KR20060126319A - Plasma display panel - Google Patents

Abstract

A plasma display panel is provided to lower a breakdown voltage by narrowing an interval between an inner surface of a dielectric wall and an X-electrode or Y-electrode. A front substrate(201) and a rear substrate(202) are disposed opposite to each other. Dielectric walls are disposed between the substrates to define discharge cells together with the substrates. X-display electrodes(210) have first X-electrodes(206) and second X-electrodes(207) which are disposed around the discharge cell, and are buried in the dielectric wall. Y-display electrodes(211) have first Y-electrodes(208) and second Y-electrodes(209) which are disposed around the discharge cell, and are buried in the dielectric wall. An R, G, and B phosphor layers(218) are applied on the discharge cell. The X-electrode or Y-electrode is narrowly spaced apart from an inner surface of the dielectric wall in relation to other X-electrode or Y-electrode.

Description

Plasma display panel

1 is an exploded perspective view illustrating a part of a conventional plasma display panel;

2 is an exploded perspective view of a plasma display panel partially cut out according to an embodiment of the present invention;

3 is a cross-sectional view taken along the line I-I in a state in which the panel of FIG. 3 is coupled;

4 is an exploded perspective view illustrating the discharge electrode of FIG. 2.

<Description of Symbols for Major Parts of Drawings>

200 ... Plasma Display Panel 201 ... Front Board

202 back substrate 203 dielectric wall

206 ... first X electrode 207 ... second X electrode

208 ... first Y electrode 209 ... second Y electrode

210 ... X electrode 211 ... Y electrode

213 ... Bulk 216 ... Address electrode

217 dielectric layer 218 phosphor layer

The present invention relates to a plasma display panel, and more particularly, to a plasma display panel in which a discharge sustaining electrode pair is separated into a plurality of electrodes, and at the same time, a distance from an inner surface of the dielectric wall is adjusted to improve the discharge efficiency of the panel. It is about.

In general, a plasma display panel injects a discharge gas between two substrates on which a plurality of discharge electrodes are formed, and discharges the discharge, and excites the fluorescent material of the phosphor layer by the ultraviolet rays generated thereby to implement desired numbers, letters, or graphics. A flat display device is referred to.

Referring to FIG. 1, the conventional plasma display panel 100 includes a front panel 100, a rear substrate 160 disposed to face the front panel 100, and the front panel 110 includes a front substrate 111, A front dielectric layer filling the X electrode 112, the Y electrode 113, and the X and Y electrodes 112 and 113, which are a pair of discharge sustaining electrode pairs disposed on an inner surface of the front substrate 111 ( 114 and a passivation layer 115 formed on a surface of the front dielectric layer 114. The back panel 160 is formed on a rear substrate 161 and an inner surface of the rear substrate 161. An address electrode 162 disposed in a direction crossing the discharge sustaining electrode pair, and a back dielectric layer 163 filling the address electrode 162 are included.

In this case, the X electrode 112 is composed of a first transparent electrode line 112a and a first bus electrode line 112b disposed at one edge of the first transparent electrode line 112a. Reference numeral 113 includes a second transparent electrode line 113a and a second bus electrode line 113b disposed at one edge of the second transparent electrode line 113a.

Meanwhile, a partition wall 164 defining a discharge cell is disposed between the front and rear panels 110 and 160, and a red, green, and blue phosphor layer 165 is coated inside the partition wall 164. have.

The operation of the conventional plasma display panel 100 having the structure as described above is to apply the electrical signal to the Y electrode 113 and the address electrode 162 respectively to select the discharge cell at the point of intersection, and then to the X and Y electrodes When surface discharge occurs from the surface of the front panel 110 by alternately applying electrical signals to the 112 and 113, and ultraviolet rays are generated, visible light is emitted from the red, green, and blue phosphor layers 165 coated in the selected discharge cells. This can be emitted to realize a still image or a moving image.

However, the conventional plasma display panel 100 has the following problems.

First, since not only the X and Y electrodes 112 and 113 but also the front dielectric layer 114 and the passivation layer 115 are sequentially formed on the inner surface of the front substrate 111, the visible light generated in the discharge cell is generated. The transmittance for light is less than 60%. Therefore, it does not function properly as a high efficiency flat panel display.

Second, when the conventional panel 100 is driven for a long time, since the discharge is diffused toward the phosphor layer 165, the charged particles of the discharge gas cause ion sputtering on the phosphor layer 165 by an electric field, causing permanent afterimages. Let's do it.

