KR100592311B1 - Plasma display panel - Google Patents

Abstract

An object of the present invention is to provide a plasma display panel in which a new discharge cell structure is introduced and an arrangement of a protective film is optimized, thereby dramatically increasing the transmittance and discharge amount of visible light and at the same time extending the life.

In order to achieve this object, the present invention is disposed to face the transparent front substrate and the front substrate, the rear substrate is edge-sealed together with the front substrate, and the front partition wall disposed behind the front substrate and formed of a dielectric And the discharge cells, which are disposed between the front bulkhead and the rear substrate and define a discharge cell that is a space for generating a discharge together with the front substrate, the front bulkhead and the rear substrate, the rear partitions formed of a dielectric material, and the front partition wall. Electrode pairs disposed to surround the discharge cells, the X electrodes extending in one direction, and the electrode pairs disposed to surround the discharge cells in the rear partition wall and having Y electrodes extending in parallel with the direction in which the X electrodes extend; And a front protective film disposed to cover at least a portion of a side surface of the front partition wall in the discharge cell, and at least one side surface of the rear partition wall. A rear protective film which is disposed to cover a portion and is thicker than the front protective film, a phosphor layer disposed in the discharge cell, a discharge gas present in the discharge cell, the phosphor layer and the rear substrate; The present invention provides a plasma display panel including address electrodes extending in a direction crossing the electrode pair in the discharge cell.

Description

Plasma display panel {Plasma display panel}

1 is an exploded perspective view showing a plasma display panel of the present invention;

2 is a perspective view showing the discharge cells, electrode pairs and address electrodes of the present invention;

3 is a cross-sectional view of the plasma display panel of the present invention taken along line III-III.

<Description of Symbols for Major Parts of Drawings>

100: plasma display panel

110: front panel 120: rear panel

113: X electrode 112: Y electrode

114: electrode pair 116f: front protective film

116a: rear shield 116r: rear shield

115: forward bulkhead 124: rear bulkhead

125: phosphor layer 126: discharge cell

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to a plasma display panel in which visible light transmittance and discharge amount are dramatically increased by introducing a new discharge cell structure.

In general, a plasma display panel is an apparatus for displaying an image using a gas discharge phenomenon, and is excellent in various display capacities such as display capacity, brightness, contrast, afterimage, viewing angle, etc. have. In such a plasma display panel, a discharge occurs in a discharge cell filled with a discharge gas by a direct current or an alternating voltage applied between electrodes, and ultraviolet rays emitted from the discharge gas excite the phosphor to emit visible light, thereby generating an image. Implement

Among the plasma display panels, a plasma display panel that is widely used is an alternating current type three-electrode surface discharge plasma display panel in which a pair of sustain electrodes are positioned on the rear surface of the front substrate and discharge occurs on the rear surface of the front substrate.

The AC-type three-electrode surface discharge plasma display panel has an electrode pair and a front dielectric layer for discharging on the rear surface of the front substrate through which visible light passes, and the transmittance of visible light is significantly reduced, resulting in a decrease in luminance.

In addition, in such an AC type three-electrode surface discharge plasma display panel, since the electrode pairs for discharging are disposed on the rear surface of the front substrate, most of the electrode pairs are used to pass visible light generated in the phosphor layer disposed inside the discharge cells. It should be formed of high resistance ITO electrode. Therefore, a voltage drop may occur at the ITO electrode, which causes a problem that the driving voltage increases and the screen is uneven.

On the other hand, in order to improve the high resistance characteristics of the ITO electrode by connecting the bus electrode formed of a metal to the ITO electrode to improve the problem of the voltage drop, the width of the bus electrode is limited due to the visible light transmittance problem, the driving voltage The problem of increase and screen unevenness is not improving.

