1. Field of the Invention
The present invention relates to a backlight for a liquid crystal display device.
2. Description of the Prior Arts
A liquid crystal display device has recently been used as a display device for a wide variety of electronic devices such as a television set, portable terminal, personal computer, electronic notebook and camera-integrated VTR, since it has a thin size, light weight and reduced power consumption. Different from a Brown tube or plasma display, the liquid crystal display device does not emit light but it displays an image or the like by controlling a quantity of light incident from the outside. In such a liquid crystal display device, a backlight for a liquid crystal display device for lighting the liquid crystal display device is provided on its backside (see Japanese Unexamined Patent Application No. 6-242439).
In a circumstance that reduced power consumption has been regarded as important in the aforesaid electronic devices, it has been said that the backlight for a liquid crystal display device holds about a half of the total power consumption of the aforesaid electronic devices. Consequently, it is important to reduce power consumption of the backlight for a liquid crystal display device. On the other hand, a demand for reducing power consumption of the backlight for a liquid crystal display device has been more and more increased when a size of a display screen of a liquid crystal television set, for example, has been increased. In view of the technical background of the backlight for a liquid crystal display device, the inventor has intended to reduce power consumption of the backlight for a liquid crystal display device and simultaneously has made an earnest study of a backlight for a liquid crystal display device that can light a liquid crystal display device with high intensity.
A backlight for a liquid crystal display device uses a cold cathode tube. Its required brightness is 10,000 cd/m2 in a typical backlight for a liquid crystal display device. In order to obtain this required brightness regardless of the screen size, an arrangement of a so-called directly-below type has to be adopted wherein an arc tube is arranged immediately below the backside face of the liquid crystal display device, since the required brightness cannot be obtained by a so-called edge-light type backlight wherein an arc tube (cold cathode tube) is arranged at the side face of the liquid crystal display device for lighting the liquid crystal display device by using a reflection plate, light-guiding plate, diffusion sheet, prism sheet or the like.
In the directly-below arrangement, plural straight-tube type arc tubes are arranged in lines or arc tubes are meanderingly arranged. However, even in the directly-below type backlight, the luminous brightness of the arc tube itself is low, so that a large quantity of luminous power is still consumed in order to obtain the required brightness. Further, it is necessary to increase the installation density of the arc tube or increase its number to be arranged in order to obtain the required brightness involved with the increased size of the liquid crystal television set. Therefore, power consumption has been rapidly increased.
Moreover, there are many components to compose the backlight since it is required to provide the diffusion sheet or diffusion plate for diffusing the emission of light in both the edge-light type backlight and the directly-below type backlight, thereby entailing a disadvantage of increasing production cost.
The present invention is accomplished in view of the technical background of the conventional backlight for a liquid crystal display device. The subject that should be solved by the present invention is to provide with low cost a backlight for a flat panel liquid crystal display device wherein the number of components such as a costly diffusion sheet required in the edge-light type or directly-below type is reduced, to thereby be capable of lighting the liquid crystal display device in a plane manner without non-uniformity in illumination with reduced power consumption and high luminous brightness.
A backlight for a liquid crystal display device according to the present invention is a flat panel type for lighting the backside face of the liquid crystal display device and has a panel case provided with a flat panel section that is divided into plural light-emitting areas, plural phosphor-coated anodes each arranged at the inner face of the flat panel section so as to correspond to each of the light-emitting areas and plural linear cathode sections each arranged so as to be opposite to each of the plural phosphor-coated anode sections in the panel case, wherein each of the plural linear cathode sections has a conductive wire arranged so as to extend linearly in the direction generally parallel to each of the plural phosphor-coated anode sections and a field electron emitter composed of a carbon-based film formed at the outer peripheral surface of the conductive wire, wherein each field electron emitter of each of the plural linear cathode sections is provided so as to be capable of radially emitting electrons toward each of the plural light-emitting areas.
Preferably, the carbon-based film is carbon nano-wall, and the conductive wire has a generally circular section, wherein the carbon nano-wall is formed at the whole outer periphery of the conductive wire with a generally uniform thickness so as to provide a high orientation.
