KR20050104006A - Plasma display panel and flat display device comprising the same - Google Patents

Abstract

The present invention relates to a plasma display panel having an arrangement of electrodes having a structure capable of improving luminance and luminous efficiency, and a flat panel display device having the same. The plasma display panel according to the present invention includes a plurality of unit light emitting cells in which discharge is performed, and includes a front substrate, a rear substrate, a partition, discharge sustain electrode pairs, address electrodes, a dielectric layer, and a phosphor layer. The front substrate and the rear substrate are disposed to face each other at a predetermined interval apart. The partition wall is formed between the front substrate and the rear substrate so as to partition the space between the front substrate and the rear substrate into the discharge space of the power generation cell. The discharge sustaining electrode pairs are formed to extend across the discharge cells. The address electrodes extend across the discharge cells to intersect with the discharge sustaining electrode pairs in the unit discharge cell, and are disposed in front of the discharge sustaining electrode pairs. The dielectric layer covers the discharge sustaining electrode pairs. The phosphor layer is formed on at least one surface of the discharge space. According to the present invention, since the vacuum ultraviolet light due to the sustain discharge is generated closer to the phosphor, the loss due to the conventional trapping or the absorption of the vacuum ultraviolet light can be prevented, and the luminance and the light emitting efficiency can be improved.

Description

Plasma display panel and flat display device comprising the same

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel and a flat panel display having the same, and more particularly, to a plasma display panel having an arrangement of electrodes having a structure capable of improving brightness and luminous efficiency, and a flat panel display having the same. .

Recently, a device employing a plasma display panel as a flat panel display device has a large screen and has excellent characteristics of high definition, ultra-thin, light weight, and wide viewing angle, and is easier to manufacture than other flat panel display devices. It is attracting attention as a large flat panel display device.

1 is a perspective view showing an internal structure of a conventional three-electrode surface discharge plasma display panel. FIG. 2 is a cross-sectional view illustrating a configuration of a unit display cell of the panel of FIG. 1.

Referring to the drawings, between the front and rear glass substrates 10 and 13 of the conventional surface discharge plasma display panel 1, the address electrode lines A _R1 , A _G1 , ..., A _Gm , A _Bm ), Dielectric layers 11 and 15, Y electrode lines (Y ₁ , ..., Y _n ), X electrode lines (X ₁ , ..., X _n ), fluorescent layer 16, partition wall 17 ) And magnesium monoxide (MgO), a protective layer 12 is provided.

The address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm are formed in a predetermined pattern on the front side of the rear glass substrate 13. The back dielectric layer 15 is entirely coated in front of the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm . In front of the rear dielectric layer 15, barrier ribs 17 are formed in a direction parallel to the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm . These partitions 17 function to partition the discharge area of each discharge cell and to prevent optical cross talk between each discharge cell. The fluorescent layer 16 is formed between the partition walls 17.

The X electrode lines (X ₁ ,..., X _n ) and the Y electrode lines (Y ₁ , ..., Y _n ) are the address electrode lines (A _R1 , A _G1 , ..., A _Gm , A _Bm ) is formed in a predetermined pattern on the back of the front glass substrate 10 to be orthogonal to each other. Each intersection sets a corresponding discharge cell. Each X electrode line (X ₁ , ..., X _n ) and each Y electrode line (Y ₁ , ..., Y _n ) have a conductivity and a transparent electrode line made of a transparent conductive material such as indium tin oxide (ITO). Metal electrode lines for heightening are formed in combination. The front dielectric layer 11 is formed by coating the entire surface behind the X electrode lines X ₁ ,..., X _n and the Y electrode lines Y ₁ ,..., And Y _n . A protective layer 12 for protecting the panel 1 from a strong electric field, for example, a magnesium monoxide (MgO) layer, is formed by applying the entire surface to the rear of the front dielectric layer 11. The gas for forming plasma is sealed in the discharge space 14.

As shown in FIG. 1, in the conventional surface discharge plasma display panel 1 including the three-electrode surface discharge plasma display panel, the X electrode lines X ₁ ,..., X _n are formed on the front substrate 10. ), Y electrode lines (Y ₁ , ..., Y _n ), and bus electrodes formed thereon, as well as dielectric layers 11 and protective layers 12 sequentially formed thereon. Here, visible light emitted from the phosphor layer 16 in the discharge space passes through the front substrate 10 during discharge, and the transmittance of visible light is only about 60% due to various components formed on the front substrate 10. There is a serious problem.

