KR910007653Y1 - Electron gun of in-line type crt - Google Patents

Abstract

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Description

Electron gun for in-line color cathode ray tube

1 is a cross-sectional view of the electron gun according to the present invention.

2 is an enlarged view and cross-sectional view of portion A of FIG.

3 is a perspective view of the fourth electrode and the fifth electrode shown in FIG.

4 is a perspective view of another embodiment that may be replaced with the fourth electrode indicated by B in FIG.

5 is a partial cross-sectional view of the outer lens forming hole of the conventional electrode corresponding to FIG. 2, (a) shows a state in which the central axis of the lens forming hole is spaced horizontally at regular intervals, and (b) protrudes toward the inner side of the electrode. The end of the lip of the formed lens forming hole is inclined.

* Explanation of symbols for main parts of the drawings

13, 23: first and second auxiliary electrode 14, 24: arc-shaped cutout of the auxiliary electrode

12, 22: forming the outer lens of the electrode

The present invention relates to an improvement of an electron gun for inline type color cathode ray tubes, and more particularly to an improvement in manufacturing.

In-line color cathode ray tube adopts various means for concentrating, so that three electron beams passing through the same plane can be unfolded and concentrated at one point on the grille, especially red and blue among three beams. On both sides of the signal electron beam, the beam is focused on the central electron beam, which is mainly the electron beam of the green signal, on the path where the beam is focused and accelerated by various electrodes.

Therefore, convergence of the electron beam is achieved by refracting toward the same point of the outer electron beam. As a method for this purpose, as shown in FIG. 5 (a), the lens forming holes 1 and 2 facing each other are formed close to the cathode side by forming their respective central axes so as to be horizontally spaced at regular intervals. The electron beam passing through the lens forming hole of the electrode, that is, the central axis of the incident side lens forming hole 1 is caused to be incident eccentrically with respect to the center of the electrostatic lens 3. Accordingly, the lip 4, 5 is formed in a cylindrical shape around the beam emitting-side lens forming hole as shown in FIG. 5 (b). The end of the inclined portion is inclined so that the lens formed thereon is inclined so that the electron beam is refracted toward the center electron beam side. This is a somewhat exaggerated display of one example, in addition to these electrodes by the wedge (Wedge) processing method, that is, the inner side of each outer lens forming hole is low and the outer side of the electrode is formed at high. The performance of the electrode to be concentrated by the eccentricity described first in the above-described prior art depends on its performance by the amount of eccentricity (center axis spacing of the lens-forming holes), and their spacing varies greatly in the process of assembling the electrode. do. Therefore, there is a problem that the productivity is also lowered as well as an increase in the defective rate of the product. As described above, the electrodes formed by the inclined lip formed around the lens forming hole or the electrode by the wedge processing method are very demanding in processing method and the processing time is longer than other processes.

Therefore, the present invention aims to provide an in-line color cathode ray tube electron gun which has a simple structure, which is simple to manufacture and easier to concentrate.

In order to achieve the above object, the present invention is to provide a main lens portion or an auxiliary lens portion of an inline type electron gun. A first auxiliary electrode of a flap is provided outside the outer lens forming hole of the preelectrode, and a second auxiliary electrode of the flap is provided inside of the outer lens forming hole of the post electrode located on the electron beam exit side opposite to the outer lens forming hole. There is a characteristic to the point.

Hereinafter, the present invention will be described in more detail with reference to one embodiment illustrated in the accompanying drawings.

In FIG. 1, a multi-stage focused electron gun is shown to illustrate the present invention. The cathode (K), the first electrode (G ₁ ), the second electrode (G ₂ ), and the auxiliary lens, which form an anterior tripolar portion, are illustrated. And the third electrode G ₃ , the fourth electrode G ₄ , the fifth electrode G ₅ , and the sixth electrode G ₆ constituting the main lens, are assembled as a structure. The first and second auxiliary electrodes 13 (1) and 23 of the first and second auxiliary electrodes 13 and 23 are arranged on the fourth electrode G ₄ and the fifth electrode G ₅ formed so that the lens forming holes facing each other form the auxiliary lens. Are installed respectively. Specifically, as shown in FIG. 3, the lens forming holes 12 (outside) of the lens forming holes 12, 11 and 12 of the fourth electrode G ₄ positioned on the electron beam incidence side ( First auxiliary electrodes 13 and 13 on which arc-shaped cutouts 14 are formed are attached to the outer side of 12. The other side of the lens forming holes 22, 12, 22 of the fifth electrode G ₅ positioned on the emission side of the electron beam is disposed toward the inner side of the outer lens forming holes 22, 22. Auxiliary electrodes of the upper bar are provided. In this embodiment, arc-shaped cutouts 24 and 24 are formed at both ends thereof so as to coincide with the inner edges of the outer lens forming holes 22 and 22. A second auxiliary electrode 23 having a through hole 25 coinciding with the central lens forming hole 21 of the electrode G ₅ is provided. In this case, the inner ends of the first auxiliary electrodes 13 and 13 and the outer ends of the second auxiliary electrodes 23 overlap each other with respect to the center of the outer lens forming holes 12, 12, 22, and 22. It is preferable not to. The through hole 25 formed in the second auxiliary electrode 23 is for preventing the beam characteristic change caused by the central lens forming hole 21 from occurring. In some cases, the through hole 25 is removed. As a result, the second auxiliary electrodes may be separated into two similar shapes to the first auxiliary electrodes and attached to the inner edges of the outer lens forming holes 22 and 22.

