The present invention relates to the structure of a field emission display. The feature is related to the reflection layer settled on the insulating supporting device between the cathode and the anode with a special effect of raising the brightness of the field emission display.
There are various kinds of flat panel display (FPD) including, for example, field emission display (FED), liquid crystal display (LCD), plasma display panel (PDP), organic light emitter device (OLED), and liquid crystal projection display. The common features of such displays are that they are thin and light weight. According to the property of every flat panel display, some of them can be applied on the small scale panel for devices such as cellular phones; only a few are suitable for application in medium or large scale devices such as computer monitors or TV displays. Yet another application for flat panel displays further comprises super large scale display device such as an outdoor digital exhibition board. But the technologies of every kind of flat panel display are all progressing toward the object of high display quality together with large scale display and extended service life for application.
One of the rising new technologies for display is the field emission display developed in the recent years. The major feature is its self-emitting ability, which makes it superior to the LCD (lacking a self-emitting ability). Further the other benefits of large watching angle, low power consumption, high response efficient and the wide operation temperature can achieve the display quality like a traditional cathode ray tube (CRT). But the FED is lighter and thinner than the CRT. In addition, the recently developed new technology of nano-carbon-tube to be used on the FED area can promote the development of the FED.
A traditional three-electrodes FED 1a is shown in
The above-described FED, however, excites the phosphors layer 13 to radiate light at a low voltage. The anode voltage is generally applied below 5 KV and this is very little compared to the anode voltage (at least higher than 20 KV) of the anode of CRT. So the emitting energy of the electrons of the cathode is still limited and the lighting brightness is limited, as well. For the brightness issue is also being presented, such as high density of nano-carbon-tube for raising the electrical current density, high efficiency low voltage phosphors layer, and the improvement of driving electrical circuit. One of the useful method is to set a reflection layer 14 to raise the radiating efficiency of the phosphors layer.
The above-mentioned method of reflection layer can be illustrated by a certain CRT application. The electron emitter has a certain distance to the anode screen. For example, from referring to the conventional 17-inch CRT, the certain distance is at least 200 millimeters. The certain distance allows speed of the electrons from the cathode to be enhanced and to strike to phosphors layer with 20 KV. Regarding the raised emission efficiency and the uniformity of the phosphors layer 82, reference is made to
For the above reason, another conventional technique from the Taiwan Patent in Pub. No. 289126 discloses a special structure in
In recent years, a new style of support device in the display panel is frequently applied in the LCD display panel as a layer separating device.
First, since the conventional supporting devices are small, the location arranging machine must be highly precise, which makes location of the supporting device very difficult. Second, the supporting device may cause pollution by the attachment of the fixing chemical since the conventional supporting device must touch the fixing chemical to attach to the display panel. The next process is to heat the panel to fix the display panel. But the attachment process may contaminate the display panel. In addition, the sintering process on the display panel may cause the fixing chemical to evaporate and further contaminate the display panel. From the description of these shortcomings of the conventional supporting device, it is evident that a new device should be developed to resolve the above problems and reduce the manufacturing cost.
The inventor has developed a new structure by modify the insulating supporting device 38 with coating a reflection layer 44. The modification provided by the inventor supports between the anode and the cathode and enhances the brightness of the phosphors layer. Additionally, the settling cost of the present invention is low because the process is simple. The conventional machine for the location arrangement of the supporting device is not required.
The prior art uses a low actuating power voltage of less than 5 KV. This is the major reason for the low efficiency of the phosphors layer. The conventional technical uses the reflection layer to raise the lighting efficiency, but the manufacturing process is very complex. In addition, in another conventional technique, contamination of the display panel is not easily prevented. The present invention thus provides a new insulating supporting device 38 with the reflection layer to raise the lighting efficiency of an FED. The installation process of the insulating device of the present invention is very easy. The insulating device of the present invention is also easy to manufacture independently with a low failure rate in quality.
The major purpose of the present invention is to provide an insulating supporting device 38 to raise the brightness of the FED.
Another purpose of the current invention is to provide a manufacturing method of an insulation supporting device 38 with the reflection layer. The insulation supporting device 38 can be manufactured independently and then installed in the FED by packaging.
The further purpose of the present invention is to provide a packaging method for an insulation supporting device 38 with the reflection layer. The insulation supporting device 38 can be applied in an FED without affecting the air guiding path and to fit the vacuum packaging process.
The structure of the present invention of field emission display with the reflection layer comprises an anode structure having a phosphors layer, a cathode structure having a nano-carbon-tube layer and an insulation supporting device located between the anode structure and cathode structure. The reflection layer faces the phosphors layer to reflect the light emitted from the phosphors layer.
The various objects and advantages of the present invention will be more readily understood from the following detailed description when read in conjunction with the appended drawings:
The present invention provides an insulation supporting device 38 with a reflection layer. Reference is made
The manufacturing method of the present invention is described as follows. First, the insulation supporting device 38 with a plurality of holes therein is formed by spluttering or evaporating a reflection layer 44 on one side of the insulation supporting device 38. The main feature of FED of present invention can thus be produced by the above method.
