KR100252064B1 - Exposure device of cathode ray tube - Google Patents

Abstract

The present invention discloses an exposure apparatus for a cathode ray tube.

The present invention relates to a cathode ray tube exposure apparatus comprising a panel on which a photoresist film is formed, an exposure light source provided to be spaced a predetermined distance apart from an inner surface of the panel, and a correction lens positioned between the exposure light source and an inner surface of the panel. And a reflector having a predetermined curvature on the rear surface of the exposure light source with respect to half of the eccentric distance of the red, green, and blue electron beams from both sides of the exposure light source. It is possible to simultaneously expose the black matrix pattern formed between the red, green, and blue fluorescent films with one exposure light source, thereby improving productivity.

Description

Exposure device of cathode ray tube

1 is a sectional view schematically showing an exposure apparatus of a conventional cathode ray tube,

2 is a sectional view schematically showing an exposure apparatus for a cathode ray tube according to the present invention,

3 is a perspective view showing an extract of the reflector shown in FIG.

* Explanation of symbols for main parts of the drawings

21: cabinet 24: correction lens

25 correction filter 30 reflector

31: the body

The present invention relates to an exposure apparatus of a cathode ray tube, and more particularly, to an exposure apparatus of a cathode ray tube, which is capable of simultaneously exposing the entire surface of a black matrix as one light source.

In general, a color cathode ray tube forms a single image by arranging red, blue, and green phosphors in the form of dots or stripes on the inner surface of the panel and allowing the electron beam emitted from the tank gun to land on each phosphor. Since the electron beam emitted from emits other colors besides the hole, there is a problem that the resolution of the image is reduced. In order to solve such a problem, conventionally, a method of filling a non-luminous absorbent material between the phosphors to prevent other colors from emitting light has been adopted.

As described above, in order to form a black matrix on the inner surface of the panel which prevents the emission of other colors by the electron beam, many processes such as coating, drying, exposure, development, graphite coating, and high pressure development are performed on the inner surface of the panel.

1 shows an example of an exposure apparatus for exposing the photoresist during the black matrix formation process.

The light source assembly 12 is installed at the bottom of the cabinet 11 and a mounting portion 13 supporting the fraud panel 100 is provided at the top thereof, while the light source assembly 12 and the mounting portion 13 are provided. The correction lens 14 and the correction filter 15 for correcting the light irradiated from the light source assembly 12 are installed between the panel 100 mounted on the light source assembly 12. A shutter 17 is provided between the correction lens 14, the correction filter 15, and the inner surface of the panel 100 to partially pass the light emitted from the light source assembly 12.

As a conventional cathode ray tube exposure apparatus configured to expose the photoresist film coated on the inner surface of the panel, the panel 100 having the photoresist film formed on the inner surface of the apparatus is mounted on the seating part of the cabinet 11 so that the inner surface of the light source assembly 12 is exposed. To face. In this state, light is irradiated from the light source to expose the photosensitive film formed on the inner surface of the panel 100 in a predetermined pattern. Here, the exposure light source is moved to match the phosphor pattern of red, blue, and green so that the black matrix can be positioned between the phosphors to perform the exposure operation. Then, the photosensitive film applied to the inner surface of the panel 100 is developed to have a predetermined pattern.

Such an exposure apparatus has to be exposed while moving the exposure light source of the light source assembly has the following problems.

first; Since the exposure light source must be moved to the deflection point of each electron beam during the formation of each fluorescent film, the scattering caused by the movement of the light source is severe and the reliability of the exposed black matrix pattern is degraded.

second; When the black matrix is formed, the exposure light source must be moved in accordance with the positional state located between the phosphors, so that the exposure time becomes long and productivity cannot be improved.

Third; Since the red, blue, and green fluorescent film patterns are different from each other, an exposure lens for forming a black matrix positioned therebetween must be processed differently according to the set pattern of the black matrix located between each phosphor, thereby increasing production cost. Done.

fourth; Correction of the lens due to distortion of the black matrix pattern is difficult.

The present invention has been made to solve the above problems, and it is possible to form a black matrix pattern on the inner surface of the panel as one exposure lens and an exposure light source, and to provide an exposure apparatus for cathode ray tubes that can improve productivity. The purpose is.

Another object of the present invention is to provide an exposure window for a cathode ray tube that can be easily corrected by a light source irradiator irradiated from the exposure light source.