In addition, in such an AC-type three-electrode surface discharge plasma display panel, an electrode for discharging is formed on the back surface of the front substrate through which visible light passes, so that the discharge is concentrated only in a part of the discharge cell, thereby discharging the space of the discharge cell. Could not be used efficiently. As a result, this inefficiency forced the formation of a high driving voltage for discharging, thereby increasing the price of the driving circuit which occupies a large part of the price of the plasma display panel.

In addition, when such an AC type three-electrode surface discharge plasma display panel is used for a long time, charged particles of the discharge gas are diffused backward from the back surface of the front substrate by the electric field and accelerated, thereby causing ion sputtering in the phosphor. This increases and there is a problem causing permanent afterimage on the screen.

On the other hand, in general, since the plasma display panel displays an image by using visible light generated through discharge, as the amount of discharge is increased under the same conditions, the amount of visible light is increased to increase luminance, and accordingly, the plasma display panel is increased. You can improve the picture quality of the panel. At this time, the increase and decrease of the amount of discharge depends on how many charged particles are accelerated by the electric field formed by the electrical signal applied to the electrodes and thus have kinetic energy that can cause discharge. For this reason, various attempts have been made to increase the amount of accelerated charged particles in the discharge cell, and a method of disposing a protective film for emitting secondary electrons by collision of charged particles in the double discharge cell is very effective for increasing the discharge amount. It turned out.

However, the amount of emission of secondary electrons varies depending on the arrangement state of such a protective film. In addition, when the plasma display panel is driven, the protective film is reduced in thickness by collision of charged particles, and the decrease in thickness is directly related to the lifetime of the plasma display panel. Therefore, although the thickness of the protective film needs to be sufficiently thick, there is a limit to the increase in the thickness due to the limitation of other design factors.

On the other hand, in order to implement an image, a plasma display panel generally needs to select a discharge cell so that a discharge occurs in response to an external image signal to generate visible light. At this time, the operation of selecting the discharge cells is generally performed by the address discharge, which must be accurately and stably generated due to its characteristics, and this characteristic has a very important effect on image realization and image quality. Therefore, it is very important to ensure that such address discharge occurs stably.

The present invention is intended to solve the following matters to solve the above problems.

First, it aims to increase brightness by improving aperture ratio and remarkably improving the transmittance of visible light.                         

Secondly, it is an object to make it possible to use a material other than ITO as a material for forming an electrode, to reduce the manufacturing cost of the electrode, to improve the electrical conductivity, and to facilitate the large area of the plasma display panel.

Third, an object of the present invention is to reduce the manufacturing cost of the plasma display panel by increasing the amount of discharge by causing the discharge to be three-dimensionally formed in the entire discharge cell, thereby reducing the driving voltage.

Fourthly, an object of the present invention is to prevent ion sputtering of a phosphor to increase the lifetime of the phosphor.

Fifth, the object of the present invention is to optimize the arrangement of the protective film to realize stable address discharge and to increase the lifetime of the plasma display panel.

Sixthly, an object of the present invention is to reduce the defect rate of the plasma display panel by fundamentally preventing shorting that may occur between the X electrode and the Y electrode when disposing the X electrode and the Y electrode in the partition wall.

Seventhly, the purpose of the present invention is to increase the discharge amount of the plasma display panel by increasing the amount of secondary electrons generated in the protective film, thereby increasing the luminance of the plasma display panel.

In order to achieve the above object, the present invention is disposed to face the transparent front substrate and the front substrate, the rear substrate is edge-sealed together with the front substrate, and is disposed in the rear of the front substrate and formed of a dielectric A rear partition wall disposed between the front partition walls, the front partition wall and the rear substrate, and defining discharge cells which are spaces for generating a discharge together with the front substrate, the front partition wall and the rear substrate, and formed of a dielectric; It is disposed to surround the discharge cell in the partition wall, and arranged to surround the discharge cell in one direction and the rear partition, and Y electrodes extending in parallel with the direction in which the X electrode extends Electrode pairs, a front protective film disposed to cover at least a portion of a side surface of the front partition wall in the discharge cell, and a side surface of the rear partition wall It is disposed to cover at least a portion, the rear protective film thicker than the front protective film, the phosphor layer disposed in the discharge cell, the discharge gas existing in the discharge cell and the phosphor layer and the rear substrate is disposed And an address electrode extending in a direction crossing the electrode pair in the discharge cell.

