This application claims priority to and the benefit of Korean Patent Application No. 10-2007-0118519, filed on Nov. 20, 2007, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
1. Field of the Invention
The present invention relates to a plasma display panel (PDP), and more particularly, to addressing operations of a PDP.
2. Description of the Related Art
In a PDP, a plurality of discharge cells arranged as a matrix are interposed between upper and lower substrates that face each other. Discharge electrodes including scan electrodes and sustain electrodes for generating a discharge between them are formed on the upper substrate, and a plurality of address electrodes are formed on the lower substrate. The upper substrate and the lower substrate are bonded together to face each other, a predetermined discharge gas is injected between the upper and lower substrates, and phosphors coated in the discharge cells are excited by generating a predetermined discharge pulse between the discharge electrodes so as to generate visible light, thereby realizing a desired image.
In order to realize gradation (e.g., colors, gray levels, or brightness) of images in the PDP, an image frame is divided into several sub-fields each having a different light emission level, thereby performing time-division driving of the PDP. Each of the sub-fields is divided into a reset period to uniformly generate discharges, an address period to select discharge cells, and a sustain period to realize gradation of images according to the number of discharges. In the address period, a kind of auxiliary discharges are generated between the address electrodes and the scan electrodes, and wall voltages are formed in the selected discharge cells so as to form a suitable environment for sustain discharges.
In general, in the address period, a higher voltage is required for an address discharge as compared to a sustain discharge. Reducing an input voltage (that is, the address voltage) for addressing and ensuring a sufficient voltage margin are essential for improving the driving efficiency of the PDP and for increasing discharge stability. Moreover, with the development of display devices such as full-HD resolution devices, the power consumption required in a circuit board increases as the number of address electrodes allotted for discharge cells is increased in proportion to the number of discharge cells. In addition, a high xenon (Xe) display, in which a partial pressure of Xe in the discharge gas injected into the inside of the PDP is increased, has high luminous efficiency but requires a relatively high address voltage for firing a discharge. Thus, in order to realize a high-efficiency PDP display, a sufficient address voltage margin should be provided.
Embodiments of the present invention provide a PDP with sufficient address voltage margin by reducing an electrical property difference between mixed phosphors.
Embodiments of the present invention provide a high-quality, high contrast display wherein noise brightness such as discharge light or background light is removed or reduced during an address discharge, except for light emission.
According to one embodiment of the present invention, there is provided a plasma display panel (PDP) including a first substrate and a second substrate facing each other; a plurality of barrier ribs on the second substrate between the first substrate and the second substrate forming a plurality of main discharge spaces and a plurality of auxiliary discharge spaces along a stepped surface of the barrier ribs; pairs of scan electrodes and sustain electrodes extending on the first substrate, the scan electrodes at locations overlapping with or adjacent to the auxiliary discharge spaces; a plurality of address electrodes for generating address discharges together with the scan electrodes; a plurality of phosphor layers respectively in the main discharge spaces; and a discharge gas in the main discharge spaces and the auxiliary discharge spaces.
Each of the barrier ribs may include a base unit and a protrusion unit protruding from the base unit, and the base unit may have a relatively large width in comparison to a width of the protrusion unit.
The barrier ribs may face the scan electrodes, and the auxiliary discharge space may be formed therebetween.
An electron emission material layer may be formed on the stepped surface of the barrier ribs. The electron emission material layer may also extend to the main discharge spaces. In addition, the electron emission material layer may continuously extend between the main discharge spaces and the auxiliary discharge spaces. The phosphor layers may respectively be on sections of the electron emission material layer in the main discharge spaces.
The main discharge spaces and the auxiliary discharge space may be adjacent and contiguous.
According to another embodiment of the present invention, there is provided a PDP including a first substrate and a second substrate facing each other; a plurality of barrier ribs on the second substrate between the front substrate and the rear substrate forming a plurality of main discharge spaces; pairs of scan electrodes and sustain electrodes extending on the first substrate; a dielectric layer covering the pairs of scan electrodes and sustain electrodes and having a plurality of grooves forming a plurality of auxiliary discharge spaces at locations overlapping with or adjacent to the scan electrodes; a plurality of address electrodes for generating address discharges together with the scan electrodes; a plurality of phosphor layers respectively in the main discharge spaces; and a discharge gas in the main discharge spaces and the auxiliary discharge spaces.
The barrier ribs may face the scan electrodes, and the auxiliary discharge spaces may be formed therebetween.
