KR100647617B1 - Plasma display panel - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a plasma display panel which stably generates an address discharge for selecting a discharge cell, increases an amount of generated wall charges due to an address discharge, and increases the luminance while causing an address discharge at a low potential. In order to achieve this object, the present invention provides a plurality of discharge cells which are disposed to face each other and whose edges are sealed to each other, and are disposed between the front substrate and the back substrate and are spaces for generating discharge. A plurality of discharge cells intersecting the discharge electrodes and the discharge cells, the plurality of discharge cells extending across the plurality of discharge cells extending adjacent to each other; A plurality of address electrodes extending transversely and in parallel with the address electrodes A plasma display panel including at least one floating electrode disposed and not electrically connected to the at least one floating electrode, a phosphor layer disposed in the discharge cell, and a discharge gas present in the discharge cell is provided.

Description

Plasma display panel {Plasma display panel}

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

2 is a cross sectional view taken along line II-II of the plasma display panel of the first embodiment of the present invention;

3 is an exploded perspective view showing the plasma display panel of the second embodiment of the present invention;

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

5 is an exploded perspective view showing a plasma display panel of a third embodiment of the present invention;

6 is a perspective view showing a front discharge electrode, a rear discharge electrode, an address electrode, a floating electrode, and a discharge cell of the plasma display panel according to the third embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100, 200, 300: plasma display panel

110, 210, 310: front panel

120, 220, 320: rear panel

140, 240, 340: discharge cells

112, 212 and 312: address electrodes

113, 213, and 313: floating electrodes

126, 226, 326: discharge electrode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to the provision of a plasma display panel which is stable and can be driven at low potential while increasing luminance.

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, AC type surface discharge plasma display panels have become popular.

In order to drive such a plasma display panel, an address discharge, which is a discharge that selects a discharge cell to be emitted and emits light, is required. The address discharge has an important effect on the driving of the plasma display panel. In particular, the implementation of a stable address discharge so that the address discharge occurs exactly as desired, and a large amount of charged particles are generated in the selected discharge cell through the address discharge to achieve the accumulation of a large amount of wall charge It is a design element that is considered very important in address discharge.

On the other hand, in order to satisfy the above-mentioned design elements of the address discharge, it is preferable to apply a high potential to the address electrode so that the address discharge can occur at a high voltage. In general, in order to cause the address discharge at a high voltage, a plasma display is required. A driving circuit for controlling the potential at which the panel is applied to the address electrode should be selected and provided as usable at high potential. In this case, since the price of the driving circuit increases as the driving voltage increases, the price of the plasma display panel driven at a high potential increases.

The present invention solves the above problems, the address discharge to select the discharge cell is generated stably in the discharge cell to be discharged, and the accumulation of the wall charge due to the address discharge increases the amount of wall charge It is an object of the present invention to provide a plasma display panel in which manufacturing cost is reduced by allowing address discharge to occur at a low potential while improving luminance by increasing sustain discharge due to accumulation.

In order to achieve the above object, the present invention provides a plurality of discharge cells that are disposed to face each other and the edge is sealed to each other, and the space between the front substrate and the rear substrate, the discharge substrate is a space for generating a discharge A barrier rib defining a barrier rib, a plurality of discharge electrodes extending across a plurality of discharge cells extending adjacent to each other, and a plurality of discharge cells crossing the discharge electrodes and the discharge cells and extending adjacent to each other. A plurality of address electrodes extending to extend, at least one floating electrode disposed in parallel with the address electrode and not electrically connected to the electrode; a phosphor layer disposed in the discharge cell; and a discharge gas present in the discharge cell. It provides a plasma display panel having a.

In this case, the floating electrode may be disposed on both sides of the address electrode in parallel with the address electrode, and the floating electrode may be disposed on the same plane as the address electrode.

The floating electrode may be disposed for each of the plurality of discharge cells, and the floating electrode may be disposed to extend in parallel along the discharge cells across the address electrode.

In the plasma display panel of the present invention, the discharge electrode may be disposed between the rear substrate and the address electrode, and the phosphor layer may be disposed in a space defined by the front substrate and the partition wall. It is preferable to further include a rear dielectric layer disposed to cover, and in addition, it is preferable to further include a protective film disposed to cover the rear dielectric layer. In the plasma display panel, the phosphor layer may be disposed to cover the address electrode and the floating electrode. When the phosphor layer is disposed, the phosphor layer is disposed between the phosphor layer and the address electrode. It is preferable to further include a front dielectric layer covering the electrode.

