such a PDP, the smaller the ratio of the electrode area to the cell area is, the higher the efficiency of the PDP is. In detail, the smaller the ratio of the electrode area, the smaller the reactive power consumed for charging the capacitance between the electrodes. Therefore, the PDP employing the electrode having a small proportion of the electrode area consumes less power and improves efficiency characteristics.

In addition, the larger the area of the opposite electrode and the shorter the distance between the electrodes, the more easily the discharge occurs even under a low applied voltage, thereby improving the discharge efficiency.

In addition, the smaller the ratio of the electrode area to the cell area is, the smaller the discharge current of the electrode is. That is, when the discharge current of the electrode is reduced, the self-absorption that the mixed gas filled in the cell absorbs the vacuum ultraviolet rays is reduced, so that a large amount of vacuum ultraviolet rays excite the phosphor. Therefore, the light emitting efficiency of the PDP employing the electrode having a small proportion of the electrode area is improved.

In order to apply this improvement effect, as shown in FIG. 4, a PDP employing a sustain electrode pair made of a T-shaped transparent electrode has been proposed.

Referring to FIG. 4, the sustain electrode pairs 30 and 32 of the proposed PDP include stripe-shaped metal electrodes 30A and 32A and transparent electrodes 30B, which protrude in a T shape from each of the metal electrodes 30A and 32A. 32B).

The metal electrodes 30A and 32A are located at both edges of the discharge cell and are formed of a highly conductive metal material such as silver (Ag) or copper (Cu).

The transparent electrodes 30B and 32B have a relatively wider width than the metal electrodes 30A and 32A and are formed in a T-shape to face each other.

The sustain electrode pairs 30 and 32 are composed of the scan / sustain electrode 30 and the sustain electrode 32. The scan signal for panel scanning and the sustain signal for sustaining discharge are mainly supplied to the scan / sustain electrode 30, and the sustain signal is mainly supplied to the sustain electrode 32.

When the ratio of the area occupied by the transparent electrodes 30B and 32B to the discharge cell area is reduced in the sustain electrode pairs 30 and 32, the discharge efficiency and the light emission efficiency are improved while consuming less power as described above. At this time, the discharge that occurs in the transparent electrode is generated on the opposite side of the transparent electrode (30B, 32B) and diffused toward the metal bus, the discharge path is long. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. However, the T-shaped transparent electrodes 30B and 32B have a larger area on the opposite side of the transparent electrodes 30B and 32B with shorter discharge paths than the metal electrodes 30A and 32A with longer discharge paths. Therefore, the PDP adopting the sustain electrode pair composed of T-shaped transparent electrodes reduces the area of the transparent electrodes, thereby improving the light emission efficiency and the discharge efficiency, but the luminance of the PDP is decreased due to the relatively large electrode area at the short discharge path. .

Accordingly, there is a need to develop an electrode capable of improving the efficiency of the PDP by reducing power consumption without lowering the luminance.

According to this need, an electrode of a PDP as shown in FIGS. 5A to 5C has been developed.

Referring to FIG. 5A, the sustain electrode pairs 40 and 42 of the PDP include metal electrodes 40A and 42A disposed at both edges of the discharge cell and trigger electrodes 40B and 42B disposed at the center of the discharge cell.

The metal electrodes 40A and 42A are made of a highly conductive metal material, for example, silver (Ag) or copper (Cu). The trigger electrodes 40B and 42B are formed in parallel with the metal electrodes 40A and 42A in a relatively narrow width compared to the metal electrodes 40A and 42A. The sustain electrode pairs 40 and 42 are composed of the scan / sustain electrode 40 and the sustain electrode 42.

When the discharge voltage is supplied to the sustain electrode pairs 40 and 42, a trigger discharge is generated at the trigger electrodes 40B and 42B which are formed between the scan / sustain electrode 40 and the sustain electrode 42 and located at the closest positions. . The charged particles formed in the trigger discharge induce long gap discharge of the two metal electrodes 40A and 42A. However, in these sustain electrode pairs 40 and 42, it is not structurally easy for the charged particles formed in the trigger discharge to move to the metal electrodes 40A and 42A for long gap discharge. Therefore, there is a disadvantage in that a high voltage must be applied to the metal electrodes 40A and 42A.

In order to compensate for this disadvantage, as shown in FIG. 5B, a bridge electrode 45 is provided between the metal electrodes 44 and 46 to allow the charged particles to move along the bridge electrode 45. When the discharge voltage is supplied to each of the sustain electrode pairs, the long gap discharge occurs easily because the charged particles can easily move to the metal electrodes 44 and 46 along the bridge electrode 45. At this time, higher luminance and efficiency can be obtained when at least two or more bridge electrodes 45 are shown as shown in FIG. 5C. That is, by arranging the plurality of bridge electrodes 47 in the vertical direction of the partition wall 26 between the two metal electrodes 44 and 46, the brightness and the efficiency are increased. However, as the number of bridge electrodes increases, the spacing between the bridge electrodes becomes narrower, and the current density increases accordingly. As a result, the luminance and the efficiency are reduced compared to the trigger electrodes arranged in a direction parallel to the partition wall 26 as shown in FIG.

Accordingly, an object of the present invention is to provide an electrode structure of a plasma display panel to improve brightness and efficiency.

1 is a perspective view showing a conventional three-electrode AC surface discharge plasma display panel.

FIG. 2 is a cross-sectional view illustrating the plasma display panel shown in FIG. 1.

3 is a plan view illustrating an electrode structure of the plasma display panel illustrated in FIG. 1.

4 is a plan view illustrating an electrode structure of another conventional plasma display panel.

5A to 5C are plan views illustrating electrode structures of another conventional plasma display panel.

6 is a cross-sectional view illustrating an electrode structure of a plasma display panel according to an exemplary embodiment of the present invention.

7A to 7C are plan views illustrating electrode structures of a plasma display panel according to a first embodiment of the present invention.

8A through 8C are plan views illustrating electrode structures of a plasma display panel according to a second exemplary embodiment of the present invention.

9A to 9C are plan views illustrating electrode structures of a plasma display panel according to a third exemplary embodiment of the present invention.

10A to 10C are plan views illustrating electrode structures of a plasma display panel according to a fourth exemplary embodiment of the present invention.

