This application makes reference to, incorporates the same herein, and claims all benefits accruing under 35 U.S.C. ยง119 from an application for PLASMA DISPLAY PANEL earlier filed in the Korean Intellectual Property Office on 21 May 2004 and there duly assigned Serial No. 10-2004-0036392.
1. Field of the Invention
The present invention relates to a Plasma Display Panel (PDP), and more particularly, to a PDP having a high aperture ratio of a discharge cell, a high light transmittance, and a high luminous efficiency and in which a stable and efficient discharge occurs uniformly at a low driving voltage on inner sidewalls of the discharge cell and concentrates in the center of the discharge cell.
2. Description of the Related Art
In an AC, triode-type, surface discharge PDP, the PDP comprises a front panel and a rear panel. The front panel comprises a front substrate, pairs of sustain electrodes composed of Y electrodes and X electrodes on a rear surface of the front substrate, a front dielectric layer covering the sustain electrodes, and a protective layer covering the front dielectric layer. Each of the Y electrodes is composed of a transparent electrode and a bus electrode, and each of the X electrodes is composed of a transparent electrode and a bus electrode. The transparent electrodes are made of Indium Tin Oxide (ITO) or the like. The bus electrodes are connected to connection cables (not shown) disposed at right and left sides of the PDP.
The rear panel comprises a rear substrate, address electrodes disposed on a front surface of the rear substrate and intersecting the pairs of sustain electrodes, a rear dielectric layer covering the address electrodes, barrier ribs disposed on the rear dielectric layer and dividing a discharge space into discharge cells, and fluorescent layers disposed in the discharge cells. The address electrodes are connected to connection cables (not shown) disposed at upper and lower sides of the PDP.
In the PDP, in addition to the pairs of the sustain electrodes which generate a discharge, the front dielectric layer and the protective layer are formed on the rear surface of the front substrate through which visible light generated by the fluorescent layers in the discharge cells is transmitted. The transmittance of visible light is significantly reduced and the brightness of the PDP is therefore also reduced.
Furthermore, since the pairs of sustain electrodes are formed on the rear surface of the front substrate in the PDP, the majority of the sustain electrodes (i.e., the transparent electrodes, excluding the bus electrodes) must be formed of ITO, which is highly resistive, in order to allow the generated visible light to be transmitted through the front substrate. Thus, a driving voltage of the PDP increases and since the high resistance of the ITO electrodes causes a voltage drop, images cannot be uniformly displayed when the PDP is large.
In the PDP, the pairs of sustain electrodes are formed on the rear surface of the front substrate, and the discharge occurs behind the protective layer and diffuses within the discharge cells. In other words, the discharge occurs only on a portion of the discharge cells and a space in the discharge cells cannot be efficiently utilized. As a result, a driving voltage for discharging must be increased, and thus, the cost of a driving circuit, which is the most expensive piece of equipment in a PDP, increases. Furthermore, due to the concentration of the discharge in a limited space in the discharge cell, the luminous efficiency of the PDP is reduced. When the PDP is used for a long time, a charged discharge gas induces ion sputtering of the fluorescent material in the fluorescent layers due to the electric field, thereby resulting in permanent after-images.
The present invention provides a Plasma Display Panel (PDP) having a high discharge cell aperture ratio, a high light transmittance, and a high luminous efficiency and in which a stable and efficient discharge occurs uniformly at a low driving voltage on inner sidewalls of the discharge cell and is concentrated in the center of the discharge cell.
According to an aspect of the present invention, a Plasma Display Panel (PDP) is provided comprising: a front substrate and a rear substrate facing each other and separated from each other; barrier ribs of a dielectric material arranged between the front substrate and the rear substrate to define discharge cells together with the front substrate and the rear substrate; discharge electrodes arranged within the barrier ribs, the discharge electrodes being separated from each other and surrounding the discharge cells and having at least one corner portion for surrounding the discharge cells; fluorescent layers arranged in the discharge cells; a discharge gas contained within the discharge cells; and
an attenuator adapted to reduce a strength of an electric field generated between at least one pair of corner portions of the discharge electrodes, the corner portions facing each other, to be less than a strength of an electric field generated between portions of the discharge electrodes facing each other, other than the corner portions, in the discharge cells.
