KR100649208B1 - Plasma display panel - Google Patents

Abstract

The plasma display panel of the present invention adopts a new discharge cell structure to increase the light transmittance, to prevent ion sputtering of the phosphor layer, to improve the lifetime, and to reduce the reactive power consumption by separating the distance between neighboring electrodes, A first electrode and a second substrate disposed to face each other, a partition wall disposed between the first substrate and the second substrate to form a discharge cell, and a first electrode formed in the partition wall to surround a first corner of the discharge cell. A second electrode formed in the partition wall to face the first corner of the discharge cell wrapped in the first electrode in a diagonal direction, the second electrode facing the first electrode, and one direction in the second substrate; And an address electrode formed to extend and cross the first electrode and the second electrode corresponding to the discharge cell, and a phosphor layer formed in the discharge cells. The first and second electrodes each include an extension part extending in one direction and protrusions protruding from the extension parts to surround the first corner and the second corner, respectively, and the length of the protrusion is the first electrode. It is formed shorter than half of the distance between the extension of the extension and the extension of the second electrode.

Plasma Display, Discharge Cell, Capacitance, Extension, Projection, Distance

Description

Plasma Display Panel {PLASMA DISPLAY PANEL}

1 is a partially exploded perspective view of a plasma display panel according to an embodiment of the present invention.

FIG. 2 is a plan sectional view taken along the line A-A of FIG. 1 to illustrate the arrangement of the first electrode, the second electrode, the address electrode, and the discharge cells of the present invention.

3 is a perspective view illustrating a first electrode, a second electrode, and an address electrode of the present invention.

4 is a cross-sectional view taken along line B-B of FIG. 1 to describe an address discharge of the present invention.

5 to 7 are plan views illustrating sustain discharges according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to adopt a new discharge cell structure to increase light transmittance, to prevent ion sputtering of a phosphor layer, to improve lifespan, and to invalidate a distance from a neighboring electrode. The present invention relates to a plasma display panel for reducing power consumption.

In general, a plasma display panel (hereinafter referred to as a 'PDP') is formed in a sealed structure between a front panel and a rear panel by embedding a discharge gas, and the front panel is a front substrate and a display formed on the rear surface of the front substrate. An electrode, a dielectric layer covering the display electrode and a protective film, and the rear panel includes a back substrate, an address electrode formed on the front surface of the back substrate to intersect with the display electrode, a dielectric layer covering the address electrodes, and formed on the dielectric layer to discharge The partition wall which partitions a cell, and the phosphor layer formed in this discharge cell are provided.

Since the PDP includes a display electrode, a dielectric layer, and a protective film on the back surface of the front substrate through which visible light passes, the transmittance of the visible light generated in the phosphor layer in the discharge cell is reduced to reduce the luminance. Although the PDP is formed on the rear surface of the front substrate, most of the display electrodes are formed of indium tin oxide (ITO) having high electrical resistance in order to increase the transmittance of the front substrate of visible light, thereby increasing the driving voltage. In case of the large screen, the image is uneven due to the voltage drop occurring at the transparent electrode.

As described above, since the PDP has a display electrode on the rear surface of the front substrate, the discharge is concentrated only in a part of the discharge cell, which makes it impossible to effectively use the space of the discharge cell. When the driving voltage for the discharge is increased, and for a long time, the discharge diffuses toward the phosphor layer from the rear of the dielectric layer, so that charged particles of the discharge gas cause ion sputtering on the phosphor by an electric field, causing permanent afterimages.

The present invention has been made to solve the above problems, the object of which is to adopt a new discharge cell structure to increase the light transmittance, to prevent the ion sputtering of the phosphor layer to improve the life, and with the neighboring electrode It is to provide a plasma display panel that is spaced apart from each other to reduce the reactive power consumption.

In order to achieve the above object, a plasma display panel according to the present invention includes a first substrate and a second substrate disposed to face each other, a partition wall disposed between the first substrate and the second substrate to form a discharge cell, and the discharge. A first electrode formed in the partition wall with a structure surrounding the first corner of the cell, and formed in the partition wall with the structure surrounding the first corner of the discharge cell facing in a diagonal direction with the first corner of the discharge cell surrounded by the first electrode A second electrode facing the first electrode, an address electrode extending in one direction on the second substrate to cross the first electrode and the second electrode in correspondence with the discharge cell, and a phosphor layer formed in the discharge cells; The first electrode and the second electrode may each include an extension part extending in one direction and protrusions protruding from the extension part to surround the first corner and the second corner, respectively. , The length of the projecting portion is formed to be shorter than 1/2 of the distance between the first electrode extension and the second electrode extending portion of the.