In the plasma display panel of the present invention, the address electrode may be disposed between the rear substrate and the discharge electrode, and the phosphor layer may be disposed in a space defined by the rear substrate and the partition wall. Preferably, the address electrode and the floating electrode are disposed to cover the address electrode and the floating electrode. In the case where the phosphor layer is disposed, it is preferable that a rear dielectric layer disposed between the phosphor layer and the address electrode and covering the address electrode and the floating electrode is further provided in the plasma display panel of the present invention. In this case, the plasma display panel of the present invention preferably further includes a front dielectric layer disposed to cover the discharge electrode. In addition, the plasma display panel may further include a protective film disposed to cover the front dielectric layer.

On the other hand, the plasma display panel of the present invention is the front discharge electrode and the rear partition wall is formed of a dielectric, the discharge electrodes are arranged so as to surround the discharge cells in the partition wall to be spaced apart from each other in parallel to cross the discharge cells and the rear A discharge electrode may be provided, and the phosphor layer may be disposed in a space defined by the rear substrate and the partition wall, and the address electrode and the floating electrode may be disposed between the phosphor layer and the rear substrate. In this case, the plasma display panel may further include a dielectric layer disposed between the phosphor layer and the address electrode and covering the address electrode and the floating electrode. In this case, the plasma display panel of the present invention preferably further includes a protective film covering at least a portion of the partition wall.

Hereinafter, a preferred embodiment of a plasma display panel according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 2.

The plasma display panel 100 includes a front panel 110 and a rear panel 120. In this case, the front panel 110 has a front substrate 111 having a thickness of approximately 2.8 mm made of soda glass and the like, and the rear panel 120 has a rear substrate 121. At this time, the front substrate is preferably formed of a material such as transparent soda glass so as to be excited by the ultraviolet light generated by the discharge to transmit visible light generated in the phosphor layer described later, but the back substrate is a visible light generated in the phosphor layer Since it is not located on the optical path (hereinafter, referred to as the optical path) as a path to proceed, it is not necessarily transparent and can be formed of glass or the like, but can also be formed of an opaque material such as metal or plastic. The plasma display panel includes a partition wall 130 disposed between the front substrate and the rear substrate and defining discharge cells 140, which are spaces for generating discharge.

The rear panel 120 includes a rear substrate 121 and a plurality of discharge electrodes 126 extending to cross the plurality of discharge cells 140 extending adjacent to each other. In this case, the discharge electrode is preferably disposed between the rear substrate 121 and the address electrode 112 to be described later. More specifically, the discharge electrode is disposed on the front surface 121a of the rear substrate, or when a layer that performs a separate function is disposed on the front surface of the rear substrate, such as a reflective layer that reflects visible light. The discharge electrodes may be disposed. On the other hand, the discharge electrodes may be composed of a pair of sustain electrodes including only the X electrode 125 and the Y electrode 124, an intermediate electrode (not shown) is applied to the potential applied between the X electrode and the Y electrode As a result, an increase in the distance between the X electrode and the Y electrode may allow sustain discharge to occur at a low potential. Therefore, as shown in FIG. 1, the discharge electrode 126 is not limited to having only the X electrode 125 and the Y electrode 124.

On the other hand, since the discharge electrode is disposed in front of the back substrate as described above, since the discharge electrode is not located on the optical path, the choice of the material is wide, thus the electrical conductivity is high and the price is relatively The discharge electrode may be formed of various materials such as inexpensive aluminum, copper, and chromium. In addition, since the discharge electrode is not only a material but also a selection of shapes, there is an advantage that can be freely modified in accordance with the characteristics of the discharge. On the other hand, the discharge electrode is formed by applying a discharge electrode paste containing the discharge electrode material to the entire surface of the rear substrate through a screen printing method, and then drying and baking, or by including a photosensitive photoresist in the discharge electrode paste Etching may be performed to form the discharge electrodes by a photolithography method for forming the discharge electrodes.

In addition, the rear panel may further include a rear dielectric layer 123 disposed to cover the discharge electrodes 126. At this time, looking at the arrangement position of the rear dielectric layer in more detail, it is preferable that the rear dielectric layer is disposed on the front surface (121a) of the rear substrate. At this time, the rear dielectric layer is disposed to cover the discharge electrode and induces charged particles to accumulate or accelerate wall charges and to prevent the accelerated charged particles from directly colliding with the electrodes, thereby increasing the lifespan of the discharge electrodes. Therefore, it is important that the rear dielectric layer covers the discharge electrode, and the position thereof is not limited to the front surface of the rear substrate. On the other hand, the rear dielectric layer may be disposed by applying a dielectric paste, which may be formed of PbO, SiO _2, etc., having a thickness of about 30 μm to the entire surface of the back substrate and then baking.

