KR19990050098A - Hyperplane CRT - Google Patents

Abstract

The present invention relates to an ultra-planar CRT (cathode ray tube) to solve the problem of the conventional cathode ray length to make the ultra-flat CRT and to secure the disadvantages of the flat cathode. According to the present invention, a fluorescent screen is attached to an inner front surface of a glass tube, and a surface opposite to the first reflector is configured to deflect an electron beam generated from an electron gun by changing a current value and to first reflect the deflected beam. The second and third reflectors are used to repeatedly reflect the electron beam reflected from the first reflecting mirror to the second and third lights by using a signal shift phenomenon caused by the reflection phase difference. The reflective surfaces are arranged in a staggered manner between two inner matrices of the glass tube and the electron gun. The beams generated by the electron beam and deflected by the method of changing the current value are separated from the inside of the glass tube. Direct scanning of the electron gun onto the fluorescent surface by reflecting by reflectors arranged staggered in two matrices between It is an invention that enables the production of a more compact and ultra-planar CRT while maintaining high image quality because it allows the electron beam to reach a desired position on a desired fluorescent screen while preventing the problem.

Description

Super Plane Crt

The present invention relates to a super planar CRT (cathode ray tube), to solve the problem of the conventional cathode ray length CRT made of a super flat membrane and to compensate for the shortcomings with a flat cathode ultra-flat CRT (Super-thin cathode ray tube) It is about.

In the conventional CRT, red, blue, and green electron guns are placed on the rear side of the CRT to emit three fluorescent lights of red green blue in front of the shadow mask, and the electron beam emitted from the electron gun is deflected through the deflection coil, and the fluorescent material is painted. It is a structure that emits light by colliding with a fluorescent point.

In the prior art, the larger the screen size, the longer the scanning distance is required to reach the fluorescent surface coated with the fluorescent material from the electron gun, which is why the overall size of the CRT and especially the length of the CRT is increased, so that the volume of the display device using the CRT is increased. It has been a cause for increasing.

Accordingly, the present invention has been invented to solve such a conventional problem, and an object of the present invention is to provide a beam deflected by a method generated by an electron beam to change a current value between the inner front surface of the glass tube and the electron gun. Reflected by alternating reflectors arranged in a matrix, the CRT prevents direct scanning of the electron gun onto the fluorescent screen while allowing the electron beam to reach the desired position on the desired fluorescent screen, making the CRT more compact and ultra-planar while maintaining high image quality. To provide.

According to the technical idea of the present invention, a fluorescent screen is attached to the inner front surface of the glass tube, and the surface facing the glass tube is made to deflect the electron beam generated from the electron gun by the method of changing the current value and to first reflect the deflected beam. 1 By using the signal shift phenomenon caused by the reflector and the reflection phase difference, the reflector such as the second and third for repeatedly reflecting the electron beam reflected from the first reflector to the second or third order is incorporated. It is suggested that the reflectors are arranged so that the reflecting surfaces face each other in two matrices between the inner front face of the glass tube and the electron gun.

1 illustrates an embodiment of a conventional CRT.

2 is another embodiment of a conventional CRT.

3 is an overall configuration diagram of a CRT according to the present invention.

FIG. 4 is a diagram illustrating a process of electron beams inside a CRT in FIG. 2.

FIG. 5 is a diagram illustrating an arrangement of reflectors inside the CRT of FIG. 2.

6 is a diagram illustrating a detailed structural diagram of the reflector of FIG. 2.

<Explanation of symbols for main parts of the drawings>

100: electron gun 110: fluorescent screen

120: glass tube 130: deflection coil

140: second reflecting light 190: first reflecting light

200: first reflector 300: absorption surface

400: reflecting surface

Hereinafter, with reference to the accompanying drawings will be described a specific embodiment for achieving the above object of the present invention.

1 and 2 are examples of conventional CRTs. As shown in FIGS. 1 and 2, two forms are known. As shown in FIG. 1, the image is generated by the electron gun 100 generating the electron beam and the electron beam. Fluorescent screen 110 is installed and the electron gun 100 and the fluorescent screen 110 is fixed to the inside of the glass tube 120 is maintained in a high vacuum, the neck portion 140 of the glass tube 120 The deflection coil 130 for controlling the electron beam is coupled to the outside.

The cathode ray tube is scanned toward the fluorescent screen 110 as the hot electrons generated by the electron gun 100 are accelerated to a high voltage and are emitted in the form of an electron beam, and are deflected by the magnetic field of the deflection coil 130 and hit the fluorescent surface of the fluorescent screen 110. Light emission.

The cathode tube of FIG. 1 and FIG. 2 has the same function, but the cathode tube of FIG. 1 has the fluorescent screen 110 perpendicular to the axis of the electron beam, and the cathode tube of FIG. 2 has the fluorescent screen 110 of the electron beam axis. It is inclined about 20 ° and curved.

