KR100223840B1 - Electron gun for cathode ray tube - Google Patents

Abstract

The present invention relates to a bead supporter for supporting an eyelet constituting a cathode to bead glass. An electron beam radiated from each cathode during the initial operation of the CRT by equalizing the thermal expansion coefficient of the three eyelets to which the cathode is fixed. This is to minimize the variation of the quantity.

To this end, a plurality of cathodes (1) for emitting an electron beam (2), eyelets 20 surrounding each of the cathodes independently, bead supporter (18) is fixed to the outer peripheral surface of the eyelet and to support the eyelets; In the electron gun for a color cathode ray tube composed of the bead glass 19, the bead supporter and a plurality of electrodes buried, the bead supporter 18 fixed to the outer peripheral surface of the eyelet 20 is fixed to each eyelet in the same direction Or, the bead supporter 18 fixed to the outer circumferential surface of the eyelet 20 is wrapped around the entire outer circumferential surface of each eyelet.

Description

Electron gun for color cathode ray tube

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun for color cathode ray tubes, and more particularly, to a bead supporter for supporting eyelets constituting a cathode to bead glass.

1 is a cross-sectional view of a typical color cathode ray tube, in which each electrode of the electron gun for a color cathode ray tube allows the electron beam 2 emitted from the three cathodes 1 to be controlled in a constant intensity to reach the fluorescent surface 3. In order to be perpendicular to the path through which the electron beam (2) is passed, they are arranged in-line at regular intervals from each other.

The configuration thereof will be described in more detail with reference to FIG. 1, wherein the three independent cathodes 1 and the first electrode 4 arranged to maintain a predetermined distance from the cathode control the hot electrons generated from the cathode. And a second electrode 5 arranged to maintain a predetermined distance from the first electrode to accelerate and draw hot electrons collected on the surface of the electron emission material (not shown) of the cathode, and a third electrode. (6), the fourth electrode (7), the fifth electrode (8), and the sixth electrode (9) are disposed in this order, and on one side of the sixth electrode (the traveling direction side of the electron beam) on the inner surface of the funnel 10; A shield cup 13 having a plurality of shield springs 12 fixed to the coated graphite film 11 and serving to be supported at the center of the neck portion 10a by the electron gun is disposed. .

Different voltages are applied to the cathode 1 in order to obtain a constant current value such that the cut-off voltage of each electron gun is the same.

Therefore, when power is applied from the stem pin 15 to the heater 14 in the cathode 1 constituting the triode of the electron gun, when the heater generates heat, the hot electrons are emitted from the electron emission material applied to the tip of the cathode.

The hot electrons emitted as described above are controlled by the first electrode 4 as the control electrode and accelerated by the second electrode 5 as the acceleration electrode to pass through the third and fourth electrodes 6 and 7 and then continue. The fifth and sixth electrodes 8 and 9, which are the main lens forming electrodes, are sequentially passed through.

The electron beam accelerated and focused while passing through each electrode is installed to be maintained at a predetermined distance from the fluorescent surface 3, passes through a shadow mask 16 that serves as color screening, and then collides with the fluorescent surface 3 to emit phosphors. Is reproduced.

In the above operation, the deflection yoke 17 provided on the outer peripheral surface of the neck portion 10a of the funnel 10 deflects the electron beam 2 emitted from the electron gun to the entire fluorescent surface.

As described above, the cathode 1 emitting the electron beam 2 is fixed to the bead glass 19 by the bead supporter 18 as shown in FIG. 2.

That is, the cathode 1 is inserted into the eyelet 20 to be welded and installed to maintain a predetermined distance from the first electrode 4, wherein the eyelet 20 is welded to the bead supporter 18 to bead glass. Buried in 19.

Therefore, when power is applied to the heater 14 inserted into the cathode 1 and the temperature of the heater rises to about 800 ° C., the heat generated from the heater 14 is transferred to the cathode 1 by the radiation phenomenon. Hot electrons are emitted from the electron-emitting material 21.

As such, when heat generated by the heat of the heater 14 is transferred to the cathode 1, a part of the transferred heat is transferred to the eyelet 20 and the first electrode 4 by conduction and radiation, and the eyelets and the first The heat transferred to the first electrode is transferred to the bead supporter 18 and the second electrode 5 side again.

When heat is transferred to each part due to conduction and radiation phenomena due to heat generation of the heater 14, as time passes, the cathode 1, the eyelet 20, the bead supporter 18, the first electrode 4, and the first electrode are formed. Each of the second electrode 5, the third electrode 6, and the like rises to a constant temperature. The temperature of each part is shown in the graph of FIG. 4.

As the temperature of each component rises as described above, the components expand thermally.

Thermal expansion of the negative electrode 1 radiating hot electrons according to the heat generated by the heater 14 occurs instantaneously as shown in FIG. 4 due to the proximity of the heater, and the thermal expansion direction of the negative electrode 20 is the lower portion of the eyelet 20. Is fixed to the first electrode 4 side.

On the other hand, the eyelet 20 to which the cathode 1 is fixed is gradually expanded compared to the cathode 1, and the expansion direction is welded and fixed to the bead supporter 18 so that the opposite direction of the first electrode 4 is fixed. Headed.

