KR100209612B1 - Getter cover for cathode ray tube - Google Patents

Abstract

In order to prevent the barium in the getter installed in the cathode ray tube from scattering on the shadow mask axis, the getter shield is integrally formed or separately formed on the opening of the inner shield, so that uneven thermal expansion of the shadow mask causes doting So that it is possible to prevent the occurrence of the defects and increase the luminance.

The getter shield 6 is provided on the opening 3 formed in the inner shield 2 to prevent the barium in the getter 4 from scattering to the effective surface side of the shadow mask 5 through the opening. .

Description

Getter cover for cathode ray tube

FIG. 1 is a longitudinal sectional view showing a conventional cathode ray tube. FIG.

FIG. 2 is a cross-sectional view showing a cathode ray tube equipped with the present invention. FIG.

3 is a longitudinal sectional view showing part A of FIG. 2;

FIG. 4 shows the getter cover of FIG. 3, wherein (a) is a plan view and (b) is a side view.

DESCRIPTION OF THE REFERENCE NUMERALS

1: Frame 2: Inner shield

3: opening 4: getter

5: shadow mask 6: getter shield

t: Shield W: Width

f: bent portion b: connecting portion

c:

The present invention relates to a getter cover for a cathode ray tube, and more particularly to a getter cover for a cathode ray tube, which can prevent scattering of barium in a getter provided in a cathode ray tube.

1, a funnel 8 having a neck portion is fixed to a rear portion of a panel 7, and a frame 1 provided inside the panel 7 is provided with an electron beam A shadow mask 5 serving as a color ray of the electron beam is installed on the frame 1. In order to prevent a phenomenon that the path of the electron beam is distorted due to the influence of an external magnetic field behind the frame 1 A shield 2a is provided.

In the process of assembling the cathode ray tube, the operation of coating the graphite band and the phosphor on the inner surface of the panel 7 is completed, and then the emulsion is coated on the upper surface to increase the flatness, In order to increase the brightness of the screen, aluminum is sputtered to complete the formation of the fluorescent film.

Thereafter, a frit glass (liquid glass) is applied to the connection surface between the Coated Panel Shadow Mask Assembly (CMA) having the shadow mask 5 integrally formed therein and the funnel 8 coated with graphite on the inner surface, Approximately 350 To the ceiling furnace.

After the panel 7 and the funnel 8 are fused together by the above-described process, the electron gun is sealed on the neck portion of the funnel and then the exhaust process is performed. In the exhaust process, the exhaust cart is connected to the barrel formed integrally with the stem of the electron gun Up to about 350 And the remaining gas in the cathode ray tube is extracted for about 1 hour and 20 minutes while moving the tunnel to become the cathode ray tube.

The degree of vacuum in the cathode tube thus vacuumed by mechanical means is about 5 10 ^-6 Torr. However, the electron emission from the electron gun is difficult with such a vacuum, and the vacuum degree is rapidly increased due to the outgassing occurring at the time of driving.

Therefore, in order to solve such a problem, when the getter 4 is installed in the cathode ray tube and the heat is externally applied, barium in the getter is scattered into the cathode ray tube through the opening 3 to form a getter film, Thereby suppressing gas absorption and generation.

As a result, the vacuum degree of the cathode ray tube becomes higher than that after the exhaust, 10 ^-5 Torr. This phenomenon is that the vacuum level temporarily rises due to the gases remaining in the getter, and the ionization phenomenon occurs during aging, and the bond with the getter becomes vigorous and the degree of vacuum is drastically lowered.

The vacuum degree is maintained until the end of the life of the cathode ray tube. Aging is a process of thermally decomposing the carbonate in the cathode to activate electrons. When the process is completed, the cathode ray tube manufacturing process is completed.

As shown in FIG. 1, the shadow mask 5 attached to the inner surface of the panel 7 on the basis of the frame 1 serving as a support acts as an electron beam emitted from the electron gun And the inner shield 2a attached to the lower end of the frame 1 serves to prevent the distortion of the electron beam due to the influence of the external magnetic field, The getter 4 attached to the substrate 1 serves to scatter barium by an angle? Of about 120 degrees by high-frequency heating.

However, in such a conventional cathode ray tube, when barium in the getter 4 is scattered by high-frequency heating, a part of barium is scattered toward the shadow mask 5 to form an uneven film, A dumping phenomenon occurs in which the shadow mask 5 is unevenly thermally expanded.

In addition, since barium scattered in the getter 4 is scattered to the effective surface on the side of the shadow mask 5, part of the barium is applied to the aluminum film coated on the phosphor through the fine holes of the shadow mask, Resulting in lowering the luminance.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a cathode ray tube in which scattered barium in a getter in a cathode ray tube is deposited on the effective surface of a shadow mask by a simple structure, And the object of the present invention is to prevent a doming phenomenon in which the mask is thermally expanded unevenly.

