KR20030062930A - The Flat type CRT - Google Patents

Abstract

PURPOSE: A flat cathode ray tube is provided to achieve improved color purity by reducing the difference of beam grouping between the center and upper and lower portions of the screen. CONSTITUTION: A flat cathode ray tube comprises a panel having flat inner and outer surfaces; a rectangular rail(14) attached to the inner surface of the panel; and a shadow mask attached to the rail and which discriminates colors of electron beams. The height(Qr) of the center of the rail is higher than the height(Q'''r) of both ends. The height of the rail gradually decreases as it goes from the center toward both ends of the rail.

Description

Flat cathode ray tube {The Flat type CRT}

The present invention relates to a planar cathode ray tube, and more particularly, to a planar cathode ray tube which reduces the purity of the beam grouping between the center and the upper and lower portions of the screen, thereby improving the purity characteristics and preventing color purity from being lowered. will be.

Generally, a planar cathode ray tube is used for a television receiver or a monitor, and the cathode ray tube is roughly classified into a curved type and a flat type according to the shape of the screen.

The curved cathode ray tube is distorted and its demand is gradually reduced due to eye fatigue caused by reflection of light. On the other hand, the planar cathode ray tube is actually closer to the image and the demand is gradually decreased because of less reflection by external light. It is becoming a trend.

1 is a cross-sectional view showing a part of a planar cathode ray tube, which is a flat panel 1 having a phosphor 2 coated on its inner surface and a resin paper fixed to a front surface of the panel to maintain the explosion-proof characteristics of the cathode ray tube. Safety glass (3), metal rail (4) of rectangular frame shape fixed to the inner surface of the panel by frit glass, and fixed to the rail with tension applied to the air gap shape to serve as the color selection of the electron beam Or a shadow mask 5 having a large number of circular electron beam through holes 5a, a funnel 6 fixed to the panel 1 with frit glass, and having a neck 6a integrally formed at the rear thereof, and the funnel An electron gun 7 encapsulated in the neck portion 6a of (6) to emit electron beams of three colors R, G, and B to the phosphor side, and installed so as to surround the outer circumferential surface of the neck portion 6a so that the electron beam is horizontally positioned on the screen. And a deflection yoke for deflecting in the vertical direction (8) Etc.)

In the planar cathode ray tube configured as described above, power is applied to the heater of the electron gun 7 so that three electron beams of R, G, and B generated from the cathode are accelerated and focused while passing through a plurality of electrodes, and then the deflection yoke ( Scanned toward the screen in a state deflected in the horizontal and vertical directions by the magnetic field of 8).

The electron beam scanned as described above passes through the electron beam through hole 5a of the shadow mask 5, which serves as color screening, and emits the phosphor 2 coated on the inner surface of the panel 1, thereby reproducing an image.

3 schematically illustrates the contents of grouping ratios.

In general, the uniformity of the interval between the R, G, and B phosphors 2 applied to the inner surface of the panel 1 shown in FIG. 1 is referred to as a screen grouping ratio. As shown in FIG. The grouping ratio is "1" when the distance between the B and B phosphors and the distance between the R and R phosphors is 2/3. The grouping ratio is larger than "1", and the group is smaller than "1". It is called (Group).

2 is a cross-sectional view showing a part of a planar cathode ray tube.

As shown in FIG. 2, beam grouping is determined by the distance Qm between the inner surface of the panel 1 and the shadow mask 5 and the distance between electron beams of three colors R, G and B at the deflection center. , Calculated by the horizontal pitch Ph of the electron beam through hole formed in the shadow mask 5, and the distance L to the deflection center of the deflection yoke of the panel.

GR = (3 * S * Qm) / (Ph * L)

Accordingly, in the conventional flat cathode ray tube, since the shadow mask 5 applied by using the rail 4 having a constant height is fixed, the distance Qm between the inner surface of the panel 1 and the shadow mask 5 and the inner surface of the panel. And the distance L to the center of deflection is determined.

Therefore, it is very difficult to keep the beam grouping constant and uniform throughout the screen in the planar cathode ray tube of this structure.

