TWI295048B - Plasma display panel and rear substrate and driving method thereof - Google Patents

Description

1295048 1 3 549twf.doc IX. Description of the Invention: [Technical Field] The present invention relates to a plasma display panel (PDP), and in particular to an auxiliary address electrode (auxiliary address electrode) ) The plasma display and its rear substrate buckle rainbow substrate structure and drive method. [Prior Art] With the development of multimedia, the importance of the display as the communication interface between the human and the computer interface has increased day by day. In recent years, the flat-aged device has largely replaced the conventional cathode ray tube display. At present, there are mainly the following types of flat-panel displays: electric display, organic electroluminescence display (Electronic-Luminescent Display, 0ELD), and liquid crystal display (LCD). Among them, the plasma display has great application potential due to its large size, self-illumination, no viewing angle dependence, light weight and full color, and is expected to become the mainstream of the next generation island flat panel display. FIG. 1 is a perspective exploded view of a conventional plasma display. Referring to FIG. 1, the plasma display device 100 is mainly composed of a front substrate, a rear substrate, a germanium electrode, a gamma electrode, an address dectrode 15, and a barrier wall (seven). Chuan is composed. The Χ electrode and the Y electrode are disposed on the front substrate 1 , and the electrode and the Υ electrode are covered with the dielectric layer u and the protective layer 12 . The back substrate 2 is configured with a address electrode 15 and a barrier wall 3〇, wherein the barrier wall % is formed by a strip pattern parallel to each other, and the rear substrate is divided into a plurality of discharge spaces 13 to Lin 1229548 1 3549twf.doc Electrodes 15 are electrically isolated from each other. Discharge gas (not shown) in the plasma display device 100 is disposed in these discharge spaces 13. The phosphor layer 21 is disposed on the side wall of the barrier rib 3 and a portion of the substrate 10 corresponding to the discharge spaces 13. The area between each pair of X electrodes and Y electrodes corresponding to the address electrodes 15 is the pixel area of the plasma display 100. As described above, by the voltages supplied from the X electrode, the gamma electrode, and the address electrode 15, a plasma is generated in the discharge space 13 to emit ultraviolet light, and is irradiated to the phosphor layer 21, thereby causing the plasma display 100 to display. Out of the image. However, since each pair of X electrodes and Y electrodes are arranged in the column direction, and the address electrodes 15 are arranged in the row direction, when the address signals are input to the address electrodes 15, they are often easily distributed to correspond to adjacent ones. The electric field in the discharge space of the address electrode 15 affects, which in turn causes an error discharge in adjacent pixels. SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a substrate behind a plasma display that reduces the chance of false illumination of the plasma display. Another object of the present invention is to provide a driving method for a plasma display which can reduce the probability of occurrence of erroneous lighting of the plasma display, reduce the probability of the phosphor powder being struck by ions, and increase the service life of the panel. The present invention provides a substrate after a plasma display, comprising a substrate, a plurality of address electrodes, a barrier wall, a multi-sided auxiliary address electrode, and a luminescent material layer. Wherein, the barrier wall and the addressed electrode systems are disposed on the substrate, and the barrier wall defines a plurality of discharge spaces on the substrate, and each address electrode corresponds to at least - discharge (four). The lion-addressed electrode system is disposed on the barrier wall 129. The optical material layer is disposed on the substrate in the discharge space, and supports the address electrode and the sidewall of the barrier wall. Gas A plasma display 'mainly includes a rear substrate, a discharge electrode, and a resist = plate. Wherein the rear substrate comprises a first substrate, a plurality of addressed wall disks, a plurality of auxiliary address electrodes, and a layer of phosphor material. The barrier-pole is disposed on the first and upper, and the barrier wall is in the plurality of discharge spaces, and each of the (four) poles corresponds to at least the gate. The auxiliary address electrode is disposed on the substrate in the discharge space and the first base material is disposed on the substrate in the discharge space, and the fff planting is thin and the barrier is difficult. The front substrate is placed on the rear substrate. The front substrate and the other substrate include a second substrate and a plurality of pairs of electrodes, and the interlayer is disposed on the second substrate and located on the second substrate and the rear substrate. The discharge gas is disposed in these discharge spaces. In the embodiment of the floating ί::,:, the auxiliary address electrode is, for example, electrically connected to the positive potential terminal or the ground terminal. The