KR830001013B1 - Inline Gun Sphere - Google Patents

Abstract

No content.

Description

Inline Gun Sphere

1 is a partially broken side view showing an example of a conventional inline electron gun sphere.

2 is a correspondence diagram between various sleeve lengths and a focus characteristic at an image center of a color receiver.

3 is a correspondence diagram between various sleeve inner diameter roundness and the focus characteristic at the image periphery of the color receiving tube.

4 is a top view showing an example of the main lens electrode in the conventional inline electron gun sphere.

5 is a longitudinal cross-sectional view of FIG.

6 and 7 are main cross-sectional process diagrams for explaining an example of a protrusion molding method of a conventional sleeve portion.

8, 9 and 10 are main cross-sectional process charts for explaining another example of the conventional shaping | molding method of the sleeve part.

11 is a partially broken side view showing an example of the inline electron muzzle according to the present invention.

12th (a) to 12th (f) are sectional views of main parts for explaining an example of a method for protruding a sleeve portion of an inline electron gun body according to the present invention.

The present invention relates to an inline electron gun body, in particular its electrode structure.

In general, the three-electron gun used for the color receiving tube is used with a three-electron gun-electrode type electron gun body in which the relative accuracy of the three-electron gun is increased in order to exhibit excellent convergence characteristics.

1 is a partially broken side view showing an example of an inline electron gun body generally used in the related art.

In the figure, three cathodes 2 arranged in parallel are supported on a plate-shaped cathode support 1, and the cathodes 2 are provided by a heater 3 provided in the cathodes 2. Heated to release the electron beam. In addition, at the distal end of the cathode 2, the first grid 4 for controlling the electron beam 4, the second grid 5 for accelerating the electron beam and the third and fourth grids 6 constituting the electron lens (7) and the like are arranged in series and fixedly supported by the bead glass 8.

Each of these grids causes the electron beam to strike a predetermined phosphor sparse, wherein the third and fourth grids 6 and 7 are also called main lens electrodes, and each of the three sleeves 6a. (6b) (6c) and (7a) (7b) and (7c) are arranged in parallel, and cylindrical auxiliary electrodes 9 are coaxially and fixedly installed in each of these sleeves.

In this case, the auxiliary electrode 9 influences the electric field formed in the third and fourth grids 6 and 7 and the sidewalls of the third and fourth grids 6 and 7. It is installed so as not to provide a shape, and the length of the sleeves of the sleeves 6a, 6b, 6c, and 7a, 7b, 7c is long until a certain condition is satisfied. It is not necessary to use it if the precision can be secured until the inner diameter of the satisfies a certain condition.

2, the main lens electrode originally formed by theless processing is scraped off by machining using a nonmagnetic nonaqueous steel like the actual electrode, and the sleeves 6a, 6b, 6c, The lengths of (7a) (7b) and (7c) are formed in various stages, and the ratio L / D to the inner diameter D of the sleeve is expressed as a percentage as in the various lengths of the sleeves L. The vertical axis represents the ratio between the horizontal dimension A and the vertical dimension B of the electron focus in the image center portion of the color receiving tube, that is, the non-fatality ratio (B / A).

As is apparent from the figure, this non-bed aspect ratio is 1.0, i.e., the roundness is ideal, but in general, if the range is ± 5%, or 0.95 to 1.05, the focal characteristics of the color receivers are not affected.

In addition, according to the same drawing, the condition of L / D is about 50% or more in order to satisfy the focus characteristic of the color receiving tube and make the auxiliary electrode 9 unnecessary.

3 shows the result of examining the correspondence between the inner diameter roundness of the sleeve portion and the focus characteristic of the color investigator, and the horizontal axis shows the inner diameter roundness of the sleeve.

In addition, the vertical axis represents the ratio between the stepped and uniformly reflected portion of the electron focusing around the image periphery of the color receiving tube, that is, the core portion and the halo portion that looks thin.

As apparent from the figure, when the inner diameter roundness of the sleeve is lowered to about 40 mu m or less, the halow portion suddenly increases, indicating that the image quality of the color water pipe is adversely affected.

In summary, the above-mentioned matters are summarized. In the main lens nationwide, in order to remove the auxiliary electrode 9, the L / D is required to be about 50% or more, and the inner diameter roundness of the sleeve portion is about 40 µm. Becomes necessary.

Next, the conventional method of forming the main lens electrode will be described below with two examples.

That is, as shown in FIGS. 4 and 5, the main lens electrode is a sleeve having a lens portion having an inner diameter Dmm on the upper plate 11 of the electrode body 10 having a non-magnetic non-magnetic steel shape. It forms by protruding (7a) (7b) (7c) inward.

As an example of forming the sleeves 7a, 7b, and 7c, first, the hat main body 10 is subjected to pressureless molding, and then, as shown in FIG. 6 on the upper plate 11. The hole 12 having a diameter d smaller than the sleeve inner diameter D is drilled, and then the top plate 11 is placed on the base 13 as shown in FIG. ), The edge of the upper hole 12 was protruded, and the sleeves 7a, 7b, and 7c having a predetermined inner diameter D were formed.