That is, the distance between the tip of the first electrode protrusion of the one side discharge cell and the tip of the protrusion of the second electrode of the neighboring discharge cell is the protrusion of the first electrode of the one side discharge cell and the protrusion of the second electrode of the neighboring discharge cell. It is preferable to form longer than the distance of the extension part direction between them.

The partition wall may be formed of a first partition wall group provided on the first substrate side and a second partition wall group provided on the second substrate side corresponding to the first partition wall group. The first partition group and the second partition group each include a first partition member extending in one direction and a second partition member formed to intersect the first partition member. An extension of the first electrode and an extension of the second electrode are disposed in the first partition member, and a protrusion of the first electrode and a protrusion of the second electrode are disposed in the second partition member.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a partially exploded perspective view of a plasma display panel according to an embodiment of the present invention, Figure 2 is a AA of Figure 1 to show the arrangement of the first electrode, the second electrode, the address electrode, and the discharge cells of the present invention 3 is a cross-sectional plan view along a line, and FIG. 3 is a perspective view showing a first electrode, a second electrode, and an address electrode of the present invention.

Referring to the drawings, the PDP of the present embodiment will be described. As shown in FIG. 1, the PDP includes a front panel 210 and a rear panel 220, and the front panel 210 includes a first substrate ( 211, hereinafter referred to as a “front substrate”, and the rear panel 220 includes a second substrate 221 (hereinafter referred to as a “back substrate”). The PDP includes a partition wall 230 between the front substrate 211 and the rear substrate 221.

As shown in FIG. 2, the partition wall 230 includes a discharge cell 240 that includes a discharge gas and implements an image by using gas discharge of the discharge gas, and the discharge cell 240 is disposed at one side. The first corner 241 to be formed, the second corner 242 facing the first corner 241 in the diagonal direction, and the first and second corners 241 and 242 are adjacent to each other in the diagonal direction. It is made of a closed type having a third, fourth corner (243, 244). The discharge gas is composed of any one of neon, helium (He), argon (Ar) or two or more of these mixed gases including xenon (Xe) gas of about 10% and is charged in the discharge cell 240. .

The partition wall 230 may be formed separately from the front substrate 211 and the rear substrate 221 in the manufacturing process, or may be integrally formed on the rear substrate 221. When the partition wall 230 is formed separately, the first partition wall group 212 provided on the front substrate 211 and the rear partition board 221 side corresponding to the first partition wall group 212 are provided. The second partition wall 222 may be formed. The second partition wall group 222 includes a first partition wall member 222a extending in one direction (x-axis direction) and a second partition wall member 222b formed to intersect with the first partition wall member 222a. Include. As shown in FIG. 2, the first partition wall group 212 is formed of first and second partition wall members 212a and 212b that cross each other to correspond to the second partition wall group 222.

The partition wall 230 partitions the discharge cells 240 in a matrix form, but is not limited thereto and may be partitioned in various forms. In addition, although the cross section of the discharge cell 240 is illustrated in FIG. 2 as being rectangular, the present invention is not limited thereto, and may be a polygon such as a triangle or a pentagon, or a circle or an ellipse.

On the front panel 210 side, a display electrode, that is, a first electrode 213 (hereinafter referred to as a 'holding electrode') and a second electrode 214 (hereinafter referred to as a 'scan electrode'), corresponds to the discharge cell 240. The barrier rib 230 is provided. More specifically, the sustain electrode 213 is formed on the first and second partition members 212a and 212b of the first partition group 212 in a structure surrounding the first corner 241 and the scan electrode 214. ) Is formed in the first and second partition members 212a and 212b of the first partition group 212 in a structure surrounding the second corner 242. The second corner 242 faces the first corner 241 in a diagonal direction, whereby the scan electrode 214 formed at the second corner 242 is disposed to face the sustain electrode 213.

