KR100192443B1 - Inner shield of crt - Google Patents

Abstract

The present invention relates to an inner shield for a color cathode ray tube, wherein a notch is formed on each side portion as well as a corner portion of the inner shield piece so that each portion notch cancels the entire landing landing change of the beam by magnetic field resistance. Landing, convergence, and raster dispensing characteristics are improved on the screen so that display quality is not degraded.

To this end, in the present invention, two inner shield pieces which are symmetrical to each other are combined to form a rectangular hole having a trapezoidal shape, and on each side of the inner shield piece, a surface notch is formed to offset the landing change of the beam by magnetic field resistance. Corner notches are formed at each corner of the shield piece so that the change in landing of the corner of the beam is canceled by the magnetic resistance of the corner notch.

Description

Inner Shield for Color Cathode Ray Tubes

1 is a longitudinal sectional view showing a colored cathode ray tube;

Figure 2 is a plan view showing the inner shield for a conventional color cathode ray tube.

3 is a front view showing an inner shield for a conventional color cathode ray tube.

4 is a perspective view showing an inner shield for a conventional color cathode ray tube.

Figure 5 is a plan view showing the inner shield for the present invention color cathode ray tube.

Figure 6 is a front view showing the inner shield for the present invention color cathode ray tube.

7 is a perspective view showing the inner shield for the present invention color cathode ray tube.

* Explanation of symbols for main parts of the drawings

91: inner shield flight 92: rectangular ball

93: cotton notch 94: corner notch

The present invention relates to an inner shield for color cathode ray tubes, and more particularly, to change the structure to improve the shielding effect of each corner portion.

In general, the color cathode ray tube has a funnel (3) adhesively fixed to the panel (1) with a neck (2) rearward as shown in FIG. Bulb Form), and an electron gun 4 is embedded in the neck portion 2 to emit red, green, and blue three-color electron beams toward the panel 1, and the funnel 3 A deflection yoke 5 is provided on the outer circumferential surface of the neck portion 2 so as to deflect the electron beam emitted from the electron gun 4 in the horizontal and vertical directions, and a plurality of support springs 6 are provided inside the panel 1. The frame 7 is supported, and a shadow mask 8 having a large number of beam passing holes is fixed to the panel 1 side of the frame so that a part of the electron beam emitted from the electron gun 4 passes. On the funnel 3 side of the frame 7, an electron beam emitted from the electron gun 4 is provided with an external environmental magnetic field ( An inner shield is fixed so as not to be influenced by a geomagnetic field or a leakage magnetic field, and an inner surface of the panel 1 forms a fluorescent surface such that an image is formed when an electron beam passing through the shadow mask 8 strikes. 10) is formed.

Therefore, when the device is turned on while the color cathode ray tube configured as described above is mounted on the device, high pressure is applied to the electron gun 4 embedded in the neck portion 2 of the funnel 3 so that the red, green, and blue colors are three colors. The electron beam is emitted and the emitted electron beam is deflected in the horizontal and vertical directions by the magnetic field of the deflection yoke 5 provided on the outer circumferential surface of the neck portion 2 of the funnel 3, wherein the funnel 3 of the frame 7 is rotated. The inner shield 9 fixed to the c) side prevents the earth magnetic field or the leakage magnetic field of the three-color electron beam continuously radiated in a deflected state so that the path of the electron beam is not deformed along the way.

On the other hand, the emitted three-color electron beam is mostly scattered by hitting the shadow mask 8 fixed to the panel 1 side of the frame 7 and only the remaining (about 20%) of the shadow mask 8 is scattered. Since it hits each phosphor of the fluorescent surface 910 formed on the inner surface of the panel 1 through the beam passing hole, the color screen is reproduced by the combination of three-color electron beams.

As described above, the specific role of the inner shield 9 constituting the color cathode ray tube forms a magnetic closed circuit together with the shadow mask 8 and the frame 7 to correspond to an external environmental magnetic field and thus the external magnetic field. It is possible to reduce the adverse effects on the cathode ray tube by means of the inner shield (9) is completely impossible to shield the external magnetic field due to the material and various technical problems so far the shape of the inner shield in various forms The influence of the magnetic field is minimized by intentionally distorting the flow of the magnetic field by deforming to.

In the case of cathode ray tube, the effect and amount of each component of the geomagnetic field are different depending on the region of use (Northern Hemisphere, Southern Hemisphere) and the direction of orientation (orientation, west direction, etc.), so that if you do not use a separate shield mechanism, Landing, convergence, and raster displacement have serious adverse effects on quality.

However, it is difficult for the current shield mechanism to completely shield the external magnetic field due to the limitations of the material and the use of the components and the problems of the degaussing circuit as described above.

In practice, the shielding mechanism's magnetic field shielding efficiency is about 60-90% during operation of the cathode ray tube, so the remainder remains as a residual magnetic field to affect the path of the electron beam.

Therefore, the design of the inner shield is to intentionally distort the magnetic flow and minimize the influence of the residual magnetic field.

The principle of the above shield is that if the magnetic material is placed in a uniform external magnetic field, the magnetic material is magnetized by the external magnetic field, and the structure of the magnetized structure is perpendicular to the external magnetic field in the magnetic material, but the magnetic field is large, but the magnetic field is not properly magnetized, but is particularly parallel. The part is magnetized as a stimulus that generates magnetic lines in the opposite direction to the external magnetic field. As this Eck cancels the external magnetic field, the inside of the magnetic body becomes a non-magnetic field, and the electron beam passing through the inside is not affected by the external magnetic field. will be.

