KR100426566B1 - Color Cathode-ray Tube Containing Improved Inner Shield - Google Patents

Abstract

The present invention relates to a color cathode ray tube. In particular, the cross-sectional shape of the inner shield is formed by combining a long side portion with a pincushion type and a short side portion with a barrel shape in a conventional rectangular or elliptical structure. The present invention relates to a color cathode ray tube which improves geomagnetic margin by minimizing the movement of the left or right direction of the electron beam generated by the flow of the tube axis magnetic field in the tube axis direction.

Technical means of the present invention is a color cathode ray tube having an upper and a lower open cylindrical shape and an inner shield fixed to the frame to shield the geomagnetism, the long side portion of the inner shield is a pincushion (Pincushion) type , The short side shape is characterized in that the barrel (Barrel) type.

The present invention has the effect of improving the geomagnetic margin by preventing mis-landing of the electron beam by optimizing the cross-sectional shape of the inner shield to minimize the left or right movement of the electron beam.

Description

Color Cathode-ray Tube Containing Improved Inner Shield}

The present invention relates to a color cathode ray tube. In particular, the cross-sectional shape of the inner shield is formed by combining a long side portion with a pincushion type and a short side portion with a barrel shape in a conventional rectangular or elliptical structure. The present invention relates to a color cathode ray tube which improves geomagnetic margin by minimizing the movement of the left or right direction of the electron beam generated by the flow of the tube axis magnetic field in the tube axis direction.

In the conventional planar cathode ray tube, as shown in FIG. 1, the fluorescent surface 1 of R, G, and B is coated on the inner surface, and the panel 3 on which the explosion-proof glass 2 is fixed on the front surface thereof, and A funnel (4) fused to the rear end of the panel, an electron gun (7) encapsulated in the neck (5) of the funnel and radiates an electron beam (6), and mounted at regular intervals inside the panel to allow electron beams to pass through. A shadow mask 8 having a plurality of holes formed therein, a rail 9 fixing and supporting the shadow mask so that the shadow mask is kept at a constant distance from the inner surface of the panel, and an inner shield shielding the cathode ray tube to be less affected by external geomagnetism. The shield 10 and a reinforcing band 11 installed around the side portion of the panel to prevent external impact.

The inner shield is installed inside the funnel and fixed to the rail, and is made of a magnetic material having a high permeability. This shielding effect is excellent to prevent the bending of the electron beam under the influence of the Earth's magnetism, and also serves to prevent degradation of purity and color purity.

The cross-sectional shape of the conventional inner shield has a rectangular or elliptical shape as shown in FIGS. 2B and 2C. In the conventional inner shield structure as described above, when the magnetic field Bh enters the screen and the horizontal direction as shown in FIG. 3, the horizontal magnetic field is focused on the inner shield 10 made of a magnetic material to change the direction of the magnetic field. The magnetic field outside the inner shield does not affect the path of the electron beam, but the magnetic field inside the inner shield affects the electron beam emitted to the screen. That is, the horizontal magnetic field flow in the inner shield inner surface does not affect the screen purity because it causes the movement of the electron beam. However, the vertical magnetic field flow causes the electron beam to move left and right, thus affecting the screen purity. Crazy

However, as shown in FIG. 3, the center, top, bottom, left and right flows of the screen in the inner shield inner surface maintain the horizontal direction, but the magnetic field flow of the corner portion includes the horizontal and vertical directions due to the path change. Indicates the flow of. At this time, the horizontal magnetic field flow (MFx) in the corner magnetic field path does not affect the purity of the screen because it causes the movement of the electron beam, but the vertical magnetic field flow (MFy) causes the left and right movement of the electron beam. Landing occurs.

This results in a trend magnetic field (Bv = 0.4G, Bh = 0.3G, Bz = 0.0G) or a western magnetic field (Bv = 0.4G, Bh =) in the standard magnetic field (Bv = 0.4G, Bh = 0.0G, Bz = 0.0G). -0.3G, Bz = 0.0G), mis-landing occurs largely at the corners of the screen, which reduces the geomagnetism margin.

In order to correct the geomagnetic margin, conventionally, a Purity Coil or a Local Current Controller (LCC) is separately installed in the monitor circuit, which not only complicates the monitor circuit but also causes a material cost increase.

Accordingly, an object of the present invention is to improve geomagnetic margin by optimizing the structure of the inner shield for color cathode ray tubes and minimizing the left or right movement of the electron beam generated by the flow of the electron beam and the horizontal magnetic field during rotation of the cathode ray tube. It is done.