In addition, in the conventional surface discharge plasma display panel 1, the electrodes causing the discharge are formed on the front surface of the discharge space, that is, the inner surface of the front substrate 10 through which visible light passes, so that the discharge occurs on the inner surface and diffuses. In the conventional surface discharge plasma display panel 1, there is an inherent problem of low luminous efficiency.

In addition, the conventional surface discharge plasma display panel 1 has a problem in that when the particles are used for a long time, the charged particles of the discharge gas cause ion sputtering on the phosphor layer by the electric field, causing permanent afterimage.

Furthermore, a high-precision alignment is required between the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm formed on the partition 17 and the rear substrate 13. In particular, the partition wall 17 has a large shrinkage rate, which makes it difficult to align with the gap between the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm .

The present invention is to solve the various problems of the conventional plasma display panel including the above problem, the present invention provides a plasma display panel having a structure different from the conventional plasma display panel and a flat panel display device having the same. It aims to do it.

Another object of the present invention is to provide a plasma display panel having an arrangement of electrodes having a structure capable of improving luminance and luminous efficiency, and a flat panel display device having the same.

Plasma display panel according to the present invention for achieving the above object includes a plurality of unit light emitting cells that discharge is performed, the front substrate, the back substrate, the partition, the discharge sustaining electrode pairs, the address electrodes, the dielectric layer, And a phosphor layer.

The front substrate and the rear substrate are disposed to face each other at a predetermined interval apart. The partition wall is formed between the front substrate and the rear substrate so as to partition the space between the front substrate and the rear substrate into the discharge space of the discharge cell. The discharge sustaining electrode pairs are formed to extend across the discharge cells. The address electrodes extend across the discharge cells to intersect with the discharge sustaining electrode pairs in the unit discharge cell, and are disposed in front of the discharge sustaining electrode pairs. The dielectric layer covers the discharge sustaining electrode pairs. The phosphor layer is formed on at least one surface of the discharge space.

In addition, the plasma display panel according to the present invention may further include a front partition wall formed between the partition wall and the front substrate to partition a discharge space together with the partition wall. In this case, it is preferable that the discharge sustaining electrode pairs and the address electrodes are embedded in the front partition wall.

The discharge sustaining electrode pairs preferably include an address electrode and a Y electrode for generating an address discharge and selecting a discharge space to emit light from the discharge space, and an Y electrode and an X electrode for generating sustain discharge. At this time, the X electrode, the Y electrode, and the address electrode are preferably arranged in the order of the X electrode, the Y electrode, and the address electrode in the direction of the front substrate from the back substrate.

In addition, the present invention provides a flat panel display having the above-described plasma display panel.

According to the present invention, since the vacuum ultraviolet light due to the sustain discharge is generated closer to the phosphor, the loss due to the conventional trapping or the absorption of the vacuum ultraviolet light can be prevented, and the luminance and the light emitting efficiency can be improved.

In addition, the aperture ratio and visible light transmittance can be significantly improved, and stable address discharge can be performed even in the case where the xenon (Xe) partial pressure of the discharge gas is high, thereby improving luminous efficiency, and the occurrence of permanent afterimage by ion sputtering. You can prevent it.

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

3 is an exploded perspective view illustrating a portion of a plasma display panel as a preferred embodiment of the present invention. 4 is a cross-sectional view IV-IV illustrating one discharge space of the plasma display panel of FIG. 3. 5 is a cross-sectional view illustrating a V-V cross section of FIG. 4. 6 is a plan view illustrating a connection state of the discharge electrodes of FIG. 3.

The method of driving the plasma display panel according to the present invention is not only applicable to the plasma display panel described in the present embodiment, but those matters applicable to other embodiments included in the scope of the present invention, such matters are It should be noted that the same applies to the description of all other embodiments recognizable by those skilled in the art.

Referring to the drawings, the plasma display panel 200 includes a plurality of unit light emitting cells for discharging, and includes a front substrate 201, a rear substrate 202, a partition 205, a front partition 208, and a discharge. Sustain electrode pairs 206 and 207, address electrodes 203, and phosphor layer 210.

