KR19990074509A - Shield cup structure of electron gun for color cathode ray tube - Google Patents

Abstract

The present invention relates to a shield cup structure of an electron gun for a color cathode ray tube, and to provide a high resolution image quality of a color cathode ray tube by minimizing a miss convergence amount of an electron beam emitted from the electron gun.

To this end, the present invention is a cathode (8), a control electrode (9), a tripolar portion consisting of an acceleration electrode (10), a focus electrode (11), a main lens portion consisting of an anode (12), the main Cylindrical shield cup 13 which is provided in front of the lens part and consists of the bottom part 14 and the edge part 15 so that the miss convergence g of the cathode ray tube screen periphery may be corrected, and the bottom part of the shield cup 13 (14) A color cathode ray tube electron gun (6) having a central beam through hole (16) formed in the center and side beam through holes (17) formed on both sides of the bottom portion (14) of the shield cup (13); Burrings 101 having a predetermined length are formed in the side beam passing holes 17, respectively, and slits 102 are formed in the edge portion 15 of the shield cup 13.

Description

Shield cup structure of electron gun for color cathode ray tube

The present invention relates to a color cathode ray tube, and more particularly to a shield cup of an electron gun for a color cathode ray tube.

In general, a color cathode ray tube uses an in-line electron gun, and in the cathode ray tube using the in-line electron gun, three electron beams of red (R), green (G), and blue (B) are horizontally aligned. In order to converge the three electron beams in one place of the fluorescent surface, the deflection yoke of the cathode ray tube applies a self-convergence using a non-uniform magnetic field.

As shown in FIGS. 1 and 2, the color cathode ray tube has a panel 1 mounted on the front side of the cathode ray tube, and red (R), green (G), and blue ( A fluorescent mask 3 coated with the phosphor of B), a shadow mask 4 having a color discrimination function of the electron beam a incident on the fluorescent surface 3 behind the fluorescent surface 3, and the panel 1 A funnel (2) coupled to a rear surface of the funnel (2) installed to maintain the interior in a vacuum state, and mounted inside the tubular neck portion (5) which is retracted to the rear of the funnel (2) to emit an electron beam (a) It consists of an electron gun 6 and a deflection yoke 7 arranged to deflect the electron beam a in the horizontal or vertical direction, surrounding the outer side of the funnel 2.

The electron gun 6 is composed of a three pole portion and a main lens portion, and the three pole portion controls to accelerate and control the cathode 8 in which the heater is embedded and arranged inline, and the electron beam a emitted from the cathode 8. It consists of an electrode (9) and an acceleration electrode (10), the main lens portion is a focus electrode (11) for focusing the electron beam (a) generated in the triode portion and the anode 12 for the final acceleration of the electron beam (a) The shield cup 13 is configured to correct misconvergence of the cathode ray tube screen periphery in front of the main lens unit, that is, the front surface of the anode 12, and to shield the anode 12 from the high-voltage conduction, the external magnetic field, and the electric field. Is installed.

The electrodes of the electron gun 6 are sequentially arranged in the tube axis direction at regular intervals apart from each other, and the electron gun 6 is enclosed in the neck portion 5 of the cathode ray tube.

In the color cathode ray tube of this structure, the panel 1 having the fluorescent surface 3 formed on the inner surface of the cathode ray tube and the funnel 2 coated with graphite having electrical conductivity on the inner side thereof are bonded together by fusion glass in a furnace at about 450 ° C. .

When an image signal is inputted to the electron gun 6 mounted to emit the electron beam a in the tubular neck portion 5 which is retracted behind the funnel 2, the cathode 8 of the electron gun 6 The electron beam a is emitted.

The electron beam a emitted from the cathode 8 passes through the control electrode 9, the acceleration electrode 10, the focus electrode 11, and the anode 12 by a voltage applied to each electrode of the electron gun 6. While being controlled, accelerated and focused, the light is emitted by passing through the shadow mask 4 in the state deflected by the deflection yoke 7 and hitting the fluorescent surface 3 applied to the inner surface of the panel 1 to emit the phosphor.

At this time, the shadow mask 4 has three in-line electron beams (a) corresponding to red (R), green (G), and blue (B) emitted from the electron gun 6, centering on the green in the shadow mask 4. It crosses with each other to perform a color screening function for causing each of the fluorescent surfaces 3 of red (R), green (G), and blue (B) of the screen to emit light.