On the other hand, in the plasma display panel 100 of the present invention, even when the rear dielectric layer does not exist, there is no difficulty in inducing discharge by forming an electric field inside the discharge cell by applying a potential to the discharge electrode, When the charged particles are applied to accelerate the charged particles, the accelerated charged particles directly collide with the surface of the discharge electrode, which may shorten the life of the electrode. Therefore, it is preferable to arrange the rear dielectric layer to cover the discharge electrode. In addition, when the rear dielectric layer is disposed, wall charges are accumulated during address discharge and wall charges can be used in sustain discharge, thereby reducing the magnitude of the potential to be applied during sustain discharge.

On the other hand, the rear dielectric layer is not necessarily transparent because it is not located on the optical path of visible light. Rather, the rear dielectric layer is preferably disposed as a white dielectric in order to increase the reflectance of visible light and increase the ratio of visible light moving forward.

The rear panel may further include a passivation layer 127 disposed to cover the rear dielectric layer. At this time, the protective layer 127 serves to protect the discharge electrode covered by the rear dielectric layer and the rear dielectric layer, and at the same time, discharges secondary electrons when the charged particles collide due to the discharge, thereby promoting discharge. . In this case, MgO or the like is generally used as the material of the protective film, but since the protective film is coated on the rear surface of the rear dielectric layer, light transmittance does not matter, and thus, carbon nanotubes (CNT) having excellent electron emission characteristics may be used. MgO and the like may also be used.

Meanwhile, the front panel 110 intersects the front substrate 111, the discharge electrodes 126, and the discharge cell 140, and extends to cross a plurality of discharge cells extending adjacent to each other. Address electrodes 112 are provided. At this time, when the arrangement position of the address electrode in the first embodiment of the present invention in more detail, the address electrode 112 disposed on the rear surface of the front substrate, more specifically the rear surface 111a of the front substrate; Equipped with more. In this case, the address electrodes may be disposed on the rear surface of the front substrate by the screen printing method, the photolithography method, or the like used in the arrangement of the discharge electrodes. Meanwhile, the address electrodes 112 are not necessarily disposed on the rear surface of the front substrate, and a near infrared blocking film (not shown) is disposed on the rear surface of the front substrate to block near infrared rays generated during discharge, or an electromagnetic shielding filter layer. (Not shown), since the address electrodes may be disposed on the back surface of the near-infrared blocking film or the electromagnetic shielding filter layer, the address electrodes cross the discharge electrodes, and the address electrodes are adjacent to each other. It is sufficient to be arranged across the plurality of discharge cells.

On the other hand, since the address electrode is located on a light path in which the visible light generated by the discharge generated in the discharge cell 140 is directed toward the front, it is preferable that the address electrode is formed of a transparent electrode to increase the transmittance of the visible light. . In this case, in order to increase the visible light transmittance of the address electrode, in general, the address electrode is formed using indium tin oxide (ITO). Since the ITO has a high light transmittance but high resistance, a potential is applied to the address electrode formed of ITO. In this case, due to the voltage drop due to the high resistance of the ITO material, the size of the electric field formed inside the discharge cells traversing the address electrode may be different, so that address discharge may not be uniformly generated. The front panel may further include a bus electrode (not shown) formed of a metallic conductor material and having three layers of silver or chromium-copper-chromium electrically connected to the address electrode.

 The front panel 110 includes at least one floating electrode 113 disposed in parallel with the address electrode 112 and not electrically connected to the front panel 110. In this case, in more detail with respect to the arrangement of the floating electrode in the first embodiment of the present invention, the floating electrode 113 is disposed on the back surface 111a of the front substrate which is the same plane as the address electrode, the address The electrodes may be disposed to extend in parallel along the discharge cells that traverse the electrode. However, as shown in FIG. 1, the floating electrode does not necessarily extend in parallel along discharge cells intersecting the address electrode, and the floating electrode is not electrically connected. In consideration of a function or the like, each of the plurality of discharge cells may be disposed in parallel with the address electrode. The floating electrodes are preferably disposed at both sides of the address electrode, but two floating electrodes are not necessarily present in one discharge cell at both sides of the address electrode, but may be present at one side of the address electrode or both sides of the address electrode. Two or more floating electrodes may be arranged in one discharge cell on the side. Hereinafter, the function and the reason for the arrangement of the floating electrode will be described in detail later.