On the other hand, as the auxiliary electrode attached to the fourth electrode G4, as shown in FIG. 13 ') is also possible.

Here, a set of the first auxiliary electrode 13 and the second auxiliary electrode 23 may be installed in the main lens unit as well as the auxiliary electrode unit as necessary.

As described above, the present invention employs the first and second auxiliary electrodes of the first and second auxiliary electrodes as an auxiliary means for primarily concentrating on the auxiliary lens, which is before the final acceleration and concentration of the electron beam in the main lens. Convergence drift caused by an error in the focus voltage applied to the electrode G ₅ can be improved.

That is, when the focus voltage is changed, the magnification of the main lens is changed and thus the refraction angle of the electron beam is changed. This results in underfocus or overfocus phenomena, which are improved according to the present invention. That is, when the focus voltage is high, the refraction angle of the auxiliary lens is increased, while the refraction angle of the main lens is small. When the focus voltage is lowered, the above is reversed.

Therefore, the total refraction angle of the electron beam passing through them is kept constant regardless of the focus voltage, so that constant convergence is always possible. As shown in FIG. 2, the auxiliary trench main portion is enlarged as an outer lens forming portion, and is formed in the outer side of the lens forming hole 12 on the beam incident side and the inner side of the lens shaped hole 22 on the beam exit side. Since the second auxiliary electrodes 13 and 23 are positioned, the lens formed thereby is inclined to one side as shown by the imaginary line.

This is because when the high voltage power is applied to the positive electrode (G ₄ ) (G ₅ ), the coincidence lines formed around it are inclined at the same angle as the lens. As a result, the electron beam is centered according to the angle of the inclined electrostatic lens. It becomes refractive. Therefore, convergence of both outer electron beams is easily achieved by the electrostatic lens deformed by the auxiliary electrodes at both outer sides.

If necessary, if the auxiliary electrode as described above is attached to the main lens unit provided with the usual convergence means as described above, it will help in final concentration and convergence will be improved.

Since the auxiliary electrode changes the angle of formation of the equipotential lines forming the electrostatic lens by the thickness thereof, the refractive index of the electron beam can be easily adjusted according to the thickness thereof, and is formed in a simple shape and simply attached to the main electrode by welding. It is possible to make the production is simple, and the production cost is advantageous.

Claims (3)

Of both electrodes each having three lens forming holes facing each other at regular intervals to form the main lens part or the auxiliary lens part, the outer side of the outer lens forming hole of the preelectrode positioned on the side from which the electron beam is incident from the cathode side An inner end portion of the first auxiliary electrode and an outer end portion of the first auxiliary electrode in the inner side of the outer lens forming hole of the post electrode positioned on the opposite electron beam exit side, provided with the eleventh auxiliary electrodes 13 and 13 An electron gun for an in-line color cathode ray tube, characterized in that a second auxiliary electrode (23) is provided so as not to overlap each other with respect to the center of success. The method according to claim 1, wherein arc-shaped cutouts (14) and (24) are formed on the auxiliary electrodes (13) (13) and (23) provided in the preelectrode and the post electrode, respectively, to coincide with the outer circumference of the lens forming hole. An electron gun for inline type color cathode ray tubes. The monolithic electrode (13 ') according to claim 1, wherein the auxiliary electrodes (13) and (13) attached to the preelectrode on the beam incidence side have an outer circumference of both outer lens holes and a long hole (26) at which both ends are rich. Electron gun for in-line color cathode ray tube, characterized in that formed by.