KR0131168B1 - Shadow Masks for Cathode Ray Tubes - Google Patents

Abstract

The present invention relates to a shadow mask for a cathode ray tube. In particular, in order to increase the margin of a dot-type cathode ray tube, a shadow mask slot shape is formed to increase the color purity margin so that an electron beam width is formed with respect to the mislanding direction of the electron beam. In the cathode ray tube having a dot-type shadow mask, the shape of the electron beam passing through the shadow mask is configured to have a relatively small slot width in the direction of mis-landing of the electron beam during forward and backward movement of the inclined yoke to increase the margin of color purity. I would have to.

Description

Shadow Masks for Cathode Ray Tubes

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

2 is a mis-landing direction when moving before and after the deflection yoke in a dot-type cathode ray tube.

Figure 3 (a) (b) is an embodiment of the shadow mask slot shape for improving the purity in the conventional cathode ray tube.

4 is a shadow mask for the cathode ray tube of the present invention.

(A) of FIG. 5 is a detailed view of portion A of FIG. (b) is detail B of FIG. (c) is a detail of part C of FIG.

* Explanation of symbols for main parts of the drawings

101: shadow mask 102: slot

103 electron beam 104 phosphor dot

The present invention relates to a shadow mask for a cathode ray tube, in particular, to increase the color purity margin by making a shadow mask slot shape so that the width of the electron beam is formed small with respect to the mislanding direction of the electron beam in order to increase the margin of the dot type cathode ray tube. .

The conventional cathode ray tube is equipped with an electron gun (3) for emitting an electron beam (9) in the neck portion 10 of the glass bulb consisting of a panel (1) and a panel (2) as shown in FIG. 1, and in the electron gun (3) A shadow mask 5 plays an important role in selecting a color by the emitted electron beam 9, and a fluorescent film 4 in which the emitted electron beam 9 collides is applied to the panel 1. Outside the panel 2, a deflection yoke 8 for scanning the electron beam 9 from the electron gun 3 is mounted.

The cathode ray tube configured as described above has a fluorescent film 4 coated on the inner surface of the panel 1 by accelerating and concentrating hot electrons from the electron gun 3 contained in the neck portion 10 by the voltage across the inside of the funnel 2. It strikes and reproduces a predetermined image.

At this time, the electron beam 9 accelerated by the electron gun 3 is changed by the magnet outside the neck 10 and is deflected by the deflection yoke 8 which is an electron deflecting device.

The deflected electron beam 9 passes through a shadow mask 5 called a color screening electrode and strikes a fluorescent film 4 coated on the inner surface of the panel 1 to reproduce a predetermined image. 5) is supported by a structure called a frame 6, and also supports an inner shield 7 which is a geomagnetic shielding part for preventing the electron beam 9 from being affected by an external geomagnetic field.

In this way, the fluorescent film 4 is applied in a geometrically matched state to the hitting point of the accelerated electron beam 9 so that the electron beam 9 strikes the adjacent fluorescent film 4 when the shadow mask 5 is turned on. This results in poor color purity.

The reason for lowering such color purity is that the shadow mask 5 is caused by the doming phenomenon due to thermal expansion and various assembly errors in manufacturing.

It is designed to have a margin to prevent the degradation of color purity generated as described above. In the case of the dot type cathode ray tube as shown in FIG. 2, the deflection yoke 8 is formed while the green fluorescent dot 12 is formed in the process of adjusting and fixing the deflection yoke. When moving back and forth, the margin of color purity (Margin) should be large so that the electron beam 9 does not hit another adjacent fluorescent film.

In fact, when the deflection yoke 8 is moved back and forth, the mis-landing direction of the electron beam is moved horizontally with the X-axis direction on the X-axis as shown in FIG. 2, so that the electron beam 13 also moves in the Y-axis on the Y-axis. do.

In addition, the electron beam 9 moves at an angle of about 45 ° C on the D axis having the weakest color purity.

Therefore, in order to secure a margin of color purity, US Patent 4475056 has an elliptical shape of the slot 16 of the shadow mask 15 as shown in FIG. 3 (a), and forms a phosphor in an ellipse, and the electron beam is circular. Color purity margin.

