KR100730104B1 - Stem for cathode ray tube - Google Patents

Abstract

A stem for a cathode ray tube is disclosed. The present invention relates to a stator having a stem body sealed in a neck portion of a bulb, and a lead pin selectively inserted into a pinhole formed at a predetermined interval in the stem body to apply a voltage to the electron gun, The gap between the static lead pin and the dynamic lead pin to which the high voltage is applied is formed such that the interval between the portion located inside the neck portion and the portion located outside the stem body portion on the opposite side of the neck portion are different from each other.

Description

Stem for cathode ray tube

1 is a cross-sectional view schematically showing a neck portion provided with a conventional stem portion,

2 is a schematic cross-sectional view illustrating a neck portion provided with a stem portion according to an embodiment of the present invention,

FIG. 3 is a plan view showing a stem according to the first embodiment of the present invention, FIG.

FIG. 4 is a plan view of a stem according to a second embodiment of the present invention; FIG.

Description of the Related Art

10 ... stem part 11,21 ... stem body part

12, 22 ... exhaust pipe 13, 23 ... pinhole

14, 24 ... lead pins 15, 25 ... protrusions

26, 36, 46 ... static lead pins 26a, 27a ... inner pins

26b, 27b ... external pins 26c, 27c ... connecting pin

27, 37, 47 ... Dynamic lead pin 100 ... Neck part

200 ... electron gun

The present invention relates to a stem, and more particularly, to a stem for a cathode ray tube in which the structure of a lead pin to which a static voltage and a dynamic voltage are applied is improved.

The electron gun typically includes a cathode, a control electrode, a triode portion composed of a screen electrode, at least one focus electrode provided opposite to the screen electrode to form a preliminary focusing lens portion, A final accelerating electrode provided opposite to the electrode to form a main focusing lens unit, and a stem unit for supplying voltage to the cathode and the electrodes.

Referring to FIG. 1, a conventional stem 10 includes a stem body 11 sealed to a neck portion 100, a passage formed in the center of the stem body 11 for evacuating the inside of the bulb A plurality of pinholes 13 formed at a predetermined distance from the stem body 11; a lead pin 14 inserted into the pinhole 13; and a plurality of lead pins 14 And a protrusion 15 formed along the edge of the pinhole 13 to prevent deformation of the pinhole 13.

The lead pin 14 includes an inner pin 14a directed toward the inside of the neck portion 100 and an outer pin 14b directed toward the outside of the stem body portion 11 opposite to the inner pin 14a, And a connecting pin 14c molded in the stem body 11 to interconnect the external pins 14b.

The lead pin (14) is annularly arranged in the stem body (11). For example, when the diameter of the neck portion 100 is 29.1 millimeters, the gap between the adjacent lead pins 14 is 3.4 millimeters. In addition, the lead pins 14 are selectively inserted into a plurality of pinholes 13 formed at regular intervals.

Since the lead pin 14 has a strip shape, the gap D ₁ between the internal pins 14a located inside the neck portion 100 and the external pin 14b located outside the stem body portion 11 interval D ₂ between a) is the same.

However, the conventional stem portion 10 has the following problems.

The dynamic voltage applied to the electrode of the electron gun increases relative to the static voltage as the optical deflection angle of the electron beam increases with the flattening and enlargement of the cathode ray tube. Therefore, the lead pin to which the dynamic voltage is applied and the lead pin to which the static voltage is applied among the lead pins can withstand only the withstand voltage of 5 km or less when the gap is maintained due to the voltage difference. Insulation breakdown occurs at a voltage higher than that, and current leakage or short-circuit phenomenon occurs, so that the reliability of the cathode ray tube can not be ensured.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stem for a cathode ray tube in which the structure of a lead pin to which a dynamic voltage and a static voltage are applied is improved to improve the withstand voltage characteristic among the lead pins disposed in the stem portion. have.

According to an aspect of the present invention, there is provided a stem for a cathode ray tube,                     

An exhaust pipe formed at the center of the stem body to provide a passage for evacuating the inside of the bulb, and an exhaust pipe provided at a predetermined interval in the stem body And a plurality of lead pins for applying a voltage to the electron gun including a cathode and a plurality of electrodes,

A static lead pin to which a static voltage is applied among the lead pins and a dynamic lead pin to which a dynamic voltage having a relatively higher voltage than that of the static lead pin is applied is connected to the inner pin located inside the neck portion, And spaced apart from the external pin.

The static lead pin and the dynamic lead pin are integrally formed with the inner pin and the outer pin so as to be inwardly bent to connect the inner pin and the outer pin at different intervals.

In addition, the gap between the static lead pin and the dynamic lead pin is formed to be wider than the gap between the external lead pin and the dynamic lead pin.

Further, the inner pins are formed with a wider spacing than the outer pins, and the outer pins are formed with the same spacing as the other lead pins.

Further, the outer pin is formed in the same annular shape as the other lead pins while being equally spaced, and the inner pin is formed at an outer portion of another annularly arranged lead pin, .                     

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 illustrates a neck portion 100 in which a stem portion 20 according to an embodiment of the present invention is sealed.

