KR20010002781A - structure shield cup of electron gun in color cathode ray tube - Google Patents

Abstract

PURPOSE: A shield cup structure of an electron gun for a color cathode ray tube is provided to enable an eddy current have same power in the center beam and side beam which pass the shield cup. CONSTITUTION: An electron gun for a color cathode ray tube has a shield cup(66), in which three beam through-holes are formed side by side on the plane faced into an electrode. In the shield cup, a pair of compensation electrodes(90) which the beam through-hole is disposed therebetween are mounted side by side corresponding to the arrangement direction of the beam through-hole. The width of the compensation electrode is expanded gradually from the center part to the peripheral part. The compensation electrode allows to be mounted on the plane in which the beam through-hole is formed. Also, the compensation electrode allows to be integrated with the plane in which the beam through-hole is formed.

Description

Structure cup of electron gun in color cathode ray tube

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

In general, the color cathode ray tube is shaped by the combination of the panel 1 and the funnel 2 as shown in FIG. 1, and the inside of the outline maintains a high vacuum of about 10 ⁻⁷ Torr. .

In addition, a rail 3, a mask 4, an inner shield 5, an electron gun 6, and the like are provided in an inner space formed by the panel 1 and the funnel 2.

In particular, the electron gun 6 to be dealt with in the present invention is a component for generating an electron beam (or hot electrons) as shown in Fig. 2, and its configuration is roughly divided into a tripolar portion and a main lens portion.

When the triode is subdivided, an in-line cathode 61 with a heater is built therein, and a control electrode 62 and an acceleration electrode 63 for controlling and accelerating the electron beam 7 emitted from the cathode. Consists of.

When the main lens is subdivided, the focus electrode 64 focuses the electron beam 7 generated from the triode, and the anode 65 finally accelerates the electron beam 7. On the side facing the panel 1, a shield cup 66 is provided for shielding the high-voltage conduction to the anode, the external magnetic field, and the electric field.

The shield cup 66 has a cylindrical shape as shown in FIG. 3, and a pair of sides and a center beam through-hole 68 through which a center beam 7a and a side beam 7b pass respectively toward the electrode. The fixing plate 67 in which the beam passage hole 69 is formed is integrated, and the opposite side is open.

Therefore, the electron beam 7 generated thermally and electrically at the cathode 60 is formed at the triode of the electron gun 6, and is focused and accelerated at the main lens portion to form a center formed on the fixed plate 67 of the shield cup 66. Through the beam through hole 68 and the side beam through hole 69 respectively, the image is reproduced by collision with the phosphor applied to the inner surface of the panel 1.

On the other hand, the deflection yoke 8 provided outside the neck portion 2a of the funnel 2 generates a vertical deflection magnetic field and a horizontal deflection magnetic field for deflecting the electron beam 7 in the horizontal or vertical direction.

In particular, the horizontal deflection magnetic field h, which is a high frequency wave having a large influence on the deflection force of the electron beam 7, as shown in FIG. 4, has an eddy current across the shield cup 66, which is a conductor located on its path. will generate current: e).

This eddy current (e) is generated in the normal direction on the outer circumferential surface of the shield cup 66 which is proportional to the magnetic flux density, frequency, electrical conductivity of the conductor, and meets the horizontal deflection magnetic field (h), and also halves the magnetic flux change direction. Magnetic field (-h) is generated.

In addition, the strength of the eddy current e acting on the shield cup 66 decreases gradually from the center of the surface toward the side by the shape of the shield cup 66, and thus the side of the shield cup 66 becomes smaller than that of the center beam 7a. The deflection angle of the beam 7b becomes small.

In addition, since the deflection angle of the side beam 7b is smaller than that of the center beam 7a, HCR miss convergence occurs at the left and right sides of the screen, thereby making it difficult to obtain a high quality cathode ray tube.

Deflection of the side beam through hole 69 inside the shield cup 66 as shown in FIG. 5 for the purpose of preventing distortion of the path of the electron beam from the previous electron gun and correcting fine convergence at the periphery of the screen. A flat plate correction electrode 9 is added on the magnetic field propagation path, and an additional eddy current E is formed on the correction electrode 9 to act on the center beam 7a and the side beam 7b. The influence of the eddy currents was balanced (see Japanese Patent Laid-Open No. 63-190232).

However, the form in which the correction electrode 9 is added as described above, although the effect of slightly correcting the fine convergence than the previous electron gun was obtained, could not be completely prevented.

Because the additional eddy current (E) generated in the flat maintenance electrode (9) has a uniform intensity, as described above, the eddy current (e) generated on the surface of the shield cup (66) is gradually increased from the center to the periphery. This is because the sum of the eddy currents generated (e + E) still decreases toward the periphery of the shield cup 66 because the intensity gradually decreases.

Therefore, the eddy current intensity between the G beam of the center beam 7a and the R and B beams of the side beams 7b is different, resulting in fine convergence and reducing the resolution of the CRT. .

The present invention has been made to solve the above-mentioned conventional problems, the object is to allow the eddy current of the same intensity to be applied to the center beam and the side beam passing through the shield cup.