Through this, short circuit between the X electrode and the Y electrode is prevented at the time of applying the process of disposing the X electrode and the Y electrode, thereby minimizing the defect rate of the plasma display panel, and increasing the amount of discharge during address discharge, thereby ensuring stable address discharge. In addition to this, the life of the plasma display panel is increased by optimizing the arrangement of the protective film.

On the other hand, in the plasma display panel of the present invention, it is preferable to further include a rear protective film disposed on the rear surface of the front substrate, through which, the amount of discharge of secondary electrons is increased when the plasma display panel is driven. The brightness of the plasma display panel is increased accordingly.

On the other hand, it is preferable that the roughness of the rear passivation layer is larger than the roughness of the front passivation layer, and through this, the discharge amount of secondary electrons is further increased during address discharge, thereby enabling stable address discharge.

On the other hand, it is preferable that the Y electrode is a scan electrode and the X electrode is a sustain electrode.

In addition, the protective film is preferably disposed by a deposition process.

In addition, the electrode pair is preferably extended in a ladder shape.

Hereinafter, exemplary embodiments of the plasma display panel 100 of the present invention will be described with reference to FIGS. 1 to 3.

 The plasma display panel 100 according to the present invention shown in FIG. 1 is manufactured separately to facilitate the manufacturing process, and then the front panel 110 and the rear panel 120 are joined by a coupling member such as a frit. ).

On the other hand, the front panel 110 is provided with a front substrate 111 formed of a transparent material, preferably soda glass. In addition, the front panel 110 is formed on the rear of the front substrate, more specifically, the rear surface 111b of the front substrate, and the front substrate 111 and the rear substrate 121 and rear partition wall 124 to be described later. Together with the discharge cells 126, which are spaces that cause discharge, the front partition wall 115 is formed of a dielectric material.

In addition, the front panel 110 is disposed to surround the discharge cell 126 in the front partition wall and includes an X electrode 113 extending in one direction. At this time, since the X electrode is disposed in the front partition wall 115, it is not located on the optical path that is the path of visible light, it does not need to be formed of a transparent ITO electrode, Ag, Cu, Cr, etc. having good electrical conductivity It is possible to form.

On the other hand, the front partition wall 115 may be formed of a glass component including elements such as Pb, B, Si, Al, and O, etc., if necessary, ZrO ₂ , TiO ₂ , and Al ₂ O _It may be formed of a dielectric including fillers such as ₃ and pigments such as Cr, Cu, Co, Fe, TiO _2, etc., wherein the dielectric is charged particles when a pulse voltage is applied to the X electrode 113. By inducing the wall charge participating in the discharge to enable the drive through the memory effect, and serves to protect the X electrode 113 from being damaged due to the collision of charged particles accelerated during discharge.

On the other hand, the front panel 110 includes a front protective film 116f disposed to cover the side surface 115a of the front partition wall 115 in the discharge cell 126. In this case, the front passivation layer 116f may be disposed by a deposition method using MgO or the like, and the front passivation layer 116f is not disposed on the optical path of visible light, and thus has excellent secondary electron emission characteristics and durability. The protective film may be formed of a material such as strong carbon nanotubes (CNT).

On the other hand, in the process of arranging the front protective film 116f by the deposition, the rear protective film 116r may be disposed on the rear surface 111a of the front substrate 111, the discharge due to the arrangement of the rear protective film 116r When discharge proceeds in the cell 126, secondary electrons can be discharged in the discharge cell 126 to further increase the discharge amount. However, arrangement of the rear protective film 116r is not necessarily essential.