1 is a cross-sectional view of a flat cathode ray tube of the prior art,

2a to 2c is a view showing the shape of the inner shield of the prior art,

3a to 3b are views showing the moving direction of the magnetic field in the inner shield of the prior art,

4 is a cross-sectional view of the inner shield of the present invention;

5 is a view showing another embodiment of the present invention;

6 is a diagram illustrating a moving direction of a magnetic field in the inner shield of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

DESCRIPTION OF SYMBOLS 1: Fluorescent surface 3: Panel 4: Funnel

8: shadow mask 9: rail 10: inner shield

The technical means of the present invention for achieving this object is a panel having a phosphor screen on the inner surface, a funnel connected to the panel, an electron gun mounted to the neck portion of the funnel and emitting an electron beam toward the phosphor screen, the panel Shadow masks arranged at regular intervals with respect to the inner phosphor screen and serving as color screening, a frame for fixing and supporting the shadow mask, and a top and bottom open quadrangular shapes to be fixed to the frame to shield the geomagnetism. In the color cathode ray tube including an inner shield, the long side portion of the inner shield has a pincushion shape, and the short side portion has a barrel shape.

Hereinafter, the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is to minimize the movement of the electron beam due to the horizontal magnetic field by forming the long side cross-sectional shape of the inner shield in the pincushion shape, the short side cross-sectional shape in the barrel shape.

Figure 4 shows the inner shield cross-sectional shape of the present invention. As shown, the cross-sectional shape of the long side part is pincushion type, and the cross-sectional shape of the short side part is barrel shape. In addition, the long side portion and the short side portion has a form in which three straight lines which are not parallel to each other are connected, and two straight lines positioned at both ends of the three straight lines have the same length, and each of the numerical values of FIG. 4 preferably satisfies the following conditions. .

Length L1 and L2 of the long side: 0.1 <L2 / L1 <1.0

-Length S1 and S2 of the short side: 0.1 <S2 / S1 <1.0

-Non-rectangular rate at corners:

In the above equation, Dx is the horizontal distance between the center line of the inner shield short side and the end of the inner shield short side, and Dy is the horizontal distance between the center line of the inner shield long side and the end of the inner shield long side.

Figure 5 shows another embodiment of the present invention, the long side portion and the short side portion is an arc shape having an arbitrary curvature. At this time, it is preferable that each of the numerical values of FIG. 5 satisfies the following conditions.

-Radius R1 of the long side: 400 mm <R1 <8000 mm

Radius R2: 200 mm <R2 <4000 mm

-Non-rectangular rate at corners:

In the above formula, Gx is the horizontal distance between the tangent of the center of the inner shield short side and the end of the inner shield short side, and Gy is the horizontal distance between the tangent of the center point of the inner shield long side and the end of the inner shield long side.

Figure 6 shows the flow of the horizontal magnetic field by the inner shield structure of the present invention. The flow of the horizontal magnetic field in the conventional inner shield structure is shown in FIG. 3. That is, the inner shield moves in a horizontal direction, and at the corners inside the inner shield, the inner shield is focused on the inner shield, and the magnetic field is changed to have both a vertical component and a horizontal component. When it passes through the middle part of the inner shield, it moves in the horizontal direction again and has the vertical component opposite to the vertical component in the opposite corner portion. At this time, the magnetic field flow in the vertical direction of the corner magnetic field path on the inner shield inner surface causes the left and right movement of the electron beam occurs. However, in the present invention, the cross-sectional shape of the inner shield is formed by combining the long side portion with the pin cushion type and the short side portion with the barrel shape to prevent the magnetic field path of the inner portion of the inner shield from changing.

Therefore, the flow of the horizontal magnetic field of the present invention is maintained at a horizontal level without changing the path even in the corner portion of the inner shield inner surface, it is possible to minimize the mis-landing due to the left and right movement of the electron beam does not occur.

According to the present invention, the cross-sectional shape of the inner shield is formed by combining a long side portion with a pincushion type and a short side portion with a barrel shape in a conventional rectangular or elliptical structure. By minimizing the movement of the left or right of the electron beam generated by the electron beam to prevent mis-landing of the electron beam has the effect of improving the geomagnetic margin.

Claims (4)

A panel having a phosphor screen on an inner surface, a funnel connected to the panel, an electron gun mounted to a neck portion of the funnel to emit an electron beam toward the phosphor screen, and disposed at a predetermined interval with respect to the phosphor screen on the inner surface of the panel In the color cathode ray tube comprising a shadow mask that serves as a color screening, a frame for holding and supporting the shadow mask, and an inner shield fixed to the frame to shield the geomagnetism, The long side portion of the inner shield is a pincushion (Pincushion) type, the short side portion is a color cathode ray tube, characterized in that the barrel (Barrel) type. The method of claim 1. The long side portion or the short side portion of the inner shield is a color cathode ray tube, characterized in that the arc having a constant curvature. The method of claim 1, The color cathode ray tube, characterized in that a plurality of straight lines that are not parallel to the shape of the long side portion or short side portion of the inner shield is combined. The method of claim 1, The color cathode ray tube, characterized in that the shape of the long side portion or short side portion of the inner shield is formed by combining a plurality of straight lines of different curvature.