KR19990015280A - Triode type field emission display device - Google Patents

Abstract

PURPOSE: To provide a tripolar tube type field emission display device which forms a cathode from graphite to simplify the process and stabilize the properties of the cathode and emit electrons even at a low electric field.

Composition: Paste-shaped graphite fibers are screen-printed on predetermined portions of the upper surface of the negative electrode 4 formed on the substrate glass 2 in a predetermined pattern so that the graphite layers 6 are laminated, fired and fixed to the side edges. After the insulating layer 8 is applied to the upper surface of the negative electrode 4 except for the layer 6 and heat-fixed to fix, the upper surface of the negative electrode 4 is fixed. do.

Effect: As the electron-emitting material added to the negative electrode is screen-printed with a paste-like graphite fiber, it is simply formed without complicated and difficult deposition or laser upgrade, and the negative electrode thus formed is stable in physical properties such as gas ions or arc. It is durable against shocks, extending its useful life and generating sufficient electron emission at low electric fields.

Description

Triode type field emission display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a field emission display device, and more particularly, to a triode type field emission display device having a large amount of electron emission and a simple cathode formation process using graphite as a cathode material.

The field emission display device includes a structure in which a cathode and a phosphor are arranged between glass which is disposed to face each other and is hermetically sealed, and the cathode and the phosphor form a predetermined pattern, respectively. In such a configuration, when the emission surface of the cathode and the anode has a high voltage gradient, direct electron emission occurs due to the Schottky effect, and the generated electron emission excites the phosphor to emit light.

The field emission display device is known as a dipole and a triode according to its structure, and the triode has a configuration in which a grid is further added between the cathode and the anode.

The field emission display device is not only suitable for a large display device, but also has an advantage of low power consumption and high quality images.

In the field emission display device, the brightness of the screen depends on the amount of electrons emitted from the cathode, and the cathode having a large emission amount of electrons has a feature of maximizing its surface area by the uneven surface.

Initially, the cathode of the field emission display device has formed a high melting point metal thin film such as tungsten and molybdenum on a substrate and then etched it to form a sharp tip. However, this method requires a highly difficult process of exposing and etching delicately. Therefore, it is not suitable for the field emission display device having a wide screen. In addition, the tip formed as described above is vulnerable to the impact of gas ions or arc has a short service life and high operating voltage.

On the other hand, U.S. Patent No. 5,382,867 proposed by Maruo discloses a cathodic structure with a serrated surface, but this is a sawtooth of a complicated and difficult metal thin film, which still requires sophisticated exposure and etching operations. .

U.S. Patent No. 5,430,348 proposed by Kane discloses a structure in which an inversion layer is formed on a diamond faced cathode, while U.S. Patent Nos. 5,548,185 and 5,601,966 proposed by Kerma are Amor. A field emission display device using a pick diamond film is disclosed.

Diamond is one of the most stable materials composed mainly of carbon, which is a crystal having a (111) plane of tetragonal as shown in FIG. A broken bond of parts can be used as the electron emission path. In other words, when doping boron, nitrogen, etc. with impurities on the (111) plane generates a negative electron affinity phenomenon, the energy level of the conduction band is higher than the energy level of free electrons in the vacuum, resulting in spontaneous electron emission. The phenomenon is characterized by low voltage driving.

However, in order to form a diamond or a carbon similar to diamond as a cathode, plasma deposition is required to obtain a thin film of a predetermined thickness, which must be finely processed by laser upsizing. It acts as a factor that makes diffusion of the emission display element difficult.

On the other hand, graphite is a material composed mainly of graphite like diamond, and as shown in FIG. 5, the graphite includes a (0001) plane similar to the tetragonal system of diamond, but the direction of the (0001) plane is a strong double bond. It has a weak van der Waals bond between the surfaces, and has a physically strong anisotropy. In addition, the (0001) plane is good in conductivity, such as electricity, heat, but is not good in the right direction thereof, and also has the disadvantage of being easily broken due to the weak bonding state between the (0001) plane.

However, the surface of the graphite powder has a myriad of (0001) edges with strong covalent bonds, which can be used as natural electron emission tips.

In addition, even if the graphite powder is broken under external force, its fracture surface is still formed as a new corner of the (0001) plane, which has a kind of self-healing property, and thus electron emission can be continuously performed, and it contains some nitrogen impurities. As a result, the negative electron affinity phenomenon is caused, and low-field electron emission can be expected.

Accordingly, an object of the present invention is to provide a triode-type field emission display device capable of driving a low electric field while simplifying a process and stabilizing properties of a cathode by forming a cathode from graphite.

In accordance with the above object, the present invention is formed by laminating a negative electrode by ITO deposition or printing firing with silver paste on the inner surface of the substrate glass disposed opposite to the front glass having the positive electrode, and pasting the upper surface of the negative electrode. The coated graphite fibers are printed and coated in a predetermined pattern and fired so that the graphite layer is laminated on the upper surface of the negative electrode. Then, an insulating spacer is printed around the negative electrode, coated with a predetermined thickness, and heat treated to fix and then solidified. The silver paste is printed, coated and heat treated to arrange a grid of a predetermined pattern.

In the present invention having the above-described structure, a graphite fiber having a diameter of 1 to 5 µm and a length of 5 to 50 µm is used, and the ratio of the inorganic binder added to form the paste is 5 to 5 with respect to the graphite fiber. 30 weight percent is suitable.

According to the present invention having the above structure, electrons are emitted through the graphite layer. At this time, the graphite layer has the radiation characteristics of the conventional diamond thin film, so that the luminance is improved, and the graphite layer is Since it is formed by lamination by screen printing, the process is simple and easy, and the crystal structure newly exposed to the surface damaged by the impact of gas ions also becomes the same crystal as before it is broken, so the service life of the negative electrode is extended and graphite has There is an effect that driving at low voltage is possible by the negative electron affinity phenomenon.