Therefore, the amount of expansion of the cathode 1 and the eyelet 20, which may affect the radiation amount of the electron beam 2, is (l), which is the distance between the points where they are fixed by welding.

In addition, the first electrode 4 expands toward the second electrode 5 and the second electrode 5 expands toward the first electrode 4 due to the conduction and radiation phenomena caused by the heat generation of the heater 14. The shapes of the electrodes in the expansion direction of the first and second electrodes 4 and 5 are greatly affected.

As shown in FIG. 4, the expansion of each component is maintained thermally stable after about 15 minutes of applying power to the heater 14.

3 is a state diagram in which a cathode is supported on a bead glass by a bead supporter in a conventional electron gun, and the R side bead supporter 18a is fixed to be wrapped on the outer circumferential side of the R side eyelet 20a positioned at an upper portion in the drawing. The portion where the R side bead supporter is not wrapped is directed toward the G side eyelet 20b.

The G side bead supporter 18b is fixed to the outer peripheral surface side of the G side eyelet 20b symmetrically with the R side bead supporter 18a, and the B side bead supporter 18c is the G side to the outer peripheral surface of the B side eyelet 20b. It is fixed in the same direction as the bead supporter 18b.

Therefore, when the power is applied to each of the heaters 14 installed in the cathodes 1 and generates heat, the portions of the R and G side eyelets 20a and 20b facing each other are the R and G side bead supporters 18a and 18b. The temperature of the R and G side eyelets 20a and 20b is relatively higher than that of the B side eyelet 20c.

Accordingly, the temperature difference of each eyelet 20a, 20b, 20c is accompanied by a difference in the amount of expansion.

That is, (L), which is a welding point of the R, G side eyelets 20a and 20b having a high temperature, expands more than the B side eyelet 20c, but the expansion direction is opposite to the first electrode 4.

Each eyelet 20 is welded and fixed to the cathode 1 so that when the eyelet 20 expands in the opposite direction to the first electrode 4, the cathode is moved away from the first electrode. Far away from the electric field of 5), the amount of electron beam emitted from the electron-emitting material of each cathode is changed.

Accordingly, since the R and G side eyelets 20a and 20b are expanded farther from the first electrode 4 than the B side eyelet 20c, the electric field applied to the negative electrode 1 on the R and G side is also weakened. This reduces the amount of electron beams generated at the cathodes 1 on the R and G sides.

If the cathode 1 and the eyelet 20 are thermally expanded, in order to equalize the amount of the electron beam 2 emitted from each cathode, the voltage applied to the second electrode 5 is kept the same and the cathode 1 Adjust the voltage applied to).

That is, in order to match the amount of electron beams emitted from the cathodes 1 on the R and G sides with the amount of electron beams emitted from the cathodes on the B side, the electric fields of the R and G sides must be strengthened, so that the cathodes of the R and G sides are strong. The potential must be lowered.

Therefore, if the cathode potential on the R and G side is lowered, the potential difference with the second electrode 5 increases, so that a strong electric field is formed and the amount of the electron beam is increased, so the amount of the electron beam emitted from the cathode on the R, G and B side is the same. You lose.

However, the electron gun of this structure has a different temperature of the three eyelets 20 to which the cathode 1 is fixed during the initial operation of applying power to the heater 14 for a predetermined time (about 15 minutes) as shown in FIG. 5. Since the three electron beams generated at the cathode showed a difference, and then stabilized to a certain amount in a certain electric field, there was a problem that a specific color was emitted first during the initial operation of the CRT.

The present invention has been made to solve such a problem in the prior art, by equalizing the thermal expansion coefficient of the three eyelets to which the cathode is fixed to minimize the variation of the amount of electron beam emitted from each cathode during the initial operation of the CRT. Its purpose is to.

According to an aspect of the present invention for achieving the above object, a plurality of cathodes for emitting an electron beam, eyelets surrounding each of the cathodes independently, a bead supporter fixed to the outer peripheral surface of the eyelet to support the eyelets, In the electron cathode gun tube consisting of a bead supporter and a bead glass in which a plurality of electrodes are buried, there is provided an electron gun for the color cathode ray tube in which a bead supporter fixed to the outer circumferential surface of the eyelet is directed in the same direction to each eyelet.

According to another aspect of the present invention, a plurality of cathodes for emitting an electron beam, eyelets surrounding each cathode independently, a bead supporter fixed to an outer circumferential surface of the eyelet to support the eyelets, the bead supporter and a plurality of In an electron gun for a color cathode ray tube composed of bead glass, in which an electrode is buried, a bead supporter fixed to an outer circumferential surface of an eyelet is provided to surround an entire outer circumferential surface of each eyelet.

1 is a cross-sectional view showing a typical color cathode ray tube

2 is a longitudinal sectional view showing a part of an electron gun;

3 is a state in which the negative electrode is supported on the bead glass by the bead supporter in the conventional electron gun

Figure 4 is a graph showing the temperature change of each part when operating in the conventional electron gun

5 is a graph showing a change in cathode current in a conventional electron gun

6A and 6B are state diagrams showing a first embodiment of the present invention.