barrier wall is an enamel layer having a plurality of strip patterns, and (10) a plurality of strips are parallel. In accordance with an embodiment of the present invention, the front substrate further includes a protective layer and a dielectric layer, and the protective dielectric layer covers the protective layer and is disposed on the dielectric. In the implementation of the shot, the layer of the layer 3 = such as magnesium oxide. According to an embodiment of the present invention, each pair of electrode pairs includes, for example, a port X electrode and a -γ electrode ', and in an embodiment, the pair of electrodes, for example, elongated electrodes parallel to each other, extend in the direction of, for example, Is different from the address 129 pro d. The direction in which the electrodes extend is, for example, perpendicular to each other. The driving method of the above-mentioned 1 plasma display is suitable for driving the electrode to be connected to the m method. The method is first reset (F). The addresser electrically couples the auxiliary address electrode to the ground. ^ Field Wei electrode pair, and input the secret number to the address electrode, this input maintains the signal to the electrode pair and the address electrode, and floats this = help address electrode or electrically connect these auxiliary address electrodes to one Positive potential end. According to the embodiment of the present invention, after the input signal is connected to the electrode pair address electrode, and the auxiliary address electrodes are floated or the auxiliary address electrodes are f-coupled to the positive potential terminal, Repeat the above steps at least once. The second aspect of the invention reduces the probability of erroneous by the auxiliary addressing electrodes between the addressed electrodes and acts as a protective layer for the auxiliary address electrodes by the barrier walls to avoid damage during discharge. In addition, the present invention can also couple the auxiliary address electrode and the address electrode to a positive voltage during the sustain discharge, thereby reducing the probability of the positive ion county phosphor material layer to prolong the life of the plasma display. The above and other objects, features and advantages of the present invention will become more <RTIgt; [Embodiment] FIG. 2 is an exploded perspective view of a plasma display according to a preferred embodiment of the present invention. Referring to FIG. 2, the plasma display 200 mainly includes a rear base I29m, a doc board 210, and a front substrate 230. The rear substrate 210 includes a first substrate 212, an address electrode 214, a barrier wall 216, an auxiliary address electrode 218, and a phosphor layer 220. The blocking wall 216 and the address electrode 214 are respectively disposed on the first substrate 212, and the blocking wall 216 defines a plurality of discharge spaces 213 on the first substrate 212, and each of the discharge spaces 213 is provided with a certain address electrode 214. . In the present embodiment, the barrier rib 216 is, for example, a film layer having a plurality of mutually parallel strip patterns, and each strip pattern is located between adjacent address electrodes 214 as shown in FIG. In particular, the auxiliary address electrode 218 is, for example, an elongated electrode disposed between the barrier rib 216 and the first substrate 212. In other words, an auxiliary address electrode 218 is disposed between adjacent address electrodes 214, and the auxiliary address electrode 218 is covered by the barrier ribs 216. The potential of the auxiliary coupling electrode 218 is electrically coupled to the operating state of the plasma display 2 疋, which will be further explained later. The phosphor layer 220 is disposed on the first substrate 212 in the discharge space 213 and covers the sidewalls of the address electrode 214 and the barrier wall 216, and the phosphor layer 22 includes, for example, red, Fluorescent materials in three colors of green and blue. The front substrate 230 includes a second substrate 202, an electrode pair 2〇6, a dielectric layer 208, and a protective layer 204. A plurality of pairs of electrode pairs 206 are disposed on the second substrate 2〇2, and the pair of electrodes 2〇6 are covered with a dielectric layer 2〇8 and a protective layer 204. Among them, the protective layer 204 is used to protect these electrode pairs 2〇6 from being damaged during discharge. The material of the protective layer 204 is, for example, magnesium oxide. In a preferred embodiment, each pair of electrode pairs 2〇6 is, for example, 129 from each other. The parallel X electrodes 205 and Y electrodes 207 are formed and extend in a direction different from the extending direction of the address electrodes 214, for example, perpendicular to each other. Further, the X electrode 205 is composed of, for example, a transparent electrode 205a and a bus electrode 205b, and the Y electrode 207 is composed of, for example, a transparent electrode 207a and a bus electrode 207b. The material of the transparent electrode 2〇5a and the transparent electrode 207a is, for example, a tin oxide or a material which can be used as a transparent electrode. The bus electrode 205b and the bus electrode 207b are made of, for example, a low-resistance metal material, and are disposed on the