KR950004627B1 - Electron gun for color cathode-ray tube - Google Patents

Abstract

The electron gun has vertical blades which extend towards three cathodes by a set length, between electron beam passing holes formed on the outgoing plane of a focus electrode. There are lateral slots on the top and bottom of the electron beam passing holes. Horizontal blades are inserted into the slots, from on the top and bottom of electron beam passing holes formed on the incoming plane of the dynamic focus electrode. In use, a predetermined focus voltage is applied to the focus electrode, and a dynamic focus voltage, which is variably greater than the focus voltage according to the deflection of the electron beam is applied to the dynamic focus electrode.

Description

Electron gun for colored cathode ray tube

1 is a schematic perspective view showing an electron gun for a conventional color cathode ray tube.

2 is a schematic perspective view showing an electron gun for a color cathode ray tube according to the present invention.

Figure 3 (a) (b) is a perspective view showing several embodiments of the electron gun for color cathode ray tube according to the present invention.

4 is a schematic cross-sectional view showing the effect of the vertical breadboard and the horizontal breadboard on the electron beam.

* Explanation of symbols for the main parts of the drawings

11: electron gun 12: cathode

13 control electrode 14 screen electrode

15 focusing electrode 16 dynamic focusing electrode

15b: vertical breadboard 16b: horizontal rectangular hole

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun for a color cathode ray tube mounted on the neck portion of a cathode ray tube to emit an electron beam. It relates to an electron gun that can be formed uniformly at.

In general, the resolution of the color cathode ray tube depends on the size and shape of the electron beam landing on the fluorescent surface. Therefore, in order to obtain high resolution, it is important that the electron beam spot landing on the fluorescent surface is as small as possible, free from dents, and free from halo. However, conventional color cathode ray tube adopts in-line self-convergence method by adopting deflection yoke with R, G, B electron guns arranged inline type and horizontal deflection field with pincushion field and vertical deflection field with barrel field. The nonuniform magnetic field of the deflection yoke causes astigmatism of the electron beam generated from the electron gun and landing on the fluorescent film.

That is, when the electron beam generated from the electron gun is landed at the center of the fluorescent film, it is not influenced by the deflection magnetic field, and thus a circular electron gym spot with no spreading can be obtained, but when the electron beam is deflected to the periphery of the fluorescent film, It has a high brightness core portion that emanates in the horizontal direction and becomes over focused in the vertical direction and is long deformed in the horizontal direction of the electron beam, and has a low brightness upper spreading portion in the vertical direction, thereby reducing resolution.

Figure 1 shows an example of a conventional electron gun for color cathode ray tube to solve this problem.

The cathode (2), control electrode (3) and screen electrode (4) forming the pre-triode tube portion, the focus electrode (5), the dynamic focus electrode (6) and the final acceleration electrode (7) forming the auxiliary lens and the main lens system Arranged sequentially, the elongated electron beam through hole 5H and the elongated electron beam through hole 6H are formed on the surfaces of the focus electrode 5 and the dynamic focus electrode 6 that face each other. do. In addition, a focus voltage Vf and a final acceleration voltage Ve are applied to the focus electrode 5 and the final acceleration electrode 7, and the focus voltage Vf is a base voltage to the dynamic focus electrode 6, and is deflected. A parabolic type dynamic focus voltage Vf, which is changed parabolic according to the vertical synchronization signal of the yoke and also varies according to the horizontal synchronization signal, is applied.