In order to achieve the above object, the present invention provides a pair of flat correction electrodes in the beam through hole arrangement direction with a beam through hole interposed therebetween on a fixed plate inner surface fixed to the electrode of the shield cup. The width gradually extends from the central portion through which the central beam passes to the peripheral portion through which the side beam passes.

1 is a longitudinal cross-sectional view of a typical colored cathode ray tube

2 is a block diagram of a general electron gun

Figure 3 is a first embodiment of the conventional shield cup

4 is a diagram illustrating the formation of an ammeter acting on the shield cup of FIG.

Figure 5 is a second embodiment of the conventional shield cup

6 is a first embodiment of a shield cup according to the present invention;

Figure 7 is a second embodiment of the shield cup according to the present invention

8 is a view illustrating the formation of an eddy current meter acting on a shield cup according to the present invention;

Explanation of symbols for main parts of the drawings

66. Shield Cup 67. Retaining Plate

90. Correction electrode e, E: Eddy current

6 is a first embodiment of the shield cup according to the present invention, FIG. 7 is a second embodiment of the shield cup according to the present invention, and FIG. 8 is a diagram showing the formation of an eddy current meter acting on the shield cup according to the present invention. When described in detail with respect to the shield cup structure of the electron gun for color cathode ray tube of the present invention with reference to these accompanying drawings.

As shown in FIG. 6, the eddy current e generated in the normal direction in the circular shield cup 66 has a uniform intensity at any position. 90) is added.

At this time, the correction electrode 90 is composed of a pair, with the beam passing hole including the center beam through hole 68 and the side beam through hole 69 on the inner surface of the fixing plate 67 of the shield cup 66. The beams were arranged side by side in the array direction of the holes.

In particular, the shape of each of the correction electrodes 90 has a flat plate shape, and the shape of the correction electrode 90 is gradually increased from the center portion to the side. The reason is that the eddy current (e) generated on the surface of the shield cup 66 is ) Is to compensate for this, because the strength of the shield becomes smaller toward the outside than the center of the shield cup.

On the other hand, the correction electrode 90 may be formed integrally with the fixing plate 67 of the shield cup 66, or may be combined by a separate means, but it is formed in one piece with the fixing plate 67 in the manufacturing process glass Therefore, it can be called a more effective form.

In another embodiment, each correction electrode 90 is provided only in the side beam through-holes 69 as shown in FIG. 7, but the shape thereof has a shape in which the area thereof gradually increases toward the side as described above. The same effect can also be obtained.

Since the correction electrode 90 has the circular shape of the shield cup 66, the correction electrode 90 is intended to solve a problem in which the intensity of the generated eddy current e varies for each part of the shield cup 66.

In particular, if the sum (e + E) of the eddy current e formed on the outer circumferential surface of the shield cup 66 and the additional eddy current E formed on the correction electrode 90 is constant at any part of the shield cup 66, You get the ideal shield cup.

Therefore, this effect can be obtained by applying the correction electrode 90 according to the present invention.

That is, when the horizontal deflection magnetic field generated from the deflection yoke is acted on the shield cup 66, it is accompanied by a semi-magnetic field in the opposite direction, and when these two magnetic fields pass in the y direction of the shield cup 66, the horizontal deflection Eddy current (e) is generated in the shield cup 66 that meets the magnetic and semi-magnetic field.

The eddy current (e) has a great influence on the deflection of the electron beam passing through the shield cup 66, so that the deflection angles of the center beam and the side beam are equal when the intensity is constant.

However, since the strength of the eddy current e acting on the surface of the shield cup 66 gradually decreases toward the periphery rather than the center due to the circular shape of the shield cup 66, the correction electrode 90 is generated. If the eddy current (E) is small in the center, and the intensity increases as it goes to the periphery, this can be compensated. If the correction electrode 90 of the present invention is applied, the eddy current acting on the center beam 7a and the side beam 7b. You can take the total equally.

In general, the strength of the eddy current is proportional to the contact area, so that the larger the contact area is, the larger the eddy current strength becomes. If the area is changed, the intensity of the eddy current can be adjusted (see FIG. 8).

On the other hand, if the correction electrode 90 is formed integrally on the inner surface of the fixed plate 67 of the shield cup 66, or combined by other means, if the same effect can be obtained, but not limited to a specific method, but in the production process Integrating the correction electrode 90 with the fixed plate 67 is advantageous because it can reduce the labor time.

As described above, the present invention allows uniform eddy currents to flow through the R, G, and B electron beams passing through the shield cup to make the deflection angles of the three electron beams uniform, and minimizes the misconvergence of the three electron beams. You will get the effect of maintaining the state of.

Claims (3)

An electron gun for a color cathode ray tube having a shield cup having three beam passing holes formed side by side on a surface facing an electrode; A pair of correction electrodes are installed side by side in the shield cup with the beam passing holes interposed therebetween, and the correction electrode is a color brown having a shape in which the width gradually expands from the center to the periphery. Shield cup structure of a conventional gun. The method of claim 1, A shield cup structure of an electron gun for a color CRT tube, with a correction electrode provided on a surface of the beam passing hole. The method of claim 1, A shield cup structure of an electron gun for a color CRT tube, in which a correction electrode is integral with a surface on which the beam passage hole is formed.