KR20000045833A - Flat cathode ray tube structure - Google Patents

Abstract

PURPOSE: A flat cathode ray tube structure is provided to flatten the glass panel so as to minimize the distortion of the light due to the roundness of the glass panel. CONSTITUTION: A flat cathode ray tube structure includes a cathode(120), a shadow mask(192), and a glass panel(190). The cathode(120) emits electrons. The shadow mask(192) is implemented from the cathode with a predetermined spacing. The glass panel(190) includes a fluorescent layer which is applied inside the glass panel. The glass panel has a round over than 84 to minimize the distortion of the light.

Description

Flat CRT structure

The present invention relates to a cathode-ray tube (hereinafter, referred to as a 'CRT'), and more particularly, to flatten a glass panel so that the reflection of ambient light and the distortion of the screen according to the round of the glass panel are reduced. It relates to a planar CRT structure that can be minimized.

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.

As shown in FIG. 1, the structure of the CRT is a heater 410 that generates heat by receiving amplified R, G, and B signals, thereby raising the temperature of the cathode 420, and a negative ( A cathode 420 that emits electrons when a voltage is supplied, a control grid 430 that modulates luminance (change in brightness) by adjusting the amount of electrons emitted from the cathode 420, and emitted from the cathode 420. In the acceleration grid 440 and the acceleration grid 440 for supplying a constant voltage so that the electrons reach the fluorescent surface 492 behind the glass panel 490 and attracting electrons with charges to accelerate in the axial direction. The medium acceleration grid 450 which accelerates the firstly accelerated electrons by supplying a constant voltage and secondly accelerates the electrons that are emitted from the cathode 420 and move toward the fluorescent surface 492 of the glass panel 490. To spread by the repulsive force in the axial direction The glass panel is accelerated by supplying a constant voltage to the focused grid 460 and the cathode 420 emitted from the cathode 420 and accelerated twice through the acceleration grid 440 and the medium acceleration grid 450. An anode for supplying a high acceleration grid 470 colliding with the fluorescent surface 492 of 490 and a high voltage of a predetermined voltage or more to the aluminum film of the fluorescent surface 492 of the glass panel 490 and discharging a high voltage when the power is "off". The terminal 480 is provided.

In this case, a shadow mask, which is a porous metal plate attached to a position about 10 mm away from the fluorescent surface 492, is required in order to accurately match the beam emitted from the electron gun with the set fluorescent position.

Referring to FIGS. 2 and 3 attached to a conventional shadow mask for performing the above function, in the case of the color CRT, the electron gun includes three electron guns of red (R), green (G), and blue (B). Depending on the array of electron guns, it is divided into delta type and inline type.

Therefore, FIG. 2 is an exemplary diagram for explaining a relationship between a shadow mask and a fluorescent surface in a CRT equipped with a delta electron gun, which is commonly used in computer monitors. It is not well applied to color televisions because the dot pitch of the fluorescent screen pixels is small and the screen is relatively bright.

Therefore, as shown in FIG. 3 to which another conventional technique proposed to solve the problems of the technique shown in FIG. 2 is attached, the phosphor coated on the fluorescent surface has a line shape instead of a dot shape. In other words, the shadow mask is a mark form type.

As described above, the mark form-type shadow mask shown in FIG. 3 is changed to a lattice structure of an electron beam transmission hole that is formed in a dot shape in the shadow mask of FIG. 2. Further, accordingly, the arrangement of the electron gun was also changed into an inline form, and the average size of the electron beam transmission holes perforated in the shadow mask was 0.5 to 0.7 mm in width and 0.7 to 0.8 mm in length.

In this case, in the case of using the mark form-type shadow mask as shown in FIG. 3, the electron beam is at an angle due to the deflection of the electron beam at the periphery of the screen compared to the incident area of the electron beam colliding with the fluorescent surface near the center of the screen. Because of the bending, the incidence area is widened. Therefore, if the size of the electron beam transmission hole at the periphery is maintained at the same size as the vicinity of the center, the problem of emitting adjacent phosphors together occurs, thereby making the size of the electron beam transmission hole at the periphery smaller.

However, in the conventional spherical CRT illustrated in FIG. 1, the glass panel 490 has a round, that is, curvature, resulting in screen distortion in which the linear shape of the scan line changes according to the viewing position.