Third, the discharge spreads outward from the discharge gap between the X and Y electrodes 112 and 113. Since the discharge spreads along the plane of the front panel 110, the space utilization of the entire discharge cell is low.

Fourth, when a discharge gas containing a high concentration of Xe gas of 10% by volume or more is injected into the discharge cell, the generation of charged particles and excitation species is increased by ionization and excitation of atoms, thereby increasing luminance and discharge efficiency, but high concentration of Xe There is a disadvantage that the initial discharge firing voltage (initial discharge firing voltage) is increased for the reason of applying the gas.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, by separating a plurality of discharge sustaining electrode pairs disposed along the circumference of the discharge cell, respectively, to provide a plasma display panel using the initial priming particles to improve the discharge efficiency. There is a purpose.

Another object of the present invention is to provide a plasma display panel having a wider voltage margin of the panel by adjusting the distance between the plurality of separated discharge sustaining electrode pairs and the dielectric wall.

In order to achieve the above object, the plasma display panel according to an aspect of the present invention,

A plurality of substrates having front and rear substrates disposed to face each other; and

A dielectric wall disposed between the substrates and defining a discharge cell together with the substrates;

An X electrode having a first X electrode and a second X electrode separately disposed along the circumference of the discharge cell and embedded in the dielectric wall;

A Y electrode having a first Y electrode and a second Y electrode separately disposed along the circumference of the discharge cell and embedded in the dielectric wall;

And a red, green, and blue phosphor layer coated in the discharge cell.

The X electrode or the Y electrode in which the discharge is initiated preferentially is characterized in that the spacing between the inner surface of the dielectric wall is narrower than that of the other X electrode or the Y electrode.

In addition, the first X electrode and the second X electrode are continuously disposed along discharge cells disposed adjacent to one direction of the substrate, and the first Y electrode and the second Y electrode are formed of the first X electrode and the first X electrode. It is characterized in that it is disposed continuously along the direction parallel to the 2 X electrode.

Further, the first and second X electrodes and the first and second Y electrodes may be arranged to be open or closed loops along the periphery of each unit discharge cell.

Furthermore, the first X electrode and the first Y electrode are disposed to face each other at the center of the dielectric wall, and the second X electrode and the second Y electrode are formed of the first X electrode and the first Y electrode. It is characterized in that it is disposed opposite to each other from the outside.

In addition, the width of the first X electrode or the first Y electrode may be narrower than the width of the second X electrode or the second Y electrode for each unit discharge cell.

In addition, the thickness of the dielectric wall at the inner surface of the first X electrode or the first Y electrode and the dielectric wall is thinner than the thickness of the dielectric wall at the inner surface of the second X electrode or the second Y electrode and the dielectric wall. It is characterized by.

Hereinafter, a plasma display panel according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 illustrates a partial cutting of the plasma display panel 200 according to an exemplary embodiment of the present invention.

Referring to the drawings, the plasma display panel 200 includes a front substrate 201 and a rear substrate 202 disposed opposite to the front substrate 201. A sealant, such as frit glass, is applied along the edges of the front and back substrates 201 and 202 that face each other, thereby sealing the internal space by thermal fusion.

The front substrate 201 is made of a transparent substrate such as soda lime glass, and the back substrate 202 is substantially made of the same material as the front substrate 201.

A dielectric wall 203 is provided between the front substrate 201 and the back substrate 202 to define a plurality of discharge cells. The dielectric wall 203 is made of a highly dielectric material in which various fillers are added to glass paste.

The dielectric wall 203 includes a first dielectric wall 204 disposed in the X direction of the panel 200 and a second dielectric wall 205 disposed in the Y direction. The second dielectric wall 205 extends integrally in an opposite direction from the inside of the pair of adjacent first dielectric walls 204. The first dielectric wall 204 and the second dielectric wall 205 joined together form a matrix, with the result that each unit discharge cell has a square shape.

Alternatively, the dielectric wall 203 may be embodied in various shapes such as meander type, delta type or honeycomb type. In addition, the discharge cells defined by the dielectric wall 203 are not limited to any one of the discharge cell shapes as long as the discharge cells defined by the dielectric walls 203 can define discharge cells such as hexagons, ellipses, and circles.

An X electrode 210 and a Y electrode 211 which are discharge sustaining electrode pairs are embedded in the dielectric wall 203. The X electrode 210 and the Y electrode 211 are not disposed inside the discharge cell but are disposed along the circumference of the discharge cell. The X electrode 210 and the Y electrode 211 are electrically insulated from each other, and voltages having different intensities are applied.