11A to 11C are plan views illustrating electrode structures of a plasma display panel according to a fifth embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10,61: upper substrate 12,62: lower substrate

14,50, Y1: Scanning electrode 16,52, Z1: Sustaining electrode

18,66: upper dielectric layer 20,67: protective layer

22,71,72,73,81,82,83,91,92,93,101,102,103,111,112,113, X1: address electrode

24, 64: lower dielectric layer 26, 54, 63: partition wall

28,65 phosphor layer

In order to achieve the above object, the electrode structure of the plasma display panel according to the present invention, the sustain electrode pair and the sustain electrode pair patterned to have a bridge facing each other in units of discharge cells, and at the same time, the bridge of the sustain electrode pair It is characterized by having an address electrode patterned to be the same as the form of. Here, the bridge-type electrode structure refers to an electrode having both ends connected to metal electrodes and having a central portion formed therein, such as a bridge located on the surface of water such as steel.

In the electrode structure of the plasma display panel according to the present invention, the address electrode is patterned in a structure in which a position intersecting with the bridge portion of the sustain electrode pair protrudes.

In the electrode structure of the plasma display panel according to the present invention, the address electrode is formed by dividing into two electrodes each crossing the vertical end portion of the bridge portion of the sustain electrode pair.

In the electrode structure of the plasma display panel according to the present invention, the address electrode has a structure in which two electrodes are connected to each other at positions crossing each of the transverse ends of the bridge portions of the sustain electrode pairs.

Other objects and advantages of the present invention in addition to the above object will be apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 6 to 11.

Referring to FIG. 6, a PDP having an electrode structure according to an embodiment of the present invention is formed on the sustain electrode pairs Y1 and Z1 periodically formed on the upper substrate 61 and the sustain electrode pairs Y1 and Z1. The upper dielectric layer 66 and the protective layer 67, the address electrode X1 periodically formed on the lower substrate 62, the lower dielectric layer 64 formed on the address electrode X1, and the lower dielectric layer ( A partition 63 formed on the 64 and the phosphor layer 65 are provided.

The upper substrate 61 and the lower substrate 62 are spaced apart in parallel by the partition wall 63. The partition 63 is formed in parallel with the address electrode X1 to prevent ultraviolet rays generated by the discharge from leaking into adjacent cells. The phosphor layer 65 is applied to the surfaces of the lower dielectric layer 64 and the partition wall 63 to generate visible light of any one of red, green, and blue. An inert gas for plasma discharge is injected into the discharge space formed by the partition 63 and the upper and lower substrates 61 and 62.

Each of the sustain electrode pairs Y1 and Z1 includes a transparent electrode 69a made of a transparent electrode material ITO having a light transmittance of 90% or more, and a metal electrode 69b having a relatively narrower width than that of the transparent electrode 69a. . Here, the transparent electrode material (ITO) has a large resistance value and thus does not transmit power efficiently. Therefore, the overall conductivity of the sustain electrode pairs Y1 and Z1 is increased by forming a metal electrode 69b made of a material having good conductivity, for example, silver (Ag) or copper (Cu), on the transparent electrode 69a. . The sustain electrode pairs Y1 and Z1 are composed of a scan / sustain electrode and a sustain electrode. The scan signal for panel scanning and the sustain signal for sustaining discharge are mainly supplied to the scan / sustain electrode Y1, and the sustain signal is mainly supplied to the sustain electrode Z1.

The upper dielectric layer 66 and the lower dielectric layer 64 accumulate electric charges discharged from the sustain electrode pairs Y1 and Z1 and the address electrode X1 during discharge. The protective layer 67 serves to prevent damage to the upper dielectric layer 66 by sputtering of charged particles. This extends the lifetime of the PDP and increases the emission efficiency of secondary electrons. As the protective layer 67, magnesium oxide (MgO) is usually used.

The address electrode X1 is formed to cross the sustain electrode pairs Y1 and Z1. The address electrode X1 is supplied with a data signal for selecting cells to be displayed.

The PDP maintains the discharge by the surface discharge between the pair of sustain electrodes Y1 and Z1 after the discharge cell is selected by the opposite discharge between the address electrode X1 and the scan / sustain electrode Y1. In the discharge cells of the PDP, the phosphor 65 emits light by ultraviolet rays generated during the sustain discharge, so that visible light is emitted outside the cell. As a result, the PDP displays an image in pixel units of discharge cells.

As described above, it can be seen that the PDP having the electrode structure according to the present invention is the same in the laminated structure as the conventional three-electrode AC surface discharge type PDP. In fact, the PDP having the electrode structure according to the present invention can be manufactured according to the conventional manufacturing process by modifying the pattern of the sustain electrode pair and the mask for manufacturing the address electrode without an additional process.

7A to 7B are plan views schematically illustrating a sustain electrode pair and an address electrode of a PDP having an electrode structure according to the first embodiment of the present invention.

In the PDP having the electrode structure according to the first embodiment of the present invention shown in FIG. 7A, each of the sustain electrode pairs 50 and 52 protrudes from the metal electrodes 50A and 52A and the metal electrodes 50A and 52A. Electrodes 50B and 52B are provided. Here, the sustain electrode pairs 50 and 52 become the scan / sustain electrode 50 and the sustain electrode 52.

The metal electrodes 50A, 52A of the sustain electrode pairs 50, 52 are formed of a metallic material having good conductivity, for example, silver (Ag) or copper (Cu).

Each of the protruding electrodes 50B and 52B is a vertical electrode 50C, 50E, 52C, 52E, which protrudes from the metal electrodes 50A, 52A in the direction parallel to the partition wall 54 at both edges of the discharge cell. (50C, 52C) and second electrodes 50E, 52E, and third electrodes 50D, 52D, which are horizontal electrodes 50D, 52D, which connect the vertical electrodes 50C, 50E, 52C, 52E, respectively. It is composed.

The protruding electrodes 50B and 52B are formed to have a relatively wider width than the metal electrodes 50A and 52A. As a result, the area of the electrodes facing the pairs of sustain electrodes 50 and 52 is large, whereby the sustain voltage gain can be sufficiently secured such that discharge occurs easily even at low voltage.

In addition, since the protruding electrodes 50B and 52B include vertical electrodes 50D and 52D parallel to the partition wall 54, the discharge path is spread along the vertical electrodes 50D and 52D parallel to the partition wall 54 during plasma discharge. do. As a result, the plasma discharge is generated at a close distance to the phosphor layer applied on the partition wall 54, and the ratio of vacuum ultraviolet rays generated at the time of discharge to the phosphor layer is increased, and the emission of visible light is increased accordingly. Therefore, the luminance of the PDP having the electrode structure according to the first embodiment of the present invention is improved.