Referring to FIG. 1, an electron gun 200 is mounted in the neck portion 100. The electron gun 200 includes a cathode 210, a control electrode 220, a triode portion including a screen electrode 230, and at least one cathode electrode 230 facing the screen electrode 230 to form a pre- (Not shown) in which the focus electrodes 240 to 260 and the final focus electrode 260 are opposed to each other to form a main focusing lens unit.

A stem portion 20 for applying a predetermined voltage to the cathode 210 and a plurality of electrodes 220 to 260 is provided at an end of the neck portion 100.

The stem portion 20 is provided with a stem body 21 which is sealed at an end portion of the neck portion 100. The stem body portion 21 has a circular shape and has a diameter corresponding to the diameter of the neck portion 100. A through hole 22a is formed at the center of the body portion 21 and an exhaust pipe 22 for providing a passage for discharging air or foreign substances in the bulb is integrally formed from the body portion 21 have. The exhaust pipe 22 is sealed by the stem body 21 at the end of the neck portion 100 in the process of assembling the cathode ray tube, and then melted to make the inside of the bulb into a vacuum state.

A plurality of pinholes (23) are formed in the stem body part (21) so as to be annularly spaced apart from each other by a predetermined distance and penetrate through the stem body part (21). A lead pin 24 for applying a predetermined voltage to the electron gun 200 is inserted into the inner circumferential surface of the pinhole 23. The lead pin 24 is inserted into the pinhole 23 as many times as the voltage is applied to the electron gun 200 among the plurality of pinholes 23 formed in the stem body 21.

Called static lead pins 26 and dynamic lead pins 27 that supply power to the electrodes of the electron gun 200 to which the static voltage and the dynamic voltage are applied among the lead pins 24, The voltage difference is increased by the optical deflection angle of the light source. The static lead pin 26 and the dynamic lead pin 27 may be spaced apart from each other by a distance between the lead pin and the other lead pin 27. In this case, 24).

That is, the static lead pin 26 and the dynamic lead pin 27 are disposed such that the gap between the inner pins and the gap between the outer pins located in the opposite direction are different from each other.

The details are as follows.

The static and dynamic lead pins 26 and 27 each have inner pins 26a and 27a extended to the inside of the neck portion 100, respectively. The stem body portion 21 on which the inner pins 26a and 27a are located is formed with a plurality of protrusions 26a and 27b on the outer circumferential surface of the pinhole 23 in order to prevent deformation of the inner pins 26a and 27a and to enlarge the surface area of the stem body 21, The protruding portion 25 protrudes at a predetermined height.

Outer pins 26b and 27b extend outward from the lower surface of the stem body 21 in a direction opposite to the inner pins 26a and 27a. At this time, the gap D ₃ between the static lead pins 26 and the internal pins 26a and 27a of the dynamic lead pins 27 is formed wider than the gap D ₄ between the external pins 26b and 27b.

To this end, connection pins 26c (26a, 27b) for connecting the internal pins 26a, 27a and the external pins 26b, 27b are integrally formed at both ends of the stem body 21, ) 27c are formed.

The connecting pins 26c and 27c are molded inside the stem main body 21 and are bent at an angle inclined inward corresponding to the static lead pins 26 and the dynamic lead pins 27 . Accordingly, it can be said that the interval D ₃ between the inner pins 26a and 27a can be formed to be wider than the interval D ₄ between the outer pins 26b and 27b.

3 shows a stem 30 according to a first embodiment of the present invention.

Referring to FIG. 1, the stem 30 includes a stem body 31, an exhaust pipe 32 formed at the center thereof, a pinhole 33 formed at a predetermined interval in the stem body 31, A lead pin 34 inserted into the inner circumferential surface of the pin hole 33 and a protrusion 35 protruding along the edge of the pin hole 33. The lead pin 34 is connected to the electrode of the dynamic focus electron gun A static lead pin 36 and a dynamic lead pin 37. The dynamic lead pin 37 is formed of a metal plate.

At this time, when the diameter of the neck portion 100 (see FIG. 2) is 29.1 millimeters, the lead pins 34 are arranged in an annular shape maintaining an equal distance of about 3.4 millimeters. The gap between the static lead pin 36 and the dynamic lead pin 37 is wider than the gap between the other lead pins 34. [

That is, the interval D ₄ between the internal pin 36a of the static lead pin 36 and the internal pin 37a of the dynamic lead pin 37 provided adjacent to the static lead pin 36 is different from that not the distance D of the lead pin _3, for example 3.4 mm, and is formed to maintain a distance of at least 5.0 mm. This can be said to be a proper interval at which the dielectric breakdown can be prevented when the withstand voltage between the static lead pin 36 and the dynamic lead pin 37 to which the high voltage is applied is increased.

The external pin 36b of the static lead pin 36 extending in the outward direction of the stem body portion 31 in the direction opposite to the inside of the neck portion 100 and the external pin 36b of the dynamic lead pin 37 The interval D ₅ of the external pins 37b is maintained at 3.4 mm, which is equal to the interval D ₃ of the other lead pins 34. 2, the connection pins for interconnecting the inner pins and the outer pins are bent inwardly toward the mating sides of the static lead pins 36 and the dynamic lead pins 37, so that the intervals are different. In order to prevent the leakage of the current when the withstand voltage rises due to the same spacing of the external fins 36b and 37b as the other fins 34, the external fins 36a and 37b are coated with an insulating material such as silicone Is coated.

