KR19990025071A - Color CRT Spring - Google Patents

Abstract

The present invention relates to a spring for a color CRT tube that compensates the thermal expansion of a shadow mask due to the collision of an electron beam during the operation of the CRT and a CRT tube by improving the structure of a spring positioned between the panel and the supporting frame. It is to improve the mis-landing phenomenon of the electron beam due to thermal expansion of the shadow mask during the operation.

To this end, one end of the spring is fixed to the inner wall of the support frame 6 to which the shadow mask 5 is fixed, and the other end is fitted to the stud pin 8 fixed to the inner wall of the panel 1 to support the support frame 6. In a color CRT tube supported by the panel 1, the springs 12 connect the first and second arm portions 12a and 12b formed parallel to the tube axis direction and the connecting portions 12c connecting the first and second arm portions. ) Is formed integrally and roughly “ Shape, the connecting portion 12c is inclined upwardly from the stud pin 8 toward the supporting frame 6, and the connecting portion is provided with strength maintaining means.

Description

Color CRT Spring

The present invention relates to a color CRT tube, and more particularly, to a color CRT tube spring that compensates thermal expansion of a shadow mask due to collision of an electron beam during operation of the CRT.

FIG. 1 is a cross-sectional view showing a general color CRT, which is composed of a rectangular panel 1 and a funnel 3 in which a neck portion 3a into which an electron gun 2 is sealed is integrally formed.

The panel 1 has a tube axis passing through the center thereof, and phosphors of three colors emitting blue, green, and red light are coated on the inner surface of the panel 1 to form a fluorescent surface 4, and in the vicinity of the fluorescent surface, there are a myriad of holes 5a. The shadow mask 5 is formed to serve as color screening of the electron beam. The shadow mask is welded and supported by the rectangular support frame 6.

The support frame 6 is fitted to the stud pin 8 fixed to the inner surface of the panel 1 by a plurality of springs 7 to maintain the suspended state on the panel 1.

The spring 7 is formed between the hole 5a formed in the shadow mask and the fluorescent surface 4 of the screen when the shadow mask 5 and the support frame 6 are heated and expanded due to the collision of the electron beam according to the operation of the CRT. It serves to prevent discoloration (color distortion) caused by relative displacement.

2 is an exploded side view of the spring shown in Japanese Patent Laid-Open No. 64-27,144, wherein the spring 7 is divided into a first arm portion 9 and a second arm portion 10.

The first arm portion 9 is a welded portion 9a welded to the second arm portion 10 and an inclined portion 9b which is formed to be connected from the welded portion and whose angle changes as the shadow mask 5 is thermally deformed. ) And a stud pin connecting portion 9c which is formed to extend in parallel with the tube axis direction from the inclined portion.

The second arm portion 10, which is fixed to the side wall of the support frame 6 by being welded to the first arm portion 9, has a flat plate shape.

The second arm portion 10 of the spring 7 having the above structure is welded and fixed to the side wall of the support frame 6 as shown in FIG. 3, and the stud pin connecting portion 9c of the first arm portion 9. The electron beam 11 is scanned from the electron gun 2 to the fluorescent surface 4 side when power is applied to the CRT in the state fitted to the stud pin 8.

Accordingly, a part of the electron beam passes through the hole 5a formed in the shadow mask 5 and hits the phosphor to emit light, but the screen is reproduced, but most electron beams hit the shadow mask 5 which serves as color screening. The shadow mask 5 is thermally expanded.

As described above, when the shadow mask 5 is thermally expanded and its position is changed, the spring 7, which is maintained at an angle θ by the inclined portion 9b shown in Fig. 2, has a hole in which the hole 5a of the shadow mask is fluorescent. (4) to face.

When the angle θ of the inclined portion 9b is small, the length of the inclined portion 9b should be longer, resulting in a decrease in the resistance of the structure to mechanical impact.

On the contrary, when the angle of the inclined portion 9b is increased, the landing compensation of the electron beam is excessive, resulting in color distortion.

That is, since the shadow mask 5 does not expand efficiently even when the internal temperature of the CRT increases, the hole 5a of the shadow mask 5 does not move to the right position, but moves to the fluorescent surface 4 side. The electron beam 11 passing through) is mislanded in the phosphor.

4 is an exploded side view of the spring shown in Japanese Patent Laid-Open No. 63-239,752, which is intended to solve the problem of the spring of FIG.

