KR100553771B1 - Plasam display panel - Google Patents

Abstract

An object of the present invention is to provide a high quality low cost plasma display panel capable of low voltage driving while increasing the amount of discharge and increasing the ratio of xenon gas in the discharge gas to increase the amount of visible light generated.

In order to achieve this object, the present invention is a transparent front substrate and the rear substrate which is disposed to face the front substrate spaced apart by a predetermined distance, and disposed between the front substrate and the rear substrate, together with the front substrate and the rear substrate Barrier ribs defining discharge cells, which are spaces for causing discharge, and are disposed at a rear side of the front substrate, extend in one direction in which the discharge cells extend, and traverse the discharge cells that extend; A pair of sustain electrode pairs having an X electrode and a Y electrode provided between the sustain electrode pairs and the sustain electrode pairs behind the front substrate and extending in parallel with a direction in which the sustain electrode pairs extend. A plurality of intermediate electrodes including transparent electrodes and bus electrodes, and covering the sustain electrode pairs and the intermediate electrodes. An address electrode disposed in the discharge cell between the rear dielectric layer and the rear substrate and the front dielectric layer and extending across the discharge cells so as to cross the direction in which the intermediate electrodes extend; A bus electrode of the intermediate electrode provided with a phosphor layer covering the address electrode and a discharge gas in the discharge cell, and a sustain discharge displaying a predetermined gray scale in the discharge cell is triggered between the X electrode and the intermediate electrode. The present invention provides a plasma display panel, which is positioned in a direction in which the X electrodes are disposed.

Description

 Plasma display panel {Plasam display panel}

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

2 is a schematic view showing a plasma display device showing a method of applying an electrical signal applied to an electrode of the present invention,

3 is a waveform diagram showing waveforms of signals applied to the X electrode, the Y electrode, and the intermediate electrode of the present invention in one subfield;

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

<Description of Symbols for Major Parts of Drawings>

X1 .... Xn: X electrodes per line Y1 .... Yn: Y electrodes per line

A _R1 ... A _BM : line-by-line address electrodes M1 ..- Mn: line-by-line intermediate electrodes;

S _M : Electrical signal applied to intermediate electrode

S _X : electrical signal applied to the X electrode

S _Y : Electrical signal applied to Y electrode

S _M : electrical signal applied to M electrode

100: plasma display panel

110: front panel 120: rear panel

113: X electrode 112: Y electrode

114: sustain electrode pair 150: intermediate electrode

The present invention relates to a high quality, low cost plasma display panel.

BACKGROUND ART In general, a plasma display panel is a display device that realizes a predetermined image by exciting phosphors by ultraviolet rays generated by gas discharge, and has been spotlighted as a next-generation thin display device because a large screen can be configured with high resolution.

Conventionally, such plasma display panels are divided into AC type, DC type, and hybrid type according to the structure and driving principle, and AC type and DC type plasma display panel according to the discharge structure. Is divided into a surface discharge type and a counter discharge type, but in recent years, an AC type surface discharge plasma display panel has become popular.

The AC type surface discharge plasma display panel has been widely used due to its advantages such as lifespan and stability. However, only a small percentage of the power supplied to the plasma display panel is used for image realization, and thus the power consumption efficiency is very low. It has a disadvantage. However, the reason why the power consumption efficiency of the plasma display panel is extremely low is that only a part of the supplied power is used to cause discharge in the discharge cell, and most of the energy is not only wasted as unnecessary elements such as heat and sound. Even if the discharge occurs, the amount of ultraviolet light having a wavelength suitable for causing the visible light to be expressed in the phosphor layer among the ultraviolet rays generated through the plasma discharge is small, and as a result, the energy used directly for the expression of visible light is less than the energy used to generate the discharge. Because. In order to overcome this problem, a predetermined electric field is formed in the discharge cells to implement an image across the discharge cells, so that the distances between the sustain electrode pairs causing the discharge are sufficiently spaced, and an ultraviolet ray having a wavelength suitable for visible light of the phosphor is generated. Although a method of increasing the ratio of gas has been attempted, when the distance between the sustain electrode pairs increases, and if the ratio of xenon gas increases, the driving voltage must be proportionally increased, thereby applying the discharge electrode pairs. Since a driver integrated circuit chip that controls the electrical signal to be applied should be applied as being capable of driving at a high potential, a problem of increasing the manufacturing cost of the plasma display panel has been found.