On the other hand, the front panel has a phosphor layer 116 is excited by the ultraviolet light generated by the discharge in the discharge cell 140 to generate visible light. In this case, the phosphor layer may be disposed to cover the address electrode 112 and the floating electrode 113. In this case, the phosphor layer 116 may include red, green, and blue light emitting phosphor layers in order to enable the plasma display panel to implement a color image, and the red, green, and blue light emitting phosphor layers may be provided. 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⁺ .

Meanwhile, the discharge cells in which the red, green, and blue light emitting phosphor layers are disposed may be adjacent to each other in one direction to form a unit pixel which is a basic unit for realizing an image. However, the arrangement of the discharge cells of the present invention is not limited as described above, and in some cases, the width or length of the discharge cells may be different depending on the efficiency of the phosphor, and the arrangement may be a lattice type, a delta type, or the like. It may vary.

Meanwhile, the front panel 120 further includes a front dielectric layer 115 disposed between the phosphor layer 116 and the address electrode 112 and covering the address electrode and the floating electrode 113. desirable. Of course, even if the front dielectric layer is not disposed, there is no problem in driving the plasma display panel of the present invention. However, when the address discharge occurs as described above, the charged particles may directly collide with the address electrode to damage the address electrode. In order to increase the lifetime of the plasma display panel, the front dielectric layer is preferably disposed to cover the address electrode.

On the other hand, if the plasma display panel is used in a place where there is no visible light incident from the outside, such as a dark room, only visible light generated inside the discharge cell of the plasma display panel will proceed to the front of the plasma display panel and be recognized by the user's vision. In a general environment, visible light incident from the outside toward the front of the plasma display panel is reflected and perceived by the user's vision together with the visible light generated inside the discharge cell of the plasma display panel. At this time, the visible light incident to and reflected from the front of the plasma display panel lowers the clearness ratio of the plasma display panel, making it difficult to distinguish colors, thereby degrading the color and degrading the image quality. Therefore, it is necessary to devise means for preventing the reflection of external visible light that degrades the image quality as described above. For this purpose, the front panel may be provided with a black stripe (not shown) capable of absorbing external visible light. have.

On the other hand, the partition wall 130 is disposed between the front substrate and the rear substrate as described above, the discharge cell, the discharge cell that functions as a minimum component of the pixel that is the basic unit for implementing the image of the plasma display panel Define 140. In this case, when the front dielectric layer 115 is disposed, the partition wall includes a glass component including elements such as Pb, B, Si, Al, and O on the rear surface of the front dielectric layer and, if necessary, ZrO ₂ and TiO _2. , And a barrier material paste composed of a filler such as Al ₂ O ₃ and a partition material including pigments such as Cr, Cu, Co, Fe, and TiO ₂ may be coated and fired.

On the other hand, the discharge cell is filled with a discharge gas consisting of any one of neon (Ne), helium (He), or argon (Ar) including xenon (Xe) gas, or a mixed gas of two or more thereof. At this time, since the pressure of the discharge gas is in a vacuum state (0.5 atm), the pressure according to the vacuum of the discharge gas acts as a force for pressing the front substrate and the back substrate, which is supported by the partition wall. On the other hand, the front panel and the rear panel is coupled to the edge is sealed by a coupling member such as a frit (flit).

Hereinafter, the driving of the plasma display panel 100 according to the first embodiment of the present invention will be briefly described, and the functions of the above-described floating electrode 113 and the reason for the arrangement thereof will be 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 image quality and response speed of the plasma display panel may vary depending on the driving method. Since the features of the present invention are not changed, an example of driving the plasma display panel of the present invention will be described below with reference to ADS driving.

In general, a discharge occurs for an image display lamp before a reset discharge occurs to implement an image. Therefore, when the state of the wall charges or the amount of charged particles are different between the discharge cells, it is difficult to achieve the desired control between the discharge cells when the discharge is to be controlled in a uniform manner. 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 cause the discharge as a whole, the wall charges existing in the discharge cell is removed and uniformized, the state of the charged particles in the discharge cell The discharge that induces equal to is called a reset discharge. This reset discharge is generally performed by applying a high potential lamp potential to all the Y electrodes 124 and applying a ground potential to all the address electrodes 112 to discharge the entire discharge cells.