transparent electrode 2〇5a and the transparent electrode 207a, respectively, for reducing the resistance of the X electrode 2〇5 and the γ electrode 2〇7. value. In the present embodiment, discharge gases (not shown) are disposed in the discharge spaces 213 defined by the barrier walls 216, respectively. When a voltage is applied to the = electrode 205 and the Y electrode 207 and the address signal is input to the address electrode 214 in the discharge space 213, a plasma is generated in the discharge space 213 here, and ultraviolet light is excited. The violet-outer light will illuminate the layer of phosphor material in the discharge space 213, and the plasma display 2 will display the image. The auxiliary address electrode and the address electrode of the present invention may have various wiring patterns. For example, the auxiliary address electrode 3() 2 may be electrically connected to each other by the connection wire 306 connected to one of them (see FIG. 3A). The /, and then = at least - the auxiliary button electrode 3 G 2 is electrically secreted to the external circuit. In addition, the 'auxiliary address electrode 302 S may be a connecting wire that laterally supports the addressed electrode 3 〇 2 from the middle And electrically disconnected from each other, and then connected to the external circuit 3 (9) by at least one of the auxiliary address electrodes 302 129. If the connecting wire is connected by the intermediate laterally-belt-assisted addressing electrode 3〇2, the addressing electrode 3〇4 in each pixel must be divided into two segments and connected to the external circuit 3GG, respectively, as shown in Fig. 3B.丨 Of course, the above-mentioned auxiliary address electrodes and the wiring electrodes of the address electrodes are only used to exemplify the present invention, and are not intended to limit the wiring manner of the auxiliary address electrodes and the address electrodes of the present invention. Those skilled in the art can modify this in light of the spirit of the invention, which is also within the scope of the invention. The present invention will be described below with reference to the plasma display 2 shown in Fig. 2: a method of driving a plasma display. However, the present invention does not limit the driver to the plasma display 2 shown in FIG. 2, as long as it is a plasma display having the auxiliary address electrodes of the present invention. The driving method described is driven. Fig. 4 is a flow chart showing the steps of the driving method of the plasma display of the present invention. Referring to FIG. 2 and FIG. 4 simultaneously, firstly, the reset of the electrode pair 2〇6 and the address electrode 214 is performed, and then the auxiliary address electrode 218 is electrically coupled to the ground end, as described in step S400. Then, the corresponding electrode pair 206 is selected according to the pixel to be illuminated to apply a voltage thereto, and the address §fl is input to the corresponding address electrode 214 as described in step S402. Thereafter, the sustain signal is input to the electrode pair 206 and the address electrode 214, and the auxiliary address electrode 218 is electrically coupled to a positive potential or brought to a floating state, as described in step S404. At this time, if the auxiliary electrode 218 and the address electrode 214 are lightly connected to a positive voltage, the positive ions generated by the discharge gas can be prevented from hitting the phosphor material layer I29WiLd〇c 220 on the address electrode 214 to be: 3⁄4: Damage, in order to extend the life of the plasma display. Then, the money step S_ is repeated, and the above steps are repeated continuously until step S404 to actuate the plasma display 2〇〇. Wherein, when resetting the electrode pair 206 and the address electrode 214, it is necessary to electrically reduce the auxiliary address electrode 218 to the ground. In other words, in addition to maintaining the discharge f state, the galvanic address electrode (10) is electrically connected to the ground terminal to reduce noise interference, and the rotation is low, and the machine is shown as an example in the invention == waveform It can be seen from the above that the present invention is to arrange an auxiliary address electrode between the address electrodes. When the money display 7FH is carried out, the lion address electrode is electrically connected to the ground end to reduce the interference of the health, and the county is adjacent. The problem of erroneous lighting occurs in the pixels. Moreover, the auxiliary address electrode can be completed in the same process as the address i pole. Thus, the present invention does not increase the complexity of the process. Further, the auxiliary address electrode system of the present invention The crucible is disposed between the barrier wall and the substrate. Therefore, the auxiliary address electrode can be protected by the barrier wall so that it is not damaged during the discharge process. In addition, while inputting the sustain signal to the pixel to be lit, The floating auxiliary auxiliary address electrode can be floated or electrically coupled to the positive potential end, thereby avoiding damage to the camping material layer on the address electrode of the sinter county generated by the self-discharge gas, thereby further Delay The life of the plasma display. