KR19980043083A - Window type plasma display plane device - Google Patents

Abstract

An object of the present invention is to improve the luminous efficiency of a conventional plasma display planar device by increasing the transmittance of visible light generated from a phosphor by opening a window to a planar sustain electrode that maintains plasma discharge in the plasma display planar device. In the conventional plasma display planar apparatus, in order to increase the transmittance of visible light generated from the phosphor, a transparent electrode is used and at the same time, the distance between the visual electrodes is widened. However, these cases have disadvantages of low transparency of the transparent electrode and high resistance of the transparent electrode. In addition, there is a disadvantage that the discharge voltage must be increased because the electrode spacing is wide. In order to reduce the discharge voltage, the present invention shortens the distance between the sustain electrodes and simultaneously opens a window to the planar electrode to make the transmissive surface of visible light as wide as possible to increase the luminous efficiency. In addition, the present invention has the effect of reducing the amount of heat generated in the circuit of the plasma display planar device by minimizing the resistance by using only the edge portion of the electrode as a transparent electrode, or using the entire electrode without using the transparent electrode. In this case, if the process of applying the transparent electrode is omitted, the manufacturing process is also reduced. In addition, in the case of installing a metal film having windows at both boundaries of the unit cell in addition to the existing pair of electrodes, not only the effect of widening the discharge space but also distinguishing the boundary of the discharge space and sharpening the contrast with the discharge space in the existing apparatus By replacing the black stripes installed to simplify the process, the process is simplified, the contrast with the discharge space is increased, and at the same time, the light emitting surface of the unit cell is as wide as possible. Therefore, this electrode structure is utilized for display devices such as large high-definition televisions.

Description

Window type plasma display plane device

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a plasma display flat apparatus, which has been shown in prototypes for large television screens since the mid 90s. In the conventional plasma display planar device, the discharge sustaining electrode is a window type to increase the luminous efficiency of the display device, lower the discharge sustaining voltage, and at the same time minimize the resistance of the circuit to reduce heat generated in the circuit.

1 is a configuration diagram of a unit pixel of a plasma display flat apparatus. The unit pixel is a discharge space emitting red, green, and blue light as one unit. The unit pixel has various sizes according to the size of the screen. On the back 1 plate, the back electrode 2 is provided on the back glass plate in the direction of the discharge tube 3. On it, a dielectric layer is formed by applying a dielectric for insulation during discharge. And the partition 4 is installed on it. Between the partitions, a phosphor for emitting red, green, and blue light is applied. The front plate is provided with a protective film to protect the dielectric layer after the discharge holding electrode (window type electrode in the present invention) 7 is applied to the windshield 8 and the dielectric is applied. Thus, the front plate and the back plate are combined to inject and seal the discharge gas into the internal discharge space.

The difference between the present invention and the conventional plasma display plane apparatus is that the discharge sustaining electrode 7 is adapted to a window type. In the conventional apparatus, the discharge holding electrode generates ultraviolet rays from the plasma in the discharge space, and when the ultraviolet rays excite the phosphor, visible rays are generated from the phosphor. This visible light is transmitted through the transparent protective film 5, the transparent dielectric layer 6, the discharge sustaining electrode 7, and the windshield 8. In this case, in order to increase the transmittance of light from the discharge sustaining electrode, a transparent material is applied to the electrode. This transparent material uses indium oxide. However, the light transmittance of the transparent electrode is low and the specific resistance is more than 100 times greater than that of metal materials such as silver, copper, and aluminum. Therefore, the low transmittance lowers the luminous efficiency and the high specific resistance of the transparent electrode is accompanied by the problem of heat generation in the circuit. In order to increase the transmittance of visible light, it is preferable to increase the distance between the discharge sustaining electrodes. However, when the distance between the electrodes is increased, the transmittance is improved because the voltage applied to both electrodes is increased, but the discharge efficiency is lowered due to the increase of the discharge voltage. Therefore, many researchers at home and abroad have been trying to solve the technical problem of increasing the discharge efficiency and lowering the discharge sustain voltage for many years.

The present invention is to install a window-type electrode structure by removing the light blocking area at the electrode surface in order to increase the transmittance of visible light while narrowing the gap between the electrodes as much as possible. This window structure can be installed in various ways. It is a window electrode structure consisting of two window-like electrode structure of the simple form as shown in FIG. The two window electrode structures of FIG. 2 are formed by removing light blocking portions of the electrodes from the electrode structures of the conventional plasma display flat apparatus. In either case, the width (a) of the window frame in the horizontal direction is made equal to or slightly narrower than the width of the partition wall, and the width of the window frame (b) on the edge surface between the two electrodes in the vertical direction is used to reduce the line width to minimize light blocking. Make it as small as possible. Therefore, b should be as small as possible in the manufacturing technology. If necessary, the edge window frame (b) inside the longitudinal positive electrode may use a conventional transparent material. However, in order to simplify the fabrication process, the entire electrode may be installed in a single process using metal materials such as silver, copper, and aluminum, provided that line width in (b) is minimized. The width c of the window in the transverse direction is the size of the distance d between the two electrodes, but is somewhat larger or smaller depending on the size of d. The distance e from both edges of the outer side of the electrode to the boundary of the unit pixel has an appropriate distance in consideration of the discharge of the neighboring pixel close to the discharge region. The size of all unit pixels is f. The driving method for maintaining the discharge is the same as the existing device. That is, it drives by applying an alternating voltage to both electrodes.