Disclosure of Invention The present invention solves the above problems, and aims to provide a high quality low cost plasma display panel capable of low voltage driving while increasing the amount of discharge and increasing the ratio of xenon gas in the discharge gas to increase the amount of visible light. It is done.

In order to achieve the above object, the present invention is a transparent front substrate and the rear substrate which is disposed to face the front substrate spaced apart by a predetermined distance, and disposed between the front substrate and the rear substrate, the front substrate and the rear substrate Barrier ribs defining discharge cells, which are spaces for generating discharge together with a substrate, disposed behind the front substrate, extending in one direction in which the discharge cells extend, traversing the discharge cells extending, and A pair of sustain electrode pairs having an X electrode and a Y electrode having a bus electrode, and a pair of the sustain electrode pairs behind the front substrate, and extending in parallel with a direction in which the sustain electrode pairs extend; The front panel crossing the discharge cells and covering the intermediate electrodes including a transparent electrode and a bus electrode, and covering the sustain electrode pairs and the intermediate electrodes; A front dielectric layer disposed behind the plate, address electrodes disposed in the discharge cell between the rear substrate and the front dielectric layer and extending across the discharge cells so as to cross a direction in which the intermediate electrodes extend; The intermediate layer having a phosphor layer disposed in the cell and covering the address electrode, and a discharge gas in the discharge cell, wherein a sustain discharge displaying a predetermined gray scale in the discharge cell is triggered between the X electrode and the intermediate electrode; Provided is a plasma display panel, wherein a bus electrode of the electrode is positioned in a direction in which the X electrode is disposed.

In this case, the spaced distance between the transparent electrode of the X electrode and the bus electrode of the intermediate electrode is preferably smaller than the spaced distance between the transparent electrode of the Y electrode and the bus electrode of the intermediate electrode. It is particularly preferred that the spaced distance between the intermediate electrodes is less than or equal to 95 μm and greater than or equal to 70 μm.

Meanwhile, in the plasma display panel of the present invention, a spaced distance between the transparent electrode of the X electrode and the transparent electrode of the intermediate electrode may be smaller than a spaced distance between the transparent electrode of the Y electrode and the transparent electrode of the intermediate electrode. .

In addition, the X electrodes are electrically connected to each other such that the same potential is applied between the X electrodes, and the Y electrodes are electrically connected to each other such that the same potential is applied to the Y electrodes.

On the other hand, the plasma display panel of the present invention preferably further comprises a protective film disposed on the rear surface of the front dielectric layer, further comprising a rear dielectric layer disposed to cover the address electrode between the phosphor layer and the address electrode.