The attenuator preferably comprises the at least one pair of the facing corner portions of the discharge electrodes, a distance between the facing corner portions being longer than a distance between the portions of the facing discharge electrodes other than the corner portions in the discharge cells.
The attenuator alternatively preferably comprises the at least one pair of the facing corner portions of the discharge electrodes, the facing corner portions being bent in a direction to be farther from each other.
The attenuator alternatively preferably comprises the at least one pair of the facing corner portions of the discharge electrodes, a total thickness of the facing corner portions being less than a total thickness of the portions of the facing discharge electrodes other than the corner portions.
The attenuator alternatively preferably comprises the at least one pair of the facing corner portions of the discharge electrodes having a concave portion on at least one of their facing surfaces.
The attenuator alternatively preferably comprises the at least one pair of the facing corner portions of the discharge electrodes, having a concave portion on at least one of the surfaces other than the facing surfaces.
The attenuator alternatively preferably comprises the at least one pair of the facing corner portions of the discharge electrodes, at least one corner portion having a higher resistivity than the portions of the discharge electrodes other than the corner portion.
The discharge electrodes preferably extend in parallel to each other and address electrodes extend to cross the discharge electrodes.
The PDP preferably further comprises a dielectric layer arranged on the rear substrate to cover address electrodes.
The discharge electrodes alternatively preferably cross each other at a discharge cell.
The discharge electrodes preferably each have a ladder shape and at least a portion of each sidewall of the barrier ribs is coated with a protective layer.
Each of the barrier ribs preferably has a central barrier rib portion and side barrier rib portions and each of the discharge electrodes is coated with a protective layer.
The barrier ribs preferably comprise: front barrier ribs formed on a rear surface of the front substrate and rear barrier ribs formed on a front surface of the rear substrate, the discharge electrodes being arranged in the front barrier ribs; and fluorescent layers arranged in a space defined by the rear barrier ribs and the rear substrate.
A more complete appreciation of the present invention, and many of the attendant advantages thereof, will be readily apparent as the present invention becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings in which like reference symbols indicate the same or similar components, wherein:
The rear panel 120 comprises a rear substrate 121, address electrodes 122 disposed on a front surface 121a of the rear substrate 121 and intersecting the pairs of sustain electrodes 114, a rear dielectric layer 123 covering the address electrodes 122, barrier ribs 130 disposed on the rear dielectric layer 123 and dividing a discharge space into discharge cells 126, and fluorescent layers 125 disposed in the discharge cells 126. The address electrodes 122 are connected to connection cables (not shown) disposed at upper and lower sides of the PDP 100.
In the PDP 100, in addition to the pairs of the sustain electrodes 114 which generate a discharge, the front dielectric layer 115 and the protective layer 116 are formed on the rear surface 111a of the front substrate 111 through which visible light generated by the fluorescent layers 125 in the discharge cells 126 is transmitted. The transmittance of visible light is significantly reduced and the brightness of the PDP 100 is therefore also reduced.
Furthermore, since the pairs of sustain electrodes 114 are formed on the rear surface 111a of the front substrate 111 in the PDP 100, the majority of the sustain electrodes 114 (i.e., the transparent electrodes 112b and 113b, excluding the bus electrodes 112a and 113a) must be formed of ITO, which is highly resistive, in order to allow the generated visible light to be transmitted through the front substrate 111. Thus, a driving voltage of the PDP 100 increases and since the high resistance of the ITO electrodes causes a voltage drop, images cannot be uniformly displayed when the PDP 100 is large.
In the PDP 100, the pairs of sustain electrodes 114 are formed on the rear surface 111a of the front substrate 111, and the discharge occurs behind the protective layer 116 and diffuses within the discharge cells 126. In other words, the discharge occurs only on a portion of the discharge cells 126 and a space in the discharge cells 126 cannot be efficiently utilized. As a result, a driving voltage for discharging must be increased, and thus, the cost of a driving circuit, which is the most expensive piece of equipment in a PDP, increases. Furthermore, due to the concentration of the discharge in a limited space in the discharge cell, the luminous efficiency of the PDP 100 is reduced. When the PDP 100 is used for a long time, a charged discharge gas induces ion sputtering of the fluorescent material in the fluorescent layers 125 due to the electric field, thereby resulting in permanent after-images.
