KR20020057651A - Stem for cathode ray tube - Google Patents

Abstract

PURPOSE: A stem for a cathode ray tube is provided to improve the characteristic of voltage withstand by changing the structure of lead pins to which dynamic and static voltage are applied. CONSTITUTION: A stem unit(30) comprises a stem body(31), an exhaust pipe(32) formed on the center portion of the stem body(31), pin holes(33) of a ring shape formed on the stem body(31), lead pins(34) inserted into an inner surface of the respective pin holes(33), and protuberance units(35) formed on an edge of the respective pin holes(33). The lead pins(34) include a static lead pin(36) and a dynamic lead pins(37). The interval between the static lead pin(36) and the dynamic lead pins(37) is wider than that of the lead pins(34).

Description

Stem for cathode ray tube

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

Typically, the electron gun is mounted on the neck portion of the bulb, and includes at least one focus electrode disposed opposite to the cathode, the control electrode, the screen electrode, and the screen electrode to form a preliminary focusing lens part. It includes a final acceleration electrode which is installed to face the electrode to form the main focusing lens portion, and the stem portion for supplying voltage to the cathode and the electrodes.

Referring to FIG. 1, the stem part 10 of the related art is formed in the center of the stem body part 11 and the stem body part 11 which is sealed to the neck part 100, and has a passage for vacuuming the inside of the bulb. An exhaust pipe 12 to be provided, a plurality of pinholes 13 formed at predetermined intervals on the stem body portion 11, lead pins 14 inserted into the pinholes 13, and the lead pins 14. In order to prevent the deformation of the) includes a protrusion 15 formed along the edge of the pinhole (13).

The lead pin 14 has an inner pin 14a facing the neck portion 100, an outer pin 14b facing the outside of the stem body 11 in the opposite direction, and the inner pin 14a and the inner pin 14a. The connecting pin 14c molded in the stem body part 11 is formed in a strip shape so as to interconnect the external pins 14b.

The lead pin 14 is disposed in an annular shape on the stem body portion 11. For example, when the diameter of the neck part 100 is 29.1 millimeters, the space | interval between the adjacent lead pins 14 maintains 3.4 millimeters. In addition, the lead pin 14 is selectively inserted among a plurality of pin holes 13 formed at equal intervals.

At this time, since the lead pin 14 has a strip shape, the distance D ₁ between the inner pins 14a positioned inside the neck portion 100 and the outer pins 14b located outside the stem body portion 11 are provided. The spacing D ₂ between) is the same.

By the way, the conventional stem 10 has the following problems.

As the light deflection angle of the electron beam increases due to the planarization and enlargement of the cathode ray tube, the dynamic voltage applied to the electrode of the electron gun is relatively increased compared to the static voltage. Therefore, among the lead pins, the lead pins to which the dynamic voltage is applied and the lead pins to which the static voltage is applied can withstand only 5 km or less when the gap is maintained due to the voltage difference. At higher voltages, insulation breakdown occurs, resulting in leakage of current or even short-circuit, which makes it impossible to ensure the reliability of the cathode ray tube.

The present invention is to solve the above problems, to improve the structure of the lead pin to which the dynamic voltage and the static voltage is applied in the lead pin disposed in the stem portion to provide a cathode tube for improving the withstand voltage characteristics have.

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

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

3 is a plan view showing a stem according to a first embodiment of the present invention;

Figure 4 is a plan view showing a stem portion according to a second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 ... Stem part 11,21 ... Stem body part

12, 22 Exhaust pipe 13, 23 Pin hole

14,24 ... Lead pin 15,25 ... protrusion

26,36,46 ... Static Lead Pins 26a, 27a ... Inner Pins

26b, 27b ... external pin 26c, 27c ... connection pin

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

200 ... electron gun

In order to achieve the above object, the stem for a cathode ray tube according to an aspect of the present invention,

Selected in the stem body portion sealed to the neck end of the bulb, the exhaust pipe is formed in the center of the stem body portion to provide a passage when evacuating the inside of the bulb, and the pinhole formed at a constant interval on the stem body portion In the cathode ray tube stem having a plurality of lead pins inserted into the cathode and applying a voltage to the electron gun consisting of a plurality of electrodes,

Among the lead pins, 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 the static lead pin is applied, have an internal pin located inside the neck portion and an outer side of the stem body portion opposite thereto. Characterized in that the gap with the outer pin is formed differently.

In addition, the static lead pin and the dynamic lead pin is characterized in that the connection pins which are bent inward to be connected to each other while varying their spacing between the inner pin and the outer pin is integrally formed.

In addition, the interval between the static lead pin and the inner pin of the dynamic lead pin is characterized in that it is formed wider than the gap between the outer pin.

