KR100297693B1 - Electrode assembly of electron gun for CRT - Google Patents

Abstract

Among the two electrodes forming the electron lens, at least one electrode having a low positive pressure applied thereon is formed with a first electrode formed with a large-diameter electron beam through hole sharing three electron beams, and is positioned at a predetermined depth from an edge of the first electrode. And a second electrode having an independent small diameter electron beam through hole formed therein, wherein the independent small diameter electron beam through hole positioned in the center of the three independent small diameter independent small diameter electron beam through holes formed in the second electrode is formed in an elongated shape. .

Description

Electrode assembly of electron gun for color cathode ray tube {Electrode assembly of electron gun for CRT}

The present invention relates to an electron gun for a cathode ray tube, and more particularly to an electrode assembly of an electron gun having a field extension focusing lens.

Typically, the cathode ray tube is preferably made as small and dense as possible, the diameter of the beam spot landing on the fluorescent surface in order to obtain a clear image in full screen.

To this end, the electron beam through holes of at least two electrodes constituting the main lens of the electron gun are conventionally enlarged. However, the electron beam through holes formed in the two electrodes are arranged inline and inserted into the neck portion of the cathode ray tube. It is impossible to make the diameter of the electron beam through hole larger than the eccentric distance of the electron beam through hole. If the eccentric distance is increased to increase the diameter of the electron beam through hole, the convergence characteristic of the electron gun is lowered, so that a large improvement effect cannot be expected. Therefore, in order to improve spherical aberration in the conventional main lens, as shown in US Patent No. 4,370,592 and shown in FIGS. 1 and 2, the exit side surface 5a of the focus electrode 5 and the final acceleration electrode 6 are shown. The large-diameter electron beam passing hole 5H through which the R, G, and B electron beams pass through a predetermined depth is immersed in the incident side surface 6a except for the edge portion thereof (hereinafter referred to as burring portions 5b and 6b). 6H) is formed and R, G, B independent small-diameter electron beam passing holes 5H 'and 6H' are formed at positions where a predetermined length is drawn from the burring portions 5b and 6b.

The electron beam passing through the main lens through the electron beam formed with the main lens formed by the focus electrode 5 and the final acceleration electrode 5 is the center because the large-diameter electron beam passing holes 5H and 6H are asymmetrical. The vertical and horizontal focusing components of the electron beam passing through the independent small-diameter electron beam passing hole and the electron beam passing through the independent small-diameter electron beam passing hole on both sides were different from each other to uniformly form the electron beam spot landing on the fluorescent surface. That is, as shown in FIG. 2, both side electron beams RB (BB) having passed through the large-diameter electron beam through hole of the focus electrode 5 or the final acceleration electrode 6 have burrs in which low voltage or high voltage are distributed in the horizontal direction. Close to the ring portions 5b and 6b, the central electron beam through hole is located away from the burring portions 5b and 6b, so that the electron beams RB (BB) on both sides in the horizontal direction are relatively strongly focused and centered. Electron beam GB, relatively weakly focused. And both side electron beams RB and BB are approximately equal to the focusing effect in the horizontal direction in the vertical direction since the distance from the burring portions 5b and 6b in the vertical direction is approximately equal to the distance in the horizontal direction. Since the center of the electron beam GB is subjected to the burring portions 5b and 6b, the distance in the vertical direction is closer than the distance in the horizontal direction, so that the electric field is affected by many electric fields in the vertical direction, thereby receiving a strong focusing force. Therefore, the electron beams RB (BB) and the center electron beams GB on both sides passing through the main lens have a substantially circular beam cross section and a horizontal beam cross section, respectively, so that a uniform electron beam cross section can be obtained on the typical light plane. There will be no.

An electron gun for a cathode ray tube for solving such a problem is disclosed in Utility Model Publication No. 93-4792.

As shown in FIG. 3, the electron gun has a first electrode 11 formed with a burring portion at an edge of the final acceleration electrode of the electron gun, and has a large-diameter electron beam passing hole 11H sharing three electron beams, and the first electrode ( And a second electrode 12 having three independent small-diameter electron beam through holes RH (GH) (BH) formed at a predetermined depth from an edge of the edge 11, and the large-diameter electron beam of the first electrode 11 is formed. The length of the burring portion 13 formed at the edge of the through hole 11H is longer than the outside independent small diameter electron beam through hole RH (BH) side, and the electron beam through hole GH side is formed longer inward.

Such an electrode may not easily form a long length of the burring portion 13 of the first electrode 11 corresponding to the independent small-diameter electron beam passing hole GH positioned at the center of the second electrode 12. In particular, since the divergence in the vertical direction occurs according to the length of the burring portion located in the center portion, numerical management according to the length of the burring portion is difficult.

