KR20050045721A - Shodow mask for color cathode ray tube - Google Patents

Abstract

The present invention relates to a planar color cathode ray tube, and more particularly, to a color cathode ray tube panel manufactured by a close exposure method, which minimizes mislanding of an electron beam due to a southern hemisphere magnetic field without changing a fluorescent surface suitably designed for a northern half magnetic field. The present invention relates to a shadow mask for color cathode ray tubes.

In a shadow mask for a color cathode ray tube, in which a plurality of electron beam through holes are formed to face a phosphor screen formed on an inner surface of a panel, a vertical column formed by arranging the plurality of electron beam through holes vertically is curved to the left when the center portion is viewed from the front of the panel. Have

Description

Shadow Mask for Color Cathode Ray Tube {Shodow Mask for Color Cathode Ray Tube}

The present invention relates to a planar color cathode ray tube, and more particularly, to a color cathode ray tube panel manufactured by a close exposure method, which minimizes mislanding of an electron beam by a southern hemisphere magnetic field without changing a fluorescent surface appropriately designed to match the northern half magnetic field. The present invention relates to a shadow mask for color cathode ray tubes.

1 is a cross-sectional view for explaining the structure of a general flat color cathode ray tube.

As shown in FIG. 1, the flat color cathode ray tube is mounted on the front side of the cathode ray tube and fixed with resin resin on the front side of the panel 1 and the phosphor 5 coated on the inner side thereof. Safety glass 2 is formed to maintain the explosion-proof characteristics of.

On the inner surface of the panel 1, a rail 6, which is a metal support having a rectangular frame shape, which is fixed by frit glass, is formed, and numerous shadowed or circular electron beam transmission holes are formed in order to serve as color screening of the electron beam. The mask 7 is fixed with the tensile force applied to the rail. In addition, for shielding the geomagnetic field, the inner shield 8 is attached to the rail 6 by welding.

In addition, the flat color cathode ray tube is fixed to the panel 1 by a frit glass, and is formed in the back of the funnel 3 having the neck portion 3a integrally formed therein and the neck portion 3a of the funnel 3. Electron gun 4 for emitting electron beams of three colors R, G, and B to the phosphor side, and deflection yoke 9 for deflecting the electron beam in the horizontal and vertical directions of the screen by covering the outer circumferential surface of the neck portion 3a. It consists of. Moreover, the band 11 which fixes the several lugs 10 to the panel outer peripheral surface is fastened in order to fix to a chassis of a monitor or a TV.

In the flat color cathode ray tube constructed as described above, when power is applied to the heater of the electron gun 4, R, G, and B electron beams generated from the cathode are accelerated and focused while passing through a plurality of electrodes, and then the deflection yoke 9 Scanned toward the screen in a state deflected in the horizontal and vertical directions by the magnetic field. The scanned electron beam passes through the electron beam transmission hole of the shadow mask 7 which serves as color screening, and emits the phosphor 5 coated on the inner surface of the panel 1 to reproduce an image.

In the panel of the color cathode ray tube, a fluorescent film for reproducing a color screen is composed of RGB tricolor phosphors, and electrons scattered from the periphery of the panel are injected into the fluorescent film to excite the surrounding phosphors, and one The problem of emitting adjacent phosphors by an electron beam scanned for phosphor emission may occur.

In order to solve this problem, a graphite strip process for forming a black matrix of a non-luminescent absorbing material such as graphite is usually formed in the space between the pixels, and the trajectory of the electron beam scanned into each fluorescent film so that an RGB fluorescent film can be formed. It is subjected to a fluorescent strip process formed using light having the same irradiation trajectory as. The graphite strip process is performed by a BM (Black Matrix) type exposure machine, and the fluorescent strip process is performed by a PH (Phosphor) type exposure machine. Such exposure methods include mask exposure methods and proximity exposure methods.

According to the mask exposure method, a photosensitive film is coated on both surfaces of a thin sheet material forming a mask, and the photosensitive film is exposed to a predetermined pattern using an exposure mask and then manufactured by etching. On the other hand, according to the proximity exposure method, exposure is performed through a chrome etching pattern called artwork by a proximity exposure machine for panel exposure of a color cathode ray tube.

The present invention particularly relates to a fluorescent film of a panel of a color cathode ray tube manufactured by a close exposure method.

2 (a) and 2 (b) respectively show an arrangement of the vertical columns 22 of the plurality of through holes formed in the shadow mask 7 of the color cathode ray tube according to the conventional proximity exposure method and the phosphor 23 formed on the fluorescent surface. Is a diagram showing the vertical arrangement of the elements.

As shown in FIG. 2A, in the through holes 21 formed in the shadow mask 7, a plurality of through holes 21 are arranged in a line in the vertical direction to form one vertical row 22. . A plurality of such vertical through-hole rows 22 are formed in the left and right directions. That is, if one vertical column 22 of the through holes is represented by a single vertical line shape '|', the left and right arrangement of the vertical through holes is '||||' It takes shape.

