KR200374586Y1 - electron gun in color cathode ray tube - Google Patents

Abstract

The present invention relates to an electron gun for a color cathode ray tube. In particular, the coupling structure between the two members is improved to improve the binding force between the bead glass and the shield electrode which is connected to the electrode to which the focus voltage is applied to prevent creeping discharge. will be.

The present invention for this purpose is to divide the bead glass on the basis of the focusing electrode, and to be electrically connected to the focusing electrode while being supported by both bead glass between the divided bead glass.

Description

Electron gun in color cathode ray tube

The present invention relates to an electron gun for a color cathode ray tube. In particular, the coupling structure between the two members is improved to improve the binding force between the bead glass and the shield electrode which is connected to the electrode to which the focus voltage is applied to prevent creeping discharge. will be.

In general, the color cathode ray tube constitutes an outer shape by the combination of the panel 1 and the funnel 2, as shown in FIG. 1, and the mask 3 is provided with a rail (or frame) 4 inside the outer structure. Is fixed to the inner surface of the panel 1, and an electron gun 6 for emitting the electron beam 5 is enclosed in the neck portion 2a formed at the rear of the funnel 2.

In addition, an inner shield 7 is provided outside the path of the electron beam 5 so as to prevent the electron beam 5 emitted from the electron gun 6 from being distorted by the path of the external magnetic field. .

On the other hand, the electron gun 6 is usually composed of a plurality of electrodes for controlling, accelerating, and focusing the electron beam, in particular in FIG. 2 shown in one embodiment of the first electrode (61) from three mutually independent cathodes (60) , The second electrode 62, the third electrode 63, the fourth electrode 64, the first acceleration and focusing electrodes 65a and 65b, the second acceleration and focusing electrode 66, and the shield cup 67. The in-line type is sequentially arranged.

At this time, the electrodes are supported by impregnating both ends of a pair of bead glass 68, which is a non-conductor, and the electrode to which the focus voltage is applied to each of the electrodes is creeped. For prevention, a thin band-shaped shield electrode 69 is connected, and the shield electrode 69 is fixed to the surface of the bead glass 68 by vacuum evaporation.

In the above, creeping discharge means that stray electrons of the anode beam current collide with the inner wall of the neck portion 2a or the bead glass 68 near the anode voltage to generate secondary electrons. The charge accumulates in the potential, and the potential increases gradually before the collision.

As a result, the increased potential affects the lower electrode to induce field emission. The field emission generates another secondary electron and continues to increase the surface potential of the neck portion 2a. This phenomenon is called creeping discharge.

The shield electrode 69 is installed to prevent such creeping discharge, and serves to suppress the potential rise on the lower electrode side. In particular, when the shield electrode 69 is connected to the focus electrode, the shield electrode 69 has a constant potential. Since it has a distribution, the surface potential is lowered from the shield electrode installation position to the lower electrode, thereby preventing creeping discharge.

On the other hand, the outer surface of the bead glass 68 has a planar shape to prevent flow during the beading (beding) process for embedding each electrode on the inner surface.

At this time, both ends of the shield electrode 69 are fixed to the focus electrode by welding across the surface of the bead glass 67, and both ends of the shield electrode 69 are pulled to strengthen the contact force with the bead glass 67 during welding. Weld in state.

However, as the shield electrode 69 is loosened in the welding process, the contact force with the bead glass 68 falls.

In particular, the larger the contact area between the shield electrode 69 and the bead glass 68 can be improved as the extinction force of the creepage discharge is reduced, the lower the contact force of the shield electrode 69 and the bead glass 68 is creeping discharge It will lower the prevention effect.

In other words, the emission of the secondary electrons due to the stray electrons generated in the bead glass 68 or the neck portion 2a close to the anode voltage and the surface potential rise of the bead glass 68 are repeated. The raised surface potential of 68 moves to the lower electrode.

At this time, due to incomplete contact between the shield electrode 69 and the bead glass 68, the potential rise to the lower electrode may not be effectively suppressed, resulting in discharge due to the potential difference between the surface potential of the bead glass 68 and the lower electrode. This will cause damage to the cathode 60 or serious failure of the drive circuit.

The present invention has been made to solve the conventional problems as described above, the purpose is to improve the adhesion between the bead glass and the shield electrode.

The present invention for achieving the above object is to divide the bead glass based on the focusing electrode, the colored cathode ray is supported by both bead glass between the divided bead glass and the shield electrode is installed to be electrically connected to the focusing electrode A conventional gun is provided.

