DE4314366A1 - Cathode ray tube - specifies ratio between deflection angle of electron beam and distance between gun exit and border between deflection region and region of linear travel to prevent beam collision with sides of funnel - Google Patents

Abstract

The CRT has a screen (100) with a fluorescent layer (101) on its inner surface. A funnel (200) connected to the screen (100) contains a deflection yoke (203) mounted near the neck (201) of the funnel (200) and an electron gun (202) connected inside the funnel (203). The parts satisfy the equation eta /RL = 1 to 1.3. eta is a deflection angle of an electron beam emitted from the electron gun (202) and the reference line. The ref. line is the boundary between the deflection region where the beam is deflected and the linear region in which the beam moves linearly. ADVANTAGE - Prevents electron beam colliding with inner surface of funnel for beams aimed at edge of screen.

Description

The invention relates to a cathode ray tube and in particular a cathode ray tube that the wrong hit of the by emitted by an electron gun and one for the corner areas fluorescent layer prevents certain electron beam, which after a collision with the inner surface of the funnel occurs.

In general, a cathode ray tube, as shown in FIG. 1, has a screen 10 , on the inner surface of which a fluorescent layer 11 is formed, and a funnel 20 , which is connected to the screen 10 , and an electron gun mounted in a neck section 21 22 and includes a deflection yoke 23 installed around the cone portion near the neck portion 21 . Is in the cathode ray tube according to Fig. 1 a of the outlet or exit G of the last Accelerati the electron gun supply electrode 22 emitted electron beam by the deflection yoke 23 according to the scanning position on the fluorescent layer 11 deflected on the fluoresce the layer impinge 11 and thus to form a pixel; many such pixels are combined to form an image. Since the screen is very narrow and elongated in the horizontal direction, however, the deflection angle is increased so that the electron beam emitted by the electron gun 22 collides with the inner surface of the funnel 20 and cannot hit the corner areas of the fluorescent layer 11 precisely. The collision of the electron beam 22 emitted by the electron gun 22 and intended for the corner areas of the fluorescent layer 11 with the inner surface of the funnel 20 results from the shape of the funnel 20 , the installation conditions of the deflection yoke 23 , the positioning of the electron gun 22 and the deflection yokes, etc. To solve the above problem, if the cone portion is formed near the neck of the funnel 20 so that it is large enough for the electron beam to avoid the collision described above, the CRT must be enlarged accordingly, which is each part requires a different design. In particular, such an enlarged cathode ray tube significantly extends the throughput time required to establish an adequate vacuum inside it.

The invention has for its object a cathode ray tube re to create, which prevents that of an electron kano ne emitted electron beam with the inner surface of a cone section of a funnel collides and subsequently opens incorrectly hits when it hits the corner areas of a fluorescent Layer is determined.

This object is achieved by the features in the patent claim solved.

The invention provides a cathode ray tube with a screen, which is formed with a fluorescent layer therein, and with a funnel connected to the screen; the Katho  The beam tube is with an electron attached inside cannon and one near the neck portion of the same mounted deflection yoke equipped which the following glide satisfied:

where R is a deflection angle of one from the electron gun tated electron beam, G denotes the outlet of the last one Accelerating electrode of those mounted in the neck section Denotes the electron gun, and R denotes the reference line, which is the boundary between the deflection area in which the of the electron gun emitted electron beam through the deflection yoke is deflected and bent, and the linear range is in which the electron beam moves linearly (for β values between 1 and 1.3).

The following is a preferred embodiment of the invention based on the drawing, in which the same reference numerals in generally refer to the same parts, to explain further Features and advantages of the invention described. Show it:

Fig. 1 is a side cross-sectional view of a conventional cathode ray tube, and

Fig. 2 is a side cross-sectional view of a cathode ray tube according to the invention.