The conventional color cathode ray tube electron gun 1 configured as described above has a dynamic focus voltage Vfd at the dynamic focus electrode 6 when the electron beam is not deflected, that is, when the electron beam emitted by the electron gun 1 is landed at the center of the fluorescent surface. Since only the focus voltage Vf, which is the base voltage, is applied, no quadrupole lens is formed between the focus electrode 5 and the dynamic focus electrode 6, so that the focus electrode 5 and the final acceleration electrode are not applied. The main lens formed between (7) causes the electron beam to land in the optimal state at the center of the fluorescent surface. When the deflection yoke of the electron beam is deflected toward the periphery of the fluorescent film, a dynamic focus voltage Vfd, which is varied in accordance with the vertical deflection synchronous signal and the horizontal deflection synchronous signal, is applied to the dynamic focus electrode 6 to provide the focus electrode. A quadrupole lens is formed between (5) and the dynamic focus electrode 6. That is, the horizontal electron beam through hole 5H formed on the emission side of the focus electrode 5 and the horizontal electron beam through hole 6H formed on the incidence side of the dynamic focus electrode 6 are horizontal in the vertical direction. A focusing lens and a strong diverging lens, which are relatively weak compared to the direction, are formed, and a focusing lens and a weak diverging lens, which are relatively stronger than the vertical direction, are formed in the horizontal direction. Therefore, the electron beam passing through the beam is focused in the horizontal direction and diverges in the vertical direction, and thus has an elongated beam cross section.

When passing through the main lens of the elongated electron beam and deflecting to the periphery of the fluorescent film, the distortion of the electron beam due to the nonuniform magnetic field of the deflection yoke is corrected to form a circular electron beam at the periphery of the fluorescent film.

However, as described above, the electron gun 1 for the color cathode ray tube has an elongated electron beam passing hole 5H and an elongated electron beam passing on the emission side of the focus electrode 5 and the one emission side of the dynamic focus electrode 6, respectively. Since the holes 6H are formed, it is difficult to assemble these elongated electron beam through holes 5H and the horizontally elongated electron beam through holes 6H so as to intersect correctly. In particular, there is a problem that the electrostatic lens is distorted by an external electric field, ie, a leakage field flowing through the neck part, because the gap between the dynamic focus electrode 6 and the focus electrode 5 forming the quadrupole lens is spaced a predetermined distance.

The present invention was created to solve the problems of the conventional electron gun for color cathode ray tube as described above, and uniformity does not occur over the typical Guam surface by correcting the astigmatism and focus characteristics of the electron beam due to the non-uniform magnetic field of the deflection yoke. It is an object of the present invention to provide an electron gun for a color cathode ray tube that can improve the resolution by forming a beam spot.

In order to achieve the above object, the present invention is a color cathode ray tube electron gun provided with a cathode, a control electrode and a screen electrode constituting the pre-triode tube portion, a focus electrode, a dynamic focus electrode and a final acceleration electrode constituting the auxiliary and main lens system And horizontal blades extending a predetermined length to the cathode side at upper and lower portions of the electron beam passing holes formed on the incident side of the dynamic focus electrode, and both edges of the electron beam passing holes formed on the exit side of the focus electrode corresponding to the horizontal blades. The horizontal braid is formed so as to be inserted into the horizontal rectangular quadrilateral hole by forming a vertical braid and a horizontal rectangular quadrilateral hole in the upper and lower portions, respectively.

Hereinafter, a preferred embodiment of a color cathode ray gun electron gun according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing an electron gun for a cathode ray tube according to the present invention, Figure 3 is a partially enlarged perspective view.

As shown in the drawing, the electron gun for a color cathode ray tube according to the present invention forms an auxiliary and main lens system with a cathode 12, a control electrode 13, and a screen electrode 14 constituting an anterior triode tube portion. ) And the dynamic focus electrode 16 and the final acceleration electrode 17 are arranged in sequence.

In addition, the horizontal braid 16b extending a predetermined length from the upper side and the lower portion of the electron via hole 16H formed in the incident side surface 16a of the dynamic focus electrode 16 according to the characteristics of the present invention is provided therefrom. And a vertical braid 15b and a horizontal shape at both edges and upper and lower portions of the electron beam passing hole 15H formed at the emission side surface 15a of the focus electrode 15 corresponding to the fraud horizontal braid 16b. A quadrilateral hole 15c is formed so that the horizontal braid 16b is inserted into the horizontal quadrilateral hole 15c of the focus electrode 15. At this time, when the horizontal braid 16b is inserted into the horizontal rectangular hole 15c, the width t and the height d of the horizontal rectangular hole 15c are prevented to prevent a short circuit due to mutual contact. It is preferable to form larger than the width (t ') and height (d') of the horizontal braid (16a).