The front panel 210 comprises a transparent front substrate 211, and the rear panel 220 comprises a rear substrate 221 parallel to and facing the front substrate 211.
Front barrier ribs 215 are located on a rear surface 211b of the front substrate 211 to define discharge cells 226 together with the front substrate 211, the rear substrate 221, and rear barrier ribs 224. The front panel 210 comprises discharge electrodes 219 located in the front barrier ribs 215 to surround the discharge cells 226. The discharge electrodes 219 are separated from the front substrate 211 and include front discharge electrodes 213 and rear discharge electrodes 212. The rear discharge electrodes 212 extend parallel to the front discharge electrodes 213 in a predetermined direction.
The front panel 210 can comprise protective layers 216 covering outer sidewalls 215g of the front barrier ribs 215, if necessary. The protective layers 216 can be formed on outer sidewalls 224a of the rear barrier ribs 224 or front surfaces 225a of fluorescent layers 225, in addition to the outer sidewalls 215g of the front barrier ribs 215.
The rear panel 220 comprises the rear substrate 221, address electrodes 222 located on a front surface 221a of the rear substrate 221 and extending to cross the discharge electrodes 219, a dielectric layer 223 covering the address electrodes 222, the rear barrier ribs 224 located on the dielectric layer 223, and the fluorescent layers 225 located in spaces defined by the rear barrier ribs 224.
The front panel 210 and the rear panel 220 are combined with each other using a combination member (not shown) and sealed. The combination member can be a frit. The discharge cells 226 are filled with a discharge gas, such as Neon (Ne), Helium (He), and Argon (Ar), each containing about 10% of Xenon (Xe) gas, or a mixture thereof.
The front substrate 211 and the rear substrate 221 are generally made of glass. The front substrate 211 is made of a material having a high light transmittance. The PDP 200 does not include elements of the PDP 100 of
In order to increase the brightness of the PDP 200, a reflective layer (not shown) can be located on the front surface 221a of the rear substrate 221 or the front surface 223a of the dielectric layer 223, or a light reflective material can be contained in the dielectric layer 223 such that the visible light generated by the fluorescent layers 225 is efficiently reflected forward.
In the AC, triode-type, surface discharge PDP 100, in order to increase the light transmittance, the discharge electrodes are made of ITO, which has a relatively high resistance. However, in the PDP 200 of
The barrier ribs 230 are located between the front substrate 211 and the rear substrate 221 to define the discharge cells 226 together with the front substrate 211 and the rear substrate 221. The discharge cells 226 are defined into a matrix shape by the barrier ribs 230 in
The discharge electrodes 219 are located in the front barrier ribs 215 to surround the discharge cells 226. The discharge electrodes 219 can include the front discharge electrodes 213 and the rear discharge electrodes 212.
Positioning of the front discharge electrodes 213 and the rear discharge electrodes 212 in the front barrier ribs 215 will be explained with reference to
The first, second, and third front barrier rib layers 215a, 215b, and 215c can be made of dielectric materials, such as glass containing elements such as Pb, B, Si, Al, and O, and if necessary, a filler such as ZrO2, TiO2, and Al2O3 and a pigment such as Cr, Cu, Co, Fe, TiO2.
When a voltage pulse is supplied between the front discharge electrode 213 and the rear discharge electrode 212, the above dielectric materials induce charged particles and thus, induce the wall charges, and prevent the front discharge electrode 213 and the rear discharge electrode 212 from colliding with accelerated charged particles.
