KR100252408B1 - A fluorescent layer and a method for manufacturing the same - Google Patents

Abstract

PURPOSE: A fluorescent membrane of braun tube and a manufacturing method thereof are provided to improve a visibility of the screen by using a fluorescent membrane of braun tube and a luminescent principle of a luminous element. CONSTITUTION: An insulating membrane(21) is formed at the front plane of panel(20). A plurality of black matrixes are formed at the surface of insulating membrane at regular interval. An electronic fluorescent membrane(24) is sunk between the black matrixes. A plurality of CRT fluorescent membranes(25a,25b,25c) is formed at the electronic fluorescent membrane(24). The insulating membrane(21) consists ITO membrane(Indium Tin Oxide: SnO2 In2O3) having a conductivity. The electronic membrane(24) is LED or EL luminous element. The CRT fluorescent membranes(25a,25b,25c) are the green fluorescent membrane(25a), blue fluorescent membrane(25b) and red fluorescent membrane(25c).

Description

CRT fluorescent film and its manufacturing method

The present invention relates to a fluorescent film of a cathode ray tube (CRT) and a method of manufacturing the same, in particular a fluorescent film of a cathode ray tube suitable for improving the brightness of the screen using the fluorescent film of the cathode ray tube and the light emitting principle of the light emitting device; It relates to a manufacturing method.

In general, the operation principle of the CRT is to control the amount of the electron beam by applying an electrical signal to the cathode or the first grid, deflect the electron beam by an electron or electrostatic method, and focus and accelerate electrons emitted from the cathode by an electron gun. Thus, small bright spots are formed on the fluorescent surface to reproduce an image corresponding to an electric signal on the fluorescent surface.

Hereinafter, a fluorescent film manufacturing method of a conventional CRT will be described with reference to the accompanying drawings.

3A to 3D are structural cross-sectional views showing a conventional fluorescent film manufacturing method of a CRT.

As shown in FIG. 3A, after the photoresist is deposited on the entire surface of the panel 1 subjected to the cleaning process, the red, green, and blue regions are defined, a plurality of photoresist patterns having a predetermined interval using the exposure and development processes ( 2) form.

In this case, since the light transmission angles of the photoresist vary depending on red, green, and blue colors, a plurality of photoresist patterns 2 are formed according to red, green, and blue colors.

Subsequently, as shown in FIG. 3B, graphite is deposited on the entire surface including the photoresist pattern 2, and then the photoresist pattern 2 and the graphite are exposed to expose red, green, and blue regions through an etching process. It is selectively removed to form a plurality of black matrices 3 having a predetermined interval.

At this time, the etching process uses a sulfuric acid etching process.

Subsequently, as shown in FIG. 3C, the green slurry is deposited on the entire surface of the panel 1 including the black matrix 3, and then the green fluorescent film 4a is formed in the green region using an exposure and development process.

Subsequently, as illustrated in FIG. 3D, a blue slurry is deposited on the entire surface of the panel 1 including the green fluorescent film 4a, and then the blue fluorescent film 4b is formed using an exposure and development process.

The red slurry is deposited on the entire surface of the panel 1 including the blue fluorescent film 4b and the green fluorescent film 4a, and then the red fluorescent film 4c is formed in the red region using an exposure and development process.

Here, the fluorescent film of the conventional CRT will be described in detail as follows.

Green, blue, and red fluorescent film 4a formed on the inner surface of the panel by accelerating electrons emitted from the cathode from an electron gun embedded in the neck tube of the CRT and incident from a predetermined angle among electrons emitted from the electron gun through a shadow mask. It collides with (4b) and (4c) to change the energy level to emit the fluorescent film of the CRT.

Therefore, the green, blue and red fluorescent films 4a, 4b and 4c of the CRT emit light by the impact energy of electrons.

On the other hand, recently, since the color purity is increased by blackening the screen to improve the sharpness of the image quality, the luminance of the fluorescent film should be improved according to the blackening of the screen.

However, the above-mentioned conventional fluorescent tube of the CRT has the following problems.

The luminance of the CRT is limited because the electron gun accelerates the electrons emitted from the cathode and collides with each of the fluorescent films formed on the inner surface of the panel to emit the fluorescent film according to the change of the energy level.

Therefore, the luminance of the fluorescent film cannot be improved as the screen is blackened.

The present invention has been made to solve the above problems, and the fluorescent film of the cathode ray tube suitable for improving the clarity of the image quality by improving the brightness of the fluorescent membrane by using the electron impact energy of the fluorescent membrane of the cathode ray tube and the current flow of the light emitting device and its manufacture The purpose is to provide a method.

1 is a structural cross-sectional view showing a fluorescent film of the CRT of the present invention

Figure 2a to 2d is a cross-sectional view showing the structure of the fluorescent film manufacturing method of the CRT of the present invention

3A to 3D are structural cross-sectional views showing a conventional fluorescent film manufacturing method of a CRT.