As shown in FIG. 3, the sustain electrode 213 surrounds the first corner 241 and the extension part 213a extending in one direction (x-axis direction) on one side of the discharge cell 240. And a protrusion 213b protruding from the extension portion 213a. The scan electrode 214 facing the sustain electrode 213 wraps the extension portion 214a and the second corner 242 extending in one direction (x-axis direction) on the other side of the discharge cell 240. And a protrusion 214b protruding from the extension portion 214a. Therefore, the extension part 213a of the sustain electrode 213 and the extension part 214a of the scan electrode 214 face each other with the discharge cell 240 interposed therebetween, and the extension part 213a of the sustain electrode 213 The protrusion 213b surrounds the first corner 241, and the extension 214a and the protrusion 214b of the scan electrode 214 surround the second corner 242. The extension portion 213a of the sustain electrode 213 and the extension portion 214a of the scan electrode 214 are disposed on the first partition member 212a of the first partition group 212, and the sustain electrode 213 The protrusion 213b and the protrusion 214b of the scan electrode 214 are disposed on the second barrier member 212b of the first barrier group 212. Accordingly, the tip of the protrusion 213b of the sustain electrode 213 faces the extension 214a of the scan electrode 214 at the third corner 243, and the tip of the protrusion 214b of the scan electrode 214 has a fourth corner ( Since 244 faces the extension portion 213a of the sustain electrode 213, the interval between the sustain electrode 213 and the scan electrode 214 is shortened. As a result, the sustain electrode 213 and the scan electrode 214 start sustain discharge at a low voltage at the third corner 243 and the fourth corner 244 to spread to the center of the discharge cell 240.

As such, the lengths La and Lb of the protrusions 213b and 214b for inducing the initial discharge are determined by the distance L between the extension 213a of the sustain electrode 213 and the extension 214a of the scan electrode 214. It is preferable to form shorter than 1/2. That is, the distance d between the tip of the protruding portion 213b of the sustain electrode 213 of the one discharge cell 240 and the tip of the protruding portion 214b of the scan electrode 214 of the neighboring discharge cell 240 is the one side of the discharge cell ( The distance in the direction (x-axis direction) of the extension portions 213a and 214a between the protrusion 213b of the sustain electrode 213 of the 240 and the protrusion 214b of the scan electrode 214 of the neighboring discharge cell 240. It is formed longer than (d '). According to the length relationship, the sustain electrode 213 and the scan electrode 214 surround the first corner 241 and the second corner 242 of the discharge cell 240, respectively, to form the third corner 213 and the fourth corner. At the corner 214, the drive can be driven at a low voltage during sustain discharge, while effectively increasing the distance d between the protrusion 213b and the protrusion 214b.

As such, by increasing the distance d between the one side protrusion 213b and the other side protrusion 214b, unnecessary discharge is prevented between the sustain electrode 213 and the scan electrode 214 between the adjacent discharge cells 240. As a result, ineffective power consumption is minimized in driving the PDP. That is, when the area of the protrusion 213b of the sustain electrode 213 and the protrusion 214b of the scan electrode 214 and the dielectric constant of the first partition group 212 provided therebetween are constant, the distance d is As it increases, the capacitance formed between the sustain electrode 213 and the scan electrode 214 is reduced, and consequently the power consumption is reduced.

 In addition, since the sustain electrode 213 and the scan electrode 214 are provided on the side of the discharge cell 240, it is not necessary to consider the light transmittance, so it is preferable that the sustain electrode 213 and the scan electrode 214 are formed of a material such as Ag, Cu, Cr, etc. having high electrical conductivity. .

As shown in FIG. 4, the first partition wall group 212 including the sustain electrode 213 and the scan electrode 214 is formed by a potential difference applied to the sustain electrode 213 and the scan electrode 214. The electric field may be formed of a dielectric so that the electric field may be transferred into the discharge cell 240 by the molecular arrangement of the material of the first partition wall group 212. The first partition wall group 212 may be formed of a glass component including an element such as Pb, B, Si, Al, and O, and the like, and ZrO ₂ , TiO ₂ , and Al ₂ O as necessary. It may be formed of a dielectric including a filler such as ₃ and pigments such as Cr, Cu, Co, Fe, TiO _2, and the like. Moreover, it is preferable to provide the protective film 215 by the method of vapor deposition etc. in the inner surface of this 1st partition group 212. As shown in FIG. The protective layer 215 protects the sustain electrode 213 and the scan electrode 214 and the dielectric covering the electrodes 213 and 214 during discharge, and facilitates the emission of secondary electrons during discharge.