Hereinafter, a preferred embodiment of the plasma display panel 100 of the present invention will be described with reference to FIG. 1. The plasma display panel 100 includes a front panel 110 and a rear panel 120. The front panel 110 is disposed on the front substrate 111, the rear of the front substrate, more specifically, the rear surface 111a of the front substrate, between the front substrate 111 and the rear substrate 121 to be described later. The discharge electrode 126, which is a space causing the discharge defined by the partition wall 124, is extended along one direction in which the discharge cells 126 extend and extend across the discharge cell 126. 113 are disposed between each of the sustain electrode pairs 114 including the sustain electrode pairs 114, the back of the front substrate, and more particularly, the sustain electrode pairs 114 of the rear surface 111a of the front substrate. The intermediate electrode 150 extends in parallel with the extending direction of the pair to cross the discharge cells. In this case, the storage electrode pairs and the intermediate electrodes may be disposed on the rear surface of the layer, not the rear surface of the front substrate, when a layer having a separate function such as a near infrared absorbing layer is disposed on the rear surface of the front substrate. As such, the arrangement position of the sustain electrode pair and the intermediate electrode is not limited to the rear surface of the front substrate, but is sufficient to be disposed behind the front substrate. Meanwhile, each of the Y electrode 112 and the X electrode 113 includes transparent electrodes 112b and 113b formed of ITO or the like for transmitting visible light, and the transparent electrode is generally not used alone due to its high resistance. The X electrode and the Y electrode include bus electrodes 112a and 113a formed of a metal having high conductivity. The bus electrodes 113a and 112a may be disposed on the rear surfaces 113bb and 112bb of the transparent electrode, but the bus electrodes 113a and 112a are not necessarily limited to this position, and the bus electrode and the transparent electrode may be electrically connected to each other. Meanwhile, the bus electrodes 112a and 113a are connected to a connection cable (not shown) disposed on the left and right sides of the plasma display panel 100. In addition, since the intermediate electrode 150 is applied with an electrical signal like the sustain electrode pairs and positioned on the rear surface of the front substrate, the intermediate electrode 150 is formed of ITO or the like as the sustain electrode pairs. And a metallic bus electrode 150a. In this case, the bus electrode 150b of the intermediate electrode is formed so that the sustain electrode displaying a predetermined gray scale in the discharge cell is triggered between the X electrode 113 and the intermediate electrode 150. The X electrodes are oriented in the direction in which they are arranged. Hereinafter, the arrangement and characteristics of the sustain electrode pair and the intermediate electrode will be described in detail later.

The front panel 110 includes a front dielectric layer 115 covering the sustain electrode pairs 114 and the intermediate electrodes 150. In addition, the front panel may include a passivation layer 116 disposed on the first dielectric layer to protect the sustain electrode pairs, the intermediate electrodes, and the front dielectric layer. In this case, the passivation layer 116 is formed of MgO or the like, and the passivation layer functions to protect the sustain electrode pairs, the intermediate electrodes, and the front dielectric layer, and increases discharge of secondary electrons during discharge. To facilitate.

The rear panel 120 is disposed in the discharge cell 126 between the rear substrate 121, the rear substrate 121, and the front dielectric layer 115, and more specifically, the intermediate part of the rear panel 120 on the front surface 121a of the rear substrate. The address electrodes 122 extend across the discharge cells 126 so as to cross the direction in which the electrodes 150 extend. On the other hand, it is preferable that the rear dielectric layer 123 disposed to cover the address electrode to protect the address electrode and to accumulate wall charges. However, when the phosphor layer 125 described later covers the address electrode while being disposed in a discharge cell, the phosphor layer may function as a dielectric layer, and thus the rear dielectric layer 123 is not necessarily a structure.

In addition, the rear panel 120 is disposed between the front substrate and the rear substrate, more specifically, in front of the rear dielectric layer 123, and discharges together with the front substrate 111 and the rear substrate 121. A partition wall 124 defining the discharge cells 126, which are the spaces to be generated, and the phosphor layer 125 disposed in the discharge cells are provided. On the other hand, the phosphor layer is more preferably disposed in the space defined by the partition wall 124 and the rear dielectric layer 123 for the process and the emission of visible light. In this case, the partition wall is a discharge cell that implements an image by applying a predetermined voltage to the plasma display panel and generating light by generating plasma discharge due to a collision of discharge gas particles and charge induced by an electric field induced by the voltage ( 126 to form a basic unit of an image, and prevent cross talk between discharge cells. In addition, the discharge cell is filled with a discharge gas (approximately 0.5 atm or less) of a vacuum lower than atmospheric pressure, and the partition wall supports the pressure generated between the front panel and the rear panel. The discharge gas is filled with a discharge gas consisting of any one of neon (Ne), helium (He), argon (Ar), or a mixed gas of two or more thereof, including xenon (Xe) gas.

