KR800001838Y1 - Color cathode-ray tube apparatus - Google Patents

Abstract

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Description

Color cathode ray tube device

1 is a longitudinal sectional view showing the configuration of a color cathode ray tube that does not require a conventional dynamic convergence correction device.

2 is a longitudinal sectional view including the axes of three electron beams of a conventional three-beam, in-line electron barrel used for the color cathode ray tube.

3 is a shield stimulus used for the electron gun shown in FIG. Perspective to show.

4 is a plan view showing the state of the horizontal and vertical deflection magnetic fields of the conventional magnetic enhancement element and the annular magnetic shield element.

5 is a scanning screen diagram formed by both external electron beams and a central electron beam on a fluorescent surface by deflection yokes that are conventionally used.

Fig. 6 is a scanning screen diagram formed on the screen by two external electron beams when the test signal of the lattice pattern is applied during the luminescent operation.

7 is a perspective view showing the configuration of an annular magnetic shield device in an embodiment of the present invention.

FIG. 8 is a longitudinal sectional view showing a part of a state where the annular magnetic shield element shown in FIG. 7 is installed in both outer electron beam transmission holes in the shield magnetic pole bottom face;

9 is a longitudinal sectional view showing a part of a state where an annular magnetic shielding element is installed in both outer electron beam transmission holes of the shield stimulation bottom of another embodiment of the present invention;

The present invention relates to a color cathode ray tube inline electron gun in which a plurality of electron beams are concentrated at one point on a scanning screen in which a plurality of electron beams are formed on a fluorescent surface without using a dynamic convergence correction device or only using a portion thereof.

In order to facilitate the understanding of the present invention will be described in detail a conventional example used. FIG. 1 is a longitudinal sectional view showing the configuration of a color cathode ray tube using an inline electron gun which does not require a dynamic convergence correction device used conventionally. Three electron beams arranged in a straight line in the same plane, fired from the inline electron gun 1, are disposed in the funnel-shaped portion of the discharged glass envelope 2 (hereinafter referred to as deflection yaw). (5) is deflated horizontally and vertically, and the inside of the glass envelope 2 emits light in a plurality of red, green, and blue colors. A scanning screen is formed on the phosphor surface 3 on which the phosphor element is deposited. In this tube, a color sorting mechanism adjacent to the fluorescent surface 3 and made of an opening mask 4 is arranged, and each scanning electron beam is configured to stimulate only phosphor elements of a color corresponding to each beam. FIG. 2 shows the structure of a conventional inline electron gun in which the main electron lens used in the cathode ray tube shown in FIG. 1 adopts a bi-potential configuration, wherein the electrode spheres are insulated from each other and are equidistantly spaced. Three cathode spheres 11 holding S and aligned in a row, and G ₁ electrodes 12, G ₂ electrodes 13, and G ₃ electrodes 14 which are sequentially arranged in the direction of the electron beam progression opposite thereto. , G ₄ electrodes 15 and shielding stimulation 16, and each electrode except the shielding stimulation 16 is fused and fixed to an insulator supporter with each electrode support interposed therebetween to maintain a predetermined electrode gap. Doing. G ₁ electrode 12 and G ₂ are through holes 12R, 12G and 12B through which electron beams of electrode 13 and G ₃ electrode 14 pass; (13R), (13G), (13B); (14R), (14G), (14B) and _{(14R 2), (14G 2} ), (14B 2) is also equal intervals in the keep S and arranged in a line, three negative electrode of the negative electrode sphere (11) (11R ), (11G) and (11B) electron beams are accelerated to travel on parallel paths (10R), (10G), and (10B). The distance S ′ between the transmission holes of the G ₄ electrodes 15 is slightly larger than the above-described S, so that the main electron lens formed at each corresponding transmission hole spacing between the G ₃ electrodes 14 and the G ₄ electrodes 15. The two outer portions form an asymmetrical development, and when there is no deflection magnetic field generated by the deflection yoke 5, the two beams outside the center 31 of the fluorescent surface 3 are electrostatically concentrated in the center beam. have. On the deflection yoke 5 side of the electron muzzle 1 enclosed in the neck portion connected to the funnel portion of the glass envelope 2, a positive convergence device 6 is disposed, The above-described small error in the center of the fluorescent surface due to assembly error or the like can be compensated for. Adjacent to the constant converging device 6, a color purifying device 7 is arranged so that three electron beams stimulate each phosphor element of a corresponding color.