Magnesium oxide (MgO) is formed on the inner surface of the dielectric wall 203 so that ions generated inside the front substrate 201 along the four side walls of the discharge cell can emit secondary electrons by interacting with the surface. A protective film layer 212 made of the same material is deposited.

In addition, a partition wall 213 may be further provided between the dielectric wall 203 and the back substrate 202. The partition wall 213 is made of a low dielectric material unlike the dielectric wall 203. The partition wall 213 is disposed in substantially the same shape at a portion corresponding to the dielectric wall 203.

The partition wall 213 includes a first partition wall 214 disposed in a direction parallel to the first dielectric wall 204, and a second partition wall 215 disposed in a direction parallel to the second dielectric wall 205. Doing. The first partition 214 and the second partition 215 are integrally coupled to each other to form a matrix.

In this case, when only the dielectric wall 203 is disposed between the front substrate 204 and the rear substrate 205, the one-layer wall defines a discharge cell, and the dielectric wall 203 and the partition wall ( When the 213 is disposed between the front substrate 204 and the rear substrate 205 together, a two-layer wall of materials having different dielectric constants defines a discharge cell.

The address electrode 216 is disposed on an upper surface of the rear substrate 202 in a direction crossing the X electrode 210 and the Y electrode 211. The address electrode 216 extends across the center of the discharge cells disposed adjacent to the Y direction of the panel 200. The address electrode 216 is embedded by the dielectric layer 217.

The plasma display panel 200 may have various discharge electrodes depending on whether it is a surface discharge type, an opposite discharge type, or a hybrid type. In this embodiment, the common electrode causing display discharge retention, the X electrode 210 serving as the scan electrode, and the Y electrode 211 are provided, and the address electrode causing addressing discharge with the Y electrode 211 in the direction crossing the same. 216 is further installed. In this case, the address electrode 216 may be embedded in the dielectric wall 203 in which the X electrode 210 and the Y electrode 211 are embedded, in addition to being disposed on the rear substrate 202. It is not limited to one.

Meanwhile, in the discharge cells defined by the front substrate 201, the back substrate 202, the dielectric wall 203, and the partition wall 213, neon (Ne) -xenon (Xe) or helium (He)- Discharge gas such as xenon (Xe) is injected.

In each unit discharge cell, red, green, and blue phosphor layers 218 that are excited by ultraviolet rays generated from the discharge gas and emit visible light are formed. In this case, the phosphor layer 218 may be coated on any area of the discharge cell, but in the present embodiment, the phosphor layer 218 is formed to a predetermined thickness on the inner wall of the partition 213 and the upper surface of the dielectric layer 217.

The red, green, and blue phosphor layers 218 are coated for each unit discharge cell. The red phosphor layer consists of (Y, Gd) BO ₃ ; Eu ⁺³ , the green phosphor layer consists of Zn ₂ SiO ₄ : Mn ²⁺ , and the blue phosphor layer is BaMgAl ₁₀ O ₁₇ : Eu ²⁺ It is preferable that it consists of.

Here, the X electrode 210 includes a first X electrode 206 and a second X electrode 207 separately disposed along the circumference of the discharge cell, and the Y electrode 211 also has a circumference of the discharge cell. Therefore, the first Y electrode 208 and the second Y electrode 209 are arranged separately, and the electrodes in which the discharge of the X electrode 210 or the Y electrode 211 is preferentially started are the other X electrodes ( The spacing between the inner surface of the dielectric wall 203 is narrower than that of the 210 or the Y electrode 211.

In more detail, as shown in FIGS. 3 and 4.

FIG. 3 is a cutaway view taken along line I-I in a state in which the panel of FIG. 2 is coupled, and FIG.

3 and 4, the X electrodes 210 are continuously disposed along discharge cells disposed adjacent to each other in the X direction, which is one direction of the panel 200. In addition, the X electrodes 210 are disposed to be spaced apart from each other along discharge cells disposed adjacent to each other in the Y direction, which is the other direction of the panel 200.

The X electrode 210 may include a first X electrode 206 disposed along discharge cells adjacent in the X direction of the panel 200, and a second X electrode disposed in a direction parallel to the first X electrode 206. 207). In this case, the first X electrode 206 is disposed relatively far from the front substrate 201 as compared to the second X electrode 207.

The first X electrode 206 and the second X electrode 207 are closed loops in a substantially rectangular band along the periphery of each unit discharge cell. The square strips are continuously installed along the unit discharge cells adjacent to each other in the X direction of the panel 200 and are connected to each other. Alternatively, the first X electrode 206 and the second X electrode 207 may be open and looped in an intermittent shape in which at least one portion is disconnected along the periphery of each unit discharge cell.