Further, the inner pin is formed while maintaining a wider gap than the outer pin, the outer pin is characterized in that it is formed while maintaining the same interval as other lead pins.

Further, the outer pin is formed while maintaining the same interval on the same annular shape as the other lead pin, the inner pin is located in the outer portion of the other lead pin arranged in an annular shape to be formed to expand a relatively wide interval It features.

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

Figure 2 shows the neck portion 100 is sealed stem portion 20 according to an embodiment of the present invention.

Referring to the drawings, an electron gun 200 is mounted in the neck portion 100. The electron gun 200 includes at least one of a cathode 210, a control electrode 220, a triode consisting of the screen electrode 230, and a screen electrode 230, which is disposed to face the screen electrode 230. The focus electrodes 240 to 260 and the final focus electrode 260 are disposed to face each other, and include a final acceleration electrode (not shown) to form a main focusing lens unit.

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

The stem portion 20 is provided with a stem body portion 21 sealed at the end 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. The body portion 21 has a through hole (22a) is formed in the center portion, the exhaust pipe 22 for providing a passage for discharging the air or foreign matter inside the bulb during vacuum exhaust is formed integrally from the body portion 21 have. In the exhaust pipe 22, the stem body 21 is sealed at the end of the neck portion 100 during the assembling process of the cathode ray tube, and then melted to make the inside of the bulb into a vacuum state.

The stem body portion 21 is annularly spaced at a predetermined interval, and a plurality of pin holes 23 penetrating the stem body portion 21 are formed. A lead pin 24 for inserting a predetermined voltage to the electron gun 200 is inserted into the inner circumferential surface of the pinhole 23. At this time, the lead pin 24 is selectively inserted into the pinhole 23 as many as the voltage is applied to the electron gun 200 among the plurality of pinholes 23 formed in the stem body portion 21.

Among the lead pins 24, the so-called static lead pins 26 and dynamic lead pins 27, which supply power to the electrodes of the electron gun 200 to which the static voltage and the dynamic voltage are applied, have an electron beam according to the enlargement and planarization of the cathode ray tube. The voltage deflection is applied to increase the voltage difference. According to a feature of the present invention, the static lead pin 26 and the dynamic lead pin 27 may have different lead pins because the dielectric breakdown phenomenon may occur because the conventional lead pin interval does not withstand the increased withstand voltage. It is made wider than 24).

That is, the static lead pin 26 and the dynamic lead pin 27 are arranged so that the distance between the inner pin and the outer pin located in the opposite direction are different from each other.

In more detail as follows.

The static and dynamic lead pins 26 and 27 have inner pins 26a and 27a respectively extending into the neck portion 100. The outer circumferential surface of the pinhole 23 is formed in the stem body portion 21 in which the inner pins 26a and 27a are located to prevent deformation of the inner pins 26a and 27a and to expand the surface area of the stem body portion 21. The projection 25 protrudes from the predetermined height.

In the direction opposite to the inner pins 26a and 27a, the outer pins 26b and 27b extend outwardly from the lower surface of the body body 21. At this time, the interval D ₃ between the static lead pin 26 and the inner pins 26a and 27a of the dynamic lead pin 27 is wider than the interval D ₄ between the outer pins 26b and 27b.

To this end, the inner pins 26a and 27a and the outer pins 26b and 27b are connected to both ends of the stem body 21 to be embedded in the connecting pins 26c, which are integrally connected to each other at different intervals. ) 27c is formed.

The connecting pins 26c and 27c are molded in the stem body portion 21, and the static lead pins 26 and the dynamic lead pins 27 are bent at a predetermined angle in an inward direction corresponding to each other. . Accordingly, it can be said that the spacing D ₃ of the inner pins 26a and 27a can be formed to be wider than the spacing D ₄ of the outer pins 26b and 27b.

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

Referring to the drawings, the stem portion 30 includes a stem body portion 31, an exhaust pipe 32 formed at the center thereof, and a pinhole 33 formed at a predetermined interval in the stem body portion 31; And a lead pin 34 inserted into an inner circumferential surface of the pinhole 33, and a protrusion 35 protruding along an edge of the pinhole 33, wherein the lead pin 34 is an electrode of a dynamic focus electron gun. It includes a static lead pin 36 and a dynamic lead pin 37 applied to.

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 while maintaining an equal interval of approximately 3.4 millimeters. Here, the static lead pins 36 And the space between the dynamic lead pins 37 is wider than the space 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 thereto is different from the inside of the neck portion 100. It is formed not to maintain the spacing D ₃ of the lead pins, for example 3.4 millimeters, but at least 5.0 millimeters. This can be said to be a proper interval to prevent breakdown when the static voltage between the static lead pin 36 and the dynamic lead pin 37 to which a relatively high voltage is applied increases.