On the other hand, since the rear protective film 116r is disposed on an optical path that is a traveling path of visible light, the rear protective film is preferably formed of MgO or the like.

On the other hand, the rear panel 120 is preferably provided with a back substrate 121 formed of soda glass or the like. In this case, the back substrate is not a component located on an optical path through which visible light generated in a discharge cell travels, and thus it is not necessarily formed of transparent glass, for reducing reactive power or weight. It can be formed from other materials such as plastic and metal.

On the other hand, the rear panel 120 is disposed between the front partition wall 115 and the rear substrate 121, the space causing the discharge along with the front partition wall 115, the front substrate 111 and the rear substrate 121. Phosphorous discharge cells 126 are defined and have a rear partition 124 formed of a dielectric. In this case, the rear bulkhead 124 may be formed of the same material as the front bulkhead 115.

In addition, the rear panel 120 is disposed to surround the discharge cell 126 in the rear partition 124 and includes a Y electrode 112 extending in parallel with the direction in which the X electrode 113 extends. do. In this case, since the Y electrode 112 also does not exist on the optical path through which visible light travels, unlike the AC-type three-electrode surface discharge plasma display panel, the Y electrode 112 does not need to be formed of ITO or the like. It may be formed of a material having good conductivity.

On the other hand, the X electrode 112 provided in the front panel and the Y electrode 112 provided in the rear panel constitute an electrode pair 114. In this case, as described above, since the electrode pair 114 is disposed in the partition wall 130 unlike the conventional AC plasma display panel, the electrode pair 114 does not exist on the optical path that is the path of visible light generated in the phosphor layer 125. Visible light is not blocked due to the presence of the electrode pair, thereby greatly increasing the aperture ratio of the discharge cell 126.

Meanwhile, since the front panel 110 and the rear panel 120 are manufactured separately, the front panel 110 and the rear panel 120 are coupled to each other in a state where the front panel 110 and the rear panel 120 are completed. Each of the X electrode 113 and the Y electrode 112 disposed in the 124 is not shorted with each other when the front panel and the rear panel are coupled to each other. That is, when the X electrode and the Y electrode are disposed in the bulkhead in the process of forming one partition wall, the X electrode and the Y electrode are often shorted to each other during the process, but the plasma display panel of the present invention In the front bulkhead 115 and the rear bulkhead 124 are separately manufactured, and the X electrode and the Y electrode is disposed in each of the front bulkhead and the rear bulkhead by a separate process, the X electrode and the Y electrode due to a poor process The possibility of shorting is significantly reduced.

On the other hand, the rear panel 120 is disposed between the phosphor layer 125 to be described later and the back substrate 121, more specifically in the preferred embodiment of the present invention is disposed on the front surface (121a) of the back substrate, The discharge cells 126 may include address electrodes 122 extending in a direction crossing the electrode pairs 114. In this case, since the address electrode 122 is not positioned on the optical path, which is a path through which visible light travels, similarly to the electrode pair 114, it is not necessary to form a transparent ITO electrode, and has good electrical conductivity of Ag, Cu, Cr or the like.

On the other hand, the rear panel 120 preferably includes a dielectric layer 123 disposed to cover the address electrode 122. In this case, the dielectric layer is not necessarily an essential component. If the phosphor layer 125 to be described below is disposed to cover the address electrode, the phosphor layer may function as a dielectric layer and thus may be omitted. However, the dielectric layer 123 is more preferably disposed to induce charged particles and to protect the address electrode 122.

Meanwhile, the front partition wall 115 and the rear partition wall 124 may be formed as one partition wall 130 when the front panel 110 and the rear panel 120 are combined to manufacture the plasma display panel 100. Formed and functions.

On the other hand, in the shape of the discharge cell 126 defined by the partition wall 130, although the cross section is shown in Figure 1 as being rectangular, there is no limitation on the shape of the discharge cell, polygonal, circle, honeycomb form Various forms of shape can be modified.