However, the color purity margin in the up and down directions is increased, but the effect is inconsistent with the mislanding direction of the actual beam.

In addition, Japanese Patent Application Laid-Open No. 59-16249 such as (b) of FIG. 3 has a slot 18 shape of the shadow mask 17 in order to solve the difficulty in forming a perfect circle because the panel is spherical. Formed as shown in (B) to be the source of the fluorescent dot to form a circularity to try to achieve the color purity, but this also considered the shape of the electron beam, the effect was insignificant.

And (a) and (b) of FIG. 3 are characterized in that A and B, each of shadow shadows 15 and 17 slots 16 and 18, are A ≠ B, and color purity margins cannot be effectively increased.

In view of the above, an object of the present invention is to configure the shape of the electron beam passing through the shadow mask so that the slot width of the electron beam in the mis-landing direction is relatively small when the deflection yoke is moved back and forth to increase the margin of color purity. .

The shadow mask for cathode ray tube of this invention is demonstrated by FIG. 4 and FIG. The slot 102 is formed so that the slot shape formed in the shadow mask 101 is opposite to the mislanding direction of the electron beam.

That is, the shape of the electron beam 103 passing through the shadow mask 101 has a relatively small slot 102 side in the mis-landing direction of the electron beam 103 when the deflection yoke is moved back and forth with respect to the direction in which the actual electron beam falls out. It was possible to increase the margin of color purity, which is the distance to strike another adjacent phosphor.

This is a circular shape in the center of the shadow mask 101, and is formed by grading on the horizontal axis (X), the vertical axis (Y), and the diagonal axis (D).

In this manner, when the portion A of FIG. 4, which is the corner of the diagonal axis D, which represents the largest amount of movement in the forward and backward movement of the actual deflection yoke, is viewed from (a) of FIG. 5, the driving of the light source of the exposure apparatus is performed when the phosphor dot 104 is formed. Asymmetrically, formed into a round.

Therefore, the movement direction of the electron beam 103 is about 45 degrees when the shadow of the shadow mask 101 slot-shaped electron beam hits the fluorescent substance of a round shape.

By reducing the width of the electron beam 103 in the 45 ° direction as described above, the diagonal axis spacing Dd striking the adjacent phosphor increases, resulting in a greater color purity margin when adjusting the deflection yoke. You can make

In the B and C portions of FIG. 4, the shadow mask slots have a smaller width of the electron beam in the direction in which the electron beam 103 moves on the horizontal axis (X) axis or the vertical axis (Y) as shown in (a) and (b) of FIG. By forming the same, a cathode ray tube having a large value of the horizontal axis spacing Xd and the vertical axis spacing Yd similarly to the diagonal axis spacing Dd can be formed.

The interval between the electron beam width and the electron beam width was configured such that the diagonal axis spacing Dd ≥ horizontal axis spacing Yd ≥ vertical axis spacing Yd so as to have a large spacing in the most moving portion during the forward and backward movement of the deflection yoke.

And the shape of the slot 102 is composed of oval, polygonal or elliptical polygon. The cathode ray tube made of the shadow mask of the present invention has a significant color purity margin when adjusting the deflection yoke, especially when adjusting the deflection yoke much more than the conventional cathode ray tube considering the direction of electron beam movement, and thus has a significant effect on the improvement of manufacturing yield in manufacturing a high-definition cathode ray tube. It is an invention that not only affects but also secures color purity.

Claims (5)

In cathode ray tube with dot-type shadow mask, the shape of the electron beam passing through the shadow mask is configured so that the slot width in the mis-landing direction of the electron beam is relatively small when the deflection yoke is moved back and forth to increase the margin of color purity. Shadow mask for cathode ray tube, characterized in that. The shadow mask for a cathode ray tube according to claim 1, wherein an interval between the electron beam width and the electron beam width is provided at a diagonal axis interval ≥ horizontal axis interval ≥ vertical axis interval. The shadow mask for cathode ray tubes according to claim 1, wherein the slot mask has an elliptical shape. The shadow mask for cathode ray tubes according to claim 1, wherein the slot mask has a polygonal shape. The shadow mask for cathode ray tubes according to claim 1, wherein the slot mask has an elliptical polygonal shape.