The inner shield for the conventional color cathode ray tube includes two inner shield pieces 91 in a symmetrical form as shown in FIGS. 2 to 4 to form a trapezoidal rectangular hole 92. On each surface of the inner shield piece 91, a plurality of surface notches 93 are formed so as to cancel the landing change of the beam by the magnetic field resistance.

Therefore, during operation of the cathode ray tube, the electron beam radiated from the electron gun 4 passes through the trapezoidal rectangular hole 92 formed by the combination of the two inner shield pieces 91, and then the shadow mask 8, which is a color-selective electrode, is formed. Passing through each beam through hole hits the phosphor of the fluorescent surface 10 formed on the inner surface of the panel 1, at this time trapezoidal rectangular hole 92 formed by the combination of the two inner shield pieces (9) In the course of passing the electron beam, the electron beam receives the magnetic resistance of the surface notch 93 formed on each surface of the inner shield piece 9, so that only the landing change in the surface portion is canceled out considerably.

However, since the inner shield has a notch formed only on each side of the inner shield piece, the electron beam of each side portion of the inner shield piece of the electron beam effectively cancels the landing change, but each corner portion of the electron beam has a landing change. Since the electron beam in the corner portion is distorted in the path due to the influence of the external magnetic field or the residual magnetic field, the electron beam in the corner portion does not accurately strike the phosphor of the fluorescent surface. Missing (Land-Landing) is badly generated, there was a problem that the display quality of the landing, convergence, raster display, etc. is significantly reduced.

The present invention has been made to solve the above problems, the screen is formed by forming notches on each side portion of the inner shield piece as well as the corner portion so that the respective notch cancels the entire landing landing change of the beam by the magnetic field resistance Its purpose is to improve the landing, convergence, and raster dispensing characteristics on the screen so that display quality is not degraded.

According to the present invention for achieving the above object, two inner shield pieces symmetrical to each other are combined to form a trapezoidal rectangular hole, the surface to compensate for the landing change of the beam by the magnetic field resistance on each surface of the inner shield piece In the notch is formed, there is provided an inner shield for the color cathode ray tube of the present invention in which corner notches are formed at each corner portion of the inner shield piece so that the corner portion landing change of the beam is canceled by the magnetic resistance of the corner notch.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 5 to 7 of the accompanying drawings.

FIG. 5 is a plan view showing the inner shield for the color cathode ray tube of the present invention, and FIG. 6 is a plan view showing the inner shield for the color cathode ray tube of the present invention, and FIG. 7 is a perspective view showing the inner shield for the color cathode ray tube of the present invention. Two inner shield pieces 91 opposed to each other are combined to form a rectangular hole having a trapezoidal shape, and surface notches are formed on each surface of the inner shield piece 91 so as to cancel a landing change of a beam by magnetic field resistance. In this case, corner notches 94 are formed at each corner of the inner shield piece 91 so that the change in landing of the corners of the beam is canceled by the magnetic resistance of the corner notches.

The corner notch 94 is formed so that the diameter is 10-20% of the height of the inner shield piece 9 at the 25-55% point from the bottom of the inner shield piece 91 in order to minimize the influence of the residual magnetic field. This is preferred.

According to the present invention configured as described above, the electron beam is inner when the electron beam radiated from the electron gun 4 passes through the trapezoidal rectangular hole 92 formed by the combination of the two intershield pieces 91 during the cathode ray tube operation. Since the magnetic field resistance of the surface notch 93 formed on each surface of the shield piece 91 and the corner notch 94 formed on each corner is received, the landing change in all parts is substantially canceled out.

Meanwhile, as a result of comparing the conventional and the present invention, the results of experimenting with the shielding effect and the beam shifting direction according to the following characteristics were shown as shown in the following tables.

As a result of the test as described above, the corner notches 94 formed at each corner portion of the inner shield piece 9 have a diameter of the inner shield piece 91 at a diameter of 25-55% from the bottom of the inner shield piece 9. The formation of 10-20% was very good in the wheeled effect and the turning beam movement characteristics.

Therefore, in the present invention, the magnetic field resistance of all the beams is formed on the surface notches formed on each surface portion of the inner shield piece constituting the inner shield and the corner notches formed on each corner portion during operation of the cathode ray tube. As the change is canceled, the landing, convergence, and raster dispensing characteristics are improved on the screen, thereby reducing display quality.

Claims (2)

Two inner shield pieces which are symmetrical to each other are combined to form a rectangular hole having a trapezoidal shape, and on each side of the inner shield piece, a surface notch is formed so as to cancel a landing change of the beam by magnetic field resistance, and each corner portion of the inner shield piece The inner shield for the color cathode ray tube of the present invention in which a corner notch is formed in the corner notch so that the change in landing of the corner portion of the beam is canceled by the magnetic resistance of the corner notch. The inner shield according to claim 1, wherein the corner notch is formed at a diameter of 25 to 55% of the height from the bottom of the inner shield piece so as to have a diameter of 10 to 20% of the height of the inner shield piece.