As shown in FIG. 4, the rear surface of the rear panel 220 has one direction (y-axis direction) such that the address electrode 223 corresponding to the discharge cell 240 intersects the sustain electrode 213 and the scan electrode 214. Elongated). In addition, a plurality of address electrodes 223 are disposed to correspond to the respective discharge cells 240 in the x-axis direction, and the sustain electrode 213 and the scan electrode 214 provided in each discharge cell 240 are provided. And are arranged in an intersection with each other. The address electrode 223 may be arranged to intersect the scan electrode 214 for address discharge. In this embodiment, the address electrode 223 is arranged to intersect the extension portion 214a of the scan electrode 214.

The phosphor layer 246 is formed in the discharge cell 240. The phosphor layer 246 is formed on the address electrode 223 of the back substrate 221 to be excited by vacuum ultraviolet rays generated by gas discharge in the discharge cell 240 to generate red, green, and blue visible light. . More specifically, it is preferable that a dielectric layer 224 is formed on the address electrode 223 to facilitate accumulation of wall charges during address discharge. As a result, an address electrode 223 is formed on the back substrate 221, and a dielectric layer 224 is formed on the address electrode 223, and the second barrier rib group 222 is formed on the dielectric layer 224. The phosphor layer 246 is formed on the inner surface of the second partition wall group 222 and the surface of the dielectric layer 224 to complete the discharge cell 240 on the rear substrate 221 side.

4 is a cross-sectional view taken along line B-B of FIG. 1 to describe an address discharge of the present invention, and FIGS. 5 to 7 are plan views illustrating a sustain discharge of an embodiment of the present invention.

The operation of the PDP according to the present invention will be described with reference to these drawings.

The address discharge of the present invention will be described with reference to FIG. When the address discharge and the scan pulse are applied to the address electrode 223 and the extension portion 214a of the scan electrode 214, the discharge discharges intersect the scan electrode 214 and the address electrode 223, respectively. The cell 240 is selected, and wall charges are accumulated on the side surface of the discharge cell 240 due to the potential difference applied to the scan electrode 214 and the address electrode 223. That is, as shown in FIG. 5, positive wall charges are accumulated on the inner side of the discharge cell 240 and more specifically on the inner side of the discharge cell 240 in which the sustain electrode 213 is disposed due to the address discharge. Negative wall charges are accumulated on the inner side surface of the discharge cell 240 in which the scan electrode 214 is disposed.

The sustain discharge of the present invention will be described with reference to FIGS. 5 to 7. In the state of FIG. 5, when a positive potential is applied to the sustain electrode 213 for the sustain discharge and a negative potential is applied to the scan electrode 214, a predetermined potential difference is generated as shown in FIG. 6. Therefore, an electric field is formed inside the discharge cell 240.

At this time, according to the Gauss law, since the equipotential surface is formed on the surface of the conductor to which the same potential is applied, the same equipotential surface corresponding to the potential applied to the sustain electrode 213 is formed on the entire surface of the sustain electrode 213. The entire surface of the scan electrode 214 is formed with the same equipotential surface corresponding to the potential applied to the scan electrode 214. At this time, since the sustain electrode 213 is disposed to surround the first corner 241 of the discharge cell 240, and the scan electrode 214 is disposed to surround the second corner 242, the sustain electrode 213 side. The magnitude of the electric field around the first corner 241 is substantially the same size, and the electric field of the same size is also formed around the second corner 242 of the discharge cell 240 for the same reason.

On the other hand, at the other corners of the discharge cells 240 except for the first corner 241 and the second corner 242, that is, the third and fourth corner portions 243 and 244, the sustain electrode 213 and the scan electrode ( A strong electric field is formed from the sustain electrode 213 to the scan electrode 214 by the potential difference generated according to the potential applied between the 214. A stronger magnetic field is formed between the sustain electrode 213 and the protrusions 213b and 214b of the scan electrode 214 to enable low voltage driving.

As the distance from the third and fourth corners 213 and 214 toward the center of the discharge cell 240 decreases, the size of the electric field becomes smaller. This can be easily seen from the laws of physics that the magnitude of the electric field is proportional to the magnitude of the potential difference and inversely proportional to the spaced distance between the points at which the potential is applied.