On the other hand, the rear panel 120 includes a phosphor layer 125 disposed in the discharge cell 126. In this case, the phosphor layer 125 may be divided into red, green, and blue light emitting phosphor layers to be disposed in the discharge cell 126 so that the plasma display panel may realize a color image. The green, blue, and blue light emitting phosphor layers may be disposed inside the discharge cell to form a unit pixel for implementing a color image.

Meanwhile, the arrangement of the phosphor layer 125 will be briefly described with reference to the enlarged view of FIG. 1. When the dielectric layer 123 is disposed on the rear panel 120, the first rear portion is a part of the rear partition wall 124 formed in a predetermined pattern on the dielectric layer 123 and on the rear substrate 121. The partition body layer 124b is formed. Subsequently, a phosphor, a solvent, and a binder of any one of a red light emitting phosphor, a green light emitting phosphor, and a blue light emitting phosphor in a space defined by the first rear barrier rib layer 124b and the dielectric layer 123 or the back substrate 121. The phosphor layer 125 is mixed and then the phosphor layer 125 is disposed by drying and baking the paste. Thereafter, while forming the second rear partition wall layer 124a on the first rear partition wall layer 124b, the Y electrode 112 is disposed in the second rear partition wall layer 124a.

On the other hand, the red light emitting phosphor includes (Y, Gd) BO ₃ : Eu ³⁺ and the like, and the green light emitting phosphor includes Zn ² Si 04: Mn ²⁺ , and as the blue light emitting phosphor, BaMgAl ₁₀ O ₁₇ : Eu ²⁺ is used. In addition, various phosphors may be used.

Meanwhile, the discharge cells 126 in which the red, green, and blue light emitting phosphor layers 125 are disposed may be adjacent to each other in one direction to form a unit pixel which is a basic unit for implementing an image. However, the arrangement of the discharge cells 126 of the present invention is not limited to being arranged in one direction as described above in order to implement a color image, and in some cases, the width or length of the discharge cells may vary depending on the efficiency of the phosphor. They may differ from one another, and their arrangement may vary from lattice to delta.

On the other hand, the rear panel 120 is disposed on the side surface of the rear partition wall 124, more specifically the side surface 124c of the first rear partition wall layer 124a and has a thickness t of the front protective film 116f. Has a thick rear protective film 116a. In this case, the rear passivation layer 116a may be disposed by a process such as deposition. In this case, the passivation layer may be disposed on the front surface 125a of the phosphor layer 125 in addition to the side surface 124c of the rear partition. However, the protective film disposed on the front surface of the phosphor layer does not adversely affect the plasma display panel 100 of the present invention, but rather protects the phosphor layer 125 from the collision of accelerated charged particles and prevents secondary electrons from being discharged in the discharge cell. By increasing the discharge amount, it helps to increase the discharge amount.

On the other hand, it is preferable that the roughness of the rear passivation film 116a is larger than the roughness of the front passivation film 116f. In this case, as a method of increasing the roughness of the rear protective layer 116a, in the process of forming the rear partition 124, the roughness of the side surface of the rear partition is increased by adjusting the viscosity of the dielectric material, which is a material of the rear partition, upwardly. By doing so, it is possible to increase the roughness of the rear protective film 124 disposed on the side of the rear partition 124 during deposition of the rear protective film. The reason why the thickness of the rear passivation layer 116a is thicker than the front passivation layer and the reason why the roughness of the rear passivation layer 116a is increased will be described later.

Meanwhile, the front panel 110 and the rear panel 120 are joined and sealed by a coupling member such as a frit (not shown), and inside the discharge cell, Xen gas (10% before and after) is discharged. The discharge gas consisting of any one of neon (Ne), helium (He), or argon (Ar) or a mixed gas of two or more thereof is filled. In this case, since the discharge gas is generally charged at a pressure lower than atmospheric pressure, the front panel 110 and the rear panel 120 by the partition wall 130 formed by the combination of the front partition wall 115 and the rear partition wall 124. ) Is supported.