Meanwhile, the phosphor layer 125 disposed in the discharge cell may include red, green, and blue light emitting phosphor layers to enable the plasma display panel to realize a color image. , And the blue light emitting phosphor layers may be disposed inside the discharge cell to form a unit pixel. The phosphor layer may include a phosphor paste in which any one of a phosphor, a solvent, and a binder is mixed with a red light emitting phosphor, a green light emitting phosphor, and a blue light emitting phosphor. It is formed by going through a drying and firing process after being applied to a portion of the. Examples of the red light emitting phosphor include (Y, Gd) BO ₃ : Eu ³⁺ , and examples of the green light emitting phosphor include Zn ² Si 04: Mn ^{2 +,} and examples of the blue light emitting phosphor include BaMgAl ₁₀ O ₁₇ : Eu ²⁺ . The address electrodes 122 are connected to connection cables (not shown) disposed above and below the plasma display panel.

Hereinafter, an electrical signal applied to the sustain electrode pair, the intermediate electrode, and the address electrode corresponding to an external image signal to implement an image of the plasma display panel according to the present invention will be described with reference to FIGS. 2 to 4. An application method, its features, and the arrangement and function of the intermediate electrode will be described.

The plasma display device shown in FIG. 2 includes a plasma display panel 100, an image processor 66, a logic controller 62, an address driver 63, an intermediate electrode driver 67, an X electrode driver 64, and a Y electrode. The drive unit 65 is included. The image processor 66 processes an external image signal to generate an internal image signal including red (R), green (G), and blue (B) digital image data, a clock signal, and vertical and horizontal synchronization signals. The logic controller 62 generates drive-control signals S _A , S _M , S _Y , S _X in accordance with an internal image signal from the image processor 66. The address driver 63 processes the address signals S _A from the logic controller 62 to generate display data signals, and generates the generated display data signals through the address electrode lines A _R1 , A _G1 , and A _B1. ..., A _Bm ). The M driver 67 operates in accordance with the M drive-control signal S _M from the logic controller 62 to drive the M electrode lines M ₁ , ..., Mn. The X driver 64 operates in accordance with the X drive-control signal S _X from the logic controller 62 to drive the X electrode lines X ₁ ,..., Xn. The Y driver 64 operates in accordance with the Y drive-control signal S _Y from the logic controller 62 to drive the Y electrode lines Y ₁ ,..., Y n. In this case, the X electrodes are preferably electrically connected to each other such that the same X driving control signal Sx is applied to each other, and the Y electrodes are electrically connected to each other such that the same Y driving control signal Sy is applied to each other. It is preferable to be connected to. Meanwhile, at this time, each of the X electrodes is electrically connected to each other, so that the entire X electrodes are controlled by only one driving circuit, and each of the Y electrodes is electrically connected to each other, so that only one driving circuit is used for the entire Y. Since the electrodes can be controlled, there is no or minimal number of driving circuits due to the arrangement of the intermediate electrodes. As a result, the manufacturing cost of the plasma display panel does not increase.

Meanwhile, a scan pulse is sequentially applied to each of the intermediate electrode lines M ₁ , ..., Mn to perform an address discharge for selecting a discharge cell to emit light, and at the same time, the address electrode lines A _R1,. ..., it is applied to the data pulse to the address electrode lines selected from the group consisting of a _Bm). Next, all of the X electrode lines (X1, ..., Xn) and all of the Y electrode lines are caused so that the discharge cells selected by the address discharge cause a sustain discharge that displays a gray scale so that a predetermined image is displayed on the plasma display panel. AC voltage is applied between the fields Y1, ..., Yn, and discharge is generated only with the help of the wall charge accumulated by the address discharge only in the discharge cells generated above address discharge. Meanwhile, in the present invention, the X electrode lines are electrically connected to each other, and all of the Y electrode lines are electrically connected to each other. However, such a connection is not necessarily required for the implementation of the present invention. Only some of them may be electrically connected to each other to be connected to a plurality of driver integrated circuit chips, and so is the Y electrode. In this case, the number of integrated circuit chips required to manufacture the plasma display panel may be increased, but may also contribute to the improvement of image quality through precise driving.