In particular, in the case of curved cathode ray tubes, beam grouping can be maintained uniformly throughout the screen by the curvature of the shadow mask. However, in the case of planar cathode ray tubes, the curvature can be applied because it is made to be completely flat by applying tension to the shadow mask. As a result, beam grouping adjustments by shadow masks are impossible.

Looking at the conventional techniques for making the beam grouping ratio constant and uniform throughout the screen, as described above, the method of adjusting the curvature of the shadow mask and the method of adjusting the horizontal pitch (Ph) of the shadow mask are widely used. Used.

However, the method of adjusting the curvature of the shadow mask is not applicable in the planar cathode ray tube, and also in the case of the method of adjusting the horizontal pitch Ph of the shadow mask, beam grouping in the horizontal direction of the screen (Beam Grouping). Ratio can be made uniform, but not applicable in the vertical direction.

That is, when the horizontal pitch Ph of the center and the upper and lower portions of the screen are different from each other, the vertical straightness of the screen is degraded.

The reason for generating a difference between beam grouping ratios in the center and upper and lower portions of the screen in the planar cathode ray tube will be described with reference to FIGS. 4, 5, 6, and 7.

Figure 4 is a simplified diagram showing the beam path of the center and corners of the screen in a planar cathode ray tube.

In FIG. 4, if the deflection center A ′ of the center and the corner of the screen is the same, the relationship is as follows.

Q / L = Q '/ L'

According to the equation representing beam grouping, beam grouping of the center and the corner is the same.

However, in the case of the electron beam deflected to the corner portion in the actual driving of the planar cathode ray tube, the deflection center A '' is positioned closer to the screen side than the deflection center A 'of the central beam of the screen.

At this time, the position of the deflection center (A '') of the electron beam deflected to the corner portion is an imaginary point obtained by experiment, the actual L 'value of the corner portion is represented by L'',Q' value is represented by Q '', which is the screen And the horizontal pitch (P _H ) of the shadow mask.

Therefore, beamgrouping at the center and the corner of the screen during deflection of the cathode ray tube has the following relationship.

Q / L <Q '' / L ''

That is, the beam grouping ratio (Beam Grouping Ratio) of the corner portion is larger than the center portion, which appears as the tendency of Degroup.

However, in the case of a planar cathode ray tube, the beam grouping tends to be more degroup than the center of the screen rather than the left and right corners of the screen which are farther from the center.

This is largely due to two causes.

First, the vertical sensitivity of the deflection device is smaller than the horizontal sensitivity. Due to the low sensitivity, the deflection center moves towards the screen, and the beam has a degroup tendency.

Second, it occurs in the process of correcting geometric problems that occur because the inner surface of the panel is completely flat.

Screen pincushion of planar cathode ray tube As shown in FIG. 5, the last of screens displayed by pure deflector without correction or correction device in cathode ray tube with inner surface of panel is completely flat compared to cathode ray tube with curvature on inner surface. Pincushion appears worse.

In order to correct this, the tracks L ″ and Q ″ of the beam when the pincushion correction magnet 9 is mounted are shown in FIG. 7, and the following relationship is established in FIG. 7.

Q '' / L '' <Q '' '/ L' ''

If the above relationship is established, when the magnet for pincushion correction is mounted, the beam grouping ratio will have a tendency of degroup compared to the center portion.

The beam grouping difference between the center and the top and bottom of the screen deteriorates the purity and degrades the color purity.

Accordingly, an object of the present invention is to solve the conventional problems, and to reduce the difference in beam grouping between the center and the top and bottom of the screen while maintaining the same horizontal pitch of the center and top and bottom of the shadow mask.

1 is a cross-sectional view showing a part of a typical planar cathode ray tube cut away.

2 is a cross-sectional view showing a portion of a planar cathode ray tube.

3 is a schematic diagram illustrating a screen and a grouping ratio.

Figure 4 is a simplified diagram showing the beam path of the center and corners of the screen in a planar cathode ray tube.

5 is a screen pincushion of the planar cathode ray tube.

Figure 6 is a simplified diagram showing the beam path when the pincushion correction magnet attached to the upper portion of the planar cathode ray tube.

Figure 7 is a perspective view showing the beam path when the pincushion correction magnet attached to the upper portion of the flat cathode ray tube.