Hereinafter, the arrangement of the electrode pairs 114 of the plasma display panel 100 of the present invention will be described with reference to FIG. 2. 2 shows an arrangement of an electrode pair 114 having an X electrode 113 and a Y electrode 112, an address electrode 122, and a discharge cell 126. In this case, the X electrode 113 and the Y electrode 112 has a ladder shape and extends in parallel to each other along the direction of the x-axis, the X electrode 113 and the Y electrode 112 in the discharge cell 126. The address electrode 122 extends in the direction of the y-axis that intersects with the extending direction. Meanwhile, the X electrode and the Y electrode do not necessarily extend in a ladder shape, and in some cases, the extension may be extended by an extension having a predetermined size.

On the other hand, since the distance between the Y electrode 112 and the address electrode 122 is short, it is preferable that an address discharge for selecting a discharge cell in which sustain discharge is to occur occurs between the Y electrode 112 and the address electrode 122. In this case, it is preferable that the Y electrode 112 be a scan electrode and the X electrode 113 be a sustain electrode.

In this case, since the address discharge refers to a discharge occurring independently in a discharge cell selected by the crossing of the Y electrode and the address electrode, the meaning that the Y electrode 112 becomes a scan electrode means that an address electrode (for each of the Y electrodes 112) is used. Like 122), it means that the driving pulse signal is applied independently.

In addition, the X electrode 113 becomes the sustain electrode, which means that the entire driving pulse signal is applied to all of the X electrodes without applying an independent driving pulse signal, thereby causing sustain discharge. (113) is used. However, all of the X electrodes 113 do not necessarily need to have a signal applied in common, and if necessary, a signal may be applied separately between the X electrodes.

Hereinafter, referring to FIG. 3, an example of the operation of the plasma display panel 100 and the thickness t and the roughness of the rear passivation layer 116a in the present invention are arranged to be larger than that of the front passivation layer 116f. The reason for this will be briefly described.

The driving method for driving the plasma display panel according to the present invention may include various driving methods such as ADS driving and ALIS driving, and various factors such as the image quality and response speed of the plasma display panel may vary according to driving methods. Since this does not change the essential features of the present invention, an example of driving the plasma display panel of the present invention will be described below with reference to the ADS driving method.

In general, a discharge occurs in each of the discharge cells 126 included in the plasma display panel for displaying an image for realizing an image. As a result, the state of the wall charges or the amount of charged particles are different between the discharge cells 126, and thus, the desired control between the discharge cells is desired when the discharges occurring in the discharge cells are to be controlled in a uniform manner. It happens that it is difficult to make. In order to prevent such a difficulty of the discharge control, by applying a high voltage of a predetermined level or more to all the discharge cells to generate a discharge in all the discharge cells at the same time by removing the wall charges existing in the discharge cells to equalize, discharge cells Induced to be the same state of the charged particles in this is called a reset discharge.

Such a reset discharge is generally performed by applying a high potential lamp potential to all the Y electrodes 112 and applying a ground potential to all the address electrodes 122 to discharge all of the discharge cells.

Then, after the above-described reset discharge occurs, an address discharge occurs. In this case, the address discharge refers to a discharge cell in which one of the electrode pairs 114, that is, the Y electrode 112 and the address electrode 122, intersects a discharge cell in which an image is to be implemented in response to an external image signal. 126, a predetermined pulse voltage of opposite polarity is applied to the Y electrode 112 and the address electrode 122 to cause the discharge cell to discharge, and the discharge cell is caused by the discharge. The sidewalls of the barrier ribs 130 in the interior, more specifically, the charges are attached to the sidewalls 124c of the rear barrier ribs 124 to refer to the discharge to accumulate wall charges.