After the front barrier rib 215 is formed, the protective layer 216 can be formed on the outer sidewall 215g of the front barrier rib 215 by deposition, etc. The protective layer 216 can protect the front discharge electrode 213, the rear discharge electrode 212, and the front barrier rib 215, and emit secondary electrons during the discharge, thereby allowing the discharge to be easily generated. During the formation of the protective layer 216, a protective layer can be further formed on the rear surface 211b of the front substrate 211 and on the rear surface 215g of the front barrier rib 215. The protective layer thus formed does not have an adverse effect on the operation of the PDP 200.
Referring to
The rear barrier ribs 224 define spaces on which the fluorescent layers 225 are coated and, together with the front barrier ribs 215, resist the force of the vacuum (for example, 0.5 atm) of the discharge gas filled between the front panel 210 and the rear panel 220. The rear barrier ribs 224 also define spaces for the discharge cells 226 and prevent cross-talk between the discharge cells 226. The rear barrier ribs 224 can contain a reflective material to reflect the visible light generated in the discharge cells 226 forward. The fluorescent layers 225, which emit red, green, or blue light, can be located in the spaces defined by the rear barrier ribs 224. The fluorescent layers 225 are divided by the rear barrier ribs 224.
The fluorescent layers 225 are formed by coating a fluorescent paste comprising either red, green, or blue light-emitting fluorescent material, a solvent, and a binder, on the front surface 223a of the dielectric layer 223 and the outer sidewalls 224a of the rear barrier ribs 224, and drying and baking the resultant structure. The red light-emitting fluorescent material can be Y(V,P)O4:Eu, etc., the green light-emitting fluorescent material can be ZnSiO4:Mn, YBO3:Tb, etc. and the blue light-emitting fluorescent material can be BAM:Eu, etc.
The rear protective layers (now shown), made of, for example, MgO, can be formed on the front surfaces 225a of the fluorescent layers 225. When the discharge occurs in the discharge cells 226, the rear protective layers can prevent deterioration of the fluorescent layers 225 due to collisions with the discharge particles and emit secondary electrons, thereby allowing the discharge to be easily generated.
Referring to
Since the rear discharge electrodes 212 are close to the address electrodes 222, an address discharge for selecting one of the discharge cells 226 in which a sustain discharge occurs preferably occurs between the rear discharge electrodes 212 and the address electrodes 222. The rear discharge electrodes 212 can be common electrodes and the front discharge electrodes 213 can be scan electrodes, but are not limited thereto.
The operation of the PDP 200 of
When a predetermined address voltage is supplied between the address electrodes 222 and the rear discharge electrodes 212, one of the discharge cells 226 is selected and wall charges accumulate on the sidewalls of the front barrier ribs 215 in which the rear discharge electrodes 212 are located, in the selected discharge cell 226. Such a discharge is called an address discharge.
After the address discharge occurs, a sustain discharge occurs. The sustain discharge will now be explained. When a high pulse voltage is supplied to the front discharge electrodes 213 and a low pulse voltage is supplied to the rear discharge electrodes 212, wall charges move due to the voltage difference between the front discharge electrodes 213 and the rear discharge electrodes 212, and collide with discharge gas atoms, thereby generating a discharge and creating plasma. The discharge occurs more easily when the front discharge electrodes 213 are close to the rear discharge electrodes 212 since a stronger electric field is formed there.
Unlike the AC, triode-type, surface discharge PDP 100, the PDP 200 comprises the discharge electrodes 219 located in the barrier ribs 230 to surround the discharge cells 226 and thus, a probability that a discharge occurs at sidewalls of the discharge cells 226 near the front discharge electrodes 213 and the rear discharge electrodes 212 is increased and the discharge can occur inner sidewalls of the discharge cells 226. Thus, the discharge is generated more easily and over a greater area, compared to the PDP 100.
When the discharge occurs successfully along the inner sidewalls of the discharge cells 226 and the voltage difference between the discharge electrodes 219 is maintained for a predetermined time, the electric field generated on the sidewalls of the discharge cells 226 is concentrated in the central portions of the discharge cells 226. Thus, the discharge region is much larger than in the PDP 100, thereby increasing the amount of UV light generated by the discharge. Furthermore, since the discharge diffuses from the walls of the discharge cells 126 to the centers, ion collision with the fluorescent layers 225 is inhibited and thus, ion sputtering is prevented.
