KR20030038251A - Shadowmask for Color CRT - Google Patents

Abstract

The present invention improves the brightness by improving the slot structure of the color-selective electrode of the color cathode ray tube, reduces the difference in brightness between the center and the periphery, and accurately expresses the width of the phosphor when the phosphor is formed on the screen. An object of the present invention is to provide a color-selective electrode of a color cathode ray tube that improves the efficiency of the color cathode ray tube.

To this end, the present invention is a color-coded electrode including an open bridge formed by forming a slot parallel to the short side direction on a substantially rectangular thin panel panel and cutting the bridge between the slot and the slot, wherein the width of the slot center portion is opposite the slot. It is formed to be narrower than the width of the provides a color-selective electrode of the color cathode ray tube, characterized in that provided with a slot of approximately peanut shape.

Description

Color screening electrode of color cathode ray tube {Shadowmask for Color CRT}

The present invention relates to a color screening electrode of a color cathode ray tube, and more particularly, to a slot structure of a color screening electrode.

In general, as shown in FIG. 1, the color cathode ray tube is combined with a front glass called a panel 1 and a rear glass called a funnel 2, and inside thereof, a fluorescent screen 4 and a fluorescent screen ( There is an electron gun, which is the source of the electron beam 6 emitting light 4), a dichroic electrode 3 which selects colors to emit light of a predetermined phosphor, and a frame 7 supporting the same.

In addition, a spring (8) for coupling the frame assembly to the panel (1) and an inner shield (9), which serves as a shield so that the cathode ray tube is less affected by external geomagnetisms during operation, are sealed in a high vacuum while being fixed to the frame. .

Hereinafter, the operation principle of the CRT will be described in which the electron beam 6 strikes the fluorescent surface 4 formed on the inner surface of the panel 1 by the anode voltage applied to the cathode ray tube in the electron gun embedded in the neck of the funnel 2. At this time, the electron beam is deflected up and down and left and right by the deflection yoke 5 before reaching the fluorescent surface to form a screen.

There are 2, 4 and 6 pole magnets 10 that modify their trajectory so that the electron beam 6 strikes a predetermined phosphor precisely, thereby preventing poor color purity. The CRT is designed to have a structural strength that can withstand atmospheric pressure in order to prevent this since the firecracker can be easily caused by external impact because it is sealed by high vacuum. Moreover, by attaching the reinforcement band 11 to the skirt of the panel 1, the stress which a CRT tube of a high vacuum state receives is disperse | distributed and the shock resistance is ensured.

2 is a plan view and a partially enlarged view showing an example of a conventional dichroic electrode.

Referring to the drawings, a hole 32 is formed in the dichroic electrode 3 so as to allow electron beams to pass therethrough. The hole 32 is called a slot 32, and the boundary between the slot 32 and the slot 32 is bridged 34. Is called. Conventionally, in order to improve the screen quality, several screening electrodes are formed by cutting several bridges 34 to form open bridges 36.

In the optically deflected color cathode ray tube employing the color-selective electrode 3 as described above, the transmittance of the electron beam passing through the color-selective electrode 3 must be increased in order to improve luminance, which is one of the most important characteristics among the quality characteristics.

In particular, in the light deflection color cathode ray tube, the distance difference between the center part and the peripheral part is large, and thus the transmittance is very important because the difference in the intensity of the beam remains large. In order to increase the transmittance, the width of the slot 32 should be increased or the length of the slot 32 should be increased to increase the area through which the electron beam passes.

When the width of the slot 32 is increased, the size of the electron beam increases in the X direction when the electron beam passes through the slot 32 and strikes the phosphor formed on the screen. Therefore, the path of the electron beam is due to external factors or characteristics of the color cathode ray tube. Since the margin for landing error that occurs when the electron beam does not strike the phosphor accurately is reduced, the width of the slot 32 is adjusted in consideration of this margin, and the length of the slot 32 is increased. The bridge 34, which is composed at regular intervals due to visual factors, is represented by the combination of the bridge shadow observed by the user and the scan interval of the deflection yoke and the bridge 34 separating the slots 32 in the vertical direction. Considering the moire, the interference fringe of light, the length of the slot is increased to adjust the electron beam transmittance.

