This application is a U.S. national phase application of PCT international application PCT/JP2004/017900.
The present invention relates to plasma display panels to be used in plasma display devices that are known as display devices featuring a large size screen, and yet, a thin body and a light weight
A plasma display panel (hereinafter referred to as PDP) displays videos by the following method: generating ultraviolet rays by gas discharge, then the ultraviolet rays excite phosphor to emit light.
The PDPs are divided into two types in terms of driving methods, namely, an AC driven PDP and a DC driven PDP, and two discharge methods are available in PDPs, namely, a surface discharge PDP and an opposed discharge PDP. Presently the AC driven and surface discharge PDP having three electrodes becomes a mainstream in the market, which requires PDPs of a higher resolution, easiness for increasing a screen size, a simpler structure, and easiness for manufacturing.
The AC driven PDP is formed of a front plate and a rear plate. The front plate comprises the following elements:
Each one of the display electrodes includes a transparent electrode and a bus electrode. The bus electrode is formed of a black electrode and a metal electrode made of mainly metal. The black electrode suppresses reflection of external light, and the metal electrode has a low resistance.
The PDPs have drawn attention recently among other flat panel displays because of the following advantages over liquid crystal display panels:
Japanese Patent Application Unexamined Publication No. 2002-83547 discloses a structure of the light blocking sections formed between each one of the display electrodes as well as the black layer as a structural element of the display electrode. The structure is this: a group of the electrodes is made of plural layers formed on a substrate, and one of the layers is made of a black layer having a higher sheet resistance than the other layers so that the one layer forms a black electrode. This black layer is integral with the light blocking sections.
However, when the black layer and the light blocking layer are commonly used as discussed above, electrostatic capacitance increases in the light blocking layer as a resistance of the black layer decreases, so that the power consumption increases. On the other hand, a greater resistance of the black layer increases an electric resistance of a transparent electrode, which is an element of the display electrode, so that the display characteristics are degraded.
The present invention addresses the problems discussed above, and aims to reduce the number of manufacturing steps and achieve PDPs that can display quality videos.
In order to achieve the foregoing objectives, the PDP of the present invention comprises the following elements:
The foregoing structure allows achieving a PDP excellent in display characteristics and consuming a fewer power and also being manufactured with a fewer manufacturing steps.
A PDP in accordance with an exemplary embodiment of the present invention is demonstrated hereinafter with reference to the accompanying drawings.
Front plate 2 of PDP 1 comprises the following elements:
Rear plate 10, on the other hand, comprises the following elements:
Front plate 2 and rear plate 10 are placed confronting each other such that display electrodes 6 are oriented orthogonally to address electrodes 12 with barrier ribs 14 in between. The front and rear plates are sealed together with sealant member, and space 16 therebetween is filled with dischargeable gas of Ne—Xe 5% at about 66.5 kPa (ca. 500 Torr). This structure allows the intersections of display electrodes 16 and address electrodes 12 in dischargeable space 16 to work as discharge cells 17 (each one of cells 17 is counted as a unit of light emitting area).
Next, structures of display electrode 6 and light blocking section 7 of the PDP in accordance with this embodiment are described hereinafter with reference to
Bus electrodes 4b, 5b are formed by laminating plural electrode-layers as follows: forming black layer 19 as an electrode layer on transparent electrodes 4a, 5a, then forming metal electrodes 20, 21 as electrode-layers on black layer 19. Black layer 19 is made of material including ruthenium tetroxide and having a comparatively high electric resistance. Metal electrodes 20, 21 formed on black layer 19 are made of material, such as silver, having a low resistance.
In non-dischargeable section 18 between display electrodes 6 adjacent to each other, light blocking section 7 integrally formed with black layer 19 as an electrode layer is prepared. In other words, when light blocking section 7 is formed in non-dischargeable section 18 between scan electrode 4 and sustain electrode 5 adjacent to each other, black layer 19 is formed such that it covers parts of scan electrode 4 and sustain electrode 5. As a result, light blocking section 7 is integrally formed with black layer 19 of bus electrodes 4b, 5b.
The foregoing structure allows forming light blocking section 7 integrally and simultaneously with black layer 19 of bus electrodes 4b, 5b. This structure is advantageous over the prior art, i.e. using material independently in separate steps of forming light blocking section 7 and black layer 19, so that the material can be used more efficiently and the number of steps can be reduced.
If the specific volume resistance of black layer 19 is less than 105 Ωcm in the foregoing structure, i.e. display electrodes 6 adjacent to each other are coupled with black layer 19, a portion of electric current leaks from between the adjacent display electrodes 6 via black layer 19 when the PDP is driven, thereby interfering with a driving voltage waveform of display electrode 6. As a result, discharge cells 17 cannot receive a predetermined voltage waveform, and the PDP thus cannot display videos excellent in picture quality.