When the voltage difference between the discharge electrodes 219 becomes lower than the discharge voltage after the discharge, the discharge is no longer generated, and space charges and wall charges accumulate in the discharge cells 226.
When a low pulse voltage is supplied to the front discharge electrodes 213 and a high pulse voltage is supplied to the rear discharge electrodes 212, the difference between these supplied pulse voltages and the wall charges previously formed have a synergistic effect to allow the voltage difference to reach the firing voltage and thus, a discharge is again generated.
When the polarity of the pulse voltage supplied between the discharge electrodes 219 is repeatedly changed, the discharge is maintained. The UV light generated by the discharge strikes the fluorescent layers 225, thereby exciting fluorescent molecules in the fluorescent layers 225. When the energy level of the excited fluorescent molecules drops, visible light of a predetermined wavelength is generated, thereby displaying images.
As described above, to ensure that the space in the discharge cells 226 is efficiently utilized, the discharge is concentrated in the centers of the discharge cells 226 rather than on the sidewalls of the discharge cells 226 to increase the discharge efficiency.
Although constant voltages are supplied to the discharge electrodes 219, the uniform discharge cannot be sufficiently attained, since the discharge does not occur due to the voltages supplied to the discharge electrodes 219, but rather due to the voltage difference between the discharge electrodes 219. When an electric field is generated in the discharge cells 226 due to the voltage difference, wall charges have a kinetic energy and arbitrarily collide with a discharge gas to generate plasma particles and thus, the discharge occurs. That is, the electric field generated in the discharge cells 226 can be a more important factor for the uniform discharge than the voltages supplied between the discharge electrodes 219. Such an electric field can greatly depend on a shape or a material of the discharge electrodes 219.
Thus, to confirm that the uniform discharge occurs along the inner sidewalls of the discharge cells 226 due to the voltages supplied between the discharge electrodes 219, there is a need to confirm a distribution of the electric field generated in the discharge cells 226 due to the voltages supplied between the discharge electrodes 219.
The distribution of the electric field in a discharge cell 226 is described below with reference to
Referring to
Although the electric field is concentrated in the center of the discharge cell 226, if a discharge occurs only on a limited surface in the discharge cell 226, the discharge cannot efficiently extend to the center thereof, i.e., the discharge cannot efficiently occur. From this consideration, it is confirmed that the electric field is preferably generated uniformly along the inner sidewalls of the discharge cell 226 to ensure that the discharge uniformly occurs in the entire discharge cell 226. The equipotential surfaces E1 in corner portions 231 of the discharge cell 226 are rounded against the corner portions 231 and since the electric field is generated perpendicular to the equipotential surfaces E1, the electric field is highly concentrated especially in the corner portions 231.
Referring to
The characteristic distribution of the electric field implies that a high strength electric field E is generated only in the corner portions 231 of the discharge cell 226 and wall charges generated in the corner portions 231 have still higher kinetic energy than wall charges generated in the inner sidewalls of the discharge cell 226 other than the corner portions 231. Thus, a probability that the discharge occurs in the corner portions 231 of the discharge cell 226 is increased. This does not comply with the original intention of the invention to design the discharge cells such that the discharge can uniformly occur along the inner sidewalls of the discharge cell 226.
To overcome this problem, a attenuator such that a strength of an electric field generated between corner portions of discharge electrodes, the corner portions facing each other, is less than a strength of an electric field generated between portions of the discharge electrodes facing each other, other than the corner portions, should be supplied to discharge cells. The attenuator will now be described in detail.
Specifically, the electric field in the discharge cells 326 is generated due to a voltage difference between the discharge electrodes 319, i.e., between front discharge electrodes 313 and rear discharge electrodes 312. Thus, to ensure that the strength of the electric field in the corner portions 331 of the discharge cells 326 is identical to the strength of the electric field on inner sidewalls of the discharge cells 326 other than the corner portions 331, a attenuator for reducing a strength of an electric field generated between pairs of corner portions 313a and 312a of the discharge electrodes 319 is needed.