When the screen is formed, the lens is used to have the same trajectory as the electron beam, and since the light is deflected, the length of the cathode ray tube that is shortened is controlled by shortening the length of the light source and the surface on which the phosphor is to be generated.

In the periphery of the dichroic electrode 3, when the light passes through the dichroic electrode 3, the phenomenon caused by the intensity of the electron beam is weakened due to the increase in the deflection angle. It can be seen that it does not occur and the intensity does not fall, but the connection part of the slot 32, that is, the bridge part, can be seen that the electron beam is distorted in a shape that is significantly different from that of the color-coded electrode design. The slot width that passes through the electron beam is also smaller than the design value.

In the light deflecting color cathode ray tube, the slot structure of the color discriminating electrode is very important as described above. As shown in FIG. 3, slots can be roughly classified into three types.

In FIG. 3, the structure capable of maximizing the amount of electron beams passing through the dichroic electrodes according to the shape of the slot is rectangular. However, in the fabrication method of the color-coded electrode 3, the photochromic method is used in the tensile color-coded electrode employing the open bridge 36, so that the bridge is much narrower than the conventional cathode ray tube. It is impossible to produce slots of the shape.

In order to solve this problem and increase the electron beam transmittance at the periphery, a method of increasing the area of the slot to transmit the electron beam by the rectangular slot area is adopted. However, it is difficult to solve the problem of distorting the electron beam in the slot shape of FIG. 3 as shown in FIG. 4.

In the general color cathode ray tube, the exposure process of forming the phosphor on the screen is composed of a light source acting as an electron beam and a lens acting as a deflection yoke. The deflection yoke is used for the purpose of shortening the length of the color cathode ray tube. It is mainly used to reduce the length by increasing the deflection angle of.

As described above, if the deflection angle is increased to reduce the length, the length of the light source from the light source to the fluorescent surface is reduced in the same manner as in the application process.

In this way, the length of the center portion is shortened, but the length ratio from the light source of the center portion and the peripheral portion to the fluorescent surface increases as the deflection angle increases in the peripheral portion.

When the length ratio increases, the intensity of the light emitted from the light source unit is considerably lowered compared to the existing cathode ray tube. As a result, the intensity of light passing through the dichroic electrode 3 becomes relatively small at the periphery, thereby narrowing the surface forming the phosphor, and the difference in brightness between the center and the periphery appears to be greater than the design value, thereby degrading the quality of the cathode ray tube. It causes.

In addition, in order to realize the color, the black matrix that forms the boundary between colors must maintain a straight line so that the human eye cannot recognize it.However, due to the above effects, an uneven boundary occurs in the black matrix. There is a problem that adversely affects.

The present invention has been made to solve the above-described problems of the prior art, and improves the brightness by improving the slot structure of the color-selective electrode of the color cathode ray tube, reducing the difference in brightness between the center and the peripheral portion, when forming a phosphor on the screen It is an object of the present invention to provide a color selection electrode of a color cathode ray tube that improves the ability to express colors on a screen by accurately manufacturing a width at which a phosphor is located.

1 is a schematic cutaway cross-sectional view of a typical colored cathode ray tube.

2 is a plan view and a partially enlarged view showing a general shape of a conventional dichroic electrode;

3 is a plan view showing a slot shape of a conventional dichroic electrode;

4 is a photographic view showing distortion of an electron beam passing through a dichroic electrode.

5 is a comparative view showing a comparison between a rectangular slot and a peanut-shaped slot according to the present invention

Figure 6 is a plan view and partially enlarged view showing a peanut-shaped slot according to the present invention.

** Explanation of symbols for main parts of drawings **

3: color-coded electrode 30: slot

34: bridge 36: open bridge

In order to achieve the above object, the present invention provides a color-coded electrode comprising an open bridge in which a slot is formed on a substantially rectangular thin panel in parallel with a short side direction, and a bridge between the slot and the slot is cut. The width of the slot is formed narrower than the width of both ends of the slot to provide a color-selective electrode of the color cathode ray tube, characterized in that provided with a slot of approximately peanut shape.

The structure of this invention is demonstrated in detail, referring an accompanying drawing. For reference, prior to describing the configuration of the present invention, in order to avoid duplication of description of the prior art reference to the same reference numerals will be referred to.