Looking at the configuration of the spring (7), the first arm portion (9) is formed in almost the same shape as in one embodiment, the second arm portion 10 is also formed almost similar to the first arm portion (9) The first arm portion 9 is positioned symmetrically, and the inclination angles θ ₁ and θ ₂ of the inclined portions 9b and 10b may be set differently.

The second arm part 10 is a welded part 10a welded to and fixed to the first arm part 9 and an inclined part which is formed to be connected from the welded part and whose angle changes as the shadow mask 5 is thermally deformed ( 10b) and a fixing portion 10c which is formed to be connected in parallel with the tube axis direction from the inclined portion and fixed to the side wall of the support frame 6.

The spring 7 of the above structure may be formed by one member such that the spring 7 is bent into a V shape so that one side is fitted to the stud pin 8 and the other side is fixed to the support frame 6.

The spring 7 of another embodiment having the above structure must be designed to satisfy the following equation.

tan θ ₁ / K ₁ 〈tan θ ₂ / K ₂ ------------------ (1)

Where K ₁ (kg _f / mm ² ) is the spring constant of the first arm part 9, K ₂ (kg _f / mm ² ) is the spring constant of the second arm part 10, and θ ₁ is The inclination angle of the first arm portion 9 and θ ₂ are the inclination angles of the second arm portion 10.

The spring 7 configured as described above is made of a material having a small coefficient of thermal expansion such as an invar alloy, and thus, when the thermal expansion of the panel 1 does not occur, it is possible to solve the problem of the spring 7 shown in one embodiment.

However, the spring 7 of another embodiment uses expensive invar alloys, which increases manufacturing costs, and also makes it difficult to apply the design due to difficult design.

When the spring 7 of another embodiment is manufactured by the above equation (1), the distance between the first arm portion 9 and the second arm portion 10 in operation is reduced, but accurate design is difficult.

On the other hand, the above formula (1) does not consider the length and width of the spring (7) because only the constant and the inclination angle of the spring is considered, it is difficult to apply to various types of springs according to the size of the CRT.

When the CRT is operated, similar landing errors of the electron beam are generated in the other embodiments, and thus color distortion occurs.

The spring 7 of one embodiment and the other embodiment is divided into first and second arm portions 9 and 10 and integrated with each other by welding, thereby increasing the difficulty in manufacturing the spring and increasing the unit cost.

In addition, the spring (7) for supporting the shadow mask support has a structure that is weak to vibration, when the impact is applied during the operation of the CRT, the shadow mask support is shaken, there is also a problem that causes a decrease in color purity.

The present invention has been made to solve such a problem in the prior art, by improving the structure of the spring located between the panel and the support frame to improve the mis-landing phenomenon of the electron beam due to thermal expansion of the shadow mask during operation of the CRT. The purpose is to make it.

According to an aspect of the present invention for achieving the above object, a collar for fixing one end of the spring to the inner wall of the support frame to which the shadow mask is fixed and the other end is inserted into a stud pin fixed to the inner wall of the funnel to support the support frame to the panel. In the CRT, the first and second arm portions in which the spring is formed parallel to the tube axis and the connecting portion connecting the first and second arm portions are integrally formed to form a substantially “ Shape, wherein the first arm portion is fixed to the stud pin of the panel, the second arm portion is welded to the frame, the connecting portion is inclined upwardly from the first arm portion to the second arm portion and the strength is maintained on the connecting portion. A spring for a color CRT tube is provided.

1 is a cross-sectional view showing a typical color CRT

Figure 2 is an exploded side view showing an embodiment of a conventional spring

Figure 3 is a partial longitudinal cross-sectional view of the CRT illustrating the state of use of Figure 2

Figure 4 is an exploded side view showing another embodiment of the conventional spring

Figure 5 is a partial longitudinal cross-sectional view of the CRT illustrating the use state of Figure 4

Figure 6 is a perspective view showing one embodiment of a spring that is the main part of the present invention

Figure 7 is a partial longitudinal cross-sectional view of the CRT illustrating the use of the present invention

Figure 8 is a longitudinal sectional view showing another embodiment of the spring which is the main part of the present invention.

Explanation of symbols for main parts of the drawings

1 panel 3 funnel

5: shadow mask 6: support frame

8: stud pin 12: spring

12a: 1st arm part 12b: 2nd arm part

12c: connection part 12f: embossing projection

Hereinafter, the present invention will be described in more detail with reference to FIGS. 6 and 8, which illustrate one embodiment.