Accordingly, the first X electrode 206 and the second X electrode 207 are arranged in a substantially ladder shape along the X direction of the panel 200, and a ladder structure is formed along the Y direction of the panel 200. The structure is spaced apart by a predetermined interval.

In addition, although the first X electrode 206 and the second X electrode 207 are disposed for each unit discharge cell in a vertically separated state, the first X electrode 206 and the second X electrode 207 are electrically separated from each other in order to apply the same voltage at the edge of the panel 200. Is connected.

The Y electrodes 211 are continuously disposed along discharge cells disposed adjacent to each other in the X direction of the panel 200, and are spaced apart at predetermined intervals along discharge cells disposed adjacent to the Y direction.

The Y electrode 211 includes a first Y electrode 208 and a second Y electrode 209 disposed in a direction parallel to the first Y electrode 208, and the first Y electrode 208. Is disposed relatively far from the rear substrate 202 as compared to the second Y electrode 209.

The first Y electrode 208 and the second Y electrode 209 are closed looped along the periphery of each unit discharge cell, and form a substantially rectangular band. Such a shape is continuously arranged in the X direction of the panel 200, and as a result, it maintains a substantially ladder shape. Alternatively, the first Y electrode 208 and the second Y electrode 209 may have an intermittent shape in which at least one portion is disconnected along the circumference of each unit discharge cell.

In addition, although the first Y electrode 208 and the second Y electrode 209 are disposed for each unit discharge cell in a vertically separated state, the first Y electrode 208 and the second Y electrode 209 are electrically connected to each other at the edge of the panel 200 to apply the same voltage. Is connected.

Referring to the overall arrangement of the X electrode 210 and the Y electrode 211, the first X electrode 206 and the first Y electrode 208 are disposed to face each other at the center of the dielectric wall 203. The second X electrode 207 is disposed outside the first X electrode 206, and the second Y electrode 209 is disposed outside the first Y electrode 208.

In addition, the second X electrode 207 is disposed closest to the front substrate 201, and the second Y electrode 209 is disposed closest to the rear substrate 202.

In this case, the distance d ₁ between the first X electrode 206 or the inner surface of the first Y electrode 208 and the dielectric wall 204 is the second X electrode 207 or the second Y electrode. It is relatively narrower than the distance d ₂ between 209 and the inner surface of the dielectric wall 204.

To this end, for each unit discharge cell, the total width w ₁ of the first X electrode 206 or the first Y electrode 208 is the second X electrode 207 or the second Y electrode 209. Of the dielectric wall 204 formed relatively narrower than the entire width w ₂ ) or between the first X electrode 206 or the inner surface of the first Y electrode 208 and the dielectric wall 204. The thickness is relatively thinner than the thickness of the dielectric wall 204 between the second X electrode 207 or the inner surface of the second Y electrode 209 and the dielectric wall 204.

Meanwhile, on the back substrate 202, an address electrode 216 extending across the center of an adjacent discharge cell in a direction crossing the X electrode 210 and the Y electrode 211 along the Y direction of the panel 200. ) Is further provided in a stripe shape, and the address electrode 216 performs address discharge with the Y electrode 211.

The operation of the plasma display panel 200 having the above structure will be described with reference to FIGS. 2 to 4.

First, when a predetermined address voltage is applied between the address electrode 216 and the Y electrode 211 from an external power source, the discharge cells to emit light are selected. Wall charges are accumulated on the Y electrode 211 of the selected discharge cell.

Subsequently, when a “+” voltage is applied to the X electrode 210 and a relatively higher voltage is applied to the Y electrode 211, the voltage difference between the X electrode 210 and the Y electrode 211 is applied. Wall charges move.

The movement of the wall charges generates a plasma by colliding with the discharge gas atoms in the discharge cell, and the discharge is generated from the discharge gap between the X electrode 210 and the Y electrode 211 in which a relatively strong electric field is formed. The probability is high.

As a result, since the X electrode 210 and the Y electrode 211 are formed along the four sides of the discharge space, the possibility of discharging greatly increases.

Subsequently, as time passes, if the voltage difference between the X electrode 210 and the Y electrode 211 is still sufficiently large, the electric field formed between the X electrode 210 and the Y electrode 211 gradually becomes stronger. By concentration, the discharge spreads to the entire discharge space.