The front substrate 201 and the rear substrate 202 are disposed to face each other at a predetermined interval. The partition wall 205 is formed between the front substrate 201 and the rear substrate 202 to partition the space between the front substrate 201 and the rear substrate 202 into the discharge space 220 of the discharge cell. The discharge sustaining electrode pairs 206 and 207 are formed to extend across the discharge cells. The address electrodes 203 extend across the discharge cells to intersect with the discharge sustaining electrode pairs 206 and 207 in the unit discharge cell, and are disposed in front of the discharge sustaining electrode pairs 206 and 207. The phosphor layer 210 is formed on at least one surface of the discharge space 220.

The front partition wall 208 is formed between the partition wall 205 and the front substrate 201 to partition the discharge space 220 together with the partition wall 205. In this case, it is preferable that the discharge sustaining electrode pairs 206 and 207 and the address electrodes 203 are embedded in the front partition wall 208. In addition, the front partition 208 is covered by the MgO protective film 209.

In addition, as illustrated, the phosphor layer 210 may be formed on the barrier rib 205 and the back substrate 202 in the discharge space 220. That is, in this embodiment, the discharge sustaining electrode pairs 206 and 207 causing the sustain discharge are disposed closer to the phosphor layer 210 than the address electrodes 203, so that the vacuum ultraviolet light due to the sustain discharge is emitted from the phosphor layer 210. ) Can be increased to increase the luminance and luminous efficiency.

As such, the plasma display panel 200 includes a pair of substrates, for example, a front substrate 201 and a back substrate 202, which face each other at predetermined intervals. In this case, the front substrate 201 and the back substrate 202 may be made of a transparent glass substrate. Here, the front substrate 201 is disposed in front of the rear substrate 202, the front substrate 201 direction in the front of the description of the specification, the rear substrate 202 direction is the rear.

Between the front substrate 201 and the rear substrate 202, sidewalls forming the plurality of discharge spaces 220, for example, a partition wall 205, are disposed in a predetermined pattern. As long as the barrier rib 205 can form a plurality of discharge spaces 220, the barrier rib 205 of various patterns, for example, an open barrier rib 205 such as a stripe or the like, as well as a closed barrier rib such as a waffle, a matrix, a delta, etc. 205. In addition, the closed partition wall 205 may be formed such that the cross section of the discharge space 220 is a polygon, such as a triangle, a pentagon, or a circle, an ellipse, or the like, in addition to the quadrangle as in the present embodiment.

The front partition 208 partitions the discharge space 220 together with the partition 205 and is formed along the partition 205 between the partition 205 and the front substrate 201. The discharge sustaining electrode pairs 206 and 207 and the address electrodes 203 are formed in the interior of the front partition 208 so as to surround the discharge space 220 along the interior of the front partition 208. In this case, the front partition wall 208 is preferably formed of a dielectric material, it is preferable that the surface facing the discharge space 220 of the front partition wall 208 is covered by a protective layer 209 made of MgO film.

The discharge sustaining electrode pairs 206 and 207 are embedded in the front partition wall 208 and are spaced apart from the front substrate 201 in a direction toward the rear substrate 202 so as to surround the discharge space 220. They are disposed side by side and extend to cross the address electrode 203. The discharge sustaining electrode pairs 206 and 207 include an Y electrode 206 for generating an address discharge with the address electrode 203 and selecting a discharge space to emit light from the discharge space, and a sustain discharge with the Y electrode 206. It is preferable to provide the X electrode 207 which produces | generates.

In particular, in order to implement the object of the present invention more effectively, the X electrode 207, the Y electrode 206, and the address electrode 203, the X electrode (from the rear substrate 202 toward the front substrate 201) 207, the Y electrode 206, and the address electrode 203 may be disposed in this order.

The X electrode 207 and the Y electrode 206 are arranged so that the discharge due to the voltage difference applied between the two electrodes can be initiated on the same side of the front partition 208. In the present embodiment, the X electrode 207 and the Y electrode 206 are formed in the direction of the front substrate 201 from the rear substrate 202 in the interior of the front partition 208, in the present invention, the X electrode ( The 207 and the Y electrode 206 may be disposed in various shapes and positions as long as surface discharge can be generated from the side forming the discharge space 220. For example, the X electrode 207 and the Y electrode 206 may be formed in parallel with each other along the circumference of the partition 205 in a ring shape at the side of the front partition 208. However, it is preferable that the discharge sustaining electrode pairs 206 and 207 be disposed close to the phosphor so as to adhere to the spirit of the present invention.