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

Figure 2 is a front view showing an embodiment of a conventional electron gun

3 is a perspective view of a shield electrode according to the present invention

Figure 4 is a longitudinal cross-sectional view of the coupling state of the shield electrode and the bead glass according to the present invention

5 is another longitudinal cross-sectional view of the shield electrode and the bead glass according to the present invention

6 is a coupling state of the shield electrode and the electron gun according to the present invention

Explanation of symbols for main parts of the drawings

65a, 65b: focusing electrode 68a. High Twist Beaded Glass

68b: low potential bead glass 70: shield electrode

71: seating plate 72: connection

3 is a perspective view of a shield electrode according to the present invention, Figure 4 is a longitudinal cross-sectional view of the coupling state of the shield electrode and the bead glass according to the present invention, Figure 5 is another longitudinal cross-sectional view of the shield electrode and the bead glass according to the present invention 6 is a diagram illustrating a state of coupling between the shield electrode and the electron gun according to the present invention, which will be described in detail with reference to the accompanying drawings.

The present invention divides a pair of bead glass (68) for supporting each electrode in-line as shown in Figures 3 and 4 into a portion with a high surface potential and a low portion based on the focusing electrode (65a), In addition, the focusing electrode 65a composed of two units was also divided.

In addition, the shield electrode 70 is connected between the divided high potential bead glass 68a and the low potential bead glass 68b while being connected to the focusing electrode 65a.

Meanwhile, in order to combine the divided high potential bead glass 68a, the low potential bead glass 68b, and the shield electrode 70, the structure has the following structure.

That is, the shield electrode 70 is formed in a flat plate shape, and both ends thereof are formed on a seating plate 71 which is respectively seated on the high potential bead glass 68a and the low potential bead glass 68b, and an inner surface of the seating plate. It is comprised by the connection piece 72 welded to the flange part 65c of the divided focusing electrode 65a, and maintaining the state connected electrically with the focusing electrode.

In addition, grooves 68c are formed in the high potential bead glass 68a and the low potential bead glass 68b so that the seating portion of the seating plate is inserted in the site where the seating plate 71 is seated. ) And the shielding electrode 70 are strengthened.

In particular, the groove 68c and the seating plate portion seated thereon may have a flat shape. However, as shown in FIG. It's a more efficient form.

Referring to the operation of the present invention configured as described above is as follows.

The bead glass is divided into a high potential bead glass 68a and a low potential bead glass 68b on the basis of the focusing electrode 64, and a shield electrode for suppressing an increase in potential at the lower electrode side between the two bead glasses. As the 70 is tightly coupled and a constant focus voltage is applied, a stable electric potential is formed on the surfaces of the bead glasses 68a and 68b.

As a result, creeping discharge can be effectively prevented by suppressing the potential rise at the lower electrode side, and the discharge current flowing from the high potential side to the low potential can be effectively blocked.

In particular, the grooves 68c are formed in the mounting portions of the shield electrodes 70 of the bead glasses 68a and 68b, so that both ends of the mounting plate 71 of the shield electrodes 70 are inserted into the shield electrodes 70. ) And better adhesion of each bead glass (68a, 68b) than the conventional form wound around the shield electrode on the surface of the bead glass, it is more effective to prevent creeping discharge, thereby preventing damage to the cathode, heater and drive circuit You can do it.

In addition, when a predetermined angle is given to the connection portions of the bead glass (68a) (68b) and the shield electrode 70, the coupling force and contact force between each of the bead glass (68a) (68b) can be improved, so that the effect of creeping discharge can be further improved.

The present invention as described above can improve the adhesion between the bead glass and the shield electrode, it is possible to minimize the creeping discharge generated in the lower electrode can prevent damage to the cathode, the heater, the drive circuit by the discharge.

Claims (4)

In the configuration comprising a plurality of electrodes arranged inline, and a pair of bead glass that is provided opposite to both sides of the electrode to fix each electrode, Each bead glass is divided into two parts on the basis of the focusing electrode, and the shielded electrode which is supported by both bead glasses and electrically connected to the focusing electrode is installed between the divided bead glasses. Electron gun. The method of claim 1, Shield electrode, A seating plate seated on both bead glasses; An electron gun for a color cathode ray tube, formed on an inner surface of the seating plate, the connecting piece being electrically connected to the focusing electrode by coupling with the focusing electrode. The method of claim 2, Electron gun for color cathode ray tube, in which mounting grooves are formed at the site where the shield electrodes of both bead glasses are seated. The method of claim 3, wherein An electron gun for a color cathode ray tube in which a seating groove and a shield electrode seated thereto are inclined at a predetermined angle.