As described above, the shield cup 13 installed in the electron gun 6 to correct the fine convergence of the cathode ray tube screen periphery on the front surface of the anode 12 and shield the high-voltage conduction, the external magnetic field, and the electric field from the anode 12. 3 and 4 have a cylindrical shape. The shield cup 13 has a bottom portion 14 and an edge 15 formed thereon, and the shield cup 13 In the bottom portion 14 of the center beam through hole 16 passing through the electron beam (a) and a plurality of side beam through holes 17 are formed, the electron beam (a) passing through the center beam through hole 16 ) Is the central beam (b), the electron beam (a) passing through the side passage hole 17 is formed as a side beam (c).

In the shield cup of the electron gun configured as described above, the electron beam a generated thermally and electrically at the cathode 8 is primarily formed at the triode of the electron gun 6 to be collected and accelerated at the main lens of the electron gun 6. The central beam (b) of the electron beam (a) passing through the center beam through hole 16 of the shield cup 13 and the electron beam passing through the side beam through hole 17 of the shield cup 13 in the entire area of the screen ( The side beams c of a) coincide to realize an image.

At this time, the deflection yoke 7, which deflects the electron beam a in the horizontal and vertical directions, has a shield cup located at a part of the deflection region because the pincushion magnetic field d, which deflects and converges in the horizontal direction, is operated at a high frequency. The pincushion magnetic field d is applied to 13 to generate an eddy current e over the entire edge portion 15 of the shield cup 13.

The intensity of the eddy current (e) is related to the magnetic flux density distribution and frequency and the radius of the eddy current (e) can flow, and the magnetic flux density distribution is generally proportional to the distance, so the center beam (b) and the side beam (c) It is well known that the magnetic flux density distribution in the central beam (b) is large when comparing), and the intensity of the eddy current (e) is the partial shield cup (13) of the central beam through hole (16) of the shield cup (13). It is the strongest at the edge 15 of.

At this time, the anti-magnetic field (f) opposite to the deflection magnetic field is formed by the eddy current (e) to interfere with the deflection, which is the central beam (b) passing through the center beam through-hole 16 is the side through-hole 17 Since the semi-magnetic field f is larger than the side beam c passing through, i.e., the center beam b is deflected smaller than the side beam c, so that the center beam b is larger on the left side of the screen as shown in FIG. ) And the side beam (c) do not coincide with each other, so that the large miss convergence g is difficult to reproduce a high resolution image.

In addition, when the horizontal frequency of the deflection yoke 7 is increased to improve the resolution, the eddy current e is generated at the edge portion 15 of the shield cup 13 so that the convergence of miss convergence at the shield cup 13 may be increased. g) tends to be even larger.

Thus, in order to reduce the eddy current (e) of the central beam (b) passing through the central beam through hole 16 of the shield cup 13, as shown in Figure 5 to the edge portion 15 of the shield cup (13) The lattice groove 18 was formed around the center beam through-hole 16.

However, since a large number of lattice grooves 18 should be formed around the central beam through hole 16, the semi-magnetic field f can be greatly reduced, so that the production of the shield cup 13 is difficult and expensive because of mold design. There was a problem that is difficult to commercialize.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide a high resolution image quality of a color cathode ray tube by minimizing a miss convergence amount of an electron beam emitted from an electron gun.

In order to achieve the above object, the present invention is the cathode, the control electrode, the tripolar portion consisting of the acceleration electrode, the focus electrode, the main lens portion consisting of the anode, and is installed in front of the main lens portion, the cathode ray tube screen peripheral portion A color cathode wire having a cylindrical shield cup consisting of a bottom portion and a rim portion, a central beam through hole formed in the center of the bottom portion of the shield cup, and side beam through holes formed on both sides of the bottom portion of the shield cup so as to correct miss convergence of the shield cup. In a conventional electron gun; A shield cup structure of an electron gun for a color cathode ray tube is provided, wherein burrings each having a predetermined length are formed in each side beam passing hole, and a slit is formed at an edge portion of the shield cup.

1 is a schematic structural diagram for explaining the structure of a general color cathode ray tube.

2 is a perspective view showing a conventional electron gun for a color cathode ray tube.

Figure 3 is a state diagram showing a semi-magnetic field formed by the eddy current in the conventional shield cup.

Figure 4 is a state diagram showing the miss convergence formed on the screen by the electron beam passing through the conventional shield cup.

Figure 5 is another embodiment showing a conventional shield cup structure of the electron gun.

Figure 6 is a perspective view showing the shield cup structure of the present invention of the electron gun.

Figure 7 is a state diagram showing a semi-magnetic field formed in the shield cup of the present invention.

8 is a state diagram showing the miss convergence formed on the screen by the electron beam passing through the shield cup of the present invention.