However, since the PDP in accordance with this embodiment employs black layer 19 made of high resistance material and thus having a specific volume resistance not lower than 105 Ωcm, the interference with the driving voltage waveform is suppressed, and the PDP achieves excellent display characteristics. A smaller resistance of black layer 19 increases a electrostatic capacitance of light blocking section 7, so that the PDP consumes a larger power; however, the resistance value of black layer 19 of the present invention is high enough to suppress increasing the power consumption.
On the other hand, if the specific volume resistance of black layer 19 exceeds 109 Ωcm, the electric resistance between metal electrodes 20, 21 and transparent electrodes 4a, 5a becomes greater. When an electric current flows from metal electrodes 20, 21 to transparent electrodes 4a, 5a, a voltage drop across black layer 19 increases, so that discharge cells 17 sometimes cannot receive a voltage high enough to discharge, which adversely affects displaying videos. In such a case, an amount of the voltage drop across black layer 19, namely, a black electrode, is superimposed on a signal waveform, which is then supplied to metal electrodes 20 and 21, so that discharge cell 17 can receive a voltage high enough to discharge. In this case, both of the driving voltage and the power consumption are obliged to increase.
However, since the maximum specific volume resistance of black layer 19 in accordance with this embodiment is 1×109 Ωcm, so that the increases of both the driving voltage and power consumption can be suppressed.
As discussed above, the PDP of the present invention selects the specific volume resistance of black layer 19 from the range between 1×105 and 1×109 Ωcm.
The resistance values of black layer 19 in bus electrodes 4b, 5b or that in light blocking section 7 can be changed by a film thickness. An extraordinary thin film allows a portion of incident light into black layer 19 to transmit, which causes insufficient light blocking. As a result, an effect on improving the contrast is reduced. On the other hand, an extraordinary thick film makes it difficult to pattern electrodes when they are formed. The film thickness thus can be variable within the range of 1 μm-5 μm. On top of this, the selection of a specific volume resistance from the range of 1×105-1×109 Ωcm can suppress an adverse effect due to the change in resistance of black layer 19 and also an adverse effect due to the degrading of light blocking performance. The specific volume resistance of black layer 19 is adjustable with an additive amount of ruthenium tetroxide.
Next, a method of manufacturing the PDP in accordance with this embodiment is demonstrated hereinafter with reference to
First, form scan electrodes 4 and sustain electrodes 5 in a striped pattern on substrate 3 facing the front of front plate 2 of PDP1. To be more specific, form an ITO film by an electron-beam evaporation method on substrate 3 facing the front. The ITO film is the material of transparent electrodes 4a, 5a. Then apply resist thereon for patterning, and etch the film of transparent electrodes 4a, 5a. Finally, peel the resist for forming transparent electrodes 4a, 5a patterned. Meanwhile, SnO2 can be also used as the material of the transparent electrodes.
Next, form bus electrodes 4b, 5b and light-blocking section 7 on transparent electrodes 4a, 5a thus formed. To be more specific, using the following materials, form black layer 19 on substrate 3 facing the front by a screen printing method:
On black layer 19 thus formed, form a film of metal electrode by a screen printing method using the following materials:
As discussed above, the present invention allows forming black layer 19 of bus electrodes 4b, 5b in display electrode 6 and light-blocking section 7 simultaneously and integrally. As a result, the number of steps of manufacturing display electrodes 6 and light-blocking sections 7 can be reduced.
Next, cover the display electrodes 6 and light-blocking sections 7 thus formed with dielectric layer 8, which is made by the following steps: apply paste containing lead-based glass material by a screen printing method, then dry and fire the paste. After that, cover dielectric layer 8 with protective layer 9 which is made of MgO and formed through a film-forming process such as evaporation or sputtering.
On the other hand, rear plate 10 is formed of substrate 11 facing the rear and address electrodes 12 prepared, e.g. in a stripped pattern on substrate 11. To be more specific, apply a film of photosensitive Ag paste, which is the material of address electrode 12, onto substrate 11 facing the rear by a screen printing method, then provide the paste film with patterns by a photolithography method, and fire the paste patterned. Next, cover address electrode 12 thus formed with dielectric layer 13, which is made by the following method: apply paste containing lead-based glass material by a screen printing method, then dry and fire the paste. In stead of applying the paste by the screen printing method, laminate film-like molded pre-bodies of the dielectric layer, and fire the laminated pre-bodies for forming dielectric layer 13.
Next, barrier ribs 14 are prepared in a stripped pattern. Ribs 14 are formed by the following method: form a film of photosensitive paste, of which major ingredients are aggregate made of Al2O3 and glass frit, by a printing method or a die-coat method. Then provide the film with patterns by a photolithography method, and fire the patterned film for forming barrier ribs 14. Another method of forming ribs 14 is this: apply the paste containing lead-based glass material at given intervals repeatedly by the screen printing method, then dry and fire the paste. Spaces between each one of barrier ribs 14 are approx. 130 μm-240 μm in the case of HDTV having a screen size of 32-50 inches.