However, in order to reproduce a color image without color misalignment over the entire fluorescent surface, it is necessary to concentrate three electron beams at every point on the scanning screen, but the pincushion of the horizontal deflection magnetic field of the deflection yoke 5 is strong. With the type twist, the vertical deflection magnetic field is a coil winding fraction of the deflection yoke, which is a strong barrel twist, and the asymmetry of the magnetic field in the deflection coil is appropriately harmonized, and the three-electron beams are aligned in a straight line. By selecting the interval S to a suitable small value, as shown in Fig. 5, the scanning screens 33G and 33B made by the two outer beams coincide with each other, and the scanning screen 33R made by the center beam thereof is shown. ) Can be roughly matched. The concentration error of the scanning screen is small enough to be acceptable in a cathode ray tube of 15 inches or less, for example, but a larger screen can not be ignored in a cathode ray tube, and the reproduced color image is unpleasant in color. It becomes. This is because the two outer beams of the inline electron beam are eccentric with respect to the center of the deflection yoke, so that the size of the scanning screen scanned by them is different depending on the central electron beam and both outer electron beams. A) due to torsion. In order to correct this coma torsion, a small magnetic element that partially controls the deflection magnetic field in the electron beam passing region of the rear leakage magnetic field 51 (FIG. 1) of the deflection yoke 5 has a electron beam G ₄ electrode 15 is provided on the outlet through-hole part. That is, in the bottom surface of the shielding electrode 16 provided so as to have such a potential at the electron beam exit side of the G ₄ electrode 15, its center is matched to the parallel paths 10G, 10R, and 10B. Of the holes 16G, 16R, and 16B, two annular permeable holes 16G, 16B are surrounded by a shielding element 17 by a ring-shaped annular plate made of a magnetic material of high magnetic permeability, As shown in FIG. 4, the horizontal and vertical amplitudes of the scanning screen which are partially shielded from the horizontal, vertical and leakage magnetic fields 5H and 5V and formed on the fluorescent surface by the two outer electron beams are reduced. As shown in Figs. 2 and 3, in order to compensate for the remaining coma twist, to match the outer scanning screens 33G and 33B made by the outer electron beam and the inner scanning screen 33R made by the central beam. Similarly, a pair of small pieces of high permeability magnetic material are formed on both sides of the two rows of non-adjacent electron beam through holes 16G and 16B and the central electron beam through holes 16R in the vertical direction. The magnetic sensitization element 18 made of a disc is placed in the same plane as the magnetic shield element 17. As shown in FIG. 4, this enhances the horizontal leakage magnetic field 5H near the central electron beam transmission hole, slightly enlarges the horizontal amplitude of the scanning screen made by the central electron beam, and simultaneously annular magnetic shield element 17. Slightly increases the vertical leakage magnetic field (5V) near the central electron beam through hole 16R, and slightly enlarges the vertical amplitude so that the scanning screens 33G and 33B of the outer beam and the scanning screen 33R of the center beam are Matches. In this case, the inner hole diameter of the annular magnetic shield element 17 of the plate and the diameters of the two outer through holes 16G and 16B to be installed on the bottom surface of the shielding magnetic pole 16 are the same and are welded and fixed coaxially. If the coaxial relationship is not maintained and the annular magnetic shielding element 17 is fixedly displaced, a lattice drawn by each of the two outer electron beams is generated when a lattice test signal is issued to the screen during the tube operation. The patterns are shifted from each other, and the size of the shift is different from the left and right or up and down of the screen, and it is impossible to match the central electron beam to the grid pattern drawn by the two outer beams by the action of the magnetic enhancement element 18. In this case, as shown in the sixth diagram, the vertical lines of the lattice pattern drawn by the two outer beams are isolated as if the backs of the bows face each other on the upper and lower sides of the screen. In addition, the so-called swing phenomenon in which the horizontal lines of the lattice pattern drawn by the two outer beams are waved in an S-shape and shifted from each other becomes prominent, and both of the scanning screens become unpleasant with color shifts. Therefore, careful attention is required to fix the annular magnetic shield element 17 of the flat plate to the two outer transmission holes 16G and 16B on the bottom of the shielding pole 16. The core rod fitted into the perforation holes 16G and 16B, is inserted therein, the annular magnetic shield element 17 is inserted into the core rod, and the position thereof is adjusted. Postcardiac extraction has been used. However, the former method is not accurate and is not suitable for mass production. In the latter method, the width of the annular portion of the annular magnetic shield element 17 is usually as small as about 1 to 3 mm, and the centering rod of the positioning becomes obstructive and the welding electrode Cannot be brought into sufficient contact with this, welding was insufficient, and welding was difficult.