Furthermore, since the protruding electrodes 50B and 52B have a distance from the partition wall 54, the amount of charged particles diffused toward the partition wall 54 or the phosphor is reduced. As a result, the PDP having the electrode structure according to the first embodiment of the present invention can be improved in brightness and efficiency without loss of the sustain voltage gain.

In detail, when the ratio of the electrode area to the area of the discharge cell is reduced, the reactive power consumed to charge the capacitance between the electrodes becomes smaller, so that the PDP employing the electrode having the smaller electrode area ratio consumes less power. Consumed.

The sustain electrode pairs 50 and 52 have a smaller ratio of the area occupied by the transparent electrodes 50B and 52B than the area of the discharge cell, and thus consume less power as described above, thereby improving discharge efficiency and luminous efficiency. At this time, the discharge that occurs in the transparent electrode occurs on the opposite side of the transparent electrodes 50B, 52B, and diffuses toward the metal bus, thereby extending the discharge path. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. The transparent electrodes 50B and 52B of the PDP having the electrode structure according to the first embodiment of the present invention have metal discharges 50A and 52A having a longer discharge path than those of the opposite surfaces of the transparent electrodes 50B and 52B having short discharge paths. The larger the area of) is, the higher the luminous efficiency and luminance of the PDP is. Therefore, the PDP employing the sustain electrode pair made of the transparent electrode reduces the area of the transparent electrode, thereby improving the luminous efficiency and the discharge efficiency and improving the luminance characteristic.

At this time, when the address electrodes are formed in a simple straight pattern as in the related art, since the intersection area between the address electrodes and the sustain electrode pairs 50 is small, the discharge voltage increases or misdischarges (or misses) occur during address discharge. As a result, the address voltage gain can be reduced. This problem can be solved by slightly altering the shape of the address electrode by increasing the cross-sectional area of the address electrode and the sustain electrode pair.

The address electrodes 71 shown in FIG. 7A are horizontal electrodes 50D and 52D of the first electrode portion 71a and the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52 having the same area as the conventional address electrodes. The second electrode portion 71b is formed to extend only the portion overlapping with each other and is patterned to correspond to the shape of the horizontal electrodes 50D and 52D of the protruding electrodes 50B and 52B of each of the sustain electrode pairs 50 and 52. As a result, the cross-sectional area of the sustain electrode pairs 50 and 52 and the address electrode 71 is wider than that of the conventional straight address electrode. As a result, an address voltage rise phenomenon or a miss discharge (or miswriting) phenomenon, which is caused by a small overlapping area of the sustain electrode pair and the address electrode, is prevented. Therefore, the address electrode 71 of the PDP having the electrode structure according to the first embodiment of the present invention increases the area overlapping with the sustain electrode pairs 50 and 52 so that address discharge can be stably generated. The pattern of the address electrode 71 includes all those formed to have a large area overlapping with the sustain electrode pair, and applicable embodiments thereof are shown in FIGS. 7B to 7C.

The address electrode 72 shown in FIG. 7B has a structure of “11” shape formed by dividing the conventional address electrode into two and overlapping the vertical electrodes 50C, 50E, 52C, 52E of the sustain electrode pairs 50, 52. Have The first address electrode 72A overlaps the vertical electrodes 50C and 52C of one of the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52, and the second address electrode 72B is the sustain electrode pair. The other of the protruding electrodes 50B, 52B of 50, 52 overlaps with the other vertical electrodes 50E, 52E. At the distal end of the address electrode 72, the first address electrode 72A and the second address electrode 72B are patterned to be coupled to each other, and the same voltage is applied to the pad portion at which the distal end of the address electrode 72 is located.

The address electrode 72 of this structure exhibits improved performance compared to the address electrode 71 shown in Fig. 7A. In detail, the address electrode 71 of FIG. 7A has a large area of the electrode at the center of the cell, thereby increasing the total area of the address electrode. As described above, when the area of the electrode is reduced, the power consumption of the electrode is reduced. Since the address electrode 71 of FIG. 7A is vice versa, power consumption is increased during address discharge. In addition, since the sustain electrode pairs 50 and 52 that cross the address electrode 71 correspond only to the horizontal electrodes 50D and 52D, the efficiency during address discharge is not so great. Therefore, the address electrode 72 of FIG. 7B is divided into the first address electrode 73A and the second address electrode 73B so as to have the same area as the conventional address electrode, and each of the vertical electrodes 50C, 50E, 52C, By forming parallel to 52E, the overlapping area of the sustain electrode pairs 50 and 52 and the address electrode 72 is increased. As a result, the PDP having the electrode structure according to the first embodiment of the present invention employing the address electrode 72 of Fig. 7B has a constant address electrode area formed in the cell so as to consume the same power consumption as before. In this case, the efficiency of address discharge can be improved.

Another applicable embodiment may be an address electrode as shown in FIG. 7C.

The address electrode 73 shown in FIG. 7C overlaps the horizontal electrodes 50D and 52D of the portion where the scan / sustain electrode and the sustain electrode face each other in the " 11 " shaped address electrode 72 shown in FIG. The third electrode portion 73C, which is a connection portion connecting the address electrode 73A and the second address electrode 73B, has a structure in which the address electrode 73 is patterned in a “H” shape. The address electrode 73 having such a structure has a large area where the sustain electrode pairs 50 and 52 and the address electrode 73 overlap with each other, thereby improving the efficiency of address discharge.

The sustain electrode pairs of FIGS. 8 to 11 are a slight modification of the electrode structure of the sustain electrode pairs 50 and 52 shown in FIG. 7.

8A to 8C are plan views schematically illustrating a sustain electrode pair and an address electrode of a PDP having an electrode structure according to a second embodiment of the present invention.

In the PDP having the electrode structure according to the second embodiment of the present invention shown in FIG. 8A, each of the sustain electrode pairs 50 and 52 protrudes from the metal electrodes 50A and 52A and the metal electrodes 50A and 52A. Electrodes 50B and 52B are provided. Here, the sustain electrode pairs 50 and 52 become the scan / sustain electrode 50 and the sustain electrode 52.

The metal electrodes 50A, 52A of the sustain electrode pairs 50, 52 are formed of a metallic material having good conductivity, for example, silver (Ag) or copper (Cu).