On the other hand, the horizontal braid 16b formed above and below the electron beam passing hole 16H of the dynamic focus electrode 16 is preferably formed by, for example, lancing the incident surface side thereof. As shown in (b), a metal piece 16b 'having a predetermined length is attached to the incident side of the electron beam passing hole 16H of the dynamic focus electrode 16, and the front surface of the metal piece 16b' corresponds to the dynamic focus electrode 16. The upper and lower portions of the plate-shaped member 16 'provided with the electron beam passing hole 16H' may be bent toward the cathode 12 to form. In addition, the vertical braid 15b formed on the emission surface side of the focus electrode 15 may be formed by attaching a metal piece 15 'having a predetermined length.

In addition, a predetermined focus voltage Vf is applied to the focus electrode 15, the focus voltage Vf is applied to the dynamic focus electrode 16, and the parabola is varied in accordance with a vertical synchronization signal of deflection yoke. In addition, a dynamic focus voltage Vfd variable according to the horizontal synchronization signal is applied, and a high voltage anode voltage is applied to the final acceleration electrode 17.

Referring to the operation of the electron gun for the color cathode ray tube according to the present invention configured as described above are as follows.

In the electron gun for the color cathode ray tube according to the present invention, a prefocus lens is formed on the screen electrode 14 and the focus electrode 15 as each potential is applied to each electrode, and the focus electrode 15 and the dynamic focus electrode are provided. A quadrupole lens is formed between the 16, depending on whether the dynamic focus voltage Vfd is applied, and a main lens is formed between the dynamic focus electrode 16 and the final acceleration electrode 17. Accordingly, the electron beam emitted from the cathode 12 passes through the electrostatic lens formed between the electrodes, and then lands on the entire fluorescent film. The electron beam is not deflected by the deflection yoke of the electron beam, and lands in the central portion of the fluorescent film. In this case, since the dynamic focus voltage Vfd is not applied to the dynamic focus electrode 16, only the focus voltage Vf, which is a base voltage, is applied to the focus electrode 15 and the dynamic focus electrode 16. The voltage Vf is applied. Therefore, a quadrupole lens is not formed between the focus electrode 15 and the dynamic focus electrode 16. The electron beam emitted from the cathode 12 passes through the prefocus lens and then the dynamic focus electrode 16 and the final focus electrode. It passes through the central portion of the main lens formed between the acceleration electrodes 17 and lands optimally in the center of the fluorescent film.

When the electron beam emitted from the cathode 12 is deflected to the periphery of the fluorescent film by the deflection yoke, a dynamic focus voltage Vfd is applied to the dynamic focus electrode 16, so that the dynamic with the focus electrode 15 is performed. A quadrupole lens is formed between the focus electrodes 16. Therefore, the electron beam emitted from the cathode 12 passes through the prefocus lens and the quadrupole lens and is lengthened, passes through the main lens, and is deflected by deflection yoke to be scanned at the periphery of the fluorescent film. When the shaped electron beam is deflected by the deflection yoke, the electron beam spot that is distorted by the uneven magnetic domain and landed on the fluorescent film is circular. That is, the focus electrode 15 and the dynamic focus electrode 16 forming the quadrupole lens have an electron beam passing hole 15H formed at the emission side surface 15a and an electron beam passing hole 16H formed at the entrance side surface 16a. The vertical braid 15b and the horizontal braid 16b are respectively formed in the horizontal braid 16b, and the horizontal braid 16b is inserted into the electron beam passing hole 15H formed in the emission side surface 15a of the focus electrode 15. As shown in FIG. 4, the electron beam passing through the balls 15H and 16H receives a weak divergence force and a strong focusing force under the influence of the vertical blade 15b to which the focus voltage Vf is applied in the horizontal direction. A strong diverging force and a weak focusing force are received by the horizontal braid 16b to which the dynamic focus voltage Vfd is applied in the vertical direction. Therefore, the electron beam passing through this forms an elongate cross section.