8 is a perspective view of a short side rail according to the present invention;

Explanation of symbols on the main parts of the drawings

1: panel 2: phosphor

4,14: Rail 9: magnet

The present invention for achieving the object as described above, the planar cathode ray tube comprising a panel having a flat inner and outer surfaces, a rectangular rail attached to the inner surface of the panel and a shadow mask attached to the rail to perform color screening function of the electron beam. The height of the center portion of the short side rail is formed higher than the height of the other side.

Hereinafter, with reference to the accompanying drawings, the present invention to achieve the above object will be described in detail.

The present invention is to adjust the beam grouping (Beam Grouping) having a degroup characteristics of the upper and lower portions of the screen by adjusting the height of the short side rail.

In general, it is known that the top view of the upper surface of the rail 4 for fixing the shadow mask should be kept very precisely. However, when viewed from the beam grouping side of the center and top and bottom of the screen, It is more advantageous to make the height lower than the center part.

At this time, in the case of the long side rail is usually not necessary to vary the height.

0, because the horizontal pitch (P _H ) of the shadow mask can be adjusted to maintain the beam grouping in the horizontal direction of the screen uniformly.

8 is a perspective view of a short side rail according to the present invention.

As shown, the height (Qr) of the central portion of the short side rail is formed higher than the height (Q '' r) of both ends, it is preferable to be formed to be curved so as to gradually lower from the center to both ends. .

In general, considering that the difference between the beam grouping ratio of the center portion and the upper and lower portions of the flat cathode ray tube is 6% to 10%, the following relationship is established in FIGS. 4 and 7.

(1.05 ~ 1.10) * (Q / L) = Q '' '/ L' ''

This is due to the fact that the upper and lower L '' 'values are reduced compared to the central part.

Typically, when the beam grouping ratio of the center part is about 0.95 and the beam grouping ratio of the upper and lower parts is about 1.03, the beam grouping ratio of the center part and the upper and lower parts is about 8%. There is a difference.

Based on the difference of about 8%, a distance difference (Qm) of about 4% should occur between the center mask and the upper and lower shadow masks and the inner surface of the panel, and the distance difference eliminates the beam grouping difference between the center and the upper and lower screens. . When the distance (Qm) between the center and top and bottom shadow masks and the inner surface of the panel is maintained at 2% to 5%, the difference between the center and top and bottom beam groupings can be compensated for by 6 to 10%.

Therefore, it is preferable that the center height Qr of the short side rail has a value of 102% to 105% as compared with the height Qr '' 'of both ends of the rail.

The short side rail 14 formed as described above is attached to the inner surface of the panel 1, as shown in FIG. 1, and a shadow mask 5 is attached to the upper surface of the rail 14.

The rail 14 according to the present invention has a central portion height Qr formed higher than the heights Qr '' 'of both ends to form a curvature on the upper surface, and the shadow mask 5 is the upper surface of the rail 14. It is fixed at and has curvature.

The shadow mask 5 having the curvature adjusts beam grouping to reduce the difference between the beam grouping at the center and the corner of the screen.

Therefore, the shadow mask 5 of the planar cathode ray tube made of a completely flat plane with no curvature and the beam grouping adjustment is impossible, by using the short side rail 14 according to the present invention, the beam grouping adjustment This is possible.

Therefore, according to the present invention, in the planar cathode ray tube employing the shadow mask and the deflection yoke fixed to the rail by the tensile force, the height of the center portion of the short side rail among the rails is higher than the height of the other side of the planar cathode ray tube. It prevents the difference of beam grouping between the upper and lower parts of the screen and keeps it uniform.

Claims (3)

In a planar cathode ray tube comprising a panel having a flat inner and outer surfaces, a rectangular rail attached to an inner surface of the panel, and a shadow mask attached to the rail to perform color discrimination of electron beams. A flat cathode ray tube, characterized in that the height of the center portion of the short side rail is higher than the height of the other side. The method of claim 1, A flat cathode ray tube, characterized in that the height of the short side rail is gradually lowered from the center to both ends. The method according to claim 1 and 2, The center portion of the short side rail is a flat cathode ray tube, characterized in that formed in 102% ~ 105% compared to the height of both ends.