FIG. 3 shows the position 30 at which the scanned electron beam is projected on the fluorescent surface shown in FIG. 2 (b) through the through hole 21 shown in FIG. 2 (a) when the color cathode ray tube is installed in the northern hemisphere magnetic field. ) Is shown.

As shown in Fig. 3, the electron beam starting with the electron gun 4 of the color cathode ray tube is passed through the vertical column 22 '||||' of the shadow mask for the northern hemisphere magnetic field. After passing through the through-holes 21 arranged in, it reaches the phosphor strip 23 of the fluorescent surface. In the northern hemisphere magnetic field, the electron beam that has passed through the shadow mask passage hole 21 for the northern hemisphere magnetic field is accurately projected onto the phosphor strip 23 of the fluorescent surface.

FIG. 4 shows that when a cathode ray tube having a shadow mask for the northern hemisphere magnetic field is installed in the southern hemisphere magnetic field, the scanned electron beam passes through the through hole 21 shown in FIG. The position 40 projected onto the phosphor strip 23 is shown. As shown in FIG. 4, in the southern hemisphere magnetic field, the electron beam passing through the through hole 21 of the shadow mask for the northern hemisphere magnetic field is shifted to the left when viewed from the front of the panel at the upper and lower portions of the phosphor strip 23, and is centered. The part is shifted to the right when viewed from the front of the panel.

The reason for this phenomenon is that when the magnetic field is converted from the northern hemisphere (Bv = 0.4G) to the southern hemisphere (Bv = -0.45G), the center of the inner shield flows upward and the electron beam moves to the right. Because the lower part is close to the inner shield, an inverse magnetic field is generated for the external magnetic field so that the magnetic field flows downward and the electron beam moves to the left.

Therefore, in the related art, when a cathode ray tube having a shadow mask for a northern hemisphere magnetic field is installed in a southern hemisphere magnetic field to emit an electron beam, as shown in FIG. 4, the electron beam reaching the phosphor strip 23 is formed by the upper and lower ends of the phosphor strip. There is a problem in that the mis-landing occurs due to the shift to the left and right in the center. Such mislanding is a cause of deterioration of screen characteristics.

In order to solve such a problem, it may be considered to manufacture a near-exposure fluorescent surface for the southern hemisphere magnetic field, but there is a problem that a considerable production cost is additionally used when using southern hemisphere artwork. In addition, there is a problem that additional time is required to prepare the equipment for exposure equipment in order to replace the proximity exposure artwork for the southern hemisphere magnetic field. Therefore, it is not preferable to fabricate the near exposure fluorescent surface for the southern hemisphere magnetic field in that additional cost and time are required.

An object of the present invention is to provide a shadow mask for a color cathode ray tube which can be applied to a southern hemisphere magnetic field without changing the proximity exposure machine for the northern hemisphere magnetic field in a color cathode ray tube of the proximity exposure method.

The shadow mask for color cathode ray tube of the present invention for achieving the above object is, in the shadow mask for color cathode ray tube formed with a plurality of electron beam through holes facing the phosphor screen formed on the inner surface of the panel, the plurality of electron beam through holes are up and down When the vertical rows arranged are viewed from the front of the panel, the central portion has a curved shape to the left.

Hereinafter, the present invention will be described in detail with reference to the drawings.

Figure 5 shows the vertical arrangement of the through-holes perforated in the shadow mask for the southern hemisphere magnetic field of the color cathode ray tube according to the present invention.

As shown in FIG. 5, the shadow mask according to the present invention is different from the conventional shadow mask illustrated in FIG. 2A, in which a plurality of through holes 51 are arranged vertically in a vertical row 52. It is not a single vertical line but an open parenthesis. Preferably, the vertical rows 52 of the plurality of through holes 51 have a parenthesis shape in which the central portion of the vertical rows 52 is bent to the left when viewed from the front of the panel. If one vertical column 52 of the through-holes is expressed in parenthesis shape '(', the left and right arrangements of the vertical through-holes 52 of the through-holes take the shape '((((').

If the shape of the vertical column 52 of the through hole 51 of the shadow mask according to the present invention is expressed by another method as follows. First, a straight line connecting the centers of the uppermost and the lowermost passing holes among the through holes included in the vertical column in which the plurality of through holes are arranged up and down is defined as a vertical vertical line. At this time, the center of the through hole is spaced apart from the vertical line to the left as the through hole disposed in the center portion of the through holes included in the vertical column. Thus, the distance that the center of the through-hole is separated from the vertical line to the left by h is shown in FIG.

FIG. 6 shows that when a cathode ray tube having a shadow mask according to the present invention is installed in a southern hemisphere magnetic field, the scanned electron beam passes through the through hole 51 shown in FIG. 5 and is projected onto the fluorescent surface shown in FIG. The location is shown.

