KR20000045831A - Flat cathode ray tube for controlling sagging phenomenon - Google Patents

Abstract

PURPOSE: A flat cathode ray tube for controlling sagging phenomenon is provided to reduce the rising spacing by forming a curvature with a radius less than 5000mm so as to control sagging phenomenon efficiently. CONSTITUTION: A flat cathode ray tube for controlling sagging phenomenon includes a flat glass panel(90), a fluorescent layer(92), and a shadow mask(95). The outer surface of the flat glass panel(90) has a round shape. The fluorescent layer(92) receives the light from the electron beam. The shadow mask(95) is implemented with a predetermined spacing from the fluorescent layer. A round shape with a radius from the center of the glass panel less than 5000mm is formed inside the glass panel. A skirt member(93) is connecting the curvature of the inner surface(90b) further formed on the outside of the glass panel(90).

Description

Sagging Restrained Flat Type CRT for Sagging Suppression

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flat cathode ray tube (hereinafter referred to as a CRT) such as a television receiver, wherein a sagging phenomenon is suppressed and formed by forming a curved surface having a radius of 5000 mm or less on an inner surface of a flat glass panel. The present invention relates to a planar CRT improved by increasing a skirt allowable internal vacuum by forming a skirt at the skirt.

In general, a CRT is a display device that focuses electrons emitted from a cathode enclosed in a tube and then accelerates them to make an electron beam and control its direction by the action of an electric field or a magnetic field.

Referring to FIG. 1 attached to the structure of the above-described CRT, the heater 110 and the heater 110 for raising the temperature of the cathode 120 by generating heat by receiving the image amplified R, G, and B signals. Cathode 120 that emits electrons when a negative voltage is supplied from the control grid 130 that modulates luminance (change in brightness) by adjusting the amount of electrons emitted from the cathode 120, and emits from the cathode 120. An acceleration grid 140 for supplying a constant voltage (for example, 110 V to 400 V) to attract electrons having negative charges and accelerating in the axial direction so that the electrons reach the fluorescent layer 192 at the rear of the panel 190, The medium acceleration grid 150 accelerates the electrons accelerated primarily by the acceleration grid 140 to a second voltage by supplying a constant voltage (for example, 10 kV or more), and the cathode 120 is emitted from the panel 190. Electrons traveling toward the fluorescent layer 192 diffuse by the repulsive force between the electrons Is focused in the axial direction to form a thinner electron beam, and a constant voltage (e.g., electrons emitted from the cathode 120 and accelerated twice through the acceleration grid 140, the medium acceleration grid 150). A high acceleration grid 170 for accelerating in the third order by supplying 10 kV or more to impinge on the phosphor layer 192 of the glass panel 190, and a high voltage of a predetermined voltage (for example, 10 kW) or more. An anode terminal 180 for supplying the fluorescent layer 192 of the aluminum film 190 and discharging a high voltage when the power is "off" is provided.

In addition, in the case of the color CRT, the electron gun is equipped with three electron guns of red (R), green (G), and blue (B).

In addition, a shadow mask 195, which is a porous metal plate attached to a position about 10 mm away from the fluorescent layer 192, is required in order to accurately match the beam emitted from the electron gun with the set fluorescent position. Such a shadow mask 195 is provided. There are two types according to the shape of the slot type (a slot type) and the aperture grill type (aperture grill type).

However, in the conventional spherical CRT as shown in FIG. 1, since the glass panel 190 has a round, or curvature, of about 1 to 3.5 R, the curvature of the straight line of the scanning line changes depending on the viewing position, as well as the curvature. This causes a problem that the ambient light is reflected.

In this case, the change of the straight line means that the straight line of the image is curved according to the viewing position. If the viewpoint is placed at the center of the screen, the screen distortion is minimal, and if the viewpoint is placed at the outside of the screen, the screen distortion is maximized. There is a problem that it is difficult to watch natural and clear images. In addition, the light reflected through the screen from the fluorescent lamp or the glass window not only tired the viewer's eyes, but also interferes with viewing.

Recently, the CRT of the flattened glass panel which minimizes the screen distortion by flattening the outer surface of the glass panel has been developed and used.

The CRT of the flattened glass panel has two types of structures that flatten the outer surface of the glass panel and give rounding to the inner surface and the shadow mask to have a certain curvature, and a structure in which both the inner and outer surfaces are flattened. As the outer surface becomes flat, it is possible to minimize distortion and diffuse reflection of the screen.