As described above, the cathode ray tube of FIG. 1 has a disadvantage in that the distance between the electron gun 100 and the fluorescent screen 110 is long, so that the cathode ray tube cannot be made thin when a TV receiver, a computer, a monitor, or the like is manufactured. Although the planar cathode ray tube as shown in FIG. 2 has been developed, the cathode ray tube has the advantage of thinning the instrument, whereas the size of the beam spot is increased because the electron beam is inclined at a constant inclination (θ) with respect to the fluorescent surface. It becomes an elliptical spot that is 1 / sinθ times larger than the vertical incidence type, and the size S of the beam spot is proportional to the length L from the focus lens to the fluorescent surface as follows.

The deformation of the beam spot due to the oblique incidence of the electron beam causes the deterioration of image quality, and the flat cathode ray tube is not vertical when viewed in the direction "A" as shown in FIG. The defect was difficult to enlarge.

Figure 3 shows the overall configuration of the CRT according to the present invention and will be described with reference to Figure 3 the present invention is attached to the fluorescent screen 110 on the inner front surface of the glass tube, the electron gun 100 on the opposite surface The electron beam reflected from the first reflector 200 by deflecting the electron beam generated from the first reflector 200 and the signal shift phenomenon due to the reflection phase difference. And reflectors such as a, a ', b, b' for repeatedly reflecting the light into the second, third, and the like. In particular, the reflectors have a first reflector between the inner front surface of the glass tube and the electron gun 100. The reflective surfaces are alternately arranged in two matrices of columns 190 and second reflective columns 180.

Hereinafter, an operation according to an embodiment of the present invention made as described above will be described in detail with reference to the drawings.

First, FIG. 4 is a view showing the progress of an electron beam inside a CRT according to the present invention. As shown in the drawing, the beam generated by the electron gun 100 is deflected by a method of changing a current value, and the reflective surface is first placed in front of the electron gun. Scanning is made to the first reflecting mirror 200 which is arranged to face each other. The beam reflected from the reflecting surface of the first reflector 200 is reflected and reflected by a, which is the reflector closest to the right of the first reflector 200 among the second reflecting columns 190 by the signal shift effect due to the reflection phase difference. The beam is reflected back to a 'closest to a and to the right of the second reflecting light 180 of the first reflecting light 190 and the beam is again reflected by the first reflecting light 180 of the second reflecting light 190. The beam reflected by a 'and b, which is the nearest reflector to the right side, is reflected in the form reflected by b of the second reflector 190 and b', which is the nearest reflector to the right side of the first reflecting mirror 190, and finally The fluorescent screen 110 of the inner front surface of the glass tube reaches. The beam emitted from the electron gun enters the first reflector at a predetermined angle according to the deflected angle, and the reflection angle of the light is determined according to the incident angle, thereby reaching the fluorescent screen at a desired position.

The structure in which the reflectors are arranged in the glass tube is shown in the drawing showing the arrangement of the reflectors in the CRT of the present invention of FIG. 5. Referring to this, the first reflecting column 190 and the second reflector are arranged between the fluorescent screen and the electron gun in the glass tube. The rows 180 are disposed, and the central axes of the reflectors of the first reflecting mirrors 190 and the central axes of the reflecting mirrors of the second reflecting mirrors 180 are arranged to be offset at a predetermined distance so as not to coincide with each other, such that the beam is emitted from the electron gun. It is configured to repeatedly reflect the reflection to the desired position of the fluorescent screen 110.

6 is a view showing a detailed structure of the reflector used in the present invention, the front 400 and the rear 300 of the reflector is made of a material having a different refractive index, the front portion of the reflector may be configured as a material such as a mirror.

As described above, the present invention solves the length problem of the conventional CRT and compensates for the shortcomings of the planar cathode ray tube. Reflected by two mirrors arranged in a staggered two matrixes between and prevents direct scanning of the electron gun onto the fluorescent screen while allowing the electron beam to reach the desired position on the desired fluorescent screen, further miniaturizing and providing ultra-high plane There is an effect of enabling the production of this possible CRT.

Claims (2)

Attach the fluorescent screen 110 to the inner front surface of the glass tube, On the surface opposite thereto, the electron beam generated from the electron gun 100 is deflected by changing a current value, In order to reflect the deflected beam, the electron beam reflected from the first reflector 200 is second-order by using a first reflection mirror 200 for firstly reflecting the electron beam generated by the electron gun and a signal shift phenomenon due to a reflection phase difference. The reflective surfaces of the first and second reflective arrays 190 and 180, which are repeatedly reflected by the third differential, are alternately spaced apart from each other by a predetermined distance from the central axes of the reflectors in the reflective array. Ultra Planar CRT (cathode ray tube), characterized in that the configuration by attaching a plurality of reflection arrays According to claim 1 or claim 2, wherein the second reflector and the material of the first and second reflecting mirrors having different reflectances are attached to each other, the reflecting portion is made of a material having a good reflectance and the opposite surface absorbs light Ultra Planar CRT (cathode ray tube), characterized in that consisting of