KR930007899B1 - Method of sealing a crt - Google Patents

Abstract

The method is related to the sealing of the neck section of CRT bulb with stem section of an electron gun by frit. The method comprises coating frit (10) on the periphery of flange (4a) of stem section (4), inserting the flange (4a) to cylindrical neck section (2) of CRT and bonding the flange with the section, and sealing the flange with the section after heating. The neck structure suitable for sealing, comprises neck section (2) with elongated cylindrical tube section (2a); stem section (4) of an electron gun having flange (4a) with slanted peripheral surface (4b).

Description

Cathode ray tube encapsulation method and suitable neck encapsulation structure

1 is a cross-sectional state diagram before sealing showing the structure of the neck portion and the electron gun stem portion of the cathode ray tube implementing the first embodiment of the present invention.

FIG. 2 is a cross-sectional state diagram showing after sealing of FIG.

3 is a view corresponding to FIG. 1 showing a second embodiment of the present invention;

4 is a view corresponding to FIG. 1 showing a third embodiment of the present invention.

FIG. 5 is a cross-sectional state view showing after sealing of FIG.

FIG. 6 is a view corresponding to FIG. 1 showing a modification according to the third embodiment of the present invention. FIG.

* Explanation of symbols for main parts of the drawings

2: neck portion 2a: terminal portion

4 stem portion 4a flange

4b: slope 4c: jaw

10: frit 40b: end

The present invention relates to an encapsulation of a cathode ray tube that seals between a neck portion of a bulb and a step portion of an electron gun assembly, and more particularly, to a cathode ray tube improved to bond the neck portion of a cathode ray tube and a stem portion of an electron gun to frits. The present invention relates to a sealing method and a neck portion sealing structure suitable for the same.

In the manufacture of the cathode ray tube, the electron gun assembly is enclosed inside the neck portion of the bulb, and in this process, it is to be closely sealed between the neck inner circumferential wall of the bulb and the stem portion of the electron gun assembly.

However, since the stem portion of the neck portion and the electron gun assembly is made of glass, conventionally, the torch flame is applied to the neck outer circumferential surface in a state where the electron gun assembly is sealed with the neck portion of the bulb to seal the glass surfaces in contact with each other.

In this method, the high temperature torch flame is applied to the outer periphery of the neck portion, so that each electrode of the electron gun assembly receives high temperature and is highly oxidized, and the free vapor generated during the fusion between the neck portion and the stem portion is evaporated. There is a drawback that the film penetrates into the phosphor pattern of the upper panel and causes a film defect to fill the stripe, and also has the drawback that the glass is too time-consuming to melt by the torch flame.

Korean Patent Publication No. 2095 No. 90-8197 proposes a new cathode ray tube encapsulation method that solves the problems of the conventional encapsulation method described above.

In the method disclosed herein, a low melting frit is melted by radiant heat through the metal ring by interposing a metal ring between the neck portion and the stem portion, receiving a low melting frit into the inside of the metal ring, and then performing a high frequency heating from the outside. Thus, the neck portion, the stem portion, and the metal ring are integrally sealed.

The above method has the advantage of fundamentally solving all the causes of the problems caused by the conventional torch flame, but in order to realize this method, it is necessary to prepare a suitable type of metal ring, which is also made of nonmagnetic material. Increasing the number and inserting the metal ring into the outer periphery of the neck part in the process, and then making the stem part of the electron gun be located inside the metal ring, which makes the process cumbersome. From the side, it's hard to see it's perfect.

Accordingly, an object of the present invention is to provide an encapsulation method of a cathode ray tube improved so that a neck portion and a stem portion can be directly bonded using only frit as a medium without using a separate structure such as a metal ring, and a sealing structure suitable for the neck portion. .

In order to achieve the above object, the present invention applies a conventional pleat to the outer periphery of the flange retained by the stem portion of the electron gun, and then joins the flange to the neck portion of the cathode ray tube of which the end portion has a normal cylindrical shape. A method of sealing a cathode ray tube is provided in which the flange and the neck portion are fired while being kept in a bonded state, and the neck portion and the flange are joined by the frit.