The present invention was created in order to solve the above problems, it is easy to cross-sectional compensation of the electron beam due to the distortion of the electric field forming the main lens system, and improve the spherical aberration of the electron lens constituting the main lens system through the electron beam It is an object of the present invention to provide an electrode assembly of an electron gun for a color cathode ray tube which can prevent distortion of the cathode ray tube and improve the resolution of the cathode ray tube employing the same.

1 is a cross-sectional view showing an example of an electron gun for a cathode ray tube,

2 is a front view of a conventional final acceleration electrode,

3 is a partial ablation perspective view of a conventional final acceleration electrode,

4 is an exploded perspective view illustrating an electrode forming a main lens according to the present invention;

5 is an exploded perspective view showing another embodiment of the electrode assembly according to the present invention;

6 is a front view of the final acceleration electrode shown in FIG.

<Description of the symbols for the main parts of the drawings>

20; Final acceleration electrode 30; Focus electrode

31; A first electrode 32; Second electrode

32HR, 32HG. 32HB; Independent small diameter electron beam through hole.

In order to achieve the above object, the present invention provides a first electrode and a large-diameter electron beam and a hole in which one of the two electrodes to which the low potential is applied among the two electrodes forming the electron lens with different voltages, respectively, share three electron beams; A second electrode having an elongated shape having an independent small-diameter electron beam passing hole positioned in a predetermined depth from the edge of the first electrode and positioned at the center of the three independent small-diameter electron beam passing holes;

Among the two electrodes, the electron beam through hole positioned in the center of the independent small diameter electron beam through holes of the electrode to which the high potential is applied is formed in a circular shape.

In the present invention, the elongated independent small diameter electron beam passing hole is preferably formed in an elliptical shape.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

As shown in FIGS. 1 and 4, an electron gun 1 for a cathode ray tube according to the present invention forms a main lens system with a cathode 2, a control electrode 3, and a screen electrode 4 constituting a pre-triode tube part. A focus electrode 30 to which a low potential is applied and a final acceleration electrode 20 to which a relatively high high potential is applied are provided. The focus electrode 30 has a burring portion 31a formed at an edge thereof, and includes a first electrode 31 having a large-diameter electron beam passing hole 31H for sharing three red, blue, and green electron beams, and the burring portion ( The second electrode 32 is positioned inside the first electrode 31 so as to be spaced apart from the predetermined distance 31a by three independent small diameter electron beam passing holes 32HR, 32HG, and 32HB.

Here, the independent small diameter electron beam through hole 32HG located at the center of the three independent small diameter electron beam through holes 32HR, 32HG and 32HB formed in the second electrode 32 is formed in an elongated shape. That is, the independent small-diameter electron beam passing holes 32HR located at both sides are formed in a circular shape, and the independent small-diameter electron beam passing holes 32HG located at the center are formed in an elongated oval or rectangular shape. The shape of the independent small-diameter electron beam passing hole 32HG located at the center is not limited to the above-described embodiment, and can be modified in various forms. For example, it may be formed in an elongated keyhole shape, and may be formed in an elongated polygonal shape. Herein, the vertical length of the longitudinal independent small-diameter electron beam passing hole 32HG located at the center of the wing is the circular independent small-diameter electron beam passing hole 22G located at the center of the corresponding fourth electrode 22. It is preferable to form longer than the vertical length.

The final acceleration electrode facing the focus electrode 30 and to which a voltage higher than the voltage at which the focus electrode is applied is applied may include a third electrode 21 and a third electrode 21 having a large-diameter electron beam passing hole 21H through which three electron beams pass. The fourth electrode 22 is positioned inside the electrode and has independent small-diameter electron beam passing holes 22R, 22G and 22B, and the independent small-diameter electron beam passing hole 22R of the fourth electrode 22 is formed. The electron beam through hole located in the center of the 22G and 22B is formed in a circular shape.

As another embodiment of the electrode assembly, as shown in FIG. 5, the two electrodes may include large diameter forming portions 33 and 23 having large diameter electron beam passing holes 31H and 23H, and large diameter forming portions 33 and 23. The small diameter forming portions 34 and 24 formed with three independent small diameter electron beam through holes are formed at positions deeply inserted from the plurality of electrodes. The independent small-diameter electron beam passing holes formed in the electrode to which the high voltage is applied and the electrode to which the low voltage is applied among the two electrodes 30 'and 20' are the same as in the above embodiment and will not be described again.

Referring to the operation of the electron gun having an electrode assembly according to the invention configured as described above are as follows.

When a predetermined voltage is applied to each electrode of the cathode ray tube electron gun 1, a cathode lens is formed between the control electrode 3 and the screen electrode 4, and the screen electrode 4 and the focus electrode 30 A prefocus lens is formed between the electrodes and a kettle lens is formed between the focus electrode 30 and the final acceleration electrode 20. Therefore, the electron beam emitted from the cathode 2 is prefocused and accelerated in the cathode lens and the prefocus lens, and finally accelerated and focused in the kettle lens and landed on the screen surface of the cathode ray tube.