Then, after the above-described reset discharge occurs, an address discharge occurs. In this case, the address discharge is generally applied by applying a pulse voltage to the crossing electrode pairs to emit the discharge cells specified by the electrode pairs that cross each other in an arbitrary discharge cell in order to select the discharge cells to be implemented. It refers to the discharge which generate | occur | produces a discharge, and selects the discharge cell which a discharge should generate | occur | produce by accumulating wall charge on the inner surface of a discharge cell by this discharge. This address discharge selects the discharge cell by accumulating wall charges on the inner surface of the discharge cell as described above, and enables the sustain discharge described later with the aid of the accumulated wall charges. Therefore, only when the address discharge is appropriately generated in the desired discharge cell, the sustain discharge occurs in the desired discharge cell during the sustain discharge, the gray scale is displayed, and the predetermined image is implemented accordingly, so that the address discharge is stably generated. It is a very important part to improve the quality of the panel.

In this case, since the Y electrode 124 and the X electrode 125 are disposed to intersect the address electrode 112, such an address discharge is performed by the Y electrode 124 and the address electrode 112 or the X electrode 125 and Although it may be caused by the address electrode 112, it is assumed here that an address discharge occurs between the Y electrode and the address electrode. When a predetermined pulse voltage is applied between the address electrode 112 and the Y electrode 124 from an external power source, the discharge cell 140 to emit light is selected by crossing the Y electrode and the address electrode, and the selected discharge cell is selected. Is discharged while the potential difference applied to the Y electrode and the address electrode reaches the firing voltage, thereby accumulating wall charges on the front, rear, or side surfaces of the discharge cell.

On the other hand, a sustain discharge occurs after the above-described address discharge occurs to implement an image. At this time, in the discharge cell selected by the address discharge, an electric potential is alternately applied to the discharge electrodes a certain number of times in order to display a specific gray level so that a predetermined visible light is emitted from the discharge cell, thereby substantially giving an image to the panel. The discharge at the stage of implementation is called sustain discharge. At this time, when a potential is applied to a plurality of discharge electrodes arranged in all the discharge cells alternately to form a voltage lower than the discharge start voltage, wall charges are accumulated only in the discharge cells in which the address discharge has occurred. As the potential difference formed by the electrodes is added to exceed the discharge start voltage, sustain discharge occurs only in the discharge cell in which the address discharge has occurred, thereby generating visible light. At this time, assume that positive wall charges are accumulated on the Y electrode 124 and negative wall charges are accumulated on the X electrode 125 by the address discharge. At this time, when a predetermined amount of pulse potential is applied to the Y electrode and a ground potential is applied to the X electrode, the positive wall charges accumulated on the Y electrode are accelerated by the electric field formed by the voltage between the Y electrode and the X electrode. It will move toward the X electrode. On the other hand, the negative wall charges accumulated in the X electrode are accelerated toward the Y electrode by the electric field and move. At this time, when the accelerated positive wall charge and the negative wall charge have kinetic energy of sufficient magnitude, the discharge gas atoms are excited while colliding with the discharge gas in the discharge cell 140. Thus, the excited gas discharges its energy level to a high energy level, and again generates an ultraviolet ray having a predetermined wavelength as the energy level falls to a low energy level. At this time, the discharge gas containing Xe generates ultraviolet rays having a relatively short wavelength in the vicinity of 146 nm and 173 nm, and these ultraviolet rays excite the phosphor to generate visible light having a predetermined wavelength. Subsequently, when the ground potential is applied to the Y electrode again and the positive potential is applied to the X electrode, the wall charge is accelerated and moved again, and the wall charge repeats the collision with the discharge gas to generate predetermined visible light. . Then, if the process is repeated repeatedly, visible light generated in the discharge cells in which the sustain discharge is generated displays a predetermined gray scale to implement an image.

At this time, as described above, the sustain discharge depends on the wall charge accumulated in the discharge cell, and the discharge start voltage of the sustain discharge can be lowered with the help of the wall charge, so that the wall must be discharged in the discharge cell where the sustain discharge should occur. Address discharge must be properly generated so that charge can accumulate. However, since the address discharge is generated in the discharge cell in which most of the wall charges are erased in the discharge cell due to the reset discharge, a high voltage must be applied between the address electrode and the Y electrode to generate the discharge, and the electric field in the discharge cell It is preferable that the width of the address electrode is increased so that the surface area of the address electrode is large so that it can be formed sufficiently uniformly. That is, when the surface area of the address electrode is increased, the electric field formed in the discharge cell is more uniformly formed, and thus, the charged particles present in the discharge cell can be easily accelerated to have a kinetic energy at a level capable of causing a discharge. As a result, address discharge can occur well. In addition, when the surface area of the address electrode is large, the amount of wall charges accumulated in the discharge cells can be increased, thereby lowering the sustain discharge voltage or increasing the amount of discharge during sustain discharge, thereby increasing the brightness of the plasma display panel.