The protruding electrodes 50B and 52B are vertical electrodes 50C, 50E, 52C, and 52E protruding from the metal electrodes 50A and 52A in parallel with the partition wall 54 at both edges of the discharge cell, and each sustain electrode pair. The first electrode 50C, 52C and the second electrode 50E, 52E, which are the vertical electrodes 50C, 50E, 52C, 52E of (50, 52), are connected, and one side is a straight line 57 and the other side is a metal electrode. And the third electrodes 50D and 52D which are horizontal electrodes 50D and 52D having a triangular protrusion form 56 toward 50A and 52A.

The electrode according to the second embodiment of the present invention has a triangular protrusion 56 so that the electrode area becomes larger than that of the horizontal electrode of the first embodiment. As a result, the cross-sectional area with the address electrode passing through the center of the discharge cell becomes large, so that discharge occurs easily even under low voltage, and thus the address voltage gain can be secured during address discharge, thereby improving discharge efficiency.

In addition, since the protruding electrodes 50B and 52B include vertical electrodes 50D and 52D parallel to the partition wall 54, the discharge path is spread along the vertical electrodes 50D and 52D parallel to the partition wall 54 during plasma discharge. do. As a result, the plasma discharge is generated at a close distance to the phosphor layer applied on the partition wall 54, and the ratio of vacuum ultraviolet rays generated at the time of discharge to the phosphor layer is increased, and the emission of visible light is increased accordingly. Therefore, the luminance of the PDP having the electrode structure according to the first embodiment of the present invention is improved.

Furthermore, since the protruding electrodes 50B and 52B have a distance from the partition wall 54, the amount of charged particles diffused toward the partition wall 54 or the phosphor is reduced. As a result, the PDP having the electrode structure according to the second embodiment of the present invention can improve the brightness and efficiency without losing the sustain voltage gain.

In detail, when the ratio of the electrode area to the area of the discharge cell is reduced, the reactive power consumed to charge the capacitance between the electrodes becomes smaller, so that the PDP employing the electrode having the smaller electrode area ratio consumes less power. Consumed.

The sustain electrode pairs 50 and 52 have a smaller ratio of the area occupied by the transparent electrodes 50B and 52B than the area of the discharge cell, and thus consume less power as described above, thereby improving discharge efficiency and luminous efficiency. At this time, the discharge that occurs in the transparent electrode is generated on the opposite side of the transparent electrode (50B, 52B) and diffused toward the metal bus, the discharge path is long. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. The transparent electrodes 50B and 52B of the PDP having the electrode structure according to the second embodiment of the present invention are metal electrodes 50A and 52A having a longer discharge path than those of the opposite surfaces of the transparent electrodes 50B and 52B having short discharge paths. The larger the area of) is, the higher the luminous efficiency and luminance of the PDP is. Therefore, the PDP employing the sustain electrode pair made of the transparent electrode reduces the area of the transparent electrode, thereby improving the luminous efficiency and the discharge efficiency and improving the luminance characteristic.

At this time, when the address electrodes are formed in a simple straight pattern as in the related art, since the intersection area between the address electrodes and the sustain electrode pairs 50 is small, the discharge voltage increases or misdischarges (or misses) occur during address discharge. As a result, the address voltage gain can be reduced. This problem can be solved by slightly altering the shape of the address electrode by increasing the cross-sectional area of the address electrode and the sustain electrode pair.

The address electrodes 81 shown in Fig. 8A are horizontal electrodes 50D and 52D in the first electrode portion 81a and the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52 having the same area as the conventional address electrodes. The second electrode portion 81b extends only in a portion overlapping with each other and is patterned to correspond to the shape of the horizontal electrodes 50D and 52D of the protruding electrodes 50B and 52B of each of the sustain electrode pairs 50 and 52. As a result, the cross-sectional area of the sustain electrode pairs 50 and 52 and the address electrode 81 is wider than that of the conventional straight address electrode. As a result, an address voltage rise phenomenon or a miss discharge (or miswriting) phenomenon, which is caused by a small overlapping area of the sustain electrode pair and the address electrode, is prevented. Therefore, the address electrode 81 of the PDP having the electrode structure according to the second embodiment of the present invention increases the area overlapping with the sustain electrode pairs 50 and 52 so that address discharge can be stably generated. The pattern of the address electrode 81 includes all those formed to have a large area overlapping with the sustain electrode pair, and applicable embodiments thereof are shown in FIGS. 8B to 8C.

The address electrode 82 shown in FIG. 8B has a structure of “11” shape formed by dividing the conventional address electrode into two and overlapping the vertical electrodes 50C, 50E, 52C, 52E of the sustain electrode pairs 50, 52. Have The first address electrode 82A overlaps the vertical electrodes 50C and 52C of one of the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52, and the second address electrode 82B is the sustain electrode pair. The other of the protruding electrodes 50B, 52B of 50, 52 overlaps with the other vertical electrodes 50E, 52E. At the distal end of the address electrode 82, the first address electrode 82A and the second address electrode 82B are patterned so as to be coupled to each other, and the same voltage is applied to the pad portion at which the distal end of the address electrode 82 is located.

The address electrode 82 of this structure exhibits improved performance compared to the address electrode 81 shown in Fig. 8A. In detail, the address electrode 81 of FIG. 8A has a large area of the electrode at the center of the cell, thereby increasing the total area of the address electrode. As described above, when the area of the electrode is reduced, the power consumption of the electrode is reduced. However, since the address electrode 81 of FIG. 8A is reversed, power consumption is increased during address discharge. In addition, since the sustain electrode pairs 50 and 52 that cross the address electrode 81 correspond to the horizontal electrodes 50D and 52D only, the efficiency of the address discharge is not very high. Therefore, the address electrode 82 of FIG. 8B divides the address electrode into the first address electrode 83A and the second address electrode 83B so as to have the same area as the conventional address electrode, and respectively divides the vertical electrodes 50C, 50E, 52C, By forming parallel to 52E, the overlapping area of the sustain electrode pairs 50 and 52 and the address electrode 82 is increased. As a result, the PDP having the electrode structure according to the second embodiment of the present invention employing the address electrode 82 of Fig. 8B has a constant address electrode area formed in the cell so as to consume the same power consumption as before. In this case, the efficiency of address discharge can be improved.

Another applicable embodiment may be an address electrode as shown in FIG. 8C.

The address electrode 83 shown in FIG. 8C overlaps the horizontal electrodes 50D and 52D of the portion where the scan / sustain electrode and the sustain electrode face each other in the " 11 " shaped address electrode 82 shown in FIG. The third electrode portion 83C, which is a connecting portion connecting the address electrode 83A and the second address electrode 83B, has a structure in which the address electrode 83 is patterned in an “H” shape. The address electrode 83 having such a structure has a large area where the sustain electrode pairs 50 and 52 and the address electrode 83 overlap with each other, thereby improving the efficiency of address discharge.

