KR880002987Y1 - A electron-gun for a c.r.t - Google Patents

Abstract

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Description

Cathode structure of electron gun for cathode ray tube

1 is a longitudinal cross-sectional view showing a conventional cathode structure.

2 is a longitudinal cross-sectional view showing a cathode structure of the present invention.

3 is a comparative graph showing a cathode radiation current of a conventional cathode structure and a cathode structure of the present invention, 3 (a) is a cathode radiation current of the conventional cathode structure 3 (b) is a cathode of the anode structure of the present invention Radiation current.

* Explanation of symbols for main parts of the drawings

12: sleeve 13: sleeve holder

13 ': bend 15: cap

16 insulator 17 cathode support

The present invention relates to a cathode ray tube structure that is installed behind the cathode ray and inside the cathode ray tube electron gun that emits an electron beam on a fluorescent screen in front, so that the screen appears as soon as possible at an initial time when power is applied.

In general, the fast-moving cathode structure is made of a nichrome alloy, and the surface is oxidized in a wet hydrogen furnace to increase the thermal radiation efficiency, and to rapidly increase the temperature, and also to provide a heater embedded in the sleeve. By thinning and widening the surface area, blackening the surface to increase the thermal radiation efficiency, and increasing the thermal conductivity to the sleeve, the screen is about 5 to 6 seconds faster than the general cathode structure at the initial time when the power is applied. In this case, the conventional fast-moving cathode structure has a defect in which an abnormal phenomenon occurs in thermal equilibrium so that a transient phenomenon of the cathode radiation current occurs severely at an initial time when power is applied.

That is, in the conventional fast-acting cathode structure, as shown in FIG. 1, the lower part of the sleeve 2 in which the heater 1 is built is fixed to the sleeve holder 3, and the front end of the sleeve 2 is fixed. In the upper surface, a cap 5 coated with an oxide 4, which is a hot electron radioactive material, is provided, while the outer portion of the sleeve holder 3 is bent downward, and the bent portion 3 'is insulated from each other. 6) was fixed to the lower portion of the negative electrode support (7) fixed.

In the conventional fast-moving cathode structure as described above, when power is applied to the heater 1, the sleeve 2 is heated by the heat generated by the heater 1 at an initial time when the power is applied, and the oxide expands upward. Since the distance between the electron beam through hole 8 'formed in the first grid 8 on the upper portion of the oxide 4 becomes narrower, the power supply to the heater 1 as shown in the curve shown in FIG. At this initial time, the electron emission current at the cathode rapidly increased, that is, a transient phenomenon occurred, and thus the brightness of the screen was not constant.

Therefore, in the Utility Model Registration Application No. 85-10431, which was filed by the applicant, the middle part of the sleeve was fixed to the sleeve holder to suppress the expansion of the sleeve to the upper part at the initial time when the heater was applied. While the eve is suppressed from expanding upward, the transient is hardly generated, while the periphery of the electron beam through hole of the first grid is rapidly heated and bent upwards, so that the gap between the oxide and the electron beam passing space is farther away and the heat of the heater is increased. Since it is not efficiently conducted, the periphery of the first and second grids return to the original state, which requires a long time until the cathode radiation current flows to the normal state, and the screen appears late, and there is a defect that the screen stabilizes.

In view of such conventional defects, the present invention not only prevents the sleeve from expanding upward at the initial time when the power is applied to the heater, but also causes the inner side of the first grid to heat up rapidly so that no transient phenomenon occurs. As soon as the screen appears and stable, it will be described in detail with reference to Figure 2 as follows.

As shown in FIG. 2, after the cap 15 coated with the oxide 14 is installed at the front end of the heater 11 and the sleeve 12 embedded therein, the sleeve holder 13 and the cathode supporter ( 17. In the negative electrode structure fixed to the insulator 16 by 17), the negative electrode support 17 is fixed to the insulator 16 so that one end thereof is positioned above the insulator 16, and the middle portion of the sleeve 12 is fixed. The outer portion of the sleeve holder 13 fixed to the bent upwards to fix the bent portion 13 'to the upper portion of the negative electrode support (17).

When the cathode structure of the present invention configured as described above is applied with power to the heater 11, the heat generated by the heater 11 is absorbed by the sleeve 12 is suddenly expanded, but at this time, Since the middle part is fixed to the sleeve holder 13, the sleeve 12 expands to the lower side and expands to the lower side, so that the electron beam passage hole 18 'of the oxide 14 and the first grid 18 is expanded. There is little influence on the spacing between them, and accordingly the transient phenomenon of the cathode radiation current is prevented as in the curve shown in FIG. 3 (b).

In addition, the periphery of the electron beam through hole 18 'is rapidly heated to bend upward by the heat generated by the cap 15 being heated, but at this time, the outer side of the sleeve holder 13 is bent upward, so that the cathode supporter Since the sleeve 12 is fixed to the upper portion of 17, the heat generated from the upper portion rises to the upper portion to heat the first grid 18, so that the first grid 18 is quickly removed. Since the periphery of the uniformly heated and upwardly curved electron beam through hole 18 'is returned to its original state, the cathode radiation current flows to normal within a short time, and the screen appears quickly, and the screen is stabilized within a short time.

As described above, the present invention does not generate a transient phenomenon of the cathode radiation current at the initial time when the power is applied, so that the brightness of the screen is constant, and the screen is not overloaded to the cathode, and the screen appears faster as well as stabilized. It is effective.

Claims (1)

In the negative electrode structure in which the sleeve 12 having the cap 15 provided at the distal end thereof is fixed to the insulator 16 by the sleeve holder 13 and the negative electrode support 17, the negative electrode support 17 has one end thereof. The outer portion of the sleeve holder 13 fixed to the insulator 16 so as to be located above the insulator 16 and fixed to the middle portion of the sleeve 12 is bent upward, and the bent portion 13 ' The cathode structure of the electron gun for cathode ray tube, characterized in that the structure is fixed to the upper portion of the cathode support (17).