By the way, the CRT that flattened both the inner and outer surfaces has several advantages, such as structural manufacturability, compared to the CRT having only the outer surface, but it causes a sagging phenomenon in which the central part is concave due to the difference in refractive index between the glass panel and the air. Done.

That is, when the sagging phenomenon appears in detail, each of the R, G, and B beams are deflected by deflection yoke coils in the electron gun in the CRT having the inner and outer surfaces flattened, so that the slits of the shadow mask ( Slit) is cross (cross) to the light emitted by the R, G, B fluorescent layer of the glass panel.

In this case, a real image appears on the inner surface of the glass panel directly under the fluorescent layer. However, the virtual image of a person seems to appear on the outer surface of the glass panel.

This rising phenomenon, that is, the virtual image felt by love is more floating than the actual image is caused by the difference of 1.542 refractive index of glass panel and 1.003 refractive index of air.

As shown in FIG. 2, the electron beam emitted from the electron gun diverges from the R, G, and B fluorescent layers at an angle Φ by the refractive index of the glass panel, and is also refracted at an angle θ by the refractive index of air to be felt by the viewer's eyes. Will be. Thus, the virtual image felt by the viewer appears at the point where it extends to two sides of two adjacent rays.

Where angle Φ and angle θ are determined by Snell's law.

That is, the refractive index n_One＞ n₂If n_OneSin θ_One= n₂Sin θ₂to be. N at this time_OneSilver refractive index_Oneego , n₂The refractive index₂Θ_OneIs the angle of incidence, θ₂Is the angle of incidence.

Accordingly, the rising phenomenon is not large enough to feel when the viewing distance is long, but there is a problem that the sagging phenomenon that looks concave fundamentally is not solved.

In addition, since the inner and outer surfaces of the CRT flattened as described above, since the inner and outer surfaces are completely flat, the flatness of each of the inner and outer surfaces must be matched when manufacturing the glass panel, and thus, a complicated polishing process is required.

In addition, since the inner surface of the CRT is a vacuum, the planar structure of the inner and outer surfaces is insufficient in vacuum allowable stress, and the thickness of the glass panel must be formed relatively thicker than the spherical structure. In this case, when the thickness of the glass panel is thick, the cooling time becomes long, resulting in a problem that the drop per minute (DPM) is lowered and productivity is lowered.

Accordingly, the present invention has been made in view of the above-described conventional problems, and a first object is to suppress sagging due to the difference in refractive index between the flattened glass panel and the air by forming an appropriate round structure on the inner surface of the flattened glass panel. The purpose is to provide a planar CRT.

A second object of the present invention is to provide a planar CRT that can increase productivity by increasing an internal vacuum allowable stress.

1 is a configuration diagram of a general CRT

Figure 2 is an exemplary view showing the sagging phenomenon in the conventional CRT planar inner and outer surfaces

Figure 3 is a block diagram showing a planar CRT for suppressing the sagging according to an embodiment of the present invention

4 is an enlarged cross-sectional view of the glass panel of the flat CRT shown in FIG.

5 is an exemplary view showing a sagging suppression state by the glass panel shown in FIG.

Explanation of symbols on the main parts of the drawings

90: glass panel 90a: outer surface

90b: inner surface 92: fluorescent layer

93: skirt portion 95: shadow mask

The present invention for achieving the first object of the present invention is a planar CRT in which an outer surface is formed on the inner surface of the flattened glass panel is formed a fluorescent layer for projecting the beam from the electron gun and a shadow mask is installed at a predetermined interval from the fluorescent layer To provide a planar CRT in which a curved surface having a radius of 5000 mm or less from the center is formed on the inner surface of the glass panel.

In addition, the present invention for achieving the second object is to provide a planar CRT in which the skirt portion for connecting the curved surface of the inner surface to the rear of the outer glass panel is formed.

Hereinafter, an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

3 illustrates a planar CRT 1 for suppressing sagging according to an embodiment of the present invention. The basic structure except for the detailed structure of the glass panel 90 of the CRT 1 is different from that of the conventional planar CRT structure. Almost the same.

That is, a heater 10 for raising the temperature of the cathode 20 is installed behind the cathode 20 by generating heat by receiving the amplified R, G, and B signals, and at this time, the cathode 20 is negative. It is made to emit electrons when a negative voltage is supplied.