At this time, the discharge starts in a portion where the electric field is relatively strong, and the discharge extends to a portion where the electric field is relatively weak. That is, the discharge starts at the third and fourth corners 243 and 244 and extends toward the center of the discharge cell 240. Based on this reason, the wall charges stored therein are moved in the direction of the electric field by the strong electric fields formed at the third and fourth corners 243 and 244, and the discharge cells 240 are moved by the wall charges. Discharge gas atoms in the c) and the wall charges collide with each other, and the collision with the discharge gas due to the movement of the wall charges extends toward the center of the discharge cell 240 as shown in FIG. The energy level of the internal discharge gas is excited from the low energy level to the high energy level.

The energy level of the excited discharge gas is changed from the high energy level to the low energy level again, generating ultraviolet rays having a predetermined wavelength. In addition, the ultraviolet rays excite the phosphor layer 246 disposed inside the discharge cell 240, more specifically, in the space defined by the second partition group 222 and the dielectric layer 224, from a low energy level to a high energy level. Let's go.

As the phosphor layer 246 changes from the high energy level to the low energy level again, it generates a predetermined visible light. As described above, since the discharge starts at the third and fourth corners 243 and 244 and extends to the center of the discharge cell 240, the movement of the wall charges is caused by the third and fourth corners of the discharge cell 240 ( 243 and 244, the probability that the wall charges impinge on the phosphor layer 246 applied on the dielectric layer 224 is greatly reduced. This decreases the probability that the ion particles in the discharge cell 240 collide with the phosphor layer 246, thereby preventing ion collision to the phosphor layer 246, thereby preventing ion sputtering.

After the sustain discharge is formed, when the voltage difference between the sustain electrode 213 and the scan electrode 214 becomes lower than the discharge start voltage, the discharge no longer occurs, and the space charge and the wall charge are applied to the discharge cell 240. Is formed. At this time, when the polarities of the pulse voltages applied to the sustain electrode 213 and the scan electrode 214 are changed, the firing voltage is reached again with the help of the wall charge, and the discharge is generated again.

When the potential of the pulse voltage is alternately applied between the sustain electrode 213 and the scan electrode 214 repeatedly, the sustain discharge continues. In addition, a predetermined visible light is generated as many times as the number of discharges in the phosphor layer 246 due to the potentials applied to the sustain electrode 213 and the scan electrode 214 alternately, so that a predetermined gray scale is displayed on the screen. do. Through such sustain discharge, the PDP implements an image.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the scope of the invention.

As described above, according to the plasma display panel according to the present invention, the sustain electrode and the scan electrode are provided in a structure surrounding both sides of the discharge cell in the diagonal direction, and the other electrode of the discharge cell adjacent to the front end of the sustain electrode and the scan electrode, and Since the structure is spaced apart from the tip of the sustain electrode, the capacitance between the sustain electrode and the scan electrode of the neighboring discharge cell is reduced during sustain discharge, thereby reducing the reactive power consumption therein, thereby enabling low voltage driving. .

Claims (5)

A first substrate and a second substrate disposed to face each other; Barrier ribs disposed between the first substrate and the second substrate to form discharge cells; A first electrode formed in the partition wall to surround the first corner of the discharge cell; A second electrode formed in the partition wall so as to surround the first corner of the discharge cell surrounded by the first electrode in a diagonal direction and facing the first electrode; An address electrode which extends in one direction on the second substrate and crosses the first electrode and the second electrode in correspondence with a discharge cell; And A phosphor layer formed in the discharge cells, The first electrode and the second electrode includes an extension part extending in one direction, respectively, and protrusions protruding from the extension part to surround the first corner and the second corner, respectively, And the length of the protrusion is shorter than half of the distance between the extension of the first electrode and the extension of the second electrode. The method of claim 1, The distance between the tip of the first electrode protrusion of the one discharge cell and the tip of the protrusion of the second electrode of the neighboring discharge cell is between the protrusion of the first electrode of the one discharge cell and the protrusion of the second electrode of the neighboring discharge cell. The plasma display panel is formed longer than the distance in the extension direction of the. The method of claim 1, The partition wall includes a first partition wall group provided on the first substrate side and a second partition wall group provided on the second substrate side corresponding to the first partition wall group. The method of claim 3, wherein And the first and second partition wall groups each include a first partition member extending in one direction and a second partition member formed to intersect the first partition member. The method of claim 4, wherein An extension part of the first electrode and an extension part of the second electrode are disposed in the first partition member, and a protrusion part of the first electrode and a protrusion part of the second electrode are disposed in the second partition wall member.

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