KR960008108B1 - In-line type electron gun - Google Patents

Abstract

The electron gun is for improving the beam focusing characteristics and astigmatism influencing on the picture resolution by modifying a configuration of the electrode, which forms the main lens in the large diameter inline type electron gun. The burying section, which is scrolled towards the inside of the electrode from the aperture of the third and fourth electrodes, is formed in wave type. Rectangular type openings, not elliptical one, are made on the plate electrode of the electron gun, thereby satisfying the astigmatism and STC at the same time.

Description

In-line gun for color cathode ray tube

1 is a cross-sectional view schematically showing the internal structure of a conventional cathode ray tube.

2 is a perspective view of a part of a conventional large-diameter main focusing lens electrode unit developed.

3 is a perspective view of a part of the large-diameter main focusing lens electrode according to the present invention.

Figure 4 is a cross-sectional view showing the electric field shape according to the burring depth according to the present invention.

5 is a perspective view partially cut out another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

19, 20: plate electrodes 19a, 20a: rectangular hole

22: equipotential lines 23, 24: electron beam

60: third electrode 70: fourth electrode

61, 71: wavy horizontal burring 62, 72: vertical burring

63: through hole

The present invention relates to an electron gun for a color cathode ray tube, and is particularly suitable for improving astigmatism and beam focusing characteristics affecting screen resolution by changing the shape of an electrode forming the main lens of a large diameter inline electron gun.

The conventional inline electron gun has three independent cathodes 3 as shown in FIG. 1, a first electrode 4 which is a control electrode disposed at a predetermined distance from the cathode 3, and a second acceleration electrode. The electrode 5, the third electrode 6 as the focusing electrode, the fourth electrode 7 as the acceleration electrode, and the shield cup 8 with the contact spring 9 are arranged in the neck portion of the CRT. The electron gun is mounted toward the panel 11, and when the heater 2 embedded in the cathode 3 receives power from the stem pin 1 and generates heat, electrons are emitted from the cathode 3 by the heat. The electrons are controlled by the first electrode 4 as the control electrode and accelerated by the second electrode 5 as the acceleration electrode, and then pass through the third electrode 6 and the fourth electrode 7 as the main lens forming electrodes. Then, color is screened by the shadow mask 01 provided on the inner surface of the fluorescent surface 11a to cause the fluorescent surface 11a to emit light.

At this time, the structure of the third electrode 6 and the fourth electrode 7 for forming the main focusing lens is a shape in which the openings face each other as shown in FIG. (B) Burring portions 6a and 7a which are common to the three beams and have been constantly rolled into the electrode by the same amount in parallel with the outer circumferential surface, and the race track-shaped rim portions 6b and 7b by the burring portions. The outer hole is formed and the center hole 14a, 15a of the ellipse and the elliptic opening are cut in half with a predetermined distance to the rims 6b and 7b, and the parts which contact the outer peripheral surface of the electrode at both left and right ends are removed. (14b) (15b) formed plate electrodes (14, 15) are located, if the characteristics are not satisfied only by the opening of the ellipse, a pair of sunshade correction electrode 16 in parallel with the electron beam array direction (after Mounted on the shield cup (8) such that the three electron beams are sandwiched between To configure.

In this conventional electron gun, the main lens through which three electron beams pass is formed by the entire position between the third electrode 6 and the fourth electrode 7, and the main lens has a rim portion 6b having the same amount of burring ( 7b), one main lens common to the three electron beams is formed.

In addition, since the main lens common to the three electron beams has a stronger influence of the focusing / acceleration electrode in the vertical direction than the focusing / acceleration field in the horizontal direction, the shape of the three electron beams appears to be horizontally longer than vertical after the main lens passes. Therefore, to compensate for this horizontal phenomenon, the plate-shaped electrodes 14 and 15 having an elliptical opening having a vertical diameter longer than the horizontal diameter are disposed on the rim portions 6b and 7b at a predetermined interval. The structure allows the focusing force (hereinafter referred to as STC) of both side rims (R) (B) to the center beam (G), which is an important characteristic for both beams, due to the retreat of the plate electrodes (14, 15). The plate-like electrode structure with the opening of the ellipse alone has a large influence on the astigmatism due to the limitation of the change of focusing force between the horizontal beam and the vertical beam (hereinafter referred to as astigmatism) and the STC at the same time. The force is arranged to note a pair of shade-like correction electrode 16 is to satisfy the astigmatism and the STC of both beams simultaneously.