In addition, a control grid 30 is provided in the cathode 20 to modulate the luminance by controlling the amount of electrons emitted, and the electrons emitted from the cathode 20 extend to the fluorescent layer 92 on the rear surface of the glass panel 90. An acceleration grid 40 is provided in front of the cathode 20 that supplies a constant voltage to reach and attracts electrons with charges to accelerate in the axial direction.

In front of the acceleration grid 40, the medium acceleration grid 50 accelerates the electrons accelerated primarily in the acceleration grid 40 to a second by supplying a constant voltage, and the cathode 20 is discharged from the glass. The focusing grid 60 makes an electron beam axially concentrating the electrons moving toward the fluorescent layer 92 of the panel 90 by the repulsive force between the electrons, and the cathode 20 is emitted from the acceleration grid ( 40), the super acceleration grid 70 is provided to supply a constant voltage to the electron accelerated twice through the medium acceleration grid 50 to accelerate the third order to impinge on the fluorescent layer 92 of the glass panel 90. .

On the other hand, the funnel coupled to the glass panel 90 is provided with an anode terminal 80 for supplying a high voltage of a predetermined voltage or more to the aluminum film of the fluorescent layer 92 of the glass panel 90 and discharging the high voltage when the power is "off". The shadow mask 95 made of a porous metal plate is attached to the fluorescent layer 92 at a predetermined distance. At this time, the shadow mask 95 is to be exactly matched to the position of the fluorescent layer 92, the beam emitted from the electron gun, and maintain a constant distance from the inner surface (90b) of the glass panel 90.

4, the outer surface 90a of the glass panel 90 is formed in a flat surface, and the inner surface 90b is formed to suppress sagging due to the difference in refractive index between the glass panel 90 and the air. Consists of a curved surface with a small radius. At this time, the curved surface of the inner surface (90b) is formed with a radius of less than 5000mm to form a thickness of the outer portion of the glass panel 90 gradually thicker than the center.

In addition, a skirt portion 93 is formed on the outer side of the glass panel 90 to connect the curved surface of the inner surface 90b to the rear, and the shadow mask 95 is the skirt of the glass panel 90 by the stud pin 96. It is fixed to the part 93.

According to the planar CRT 1 according to the embodiment of the present invention configured as described above, a relatively small radius curved surface is formed on the inner surface 90b of the glass panel 90 so that the thickness gradually increases from the center to the outer portion. Therefore, as shown in FIG. 6, the rising interval is shortened by the distance of L, and the sagging phenomenon is considerably reduced.

In other words, as the viewing distance becomes longer as the viewing angle becomes larger, the central portion of the glass panel 90 appears more concave. On the contrary, the smaller the viewing angle, the shorter the rising interval, so that the sagging phenomenon is reduced.

Therefore, the glass panel 90 according to the embodiment of the present invention compensates the rising interval according to the viewing angle by the curved surface formed on the inner surface 90b, thereby suppressing the sagging phenomenon.

In addition, the skirt 93 in the glass panel 90 can increase the vacuum allowable stress of the glass panel 90 by dispersing the stress due to the internal vacuum and reinforcing the outer portion.

As described above, the present invention has an effect of improving the image quality by effectively suppressing sagging by forming a curved surface having a radius of 5000 mm or less on the inner surface of the flat glass panel to shorten the rising interval.

In addition, the present invention is to form a skirt portion on the outer side of the flat glass panel to be able to expect a high internal vacuum allowable stress even in a relatively thin thickness, as well as to eliminate the internal and external surface polishing process, thereby improving the productivity of the glass panel It can be effective.

While the invention has been shown and described with respect to particular embodiments, those skilled in the art will recognize that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended claims. Anyone can easily know.

Claims (2)

On the inner surface 90b of the flattened glass panel 90 whose outer surface 90a is flat, a fluorescent layer 92 on which a beam from an electron gun is projected is formed, and a shadow mask (a predetermined distance from the fluorescent layer 92 is formed). 95. A planar CRT (1), wherein a flat surface having a radius of 5000 mm or less from the center is formed on an inner surface (90b) of the glass panel (90). The planar CRT according to claim 1, wherein a skirt portion (93) is formed on the outer side of the glass panel (90) to connect the curved surface of the inner surface (90b) to the rear.