As an example of an encapsulation structure suitable for the above method, the present invention provides an electron gun having a neck portion having a terminal portion extending into a conventional cylindrical tube, and an flange having an outer diameter coinciding with the inner diameter of the neck portion and the outer circumferential surface being inclined. The neck portion and the flange portion of the stem portion of the cathode ray tube structure configured to be joined by a common pleat propose a neck portion sealing structure.

As another example of the encapsulation structure, the present invention has a longitudinal end portion extending from a conventional cylindrical tube, a neck portion provided with an inclined surface on an inner circumferential surface thereof, a flange having an outer diameter corresponding to the outer diameter of the neck portion, and an outer circumferential surface formed of an inclined surface The stem portion of the electron gun, and the neck portion and the flange propose a neck portion sealing structure of the cathode ray tube configured to be joined by a common pleat.

When the inclined surface is provided to the inner peripheral surface of the end portion of the neck portion and the outer peripheral surface of the flange as in the above example, it is possible to obtain the advantage that the joint area by frits becomes wider.

As another example of the encapsulation structure, the present invention is composed of a stem portion of an electron gun having a neck portion extending from a conventional cylindrical tube and an outer diameter corresponding to the outer diameter of the neck portion, and having a flange formed at an end portion thereof with an outer circumferential surface thereof. The neck portion and the flange propose a neck portion sealing structure of a cathode ray tube configured to be joined by a common pleat.

In the above configuration, the end portion of the flange may be formed as a semicircular concave groove, and in this case, an advantage of interposing a sufficient amount of frit between the neck portion and the flange can be obtained.

The frit suitable for the present invention is a conventional one that is cured in a minor component atmosphere of 400-500 ° C., and the means for firing the frit may be applied with a resistance or an induction heating method.

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

FIG. 1 is a cross-sectional view showing the first embodiment of the present invention, showing the structure before sealing the neck portion 2 and the stem portion 4 of the cathode ray tube.

The end portion 2a of the neck portion 2 is a conventional cylindrical tube cut into a quadrilateral cross section, and the stem portion 4 corresponding thereto has a flange having an outer diameter equal to that of the neck portion 2. 4a).

On the extended surface of the flange 4a, a plurality of leads 6 are arranged to penetrate in the axial direction of the stem portion 4, and an electron gun 8 is attached to the upper side thereof.

The outer circumference of the flange 4a is formed of an inclined surface 4b.

The frit 10 is applied to the inclined surface 4b. At this time, the jaw 4c slightly higher toward the center from the inclined surface 4b is not applied so that the applied frit 10 does not propagate to the center side of the flange 4a. It is good to form.

In addition, the frit 10 is applied over the entire inclined surface 4b, and after the application of the frit 10 is finished, the flange 4a of the stem portion 4 inside the end portion 2a of the neck portion 2. When the stem portion 4 is inserted as shown in FIG. 2, the frit 10 applied to the inclined surface 4b seals between the inner circumferential surface of the neck portion 2 and the outer circumferential surface of the flange 4a. Done.

The assembled state of the neck portion 2 and the stem portion 4 is preserved by using a suitable jig means until the frit 10 is plastically cured.

Firing of the frit 10 may be carried out by resistance heating or induction heating, and the firing temperature thereof is suitably within the range of 400-500 ° C.

3 is a cross-sectional view corresponding to FIG. 1 showing a second embodiment of the present invention.

In this embodiment, the neck 2 has at its end 2a a camper 2b corresponding to the inclined surface 4b of the flange 4a.

Since the area in contact with the frit 10 is increased by the camper 2b of the neck portion 2, according to this embodiment, the bonding force between the neck portion 2 and the stem portion 4 becomes strong.

4 is a cross-sectional view showing the third embodiment according to the present invention, showing the state before the neck portion 2 and the stem portion 4 are sealed.