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the invention, and may be made without departing from the spirit and scope of the invention. </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; 2 is a perspective exploded view of a plasma display device according to a preferred embodiment of the present invention. FIGS. 3A and 3B are respectively schematic diagrams showing the manner of wiring the auxiliary address electrodes and the address electrodes in an embodiment of the present invention. 4 is a flow chart showing the steps of the driving method of the plasma display of the present invention. Fig. 5 is a schematic diagram showing driving waveforms used in an example of the present invention. [Description of main component symbols] 100, 200, 300 · Plasma display 10, 230: front substrate 11: dielectric layer / 12: protective layer 13, 213: discharge space 15, 214, 314, 304: address electrode 20: substrate 21, 220: phosphor layer 30, 216: Resistance The spacer 202: the second substrate 204: the protective layer 205, the X: X electrode 13, 1295048n 1 3549twf.doc 205a, 207a: the transparent electrode 205, 207b: the bus electrode 206, 306: the electrode pair 207, the Y: Y electrode 208: Electrical layer 210: rear substrate 212: first substrate 218, 302: auxiliary address electrode 300 · external circuit 306: connecting wire S400 1 set (four) reduce electrode pair, and then electrically coupled to the ground end address telegraph Electrode pair, and input the address signal to S404: input the sustain signal to the electrode pair to address the electrode, and the auxiliary address electrode is secreted to the positive (4) or it is in the floating state

Claims (1)

I29m, d〇c X. Patent application scope: 1. A plasma display comprising: a rear substrate comprising: a first substrate; a plurality of addressed electrodes disposed on the first substrate; a barrier wall disposed at a plurality of discharge spaces are defined on the first substrate, and each of the address electrodes corresponds to at least one of the discharge spaces; a plurality of auxiliary address electrodes are disposed on the barrier wall and the first substrate a phosphor material layer disposed on the first substrate in the discharge spaces and covering the address electrodes and sidewalls of the barrier wall; a substrate disposed above the rear substrate, and The front substrate includes: a second substrate; a plurality of pairs of electrodes disposed on the first substrate and located between the first substrate and the rear substrate; and a discharge gas disposed in the discharge spaces. The plasma display device of claim 1, further comprising a dielectric layer, a protective layer, wherein the dielectric layer is disposed on the second substrate and covers the pair of electrodes, The protective layer is disposed on the dielectric layer. 3. The plasma display of claim 2, wherein the material of the protective layer comprises magnesium oxide. 4. The plasma display according to claim </ RTI> wherein the 15 grounding terminal or a positive auxiliary addressing electrode is electrically connected to the potential terminal by a floating connection. Fine-moving coffee, in which the strips turn 5 torn electricity _m, which 7· as claimed patent scope! The plasma display of the present invention, wherein the pair of electrodes are wire electrodes parallel to each other, and the extending direction is different from the extending direction of the address electrodes. 8. The plasma display of claim 7, wherein the pair of electrodes extend in a direction perpendicular to the direction in which the addressed electrodes extend. 9. The plasma display of claim 2, wherein each of the pair of electrodes comprises an x electrode and a gamma electrode. a substrate after the plasma display, comprising: a substrate; - a plurality of address electrodes disposed on the substrate; a partition wall disposed on the substrate to define a plurality of discharge spaces, and a mother The address electrodes are corresponding to at least one of the discharge spaces; a plurality of auxiliary address electrodes are disposed between the barrier walls and the substrate; and a phosphor layer is disposed in the discharge spaces On the substrate, and covering the address electrodes and the sidewalls of the barrier wall. 11. The base of the plasma display as described in claim 10 is 1295ML·^ === the address electrode is floating or electrically connected. 12. As claimed in the first panel, the barrier wall includes money. The strips _ after the base L3t! Please refer to the substrate after the electric actuator described in claim 12, wherein the strip patterns are parallel to each other.円 ? · · · · · · 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电The address electrodes and the pair of electrodes are disposed, and then the auxiliary address electrodes are electrically coupled to a ground terminal; (b) a scan signal is input to the electrode pairs, and a certain address is input. And (c) inputting a sustain signal to the address electrodes and the pair of electrodes, and floating the lion-addressed electrodes or electrically connecting the lion-addressed electrodes to a positive potential terminal . The method of driving a plasma display according to claim 14, wherein after resetting the address electrodes and the pair of electrodes, repeating steps (a) to (c) at least once is repeated.