KR940008500Y1 - Crt with misalignment correction band - Google Patents

Abstract

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Description

Cathode ray tube with explosion proof band

1 to 3 are perspective views each showing an embodiment of a cathode ray tube according to the present invention.

4 to 8 are perspective views each showing an embodiment of an explosion-proof band applied to the present invention.

9A and 9B are perspective views of the main portion showing the state of use of the explosion-proof band of FIG.

10 to 12 are perspective views each showing an example of a conventional cathode ray tube.

13 to 14 are plan views and side views of the cathode ray tube showing the panel surface used in the description of the present invention.

* Explanation of symbols for main parts of the drawings

1: cathode ray tube body 2: panel

3: explosion-proof band 10: slits

11, 12: hole

The present invention relates to a color cathode ray tube (CRT) that optimizes beam landing.

The present invention is a cathode ray tube wound around the outside of the panel (explosion-proof band), by installing a recess in the explosion-proof band by the amount of misslanding correction of the electron beam, thereby By determining the effective cross-sectional area, the miss landing correction of the electron beam is made.

In a normal color cathode ray tube, as shown in FIGS. 10 to 12 for reinforcing the tube body, the explosion-proof band 3 surrounds the outer periphery of the panel 2 of the tube body 1. It is installed. 10 and 11 show a cathode ray tube with the panel 2 as a cylindrical surface, and FIG. 12 shows a cathode ray tube with the panel 2 as a spherical surface. (4) is a fixing metal fitting fixed to the corner part of the explosion-proof band 3 integrally.

When the tube body reinforcement is evacuated in the tube body 1, the panel surface and the tube body as a whole are deformed as shown in FIG. 14, and a large surface stress is generated at the periphery of the panel. It is based on reducing the external force F by the explosion-proof band 3, and restoring the panel surface to a fundamental state as much as possible, as shown by the tangential line. In the past, this distortion recovery amount δ is mainly focused on explosion-proof reinforcement of the tube body, and thus, it is managed in the direction of suppressing the minimum value. For example, there is a variation of ± 150 μm in a 20-inch cathode ray tube.

By the way, the high-precision color cathode ray tube has less margin of error in electron beam landing for a phosphor layer, such as a phosphor stripe, compared to a commercially available color cathode ray tube. In the color cathode ray tube, as one of areas where mis-landing is likely to occur, as shown in FIG. 13, there are regions A and B on both sides sandwiching the center portion as viewed from the front of the panel 2. These region A and B are easy to produce the position change of a fluorescent stripe by vacuum deformation (concave inward) of the panel glass at the time of evacuating the inside of a tube body, and manufacturing conditions in a fluorescent surface formation process, and the completed cathode ray tube Inconsistent with the position of the electron beam in the case, it was difficult to obtain sufficient color purity.

On the other hand, the cathode ray tube is reinforced with the explosion-proof band 3 as described above, but the variation in the amount of distortion recovery δ directly affects this color purity. In the past, the mis-randy correction of the regions A and B was dependent on the adjustment of the correction lens system in the fluorescent surface forming step. In this method, even if the estimated value (normal value) of the delta value for each lot was maintained, it was impossible to follow the fluctuations of individual cathode ray tubes in the lot.

The present invention provides a cathode ray tube which can greatly reduce the fluctuation of the distortion recovery amount δ and make the mislanding amount as zero as possible in view of the above.

In the cathode ray tube after vacuum evacuation, the so-called mislanding correction amount for reducing the position mismatch between the phosphor layer, for example, the phosphor stripe and the electron beam, in regions A and B on the panel surface shown in FIG. , ΔS is the distortion recovery is δ (h),

ΔS = α · (h)... … (One)

Is given as. However, α = 0.1 to 0.3, such as about 0.18 to 0.19 in 20-inch pipes and about 0.3 in civilian pipes. ΔS and δ (h) are in μm. This δ (h) is an amount in which mislanding occurs, including misalignment of the panel in vacuum evacuation and displacement of the phosphor stripe in the production of the fluorescent surface.