Referring to FIG. 3, driving of the plasma display panel of the present invention will be described with reference to an example of waveforms of signals applied to the X electrode, the Y electrode, and the intermediate electrode of the plasma display panel 100 of the present invention. . The waveform shown in FIG. 3 shows a signal applied to a sustain electrode pair, an intermediate electrode, and an address electrode across an arbitrary discharge cell of the plasma display panel, and more specifically, a waveform of potential. As described above, discharge occurs while the rising lamp is applied to the intermediate electrode at any time t1-t2, and then erase discharge occurs while the falling lamp is applied. Thus, reset discharge occurs in the entire plasma display panel, The state of wall charge is uniform. Subsequently, an address voltage Va, which is a predetermined data signal according to a control signal applied corresponding to an external video signal, is applied to the address electrode at times t2 to t3, and crosses the address electrode in the discharge cell to emit light. When the data signal is applied to the intermediate electrode, a negative scan voltage Vscan is applied, and the potential difference between the address electrode and the intermediate electrode reaches a discharge start voltage, thereby causing a discharge in the selected discharge cell. At this time, while such an address discharge occurs, predetermined wall charges are accumulated in the discharge cell. Subsequently, at a time t3-t4, a predetermined sustain discharge voltage Vs is alternately applied between the X electrode and the Y electrode to accelerate the wall charge accumulated in the discharge cell in the discharge cell to display a predetermined gray scale. This happens. At this time, a predetermined sustain discharge voltage Va is applied to the address electrode at the time t2-t3, and at the same time, a negative scan voltage Vscan is applied to the intermediate electrode to generate an address discharge for selecting a discharge cell. Therefore, when the address discharge is completed, negative wall charges are accumulated on the front surface of the phosphor layer 125 on which the address electrodes are disposed, and positive wall charges are accumulated on the rear surface of the passivation layer 116 on which the intermediate electrode is disposed. . At this time, if a predetermined sustain discharge voltage (Vs) having a potential higher than the scan voltage is applied to the intermediate electrode during the sustain period of t3-t4, the positive wall charge accumulated on the back surface of the protective film on which the intermediate electrode is disposed is X. As the electrode is accelerated and moved to the rear surface of the protective film on which the electrode is disposed, it is caused to collide with the discharge gas existing in the discharge cell to generate a discharge. Subsequently, while a predetermined sustain discharge voltage Vs is alternately applied to the Y electrode and the X electrode, a sustain discharge that displays a predetermined gray level during the sustain period is continuously generated to implement an image. At this time, when the intermediate electrode does not exist, wall charges are accumulated on the surface where the address electrode and the address electrode and the X electrode or the Y electrode which cause the address discharge are accumulated and are alternately moved between the sustain electrode pairs. Therefore, the driving voltage applied to the sustain electrode pair must be large in order for the wall charge having a kinetic energy such that the wall charge collides with the discharge gas in the discharge cell to cause the discharge. The spacing between the sustain electrode pairs cannot be widened. At this time, when the interval between the sustain electrode pairs is narrow, the number of wall charges participating in the discharge becomes small and discharge becomes weak. Consequently, the luminance of the plasma display panel is lowered. It should be increased. This is decisive for an increase in the manufacturing price of the plasma display panel with respect to the driver integrated circuit chip, thereby lowering the price competitiveness of the plasma display panel. However, as described above, when an intermediate electrode is disposed between the X electrode and the Y electrode, and a discharge occurs first between the intermediate electrode and the X electrode to trigger a sustain discharge between the sustain electrode pairs, a full sustain discharge Before this occurs, a sufficient number of wall charges are generated in the discharge cell with sufficient kinetic energy to cause sustain discharge, resulting in sustain discharge without increasing the driving voltage even if the gap between the pair of sustain electrodes is widened. This makes it possible to use a circuit driven at a low voltage, thereby lowering the manufacturing cost of the plasma display panel.