An electron emission material layer may be on top surfaces of the barrier ribs, the electron emission material layer defining the auxiliary discharge spaces. Also, the electron emission material layer may extend to the main discharge spaces. In addition, the electron emission material layer may continuously extend between the main discharge spaces and the auxiliary discharge spaces. The phosphor layers may be respectively formed on sections of the electron emission material layer in the main discharge spaces.
The main discharge spaces and the auxiliary discharge spaces may be adjacent and contiguous.
According to still another embodiment of the present invention, there is provided a PDP including a first substrate and a second substrate facing each other; a plurality of barrier ribs on the second substrate between the first substrate and the second substrate, each of the barrier ribs including a base unit and forming a plurality of cells and a protrusion unit protruding from a part of the base unit, wherein a width of the protrusion unit is narrower than a width of the base unit; pairs of scan electrodes and sustain electrodes alternately arranged on the first substrate; a plurality of phosphor layers respectively located at at least a part of the plurality of cells; and a discharge gas in the plurality of cells. The scan electrodes overlap with at least parts of the base units
The protrusion unit protrudes from a part of the base unit that is distant from a center of an adjacent cell among the plurality of cells.
According to yet another embodiment of the present invention, there is provided a PDP including a first substrate and a second substrate facing each other; a plurality of barrier ribs on the second substrate between the first substrate and the second substrate forming a plurality of cells; pairs of scan electrodes and sustain electrodes extending on the first substrate; a dielectric layer covering the pairs of scan electrodes and sustain electrodes and having grooves at locations overlapping with or adjacent to the scan electrodes; a plurality of phosphor layers respectively located at at least a part of each of the plurality of cells; and a discharge gas filled in the plurality of cells.
The above and other features and aspects of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which:
Hereinafter, embodiments of the present invention will now be described more fully with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown.
The address electrode 122 is disposed on the rear substrate 120. The address electrode 122 performs an address discharge with the scan electrode Y. The address discharge represents a kind of auxiliary discharge that supports a display discharge by accumulating priming particles in each of the unit cells S before the display discharge occurs, thereby firing the display discharge. The address discharge occurs mainly in an auxiliary discharge space S2 that is formed by the barrier ribs 124. That is, the scan electrode Y and the address electrode 122 cross each other across the auxiliary discharge space S2 or at least at a location adjacent to the auxiliary discharge space S2, and a discharge voltage applied therebetween converges in the auxiliary discharge space S2 via the dielectric layer 114 covering the scan electrode Y and the barrier rib 124 on the address electrode 122, so that a high electric field that is sufficient to fire the discharge is formed in the auxiliary discharge space S2. The auxiliary discharge space S2 is not separately created by a wall structure but extends from a main discharge space S1, thereby forming a space along with the main discharge space S1. The priming particles formed in response to the address discharge in the auxiliary discharge space S2 diffuse to the main discharge space S1 and participate in the display discharge. The auxiliary discharge space S2 is defined by the barrier ribs 124 that have a step difference with the main discharge space S1, and has a discharge volume smaller than that of the main discharge space S1.
The address electrode 122 may be covered with a dielectric layer 121 formed on the rear substrate 120, and the barrier ribs 124 may be formed on a flat surface of the dielectric layer 121. Corresponding to a unit cell S, the barrier ribs 124 include a base unit 124a having a wide width on the rear substrate 120 and separated from the front substrate 110 by a gap (e.g., a predetermined gap), and a protrusion unit 124b having a narrow width and protruding from a location (e.g., a location no top surface near an edge) on the base unit 124a toward the front substrate 110, such that the barrier ribs 124 has a stepped shape in the unit cell S. The stepped shape of the barrier ribs 124 in the unit cell S defines the auxiliary discharge space S2 in which the address discharge is generated, wherein the stepped shape is formed from a top surface of the base unit 124a to the protrusion unit 124b. In order to store sufficient wall charges via the address discharge, the auxiliary discharge space S2 should have a volume that can hold an amount of discharge gas over a critical volume. The volume of the auxiliary discharge space S2 is determined according to an aspect ratio of the base unit 124a and the protrusion unit 124b that are parts of the barrier ribs 124. For example, when the protrusion unit 124b is too thin, it may create structural stability problems, and therefore, a width Wb of the base unit 124a may be large as compared to the width of the protrusion unit 124b. For example, a width of a barrier rib in an exemplary 50-inch full-high definition (HD) PDP television is 30-40 μm, the width Wb of the base unit 124a of the barrier ribs 124 may be equal to 60-80 μm, which is twice as wide as the width of the barrier rib in the exemplary PDP television. If the width Wb of the base unit 124a is excessively increased so as to exceed a proper range for a standard panel size, the discharge volume of the main discharge space S1 is relatively decreased so that brightness may deteriorate. A vertical height of the protrusion unit 124b associated with the volume of the auxiliary discharge space S2 should be over a critical value, e.g., 30 μm. The vertical height of the protrusion unit 124b corresponds to a discharge path of the address discharge, thereby affecting a firing voltage, and thus, the vertical height may be designed so as not to exceed a proper range, considering power consumption and allowed circuit rating.