On the other hand, the outer 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 inner side of the neck portion 100 and the dynamic lead pin 37 The spacing D ₅ of the outer pin 37b is maintained at the same 3.4 millimeter as the spacing D ₃ of the other lead pins 34. As described in FIG. 2, the connecting pins interconnecting the internal pins and the external pins are bent inward to the opposite side of the static lead pins 36 and the dynamic lead pins 37, thereby varying their spacing. In addition, in order to prevent the leakage of current when the withstand voltage rises due to the same distance between the outer pins 36b and 37b, the outer surface of the outer pins 36a and 37b may have an insulator, for example, silicon. Is coated.

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

Referring to the drawings, the stem portion 40 may include a stem body portion 41, an exhaust pipe 42, a plurality of pinholes 43, and a lead selectively inserted according to a voltage applied to the pinhole 43. And a pin 44 and a protrusion 45 formed at an edge of the pin hole 43.

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

In more detail as follows.

The stem body portion 44 is arranged with a lead pin 44 while maintaining the same interval in an annular shape. The lead pin 44 maintains an interval of approximately 3.4 millimeters when the neck portion 100 (see Fig. 2) has a diameter of 29.1 millimeters. In this case, the static lead pin 46 and the dynamic lead pin 47 are not disposed on the same annular shape as the other lead pins 44, but are disposed outwardly.

For this reason, the static lead pin 46 and the dynamic lead pin 47 is advantageous to secure space in the stem body portion 44. The spacing D ₆ between the internal pin 46a of the static lead pin 46 and the internal pin 47a of the dynamic lead pin 47 is at least 5 millimeters wider than D ₁ , the spacing between the other lead pins 44. Is keeping.

On the other hand, the distance D ₇ between the outer pin 46b of the static lead pin 46 and the outer pin 47b of the dynamic lead pin 47 extending to the outside of the stem body portion 41 is different from the other lead pin ( 44) is equal to D ₁ , the spacing between them, and is located on the same annular shape. This is possible because the connecting pins interconnecting the inner pins and the outer pins are bent inward as in the first embodiment.

As such, the distance between the internal lead of the static lead and the dynamic lead pin having a relatively large voltage difference is wider than that of other lead pins. Although it was able to withstand only the withstand voltage of Volt Kv or less, in this embodiment, it can be said that the breakdown of the dielectric breakdown can be prevented even with a breakdown voltage of approximately 10 kilovolts (Kv).

As described above, the stem for a cathode ray tube of the present invention has a gap between an internal pin and an external pin of a static lead pin and a dynamic lead pin connected to an electrode to which a static voltage and a dynamic voltage are applied among the electrodes of the electron gun. By bending the connecting pins to be connected inwardly, it is possible to extend the distance between two lead pins rather than the gap of the lead pins to which different voltages are applied.

As a result, as in the case of the electron focusing gun of the dynamic focus type, it is able to withstand the increased withstand voltage due to the relative voltage difference between the static voltage and the dynamic voltage, thereby preventing insulation breakdown. The reliability of cathode ray tube can be ensured even when

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (5)

Selected in the stem body portion sealed to the neck end of the bulb, the exhaust pipe is formed in the center of the stem body portion to provide a passage when evacuating the inside of the bulb, and the pinhole formed at a constant interval on the stem body portion In the cathode ray tube stem having a plurality of lead pins inserted into the cathode and applying a voltage to the electron gun consisting of a plurality of electrodes, Among the lead pins, 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 the static lead pin is applied, have an internal pin located inside the neck portion and an outer side of the stem body portion opposite thereto. Cathode ray tube stem, characterized in that the gap between the outer pin is formed differently. The method of claim 1, The static lead pin and the dynamic lead pin is a stem for cathode ray tube, characterized in that the connecting pin is formed integrally bent inwardly to connect to each other while varying their spacing between the inner pin and the outer pin. The method of claim 2, The stem between the static lead pin and the inner pin of the dynamic lead pin is wider than the gap between the outer pin is formed for the cathode ray tube stem. The method of claim 3, The inner pin is formed while maintaining a wider gap than the outer pin, the outer pin is a stem for a cathode ray tube, characterized in that formed while maintaining the same interval as other lead pins. The method of claim 3, The outer pin is formed while maintaining the same spacing on the same annular shape as the other lead pin, the inner pin is located in the outer portion of the other lead pin arranged in an annular shape, characterized in that the relatively wider gap is formed Cathode ray tube stem.