9A to 9B are plan views schematically illustrating a sustain electrode pair and an address electrode of a PDP having an electrode structure according to a third embodiment of the present invention.

In the PDP having the electrode structure according to the third embodiment of the present invention shown in FIG. 9A, each of the sustain electrode pairs 50 and 52 protrudes from the metal electrodes 50A and 52A and the metal electrodes 50A and 52A. Electrodes 50B and 52B are provided. Here, the sustain electrode pairs 50 and 52 become the scan / sustain electrode 50 and the sustain electrode 52.

The metal electrodes 50A, 52A of the sustain electrode pairs 50, 52 are formed of a metallic material having good conductivity, for example, silver (Ag) or copper (Cu).

The protruding electrodes 50B, 52B are the first electrodes 50C, 50C, 50E, 52C, 52E, which are vertical electrodes 50C, 50E, 52C, 52E protruding from the metal electrodes 50A, 52A in parallel with the partition wall 54 at both edges of the discharge cell. 52C) and the second electrode 50E, 52E and the vertical electrodes 50C, 52C of each of the sustain electrode pairs 50, 52, and one side is a straight line 57 and the other side is a curve 58 horizontally. It consists of 3rd electrodes 50D and 52D which are electrodes 50D and 52D.

The sustain electrode pairs 50 and 52 of the PDP having the electrode structure according to the third embodiment of the present invention have the first embodiment by having the horizontal electrodes 50D and 52D having convex curves 58 toward the center of the discharge cell. The electrode area becomes larger than the horizontal electrode of the example. As a result, the area overlapping with the address electrode passing through the center of the discharge cell becomes large, so that the address voltage gain can be secured such that the discharge occurs easily even under low voltage during the address discharge, thereby improving the discharge efficiency.

In addition, since the protruding electrodes 50B and 52B include vertical electrodes 50D and 52D parallel to the partition wall 54, the discharge path is spread along the vertical electrodes 50D and 52D parallel to the partition wall 54 during plasma discharge. do. As a result, the plasma discharge is generated at a close distance to the phosphor layer applied on the partition wall 54, and the ratio of vacuum ultraviolet rays generated at the time of discharge to the phosphor layer is increased, and the emission of visible light is increased accordingly. Therefore, the luminance of the PDP having the electrode structure according to the third embodiment of the present invention is improved.

Furthermore, since the protruding electrodes 50B and 52B have a distance from the partition wall 54, the amount of charged particles diffused toward the partition wall 54 or the phosphor is reduced. As a result, the PDP having the electrode structure according to the third embodiment of the present invention can improve luminance and efficiency without losing the sustain voltage gain.

In detail, when the ratio of the electrode area to the area of the discharge cell is reduced, the reactive power consumed to charge the capacitance between the electrodes becomes smaller, so that the PDP employing the electrode having the smaller electrode area ratio consumes less power. Consumed.

The sustain electrode pairs 50 and 52 have a smaller ratio of the area occupied by the transparent electrodes 50B and 52B than the area of the discharge cell, and thus consume less power as described above, thereby improving discharge efficiency and luminous efficiency. At this time, the discharge that occurs in the transparent electrode is generated on the opposite side of the transparent electrode (50B, 52B) and diffused toward the metal bus, the discharge path is long. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. The transparent electrodes 50B and 52B of the PDP having the electrode structure according to the third embodiment of the present invention are metal electrodes 50A and 52A having a longer discharge path than those of the opposite surfaces of the transparent electrodes 50B and 52B having a short discharge path. The larger the area of) is, the higher the luminous efficiency and luminance of the PDP is. Therefore, the PDP employing the sustain electrode pair made of the transparent electrode reduces the area of the transparent electrode, thereby improving the luminous efficiency and the discharge efficiency and improving the luminance characteristic.

At this time, when the address electrodes are formed in a simple straight pattern as in the related art, since the intersection area of the address electrodes and the sustain electrode pairs 50 is small, the discharge voltage increases or miss discharge (or miswriting) occurs during address discharge. As a result, the address voltage gain can be reduced. This problem can be solved by slightly altering the shape of the address electrode by increasing the cross-sectional area of the address electrode and the sustain electrode pair.

The address electrodes 91 shown in Fig. 9A are horizontal electrodes 50D and 52D in the first electrode portion 91a and the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52 having the same area as the conventional address electrodes. The second electrode portion 91b extended only to a portion overlapping with each other) is patterned to correspond to the shape of the horizontal electrodes 50D and 52D of the protruding electrodes 50B and 52B of each of the sustain electrode pairs 50 and 52. As a result, the cross-sectional area of the sustain electrode pairs 50 and 52 and the address electrode 91 is wider than that of the conventional linear address electrode. As a result, an address voltage rise phenomenon or a miss discharge (or miswriting) phenomenon, which is caused by a small overlapping area of the sustain electrode pair and the address electrode, is prevented. Therefore, the address electrode 91 of the PDP having the electrode structure according to the third embodiment of the present invention increases the area overlapping with the sustain electrode pairs 50 and 52 so that address discharge can be stably generated. The pattern of the address electrode 91 includes all those formed to have a large area overlapping with the sustain electrode pairs, and applicable embodiments thereof are shown in FIGS. 9B to 9C.

The address electrode 92 shown in FIG. 9B has a structure of "11" shape formed by dividing the conventional address electrode into two and overlapping the vertical electrodes 50C, 50E, 52C, 52E of the sustain electrode pairs 50, 52. Have The first address electrode 92A overlaps the vertical electrodes 50C and 52C of one of the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52, and the second address electrode 92B is the sustain electrode pair. The other of the protruding electrodes 50B, 52B of 50, 52 overlaps with the other vertical electrodes 50E, 52E. At the distal end of the address electrode 92, the first address electrode 92A and the second address electrode 92B are patterned to be coupled to each other, and the same voltage is applied to the pad portion at which the distal end of the address electrode 92 is located.