In one embodiment of FIG. 2, a cathode ray tube generally has a screen 100 , on the inner surface of which a fluoroscent layer 101 is formed, and it has a funnel 200 which is connected to the screen 100 and with one in a neck portion 201 mounted electron gun 202 and a deflection yoke 203 installed around the cone portion near the neck portion, which deflects the electron beam emitted from the electron gun 202 according to the scanning position on the fluorescent layer 101 . As the size of the cathode ray tube is enlarged and the screen is lengthened in the horizontal direction, the deflection angle of the electron beam 202 emitted from the outlet of the last accelerating electrode of the electron gun 202 becomes large in the cathode ray tube according to the above construction. At this time, the electron beam emitted from the electron gun 202 collides with the inner surface of the cone portion of the funnel 200 and cannot strike the corner portions of the fluorescent layer 101 precisely, so that the image of the corner portions is out of focus. The inventor examined the reasons of the above problems (ie, why the electron beam emitted from the electron gun cannot strike the corner portions of the fluorescent layer precisely) and found the following factors contributing to such a phenomenon: 1. The installation conditions for the deflection yoke and the size of the deflection angle; 2. the eccentric distance between the centers of the electron beam openings of the three electron guns, which emit the electron beams for red, blue and green; and 3. the distance between the outlet of the last accelerating electrode and a reference line R, which is the boundary between the deflection area (in which the electron beam emitted by the electron gun is deflected and curved by the deflection yoke) and the linear area (in which the electron beam is located is moved linearly.

In order to avoid a collision of the electron emitted by the electron gun electron beam with the inner surface of the cone section and incorrect impact on the corner sections of the fluorescent Accordingly, the inventor formulated to prevent shift in relation based on the above reasons and led the equation below Attempts to obtain the results shown in Tables 1 and 2 extract nisse:

(FL / RL) × (R / S) = α.

FL is the distance from the edge of the funnel  to the reference line R, RL the distance between the outlet of the last accelerating electrode and the reference line R, R den Deflection angle of the electron emitted by the electron gun rays and S the eccentric distance between the center th of the electron beam through openings of the electron canon ne forming electrodes.

Table 1

Table 2

According to Tables 1 and 2, this phenomenon in which the electron beam emitted from the electron gun 202 collides with the inner neck portion is closely related to the distance RL between the outlet of the last accelerating electrode of the electron gun 202 and the reference line R, which is the boundary between the Deflection area and the linear area of the electron beam, whereas there is a weaker correlation with an eccentric distance S and a distance FL between the reference line R and the edge of the screen 101 be.

Accordingly, the applicant formulated with reference to the above Tables the equation below and performed experiments to extract the results shown in Table 3:

R / RL = β,

where R denotes the deflection angle of an electron beam, and RL is the distance between the outlet of the last acceleration supply electrode and the reference line R.

Table 3

If, according to Table 3, the value of β (which is the equation above fulfilled) is between 1 and 1.3, the one of the elec The tron cannon did not emit the electron beam with the inside area of the funnel and the picture is in the corner areas of the  fluorescent layer sharply formed. This will be without one The internal volume of the funnel is increased.

Accordingly, in the cathode ray tube according to the invention, the Hopper can be optimally constructed without losing its internal volume enlarge because the deflection angle of that of the electron gun emitted electron beam can be enlarged if the Screen is extended in the horizontal direction, which will result can that the electron emitted by the electron gun beam collides with the inner surface of the funnel and thus not exactly on the corner areas of the fluorescent layer hits.

The invention relates to a cathode ray tube, which contains a screen ( 100 ), on the inner surface of which a fluorescent layer ( 101 ) is formed, and a funnel ( 200 ) which is connected to the screen and an electron gun ( 202 ) or contains a deflection yoke ( 203 ) mounted in the vicinity of the neck portion ( 201 ) of the same, which fulfills the following equation:

R / RL = 1 to 1.3,

here R denotes a deflection angle of one of the electrons gun emitted electron beam and RL the distance between the outlet of the electron gun mounted in the neck section and the reference line, which is the boundary between the deflection area, in which the electron beam emitted by the electron gun is deflected by the deflection yoke and the linear region, in where the electron beam is moving linearly. The cathodes Beam tube can prevent that from the electron gun emitted electron beam with the inner surface of the funnel collides and in the corner areas of the fluorescent layer occurs incorrectly.

Claims (1)

Cathode ray tube with a screen ( 100 ), on the inner surface of which a fluorescent layer ( 101 ) is formed, and
a funnel ( 200 ) which is connected to the screen ( 100 ) and has an electron gun ( 202 ) arranged inside and a deflection yoke ( 203 ) arranged near the neck section ( 201 ),
characterized,
that the following equation is satisfied: R / RL = 1 to 1.3, where R denotes a deflection angle of an electron beam emitted from the electron gun ( 202 ), and RL the distance between the outlet of the electron gun ( 202 ) mounted in the neck portion ( 201 ) ) and the reference line R, which is the boundary between the deflection range in which the electron beam emitted from the electron gun ( 202 ) is deflected and bent by the deflection yoke ( 203 ) and the linear range in which the electron beam is linear emotional.