KR930009359B1 - Shadow mask frame assembler for cathode-ray tube - Google Patents

Abstract

The shadowmask frame assembly for a cathode tube comprises a frame and a shadowmask having many electron beam through-holes, whose spaces between one another on the corner region of the mask are etched to a specified depth. Thus it decreases the heat capacity of the shadowmask corner part fixed on the frame, and standardize purity drift quantity of the cathode tube to increase the resolution.

Description

Shadow Mask Frame Assembly for Cathode Ray Tubes

1 is a cross-sectional view of a typical colored cathode ray tube.

2 is a perspective view of a shadow mask frame assembly for a conventional cathode ray tube.

3 is a partially enlarged perspective view showing a shadow mask frame assembly for a cathode ray tube according to the present invention.

4 is a graph showing the amount of fret drift of the shadow mask.

* Explanation of symbols for main parts of the drawings

10: shadow mask frame assembly 11: shadow mask

11a: electron beam through hole 11b: lead-in

14: bimetal 15: hook spring

The present invention relates to a cathode ray tube, and more particularly, to a shadow mask frame assembly mounted on an inner surface of a panel.

Typically, the cathode ray tube is a panel having a shadow mask frame assembly 4 in which a shadow mask 2 and a frame 3 are combined with a plurality of electron beam through holes 2a formed therein, as shown in FIG. (5) and the funnel 6 in which the electron gun 7 is attached to the neck part 6a are sealed.

The electron beam emitted from the electron gun 7 for the cathode ray tube configured as described above passes through the electron beam through hole 2a of the shadow mask 2 and then lands on the fluorescent film to form a lower surface, and these pixels are gathered to form one screen. Will come true. However, the electron beam passes only a part of the electron beam through hole 2a of the shadow mask 2 and the electron beam that does not pass, that is, the hot electrons, heats the shadow mask 2 and the frame 3 to dope the shadow mask 2. It causes a phenomenon. Here, the dominant phenomenon acting on the shadow mask 2 is generated in the opposite direction at the center portion of the shadow mask 2 and at the screen left and right reference points B and the diagonal corner portion A of the shadow mask. There was a problem that the resolution is reduced. That is, as shown in FIG. 1, the landing trajectories at the center and left and right reference points when the light is emitted from the electron gun 7 and landed on the fluorescent surface are first moved to the shadow center direction as the shadow mask is heated. As 3) is thermally expanded, the shadow mask 2 is moved outward. The movement of the landing trajectory is corrected by moving the shadow mask frame assembly 4 to the inner side of the panel 5 by a bimetal and a hook spring that fixes the shadow mask frame assembly 4 to the inside of the panel. However, the electron beam landing trajectory at the corner portion A due to thermal expansion of the shadow mask 2 hardly changes at the time of thermal expansion of the initial shadow mask 2, and as the next frame 3 is heated to thermal expansion, Will be moved to. Accordingly, the electron beam landing trajectory at the corner portion A of the shadow mask 2 is moved outward in accordance with the thermal expansion of the frame 4 and the correction of the dominant phenomenon of the shadow mask of the bimetal and the hook spring. There was a problem that the resolution is lowered at the screen corner of the tube.

The present invention has been made to solve the above problems, and the cathode capacity can be improved by reducing the heat capacity of the shadow mask corner portion fixed to the frame relative to the center portion to make the purity drift of the cathode ray tube constant throughout the entire screen. Its purpose is to provide a conventional shadowmask frame assembly.

In order to achieve the above object, the present invention provides a shadow mask frame assembly for a cathode ray tube, in which a shadow mask having a plurality of electron beam through holes is formed and a frame, wherein a predetermined depth is etched between each electron beam through holes at the corners of the shadow mask. It features.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