Preferably, the carbon-based film is carbon nano-wall having collectively and continuously formed wall-like section composed of a great number of nano-order carbon flakes, wherein the wall-like section is used as a wall-like section for emitting electrons.
The present invention pays an attention to a field electron emission type fluorescent tube as an arc tube. Different from the cold cathode tube, the field electron emission type fluorescent tube has no rare gas or mercury vapor therein, that means it is in a vacuum state or in a generally vacuum state. Therefore, it has advantages of being environmentally friendly, being thin-sized capable of increasing the installation density since the tube wall is not heated, having high luminous efficiency and high luminous brightness, having a long service life to thereby obtain high reliability, or the like.
The backlight for a liquid crystal display device of the present invention can light the liquid crystal display device without a need for arranging plural arc tubes in lines or arranging a diffusion sheet or the like in order to eliminate luminous unevenness.
The above-mentioned “linear” is not limited to a straight line shape, but includes a curved line such as a spiral shape or wave-like shape, a shape wherein a curved line and straight line are mixed, and other shape. Further, it does not matter whether it has a solid-core or is hollow. Further, its sectional shape is not particularly limited. Specifically, its sectional shape is not limited to a circle, but may be an ellipse, rectangle or other shape. The above-mentioned “field concentration assigning concave/convex sections” include from field concentration assisting concave/convex sections each having a visible size made of projections or grooves to field concentration assisting concave/convex sections each having a microscopic size formed by surface roughness or the like. Its size does not matter. Further, the forming direction of the concave/convex sections may be a circumferential direction or longitudinal direction of the conductive wire. They can be made by spirally forming the concave/convex sections in the circumferential direction of the conductive wire. Further, they can be made by forming a great number of microscopic ribbed concave/convex sections in the longitudinal direction of the conductive wire. The carbon-based film includes a film made of carbon-nano material having a tube shape, wall shape or other shape. The shape having somewhat roundness can be included in the above-mentioned “sharp” shape so long as it has electron emission property.
A backlight for a liquid crystal display device according to an embodiment of the present invention is explained in detail hereinafter with reference to the attached drawings.
With reference to FIGS. 1 to 5, numeral 20 denotes the entire liquid crystal television set. Numeral 21 denotes a liquid crystal television body, 22 a liquid crystal display device incorporated into the liquid crystal television body 21 and 23 a backlight according to the embodiment for lighting the backside of the liquid crystal display device 22.
The backlight 23 has a panel case 24, phosphor-coated anode section 25 and linear cathode sections 26.
The panel case 24 is encircled by a pair of opposing flat panel sections 27 and 28 and four side panel sections 29, 30, 31 and 32. The inside thereof is vacuum or generally vacuum. A technique for vacuum-pumping the inside of the panel case 24 or sealing the inside of the panel case 24 to be vacuum is well-known, so that its detailed explanation is omitted. One flat panel section 27 faces to the backside of the liquid crystal display device 22. This flat panel section 27 is divided into plural light-emitting sections, e.g., three light-emitting sections A1, A2 and A3 in the embodiment, for lighting the backside of the liquid crystal display device 22. The flat panel section 27 is made of a glass, preferably a soda lime glass. The other flat panel section 28 is on the backside with respect to the flat panel section 27. This flat panel section 28 and side panel sections 29, 30, 31 and 32 are made of the same glass as of the flat panel section 27 and formed integral with the flat panel section 27. The material for the flat panel case 24 is not limited to the glass. Any material is usable for the flat panel case 24 so long as it transmits emitted light so as to light the backside of the liquid crystal display device 22. A material excellent in light transmittance is preferable for the material for the panel case 24.