With respect to an electric field, a strength of an electric field generated due to a voltage supplied between two electrodes is proportional to a voltage difference between the two electrodes divided by a distance between the two electrodes. Thus, when the distance between the two electrodes is increased, the electric field strength between the two electrodes is decreased.
Accordingly, when a distance between the corner portions 313a and 312a of the discharge electrodes 319, which generates an electric field in the corner portions 331 of the discharge cells 326, is increased to be greater than a distance between the portions 313b and 312b of the discharge electrodes 319 other than the corner portions 313a and 312a, a strength of an electric field generated between the pairs of the corner portions 313a and 312a of the discharge electrodes 319 is less than a strength of an electric field generated between the portions 313b and 312b of the discharge electrodes 319 other than the corner portions 313a and 312a. As a result, the strength of the electric field in the corner portions 331 of the discharge cells 326 becomes greater than the strength of the electric field on the inner sidewalls of the discharge cells 326 other than the corner portions 331 due to the concentration of the electric field in the corner portions 331 of the discharge cells.
Referring to
In the PDP 300, to ensure that a distance d1 between corner portions 313a and 312a of the discharge electrodes 319 is greater than a distance d2 between portions 313b and 312b of the discharge electrodes 319 other than the corner portions 313a and 312a, the pairs of the corner portions 313a and 312a are bent in such a direction that they are farther from each other. Thus, the electric field strength between the pairs of the corner portions 313a and 312a of the discharge electrodes 319 is less than the electric field strength between the portions 313b and 312b of the discharge electrodes 319. As a result, the electric field is uniformly generated in the discharge cells 326 and the wall charges on the corner portions 331 of the discharge cells 326 have substantially the same kinetic energy as the wall charges on the inner sidewalls of the discharge cell 326 other than the corner portions 331, and thus, the discharge uniformly occurs along the inner sidewalls of the discharge cells 326.
Referring to
Referring to
To prevent a non-uniform discharge due to the concentration of the electric field in corner portions 431 in the PDP 400, pairs of corner portions 413a and 412a of the discharge electrodes 419 are bent in such a direction that they are farther from each other, such that a distance d1 between the corner portions 413a and 412a of the discharge electrodes 419 is greater than a distance d2 between portions 413b and 412b of the discharge electrodes 419 other than the corner portions 413a and 412a.
The operation of the PDP 400, which does not comprise address electrodes 222, is explained below based on the differences from the PDP 300 of
In the PDP 400, an address discharge for selecting the discharge cells 426 in which a sustain discharge will occur is determined as follows. First, a predetermined voltage is supplied between the discharge electrodes 419 disposed to cross each other in the discharge cells 426 to be selected and due to the supplied voltage, an electric field is induced and the sustain discharge occurs. As described above, due to the sustain discharge, wall charges are generated on the sidewalls of the discharge cells 426.
Thereafter, as described above, the sustain discharge occurs with the aid of the wall charges by applying a voltage between the discharge electrodes 419 sequentially. Such a procedure is selectively and repeatedly performed for the discharge cells 426 of the PDP 400, and thus, an image is realized.
The integration of the front barrier ribs 215 and the rear barrier ribs 224 into the integrated barrier ribs 530 means that front barrier ribs 215 and the rear barrier ribs 224 are joined and cannot be separated without breaking, but the barrier ribs 530 are not produced in one process.
The production of the integrated barrier ribs 530 is explained below with reference to
Then, a second barrier rib layers 515b is formed to cover the rear discharge electrode 512, and a front discharge electrode 513 is formed on the second barrier rib layer 515b. Third barrier rib layer 515c is formed to cover the front discharge electrode 213. The first barrier rib layer 515a, the second barrier rib layer 515b, and the third barrier rib layer 515c constitute a front portion 515 of the integrated barrier rib 530. The rear portion 524, the first barrier rib layer 515a, the second barrier rib layer 515b, and the third barrier rib layer 515c can each comprise more than one layer, if necessary (for example, in order to increase their thicknesses).