3 is a structural diagram of an electrode having a reduced number of window frames positioned on a partition wall in a horizontal axis direction. This figure is a case in which two window frames in the horizontal direction in Figure 2 is removed. This will prevent the light from being blocked because the window frame in the horizontal direction does not coincide with the bulkhead when assembling the front and the back, but this is eliminated in case the alignment is scattered during assembly.

FIG. 4 is an electrode structure having four windows in a unit pixel in a horizontal direction by coating the entire surface except a surface through which light is transmitted in a discharge space with a metal material. By blocking surfaces other than the effective discharge space, the contrast between the light generating portion and the non-generating portion in the discharge space is increased. In addition, unlike the conventional structure, the entire area including the edge of the unit pixel is used as a discharge space. That is, in FIG. 4, the pair of middle electrodes serve as the electrodes as in the conventional structure. Therefore, a voltage is applied to the two middle electrodes. Also, do not ground or apply power to two electrodes shared with neighboring pixels located at the boundary of both unit pixels. This is selected according to the driving method. The main discharge space will be between the two positive electrodes in the middle. However, the discharge space can be maximized by adjusting the distance between the center electrode and the electrodes at both interfaces. This can be applied to a high quality screen that minimizes the size of the unit pixel.

In FIG. 4, the width a of the window frame in the horizontal direction is the same as or smaller than the width of the partition wall as in FIG. 2 so that light is not blocked after assembly. The width b of the window frame in the vertical direction is as narrow as possible to minimize the blocking of light, and in some cases, transparent materials may be separately used to increase the transmission of light. However, if the purpose is to install the electrode structure in a single process, it may be installed using the same metal material. The width c of the horizontal window is made to be similar to the distance d between the two positive electrodes in consideration of the discharge space. The distance d between the center electrodes is appropriately selected in consideration of the discharge efficiency and the discharge start voltage. The spacing e between the electrodes on both pixel borders and the center electrode has an appropriate value smaller than d in consideration of the voltage difference between the anodes. That is, when AC voltage is applied to the center electrode and both pixel boundary electrodes are always grounded, e is designed to be almost the same size as d. In the case of a free electrode in which no power is applied to the electrode at the boundary, the discharge space can be increased by making e less than d in consideration of the voltage difference between both ends. In Figure 4 f is the size of the unit pixel. In the case of a large-screen high-definition television, f is made small and many windows are installed as shown in FIG. 3 to utilize the discharge space as much as possible. In addition, the number of windows in a manner similar to that of FIG. In the case of installing the electrode in a single process in such a window electrode structure, the manufacturing cost is reduced by simplifying the process. In addition, by using a metal electrode having a specific resistance of about 100 times less than the conventional transparent electrode, the resistance of the circuit is reduced, thereby reducing the heat generated in the circuit, thereby solving the problem of failure or lifespan of the plasma display flat panel device. In particular, the width of the window frame at the edge of the electrode is increased to provide a dual method of minimizing resistance.

FIG. 5 is a structural diagram of an electrode in which the inner window frame in the horizontal axis direction is removed in the same manner as in FIG. 3. This is because when the front plate and the back plate does not coincide with the partition wall of the window frame portion of the horizontal axis of the electrode is concerned to block the light and remove it.

The present invention aims to solve problems such as low luminous efficiency, high driving voltage, and heat generation, which are fundamental problems of the plasma display flat panel device, by modifying the structure of the discharge sustaining electrode in the conventional plasma display flat panel device. A window is provided on two existing discharge sustaining electrodes so that light emitted from the phosphor is directly transmitted through the window. In the structure of the conventional discharge sustaining electrode, to increase the distance between the electrodes in order to increase the transmittance of light, but in this case, there is a difficulty in increasing the driving voltage when the distance between the electrodes is widened. By providing a window in such a sustain electrode, even if the electrode gap is narrowed, there is no problem in the transmittance, and thus the driving voltage can be reduced to the maximum. The lower the driving voltage, the higher the discharge efficiency, and the higher the transmittance, the higher the discharge efficiency. In addition, the transparent electrode used in the existing device is a problem that the heat generation caused by the large circuit is a serious problem, but the purpose of solving the heat problem by reducing the resistance by using a metal electrode without using the transparent electrode. In addition, the structure of the window electrode has the effect of simplifying the process by eliminating the process of the transparent stripes and the process of the black stripe installed in order to distinguish the boundary between the unit pixel and the light emitting area of the screen. have.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flat panel display device used for high definition televisions and large screen televisions. Plasma display flat-panel devices related to this device were already developed by several Japanese electronics companies and were partially commercialized in '96. In Korea, a prototype was introduced in '96. However, at this stage, there are some technical problems in the popularization of the plasma display flat panel by full-scale commercialization, and it is difficult to popularize it without solving this problem. That is, it is a problem of low efficiency, high driving voltage, and heat generation. In general, it is preferable to widen the interval between the discharge sustain electrodes in order to increase the efficiency. At this time, however, the driving voltage becomes higher. In addition, the driving voltage must be increased to maximize the light emission. In this case, the current of the circuit increases and the problem of heat generation due to the circuit resistance becomes more serious, and at the same time, the problem of heat generation causes a damage to the circuit and encounters a problem of lifespan that is fatal to commercialization. It is this fundamental problem that is delaying the commercialization of plasma flat panel displays. The present invention seeks to solve these problems at once.