A phosphor-coated anode section 25 is formed at the inner face of the flat panel section 27. The phosphor-coated anode section 25 has at least a two-layer structure of a phosphor layer 25a and anode layer 25b. The phosphor layer 25a is applied on the inner face of the flat panel section 27. The anode layer 25b is deposited on the phosphor layer 25a by a vacuum deposition or sputtering method. An anode terminal 25c is for drawing the anode layer 25b of the phosphor-coated anode section 25 to the outside. The phosphor material of the phosphor layer 25a is not particularly limited. A material that can emit white light is preferable for the phosphor material of the phosphor layer 25a. An aluminum thin film is preferable for the material of the anode layer 25b. The material of the anode layer 25b is not limited to aluminum. The material of the anode layer 25b may be ITO (indium tin oxide) that is a transparent electrode. The ITO can be formed by, for example, a sputtering. The phosphor-coated anode section 25 is formed so as to be flatly widespread on the inner face of the flat panel section 27. The phosphor-coated anode section 25 is divided into plural light-emitting areas A1 to A3 at the inner face of the flat panel section 27.
The phosphor-coated anode section 25 can be divided into plural phosphor-coated anode sections 25A1, 25A2 and 25A3 with respect to the light-emitting areas A1, A2 and A3, whereby it is composed of these plural phosphor-coated anode sections 25A1, 25A2 and 25A3.
Linear cathode sections 26A1, 26A2 and 26A3 are provided at the inner face of the flat panel section 28 so as to correspond to each of the phosphor-coated anode sections 25A1, 25A2 and 25A3. Each of the linear cathode sections 26A1, 26A2 and 26A3 preferably has a conductive wire 33 made of nickel.
The conductive wire 33 may have a great number of concave/convex sections formed on its outer peripheral surface for assisting a field concentration.
A carbon-based film 35 is formed on the outer peripheral surface of the conductive wire 33 with concave/convex formed or without forming concave/convex. The carbon-based film 35 has a great number of sharp microscopic sections serving as a field electron emitter. The carbon-based film 35 is made of carbon nano-wall. The concave/convex sections include concave/convex sections each having a visible size formed by a screw-thread cutting. The concave/convex sections include concave/convex sections each having a microscopic size formed by stretching the conductive wire 33. The concave/convex sections include, for example, spiral concave/convex sections in the circumferential direction of the conductive wire 33. The concave/convex sections include concave/convex sections along the longitudinal direction of the conductive wire 33. A technique for forming the concave/convex sections along the longitudinal direction of the conductive wire 33 include, for example, grinding the outer peripheral surface of the conductive wire 33 in the longitudinal direction by a grinder to roughen the surface to thereby form a great number of microscopic ribbed concave/convex sections. The concave/convex sections are preferably aligned in the circumferential direction or longitudinal direction of the conductive wire 33 from the viewpoint of stabilization of the electron emission. The size, shape or number of the concave/convex sections is not particularly limited. The conductive wire 33 may have conductivity. The conductive wire 33 is not limited to nickel.
Carbon nano-wall can be film-formed by a DC plasma CVD (chemical vapor deposition) method. This film-forming method includes the one wherein a conductive wire is arranged in the decompressed inner space of a tube-like member, into which hydrogen gas and carbon-based gas are introduced, whereupon DC power source is applied between the tube-like member serving as a cathode and the conductive wire serving as an anode to create a plasma column in the tube-like member, thereby film-forming carbon nano-wall on the surface of the conductive wire. The tube-like member includes the one wherein a lead wire is formed into a coil, a cylindrical member having both ends opened, and the one wherein the peripheral wall of the aforesaid cylindrical member is meshed or made into a fence-like shape. In this film-forming method, the voltage from the DC power source is 300 to 1000 V, preferably 500 to 800 V, and the pressure in the inner space is 10 to 10000 Pa, preferably 1000 to 2000 Pa. Since the conductive wire has a circular section and carbon nano-wall is film-formed with the conductive wire arranged at generally the center of the tube-like member in this film-formation, carbon nano-wall is film-formed at the outer peripheral surface of the conductive wire with generally uniform thickness, and further the carbon nano-wall is film-formed at the entire circumference of the outer periphery of the conductive wire so as to provide generally uniform and high orientation. Therefore, the carbon nano-wall can be film-formed with excellent electron emission characteristic.
The carbon nano-wall has a crystal structure close to graphite having high electrical conductivity. It is made of several tens of graphene sheet layers, wherein a wall-like section composed of a great number of nano-order carbon flakes is collectively and continuously formed in the plane direction. A high field concentration is caused by the voltage application at the top face of the wall-like section that is an end section, thereby emitting electrons. Carbon nano-wall is excellent in mechanical strength and has a stable electron emitting characteristic even at a relatively low temperature and under a low vacuum environment such as about 10−1 to 10−2 Pa.