As shown in FIGS. 1 and 3, the shadow mask frame assembly 10 for a cathode ray tube according to the present invention includes a bimetal 14 and a hook spring 15 and a panel of a cathode ray tube 5 installed on the side of a frame, which will be described later. And a shadow mask 11 having a plurality of electron beam through holes 11a formed in a dot or stripe shape in the perforated part, which is fixed to the inner surface of the panel 5 by coupling the stud pins 8 formed on the inner surface thereof. And a frame 12 welded to the skirt portion bent in a substantially perpendicular direction from the hole portion of the shadow mask 11 to support the shadow mask 11. Here, the corner portion C of the shadow mask 11 is etched between each electron beam through hole 11a formed in the corner portion C in accordance with a feature of the present invention, and the lead portion 11b having a predetermined depth is formed. Is formed. At this time, the depth of the inlet portion (11b) etched in the corner portion (C) of the shadow mask 11 is preferably 50 to 70% of the thickness (t) of the shadow mask (11) and the corner portion (C) The etching part is 1/4 of the shadow mask short side length (L ') in the vertical direction from each corner of each shadow mask 11 and 1/4 of the shadow mask long side length (L) in the horizontal direction. Preferably, the lead portions 11b etched at each corner portion C of the shadow mask are formed continuously or discontinuously in the longitudinal direction of the short side portion of the shadow mask.

Referring to the operation according to the invention configured as described above are as follows.

The shadow mask 11 is etched when the shadow mask 11 is heated by an electron beam that is emitted from the electron gun and does not pass through the electron beam passing hole 11a of the shadow mask 11, that is, hot electrons. The center and periphery of (11) and each corner portion (C) are almost uniformly thermally expanded and emitted from the electron gun (7) and then the landing trajectory of the electron beam landing through the electron beam through hole (11a) and landing on the fluorescent surface is a shadow mask. Will be moved to the center of. As the frame 12 is gradually thermally expanded, the landing trajectory of the electron beam is moved outwardly of the shadow mask 11, and the movement amount is moved by the bimetal 14 and the hopping through the shadow mask frame assembly. 10) is corrected by moving to the frame 12 axis. That is, since each electron beam through hole 11a of the corner portion C of the shadow mask 11 is etched, the electron beam landing trajectory at the corner portion C is moved around the screen according to the movement in the outward direction. The color purity can also be prevented. More specifically, the shadow mask 11 corresponds to one-quarter of the long side length of the shadow mask 11 in the horizontal direction from each corner portion C of the shadow mask 11, and in the vertical direction one-quarter of the shadow mask short side portion. Since each electron beam through hole of the corresponding corner portion C is etched to a depth of about 50 to 70% of the thickness of the shadow mask 11, the heat capacity of the corner portion C is at the center of the shadow mask 11. Relatively small relative to the Therefore, the initial thermal expansion amount that is heated with respect to the electron beam emitted from the electron gun 7 has a larger corner portion C than the central portion of the shadow mask 11.

Therefore, when the landing trajectory of the electron beam at the center of the shadow mask 11 emitted from the electron gun 7 is called D ₁ and the electron beam landing trajectory at the corner C is referred to as D ₂ , the periphery of the shadow mask 11 is obtained. And move in the center direction at the corner portion C (Fig. 4 section a). Then, as the frame 12 supporting the shadow mask gradually expands, the landing trajectory of the electron beam is directed outwardly (section 4b). It is corrected by the bimetal 14 and the hook spring 15 fixed to the stud pin 8 (Fig. 4c section).

Therefore, it is possible to prevent local changes in color purity caused by the dominant phenomenon of the shadow mask.

Thus, the shadow mask frame assembly for cathode ray tube of the present invention improves the resolution of the cathode ray tube employing the same by etching the corner portion of the shadow mask to relatively reduce the heat capacity of the portion so that the thermal expansion is almost the same in all areas of the shadow mask. Has the advantage of being able to.

Claims (3)

In a shadow mask frame assembly for a cathode ray tube, in which a shadow mask having a plurality of electron beam through holes and a frame are combined, 1/4 of a short side length in a vertical direction from a corner of a shadow mask, and 1/4 of a long side length in a horizontal direction The shadow mask frame assembly for cathode ray tubes characterized in that the etching between the electron beam through hole located in the corner portion of the phosphorus region. The shadow mask frame assembly for a cathode ray tube according to claim 1, wherein the depth etched in the shadow mask corner portion is 50 to 70% of the thickness of the shadow mask. The shadow mask frame assembly for a cathode ray tube according to claim 1, wherein the shadow mask is etched continuously or discontinuously in the vertical direction between the electron beam passing holes of the shadow mask.