KR100337881B1 - Innershield assembly for anti-magnetic field - Google Patents

Abstract

Purpose: The present invention is to enhance the intensity of the anti-magnetic flux that can reduce the total amount of movement of the electron beam so that the electron beam is not affected by the external magnetic field.

Configuration: The present invention has a configuration in which a serrated portion is provided to a U-shaped notch of an inner shield that defines an incident path of an electron beam.

Effect: Since the line area of the U-shaped notch is substantially increased by several times by the sawtooth part, the area of the magnetic pole is widened, so that the intensity of the anti-magnetic field generated by this is also increased to completely offset the influence of the external magnetic field. There is.

Description

Innershield assembly for geomagnetic shielding {Innershield assembly for anti-magnetic field}

The present invention relates to an inner shield assembly, and more particularly, to an inner shield assembly that shields an electron beam scanned from a color cathode ray tube from being affected by a geomagnetic field.

The in-line electron gun applied to the color cathode ray tube passes three electron beams of red, green, and blue along the converging passage formed in the common plane, and scans the electron beam to the focusing point located near the shadow mask or the screen.

Scanning of the electron beam in the electron gun is scanned into an energetic electron beam as it is focused into a beam via an electron lens formed through a plurality of arranged electrodes.

When the electron beam emitted from the electron gun is landed in any one of the phosphor patterns applied to the inner surface of the face plate, it emits fluorescence that becomes one of R, G, and B, thereby displaying an image.

The electron beam is scanned under the influence of the electromagnetic field generated in the deflection yoke over the entire surface of the face plate. That is, the electron beam is deflected under the influence of the vertical and horizontal magnetic fields generated by the vertical coil and the horizontal coil of the deflection yoke. This action is intended for the purpose of causing the electron beam to land in the phosphor pattern applied to the corner of the screen to generate light. It is.

As such, the electron beam is deflected by the action of the electromagnetic field, which is sensitively affected by the geomagnetic field, thus acting as a cause of deterioration of image quality.

Therefore, conventionally, the inner shield is mounted on the mask frame in order to prevent the electron beam from being affected by the geomagnetic field.

As the inner shield is mounted toward the electron gun at the inlet side of the mask frame, the inner shield is installed to shield the path from which the electron gun is scanned from the geomagnetic field. The inner shield is usually press-molded using a silicon steel sheet.

Earth's magnetic field is generated around the Earth's Antarctic and Arctic = Ｑ ＊ ( × × It affects the force of) and changes the path of the electron beam, which causes the degradation of the purity characteristic, the raster distortion, and the change of the convergence characteristic. The use of inner shield reduces the effect to 50%. here Where is the force the electron receives, The strength of the electric field, Is the strength of the voltage, Is the external magnetic field.

In the shielding of a geomagnetic field, when a metal material is placed in a magnetic field region in which an external magnetic field exists, a spin moment is formed inside the metal material, and the magnetic conductor is arranged in a certain direction, and the metal conductor becomes a kind of magnetic material. At the same time, the magnetic force is generated in the metal material by the micro-magnet structure formed on the metal material itself, and this magnetic force causes a cancellation or reinforcement interference with the external magnetic force, and as a result, the external magnetic field changes the path of the magnetic field due to the metal material. This phenomenon occurs inside the actual colored cathode ray tube = Ｑ · ( + × d _D + B _T Acts as a force of). here Is the velocity of the electron beam, d _D is the magnetic flux density due to the deflection yoke, B _T Is the magnetic flux density in the tube due to the external magnetic field.

Under the above conditions, the magnetic shielding effect by the inner shield is characterized by the change of magnetic field toward the inner shield as the permeability increases. In other words, the magnetic shielding effect is proportional to the permeability and the thickness of the material and inversely proportional to the width.

Inner shields, which have been put to practical use in the prior art, are known to be integral, rectangular and polygonal. The one-piece type is formed by press-molding into one part, and has the advantages of shielding effect and the amount of magnetic field movement in the east-west direction, but it is restricted to molding when the elongation of the material is 35% or more, and the press mold structure is complicated. There is a drawback to this.

On the other hand, the square separation type and the polygon separation type can use a material with low elongation, and the mold can be manufactured relatively simply, and there is an advantage in that the north-south magnetic field movement is excellent, and most large color cathode ray tubes are manufactured in this manner. The influence of the magnetic field is so small that the east-west direction can be neglected, and it is common to design a design that emphasizes the north-south direction.

The mounting of the inner shield causes the electron beam to pass through to generate a counterclockwise rotating beam, whereas the inner shield generates a clockwise horizontal beam to offset each other, and through the incidence of the inner shield The generated magnetic flux reduces the total amount of movement.

However, in the inner shield of the conventional structure, there is a problem that it is difficult to increase the intensity of the anti-magnetic flux above a certain level.

Therefore, an object of the present invention is to increase the intensity of the anti-magnetic flux to reduce the total amount of movement of the electron beam, the inner magnetic shield shield inner structure to solve the degradation of the purity characteristics, raster distortion and convergence characteristics due to the movement of the electron beam It is to provide a shield assembly.

In order to achieve the above object, the present invention has a configuration in which a serrated portion is provided to a U-shaped notch of an inner shield that defines an incident path of an electron beam.

According to the present invention, since the area of the U-shaped notch is increased by several times and the area of the magnetic pole is also widened by the tooth-shaped portion, the intensity of the anti-magnetic field generated through this increases, resulting in reduced purity, raster distortion and control. Changes in the characteristics of the version can be prevented beforehand.

1 is an external perspective view of an inner shield assembly according to the present invention;

2 is a view for explaining the magnetic shielding effect by the inner shield of the present invention.

* Description of the symbols for the main parts of the drawings *

2 shield 4 mask frame

6: flange 8: extension part

10: fastening hole 12: tooth shape

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention described above will be described in detail with reference to preferred embodiments according to the accompanying drawings.

Fig. 1 is a perspective view showing an outer configuration of an inner shield according to the present invention, and shows a band-shaped rectangular divided mold as an example.

The inner shield shown in the drawing comprises a shield portion 2 having a predetermined shape which is divided into two or more so as to block the exit front of the electron gun from the geomagnetic field, and the shield portion 2 has a flange which is in contact with the mask frame 4. 6) It holds one. The pair of shielding parts 2 formed in the symmetrical form are means for connecting together integrally, and an extension part 8 is formed at one side and a fastening hole into which the extension part 8 is inserted and bent. (10) is open.

In the shielding portion 2, a portion formed as a U-shaped notch at the peripheral portion of the direction in which the electron beam is incident is formed as a sawtooth portion 12.

Since the serrated portion 12 acts to substantially increase the linear area of the U-shaped notch, it is excited by the serrated portion 12 against the earth magnetic field applied from the outside as shown in FIG. The intensity of the semi-magnetic field is also increased to weaken the force applied by the external magnetic field to the inside.

As a result, the amount of the electron beam scanned into the shield 2 is minimized due to the influence of an external magnetic field, and thus the degradation of the purity characteristic, the raster distortion, and the change of the convergence characteristic can be actively suppressed.

As described above, the present invention increases the strength of the semi-magnetic field generated in this area by increasing the linear area of the shield as the jagged notch of the shield in the inner shield assembly increases the strength of the external magnetic field. It is possible to fundamentally solve the degradation of the purity characteristics, the raster distortion, and the change in the convergence characteristics caused by the geomagnetic field.

Claims (1)

An inner shield assembly for a color cathode ray tube, characterized by a configuration in which a serrated portion is provided to a U-shaped notch of an inner shield that defines an incident path of an electron beam so that a substantial line area is enlarged.