Although the distance between the X electrode 207 and the Y electrode 206 should be a level suitable for the surface discharge to be initiated and diffused, it is preferable to shorten the distance between the two electrodes as low as possible to drive the voltage. The shapes of the X electrode 207 and the Y electrode 206 have a ring shape in the present embodiment, but the present invention is not limited thereto, and may have various shapes. The X electrode 207 and the Y electrode 206 may be arranged in various ways, but it is preferable that the X electrode 207 and the Y electrode 206 are disposed so that discharge can be easily initiated and easily diffused even at a low voltage.

For example, in order to arrange the X electrode 207 and the Y electrode 206 so that the discharge surface, which is the surface on which discharge occurs, is as wide as possible, the ring-shaped Y electrode 206 is placed in front of and behind the ring-shaped X electrode 207 therebetween. ) May be arranged and vice versa. By arranging the X electrode 207 and the Y electrode 206 in this way, it is possible to obtain the effect that the surface where the discharge occurs is enlarged toward the height direction of the discharge space 220. In this case, in order to lower the address voltage applied between the address electrode 203 and the Y electrode 206, the Y electrode 206 is located close to the address electrode 203, that is, the Y electrode 306 is placed on the front substrate. It is preferable to arrange so as to be close to the 201 side.

In addition, the X electrode 207 and the Y electrode 206 may be provided such that portions facing each other are disposed in a direction perpendicular to the substrate, for example, the front substrate 201, on the side of the discharge space 220.

The discharge electrodes 206 and 207 configured as described above can obtain the effect that the surface where the discharge occurs extends toward the circumferential direction of the discharge space 220. In addition, the shape and arrangement of the discharge electrodes 206 and 207 may be various. The formation of the X electrode 207, the Y electrode 206, and the address electrode 203 may be, for example, a printing method, a sand blasting method, a deposition method, or the like. Preferably, the X electrode 207 and the Y electrode 206 are disposed to be located at the front surface of the partition wall 205.

The voltage is applied to the X electrode 207 and the Y electrode 206 alternately, so that the plasma tends to gather to the center part by the electric field formed in the discharge space 220. As a result, the plasma density is increased so that The occurrence increases, and the luminance increases. Therefore, the luminous efficiency increases accordingly.

Phosphor which is excited by ultraviolet rays generated from discharge gas in the discharge space 220 formed by the barrier rib 205, the front barrier rib 208, the back substrate 202, and the front substrate 201 to emit visible light. Layer 210 is formed. The phosphor layer 210 may be formed in any portion of the discharge space 220, but considering the transmittance of visible light, the bottom surface of the discharge space 220 below the discharge space 220 toward the rear substrate 202. It is preferable to arrange | position so that 220a and the partition wall part 220b may be covered.

The discharge space 220 is filled with a discharge gas, such as Ne, Xe and the like and a mixture of these. In the present invention including this embodiment, the discharge surface can be increased and the discharge region can be enlarged, so that the amount of plasma formed is increased, thereby enabling low voltage driving. Therefore, in the case of the present invention, even when a high concentration of Xe gas is used as the discharge gas, low voltage driving is possible, thereby significantly improving the luminous efficiency. This solves the problem of low voltage driving when using a high concentration of Xe gas as a discharge gas in a conventional plasma display panel.

The front opening of the discharge space 220 is sealed by the front substrate 201. The front substrate 201 does not have a discharge electrode or a bus electrode made of an indium tin oxide (ITO) film existing on the front substrate of the conventional plasma display panel, and a dielectric layer formed on the front substrate to cover them. Therefore, in the present invention including the present embodiment, the aperture ratio of the front substrate 201 can be significantly improved, and the light emission efficiency can be realized by enabling the low voltage driving by dramatically improving the transmittance of visible light by 90%. To maximize. The front substrate 201 may be made of any material as long as it is transparent. For example, the front substrate 201 may be made of glass.

The discharge phenomenon in the sustain discharge cycle of the plasma display panel of FIGS. 3 to 6 by the conventional driving method is as follows.

First, when a predetermined address voltage is applied between the address electrode 203 and the Y electrode 206 from an external power source, the discharge space 220 to be emitted is selected, and the Y electrode 206 of the selected discharge space 220 is selected. Wall charges accumulate on the phase.