In the window type discharge sustaining electrode structure of the present invention, manufacturing techniques such as metal film installation steps are secured at home and abroad. However, it is good to increase the transmission of light by making the line width of the window frame at the edge between the discharge electrodes as small as possible. In the case of high-definition television, it is recommended that the line width be set to a size of 10 microns or less, and the production technology of such line width does not have technical problems at home and abroad. However, when assembling the front plate and the back plate, it is important to align the front and back so that the window frame in the horizontal direction of the front surface coincides with the partition wall. Therefore, the rear side of the window frame in the horizontal direction can be made smaller than the width of the partition wall or the number of window frames in the horizontal direction can be reduced to avoid the alignment problem during assembly.

1 is a configuration diagram of a unit pixel of a window electrode plasma display flat apparatus. On the back side, the back electrode is coated with a discharge tube with a metal on the back plate, and a dielectric layer is applied thereon. After the partition is installed, phosphors for red, green, and blue light emission are applied to the spaces between the partitions. On the front side, apply a discharge holding electrode to the front glass plate. In this case, the discharge sustaining electrode is applied using a transparent material in the conventional apparatus, and applied to the outer edges of both sides with a metal material smaller than the width of the transparent electrode in order to lower the resistance. In the present invention, the discharge holding electrode is replaced with a window as shown in the drawing. After the electrode is installed, a dielectric layer is applied and a protective film is applied to prevent damage of the dielectric layer during discharge. Thus, the front side and the back side are combined, gas is injected and then sealed. The present invention is different from the structure of the discharge sustaining electrode in that the discharge sustaining electrode has a window shape as shown in the drawing.

2 is a schematic diagram of two window electrode structures. a shall be provided with a width equal to or less than the thickness of the bulkhead. The size of b, the thickness of the window frame at the inner edge of the positive electrode, should be as narrow as possible, and the thickness e on the outside should be larger than b. c is the width of the window. The spacing d of the positive electrode has a suitable spacing as narrow as possible to make the driving voltage as low as possible. f is the total length of the unit pixel.

3 is a view of reducing the number of window frames on the top of the partition wall in the horizontal axis direction in the two window electrode structure. That is, in FIG. 2, when the window frame does not match the partition wall, the window frame of the horizontal side is removed to prevent blocking of visible light.

4 is a schematic diagram of four window electrode structures. a is installed in the same size as the thickness of bulkhead. The longitudinal window frame thicknesses b of the two inner electrodes and the two outer edges are installed as small as possible to minimize the blocking of visible light. c is the width of the window. The interval between the inner two electrodes is d, and the interval between the outer two electrodes and the inner electrode is e. The outer two electrodes are installed so that the boundary line of the unit pixel and the center line of the vertical axis coincide. The length of the entire unit pixel is f.

5 is a structural view of four window electrodes with a small number of window frames. This is to prevent the blocking of visible light when the window frame in the horizontal axis direction is not aligned with the bulkhead line in FIG. 4.

[Description of symbols on the main parts of the drawings]

One ; Back, 2; Back electrode, 3; Discharge tube, 4; Bulkhead, 5; Protective film, 6; Dielectric layer, 7; Window electrodes, 8; Windshield

No identifier above

It is possible to commercialize and popularize high-definition television and various large-screen flat panel display devices using plasma discharge. It solves the fundamental problem of the plasma display flat panel apparatus which has been showing the line since the middle of '90, and has the effect of low cost and efficiency increase in the manufacturing process.

Claims (3)

In order to increase the transmittance of light in the discharge holding electrode of the plasma display flat panel device and to minimize the distance between the electrodes in order to lower the discharge holding voltage, the window-shaped electrode structure is removed by removing the light blocking part of the flat electrode. Device. A device having a multi-window electrode structure in which a plurality of window-type metal electrode surfaces are provided, including an interface of a unit pixel, to expand a discharge space in a p-window-type discharge sustaining electrode of a plasma display flat panel device. In the window-type electrode structure that removes the light blocking by the electrodes in the plasma display flat panel device, the width of the window frame in the horizontal direction is smaller than the width of the partition wall or the number of the window frames is reduced to avoid alignment problems when assembling the front and the back. Device of window frame type electrode.