The address electrode 122 and the scan electrode Y may cross each other across the auxiliary discharge space S2 or at least at the location adjacent to the auxiliary discharge space S2 so that the address discharge converges in the auxiliary discharge space S2. Here, the discharge voltage applied between the scan electrode Y and the address electrode 122 cause the address discharge through a discharge gap g between the dielectric layer 114 (or the protective layer 115) and the base unit 124a, to which an electric field of the scan electrode Y and an electric field of the address electrode 122 respectively reach. In order to shorten the discharge path of the address discharge, the scan electrode Y and the base unit 124a may be disposed to overlap each other, and in some embodiments, the scan electrode Y and the base unit 124a may be disposed so as to form width WO that is overlapping between the scan electrode Y and the base unit 124a.
The address discharge generated in the auxiliary discharge space S2 serves to supply the priming particles for firing the display discharge and does not directly provide light emission. When discharge light unavoidably occurring during the address charge is leaked with the light emission, the discharge light creates blurry noise brightness around an emitting pixel, thereby causing deterioration of the resolution of a display. Thus, in order to block the discharge light generated in the auxiliary discharge space S2, a black stripe (not shown) formed on the auxiliary discharge space S2 may be considered as a solution. However, in general, the bus electrode 112Y, which is a part of the scan electrode Y, may be made of a metallic conductive material, and thus, may directly block the light. Hence, forming the black stripe may not be essential. In this regard, according to the first embodiment of the present invention, since the main discharge space S1 for the display charge and the auxiliary discharge space S2 for the address charge are located at different locations, the discharge light can be easily blocked. Applying the black stripe to a selected location may be one option for blocking the discharge light generated in the auxiliary discharge space S2. However, in conventional technology, the display discharge and the address discharge are generated at the same location, and thus, blocking the discharge light is actually impossible or very difficult, thereby causing deterioration of display quality. In particular, in the conventional technology, visible light generated by phosphor excited by the address discharge creates background light that causes deterioration of a contrast characteristic of a display.
The first embodiment of the present invention structurally excludes a phosphor layer from the auxiliary discharge space S2 to which the address discharge converges, and thus, the background light caused by light emission due to phosphor excitation during an address discharge can be removed from the auxiliary discharge space S2, and thus an HD display having high contrast can be realized.
A phosphor layer 125 is formed over an inner wall of the main discharge space S1. For example, the phosphor layer 125 may be formed to cover the dielectric layer 121, a second side 124b2 of the protrusion unit 124b, and a side of the base unit 124a of the barrier ribs 124. The phosphor layer 125 interacts with ultraviolet light generated from the display discharge, thereby generating visible light of different colors. For example, by coating red (R), green (G), and blue (B) phosphors in the main discharge space S1, each main discharge space S1 or each of the unit cells S corresponds to one of the R, G, or B subpixels. The phosphor layer 125 is not coated on a top surface of the base unit 124a of the barrier ribs 124 and on a first side 124b1 of the protrusion unit 124b in contact with the auxiliary discharge space S2. Different phosphors including different materials have different electrical properties that may affect a sensitive discharge environment. For example, a surface potential of a G phosphor, which is based on zinc silicate such as Zn2SiO4:Mn, has a tendency to be charged with negative charges, while R and B phosphors such as Y(V,P)O4:Eu or BAM:Eu, etc., have a tendency to be charged with positive charges. Thus, in order to prevent or reduce the occurrence of a discharge interference of the phosphors and to form a uniform discharge environment, the phosphor is separated from a path for the address discharge. This is the reason why the phosphor layer 125 is not coated inside the auxiliary discharge space S2. In a conventional PDP, the phosphor is directly exposed to the environment for the address discharge, and thus, even when a uniform address voltage is applied to discharge spaces, voltages actually applied inside the discharge spaces may have variations according to an electrical property of the phosphor in the discharge spaces. That is, G phosphor (which has a tendency to be charged with negative charges) serves to decrease the address voltage while R and B phosphors (which have a tendency to be charged with positive charges) serve to increase the address voltage, and therefore, the voltages applied inside the discharge spaces are varied although the uniform address voltage is applied to the discharge spaces. As a result, the address voltage margin is reduced.