Next, when a positive voltage is applied to the X electrode 207 and a relatively lower voltage is applied to the Y electrode 206, the voltage difference applied between the X electrode 207 and the Y electrode 206 is applied. Wall charges move. The movement of the wall charges causes a discharge by colliding with the discharge gas atoms in the discharge space 220 to generate a plasma, and the discharge is performed by the X electrode 207 and the Y electrode 206 which are formed with a relatively strong electric field. It is more likely to occur from nearby parts.

In this embodiment, since portions of the X electrode 207 and the Y electrode 206 that are close to each other are formed along the side of the discharge space 220, the portions of the discharge electrode that are close to each other are formed only on the front portion of the discharge space. Compared with the prior art, the possibility of discharge occurring is greatly increased. If the voltage difference between the two electrodes is still sufficiently large over time, the electric field formed between the surfaces of the two electrodes is gradually concentrated so that the discharge is diffused to the entire discharge space 220. In the present embodiment, the discharge is generated in a ring shape at four sides of the discharge space 220 and spreads to the center portion, while in the conventional technology, the discharge is generated at one front portion of the discharge space 220 to the center portion. Because of the diffusion, the discharge in the present embodiment is greatly increased in the diffusion range compared with the discharge in the prior art.

In addition, in the present embodiment, since the plasma generated by the discharge is formed in a ring shape along the side surface of the discharge space 220 and then diffuses to the center portion, the volume thereof is greatly increased, so that the amount of visible light is greatly increased, and the plasma is discharged. As the center of the space 220 is concentrated, the space charge can be utilized, thereby enabling low voltage driving and improving luminous efficiency.

In addition, since the plasma is concentrated in the center portion of the discharge space 220 and the electric fields by the discharge electrodes 206 and 207 are formed on both sides of the plasma, the charge is concentrated in the center portion of the discharge space 220 and the phosphor layer 210 is formed. It is possible to prevent ion sputtering at).

Once this discharge is formed, if the voltage difference between the X electrode 207 and the Y electrode 206 becomes lower than the discharge voltage, the discharge no longer occurs, and the space charge and the wall charge are formed in the discharge space 220. . At this time, if the polarities of the voltages applied to the X electrode 207 and the Y electrode 206 are changed to each other, the discharge is generated again with the help of the wall charge. Thereafter, the discharge diffuses into the entire discharge space 220 and then disappears.

When the polarities of the X electrode 207 and the Y electrode 206 are changed again, the first discharge process is repeated. The discharge is stably generated while repeating these processes. However, the discharge in the present invention is not necessarily limited thereto, and various discharges are possible within a range that can be understood by those skilled in the art.

In particular, according to the present invention, the address electrode 203 is disposed on the front substrate 201 side, and the Y electrode 206 and the X electrode 207 are sequentially disposed behind the partition wall, and the phosphor layer 210 is formed. A sustain discharge occurs at a position close to the 205 and the back substrate 202. Therefore, more visible light can be emitted from the phosphor by vacuum ultraviolet rays more effectively in a conventional plasma display panel.

FIG. 7 is an exploded perspective view illustrating a portion of a plasma display panel as another exemplary embodiment of the present invention. FIG. 8 is a cross-sectional view illustrating one discharge space of the plasma display panel of FIG. 7. FIG. 9 is a cross-sectional view illustrating the VIII-VIII cross-section of FIG. 8. 10 is a plan view illustrating a connection state of the discharge electrode of FIG. 6.

Referring to the drawings, in the plasma display panel 300 according to the present exemplary embodiment, the address electrode 203 is disposed in front, and the Y electrode 206 and the X electrode 207 are arranged side by side, and the Y electrode is disposed side by side. 3 through 6 and the above-described implementation in that the amount of vacuum ultraviolet rays generated by the sustain discharge by the 206 and the X electrode 207 reaches the phosphor layer 310 increases the luminance and the luminous efficiency. Example similar to the example. Therefore, for the same matters as the above-described embodiment, the description of the above-described embodiment is referred to, and the detailed description thereof is omitted. At this time, similar reference numerals are used for components that perform the same function.

The plasma display panel 300 includes a plurality of unit light emitting cells in which discharge is performed, and includes a front substrate 301, a rear substrate 302, a partition 305, pairs of discharge sustain electrodes 306 and 307, and an address. Electrodes 303, dielectric layer 308, and phosphor layer 310 are provided.