However, in the above-described conventional technology, the plate electrode having the elliptical opening and the correction electrode disposed under the shield cup as an auxiliary means satisfy the astigmatism and the STC, so that complicated parts such as the correction electrode are added during mass production. In the plate electrode structure having elliptic openings, there are problems that the design elements of the ellipse shape necessary for the adjustment of astigmatism are limited to the horizontal width, the vertical height, and the retreat amount at the rim of the plate electrode having the elliptic opening.

The present invention is to solve the above problems, which is particularly formed in the plate-like electrode which is formed in the wave shape and the burring portion rolled into the electrode from the opening of the third electrode and the fourth electrode forming the main focusing lens in the electrode It is to provide an inline electron gun for color cathode ray tube which can satisfy astigmatism and STC simultaneously by forming rectangular opening instead of elliptical opening.

Hereinafter, the configuration of the present invention will be described in detail by the accompanying drawings.

3 is a perspective view partially cutting the main focusing lens electrode according to the present invention. As shown in the drawing, the third electrode 60 and the fourth electrode 70 maintain a predetermined distance from the outer circumferential electrode at their openings. In the horizontal direction (parallel to the electron beam) of the burring portion rolled into the electrode in parallel with each other, the wavy horizontal burring portion 61 having a different burring depth by making the burring amount between the three electron beam centers larger than the burring amount of the three electron beam centers. And forming a vertical burring portion 62, 72 in which the burring amount of the fourth electrode is smaller than the burring amount of the third electrode in the rounded vertical direction of the burring part. In addition, rectangular plate-shaped electrodes 19 and 20 having rectangular openings 19a and 20a formed in the third electrode 60 and the fourth electrode 70 are formed at the rim portions 6b and 7b of the openings. The third electrode 60 and the fourth electrode 7 A through hole 63 perpendicular to the horizontal burring portions 61 and 71 is formed on the outer circumferential electrode of FIG. 5 independently of the three electron beams or in common for the three electron beams.

The operation and effects of the present invention configured as described above are as follows.

In order to satisfy both the astigmatism and STC of the main lens formed by the potential difference between the third electrode 60, which is the focusing electrode, and the fourth electrode 70, which is the acceleration electrode, perpendicular to the rim portions 6b, 7b of the race track shape. The reinforcement of the focusing force is compensated by strengthening the focusing force of the horizontal lens with the rectangular plate-shaped electrodes 19 and 20 disposed by retreating at regular intervals as shown in FIG. 3 and horizontally at the burring of the rims 6b and 7b. By constructing the shape of the burring in the form of a wave, the focusing force of the vertical lens is compensated for the abrupt shape change of each of the three electron beams by the plate electrodes 19 and 20 by making a difference between the center portion and the outer portion of the electron beam burring.

In addition, as shown in FIG. 4, the vertical burring amount of the second electrode 60 is larger than the vertical burring amount of the fourth electrode 70, thereby forming a shape of a strong electric field 22 inside the two beams 23, thereby making the two beams both sides. This increases the STC characteristic that 23 is focused toward the center beam 24. As shown in FIG. 5, an independent through hole is formed in the horizontal direction of the outer peripheral electrodes of the third electrode 60 and the fourth electrode 70 for each of the electron beams, or is horizontally common to the three electron beams. By forming the rectangular through-hole 63 longer than the vertical, it is possible to prevent the horizontal burring portion from being reduced by the outer circumferential electrode and the horizontal burring portion having the same potential.

As described above, the present invention can control the STC by changing the horizontal burring center value or the vertical burring amount from the burring to the rims of the third electrode and the fourth electrode. By controlling astigmatism, it is useful to satisfy both astigmatism and STC as a simple and easy design structure.

Claims (3)

In an inline electron gun in which a third electrode and a fourth electrode forming a main focusing lens face each other with an opening common to three electron beams, a horizontal direction (a direction parallel to the electron beam) of the burring portion rolled into the electrode from the opening. 3) the third electrode 60 and the fourth electrode 70 having the wavy horizontal burring portions 61 and 71 having different burring depths by making the burring amount between the three electron beam centers larger than the burring amount of the three electron beam centers. ), And the rectangular plate electrodes 19 and 20 having rectangular holes 19a and 20a formed for each of the electron beams are retracted from the openings of the two electrodes at a predetermined interval and mounted inside the electrode. Inline electron gun for color cathode ray tubes. The in-line electron gun for color cathode ray tube according to claim 1, wherein a through hole (63) perpendicular to the horizontal burring portion is formed in the outer circumferential electrodes of the third electrode (60) and the fourth electrode (70). The method of claim 1, wherein the third electrode (60) and the fourth electrode (70) have a smaller burring amount of the fourth electrode than the burring amount of the third electrode. Type inline electron gun for color cathode ray tube.