BRIEF DESCRIPTION OF THE DRAWINGS The process figure explaining the process of manufacturing the substrate glass of the triode type field emission display element which concerns on this invention.

2 is a partial perspective view showing an example of coating on a stripe with graphite fibers;

Fig. 3 is a schematic side cross-sectional view showing the configuration of a triode tube flat panel display element according to the present invention.

4 is a crystal structure diagram of diamond;

5 is a crystal structure diagram of graphite.

* Description of the symbols for the main parts of the drawings *

2: substrate glass 4: negative electrode

6: graphite layer 8: insulation layer

10 grid 12 front glass

14 phosphor 16: positive electrode

The present invention having the above-described configuration will be described in detail with reference to preferred embodiments according to the accompanying drawings.

1 is a process chart showing an example of forming a cathode of a triode tube flat panel display device according to the present invention.

The silver paste is printed on the upper surface of the substrate glass 2 so that the negative electrode 4 is formed in a predetermined line shape. The silver paste is heat-treated after screen printing to be fixed on the substrate glass 2, and the graphite layer 6 is formed at predetermined positions on the upper surface of the negative electrode 4 thus formed.

The graphite layer 6 is formed by screen printing a paste-like graphite fiber, and the form is an arbitrary shape of a dot or stripe.

1 shows a dot shape, and when applied in a stripe shape, a laminated structure as shown in FIG. 2 is formed.

The graphite fiber is used as a paste in which 5-30% by weight of an inorganic binder is mixed with a cylindrical shape having a diameter and a length of 10 µm.

The graphite layer 6 formed and arranged in a predetermined pattern is baked and fixed, and then the insulating layer 8 described with reference to FIG. 1 is applied to the upper surface thereof. The insulating layer 8 is laminated by screen printing and heat-processing the paste of a glass component through the screen by which the part corresponding to the said graphite layer 6 is clogged.

The grid 10 is printed and coated above the insulating layers 8 thus stacked.

The grease 10 is formed by screen printing silver paste, which is arranged in a direction orthogonal to the negative electrode 4 and is fixed by heat treatment.

Fig. 3 shows the structure of the triode type field emission display device according to the present invention.

The substrate glass 2 is disposed to face the front glass 12 separately made and sealed.

On the surface of the front glass 12 that faces the substrate glass 2, a positive electrode 16 having a phosphor 14 coated on the top surface is formed.

The positive electrode 16 is formed by ITO deposition, and the phosphor 14 is line-patterned in the order of R, G, and B in order of a conventional thing applied to a cathode ray tube, and is applied and arranged by printing or electrodeposition.

The above-mentioned substrate glass 2 and the front glass 12 are sealed while being kept at a predetermined interval by an insulating spacer or the like, and sealed while being vacuumed inside to form a desired field emission display device.

In the field emission display device manufactured as described above, the distance between the negative electrode 4 and the grid 10 is 5 to 200 mu m, and the distance between the grid 10 and the positive electrode 16 is 10 to 2000 mu m.

Also in the degree of vacuum, 10 ^-6 Torr was satisfied, and the operating voltage was driven at 10 ⁶ V / cm. Such a characteristic of the present invention is that the spin type using a high melting point metal thin film as a negative electrode has to have a vacuum degree of 10 ^-8 Torr and an operating voltage of 10 ⁸ V / cm.

In operation, electrons emitted from the graphite layer 6 applied to the negative electrode 4 are attracted to the positive potential applied to the grid 10, and again to the positive potential applied to the positive electrode 16 of the front glass 12. It is attracted and impinges on the phosphor 14 applied thereon to excite it. Therefore, the phosphor 14 excited by the electrons emits light, and the light can be seen as an image from the outside through the front glass 12.

In the present invention, since the electrons are emitted through the graphite layer 6 while performing the function as the field emission display device, the emission amount is increased to improve the luminance.

In addition, even when the graphite layer 6 is damaged due to the impact of metal ions during operation, the crystal structure of the newly exposed fracture surface appears to be the same, so that the electron emission effect is homogeneous without deterioration.

As described above, the present invention forms an electron emitting material layer using graphite powder which can be screen printed, and the effects such as electron emission amount and low electric field driving are comparable to those of conventional expensive diamond thin films. The process is very simple and easy to reduce the equipment cost and cost required for manufacturing, and even if the damage caused by gas ions does not change the electrospinning characteristics of the newly exposed surface, the service life is long. In addition, even if the internal vacuum degree of the triode type field emission display device is significantly lowered, it is possible to have a characteristic of driving at a low voltage.

Claims (3)

The negative electrode 4 is laminated on the substrate glass 2 and screen-printed a paste-like graphite fiber on the upper surface thereof so that the graphite layer 6 is formed at predetermined positions, and then fired and solidified, and then the graphite layer ( The insulating layer 8 is applied to the upper surface of the negative electrode 4 except for 6) by a predetermined thickness, and heat-fixed, and then fixed. Then, the silver paste is printed and applied by heat-treating thereon to arrange the grid 10 of a predetermined pattern. A triode type field emission display device comprising one configuration. The tripolar electric field according to claim 1, wherein the graphite layer 6 is formed by mixing graphite fibers having a diameter and a length of about 10 mu m with a 5-30 wt% inorganic binder to form a paste. Emission indicator. 3. A tripolar tube type field emission display device according to claim 1 or 2, wherein the graphite fibers forming the graphite layer (6) are compression molded.