The major feature of the present invention is insulation supporting device 38 and its assembly method is not the same as that of the conventional method in which it is directly inserted into the gap between the anode and the cathode. The assembly method according to the present invention adds an interference rib 39 on the side of cathode structure 20 (with the electron emitting layer 36) or anode structure 10 (with the phosphors layer 41). The interference rib 39 is formed to relate to the connection area between the holes of the insulation supporting device 38 for the function of additional support to provide an air or vacuum-flowing gap for the FED panel package. The air gap allows the residual air to escape from the cells (or the holes of the insulation supporting device 38) of the anode or the cathode during the packaging process of the FED. Another important assembly method is to attach the fixing chemical to the extra area 43 of the FED panel. The fixing chemical includes organic glue and binding material. The organic glue is for temporary fixing and the binding material is for binding the FED panel through sintering. The assembly process of the insulation supporting device 38 is to fix it between the anode and the cathode then to perform a heating process for sintering. The binding material can be the general glass glue to be applied in the sintering process for the binding of anode and the cathode. In addition, the alignment mark is designated to be formed on the insulation supporting device 38 to calibrate the position of the anode structure 10, cathode structure 20, and the insulation supporting device 38. The reflection layer 44 of the insulation supporting device 38 is formed on the side to face the phosphors layer 41 of the anode structure 10. From the application of the alignment mark, the cell in the cathode and the anode can fit the position of the holes on the insulation supporting device 38. Then the organic glue temporarily secures the calibrated components. Finally, the sintering process is performed on the fixing calibrated components by heating at a high temperature to bind the insulation supporting device 38 to the cathode structure 20 and the anode structure 10.
The electron emitting layer 36 (nano-carbon-tube layer), is described with the following application as the embodiment.
The insulation supporting device 38 of the present invention can be made of the glass material with a thermal expansion modulus of 82×10−7–86×10−7/° C, which is similar in range to that of the expansion modulus of the cathode plate 35 and anode plate 31. The outline dimension of the insulation supporting device 38 is designated by the FED panel size and multiple alignment marks are usually formed to fit the anode structure 10 and the cathode structure 20 at calibration. The holes in the insulation supporting device 38 are arranged relative to the cells array of anode structure 10 and the cathode structure 20. Reference is also made to
The basic structure of the present invention is described as comprising an anode structure 10 having a phosphors layer 41, a cathode structure 20 having the nano-carbon-tube layer 36 (electrons emitting layer 36) and an insulation supporting device 38 located between the anode structure 10 and cathode structure 20. The reflection layer 44 faces the phosphors layer 41 to reflect the light emitted from the phosphors layer 41.
Various embodiments will be described in the following. The cathode structure 20 may comprises the gate electrode layer 37 between the nano-carbon-tube layer 36 and the insulation supporting device 38. Additionally the phosphors layer 41 can be formed by screen printing or spray coating. The nano-carbon-tube layer 36 is formed by screen printing or spray coating (by spray nozzle) as well. The nano-carbon-tube layer 36 comprises the property-improved (with a high degree of electron emitting efficiency) nano-carbon tube. In addition, the insulation supporting device 38 has a plurality of holes 42 and every nano-carbon-tube layer 36 in cell shape is placed in the holes 42. The present invention can further comprising an interference rib 39 placed in the insulation supporting device 38 and the anode structure 10; the interference rib 39 forms many air (vacuum) communication paths connecting to every of the holes 42. The reflection layer 44 can also be made of aluminum or chromium. For uniform expansion, the insulation supporting device 38 is made of glass with a thermal expansion modulus of about 82×10−7–86×10−7/° C. For sintering, a binding material containing glass is used to package the cathode structure 20 and the anode structure 10.
The benefits of the FED structure of the present invention are described in the following. The manufacturing process of the insulation supporting device is simple and can be manufactured independently. Additionally, the structure of the present invention can be manufactured without using the supporting post placing machine. The process is very simple for the insulation supporting machine. Further, the major benefit of the main feature of the reflection layer on the insulation supporting device is to reflect the light (deflected or reversed) emitted from the phosphors layer. The brightness can be raised with an obvious period.
Although the present invention has been described with reference to the preferred embodiment thereof, it will be understood that the invention is not limited to the details thereof. Various substitutions and modifications have suggested in the foregoing description, and other will occur to those of ordinary skill in the art. Therefore, all such substitutions and modifications are intended to be embraced within the scope of the invention as defined in the appended
Number | Name | Date | Kind |
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6181061 | Inoue | Jan 2001 | B1 |
6674242 | Kastalsky et al. | Jan 2004 | B2 |
6727642 | Cho et al. | Apr 2004 | B1 |
20050082964 | Konishi | Apr 2005 | A1 |
Number | Date | Country |
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289126 | Feb 1993 | TW |
Number | Date | Country | |
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20050194886 A1 | Sep 2005 | US |