At this time, since the sustain discharge is triggered between the intermediate electrode and the X electrode as described above, to optimize the placement of the intermediate electrode so that the discharge triggering the sustain discharge between the intermediate electrode and the X electrode can occur more easily. This will be described with reference to FIG. 4. As described above, the sustain electrode pair 114 and the intermediate electrode 150 include a transparent electrode and a bus electrode. In this case, the bus electrode is formed of a high-conductivity material having a low resistance so that the electrode line can be uniformly applied to the electrode across the entire panel, and disposed on the rear surface of the transparent electrode with a width smaller than that of the transparent electrode. Therefore, when a voltage is applied to the sustain electrode pair and the intermediate electrode, an electric field is concentrated at a portion where the bus electrode is disposed. In this case, as described above, since the sustain discharge is triggered between the intermediate electrode 150 and the X electrode 113, the bus electrode 150a of the intermediate electrode provided in the intermediate electrode is biased in the direction in which the X electrode is disposed. When positioned, since the electric field is concentrated more strongly at the bus electrode of the intermediate electrode, the discharge generated between the X electrode and the intermediate electrode can be easily generated even at a lower voltage. As a result, the distance W1 between the bus electrode 150a of the intermediate electrode and the transparent electrode of the X electrode is greater than the distance W2 between the transparent electrode of the Y electrode and the bus electrode of the intermediate electrode. Preferably, the bus electrode of the intermediate electrode is arranged small. Meanwhile, the distance between the transparent electrode 150b of the intermediate electrode and the transparent electrode 113b of the X electrode and the distance from the transparent electrode 112b of the Y electrode of the intermediate electrode In the case where the intermediate electrodes are disposed identical to each other, the intermediate electrodes preferably serve as bridges of moving wall charges in the sustain discharge generated between the X electrode and the Y electrode. Thus, the transparent electrode 150b of the intermediate electrode is the X electrode. The distance between the transparent electrode 113b and the distance between the transparent electrode 150b of the intermediate electrode and the transparent electrode 112b of the Y electrode is preferably equal to each other, but the present invention is not limited thereto. The distance between the transparent electrode of the X electrode and the transparent electrode of the intermediate electrode is greater than that of the transparent electrode of the Y electrode and the It may be formed to be smaller than the spaced distance between the transparent electrode of the intermediate electrode.

As described above, any one of neon, helium, or argon (Ar) including xenon (Xe) gas, or a mixed gas of two or more thereof is present in the discharge cell. When the gas is discharged, it is excited to generate ultraviolet rays, and the ultraviolet rays excite the phosphor layer 125 to emit predetermined visible light. At this time, an ultraviolet ray having a wavelength of 147 nm or 173 nm generated by excitation of xenon gas due to the characteristics of the phosphor present in the phosphor layer is most effective for exciting the phosphor. Therefore, as the proportion of xenon gas in the discharge gas increases, the amount of ultraviolet rays of the above-described wavelength is increased to increase the luminance of the plasma display panel. However, when only xenon gas is used as the discharge gas, the average energy (average temperature of the electrons) of the charged particles in the discharge cell is so low that the number of electrons that can cause the discharge must be increased to a predetermined level or more when the driving voltage is increased to cause discharge. Therefore, in consideration of the problems of xenon gas, the above-described mixed gas such as helium or argon is added to induce a penning effect to lower the driving voltage. However, as described above, since the ultraviolet light generated by excitation of the xenon gas is efficient for emitting visible light, it is effective that the specific gravity of the xenon gas is higher than a predetermined level, so that the ratio of the desired xenon gas in the discharge gas is 10% to 20%. The relationship between the spaced distance between the bus electrode 150a of the intermediate electrode and the transparent electrode 150b of the X electrode and whether or not the discharge cells of nine discharge cells are discharged in Table 1 will be described.

division Distance (μm) between the transparent electrode of the X electrode and the bus electrode of the intermediate electrode Driving voltage Xenon Ratio 105 100 95 90 85 80 75 70   230 V 10% 2 9 9 9 9 9 9 9 13% One 2 9 9 9 9 9 9 15% 0 3 9 9 9 9 9 9 17% 0 4 9 9 9 9 9 9 20% 0 4 9 9 9 9 9 9