After forming the integrated barrier rib 530, protective layers 216 are formed on at least sidewalls 515g of the front portion 524 of the integrated barrier rib 530, using deposition. During the deposition of the protective layers 216, rear protective layers (not shown) can also be formed on front surfaces 225a of the fluorescent layers 225. The function of the protective layers 216 is as described above.
During the deposition of the protective layers 216, a protective layer can be further formed on a front surface 530h of the in the integrated barrier rib 530. The protective layer formed on the front surface 530h does not have a great adverse effect on the operation of the PDP 500.
The PDP 600 differs from the PDP 300 of
The center barrier ribs 615a can be made of a material having a lower relative dielectric constant than a material of the side barrier ribs 615b to prevent the interference between the discharge cells 626 which can occur according to the operation modes.
Referring to
The PDP 700 differs from the PDP 300 of
Referring to
It is not necessary to form the concave portions 760 on both the facing surfaces of each of the pairs of the corner portions 713a and 712a. In the present embodiment, the concave portions 760 can be formed on one of the facing surfaces of each of the pairs of the corner portions 713a and 712a.
Referring to
An electric power is inversely proportional to the square of a distance, and thus, the wall charges induced by the electric power generated at edges 713x of the discharge electrode 719 are formed on a limited area of the inner surfaces of the discharge cell 726. Since t1 is less than t2, the wall charges induced by the corner portions 713a and 712a of the discharge electrodes 719 are formed on a narrower area in the inner surfaces of the discharge cells 726 than the wall charges induced by the portions 713b and 712b of the discharge electrode 719 other than the corner portions 713a and 712a. As a result, the amount of the wall charges induced by the corner portions 713a and 712a is reduced.
As the thickness t1 of each of the corner portions 713a and 712a of the discharge electrode 719 is decreased, the amount of the wall charges induced on the corner portions 731 of the discharge cell 726 is decreased. Thus, a probability that a discharge occurs on the corner portions 731 of the discharge cell 726 is reduced.
Thus, when the pairs of the corner portions 713a and 712a of the discharge cell 726 have the concave portions 760 on their facing surfaces, the distance d1 between the corner portions 713a and 712a is increased and the thickness t1 of each of the corner portions 713a and 712a of the discharge electrode 719 is decreased. Thus, the concentration of the discharge on the corner portion 731 of the discharge cell 726 can be reduced.
Referring to
In the PDP of
Referring to
In the PDP of
In the PDP 1000, pairs of corner portions 1013a and 1012a of the discharge electrodes 1019 have concave portions 1060 on surfaces other than the facing surfaces. In this case, although a distance between the corner portions 1013a and 1012a of the discharge electrodes 1019 is identical to a distance between portions 1013b and 1012b of the discharge electrodes 1019 other than the corner portions 1013a and 1012a, a thickness of each of the corner portions 1013a and 1012a of the discharge electrode 1019 is less than a thickness of each of the portions 1013b and 1012b of the discharge electrode 1019 other than the corner portions 1013a and 1012a.
Referring to
Since a thickness t1 of each of corner portions 1013a and 1012a of the discharge electrode 1019 is less than a thickness t2 of each of portions 1013b and 1012b of the discharge electrode 1019 other than the corner portions 1013a and 1012a, the wall charges induced by the corner portions 1013a and 1012a of the discharge electrodes 1019 are formed on a narrower area in the inner surfaces of the discharge cells 1026 than the wall charges induced by the portions 1013b and 1012b. As a result, the amount of the wall charges induced by the corner portions 1013a and 1012a of the discharge electrodes 1019 is reduced.
Although a distance between the corner portions 1013a and 1012a of the discharge electrodes 1019 is identical to a distance between portions 1013b and 1012b of the discharge electrodes 1019 other than the corner portions 1013a and 1012a, when a thickness of each of the corner portions 1013a and 1012a of the discharge electrode 1019 is less than a thickness of each of the portions 1013b and 1012b of the discharge electrode 1019 other than the corner portions 1013a and 1012a, the amount of the wall charges on the corner portions 1031 of a discharge cell 1026 is reduced. Thus, a probability that a discharge occurs on the corner portions 1031 of the discharge cell 1026 is reduced. As a result, the discharge is less concentrated in the corner portion 1031 of the discharge cell 1026 and the discharge can uniformly occur along the inner sidewalls of the discharge cell 1026.