Figure 7 is a state diagram showing a second embodiment of the present invention

Explanation of symbols for main parts of the drawings

1: cathode 18,18a, 18b, 18c: bead supporter

19: Beadgrass 20, 20a, 20b, 20c: Eyelet

Hereinafter, the present invention will be described in more detail with reference to FIGS. 6A to 7.

6A and 6B are state diagrams showing a first embodiment of the present invention. As shown in FIG. 6A, the R-side eyelets 20a are fixed to each other so that a portion is wrapped in the R-side bead supporter 18a. The R side eyelet portion not wrapped in the R side bead supporter 18a faces the opposite direction of the G side eyelet 20b.

The G side eyelet 20b is fixed to each other so as to be partially wrapped in the G side bead supporter 18b, and the G side eyelet part not wrapped in the G side bead supporter 18b faces the R side eyelet 20a. .

In addition, the B side eyelet 20c is fixed to each other so as to be partially wrapped in the B side bead supporter 18c, and the B side eyelet portion not wrapped in the B side bead supporter 18c faces the G side eyelet 20b. have.

That is, three bead supporters 18 fixed to be wrapped around the outer circumferential surface of each eyelet 20 face the same direction.

FIG. 6B illustrates a state in which the bead supporter 18 is fixed to the outer circumferential surface of the eyelet 20 in the opposite direction to FIG. 6A.

On the other hand, Figure 7 is a state diagram showing a second embodiment of the present invention, the bead supporter 18 fixed to the eyelet 20 is to cover the entire outer peripheral surface of the eyelet.

Referring to the operation of the present invention configured as described above is as follows.

First, when power is applied to the heaters 14 installed inside the cathodes 1 through the stem pins 15, when the heaters generate heat, the generated heat is transferred to the cathode by radiation and at the same time, the heat transferred to the cathode is The conduction phenomenon is transferred to the surroundings of the eyelet 20 and the first electrode 4 again, and the heat transferred to the eyelet 20 is transferred to the surroundings by the radiation phenomenon.

As described above, when power is applied to each heater 14 and heat generated from the heater is transferred to the surroundings, the R side bead supporter 18a fixed to the outer circumferential surface of the R side eyelet 20a is the G side bead supporter 18b. Since a part of the radiant heat generated from the G-side eyelet 20b not wrapped by) is blocked, a phenomenon in which the temperature of the R-side eyelet 20a is increased by the radiant heat of the G-side eyelet 20b is prevented.

On the other hand, the G side eyelet 20b receives radiant heat from the B side eyelet 20c, but the G side bead supporter 18b is fixed to the outer peripheral surface of the G side eyelet 20b so as to face the B side eyelet 20c. It prevents radiant heat generated from the side eyelet 20c, and the heat transfer by the R side bead supporter 18a is less because the amount of heat transfer is small because the temperature of the G side eyelet 20b is higher than that of the R side bead supporter 18a. The phenomenon that the temperature of the side eyelet 20b rises is suppressed.

That is, since the temperature variation of each eyelet 20 according to the heat of the heater 14 is reduced, the amount of expansion of the eyelet becomes almost the same.

As described above, since the amount of expansion of the eyelets 20 fixed to the cathodes 1 emitting the R, G, and B electron beams is equal, the same amount of electron beams can be obtained in the same electric field.

On the other hand, even if the power is re-applied to the heater 14 after the power is cut off from the electron gun in which the same amount of electron beams are radiated from each cathode 1 by the operation as described above, the amount of initial electron beam generation depends on the strength of the electric field and expansion of the cathode. As a result, the difference in the amount of electron beams emitted from the respective cathodes does not occur.

Also in the second embodiment of the present invention shown in FIG. 7, since the amount of expansion of each eyelet 20 can be kept the same when power is applied to the heater 14 in the cathode 1 to generate heat, the operation as described above. Will be.

As described above, the present invention improves the orientation and structure of the bead supporter so as not to be affected by the temperature of the adjacent eyelets when each eyelet is inflated by the heating of the heater, so that the eyelets of a specific part are expanded more than other eyelets. Since the same amount of electron beams are radiated from the respective cathodes during the initial operation of the electron gun to which the power is applied to the heater, a phenomenon in which a specific color is emitted first during the initial operation of the cathode ray tube is prevented.

Claims (2)

A plurality of cathodes emitting an electron beam, an eyelet that surrounds each of the cathodes independently, a bead supporter fixed to an outer circumferential surface of the eyelet to support the eyelet, and the bead supporter and a plurality of electrodes with bead glass An electron gun for color cathode ray tubes, wherein the bead supporter fixed to the outer peripheral surface of the eyelet is fixed to each eyelet in the same direction. A plurality of cathodes emitting an electron beam, an eyelet that surrounds each of the cathodes independently, a bead supporter fixed to an outer circumferential surface of the eyelet to support the eyelet, and the bead supporter and a plurality of electrodes with bead glass An electron gun for a color cathode ray tube, comprising: a bead supporter fixed to an outer circumferential surface of an eyelet wrapped around the entire outer circumferential surface of each eyelet.

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