In this case, since the central independent small-diameter electron beam passing hole 32HG of the second electrode 32 provided in four portions of the first electrode 31 of the focus electrode 30 is formed in an elongated shape, the electron beam is used to The spherical aberration at the time of passage is self-corrected to obtain a uniform beam cross-sectional shape. That is, as shown in FIG. 6, a central electron beam, ie, a green electron beam BG, is emitted from the cathode 2 and passes through a kettle lens formed between the focus electrode 30 and the final acceleration electrode 20. ) Is located far from the burring portion 31a of the focus electrode 30 in the horizontal direction and relatively close to the burring portion 31a in the vertical direction, so that a strong focusing force is received in the vertical direction and in the horizontal direction. Receives a relatively weak focusing force has a horizontal beam cross-section, but the independent small diameter electron beam passing hole (32HG) located in the center of the second electrode 32 of the focus electrode 30 to which a high voltage is applied Since it is formed in an elongated shape, the electron beam passing therethrough is diverged in the vertical direction and is focused in the horizontal direction. Therefore, the cross section of the horizontally-shaped electron beam, which is horizontally shaped by the burring portion of the first electrode 31, is corrected to be circular.

In more detail, the vertical field of the independent small-diameter electron beam through hole 32GH formed at the center of the second electrode 31 of the focus electrode 30 is vertically enlarged, so that the electric field is vertically enlarged so that spherical aberration is small. The electron lens is formed. Therefore, the electron beam passing through the electron lens formed by the center electron beam passing holes 32GH and 22G is weakly focused or diverged in the vertical direction, and is corrected to the horizontal electron beam circle.

Both side electron beams, ie, red and blue electron beams, passing through the main lens between the focus electrode 30 and the final accelerating electrode 20 have horizontal and vertical distances from the burring portion 31a in the horizontal and vertical directions. The receiving focusing force is the same to form a circular beam cross section.

As described above, the electrode assembly of the electron gun for a color cathode ray tube according to the present invention has an elongated shape of an independent small-diameter electron beam passing hole located at the center of the electrode mounted in the large-diameter electron beam passing hole, thereby making the electron lens non-uniform in large diameter of the electron beam passing hole. One electric field can be compensated, and further, the cross section of the electron beam can be prevented from passing through the electron lens formed by the electrodes. Therefore, the astigmatism and spherical aberration of the electron lens may be improved and the focus characteristic of the electron beam may be improved.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (6)

A large diameter forming portion having a large diameter electron beam passing hole sharing three electron beams and a small diameter forming portion having a predetermined depth inlet from the large diameter forming portion, and having three independent small diameter electron beam passing holes formed therein, and having at least two different voltages applied thereto. In the electrode assembly of the electron gun for color cathode ray tube provided with electrodes, An independent small-diameter electron beam pass-through hole positioned in the center of the independent small-diameter electron beam pass-through holes of the electrodes to which the low voltage is applied is formed in a longitudinal shape; An electrode assembly for a color cathode ray tube electron gun, characterized in that the independent small diameter electron beam through hole positioned in the center of the independent small diameter electron beam through hole of the electrode to which a high voltage is applied is formed in a circle. The electrode assembly of the electron gun for color cathode ray tube according to claim 1, wherein the elongate independent small diameter electron beam passing hole is formed in an elliptical or polygonal shape. The vertical length of an elongated independent small diameter electron beam through hole of the electrode to which the low potential is applied is formed to be longer than the vertical length of a circular independent small diameter electron beam through hole positioned to the center of the electrode to which the high potential is applied. Electrode assembly of electron gun for color cathode ray tube, characterized in that. One of the two electrodes to which the different voltages are applied to form the electron lens, and the one electrode to which the low voltage is applied is a first electrode formed with a large-diameter electron beam sharing three electron beams, and a predetermined depth is drawn from an edge of the first electrode. A second electrode having an elongated shape having an independent small diameter electron beam passing hole positioned in the center of the three independent small diameter electron beam passing holes, Electrode assembly of a cathode ray tube electron gun, characterized in that the electron beam through hole located in the center of the independent small diameter electron beam through hole of the electrode to which the high potential of the two electrodes is applied in a circular shape. The electrode assembly of the electron gun for color cathode ray tube according to claim 4, wherein the elongate independent small-diameter electron beam passing hole is formed in an oval or polygonal shape. The vertical length of the longitudinal independent small-diameter electron beam through-hole of the electrode to which the low potential is applied is formed longer than the vertical length of the circular independent small-diameter electron beam through-hole positioned to the center of the electrode to which the high potential is applied. Electrode assembly of electron gun for color cathode ray tube, characterized in that.