Between each one of barrier ribs 14, phosphor layers 15R, 15G and 15B are formed respectively, those layers are formed of respective phosphor particles of red, green and blue. Each phosphor layer is formed by the following method: apply paste-like phosphor ink which is made of phosphor particles of each color and organic binder, then dry the ink, and fire the dried ink at 400-590° C., so that the organic binder is burned off. As a result, phosphor particles of each color are bound to each other for forming phosphor layers 15R, 15G, and 15B.
Front plate 2 is overlaid with rear plate 10 thus manufactured such that display electrodes 6 of front plate 2 are oriented orthogonally to address electrodes 12 of rear plate 10. The edges of the plates overlaid with each other are framed up by sealing member such as sealing glass, which is then fired at 450° C. for 10-20 minutes to form an air-tight sealing layer (not shown), thereby sealing the two plates together. Evacuate dischargable space 16 to a highly vacuum condition (e.g. 1.1×10−4 Pa), then fill space 16 with dischargable gas (e.g. He—Xe based or Ne—Xe based gas), so that PDP 1 is completed.
The material of black layer 19 of the PDP in accordance with this embodiment contains black pigment, ruthenium tetroxide, and frit glass, and the specific volume resistance of black layer 19 can be adjusted with an additive amount of ruthenium tetroxide. That has been discussed in this embodiment. However, instead of the materials and method discussed above, the black pigment, metal conductive material, and the frit glass can be used for black layer 19, and the specific volume resistance can be adjusted with an additive amount of the metal conductive material, e.g. Ag powder. Black layer 19 is not necessarily colored in pure black, and it can be dark enough to achieve the light-blocking purpose.
In this structure, since light-blocking section 7 is electrically insulated from display electrode 6, interference with the driving voltage waveforms by display electrodes 16 adjacent to each other can be substantially suppressed. As a result, this structure allows black layer 19 to select materials of a lower resistance. However, use of a lower resistance material in black layer 19 increases an electrostatic capacitance of the area (area A in
In the foregoing embodiment, ruthenium tetroxide is used as conductive material of black layer 19; however, black conductive material is needed for forming light-blocking section 7, so that some oxide containing ruthenium can be used instead of ruthenium tetroxide.
In the case of using metal conductive material as the conductive material, Cu, Pd, Pt, or Au can be used in order to prevent the glass substrate from turning yellow.
Samples of the PDP in accordance with the present invention are tested for evaluating their display characteristics and power consumption. The samples have slits 22 between respective display electrodes 6 and light-blocking sections (LBS) 7, and specifications of black layer 19 are varied for the test purpose. Table 1 below shows the specification and test result of the samples:
1 × 10−1
1 × 1011
Based on the exemplary embodiment, each one of PDP samples No. 1-7 employs a black layer having a specific volume resistance different from each other. Respective samples No. 2-6 employ ruthenium tetroxide as the conductive material in their black layers but the ruthenium tetroxide content in respective layers differs from each other, so that the different specific volume resistance in each sample is achieved. Sample No. 1 uses ruthenium tetroxide, to which Ag powder is added, as the conductive material, and sample No. 7 does not include the conductive material.
Sample No. 8 is a conventional PDP, and black electrodes of bus electrodes 4b, 5b and light-blocking section 7 are not integrally formed, but they are respectively formed of material independently prepared.
The display characteristics and the power consumption at non-lighting of sample PDPs No. 1-No. 8 are compared. The non-lighting means that the entire screen shows black in color. The display characteristics means that respective samples are driven by a voltage which drives sample No. 8 (conventional PDP) to full display, and the display statuses are compared.
Use of black material having a resistance lower than 2×104 Ωcm, namely, in the case of samples No. 1-3, proves that the power consumption at non-lighting is greater than that of sample No. 8, and the power consumption increases at a lower specific volume resistance.
Use of black material having a resistance higher than 1×105 Ωcm, namely, in the case of samples No. 4-7, proves that the power consumption at non-lighting is approximately the same as that of sample No. 8, i.e. conventional PDP.
Use of black material having a resistance higher than 5×109 Ωcm proves that a voltage applied to discharge cells at portions of the screen is insufficient, thereby lowering the brightness. This phenomenon becomes conspicuous when the specific volume resistance is higher than 1×1011 Ωcm, namely, in the case of sample No. 7. The non-lighting areas thus spread over the screen.
The foregoing test proves that samples No. 4 and 5, which are made in accordance with the exemplary embodiment of the present invention, are excellent both in power consumption at non-lighting and display characteristics.
The present invention reduces the number of steps of manufacturing PDPs, and achieves PDPs excellent in displaying videos, so that the present invention is useful for display devices having a large screen.
Number | Date | Country | Kind |
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2003-395223 | Nov 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2004/017900 | 11/25/2004 | WO | 00 | 7/26/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/052976 | 6/9/2005 | WO | A |
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Number | Date | Country | |
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