6 is a view showing a preferred embodiment of the slot form of the color-coded electrode according to the present invention.

Referring to the drawings, the slot form of the present invention may be said to be a nut shape which is approximately elongate and the center part is recessed inward. Compared with the conventional slot 32, it can be seen that the upper and lower side curvature portions are increased, so that the slot width is expanded by Sw in the drawing.

The reason for the slot 30 in the form of a peanut as shown in FIG. 5 is as follows.

The most distorted portion of the electron beam when the electron beam passes through the slot 30 is the bridge adjacent portion. In order to solve this problem, in the present invention, the slot width of the adjacent portions of the bridge is larger than the width at the slot center.

In this way, the distortion of the electron beam generated in the bridge portion can be eliminated. However, if the slot width of the bridge portion is made too large, the shape of the electron beam shown on the screen is also displayed in the same shape as the slot in the color-coded electrode.

Therefore, the shape of the slot 30 should be determined in consideration of the above matters. In the case of 32 inches, when comparing the slot area on the color-coded electrode with the slot area on the screen, the difference in area ratio is up to 7% at the periphery. If the area of the enlarged slot 30 is 7% or less at maximum, an accurate image without distortion of the electron beam can be obtained.

However, the area of compensation is different depending on the size of the color-coded electrode and the size of the slot.

5 is a comparative cross-sectional view comparing the size of the rectangular slot 30 'and the peanut slot 30 according to the present invention.

As such, comparing the sizes of the rectangular slots 30 'and the peanut-shaped slots 30 shows that the total area A of the peanut-shaped slots 30 is larger than the maximum rectangular area a of the slots, thereby increasing the amount of electron beams. This is because it is easier to explain that the distortion phenomenon of the electron beam does not occur because it is more easily transmitted.

Referring to the drawings, the ratio of the total area A of the peanut-shaped slot 30 to the maximum rectangular area (a) of the rectangular slot 30 'should not exceed 110%. The reason is that distortion of the electron beam occurs only in the bridge portion and the amount is not large enough to distort the shape of the original slot.

Therefore, in the present invention, it is preferable that the enlarged area of the slot 30 is 10% or less from the area of the original rectangular slot 30 '.

In addition, the ratio of the total area of the peanut-shaped slot 30 of the present invention to the maximum area of the original slot 32 should be maintained at least 100%. The reason for this is that in the peripheral portion, the incident angle of the electron beam is incident to more than 45 degrees, so that the beam interference and diffraction of the slot portion occur, so the transmittance is relatively poor. In order to maintain the transmittance at the periphery at the design value, it is desirable to be larger than the maximum rectangular area of the slot.

As shown in FIG. 5, when the total area of the slot formed by the present invention is A, and the area of the rectangle corresponding to the center width and length of the slot is a, it is preferable that A and a satisfy the following equation. Do.

1 <A / a <1.1

As shown in FIG. 4, when the distortion of the electron beam occurs only in one direction, that is, in the incident direction of the electron beam, the expansion of the slot may be performed in one direction.

In the color cathode ray tube, it prevents the electron beam shape distortion caused by the moving distance of the electron beam, thereby reducing the brightness difference between the center and the periphery, which is an important characteristic.

In addition, the light emitter on the screen directly observed by the user's eyes can be manufactured more uniformly according to design specifications, thereby helping to improve the visibility of the user.

By applying the present invention, it is possible to easily overcome the problems of the light deflecting cathode tube, which is widely used to reduce the total length of the cathode ray tube, that is, the process of resetting the process conditions and changing the electrode design for each color line.

Claims (3)

A slotted electrode formed on a substantially rectangular thin panel in parallel with a short side direction and including an open bridge obtained by cutting a bridge between the slot and the slot, wherein the width of the center portion of the slot is smaller than the width of both ends of the slot. Color discriminating electrode of a color cathode ray tube, characterized in that it has a substantially peanut-shaped slot The method of claim 1, Color-selective electrode of the color cathode ray tube, characterized in that the curvature of the upper and lower ends of the slot is a circular curvature The method of claim 1, When the total area of the slot is A, and the area of the rectangle corresponding to the center width and height of the slot is a, A and a satisfy the following equation. 1 <A / a <1.1