The front substrate 301 and the rear substrate 302 are disposed to face each other at a predetermined interval. The partition wall 305 is formed between the front substrate 301 and the rear substrate 302 so as to partition the space between the front substrate 301 and the rear substrate 302 into the discharge space 320 of the discharge cell. The discharge sustaining electrode pairs 306 and 307 are formed to extend across the discharge cells. The address electrodes 303 extend across the discharge cells to intersect the discharge sustaining electrode pairs 306 and 307 in the unit discharge cell, and are disposed in front of the discharge sustaining electrode pairs 306 and 307. The dielectric layer 308 covers the discharge sustaining electrode pairs 306 and 307. The phosphor layer 310 is formed on at least one surface of the discharge space 320.

The discharge sustaining electrode pairs 306 and 307 and the address electrodes 303 are formed on a surface 305a facing the discharge space 320 of the partition wall 305, and a dielectric layer 308 is disposed thereon. Are formed to cover the fields 306 and 307, and an MgO protective film 309 is formed thereon.

The discharge sustaining electrode pairs 306 and 307 may include an Y electrode 306 and an Y electrode 306 for generating an address discharge from the address electrode 303 and selecting a discharge space to emit light from the discharge space 320. It is preferable to provide the X electrode 307 which causes sustain discharge. At this time, the X electrode 307, the Y electrode 306, and the address electrode 303 are moved from the back substrate 302 to the front substrate 301 toward the X electrode 307, the Y electrode 306, and the address electrode. It is preferable to arrange in the order of 303.

Here, the partition wall 305 is not only an element for forming the discharge space, but also an element on which the discharge electrodes 306 and 307 are provided. Accordingly, the partition wall 305 may be formed in any form as long as the discharge electrodes 306 and 307 can be installed so that the discharge can be initiated and diffused. For example, a side surface of the partition wall 305 may extend in a direction inclined to either the direction perpendicular to the front substrate 301 or the direction perpendicular to the front substrate 301, and the side surface may extend in a direction inclined to one side. The remaining part may be a curved surface that is a surface extending in the opposite direction.

In this way, the barrier ribs 305 may be configured in various ways so that the discharge electrodes 306 and 307 may be arranged in various shapes and shapes on the side surfaces of the barrier ribs 305, and discharge may be performed in response to various discharge planes formed thereby. It is possible to start and spread variously.

In the partition wall 305, an electrode for generating a discharge in the discharge space 320, for example, an X electrode 307 and a Y electrode 306, is formed. The X electrode 307 and the Y electrode 306 are arranged so that the discharge due to the voltage difference applied between the two electrodes can be initiated on the surface connected to each other. In the present embodiment, the X electrode 307 and the Y electrode 306 are formed on the partition wall 305, but in the present invention, the X electrode 307 and the Y electrode 306 form a discharge space 320. As long as it can generate a surface discharge from the aspect, it can be arranged in various forms and positions. For example, the X electrode 307 and the Y electrode 306 may be formed in parallel with each other along the circumference of the partition 305 in a ring shape at the side of the partition 305.

In the discharge space 320 formed by the barrier rib 305, the rear substrate 302, and the front substrate 301, a phosphor layer 310 excited by ultraviolet rays generated from the discharge gas and emitting visible light is formed. do. The phosphor layer 310 may be formed in any portion of the discharge space 320, but considering the transmittance of visible light, the bottom surface of the discharge space 320 below the discharge space 320 toward the rear substrate 302. It is preferable to arrange so as to cover the 320a and the lower end 320b of the partition 305.

The plasma display panel and the flat panel display device having the same according to the present invention have the following effects.

First, the visible light emitted from the discharge space passes through the front substrate. Since there are no elements other than the substrate on the front substrate through which the visible rays pass, the aperture ratio and the visible light transmittance can be significantly improved.

In addition, since the surface discharge can be generated in all aspects forming the discharge space, the discharge surface can be expanded by about four times or more compared with the conventional.

In addition, since the discharge is generated in terms of forming the discharge space and diffuses to the center portion of the discharge space, the discharge area is significantly enlarged compared with the conventional one, so that the entire discharge space can be efficiently used.

In addition, since the discharge is generated in all aspects forming the discharge space and diffused to the center portion of the discharge space, the volume of the plasma due to the discharge is significantly increased, so that the amount of plasma is greatly increased, so that much ultraviolet rays can be emitted.