On the other hand, when such an address discharge occurs, only a predetermined bias voltage is applied to the X electrode 113, so that the charged particles are disposed on the Y electrode rather than the front passivation layer 116f covering the side surface of the front partition wall 115 on which the X electrode is disposed. More concentrated collision with the rear protective film 116a covering the side surface of the rear partition 124 where the 112 is disposed. At this time, the rear protective film 116a covering the side surface of the rear bulkhead 116a is damaged more quickly due to the collision of the charged particles, so that the thickness of the rear protective film 116a is reduced when used for a long time. On the other hand, during the sustain discharge described later, the charged particles collide with both the front protective film and the rear protective film to damage the protective film, but the rear protective film 116a is damaged due to the collision of the charged particles even during address discharge. Therefore, when the rear protective film 116a disappears due to the collision of the charged particles, the rear partition and the Y electrode may be damaged even if the front protective film 116f that covers the side surface of the front partition wall 115 remains. The plasma display panel cannot realize the desired image, and consequently, the lifetime of the plasma display panel is limited by the damage of the rear protective film 116a.

Therefore, in the present invention, the thickness of the rear passivation layer 116a is arranged to be thicker than the thickness of the front passivation layer 116f, thereby compensating that the rear passivation layer 116a having relatively frequent collisions of charged particles decreases in thickness more quickly. .

In addition, when the roughness of the rear passivation layer 116a covering the side surface of the rear partition 124 is formed to be larger, when the charged particles collide with the rear passivation layer 116a, due to the roughness of the rear passivation layer 116a. In the rear passivation layer 116a, the discharge amount of the secondary electrons is increased, and accordingly, the discharge amount is increased during address discharge, so that address discharge can be stably generated. In this case, the stable address discharge means that the discharge cell in which the discharge should be generated is selected correctly in response to the external image signal, which means that the desired image is realized and consequently, the image quality of the plasma display panel is improved.

Subsequently, when a high voltage pulse voltage is applied to the Y electrode 112 and a pulse voltage of a relatively low voltage is applied to the X electrode 113, when the address is discharged due to a potential difference generated between the X electrode and the Y electrode. The wall charges accumulated on the inner side of the discharge cell 126 are moved. At this time, as the wall charges move, the discharge gas atoms in the discharge cells collide with the wall charges, thereby causing a discharge to generate plasma. At this time, the discharge is likely to occur from the portions close to each other of the X electrode 113 and the Y electrode 112 in which a relatively strong electric field is formed.

At this time, in the case of the plasma display panel 100 of the present invention, the electrode pairs 130 are disposed in the partition wall 130 to surround the discharge cells, unlike the conventional AC three-electrode surface discharge plasma display panel. As a result, the probability of discharge occurring on the side surfaces of the discharge cells in the vicinity where the X electrode 113 and the Y electrode 112 are disposed increases, and thus, unlike the conventional AC three-electrode surface discharge plasma display panel, Discharge may occur on the inner side of the surroundings, thereby greatly increasing the probability of discharge and the amount of discharge.

In addition, when the discharge is successfully generated along the inner side of the discharge cell, and the voltage between the discharge electrodes is maintained for a predetermined time, the electric field formed on the side of the discharge cell 126 is strongly concentrated in the center, the discharge Compared to the prior art, the area of is greatly enlarged, whereby the amount of ultraviolet rays generated by the discharge is increased.

In addition, since the electric field is strongly concentrated in the center during discharge, the amount of accelerated charged particles proceeding to the phosphor layer 125 is lower than that of the alternating three-electrode surface discharge type, and ion sputtering is a phenomenon in which ions collide with the phosphor layer. This occurs less frequently and can increase the life of the phosphor layer.

Meanwhile, the ultraviolet rays generated by the discharge excite the phosphor layer 125 disposed in the discharge cell, and the visible phosphor layer moves to a low energy level to generate visible light, thereby realizing an image of the plasma display panel.