As in the first embodiment, the neck portion 2 is cut in the end portions 2a so that the stem portion 4 corresponds to the flange 4a having the same outer diameter as that of the neck portion 2. Holds.

Further, a plurality of leads 6 are arranged through the center of the flange 4a along the axial direction of the stem 4, and an electron gun 8 is connected and attached to the upper side thereof. Although the same, the flange 4a has the edge part 40b in the outer peripheral side.

This end 40b has a lower height than the center side to provide a surface on which the frit 10 can be applied.

The frit 10 is applied over the entire surface of the end portion 40b. After the application of the frit 10 is finished, the flange 4a of the stem portion 4 is terminated by the end portion 2a of the neck portion 2. When the is inserted in close proximity, the frit 10 is sealed between the neck portion 2 and the stem portion 4 as shown in FIG.

Similarly in this embodiment, the state where the neck portion 2 and the stem portion 4 are so close is preserved by a suitable jig means until the frit 10 is fired.

6 is a cross-sectional view corresponding to FIG. 1 showing a modification of the third embodiment.

In this embodiment, the end portion 40b of the flange 4a is formed of a semicircular recess.

As the end portion 40b is formed as a concave groove, the frit 10 can be applied on the flange 4a more stably and in sufficient quantity so that the encapsulation between the neck portion 2 and the stem portion 4 can be applied. The condition will improve.

As described above, the present invention is a method of fusion using a conventional torch flame because the present invention is to be sealed by frit by changing only the shape of the neck and stem without requiring a separate structure in sealing between the neck and the stem. It is possible to fundamentally solve the problems seen at the same time and at the same time does not require an increase in the number of parts required, so it has the advantage of encapsulating the cathode ray tube in the most economical way.

Claims (6)

In encapsulating the stem portion of the electron gun assembly in the neck portion of the cathode ray tube, the ordinary frit 10 is applied to the outer periphery of the flange 4a held by the stem portion 4 of the electron gun, and then the flange 4a is terminated. The shape of the portion 2a is inserted into the neck portion 2 of the cathode ray tube of the usual cylindrical shape and joined, and is fired while maintaining the state in which the flange 4a and the neck portion 2 are joined as it is. A method of encapsulating a neck portion of a cathode ray tube in which a neck portion 2 and a flange 4a are joined by a frit 10. A neck portion 2 having a terminal portion 2a extended by a normal cylindrical tube, and an outer diameter corresponding to the inner diameter of the neck portion 2 and a flange 4a having an outer circumferential surface formed of an inclined surface 4b are provided. A neck portion encapsulation structure of a cathode ray tube made of a stem portion (4) of a holding electron gun, wherein the neck portion (2) and the flange (4a) are joined to each other by a common frit (10). The neck portion 2 provided with the camper 2b on the inner circumferential surface of the terminal portion 2a extended by the ordinary cylindrical tube, and the outer diameter corresponding to the outer diameter of the net portion 2, and the outer circumferential surface is inclined surface 4b. The neck portion encapsulation structure of a cathode ray tube made of a stem portion 4 of an electron gun having a flange 4a formed in the shape, wherein the neck portion 2 and the flange 4b are joined to each other by a common frit 10. . The jaw 4c according to claim 2 or 3, wherein the flange 4a forms a jaw 4c for suppressing propagation of the frit 10 to a position adjacent to the center portion on the upper surface of the face opposite to the electron gun 8. Neck portion encapsulation structure of the cathode ray tube, characterized in that. Stem portion 4 of the electron gun having a neck portion 2 extending from a normal cylindrical tube and a flange 4a having an outer diameter corresponding to the outer diameter of the neck portion 2 and having an outer circumferential surface formed at the end portion 40b. And the neck portion 2 and the flange 4a are joined to each other by a common frit 10. 6. The neck encapsulation structure of a cathode ray tube according to claim 5, wherein the end portion (40b) of the flange (4a) is formed by a semicircular concave groove.