4 shows a stem portion 40 according to a second embodiment of the present invention.

Referring to FIG. 1, the stem unit 40 includes a stem body 41, an exhaust pipe 42, a plurality of pinholes 43, And a protrusion 45 formed at an edge of the pinhole 43. The protrusion 45 is formed at the edge of the pinhole 43,

The static lead pin 46 and the dynamic lead pin 47 to which the static voltage is applied are formed wider than the gap between the other lead pins 44 among the lead pins 44.

The details are as follows.

The stem body portion 44 is provided with a lead pin 44 while maintaining an annular space. The lead pin 44 maintains an interval of approximately 3.4 millimeters when the diameter of the neck portion 100 (see FIG. 2) is 29.1 millimeters. At this time, the static lead pin 46 and the dynamic lead pin 47 are not disposed in the same annular shape as the other lead pins 44, but are disposed outside the same.

Therefore, it is advantageous that the static lead pin 46 and the dynamic lead pin 47 secure a space in the stem body 44. Inner pins (46a) and a dynamic internal pin (47a), spacing D ₆ is wider at least at least 5 mm steps than the D ₁ distance between the other lead pin (44) between the lead pin 47 of the static lead pin 46 .

On the other hand, an interval D ₇ between the external pin 46b of the static lead pin 46 and the external pin 47b of the dynamic lead pin 47 extending to the outside of the stem body portion 41 is different from that of the other lead pin the same as the distance between D ₁ 44), and located in the same ring shape. This is possible because the connecting pin for interconnecting the inner pin and the outer pin is inwardly bent as in the first embodiment.

As described above, the gap between the internal lead of the dynamic lead pin and the static lead pin relatively large in voltage difference is wider than that of the other lead pin, and the external pin is coated with insulating material on the outer peripheral surface thereof. It is possible to withstand only the withstand voltage of the bolt (Kv), but in the case of this embodiment, it is possible to prevent the insulation breakdown even under withstand voltage of about 10 kilovolts (Kv).

As described above, the stem for a cathode ray tube of the present invention has a structure in which the distance between the inner lead of the static lead pin connected to the electrode to which the static voltage and the dynamic voltage are applied and the inner lead of the lead pin, By bending the connecting pin for connecting inward, the gap between the two lead pins can be wider than the gap of the lead pin to which the other voltage is applied.

As a result, the dielectric breakdown phenomenon can be prevented by increasing the relative voltage difference between the static voltage and the dynamic voltage, as in the case of the electronically focused electron gun, and as a result, the high and low voltage The reliability of the cathode ray tube can be ensured even when the cathode ray tube is applied.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (6)

A stem body sealed at an end of the neck portion of the bulb, An exhaust pipe formed at the center of the stem body to provide a passage for evacuating the inside of the bulb, And a plurality of lead pins which are selectively inserted into the pinholes formed at regular intervals in the stem body to apply voltage to the electron gun including the cathode and the plurality of electrodes, Wherein the lead pin includes a static lead pin to which a static voltage is applied and a dynamic lead pin to which a dynamic voltage having a relatively higher voltage than that of the static lead pin is applied, Wherein the static lead pin and the dynamic lead pin are integrally formed with an inner pin located on the inner side of the neck portion and an outer pin located on the outer side of the stem body portion opposite to the inner pin, Formed, Wherein the gap between the static lead pin and the dynamic lead pin is wider than the gap between the other lead pins and the interval between the static lead pin and the dynamic lead pin is equal to the gap between the other lead pins Wherein the stem of the cathode tube is formed of a synthetic resin. delete The method according to claim 1, Wherein the gap between the static lead pin and the inner lead of the dynamic lead pin is wider than the gap between the outer lead and the dynamic lead pin. delete A stem body sealed at an end of the neck portion of the bulb, An exhaust pipe formed at the center of the stem body to provide a passage for evacuating the inside of the bulb, And a plurality of lead pins which are selectively inserted into the pinholes formed at regular intervals in the stem body to apply voltage to the electron gun including the cathode and the plurality of electrodes, Wherein the lead pin includes a static lead pin to which a static voltage is applied and a dynamic lead pin to which a dynamic voltage having a relatively higher voltage than that of the static lead pin is applied, Wherein the static lead pin and the dynamic lead pin are integrally formed with an inner pin located on the inner side of the neck portion and an outer pin located on the outer side of the stem body portion opposite to the inner pin, Formed, Wherein the static lead pin and the dynamic lead pin are disposed at an outer portion of another annularly arranged lead pin so as to be wider than the other lead pins and the outer lead of the static lead pin and the dynamic lead pin is connected to another lead pin Wherein the stem is formed in the same annular shape as the stem of the cathode ray tube while maintaining equal spacing. 6. The method of claim 5, Wherein the gap between the static lead pin and the inner lead of the dynamic lead pin is wider than the gap between the outer lead and the dynamic lead pin.

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