This distortion recovery amount δ (h) is proportional to the tension T of the explosion-proof band 3. In other words

δ (h) = rT... … (2)

However, r = 0.02-0.1 micrometer / kg unit. For example, in a 20-inch pipe, it is about 0.05 micrometer / kg, and in a civil service tube, it is about 0.07 to 0.08 micrometer / kg, and this r becomes small as a panel surface becomes flat.

Again, the tension (T) of this explosion-proof band is assuming that the effective cross-sectional area of the band is t (ho-h),

T = β t (ho-h)... … (3)

Is given by Where t is the plate thickness of the band, ho is the amplitude of the band, and h is the length of the cutout 10 (see FIG. 4). In addition, β is an integer (meaning an upward recovery point) and varies with band material. For example, in SPC (temperature compensation) material, it is (beta) = 26-32 kg / mm. ho, h is in mm. therefore,

ΔS = α · r · β · t (ho-h). … (4)

The landing compensation amount DELTA S is proportional to the effective cross-sectional area t (ho-h) of the explosion-proof band 3.

In the above, the present invention is to determine the effective cross-sectional area of the band (3) by the mis-landing correction amount (ΔS) of the electron beam to the explosion-proof band (3) wound around the outside of the panel (2) of the cathode ray tube body (1) An ablation part 10 (or (11, 12)) to determine is provided. This cutout can be formed as a slitting or a hole of a predetermined shape extending from the end edge of the band.

The value of h is determined by the above equation (4), which is the mislanding correction amount (ΔS), and the effective cross-sectional area of the explosion-proof band 3 is controlled by providing an ablation section of length h in the explosion-proof band 3, and the amount of mislanding amount Preferably it is zero.

An embodiment of a cathode ray tube according to the present invention will be described with reference to the drawings.

In the present invention, for example, before winding the explosion-proof band around the panel of the cathode ray tube, the position correction amount of the phosphor layer such as the phosphor stripe and the electron beam in the regions A and B of the cathode ray tube, i. Obtained by measurement The value of h based on said Formula (4) is determined by the said correction amount (DELTA) S, and the slits 10 of length h are put into the explosion-proof band 3 as shown to FIG. 4 or FIG. To suppress the effective cross-sectional area of the band 3. Thus, the explosion-proof band 3 in which the slits 10 are inserted is wound around the outside of the panel 2 of the cathode ray tube body 1 as shown in FIGS. 1 to 3. 1 and 2 show a cathode ray tube with the panel 2 as a cylindrical surface, and FIG. 3 shows a cathode ray tube with the panel 2 as a spherical surface. In this case, the slits 10 are formed in plural so that uniform tension is distributed throughout the explosion-proof band 3. The number of slits 10 is also determined by the size and shape of the cathode ray tube. For example, in the case of a rectangular cathode ray tube, one to several slits 10 are allowed on each side.

As described above, by installing the slit 10 in the explosion-proof band 3 and modulating the installed length h by the correction amount ΔS, the effective cross-sectional area of the band is controlled, and the amount of distortion recovery δ in each cathode ray tube Variation in (h) is greatly reduced, for example, ± 5 μm or less, and non-imlanding is optimized. At the same time, an explosion-proof effect is also obtained. In addition, the proportional constant (beta) of Formula (3), (4) changes with the lot of explosion-proof band material. The plate thickness t also varies with the lot. All of these variations can be adjusted and absorbed by the length h.

In FIG. 4, the slitting 10 is placed at the funnel side, but as shown in FIG. 6, the slitting 10 may be inserted at the panel surface side. However, when the explosion-proof is considered, it is preferable to install the slits 10 on the panel side.