On the other hand, when the voltage difference between the electrode pairs 130 is lower than the discharge voltage after the discharge occurs, the discharge is no longer generated, the space charge and the wall charge is formed in the discharge cell 126. At this time, when the polarity of the pulse voltage between the discharge electrodes is changed and a voltage lower than the applied voltage is applied, the discharge starting voltage is reached with the help of the wall charge, and the discharge is generated again. In addition, when the pulse voltage is alternately applied between the electrode pairs 130 alternately, the discharge is maintained. At this time, such discharge is called sustain discharge, and the gray scale of the plasma display panel 100 is determined by the sustain discharge, thereby realizing an image.

The present invention achieves the effect as described below.

First, unlike conventional AC three-electrode surface discharge plasma display panels, there is no electrode pair or dielectric layer on the optical path, which is a path through which visible light travels, and the aperture ratio is dramatically improved. The transmittance was dramatically increased, and the luminance was greatly increased.

Secondly, unlike conventional AC three-electrode surface discharge plasma display panels, electrode pairs are arranged in the partition wall so that a material other than ITO can be used as a material for electrode formation, thereby reducing the manufacturing cost of the electrode and The electrical conductivity of is improved, making it easy to increase the area of the plasma display panel.                     

Third, the amount of discharge is dramatically increased compared to the conventional AC three-electrode surface discharge plasma display panel in which the discharge is formed in three dimensions in the entire discharge cell, and the discharge is formed on one surface of the discharge cell. The manufacturing cost of the plasma display panel was reduced by the reduction of the pressure.

Fourthly, the discharge is concentrated in the center and the amount of charged particles accelerated toward the phosphor layer is reduced, thereby preventing ion sputtering of the phosphor, thereby increasing the life of the phosphor.

Fifth, the arrangement of the protective film was optimized to realize stable address discharge and to increase the lifetime of the plasma display panel.

Sixth, when arranging the X electrode and the Y electrode in the partition wall, each of the X electrode and the Y electrode is separately disposed in the front and rear partitions respectively to complete the front and rear partitions by combining the front panel and the rear panel In addition, the defect rate of the plasma display panel is reduced by fundamentally preventing shorting between the X electrode and the Y electrode, which may be caused by a process defect.

Seventhly, the amount of discharge of the plasma display panel is increased by adding a protective film to increase the discharge amount of secondary electrons, thereby increasing the brightness of the plasma display panel.

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 (6)

A rear substrate disposed to face the transparent front substrate and the front substrate, and the edge of which is sealed together with the front substrate; Front bulkheads disposed at a rear side of the front substrate and formed of a dielectric; Rear barrier ribs disposed between the front barrier rib and the rear substrate and defining discharge cells which are spaces for generating a discharge together with the front substrate, the front barrier rib and the rear substrate; It is disposed to surround the discharge cell in the front bulkhead, and disposed to surround the discharge cells in one direction and the Y electrode extends in parallel to the direction in which the X electrode extends. Electrode pairs; A front passivation layer disposed to cover at least a portion of a side surface of the front partition wall in the discharge cell, and a rear passivation layer disposed to cover at least a portion of the side surface of the rear partition wall and having a thickness greater than that of the front passivation layer; A phosphor layer disposed in the discharge cell; Discharge gas existing in the discharge cell; And And an address electrode disposed between the phosphor layer and the rear substrate and extending in a direction crossing the electrode pair in the discharge cell. The method of claim 1, And a rear passivation layer disposed on a rear surface of the front substrate. The method of claim 1, And the roughness of the rear passivation layer is greater than the roughness of the front passivation layer. The method of claim 1, The Y electrode is a scan electrode, and the X electrode is a sustain electrode. The method of claim 1, The protective film is a plasma display panel, characterized in that disposed by the deposition process. The method of claim 1, And the electrode pairs extend in a ladder shape.

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