However, as can be seen from Gaussian theory of the electric field, when the surface area of a conductor having the same electric potential increases, the electric field flux of the electric field per unit area of the surface becomes small, so as to secure the size of the electric field above a predetermined level. A larger potential must be applied. Therefore, when the width is increased to increase the surface area of the address electrode, the magnitude of the potential applied to the address electrode must be increased in order to maintain the same line flux of the electric field per unit area formed on the surface of the address electrode.

In this case, in order to select a discharge cell by generating an address discharge, a plurality of Y electrodes and a plurality of address electrodes are controlled separately, and a discharge cell is generally selected. Therefore, an integrated circuit chip in which address electrodes and Y electrodes are to be controlled separately must be provided in the plasma display panel. Therefore, a large burden is placed on driving the integrated circuit chip, so that the price of the integrated circuit chip is considerably high. In particular, in the case where the integrated circuit chip needs to be driven at a high potential, the cost of the integrated circuit chip increases significantly and the manufacturing cost of the plasma display panel increases, so that the integrated circuit chip is applied to the Y electrode and the address electrode for address discharge. It is not desirable that the dislocations be formed too high. Therefore, while reducing the size of the potential applied to the address electrode while increasing the surface area of the address electrode is a very important problem to increase the competitiveness of the plasma display panel, but also a very difficult problem due to the conflict of the above-described conditions.

The solution of the present invention for the above-mentioned problem will be described with reference to FIG. In the plasma display panel 100 of the first embodiment of the present invention, as described above, the address electrode 112 is disposed on the rear surface 111a of the front substrate, and the floating electrode 113 is disposed on both sides of the address electrode. The address electrode is disposed on the rear surface 111a of the front substrate on the same plane as the plane on which the address electrodes are disposed. In this case, the floating electrode is not electrically connected and is formed of a conductive material. Therefore, when a predetermined potential is applied to the address electrode, charge is induced to the floating electrode and free electrons move, whereby a potential close to the potential applied to the address electrode is the same as that applied to the floating electrode. Effect occurs. When a predetermined potential is applied to the address electrode, an electric field is formed in the discharge cell as if the potential is applied to both the address electrode and the floating electrode. As a result, the width W1 of the address electrode is equal to the width of the floating electrode 113 plus the width of the floating electrode 113 during discharge due to the presence of the floating electrode 113 without increasing the width W1 of the address electrode. The same effect as that of W2) is generated, which not only forms the state of the electric field in the discharge cell more uniformly, but also increases the amount of wall charge accumulation.

On the other hand, since the width W1 of the actual address electrode has not increased, it is not necessary to increase the magnitude of the potential applied to the address electrode in order to form an electric field of the same size, so that the integrated electrode controlling the address electrode 112 is controlled. There is no need to limit the circuit chip to operating at high potential. Therefore, the manufacturing cost is not increased while improving the quality of the plasma display panel.

Meanwhile, in the above description, the floating electrode 113 is disposed on the rear surface of the front substrate which is on the same plane as the address electrode, but this is due to the convenience of the process of simultaneously placing the floating electrode 113 in the step of arranging the address electrode. It is not intended to increase the effect of the present invention. Therefore, even if the floating electrode is not on the same plane as the address electrode, the width can be increased without increasing the magnitude of the potential applied to the address electrode.

In addition, although the floating electrodes 113 are disposed on both sides of the address electrode in FIG. 1 and FIG. 2, two are provided in one discharge cell. However, in order to achieve the effect of the present invention, the number of floating electrodes is two. It is not necessary to be limited or to be necessarily present on both sides of the address electrode. Accordingly, the floating electrode may be disposed only on one side of the address electrode, and two or more floating electrodes may be disposed in one discharge cell.

Hereinafter, the plasma display panel 200 according to the second embodiment of the present invention will be described with reference to FIGS. 3 to 4 based on different points from the first embodiment of the present invention. At this time, the component having the same name as the first embodiment of the present invention performs the same function as in the first embodiment of the present invention, and may be formed of the same material. The plasma display panel 200 according to the second embodiment of the present invention includes a front panel 210 and a rear panel 220. In this case, the front panel 210 may include a front substrate 211, discharge electrodes 226 having a Y electrode 224 and an X electrode 225 formed on the rear surface 211a of the front substrate, and the discharge electrodes. A front dielectric layer 215 is provided. Each of the Y electrode 224 and the X electrode 225 has transparent electrodes 224b and 225b formed of ITO and the like and bus electrodes 224a and 225a made of a metal having high conductivity. On the other hand, the rear surface of the front dielectric layer 215 is preferably provided with a protective film 227 disposed to cover the front dielectric layer.