As another example, as shown in FIGS. 8 and 9A, the explosion-proof band 3 is provided with a plurality of slots 11 of the same width which are discontinuous and connected in the band width direction. After the explosion-proof band 3 is fitted around the panel of the cathode ray tube, the length h 'is fixed as shown in FIG. 9B by the mislanding correction amount DELTA S, that is, a plurality corresponding to the length. By passing through the hole 11, a predetermined effective cross-sectional area is obtained.

In another embodiment, a plurality of types of explosion-proof bands 3 having different lengths h of the slits 10 are already prepared, and the explosion-proof bands closest thereto are selected by the ΔS value of the cathode ray tube and the outside of the panel is selected. Wind around

In the above example, the slits 10 are used as the cutouts formed in the explosion-proof band, but as shown in FIG. 7, the holes 12 having a predetermined shape may be formed.

Moreover, as a cathode ray tube, it is common also to the cathode ray tube which installed the safety panel in the explosion-proof band, the front surface of a panel, filled with resin, and performed explosion-proof processing, or the cathode ray tube equipped with the metal shell etc. in the outer side of a tubular body.

Further, in the above example, although commonly used in a color cathode ray tube having a fluorescent surface composed of phosphor stripes, the present invention is also applied to a color cathode ray tube provided with a fluorescent surface composed of phosphor dots.

According to the present invention described above, an ablation portion is provided in the explosion-proof band wound around the outside of the panel by the mislanding correction amount (ΔS), and the effective cross-sectional area of the band is controlled, whereby explosion-proof treatment is performed and distortion recovery amount δ ( The fluctuation of h) is greatly reduced, and the amount of mis-landing can be set to zero as much as possible for each cathode ray tube (CRT).

In addition, even in the cathode ray tube of the same panel (using the same panel), in the past, a separate half-width band had to be prepared for each tube type, but according to the present invention, one band mold was satisfied, and only by adjusting the length of the explosion-proof band cutout portion. Explosion-proof and beam landing adjustment of each tube type is possible. Therefore, cost reduction in material control and production process of a cathode ray tube can be aimed at.

In the present invention, in particular, the error is very small when applied to a high-precision color cathode ray tube with a low error of beam landing.

Claims (11)

A cathode ray tube having an explosion-proof band fixed around its tube body panel and adapted to apply a compressive force around the cathode ray tube as a result of the extension of said explosion-proof band, said explosion-proof The band is provided with a recess to adjust the effective cross-sectional area of the explosion-proof band to a value suitable to compensate for misalignment (mis-landing) of the electron beam on the panel surface due to vacuum-deformation of the tube body. Cathode ray tube provided with the explosion-proof band which makes it specific. The cathode ray tube according to claim 1, wherein the ablation portion is formed at the funnel side of the explosion-proof band. The cathode ray tube according to claim 1, wherein the ablation portion is formed at a panel side of the explosion-proof band. The cathode ray tube of claim 1, wherein the ablation portion is a suitable type of gap previously formed in the explosion-proof band. The cathode ray tube according to claim 1, wherein the explosion-proof band forms a slot-shaped cutout. The cathode ray tube of claim 1, wherein the explosion-proof band forms a slits (10) shaped cutout. The cathode ray tube according to claim 1, wherein the explosion-proof band forms a hole-shaped cutout. The method of claim 1, wherein the adjustment of the effective surface area of the explosion-proof band is defined by the miss landing correction amount ΔS proportional to t (ho-h), where t is the thickness of the explosion-proof band, ho is the overall width of the band, and h Cathode ray tube having an explosion-proof band, characterized in that the length of the ablation section. 9. The explosion-proof band according to claim 8, wherein ΔS is equal to α · β · t (ho-h), α is a constant related to the size of the CRT, and β is an integer corresponding to the phase break point of the band material. Cathode ray tube provided. 10. A cathode ray tube with explosion-proof band according to claim 9, wherein α is between 0.1 and 0.3. The cathode ray tube of claim 1, wherein the explosion-proof band is mounted around the tube body panel.