The present invention eliminates the above-mentioned drawbacks, and the positioning of the two outer through-holes of the annular magnetic shield element and the shield magnetic pole bottom does not require any special jig. An object of the present invention is to provide a color cathode ray tube device having an annular magnetic shield element, wherein the annular magnetic shield element is formed integrally with cylindrical projections respectively fitted to two outer electron beam passage transmission holes. .

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

That is, as shown in FIG. 7, two outer electron beam penetrating holes 16G formed on the bottom surface of the shielding magnetic pole 16 in the annular border 27a by the high permeability magnetic material, and ( The cylindrical projection 27b fitted to 16B is integrally formed to form the annular magnetic shield element 27. The conventional annular magnetic shield element is completely different from the annular magnetic shield element 27 of the present invention in that it has only a cylindrical edge and does not have a cylindrical protrusion. In order to install this in the shielding magnetic pole 16, as shown in FIG. 8, the cylindrical projection part 27b is subtracted into the electron beam transmission hole 16G, 16B, and the annular border 27a part is carried out. Is fixed to the bottom of the shielding magnetic pole (16). In another embodiment of the present invention shown in FIG. 9, the cylindrical protrusion 27b of the annular magnetic shield element 27 is made longer than the thickness of the shielding pole 16, and the protrusion is caulked to the shielding pole. ) To fix the caulking frame 27c. In any of the above examples, since the electron beam transmission hole is narrowed by the thickness of the cylindrical projection 27b, it is necessary to widen the diameters of the two outer electron beam transmission holes on the bottom of the shielding pole so as not to impede the passage of the electron beam. have. In addition, since the cylindrical projection 27b also has a shielding effect against a part of the leakage magnetic field at the rear end of the deflection magnetic field like the annular border 27a, in order to obtain the same effect as in the absence of the cylindrical projection 27b, the annular border 27a ), You need to reduce the width slightly or decrease the thickness.

According to the embodiment of the present invention, when the annular magnetic shield element 27 is fixed to the two outer electron beam transmission holes 16G and 16B at the bottom of the shielding pole 16, mutual positions are coaxial with each other. It does not require any special jig to determine, and can be fixed very easily and with high precision within the range determined by the manufacturing precision of these parts. Therefore, the scanning screen formed by the three in-line electron beams on the fluorescent surface can be exactly matched over the entire screen, and a screen without color shift can be realized without correction by any dynamic convergence.

The shape of the cylindrical projection of the annular magnetic shield element according to the present invention is not limited to the above-described embodiment, but it goes without saying that various shapes are possible within the scope of the present invention.

Claims (1)

On the bottom of the shielding stimulus disposed in the electron beam passing region that the rear end of the deflection magnetic field of the color cathode ray tube is placed, a magnetic enhancement element fixed as if the center electron beam transmission hole is sandwiched among three aligned electron beams, and two In a color cathode ray tube device having an annular magnetic shielding element fixed so as to surround each outer electron beam transmission hole, the annular magnetic shielding element is composed of an annular border and a cylindrical projection formed integrally with the annular border. And fixed to the outer electron beam transmission hole on the bottom of the shielding stimulus.