In order to achieve the above object, the present invention includes a panel coated with a photosensitive film, an exposure light source installed to be spaced a predetermined distance apart from the inner surface of the panel, and a correction lens positioned between the exposure light source and the inner surface of the panel. In the exposed device for cathode ray tube,

A reflective mirror having a predetermined curvature is provided on the rear surface of the exposure light source from the exposure light source on both sides thereof to a half of the eccentric distance with respect to the red, green, and blue electron beams.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 shows an exposure apparatus 20 for a cathode ray tube according to the present invention, which includes a seating part on which a panel 100 having a shadow mask frame assembly 101 is installed on an inner surface of an upper surface of a cabinet 21. An exposure light source 22 for exposing the panel 100 is provided on a lower surface of the cabinet 21 opposite to the panel 100 seated on the cabinet 21. In addition, a correction lens 24 and a correction filter 25 are installed between the exposure light source 22 and the inner surface of the panel 100. And a reflector 30 is provided on the back of the exposure light source 22, the reflector 30 emits red, blue, green electron beam signals from both sides of the exposure light source 22 in accordance with the characteristics of the present invention The reflector 30 having a predetermined curvature is provided around the two points p at positions separated by a half distance of the eccentric distance corresponding to each electron beam passing air gap of the electron gun. Here, the reflector 30 has a shape in which the vertical cross-section is approximately ω by arranging two bodies 31 having a semi-cylindrical shape in parallel to each other and contacting the edges thereof.

The reflector 30 has an intersection point at which light irradiated from the exposure light source 22 is reflected by the reflector 30 and intersects that is, a dimming light source L, L ′, and a dimming light source L. (L ') must form its curvature so that the distance from the exposure light source 22 is equal to the eccentric distance.

Referring to the operation of the cathode ray tube exposure apparatus according to the present invention configured as described above are as follows.

First, in order to expose the panel 100 having the photosensitive film formed on the inner surface, the panel 100 is seated on the seating portion 21a of the cabinet 21 and light is emitted from the exposure light source 22 to the inner surface of the panel 100. The light is irradiated from the exposure light source. The light irradiated from the exposure light source is positioned at the center of the panel 100 to expose the black matrix pattern positioned between the green phosphors. The light irradiated from the exposure light source 22 and irradiated to the reflector 30 is reflected and crossed at a position spaced apart by both eccentric distances from both sides of the exposure light source 22 to form a virtual light source L (L '). As a result, the black matrix pattern positioned between the red and blue phosphors is exposed. Accordingly, the black matrix pattern positioned between the red, green, and blue fluorescent films may be simultaneously exposed with one exposure light source 22 to form a desired black matrix pattern on the inner surface of the panel 100.

When the black matrix pattern formed at the periphery of the panel 100 is distorted during the exposure process as described above, the distortion of the exposed fluorescent film pattern is easily changed by correcting the curvature of the reflector to change the irradiation angle of the reflected light source. You can correct it. Therefore, it is possible to solve the problem of correcting the exposure lens itself in order to correct the exposure pattern of the black matrix as in the prior art. Here, it may be considered that the black matrix pattern positioned between the red, green, and blue phosphors may be exposed using the reflector 30, but this may be used to irradiate the inner surface of the panel with light emitted from each of the exposure light sources. It is almost impossible to manufacture a correction lens.

As described above, the exposure apparatus for the cathode ray tube of the present invention can simultaneously expose the black matrix pattern positioned between the red, green, and blue fluorescence films as one exposure light source. Can be reduced. In addition, the present invention can significantly reduce the exposure time compared with the prior art has the advantage that the productivity can be improved.

Claims (3)

An exposure apparatus for a cathode ray tube, comprising: a panel on which a photosensitive film is formed; an exposure light source provided to be spaced a predetermined distance apart from an inner surface of the panel; and a correction lens positioned between the exposure light source and the inner surface of the panel. For the cathode ray tube, a reflecting mirror having a predetermined curvature is provided on the rear surface of the exposure light source with respect to each point that is 1/2 of the eccentric distance to the red, green, and blue electron beams from both sides of the exposure light source. Exposure apparatus. The method of claim 1, And the reflecting mirrors are positioned side by side with two semi-cylindrical shapes in contact with their edges so that the vertical section has an ω shape. The method of claim 1, The curvature of the reflector is formed so that the light reflected from the exposure light source cross each of the reflected light source at a position separated by the eccentric distance of the polarization point of the electron gun for emitting each phosphor of red, green, blue from the exposure light source An exposure apparatus for cathode ray tubes.