The address electrode 92 of this structure exhibits improved performance compared to the address electrode 91 shown in Fig. 9A. In detail, the address electrode 91 of FIG. 9A has a large area of the electrode at the center of the cell, thereby increasing the total area of the address electrode. As described above, when the area of the electrode is reduced, the power consumption of the electrode is reduced. Since the address electrode 91 of FIG. 9A is vice versa, power consumption is increased during address discharge. In addition, since the sustain electrode pairs 50 and 52 that cross the address electrode 91 correspond to the horizontal electrodes 50D and 52D only, the efficiency during address discharge is not so great. Accordingly, the address electrode 92 of FIG. 9B divides the address electrode into the first address electrode 93A and the second address electrode 93B so as to have the same area as the conventional address electrode, and respectively divides the vertical electrodes 50C, 50E, 52C, By forming parallel to 52E, the overlapping area of the sustain electrode pairs 50 and 52 and the address electrode 92 is increased. As a result, the PDP having the electrode structure according to the third embodiment of the present invention employing the address electrode 92 of Fig. 9B has a constant address electrode area formed in the cell so as to consume the same power consumption as before. In this case, the efficiency of address discharge can be improved.

Another applicable embodiment may be an address electrode as shown in FIG. 9C.

The address electrode 93 shown in FIG. 9C overlaps the horizontal electrodes 50D and 52D of the portion where the scan / sustain electrode and the sustain electrode face each other in the " 11 " shaped address electrode 92 shown in FIG. The third electrode portion 93C, which is a connecting portion connecting the address electrode 93A and the second address electrode 93B, has a structure in which the address electrode 93 is patterned in a “H” shape. The address electrode 93 having such a structure has a large area where the sustain electrode pairs 50 and 52 and the address electrode 93 overlap with each other, thereby improving the efficiency of address discharge.

10A to 10B are plan views schematically illustrating a sustain electrode pair and an address electrode of a PDP having an electrode structure according to a fourth embodiment of the present invention.

In the PDP having the electrode structure according to the fourth embodiment of the present invention shown in FIG. 10A, each of the sustain electrode pairs 50 and 52 protrudes from the metal electrodes 50A and 52A and the metal electrodes 50A and 52A. Electrodes 50B and 52B are provided. Here, the sustain electrode pairs 50 and 52 become the scan / sustain electrode 50 and the sustain electrode 52.

The metal electrodes 50A, 52A of the sustain electrode pairs 50, 52 are formed of a metallic material having good conductivity, for example, silver (Ag) or copper (Cu).

The protruding electrodes 50B and 52B are vertical electrodes 50C, 50E, 52C and 52E protruding from the metal electrodes 50A and 52A in parallel with the partition wall 54 at both edges of the discharge cell. ) And the second electrode 50E, 52E and the vertical electrodes 50C, 52C of each of the sustain electrode pairs 50, 52, and one side is a straight line 57 and the other side is a horizontal line of the concave curve 60. It consists of 3rd electrodes 50D and 52D which are electrodes 50D and 52D.

The sustain electrode pairs 50 and 52 of the PDP having the electrode structure according to the fourth embodiment of the present invention have horizontal electrodes 50D and 52D having a concave curve 60 toward the center of the discharge cell as compared with the third embodiment. ), The electrode area becomes larger than that of the horizontal electrode of the first embodiment. As a result, the area overlapping with the address electrode passing through the center of the discharge cell becomes large, so that the address voltage gain can be secured such that the discharge occurs easily even under low voltage during the address discharge, thereby improving the discharge efficiency.

In addition, since the protruding electrodes 50B and 52B include vertical electrodes 50D and 52D parallel to the partition wall 54, the discharge path is spread along the vertical electrodes 50D and 52D parallel to the partition wall 54 during plasma discharge. do. As a result, the plasma discharge is generated at a close distance to the phosphor layer applied on the partition wall 54, and the ratio of vacuum ultraviolet rays generated at the time of discharge to the phosphor layer is increased, and the emission of visible light is increased accordingly. Therefore, the luminance of the PDP having the electrode structure according to the fourth embodiment of the present invention is improved.

Furthermore, since the protruding electrodes 50B and 52B have a distance from the partition wall 54, the amount of charged particles diffused toward the partition wall 54 or the phosphor is reduced. As a result, the PDP having the electrode structure according to the fourth embodiment of the present invention can improve luminance and efficiency without losing the sustain voltage gain.

In detail, when the ratio of the electrode area to the area of the discharge cell is reduced, the reactive power consumed to charge the capacitance between the electrodes becomes smaller, so that the PDP employing the electrode having the smaller electrode area ratio consumes less power. Consumed.

The sustain electrode pairs 50 and 52 have a smaller ratio of the area occupied by the transparent electrodes 50B and 52B than the area of the discharge cell, and thus consume less power as described above, thereby improving discharge efficiency and luminous efficiency. At this time, the discharge that occurs in the transparent electrode is generated on the opposite side of the transparent electrode (50B, 52B) and diffused toward the metal bus, the discharge path is long. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. The transparent electrodes 50B and 52B of the PDP having the electrode structure according to the fourth embodiment of the present invention have metal discharges 50A and 52A having longer discharge paths than those of the opposite surfaces of the transparent electrodes 50B and 52B having short discharge paths. The larger the area of) is, the higher the luminous efficiency and luminance of the PDP is. Therefore, the PDP employing the sustain electrode pair made of the transparent electrode reduces the area of the transparent electrode, thereby improving the luminous efficiency and the discharge efficiency and improving the luminance characteristic.

At this time, when the address electrodes are formed in a simple straight pattern as in the related art, since the intersection area between the address electrodes and the sustain electrode pairs 50 is small, the discharge voltage increases or misdischarges (or misses) occur during address discharge. As a result, the address voltage gain can be reduced. This problem can be solved by slightly altering the shape of the address electrode by increasing the cross-sectional area of the address electrode and the sustain electrode pair.

The address electrodes 101 shown in FIG. 10A are horizontal electrodes 50D and 52D of the first electrode portion 101a and the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52 having the same area as the conventional address electrodes. The second electrode portion (101b) is extended only to the portion overlapping the () is patterned to correspond to the shape of the horizontal electrode (50D, 52D) of the protruding electrodes (50B, 52B) of each of the sustain electrode pair (50, 52). As a result, the cross-sectional area of the sustain electrode pairs 50 and 52 and the address electrode 101 is wider than that of the conventional linear address electrode. As a result, an address voltage rise phenomenon or a miss discharge (or miswriting) phenomenon, which is caused by a small overlapping area of the sustain electrode pair and the address electrode, is prevented. Therefore, the address electrode 101 of the PDP having the electrode structure according to the fourth embodiment of the present invention increases the area overlapping with the sustain electrode pairs 50 and 52 so that address discharge can be stably generated. The pattern of the address electrode 101 includes all those formed to have a large area overlapping with the sustain electrode pair, and applicable embodiments thereof are shown in FIGS. 10B to 10C.