Explanation of symbols for main parts of the drawings

20: substrate 21: insulating film

22: photoresist pattern 23: black matrix

24: electroluminescent film 25a: green fluorescent film

25b: blue fluorescent film 25c: red fluorescent film

The fluorescent film of the CRT of the present invention for achieving the above object is a conductive film formed on the entire surface of the substrate, a plurality of black matrix formed at a predetermined interval on the conductive film, and the electron is formed to be recessed between the black matrix And a CRT fluorescent film formed on the electroluminescent film. The method of manufacturing a fluorescent film of the CRT of the present invention includes forming a conductive film on the entire surface of the substrate, and forming a region of the CRT fluorescent film on the conductive film. After the definition, forming a plurality of black matrix having a predetermined interval, forming an electroluminescent film to be recessed between the black matrix, and forming a CRT fluorescent film on the electroluminescent film do.

Hereinafter, a fluorescent film of the CRT and a manufacturing method thereof according to the present invention will be described with reference to the accompanying drawings.

1 is a structural cross-sectional view showing a fluorescent film of the CRT of the present invention.

As shown in FIG. 1, an insulating film 21 formed on the entire surface of the panel 20, a plurality of black matrices 23 formed on the insulating film 21 at predetermined intervals, and the black matrix 23 are disposed between the insulating film 21 and the black matrix 23. And a plurality of CRT fluorescent films 25a, 25b, and 25c formed on the electroluminescent film 24.

In this case, the insulating film 21 is an ITO (Indium Tin Oxide: SnO ₂ · In ₂ O ₃ ) film having conductivity, and the electroluminescent film 24 is an LED or an EL light emitting device.

The CRT fluorescent film is a green fluorescent film 25a, a blue fluorescent film 25b, and a red fluorescent film 25c.

2A to 2D are structural cross-sectional views showing the fluorescent film manufacturing method of the CRT of the present invention.

First, as shown in FIG. 2A, an insulating film 21 is formed on the entire surface of the panel 20 subjected to the cleaning process, a photoresist is deposited on the insulating film 21, and red, green, and blue regions are defined. A plurality of photoresist patterns 22 having a predetermined interval are formed using the exposure and development processes.

In this case, since the light transmission angles of the photoresist vary depending on red, green, and blue colors, the photoresist forms a plurality of photoresist patterns 22 according to red, green, and blue colors. An ITO film having conductivity is used.

Subsequently, as illustrated in FIG. 2B, after depositing graphite on the entire surface including the photoresist pattern 22, the photoresist pattern 22 and graphite are selectively selected to expose red, green, and blue regions through an etching process. It removes to form a plurality of black matrix 23 having a predetermined interval.

At this time, the etching process uses a sulfuric acid etching process.

Subsequently, as shown in FIG. 2C, the electroluminescent film 24 is deposited on the entire surface including the black matrix 23, and the electroluminescent film is selectively removed so as to be recessed between the black matrices, thereby removing the electroluminescent film 24. Form.

At this time, the electroluminescent film 24 is a light emitting element such as an LED or an EL.

Subsequently, as shown in FIG. 2D, the green slurry is deposited on the entire surface including the electroluminescent film 24, and then the green fluorescent film 25a is formed in the green region by using an exposure and development process.

After depositing a blue slurry on the entire surface including the green fluorescent film 25a, a blue fluorescent film 25b is formed in a blue region using an exposure and development process, and the blue fluorescent film 25b and the green fluorescent film are formed. After depositing a red slurry on the entire surface including 25a, a red fluorescent film 25c is formed using an exposure and development process.

Herein, the light emitting method of the fluorescent film of the CRT of the present invention configured as described above will be described.

First, the electrons emitted from the cathode by the electron gun are accelerated to collide with the green fluorescent film 25a, the blue fluorescent film 25b and the red fluorescent film 25c formed on the inner surface of the panel to change the energy level. 25a), the blue fluorescent film 25b, and the red fluorescent film 25c emit light primarily.

In addition, since electrons are accelerated and emitted from the electron gun, current flows through the green fluorescent film 25a, the blue fluorescent film 25b, and the red fluorescent film 25c, and then flows into the electron emitting film 24. ) Is emitted secondarily.

As described above, the fluorescent film of the CRT of the present invention and the manufacturing method thereof have the following effects.

The electrons emitted by the electron gun collide with the CRT fluorescent film, and the first emission due to the impact energy of the electrons and the current generated during electron emission are flowed to the electron emission film to emit the secondary light by the current flow. Can improve.

Therefore, the luminance can be improved according to the blackening of the screen, thereby improving the clarity of the picture quality of the CRT.

Claims (4)

A conductive film formed on the upper surface of the substrate; A plurality of black matrices formed on the conductive film at predetermined intervals; An electroluminescent film formed to be recessed between the black matrices; And a CRT fluorescent film formed on the electroluminescent film. The method of claim 1, The electroluminescent film is a fluorescent film of a CRT tube, characterized in that it uses an LED or EL light emitting element. Forming a conductive film over the entire substrate; Defining a region of the CRT fluorescent film on the conductive film, and then forming a plurality of black matrices having a predetermined interval; Forming an electroluminescent film to be recessed between the black matrices; The CRT fluorescent film manufacturing method comprising the step of forming a CRT fluorescent film on the electroluminescent film. The method of claim 3, wherein The electroluminescent film is a fluorescent film manufacturing method of the CRT, characterized in that using the LED or EL light emitting element.

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