Another object of the present invention is to prevent the phenomenon in which the luminance is lowered by preventing the emission of the phosphors from being disturbed as barium in the getter is scattered and applied to the aluminum film coated with the phosphor through the holes of the shadow mask.

According to an aspect of the present invention, there is provided a getter cover for a cathode ray tube having a getter shield for preventing barium in a getter from scattering to an effective side of a shadow mask through an opening on an opening formed in an inner shield do.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 4.

2 is a cross-sectional view showing a cathode ray tube equipped with the present invention, FIG. 3 is a longitudinal sectional view showing part A of FIG. 2, and FIG. 4 is a getter cover of FIG. 3 (a) ) Is a side view.

An inner shield (2) for shielding a magnetic field is fixed to a frame (1) provided in a cathode ray tube. Barium in a getter (4) is fixed on an opening (3) of the inner shield by a shadow mask The getter shield 6 is integrally formed or separately provided so as to prevent the getter shield 6 from being scattered to the effective surface side.

The getter shield 6 has a thickness t of about 0.15 (m < 2 >) so that the getter shield 6 can flexibly respond to the getter 4 size. And the width and width W of the central portion are equal to the thickness of the inner shield 2 at about 25 to 40 Respectively.

This is so that when barium is scattered directly above the getter 4, it is sufficiently controlled so that a part can be scattered only inside the cathode ray tube.

One end of the getter shield 6 is provided with an inclination angle of about 5 to 10 (B) is provided.

When the getter shield 6 is separately provided in the inner shield 2, a fixing portion c for fixing the getter shield to the inner shield 2 by welding or the like is provided at the end of the connecting portion b, ~ 50 And a bent portion f is bent downward at the other side of the getter shield 6 perpendicular to the connecting portion b.

At this time, the bending angle of the vertical width (W) and the folded portion (f) is appropriately set as necessary, and the folded portion (f) Respectively.

2 to 4, the getter shield 6 is integrally formed on the opening 3 of the inner shield 2 attached to the frame 1 provided in the cathode ray tube Since the getter shield 6 is prevented from scattering toward the effective surface side of the shadow mask 5 when the barium in the getter 4 is scattered in the upward direction of the getter, As shown in FIG. 3, inner side pressing and back flashing are performed simultaneously with the inner shield 2 as a reference.

More specifically, when the getter 4 is heated at a high frequency from the outside of the cathode ray tube, when the barium in the getter is scattered upward, the getter shield 3, which suppresses scattering of barium on the opening 3 of the inner shield 2, The barium scattered on the getter mask 6 collides against the getter shield, and then part of the barium does not scatter to the effective surface side of the shadow mask 5 as shown by the dotted line in FIG. 3, and only the ineffective surface of the shadow mask and the inside of the cathode ray tube The inner side pressing of the cathode ray tube is performed.

Accordingly, even if the barium film is not formed on the effective surface of the shadow mask 5 and the electron beam hits the shadow mask 5, the shadow mask is uniformly thermally expanded, thereby suppressing the occurrence of the dumping phenomenon as much as possible.

As described above, since the barium is not scattered to the effective surface side of the shadow mask 5 by the getter shield 6, the barium is applied to the aluminum film coated on the phosphor or prevented, .

On the other hand, some barium scattered is reflected between the inner shield 2 and the funnel 8 by being hit by the getter shield 6, so that the back pressing is performed simultaneously with the inner side pressing.

As described above, according to the present invention, the getter shield 6 is integrally formed or installed on the opening 3 of the inner shield 2, so that the barium in the getter 4 during the pressing process is removed from the shadow mask 5 It is not scattered to the effective surface side. Therefore, the dome phenomenon in which the shadow mask 5 swells up during operation of the cathode ray tube is suppressed to the utmost, and the luminance is prevented from being lowered due to the application of barium to the aluminum film.

Claims (4)

And a getter shield for preventing the barium in the getter from being scattered to the effective surface side of the shadow mask through the opening on the opening formed in the inner shield. The getter cover for a cathode ray tube according to claim 1, wherein the getter shield is integrally formed or installed in the inner shield. The getter shield according to claim 1, wherein the getter shield has a thickness equal to the thickness of the inner shield so that it can flexibly correspond to the getter size, a width and a width of the getter shield larger than the getter, Getter cover for cathode ray tube with photo connection. The getter cover for a cathode ray tube according to claim 3, wherein a fixing part for fixing the getter shield to the inner shield is integrally formed at the end of the connection part when the getter shield is separately installed in the inner shield.