9 is a state diagram showing an eddy current formed on the shield cup.

Explanation of symbols for main parts of the drawings

101: Burling 102: Slit

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 6 to 8.

Since the structure of the electron gun for a color cathode ray tube is mentioned in the conventional structure, the overlapping part is abbreviate | omitted and the same code | symbol is attached | subjected to the same structure conventionally.

Figure 6 is a perspective view showing the structure of the shield cup of the present invention, Figure 7 is a state diagram showing a semi-magnetic field formed in the shield cup of the present invention, Figure 8 is a miss convergence formed on the screen by the electron beam passing through the shield cup of the present invention As a state diagram showing the present invention, the bottom portion 14 and the edge portion 15 of the present invention correct the misconvergence (g) at the periphery of the cathode ray tube screen and shield the high-voltage conduction, the external magnetic field, and the electric field from the anode 12. The formed cylindrical shield cup 13 is provided in front of the main lens portion of the electron gun 6, the center beam passage hole 16 formed in the center of the bottom portion 14 of the shield cup 13 and the shield cup. Side beam through holes 17 formed on both sides of the bottom face 14 of 13 are formed.

Burrings 101 having a predetermined length are formed in each of the side beam through holes 17 so as to correct the eddy current e, and a center beam b is formed at the edge portion 15 of the shield cup 13. The slits 102 are formed to minimize the influence of Eddy current (e) of the slits, and the slits 102 are cut out in plural in the central beam through hole 16.

The burring 101 is integrally processed with the side beam through hole 17.

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

First, the electron beam a emitted from the electron gun 6 passes through the bottom portion 14 of the shield cup 13 of the electron gun 6, at which time the center beam formed on the bottom portion 14 of the shield cup 13. The central beam (b) of the electron beam (a) passes through the through hole (16), and the side of the electron beam (a) in the side beam through holes (17) formed on both sides of the bottom portion (14) of the shield cup (13). The beam c passes through.

The side beam c passing through the side beam through hole 17 passes through a burring 101 having a predetermined length in a cylindrical shape formed integrally with the side beam through hole 17, and the burring 101. By forming the eddy current (e) to strengthen the semi-magnetic field (f), there is no difference in deflection between the center beam (b) and the side beam (c) of the electron beam (a).

Since a plurality of slits 102 cut off around the center beam through hole 16 are formed in the edge portion 15 of the shield cup 13, the shield cup 13 may be formed by the slits 102. As shown in FIG. 9, the total length of the edge portion 15 of the shield cup 13 is L before the division, and the radius of the eddy current e generated at the edge portion 15 is divided. In the case of r, the edge 15 is divided by the slits 102, so the length of the divided edge 15 is L / 2 and the radius of the eddy current e is r / 2 = r '. Therefore, the intensity of the eddy current e is reduced.

That is, since the intensity of the eddy current (e) is inversely proportional to the square of the radius of the eddy current (e), in the shield cup 13, when the number of slits 102 increases, the intensity of the eddy current (e) is 1. Is reduced to / 4.

Using this principle, the area of the shield cup 13 edge portion 15 of the central beam through-hole 16 portion by a plurality of slits 102 cut off at the edge portion 15 of the shield cup 13 is used. Because of this reduction, the occurrence of the eddy current e is minimized.

That is, since the semi-magnetic field f generated by the eddy current e is suppressed, the miss convergence amount g is almost 0 mm.

As described above, the present invention forms a cylindrical burring having a predetermined length in the side beam through hole of the center beam through hole and the side beam through hole formed in the shield cup bottom portion of the electron gun, and passes through the center portion of the shield cup. By forming a plurality of slits cut around the ball, the effect of the eddy current between the center beam and the side beams is equalized, thereby reducing miss convergence to the maximum, thereby enabling high resolution image realization of the monitor.

Claims (2)

A tripolar portion consisting of a cathode, a control electrode, an acceleration electrode, a focus electrode, a main lens portion composed of an anode, and a front surface of the main lens portion are installed on the bottom portion and the edge portion to correct misconvergence of the periphery of the cathode ray tube screen. An electron gun for a color cathode ray tube having a cylindrical shield cup, a central beam through hole formed in the center of the bottom of the shield cup, and side beam through holes formed on both sides of the bottom of the shield cup; And a burring having a predetermined length in each of the side beam passing holes, and a slit is formed at an edge portion of the shield cup. The method of claim 1, A shield cup structure of an electron gun for a color cathode ray tube, characterized in that a plurality of slits are cut out around the central beam through hole.