As can be seen in Table 1, the ratio of the xenon gas and the spaced distance between the transparent electrode of the X electrode and the bus electrode of the intermediate electrode were changed in nine discharge cells. When the distances between the electrodes were less than or equal to 95 µm and greater than or equal to 70 µm, it was confirmed that discharge occurred in all nine discharge cells even when the ratio of xenon gas was increased to 20%. On the other hand, when the distance is greater than 95㎛, that is, 100, or 105㎛, it was confirmed that the discharge occurs in some discharge cells as the xenon gas increases. On the other hand, when the distance was less than 70 μm, discharge stains caused by overdischarge occurred, which was confirmed to be undesirable. Based on the experimental results, when the distance between the transparent electrode of the X electrode and the bus electrode of the intermediate electrode is less than or equal to 95 µm and greater than or equal to 70 µm, the discharge characteristic is most stable and a high ratio of xenon gas is utilized. I found out.

In the present invention, the distance between the sustain electrode pairs is sufficiently widened to increase the ratio of the wall charges participating in the discharge, thereby increasing the discharge amount and optimizing the position of the intermediate electrode, thereby increasing the driving voltage, thereby increasing the plasma display panel. The fabrication of high quality, low cost plasma display panels has become possible.

In addition, while increasing the specific gravity of the xenon gas in the discharge gas, the driving voltage is not increased, and the position of the bus electrode of the intermediate electrode is prevented from increasing the driving voltage due to the increase of the ratio of xenon gas, thereby optimizing high quality, It allows the fabrication of low cost plasma display panels.

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 transparent front substrate and a rear substrate spaced apart from each other by a predetermined distance to face the front substrate; A partition wall disposed between the front substrate and the rear substrate and defining discharge cells which are spaces for generating a discharge together with the front substrate and the rear substrate; A sustain electrode pair disposed behind the front substrate, extending in one direction in which the discharge cells extend, traversing the discharge cells extending, and having an X electrode and a Y electrode having a transparent electrode and a bus electrode; field; Intermediate electrodes disposed between each of the sustain electrode pairs at the rear of the front substrate, extending in parallel to the direction in which the sustain electrode pairs extend, traversing the discharge cells, and having a transparent electrode and a bus electrode; A front dielectric layer disposed behind the front substrate to cover the sustain electrode pairs and the intermediate electrodes; Address electrodes disposed between the rear substrate and the front dielectric layer and extending across the discharge cells to intersect a direction in which the intermediate electrodes extend; A phosphor layer disposed in the discharge cell and covering the address electrode; And And a discharge gas in the discharge cell, wherein the bus electrode of the intermediate electrode is arranged in such a way that a sustain discharge displaying a predetermined gray scale in the discharge cell is triggered between the X electrode and the intermediate electrode. Plasma display panel, characterized in that the position off. The method of claim 1, And the spaced distance between the transparent electrode of the X electrode and the bus electrode of the intermediate electrode is smaller than the spaced distance between the transparent electrode of the Y electrode and the bus electrode of the intermediate electrode. The method of claim 2, The spaced distance between the transparent electrode and the intermediate electrode of the X electrode is less than or equal to 95㎛ and greater than or equal to 70㎛ plasma display panel. The method of claim 1, And the spaced distance between the transparent electrode of the X electrode and the transparent electrode of the intermediate electrode is smaller than the spaced distance between the transparent electrode of the Y electrode and the transparent electrode of the intermediate electrode. The method of claim 1, The X electrodes are electrically connected to each other such that the same control signal is applied between the X electrodes, and the Y electrodes are electrically connected to each other so that the same control signal is applied to the Y electrodes. Display panel. The method of claim 1, And a protective film disposed on the rear surface of the front dielectric layer, and further comprising a rear dielectric layer disposed to cover the address electrode between the phosphor layer and the address electrode.

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