The rear panel 220 is disposed on both sides of the rear substrate 221, the address electrodes 212 formed on the front surface 221 a of the rear substrate 221 so as to intersect the discharge electrodes, and are electrically disposed on both sides of the address electrodes. A floating electrode 213 that is not connected to the back electrode, a rear dielectric layer 223 covering the address electrodes, a partition wall 230 formed on the rear dielectric layer 223 and partitioning the discharge cell 240, and disposed in the discharge cell. The phosphor layer 216 is provided.

As described above, the plasma display panel 200 of the second embodiment of the present invention differs from the first embodiment of the present invention in that the address electrode 212 has the rear surface different from that of the first embodiment of the present invention. The phosphor layer is disposed between the substrate 221 and the discharge electrode 226, and the phosphor layer is disposed in a space defined by the back substrate 221 and the partition wall 230. Also in the plasma display panel, as described above, the address discharge must be stably generated at a low potential, and for this purpose, the floating electrodes 213 are preferably disposed on both sides of the address electrode in parallel with the address electrode.

The plasma display panel 300 of the third embodiment of the present invention will be described with reference to FIGS. 5 to 6 based on the differences from the first embodiment of the present invention. The plasma display panel 300 illustrated in FIG. 5 includes a front panel 310 and a rear panel 320, the front panel having a transparent front substrate 311, and the rear panel 320 having the front surface. A rear substrate 321 is disposed to be parallel to the substrate. In addition, a barrier rib 330 is defined between the front substrate and the rear substrate to define a plurality of discharge cells 340, which are spaces for generating a discharge.

The front panel 310 is formed at the rear of the front substrate, more specifically, the rear surface 311b of the front substrate to define the discharge cells 340 together with the front substrate 311 and the back substrate 321 and to have a dielectric. And a front partition 315 which is a part of the partition 330. In addition, the front panel 310 is disposed to surround the discharge cells 340 in the front partition 315 and spaced apart from each other so as to cross the discharge cells and extend in parallel to the front discharge electrode 324 and the rear discharge. A discharge electrode 326 having an electrode 325 is provided. In addition, it is preferable to include a protective film 327 covering at least a portion of the side surface of the front partition wall.

The rear panel 320 is disposed on the rear substrate 321 and the front surface 321 a of the rear substrate, and includes a discharge electrode 326 having the front discharge electrode 324 and the rear discharge electrode 325. The address electrodes 312 extending to intersect in the discharge cell 340, the floating electrodes 313 arranged in parallel with the address electrodes and not electrically connected to each other, and the dielectric layer 323 covering the address electrodes and the floating electrodes. ), A rear partition 329 formed on the dielectric layer 323 and a part of the partition 330, and a phosphor layer 316 disposed in a space defined by the rear partition and the back substrate.

The front panel 310 and the rear panel 320 are joined and sealed by a coupling member such as a frit (not shown), and neon containing 10% of xenon (Xe) gas inside and after the discharge cell. Discharge gas consisting of any one of (Ne), helium (He), or argon (Ar) or a mixed gas of two or more thereof is filled.

Meanwhile, the arrangement of the discharge electrode 326, the address electrode, the floating electrode, and the discharge cells will be described in more detail with reference to FIG. 6. As shown in FIG. 6, the discharge electrode 324 and the discharge electrode 325 are spaced apart from each other and extend in parallel to each other in a ladder shape. The discharge electrode and the discharge electrode are respectively discharge cells. It is arranged to surround. Meanwhile, the address electrode 312 crosses the front discharge electrode and the rear discharge electrode and the discharge cell 340 and extends to cross the discharge cells, and the floating electrode 313 is parallel to the address electrode. Is placed. In FIG. 6, the floating electrode is disposed in parallel with the address electrode to extend across the discharge cells. However, as described above in the plasma display panel of the first embodiment of the present invention, the floating electrode is electrically Since it is not connected, it does not necessarily need to be disposed to cross the discharge cells, and may be disposed separately for each of the discharge cells.