According to the first embodiment, the main discharge space S1, in which the display discharge is mainly performed, is separated from the auxiliary discharge space S2, in which the address discharge is mainly performed, and the phosphor is not coated in the auxiliary discharge space S2. Therefore, the address voltage applied from outside of the PDP may be uniformly transferred to each auxiliary discharge space S2 without being distorted by electrical property of the phosphor, and thus, the address voltage margin may be greatly increased. Compared to the conventional technology, the same address discharge effect may be obtained with a lower address voltage, and also, when the same address voltage is used, more priming particles may be stored and a discharge intensity in the subsequent display discharge may be increased.
The discharge gas is injected, as a source for generating ultraviolet light, inside the main discharge space S1 and the auxiliary discharge space S2. A multi-component gas, in which xenon (Xe), krypton (Kr), helium (He), neon (Ne), etc., capable of emitting suitable ultraviolet light by a discharge excitation are mixed in a suitable proportion by volume (e.g., a predetermined proportion), may be used as the discharge gas. A conventional method of using a high Xe discharge gas, in which a Xe mixture proportion is increased, has a high luminous efficiency. However, the conventional method requires a high firing voltage, thereby causing increase of driving power consumption, circuit re-design for increasing nominal power, etc. Considering the aforementioned problems, use of the conventional method is limited. According to the first embodiment of the present invention in which the address voltage margin is increased, sufficient priming particles for firing the discharge may be obtained, so that a high Xe PDP with increased luminous efficiency can be realized.
An electron emission material layer 235 is coated on a surface including a surface of the barrier ribs 124 and defines a boundary of the auxiliary discharge space S2, wherein the surface includes a top surface of the base unit 124a, and a first side 124b1 of the protrusion unit 124b. In the third embodiment, the electron emission material layer 235 is formed not only in the auxiliary discharge space S2 but also in the main discharge space S1. For example, as illustrated in
The scan electrode Y and the barrier ribs 224 may be arranged so as to form an overlapping area having a width WO between the scan electrode Y and a barrier rib among the barrier ribs 224. In one embodiment, for the scan electrode Y including the bus electrode 212Y and the transparent electrode 213Y, a width overlapping area is formed between the barrier rib 224 and the bus electrode 212Y to which a discharge voltage is largely converged. In an address discharge, the dielectric layer 214 (or the protective layer 215) for covering the scan electrode Y and the barrier ribs 224 on the address electrode 222 constitute opposite discharge surfaces facing each other, and a discharge is generated mainly (or converges) in the auxiliary discharge spaces S2.
Different from the stepped barrier ribs 124 of the first embodiment (see
The auxiliary discharge space S2 receives the address discharge generated between the scan electrode Y and the address electrode 222. Thus, since the auxiliary discharge space S2 is in contact with the main discharge space S1, priming particles created by the address discharge are supplied to the adjacent main discharge space S1. The auxiliary discharge space S2 should have a sufficient volume to receive a proper amount of a discharge gas so that sufficient priming particles may be supplied via the address discharge. A depth d and a width of the groove r should have appropriate values so that the groove r is not dielectrically broken down by a firing voltage applied from the outside, and a withstand voltage characteristic is sufficiently realized therein.
An electron emission material layer 335 may be formed on the top surface of the barrier ribs 224 contacting the auxiliary discharge spaces S2, and the electron emission material layer 335 reacts with a high electric field due to the applied discharge voltage and emits secondary electrons inside of the auxiliary discharge spaces S2, thereby accelerating firing of a discharge. The electron emission material layer 335 may include MgO nano powder, Sr—CaO thin film, carbon powder, metal powder, MgO paste, ZnO, BN, MIS nano powder, OPS nano powder, ACE, CEL, etc.
Method of Manufacturing Barrier Rib
A PDP according to the embodiments of the present invention does not include phosphor layers in some areas of unit cells S to which the address discharge converges, thereby preventing or reducing the discharge interference caused by the unique electrical property of the phosphor layer during the address discharge. Accordingly, the address voltage margin is increased, and discharge stability and sufficient discharge effect are obtained with a low address voltage, so that a high Xe plasma display with enhanced luminous efficiency can be obtained. Thus, the requirement for reducing power consumption of a full-HD display device can be satisfied.
Also, the embodiments of the present invention can remove or reduce the discharge light or the background light during the address discharge, so that the HD display has a high contrast.
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 changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims and their equivalents.
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10-2007-0118519 | Nov 2007 | KR | national |
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20090128035 A1 | May 2009 | US |