Since the discharge in this embodiment is generated at four sides of the discharge space and diffuses to the center of the discharge cell, the diffusion range is greatly increased. In addition, since the plasma generated by the discharge is formed along the side of the discharge cell and diffused to the center, the volume thereof is greatly increased so that the amount of visible light is greatly increased, and as the plasma is concentrated at the center of the discharge cell, the space charge is utilized. It is possible to achieve low voltage driving, and the effect of improving luminous efficiency can be obtained.

If the voltage difference between the X electrode 210 and the Y electrode 211 is lower than the discharge voltage after the discharge is formed in this manner, the discharge no longer occurs, and the space charge and the wall charge are formed in the discharge cell. . At this time, if the polarities of the voltages applied to the X electrode 210 and the Y electrode 211 are changed to each other, the discharge is generated again with the help of the wall charge. If the polarities of the X electrode 210 and the Y electrode 211 are immediately changed, the first discharge process is repeated. The discharge is stably generated while repeating this process.

The ultraviolet rays generated by the discharge excite the fluorescent material of the phosphor layer 218 applied to each discharge cell. Through this process, visible light is obtained. The generated visible light is emitted to the discharge cells to implement an image.

In this case, the X electrode 210 is separated into a first X electrode 206 and a second X electrode 207, and the Y electrode 211 is a first Y electrode 208 and a second Y electrode. 209 and the first X electrode 206, the first Y electrode 208, and the inner surface of the dielectric wall 203 are separated from each other by the second X electrode 207. The second Y electrode 209 and the inner surface of the dielectric wall 203 are formed relatively narrower than the gap.

Accordingly, the thickness of the first X electrode 206 and the first Y electrode 208 where the display sustain discharge is preferentially initiated and the first Y electrode 208 are thinned allow the discharge even at a lower voltage. do. Priming particles formed by this discharge are expanded to the second X electrode 207 and the second Y electrode 209 to improve the efficiency of the panel 200.

As described above, in the plasma display panel of the present invention, a plurality of X electrodes and Y electrodes disposed along the circumference of the discharge cell are separately disposed, and the electrodes initiating the discharge of the X electrode and the Y electrode have a dielectric wall than the other electrodes. Since the interval with the inner surface of is narrow, the initial discharge voltage can be lowered and the discharge can be induced smoothly. As a result, the discharge can be performed at a low voltage, and the discharge voltage margin of the wider panel can be ensured.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (9)

A plurality of substrates having front and rear substrates disposed to face each other; and A dielectric wall disposed between the substrates and defining a discharge cell together with the substrates; An X electrode having a first X electrode and a second X electrode separately disposed along the circumference of the discharge cell and embedded in the dielectric wall; A Y electrode having a first Y electrode and a second Y electrode separately disposed along the circumference of the discharge cell and embedded in the dielectric wall; And a red, green, and blue phosphor layer coated in the discharge cell. And the X electrode or the Y electrode, the discharge of which is preferentially initiated, being arranged with a smaller spacing from the inner surface of the dielectric wall than the other X electrode or Y electrode. The method of claim 1, The first X electrode and the second X electrode are continuously disposed along discharge cells disposed adjacent to one direction of the substrate, and the first Y electrode and the second Y electrode are the first X electrode and the second X. And a plasma display panel disposed continuously along the direction parallel to the electrode. The method of claim 1, And the first and second X electrodes and the first and second Y electrodes are openly or closed looped along the periphery of each unit discharge cell. The method of claim 2, The first X electrode and the first Y electrode are disposed to face each other at the center of the dielectric wall, and the second X electrode and the second Y electrode are disposed outside the first X electrode and the first Y electrode. And a plasma display panel disposed to face each other. The method of claim 2, The width of the first X electrode or the first Y electrode is narrower than the width of the second X electrode or the second Y electrode for each unit discharge cell. The method of claim 2, The thickness of the dielectric wall on the inner surface of the first X electrode or the first Y electrode and the dielectric wall is thinner than the thickness of the dielectric wall on the inner surface of the second X electrode or the second Y electrode and the dielectric wall. Plasma display panel. The method of claim 1, And an address electrode extending in the discharge cell to intersect the X and Y electrodes and having an address discharge with the Y electrode. The method of claim 1, The dielectric wall includes a first dielectric wall disposed in one direction of the substrate and a second dielectric wall disposed in the other direction of the substrate, wherein the second dielectric wall is opposite from an inner side of the pair of adjacent first dielectric walls. Plasma display panel, characterized in that formed integrally extending in the direction. The method of claim 1, And a partition wall between the dielectric wall and the substrate to define a discharge cell together with the dielectric wall, and the phosphor layer is coated inside the partition wall.

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