That is, the change in the linear shape means that the straight line of the image is curved in accordance with the viewing position. Especially, when viewing from the side (45 °) off the front of the CRT, the screen is not straight due to the curvature of the glass panel 490. As a result, the screen is distorted. In this case, when the viewpoint is placed at the center of the screen, the screen distortion is minimized. When the viewpoint is placed at the outside of the screen, the screen distortion is maximized, so that it is difficult to watch a natural and clear image.

In addition, the existing spherical CRT has a wide range in which the viewer sees the reflection hole by the curvature of the glass panel 490 when external light, ie, fluorescent light or light from a glass window is projected on the screen. In this case, the reflected light not only tired the viewer's eyes but also hinders viewing.

Looking at the structural change in the curvature of the glass panel 490 of the existing spherical CRT, the structure of the glass panel, which was 1.0R in the 1960s and 1970s, was 2.0R in the 1980s, and 3.0R in the 1990s. At that time, the glass panel of the CRT is gradually increasing in R.

Accordingly, the present invention has been made in view of the above problems, and by flattening the glass panel to minimize the reflection of the ambient light and the distortion of the screen according to the round of the glass panel to improve the image quality and improve the visibility The purpose is to provide a planar CRT structure.

1 is an exemplary configuration diagram of a conventional spherical CRT.

2 is an exemplary diagram for explaining a relationship between a shadow mask and a fluorescent surface in a CRT having a delta electron gun;

3 is an exemplary view for explaining a relationship between a mark form-type shadow mask and a fluorescent surface in a CRT having an inline electron gun;

4 is an exemplary view showing a planar CRT structure according to an embodiment of the present invention.

FIG. 5 is an exemplary diagram of a cross hatch image comparing an image difference between an existing spherical glass panel and a flat glass panel according to an exemplary embodiment of the present invention.

5A is an exemplary view of a cross hatch image according to an existing spherical glass panel

5B is an exemplary view of a hatch image of a flat glass panel according to an embodiment of the present invention.

Figure 6 is an exemplary view comparing the shape change of the moving object in the existing spherical glass panel and the flat glass panel according to an embodiment of the present invention

6a is an exemplary view showing a shape change of a moving object according to the existing spherical glass panel

6B is an exemplary view showing a shape change of an object moving in the flat glass panel according to the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: CRT 190: glass panel

192: light surface 195: shadow mask

The present invention for achieving the above object is a CRT having a glass panel in which a shadow mask is installed at a predetermined interval between the cathode for emitting electrons and a fluorescent surface is coated on the inner surface, the glass panel is 84 or more rounds It is to provide a planar CRT consisting of a planarization having.

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

4 shows a CRT 100 of a flattened glass panel according to an embodiment of the present invention. The basic structure of the CRT 100 is substantially the same as that of a conventional spherical CRT structure, and the details of the difference according to the glass panel are shown. It has an characteristic feature.

That is, a heater 110 for raising the temperature of the cathode 120 is installed behind the cathode 120 by generating heat by receiving the amplified R, G, and B signals, and at this time, the cathode 120 is negative. It is made to emit electrons when a negative voltage is supplied.

In addition, a control grid 130 that modulates luminance by controlling the amount of emitted electrons is installed in the cathode 120, and electrons emitted from the cathode 120 reach the fluorescent surface 192 on the rear surface of the glass panel 190. An acceleration grid 140 is provided in front of the cathode 120 by supplying a constant voltage so as to attract electrons having charges and to accelerate them in the axial direction.

In front of the acceleration grid 140, the medium acceleration grid 150 accelerates the electrons accelerated primarily by the acceleration grid 140 to a second level by supplying a predetermined voltage, and the cathode 120 is discharged from the glass. Focusing grid 160 for generating an electron beam that axially concentrates the electrons moving toward the fluorescent surface 192 of the panel 190 by the repulsive force between the electrons, and is emitted from the cathode 120 to the acceleration grid 140. A high acceleration grid 170 is provided to supply a constant voltage to the electrons accelerated twice through the medium acceleration grid 150 to accelerate the third step and collide with the fluorescent surface 192 of the glass panel 190.