Figure 6 is a perspective view showing an embodiment of a spring that is the main part of the present invention and Figure 7 is a partial longitudinal cross-sectional view of the CRT tube illustrating the use of the present invention, the spring 12 of the present invention is formed parallel to the tube axis direction The first and second arm portions 12a and 12b and the connecting portion 12c for connecting the first and second arm portions are formed in a substantially “ ”Shape.

The connecting portion 12c is formed to be inclined upward in the direction of the support frame 6 from the stud pin 8 as shown in Figs.

The connection part 12c having the above-described shape is provided with strength maintaining means for compensating the hole 5a formed in the shadow mask so that the shadow mask 5 expands during the operation of the CRT.

The strength maintaining means is a curve formed at the boundary of the second arm portion 12b and the connecting portion 12c in one embodiment of the present invention.

That is, in order to reinforce the strength of the spring 12, the connecting portion 12c is composed of a straight portion 12d and a curved portion 12e, and the straight portion 12d starting from the first arm portion 12a is made of the first portion. 2 is in contact with the curved portion 12e starting at the arm portion 12b.

The center of the curved portion 12e is located on an extension line of the second arm portion 12b parallel to the tube axis direction, wherein the radius of the curved portion 12e is determined according to the landing error compensation amount of the electron beam.

That is, when the radius is large, the curved portion is almost close to the straight line, and thus the landing error of the electron beam due to the expansion of the shadow mask 5 cannot be compensated. On the contrary, the smaller the radius, the larger the compensation amount of the landing error.

8 is a longitudinal cross-sectional view of a spring showing another embodiment of the strength holding means, the embossing projection (12f) is formed on the connecting portion 12c so that the embossing projection serves as the strength holding means.

The embossing projection 12f serves to maintain the strength of the spring 12 when the shadow mask 5 is deformed to the screen side due to thermal expansion during operation of the cathode ray tube. It may be formed to protrude, or conversely may be formed to protrude downward.

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

The support frame 6 applied to the present invention is iron (Fe), the shadow mask (5) is made of In-bar or aluminum-kilted steel (AK) material of Fe-Ni alloy, the thermal expansion coefficient of the in-bar aluminum aluminum It is about 1/10 of the coefficient of thermal expansion of steel.

Therefore, the landing error compensation amount of the electron beam by the spring 7 also depends on the material of the shadow mask 5, so the angle formed between the first arm portion 12a and the connecting portion 12c should be appropriately adjusted.

Since the spring 12 of the present invention can be easily changed in design, the landing error of the electron beam 11 due to thermal expansion of the shadow mask 5 during the operation of the CRT can be significantly reduced as compared with the conventional art.

In addition, a curved portion 12e or an embossing projection 12f, which is a strength-holding means, is provided at the connecting portion 12c connecting the first and second arm portions 12a and 12b, so that even if an impact is applied during operation of the CRT, Since the impact is prevented from being transmitted to the shadow mask 5 side, it is to prevent the degradation of color purity in advance.

As described above, in the present invention, the spring is made of one structure, so that the production is easy, and thus the production cost is reduced, as well as the curved portion or the embossing protrusion, which is a strength maintenance means, is provided at the connection part, even though the shock is applied during the operation of the CRT. Since the shadow mask support does not shake, the color purity does not change.

Claims (7)

In a color CRT tube which fixes one end of a spring to an inner wall of a support frame to which a shadow mask is fixed and the other end is inserted into a stud pin fixed to an inner wall of a funnel to support the support frame to a panel, wherein the spring is formed parallel to the tube axis direction. The first and second arm parts and the connecting part connecting the first and second arm parts are integrally formed to form a substantially “ Shape, wherein the first arm portion is fixed to the stud pin of the panel, the second arm portion is welded to the frame, the connecting portion is inclined upwardly from the first arm portion to the second arm portion, and the connecting portion maintains strength. With spring for color CRT. The method of claim 1, A spring for a color CRT tube, wherein the strength-retaining means is a curve formed at the boundary between the second arm portion and the connecting portion. The method of claim 1, Spring for the color CRT tube wherein the connecting portion is composed of a straight portion and a curved portion. The method of claim 3, wherein A spring for a color CRT comprising a straight portion starting at the first arm portion and a curved portion starting at the second arm portion. The method according to claim 3 or 4, A spring for a color CRT tube, wherein the center of the curved portion is located on an extension line of the second arm portion parallel to the tube axis direction. The method of claim 2, Spring for color CRT with embossed projections on the joint. The method of claim 1, Spring for color tube tube, embossing projection formed on the connecting portion of the strength maintaining means.