KR930006847B1 - Electron gun - Google Patents

Abstract

The electron gun for a color braun tube consists of the heater (20) for heating a cathode sleeve (18) and a controlled electrode (19) by applying an electrical voltage. In order to reduce the gradient of luminance occurred by the space variation between a cathode assembly and a controlled electrode, the controlled is prepared by oxidation and blackation of the surface of the nichrome alloy containing 80 % nickel and 20 % chromium with wet hydrogen.

Description

Collar CRT Gun

1 is a schematic view showing a general electron gun.

2 is a detailed view of the three poles of a typical electron gun.

3 is a graph of thermal equilibrium arrival temperature and arrival time of a cathode sleeve and a control electrode of a triode of a general electron gun.

4 is a graph of the current beams flowing in the center and outer cathodes after heating a common electron gun.

5 is a detailed view of the three-pole portion of the electron gun in which the control electrode of the present invention is blackened.

6 is a graph of thermal equilibrium arrival temperature and arrival time of the cathode sleeve and the control electrode of the three-electron gun of the present invention.

7 is a graph showing the change in current beams flowing in the center and outer cathodes after heating the heater of the invention electron gun.

* Explanation of symbols for main parts of the drawings

1-3: cathode 4-6, 8-10: electron beam through hole

7, 19: control electrode 11: acceleration electrode

12 electrode support 13 bead glass

14, 20: heater 15, 18: cathode sleeve

16, 21: hot electron radiator 17, 22: cathode cap

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun of a color CRT, and more particularly to an electron gun of a color CRT which blackens the control electrode in order to reduce a change in luminance gradient caused by the space change between the cathode assemble and the control electrode.

The electron gun of a color CRT tube which is generally used has a predetermined distance from the cathodes 1, 2, 3 to three electron beams emitted from the cathodes 1, 2, 3, as shown in FIG. Is controlled by the control station 7 having three electron beam through holes 4, 5, and 6, facing each other, and maintaining a predetermined interval with the control electrode 7 and the electrode support 12. It is adhered to the glass 13 and accelerated to the acceleration electrode 11 having three electron beam through holes 8, 9, and 10, and focused on a main lens composed of a plurality of main electrodes, and then R, G, The image is displayed on the same plane by colliding with the phosphor B. FIG. 2 is a detailed view of the three pole portions of the electron gun, which will be described in detail with reference to the accompanying drawings.

When a predetermined voltage is applied to the electron gun, the cathode sleeve 15 is heated by the heating of the heater 14 while the control electrode 7 is heated, and the rows of the cathode sleeve 15 and the control electrode 7 are heated. As shown in FIG. 3, when the thermoelectron radiating material 17 coated on the cathode cap 18 reaches 800 deg. After about 10 seconds, the wood sleeve 15 reaches 850 ° C, which is a temperature of thermal equilibrium, and the control electrode 7 reaches 250 ° C, which is a temperature of about 10-15 minutes. In the above, the temperature attainment and the time at which the thermal equilibrium are different are higher than those of the cathode cap 18 because the temperature of the side portion is higher than that of the head of the heater 14. The temperature of the control electrode 7 is much lower than the temperature of the cathode sleeve 15 because the control electrode 7 is far from the heater 14, and this result can be measured directly using a thermocouple.

Thus, the cathode hot electron radiating material 16, which is a variable f in the relational expression of the total electron blocking voltage E _KCO , is caused by the difference between the time at which the cathode sleeve 15 and the control electrode 7 reach the thermal equilibrium state. ) The relationship between the cutoff voltage (E _KCO ) and the beam current (I _k ) where the change in the gap from the top surface to the pore portion of the control electrode occurs, and the change in the beam current (I _k ) occurs due to the change in the gap. It is the same as formula of (I) and table (II).

K ₁ , K ₂ : proportional constant

D: diameter of control electrode pore

t: thickness of the control electrode pore area

f: distance from top surface of cathode thermoelectron emitter to bottom of control electrode pore area

b: distance between control electrode and acceleration electrode

E _C2 : applied voltage of accelerating electrode

After the heater 14 is heated by the equation (I) of the beam current I _K as described above, and the thermal equilibrium is achieved after about 10-15 minutes, the central cathode 2 is the external cathode 1 (3), the extent to which the cathode sleeve 15 expands toward the hole of the control electrode 7 due to the difference in the ascending speed and the rising temperature during heating is large in the central cathode 2 This results in a graph as shown in Figure 4, which not only maintains white balance in the typical set up for operating color CRTs, but also brightens white until thermal equilibrium is reached. There was a problem that the gradually fading phenomenon appears.

The present invention was devised to shorten the thermal equilibrium arrival time between the cathode sleeve and the comb control electrode in view of the above, which will be described in detail with reference to the accompanying drawings.

5 is a detailed view of the three-pole part of the electron gun according to the present invention.

When a predetermined voltage is applied to the electron gun, the cathode sleeve 18 is heated by the heating of the heater 20 while the surface is oxidized and blackened in a wet hydrogen furnace using a nichrome alloy (Ni80% Cr20%). The electrode 19 is heated, and the temperature and time of arrival until the thermal equilibrium of the cathode sleeve 18 and the control electrode 19 are different, respectively, so that the thermoelectron radiating material 21 coated on the cathode cap 22 When () reaches 800 ° C., the temperature at which the thermoelectron radiation is constant, as shown in FIG. 6, the cathode 18 reaches 850 ° C., which is the temperature of the thermal equilibrium state after about 10 seconds, and the control electrode 19 After about 1 minute to reach the temperature of the thermal equilibrium 250 ℃, the cathode sleeve 18 expands in the direction of the arrow (A) and the control electrode 19 expands in the direction of the arrow (B), Short interval of pore bottom branch of control electrode 19 in cathode cap 22 Since almost match the central portion cathode 2 and the external cathode (1) and (3) the current beam (I _K), the difference may be reduced to a thermal equilibrium state is reached in a short time as shown in the seventh degree by .

As described above, according to the present invention, since the control electrode 19 is blackened and used, the current beam I _K is stabilized after 1 minute, which is about 15 times faster than the conventional heater 20, so that the luminance gradient change can be greatly reduced and the color CRT tube This reduces the white balance difference that occurs during setup.

Claims (2)

In an electron gun of a color CRT tube in which the cathode sleeve 18 and the control electrode 19 are heated by heating of the heater 20 when a predetermined voltage is applied to the electron gun, the surface of the nichrome alloy is oxidized by wet hydrogen. An electron gun of a color CRT tube, characterized by blackening to form the control electrode (19). The electron gun of a color CRT tube according to claim 1, wherein the nichrome alloy is made of 80% nickel and 20% chromium.

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