On the other hand, the funnel coupled to the glass panel 190 is provided with an anode terminal 180 for supplying a high voltage of a predetermined voltage or more to the aluminum film of the fluorescent surface 192 of the glass panel 190 and discharge the high voltage when the power is "off", A shadow mask 192 made of a porous metal plate is attached at a position spaced apart from the fluorescent surface 192. In this case, the shadow mask 192 allows the beam emitted from the electron gun to exactly match the set fluorescent position.

Here, the glass panel 190 is not formed as a spherical surface, but is formed as a flattening, and when the flat glass panel 190 is compared with the glass panel of the existing CRT, it appears as shown in Table 1 below.

Spherical glass panel of existing CRT CRT flat glass panel of the present invention 60 ~ 70's 80's Early nineties R 1.0 2.0 3.0 84.0 flatness 8.0% 3.9% 2.6% 0.1% or less Outer radius 800 mm 1,600 mm 2,400 mm 100,000 mm Height of outer surface 40.0 mm 1,600 mm 2,400 mm 0.5 mm

That is, the glass panel 190 is formed of 84R to maintain the flatness of 0.1% or less, the outer radius is 100,000 mm, the height of the outer surface (the height difference between the center and both ends) is almost 0.5 mm It becomes a flat state.

Comparing the CRT structure and the existing spherical CRT according to an embodiment of the present invention configured as described above are as follows.

First, comparing the image difference between the existing spherical glass panel 490 shown in Figure 1 and the flat glass panel 190 according to the present invention shown in Figure 4,

Since the spherical glass panel 490 of the conventional CRT has no curvature, when the image is viewed, the linear shape of the scanning line changes along the curved surface depending on the position. As a result, when a cross hatch recalls at 45 ° from the front, as shown in FIG. 5A, about 7% of distortion occurs, the shape of the rectangle changes according to the position on the screen.

The spherical glass panel 490 according to the present invention does not change its linear shape depending on the position of the viewpoint unlike the surface image. That is, as shown in Fig. 5B, in the planar image, the linearity of the image is maintained as it is.

Next, when comparing the shape change of the object moving in the spherical glass panel 490 and the flat glass panel 190,

In general, when a viewer fixes a viewpoint to a natural landscape or a moving object, the linear movement is increased, and it is more natural to feel that the linear shape is preserved in human memory.

In other words, it is equivalent to moving a linear object in nature on a completely flat screen, and this also gives the viewer a natural sense of movement by keeping the quadrilateral shape in the same shape as possible.

For example, as shown in FIGS. 6A and 6B, assume an image in which a square screen of size A moves from the lower left to the upper right, and assume that the angle of the viewpoint is at right angle 45 ° and distance 3H. In the case shown in Table 2 below.

Structure of the glass panel Q ₁ Q ₂ ΔQ = Q ₂ -Q ₁ Traditional spherical screen 82 ° 98 ° 16 ° Flat screen of the present invention 88 ° 96 ° 8 °

As shown in Table 1, the values of the right angles Q ₁ and Q ₂ of the quadrilateral on each screen are the change of the right angle due to the quadrilateral movement on the spherical screen. The larger the angle change amount ΔQ is, the larger the position angle of the viewpoint is, and the larger the distance between the viewpoint and the screen is, the larger the angle is.

Accordingly, the screen of the flat glass panel 190 according to the present invention is more natural than the existing spherical screen to the person who is watching the moving image, and also in the large screen.

In addition, the flat glass panel 190 has a narrower reflection range of external light than the existing spherical glass panel 490. That is, as a result of computer simulation, the reflection area decreases as R increases, and the area of 1R screen reflects about 6 times the area of the flat screen.

As described above, the present invention can flatten the glass panel to minimize the reflection of the ambient light and the distortion of the screen due to the round of the glass panel, thereby improving the image quality due to the distortion compared to the CRT of the existing spherical glass panel. And improve the visibility.

Therefore, the present invention is able to view a natural and clear image, as well as to minimize the fatigue and disturbance of the viewer's eyes due to the diffuse reflection of external light.

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 (1)

In the CRT (100) having a glass panel 190 is provided with a shadow mask 192 and a fluorescent surface applied to the inner surface with a predetermined interval between the cathode 120 for emitting electrons, the glass panel 190 is Planar CRT, characterized in that the planarization having more than 84 rounds.