The electron beam, which has been elongated while passing through the quadrupole lens, passes through the main lens and is deflected to the periphery of the fluorescent surface by the deflection yoke. Distortion is compensated for and has a circular electron beam spot upon landing at the periphery of the fluorescent surface. In addition, since the dynamic focus voltage Vfd and the focus voltage Vf which are the base voltages are applied to the dynamic focus electrode 16, the potential difference between the voltage applied to the dynamic focus electrode 16 and the final acceleration electrode 17 is small. As a result, the intensity of the main lens is weakened and the focal length of the electron beam becomes long, so that an optimum focus can be obtained when the electron beam is deflected to the periphery of the fluorescent surface.

The electron gun 11 according to the present invention has an electron beam passing hole formed at the exit surface side 15a and the incident surface side 16a of the focus electrode 15 and the dynamic focus electrode 16, respectively, when assembled by the tank gun jig. Since the positions 15H) and 16H form circular holes having approximately the same diameter, the position of the dynamic focus electrode 16 is not only set correctly but also in the horizontal quadrangular hole 15c formed in the focus electrode 15. By accurately inserting the horizontal braid 16b, the quality deterioration due to the degree of assembly can be completely eliminated.

As described above, according to the electron gun for a color cathode ray tube according to the present invention, astigmatism is achieved by preserving a non-uniform magnetic field of the deflection yoke by a quadrupole lens formed between the focus electrode and the dynamic focus electrode during deflection of the electron beam by the deflection yoke. And since it is possible to improve the focus characteristics, it is possible to manufacture a cathode ray tube having a clear image, there is an advantage that can completely eliminate the deterioration of quality due to the degree of assembly between the electrodes.

Claims (7)

An electron gun for a color cathode ray tube comprising a cathode, a control electrode, and a screen electrode forming a transposition triode, and a focus electrode, a dynamic focus electrode, and a final acceleration electrode forming an auxiliary and main lens system, wherein the electron focusing electrode is formed on the incident side of the dynamic focus electrode. A horizontal blade having a predetermined length extending to the cathode side is formed on the upper and lower portions of the electron beam passing holes, and the vertical blades and the horizontal bars are formed on both sides of the electron beam passing holes formed on the exit side of the focus electrode corresponding to the horizontal blades, and on the upper and lower portions, respectively. An electron gun for a color cathode ray tube, characterized in that a horizontal hole is formed so that the horizontal plate is inserted into the horizontal quadrangular hole. The electron gun for a color cathode ray tube according to claim 1, wherein the electron beam through hole formed on the emission side of the focus electrode is a circular through hole. The electron gun for a color cathode ray tube according to claim 1, wherein a metal piece having a predetermined length of a vertical braid formed on the emission surface side of the focus electrode is attached to both edge portions of the electron beam through hole of the focus electrode. The electron gun for color cathode ray tube according to claim 1, wherein the height and width of the horizontal quadrangular holes provided in upper and lower portions of the electron beam through hole of the focus electrode are larger than the height and width of the horizontal blade of the dynamic focus electrode. The electron gun for a color cathode ray tube according to claim 1, wherein the horizontal braid formed on the dynamic focus electrode is lancing processed on an incident side thereof. The electron gun for a color cathode ray tube according to claim 1, wherein a horizontal braid formed on the dynamic focus electrode is provided with a metal piece having a predetermined length above and below an electron beam passing hole of the dynamic focus electrode. The plate-shaped member of claim 1, wherein a horizontal braid formed on the dynamic focus electrode is attached to the incident side of the dynamic focus electrode and has an electron beam through hole corresponding to the electron beam through hole of the dynamic focus electrode on its front surface. An electron gun for a color cathode ray tube, wherein a protrusion formed at an edge portion is bent toward the cathode.