As shown in FIG. 6, in the southern hemisphere magnetic field, the electron beam passing through the shadow mask through hole 51 according to the present invention is shifted to the left when viewed from the front of the panel at the upper and lower portions of the phosphor strip, and at the center portion. When viewed from the front of the panel is shifted to the right. At this time, since the vertical column 52 of the through holes is a parenthesis shape '(' bent to the left when viewed from the front of the panel in the center portion, the electron beams passing through the through holes 51 are shifted from the upper and lower portions and the center portion. This effect is corrected due to the shape of the vertical column 52 of the through-holes. As a result, the electron beam passing through the vertical column 52 of the parenthesis forms an upper end of the phosphor strip, as shown in FIG. Almost all positions 60 of the bottom, center part are reached exactly on the phosphor strip.

Here, the degree of warp of the vertical column shape of the shadow mask through hole is defined as the vertical length of the effective screen, and h is the center of the through hole spaced apart from a straight line connecting the top and bottom of the through hole vertical rows. In terms of distance, it is preferable to satisfy the following equation.

15000 ≤ v / h ≤ 100000

Specific embodiments satisfying the condition of Equation 1 may have the dimensions shown in Table 1.

The manufacture of the shadow mask in which the through-hole was formed in accordance with this invention can be performed, without changing the artwork used for the proximity exposure system for northern hemisphere magnetic fields.

That is, by adjusting the position of the shadow mask through hole on the iron plate coated with the photosensitive liquid, ultraviolet rays are irradiated, and the photoresist film of the unexposed portion is removed to corrode the developed iron plate surface to form a shadow mask through hole. Thereby, the shape of the vertical column of through-holes of the shadow mask can be changed in accordance with the present invention without changing the proximity exposure machine.

In the above description and the drawings, the case where the shape of the through-hole of the shadow mask is a stripe-pitch shape that is vertically elongated is described. However, it is apparent to those skilled in the art that the scope of the present invention is not necessarily limited thereto, and the present invention can be applied to a through hole having a dot pitch shape.

According to the present invention, the shadow mask for the northern hemisphere can be applied to the southern hemisphere magnetic field without changing the proximity exposure machine by changing the shape of the vertical rows of the shadow mask through-holes of the color cathode ray tube of the close-exposure type method from the conventional single vertical line shape to the open parenthesis. Can be.

Further, even if the color cathode ray tube provided with the shadow mask for the northern hemisphere magnetic field is provided in the southern hemisphere magnetic field, deterioration of the screen characteristics due to mis-landing of the electron beam can be prevented.

In addition, when the southern hemisphere artwork is used to make the fluorescent surface for the southern hemisphere, the cost increase and the replacement time of the proximity exposure machine can be suppressed.

1 is a cross-sectional view of a general color cathode ray tube structure.

Figure 2a is a schematic diagram showing the arrangement of the vertical rows of the shadow mask through-holes for a conventional color cathode ray tube.

Fig. 2B is a schematic diagram showing the vertical arrangement of phosphors formed on the fluorescent surface produced by the proximity exposure method.

Fig. 3 is a schematic diagram showing a position where an electron beam scanned in a northern hemisphere magnetic field is projected onto the fluorescent surface shown in Fig. 2 (b) through the through hole shown in Fig. 2 (a).

Fig. 4 is a schematic diagram showing a position where an electron beam scanned in a southern hemisphere magnetic field is projected onto the fluorescent surface shown in Fig. 2 (b) through the through hole shown in Fig. 2 (a).

Figure 5 is a schematic diagram showing the vertical arrangement of the through-holes perforated in the shadow mask for the southern hemisphere magnetic field of the color cathode ray tube according to the present invention.

FIG. 6 shows a position where a scanned electron beam is projected on a fluorescent surface shown in FIG. 2 (b) through a through hole shown in FIG. 5 when installing a cathode ray tube having a shadow mask according to the present invention in a southern hemisphere magnetic field; schematic.

< Description of the reference numerals for the main parts of the drawings >

One ; Panel 2; Safety glass

3; Funnel 4; Electron gun

5; Phosphor 6; rail

7; Shadow mask 8; Inner shield

9; Deflection yoke 10; rug

11; Reinforcing band 21; Through ball

22; Vertical rows of through holes 23; Phosphor strip

30, 40, 60; Scanning position of the electron beam

Claims (3)

In the shadow mask for color cathode ray tube formed with a plurality of electron beam through holes facing the phosphor screen formed on the inner surface of the panel, A shadow mask for color cathode ray tubes, wherein a vertical column formed by arranging the plurality of electron beam through holes vertically is bent to the left when viewed from the front of the panel. The method of claim 1, The relationship between the vertical length of the shadow mask effective screen and the deviation length of the center of the shadow mask effective screen is a relation between the vertical length of the shadow mask effective screen and v being the vertical length of the mask effective screen, and h being the center of the uppermost and lowest passing holes in the vertical column of the through-holes. When the distance of the center of the through hole from the straight line is the distance, 15000 ≤ v / h ≤ 100000 Shadow mask for color cathode ray tube satisfying the requirements. The method according to claim 1 or 2, The shadow mask through-holes of the shadow mask, characterized in that the stripe pitch (Stripe Pitch) type.