The address electrode 102 shown in FIG. 10B has a structure of “11” shape formed by dividing the conventional address electrode into two and overlapping the vertical electrodes 50C, 50E, 52C, 52E of the sustain electrode pairs 50, 52. Have The first address electrode 102A overlaps the vertical electrodes 50C and 52C of one of the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52, and the second address electrode 102B is the sustain electrode pair. The other of the protruding electrodes 50B, 52B of 50, 52 overlaps with the other vertical electrodes 50E, 52E. At the end of the address electrode 102, the first address electrode 102A and the second address electrode 102B are patterned so as to be coupled to each other, and the same voltage is applied to the pad portion at which the end of the address electrode 102 is located.

The address electrode 102 of this structure exhibits improved performance compared to the address electrode 101 shown in Fig. 10A. In detail, in the address electrode 101 of FIG. 10A, the area of the electrode is suddenly increased at the center of the cell, thereby increasing the total area of the address electrode. As described above, when the area of the electrode is reduced, the power consumption of the electrode is reduced. However, since the address electrode 101 of FIG. 10A is vice versa, power consumption is increased during address discharge. In addition, since the sustain electrode pairs 50 and 52 that cross the address electrode 101 correspond only to the horizontal electrodes 50D and 52D, the efficiency during address discharge is not so great. Accordingly, the address electrode 102 of FIG. 10B divides the address electrode into the first address electrode 103A and the second address electrode 103B so as to have the same area as the conventional address electrode, and respectively divides the vertical electrodes 50C, 50E, 52C, By forming parallel to 52E, the overlapping area of the sustain electrode pairs 50 and 52 and the address electrode 102 is increased. As a result, the PDP having the electrode structure according to the fourth embodiment of the present invention employing the address electrode 102 of Fig. 10B has a constant address electrode area formed in the cell so as to consume the same power consumption as before. In this case, the efficiency of address discharge can be improved.

Another applicable embodiment may be an address electrode as shown in FIG. 10C.

The address electrode 103 shown in FIG. 10C overlaps the horizontal electrodes 50D and 52D of the portion where the scan / sustain electrode and the sustain electrode face each other in the " 11 " shaped address electrode 102 shown in FIG. The third electrode portion 103C, which is a connecting portion connecting the address electrode 103A and the second address electrode 103B, has a structure in which the address electrode 103 is patterned in a “H” shape. The address electrode 103 having such a structure has a large area where the sustain electrode pairs 50 and 52 and the address electrode 103 overlap with each other, thereby improving address discharge efficiency.

11A to 11B are plan views schematically illustrating a sustain electrode pair and an address electrode of a PDP having an electrode structure according to a fifth embodiment of the present invention.

In the PDP having the electrode structure according to the fifth embodiment of the present invention shown in FIG. 11A, each of the sustain electrode pairs 50 and 52 protrudes from the metal electrodes 50A and 52A and the metal electrodes 50A and 52A. Electrodes 50B and 52B are provided. Here, the sustain electrode pairs 50 and 52 become the scan / sustain electrode 50 and the sustain electrode 52.

The metal electrodes 50A, 52A of the sustain electrode pairs 50, 52 are formed of a metallic material having good conductivity, for example, silver (Ag) or copper (Cu).

The protruding electrodes 50B and 52B are vertical electrodes 50C, 50E, 52C and 52E protruding from the metal electrodes 50A and 52A in parallel with the partition wall 54 at both edges of the discharge cell. ) And the second electrode 50E, 52E, and the vertical electrodes 50C, 52C of each of the sustain electrode pairs 50, 52, and one side is a straight line 57 and the other side is a triangle protruding to the center of the discharge cell. It consists of 3rd electrodes 50D and 52D which are horizontal electrodes 50D and 52D which have the processus | protrusion 59. As shown in FIG.

The sustain electrode pairs 50 and 52 of the PDP having the electrode structure according to the fifth embodiment of the present invention have the horizontal electrodes 50D and 52D in the form of a triangular protrusion 59, and thus have an electrode area greater than that of the horizontal electrode of the first embodiment. Will become large. As a result, the area overlapping with the address electrode passing through the center of the discharge cell becomes large, so that the address voltage gain can be secured such that the discharge occurs easily even under low voltage during the address discharge, thereby improving the discharge efficiency.

In addition, since the protruding electrodes 50B and 52B include vertical electrodes 50D and 52D parallel to the partition wall 54, the discharge path is spread along the vertical electrodes 50D and 52D parallel to the partition wall 54 during plasma discharge. do. As a result, the plasma discharge is generated at a close distance to the phosphor layer applied on the partition wall 54, and the ratio of vacuum ultraviolet rays generated at the time of discharge to the phosphor layer is increased, and the emission of visible light is increased accordingly. Therefore, the luminance of the PDP having the electrode structure according to the fifth embodiment of the present invention is improved.

Furthermore, since the protruding electrodes 50B and 52B have a distance from the partition wall 54, the amount of charged particles diffused toward the partition wall 54 or the phosphor is reduced. As a result, the PDP having the electrode structure according to the fifth embodiment of the present invention can improve luminance and efficiency without losing the sustain voltage gain.

In detail, when the ratio of the electrode area to the area of the discharge cell is reduced, the reactive power consumed to charge the capacitance between the electrodes becomes smaller, so that the PDP employing the electrode having the smaller electrode area ratio consumes less power. Consumed.

The sustain electrode pairs 50 and 52 have a smaller ratio of the area occupied by the transparent electrodes 50B and 52B than the area of the discharge cell, and thus consume less power as described above, thereby improving discharge efficiency and luminous efficiency. At this time, the discharge that occurs in the transparent electrode is generated on the opposite side of the transparent electrode (50B, 52B) and diffused toward the metal bus, the discharge path is long. In this case, when the discharge path of the electrode is long, the amount of phosphor is excited by exciting the mixed gas so that the luminous efficiency and luminance of the PDP are improved. The transparent electrodes 50B and 52B of the PDP having the electrode structure according to the fifth embodiment of the present invention have metal discharges 50A and 52A having longer discharge paths than those of the opposite surfaces of the transparent electrodes 50B and 52B having short discharge paths. The larger the area of) is, the higher the luminous efficiency and luminance of the PDP is. Therefore, the PDP employing the sustain electrode pair made of the transparent electrode reduces the area of the transparent electrode, thereby improving the luminous efficiency and the discharge efficiency and improving the luminance characteristic.