Referring to
Referring to
The PDP 1300 differs from the PDP 300 of
As described with respect to the PDP 300 of
When the voltage is supplied between the discharge electrodes 1319, the discharge electrodes 1319 have resistance and a voltage drop occurs although the discharge electrodes 1319 are made of a conductive material. When the corner portions 1313a and 1312a of the discharge electrodes 1319 are made of a material having a high resistivity, a voltage drop occurring in the corner portions 1313a and 1312a of the discharge electrodes 1319 is relatively greater than a voltage drop in the portions 1313b and 1312b of the discharge electrode 1319 other than the corner portions 1313a and 1312a. As a result, a voltage difference between the corner portions 1313a and 1312a of the discharge electrodes 1319 is less than a voltage difference between the portions 1313b and 1312b of the discharge electrode 1319 other than the corner portions 1313a and 1312a.
Although a distance between the corner portions 1313a and 1312a of the discharge electrodes 1319 is identical to a distance between the portions 1313b and 1312b of the discharge electrodes 1319 other than the corner portions 1313a and 1312a, since the voltage difference between the corner portions 1313a and 1312a of the discharge electrodes 1319 is less than the voltage difference between the portions 1313b and 1312b of the discharge electrode 1319 other than the corner portions 1313a and 1312a, a strength of an electric field generated between the pairs of the corner portions 1313a and 1312a is less than a strength of an electric field generated between portions 1313b and 1312b of the discharge electrodes 1319 other than the corner portions 1313a and 1312a. As a result, the discharge is less concentrated in the corner portion 1331 of the discharge cell 1326 and the discharge can uniformly occur on inner sidewalls of the discharge cell 1326.
Referring to
In addition to the modified examples, various modified examples of the PDP can be provided, for example, a PDP in which each of barrier ribs are formed in a integrated body and corner portions are made of a material having a higher resistivity.
Unlikely a conventional PDP in which pairs of sustain electrodes are not disposed in a front panel, in a PDP according to the present invention, discharge electrodes are disposed in barrier ribs to surround discharge cells and due to this characteristic structure, it is not necessary to dispose a dielectric layer or a protective layers, etc. on the front panel, through which visible light generated by fluorescent layers in the discharge cells is transmitted.
Thus, in the PDP according to the present invention, the visible light can be directly transmitted through a front substrate, thereby significantly increasing light transmittance.
Furthermore, since the pairs of sustain electrodes are formed on a rear surface of the front substrate in the conventional PDP, the majority of the sustain electrodes must be formed of ITO, which is highly resistive, in order to allow the generated visible light to be transmitted through the front substrate. Thus, a driving voltage of the conventional PDP increases and since the high resistance of the ITO electrodes causes a voltage drop, images cannot be uniformly displayed when the conventional PDP is large. However, since the discharge electrodes are disposed in the barrier ribs in the PDP according to the present invention, the discharge electrodes can be made of a highly conductive material, thereby overcoming the above problems.
In addition, in the conventional PDP, the pairs of sustain electrodes are formed on the rear surface of the front substrate, and the discharge occurs behind the protective layer in the discharge cells and diffuses within the discharge cells. Thus, luminous efficiency is reduced. When the conventional PDP is used for a long time, charged discharge gas induces ion sputtering of the fluorescent material in the fluorescent layers due to the electric field, thereby resulting in permanent after-images. However, in the PDP according to the present invention, the discharge uniformly occurs on inner sidewalls of the discharge cells and concentrates in the centers of the discharge cells, thereby increasing discharge efficiency and especially, the discharge is prevented from concentrating in the corner portions, thus increasing efficiency of the PDP.
As a result, the PDP according to the present invention can be driven at a low voltage and has an advantage of low production costs.
While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various modifications in form and detail can be made therein without departing from the spirit and scope of the present invention as defined by the following claims.
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Number | Date | Country | |
---|---|---|---|
20050258747 A1 | Nov 2005 | US |