In addition, even when the Xen partial pressure of the discharge gas is high, stable address discharge is possible, and a high efficiency discharge display is possible.

In addition, since the electric field due to the voltage applied to the discharge electrode formed on the side of the discharge space concentrates the plasma to the center portion of the discharge space, thereby preventing ions generated by the discharge from colliding with the phosphor even after a long discharge. It is possible to fundamentally prevent the problem of permanent afterimage caused by phosphor damage caused by ion sputtering.

In addition, since the above-described effects can be obtained, the driving can be performed at a low voltage, thereby significantly improving the luminous efficiency.

In particular, since the address electrode does not exist on the back surface of the phosphor, the deterioration of the phosphor during address discharge can be prevented, and the structure of the complex back substrate can be simplified.

In addition, since a high-precision alignment between the partition wall and the address electrode is not necessary, the plasma display panel can be easily manufactured.

In addition, since the vacuum ultraviolet light due to the sustain discharge is generated closer to the phosphor, the loss due to the conventional trapping or absorption of the vacuum ultraviolet light can be prevented, and the luminance and the light emitting efficiency can be improved.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it is merely an example, and those skilled in the art may realize various modifications and equivalent other embodiments therefrom. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is an exploded perspective view showing the structure of a conventional three-electrode surface discharge type plasma display panel.

2 is a cross-sectional view illustrating a configuration of a unit cell of the plasma display panel of FIG. 1.

3 is an exploded perspective view illustrating a portion of a plasma display panel as a preferred embodiment of the present invention.

4 is a cross-sectional view IV-IV illustrating one discharge space of the plasma display panel of FIG. 3.

5 is a cross-sectional view illustrating a V-V cross section of FIG. 4.

6 is a plan view illustrating a connection state of the discharge electrode of FIG. 3.

FIG. 7 is an exploded perspective view illustrating a portion of a plasma display panel as another exemplary embodiment of the present invention.

FIG. 8 is a cross-sectional view illustrating one discharge space of the plasma display panel of FIG. 7.

FIG. 9 is a cross-sectional view illustrating the VIII-VIII cross-section of FIG. 8.

10 is a plan view illustrating a connection state of the discharge electrode of FIG. 6.

<Brief description of the major symbols in the drawings>

1, 200, 300: plasma display panel,

10, 201, 301: front substrate, 13, 202, 302: rear substrate,

An, 203, 303: address electrode, 11, 15, 308: dielectric layer,

17, 205, 305: partition wall, Yn, 206, 306: Y electrode,

Xn, 207, 307: X electrode, 208: front bulkhead,

16, 210, 310: phosphor layer, 14, 220, 320: discharge space,

12, 209, 309: protective layer.

Claims (8)

In the plasma display panel including a plurality of unit light emitting cells to be discharged, A front substrate and a rear substrate spaced apart from each other by a predetermined interval; Barrier ribs formed between the front substrate and the rear substrate to partition a space between the front substrate and the rear substrate into a discharge space of the discharge cell; Discharge sustaining electrode pairs extending across the discharge cells; Address electrodes extending across the discharge cells to intersect the discharge sustaining electrode pairs in the unit discharge cell, and disposed in front of the discharge sustaining electrode pairs; A dielectric layer covering the discharge sustain electrode pairs; And And a phosphor layer formed on at least one surface of the discharge space. The method of claim 1, Further comprising a front partition wall formed between the partition wall and the front substrate to partition the discharge space with the partition wall, And the discharge sustaining electrode pairs and the address electrodes are embedded in the front partition wall. The method of claim 2, And the phosphor layer is formed on the barrier rib and the back substrate in the discharge space. The method of claim 2, And the front partition wall is covered by an MgO film. The method according to claim 1 or 2, The discharge sustain electrode pairs include a Y electrode for generating an address discharge with the address electrode and selecting a discharge space to emit light from the discharge space, and an X electrode for generating sustain discharge with the Y electrode. panel. The method of claim 5, And the X electrode, the Y electrode, and the address electrode are arranged in the order of the X electrode, the Y electrode, and the address electrode in a direction from the rear substrate to the front substrate. The method of claim 1, And said dielectric layer is covered with an MgO film. The flat panel display device provided with the plasma display panel of any one of Claims 1-7.