At this time, when the address electrodes are formed in a simple straight pattern as in the related art, since the intersection area between the address electrodes and the sustain electrode pairs 50 is small, the discharge voltage increases or misdischarges (or misses) occur during address discharge. As a result, the address voltage gain can be reduced. This problem can be solved by slightly altering the shape of the address electrode by increasing the cross-sectional area of the address electrode and the sustain electrode pair.

The address electrodes 111 shown in FIG. 11A are horizontal electrodes 50D and 52D of the first electrode portions 111a and the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52 having the same area as the conventional address electrodes. The second electrode portion 111b is formed to extend only the portion overlapping the horizontal electrodes 50D, 52D of the protruding electrodes 50B, 52B of the sustain electrode pairs 50, 52. Thus, the patterning is performed so as to correspond to the shape of the horizontal electrodes 50D and 52D of the protruding electrodes 50B and 52B of each of the sustain electrode pairs 50 and 52. As a result, the cross-sectional area of the sustain electrode pairs 50 and 52 and the address electrode 111 is wider than that of the conventional straight address electrode. As a result, an address voltage rise phenomenon or a miss discharge (or miswriting) phenomenon, which is caused by a small overlapping area of the sustain electrode pair and the address electrode, is prevented. Therefore, the address electrode 111 of the PDP having the electrode structure according to the fifth embodiment of the present invention increases the area overlapping with the sustain electrode pairs 50 and 52 so that address discharge can be stably generated. The pattern of the address electrode 111 includes all those formed to have a large area overlapping with the sustain electrode pair, and applicable embodiments thereof are illustrated in FIGS. 11B to 11C.

The address electrode 112 shown in FIG. 11B has a structure of "11" shape formed by dividing the conventional address electrode into two and overlapping the vertical electrodes 50C, 50E, 52C, and 52E of the sustain electrode pairs 50 and 52. Have The first address electrode 112A overlaps the vertical electrodes 50C and 52C of one of the protruding electrodes 50B and 52B of the sustain electrode pairs 50 and 52, and the second address electrode 112B is the sustain electrode pair. The other of the protruding electrodes 50B, 52B of 50, 52 overlaps with the other vertical electrodes 50E, 52E. At the distal end of the address electrode 112, the first address electrode 112A and the second address electrode 112B are patterned so as to be coupled to each other, and the same voltage is applied to the pad part at which the distal end of the address electrode 112 is located.

The address electrode 112 of this structure exhibits improved performance compared to the address electrode 111 shown in FIG. 11A. In detail, in the address electrode 111 of FIG. 11A, the area of the electrode is suddenly increased at the center of the cell, thereby increasing the total area of the address electrode. As described above, when the area of the electrode is reduced, the power consumption of the electrode is reduced. However, since the address electrode 111 of FIG. 11A is opposite, power consumption is increased during address discharge. In addition, since the sustain electrode pairs 50 and 52 that cross the address electrode 111 correspond to the horizontal electrodes 50D and 52D only, the efficiency of the address discharge is not very high. Therefore, the address electrode 112 of FIG. 11B divides the address electrode into the first address electrode 113A and the second address electrode 113B so as to have the same area as the conventional address electrode, and respectively divides the vertical electrodes 50C, 50E, 52C, By forming parallel to 52E, the overlapping area of the sustain electrode pairs 50 and 52 and the address electrode 112 is increased. As a result, the PDP having the electrode structure according to the fifth embodiment of the present invention employing the address electrode 112 of Fig. 11B has a constant address electrode area formed in the cell so as to consume the same power consumption as before. In this case, the efficiency of address discharge can be improved.

Another applicable embodiment may be an address electrode as shown in FIG. 11C.

The address electrode 113 shown in FIG. 11C overlaps the horizontal electrodes 50D and 52D of the portion where the scan / sustain electrode and the sustain electrode face each other in the " 11 " shaped address electrode 112 shown in FIG. The third electrode portion 73C, which is a connecting portion connecting the address electrode 73A and the second address electrode 73B, has a structure in which the address electrode 113 is patterned in an “H” shape. The address electrode 113 having such a structure has a large area where the sustain electrode pairs 50 and 52 and the address electrode 113 overlap with each other, thereby improving the efficiency of address discharge.

As described above, the PDP having the electrode structure according to the present invention is a sustain electrode composed of a metal electrode formed on the upper and lower edges of the discharge cell and a vertical electrode protruding from the metal electrode and parallel electrodes formed parallel to the partition wall and connecting the vertical electrodes. And a pair of address electrodes patterned to increase the area crossing the vertical electrodes and the horizontal electrodes of the sustain electrode pair.

Since the PDP having the electrode structure according to the present invention has a sustain electrode pair consisting of a vertical electrode and a horizontal electrode, the ratio of the area occupied by the electrode to the discharge cell area is reduced, thereby reducing power consumption, thereby improving discharge efficiency and luminous efficiency. do. In addition, since the PDP having the electrode structure according to the present invention has vertical electrodes parallel to the partition wall, the area of the electrode having a long discharge path is larger than that of the electrode having a short discharge path. The brightness is improved. Furthermore, since the PDP having the electrode structure according to the present invention has vertical electrodes parallel to the partition wall, the rate at which the vacuum ultraviolet rays formed during discharge reach the phosphor layer is increased, thereby improving luminance characteristics.

In addition, since the PDP having the electrode structure according to the present invention has an address electrode patterned to increase an area overlapping with the sustain electrode pair, the discharge voltage rises or the mis-discharge phenomenon is prevented during the address discharge, so that stable discharge occurs. To do that.

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 (4)

A pair of sustain electrodes patterned to have bridges facing each other in units of discharge cells, And an address electrode vertically intersecting the sustain electrode pair and patterned to have the same shape as a bridge of the sustain electrode pair. The method of claim 1, The address electrode, And an electrode structure of the plasma display panel patterned in such a manner that a position crossing the bridge portion of the sustain electrode pair protrudes. The method of claim 1, The address electrode, The electrode structure of the plasma display panel, characterized in that formed by dividing into two electrodes each crossing the longitudinal end portion of the bridge portion of the sustain electrode pair. The method of claim 3, wherein And the address electrodes have a structure in which the two electrodes are connected to each other at positions crossing each of the transverse ends of the bridge portions of the sustain electrode pairs.