When DC voltage or high-frequency pulse voltage is applied between each of the linear cathode sections 26A1, 26A2 and 26A3 and each of the phosphor-coated anode sections 25A1, 25A2 and 25A3 (phosphor-coated anode section 25), electrons are emitted so as to be radially widespread at an emission angle θ from the carbon-based film 35, that is the field electron emitter, of each of the linear cathode sections 26A1, 26A2 and 26A3 toward the corresponding phosphor-coated anode sections 25A1, 25A2 and 25A3. Each of the linear cathode sections 26A1, 26A2 and 26A3 are arranged opposite to each of the phosphor-coated anode sections 25A1, 25A2 and 25A3 with a predetermined gap, wherein the gap may have a size to a degree to which the electrons emitted from the carbon-based film 35 of each of the linear cathode sections 26A1, 26A2 and 26A3 at the emission angle θ can cover each light-emitting area of each of the phosphor-coated anode sections 25A1, 25A2 and 25A3. Each of the linear cathode sections 26A1, 26A2 and 26A3 has a conductive wire independent of each other in the embodiment. In another embodiment, the conductive wire 33 of each of the linear cathode sections 26A1, 26A2 and 26A3 may be linearly arranged in a line. The conductive wire 33 of each of the linear cathode sections 26A1, 26A2 and 26A3 may be formed by meandering or bending a single conductive wire in the panel case 24.
When DC voltage is applied between each of the phosphor-coated anode sections 25A1, 25A2 and 25A3 and each of the linear cathode sections 26A1, 26A2 and 26A3, an electric field is strongly concentrated on the sharp sections of the carbon-based film 35 that is the field electron emitter of each of the linear cathode sections 26A1, 26A2 and 26A3, whereby electrons penetrate through energy barrier due to a quantum tunnel effect to thereby be emitted into vacuum. The emitted electrons are attracted by the corresponding phosphor-coated anode sections 25A1, 25A2 and 25A3 to collide with the same, by which the phosphor present at the light-emitting area of each of the phosphor-coated anode sections 25A1, 25A2 and 25A3 is excited to emit white light that is visible light.
The experiment by the present inventor is described hereinafter.
The flat size of the panel case 24 is 90 mm in both length and breadth, and the thickness of the case is 10 mm. The length of each linear cathode section 26A1, 26A2 and 26A3 is 60 mm. A voltage of 10 kV (frequency of 3 kHz) was applied from the pulse power source between each of the phosphor-coated anode sections 25A1, 25A2 and 25A3 and each of the linear cathode sections 26A1, 26A2 and 26A3. The luminous brightness of the backlight according to the embodiment was 70,000 cd/m2 and the uniformity of the luminous brightness was more than 90% (measured points: 12 points) by this voltage application. Further, there was no deterioration in brightness after a long-period emission (720 hours) in the backlight of the embodiment. Moreover, there was no rise in the temperature at the surface of the panel case in the backlight of the embodiment.
Each of the linear cathode sections 26 has a circular section or elliptic section, so that electrons can be emitted in a 360-degree radiation manner from the whole outer peripheral surface. Further, when the size of the backlight 23 is reduced and the area thereof is increased, and further the number of the linear cathode section is decreased, the light-emitting area covered by a single linear cathode section is increased. Therefore, it is necessary to efficiently and stably emit electrons from the linear cathode section in order to obtain a backlight that can emit light with high intensity.
In this embodiment, carbon nano-wall, not carbon nano-tube, is used for an electron emitting material that is film-formed on the surface of the conductive wire composing the linear cathode section, whereby electrons can be emitted efficiently and stably from the linear cathode section and a backlight that can emit light with high intensity can be provided, as proved by the aforesaid experiment.
It should be noted that, as shown in
Number | Date | Country | Kind |
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JP 2004-247208 | Aug 2004 | JP | national |
Number | Date | Country | |
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Parent | 11076949 | Mar 2005 | US |
Child | 11245438 | Oct 2005 | US |