In the plasma display panel 300 of the third embodiment of the present invention, it is preferable that an address discharge occurs between the address electrode 312 and the rear discharge electrode 325, as in the first embodiment of the present invention. As described above, a predetermined potential difference is applied to the address electrode and the rear discharge electrode, and an electric field is formed in a discharge cell where the address electrode and the rear discharge electrode intersect with each other, thereby causing an address discharge. The sustain discharge is generated by the pulse voltage accumulated on the inner surface of the discharge cell and alternately applied between the front discharge electrode and the rear discharge electrode. At this time, it is still valid in the third embodiment of the present invention that the address discharge should be stable and occur at a low potential, and therefore, the floating electrode 313 is disposed in parallel with the address electrode 312 so that Also in the plasma display panel 300 of the third embodiment, the potential applied to the address electrode is not increased while achieving the effect of increasing the width of the address electrode.

On the other hand, in the present invention, the floating electrode disposed in parallel with the address electrode is disposed, thereby increasing the width of the address electrode without increasing the potential applied to the address electrode, thereby causing stable address discharge and discharging amount during sustain discharge. Since the brightness of the plasma display panel is increased by increasing the amount of wall charges accumulated in the discharge cells so as to be increased, the above-described electrodes of the plasma display panels can be applied to various types of plasma display panels. The scope of the present invention is not limited to the arrangement position and the like, and the scope of the present invention should be determined by the claims.

The present invention achieves the effect of increasing the surface area by increasing the width of the address electrode by arranging the floating electrode to stably generate an address discharge to select a discharge cell for sustain discharge, so that the plasma display panel can realize high image quality. It was.

In addition, since the width of the address electrode is substantially increased to increase its surface area, the amount of wall charges accumulated during address discharge is increased to increase the brightness of the plasma display panel, thereby increasing the product competitiveness of the plasma display panel. I was.

In addition, despite the stable address discharge and the increase in the brightness of the plasma display panel, the price of the integrated circuit chip controlling the potential applied to the address electrode by preventing the increase in the magnitude of the potential applied to the address electrode. By reducing the cost, a means for producing a high quality plasma display panel at a low cost is secured.

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 (18)

A front substrate and a rear substrate which are disposed to face each other and whose edges are sealed to each other; A partition wall disposed between the front substrate and the rear substrate and defining a plurality of discharge cells, which are spaces for generating a discharge, and including a dielectric; A plurality of discharge electrodes disposed in the partition wall to surround the discharge cells and spaced apart from each other so as to cross the discharge cells; A plurality of address electrodes intersecting the discharge electrodes and the discharge cells and extending to cross a plurality of discharge cells extending adjacent to each other; At least one floating electrode disposed in parallel with the address electrode and not electrically connected to the address electrode; A phosphor layer disposed in the discharge cell; And a discharge gas existing in the discharge cell. The method of claim 1, And the floating electrode is disposed on both sides of the address electrode in parallel with the address electrode. The method of claim 1, And the floating electrode is disposed on the same plane as the address electrode. The method of claim 1, And the floating electrode is disposed for each of the plurality of discharge cells. The method of claim 1, And the floating electrode extends in parallel along discharge cells crossing the address electrode. The method of claim 1, And the discharge electrode is disposed between the rear substrate and the address electrode, and the phosphor layer is disposed in a space defined by the front substrate and the partition wall. The method of claim 6, And a rear dielectric layer disposed to cover the discharge electrode. The method of claim 6, And a passivation layer disposed to cover the rear dielectric layer. The method of claim 6, And the phosphor layer is disposed to cover the address electrode and the floating electrode. The method of claim 9, And a front dielectric layer disposed between the phosphor layer and the address electrode and covering the address electrode and the floating electrode. The method of claim 1, And the address electrode is disposed between the rear substrate and the discharge electrode, and the phosphor layer is disposed in a space defined by the rear substrate and the partition wall. The method of claim 11, And the phosphor layer is disposed to cover the address electrode and the floating electrode. The method of claim 12, And a rear dielectric layer disposed between the phosphor layer and the address electrode and covering the address electrode and the floating electrode. The method of claim 11, And a front dielectric layer disposed to cover the discharge electrode. The method of claim 14, And a passivation layer disposed to cover the front dielectric layer. The method of claim 1, And the phosphor layer is disposed in a space defined by the back substrate and the partition wall, and the address electrode and the floating electrode are disposed between the phosphor layer and the back substrate. The method of claim 16, And a dielectric layer disposed between the phosphor layer and the address electrode and covering the address electrode and the floating electrode. The method of claim 16, And a protective film covering at least a portion of the partition wall.

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