However, according to this conventional method, the L / D is limited to about 24%, and hardly formed under the condition that the auxiliary electrode 9 can be removed.

On the other hand, FIGS. 8 to 10 show another molding method for improving the molding limit.

In these drawings, first, as shown in FIG. 8, the stretching process is carried out on the upper plate 11 of the electrode main body to form a pulled portion 15 having an inner diameter slightly smaller than the inner diameter D of the sleeve portion. Subsequently, as shown in FIG. 9, the pulled portion 15 is drilled to form a hole 16.

Finally, as shown in FIG. 10, the edge of the hole 16 is protruded and a sleeve 17 having a predetermined inner diameter D is formed.

According to such a molding method, the molding limit is improved compared to the molding method shown in Figs. 6 to 7, but even in this case, the L / D is limited to about 40%, and the auxiliary electrode 9 is removed. The condition is not reached. In addition, according to this molding method, as shown in FIG. 10, in the opening end 18 of the sleeve 17 at the step formed in the shape of the sleeve, distortion in the circumferential direction occurs, A phenomenon in which the inner diameter roundness of the opening end 18 is significantly degraded to 40 to 70 µm with respect to the inner diameter roundness is 15 to 25 µm.

Therefore, even if it is put to practical use, for example, L / D = 40%, there is a problem that a roundness shaping process is required after the heat treatment after the molding, and the roundness shaping process is removed after the distortion is removed.

As described above, in the related art, the above-described electron muzzle can not be adopted, which has a number of assembling steps, and further has a disadvantage of poor productivity.

Accordingly, an object of the present invention is to provide an inline electron gun body that solves the above-mentioned problems, and to form a sleeve length L of L / D = 50% or more on the main lens electrode, and to have an inner diameter roundness of about 40 μm or less. By ensuring the precision, the number of parts is reduced, and furthermore, the inline electron muzzle is constructed with less assembly process. Hereinafter, an inline electron gun sphere according to the present invention will be described in detail with reference to the accompanying drawings.

11 is a partially broken side view showing an example of the inline electron gun sphere according to the present invention. Since the same symbols as those in FIG. 1 are the same elements, the description thereof will be omitted. In the figure, sleeves 20a, 20b and 20c in which the fourth grid 7 has no auxiliary electrode and L / D = 50% or more are integrally formed by the pressing molding process. .

These sleeves 20a, 20b, and 20c are each formed in a shape in which each sleeve portion is gradually opened and the sleeve inner diameter is opened toward the open end near about 1/2 of the sleeve length L. It is. Moreover, the sleeves 21a, 21b and 21C having the above-mentioned savior are integrally formed in the third grid 6 as well.

Next, the shaping | molding method of this 4th grid 7 is demonstrated by 12th (a)-12th (f) figure. First, as shown in the drawing (a), a hole 22 having a diameter d ₁ is formed in the upper plate 11 of the electrode body.

Next, as shown in the same figure (b), the extending part 15 of the inner diameter which is slightly smaller than the inner diameter D of a sleeve is formed by the extending process. In this case, the hole 22 is extended, and the height of the part 15 which opens and increases by the diameter of the jack d ₁ ′ is fulfilling a secondary role.

Next, as shown in the same drawing (c), the sidewall portion 23 of the extending portion 15 is subjected to shaping, and the height of the extending portion 15 is further improved, and the predetermined pressing portion 15 Get the height H.

Next, as shown in the drawing (d), a uniform hole 24 having a diameter d ₂ is formed in the extending portion 15.

Next, as shown in the drawing (e), by performing the stretching process, the sleeve inner diameter D and the sleeve length L can be determined, and at the same time, molding of L / D = 50% or more can be obtained. In this case, the roundness of the sleeve opening 18 is remarkably deteriorated by the aforementioned distortion.

Finally, as shown in the drawing (f), a conical punch (not shown) is inserted on the sleeve opening end 18 side, and the inner diameter is gradually extended over the opening end at about half of the sleeve length L, or about 1/2. By pressing to open D ', the roundness of the opening end 18 due to the distortion can be fixed, and the accuracy can be improved to 15 to 25 µm, which is the same as the roundness of the inner diameter near the connecting portion 19.

In this case, the diameter D ', which is pushed apart from the opening end 18, can secure the roundness in an amount of about 1% of the sleeve inner diameter D. The third grid 6 is also molded in the same manner as above.

Incidentally, in the above embodiment, the case where the inner diameter opening start dimension of the sleeve opening end portion is set to about 1/2 of the sleeve length has been described, but the present invention is not limited thereto. In addition, although the electron gun to the 4th grid electrode was demonstrated in the Example mentioned above, it cannot be overemphasized.

Similarly, the cathode structure is not limited to the heat dissipation type.

As described above, according to the inline electron gun body according to the present invention, since the main lens electrode portion does not require the auxiliary electrode, the roundness of the sleeve is significantly improved and productivity is improved as compared with the conventional one using the auxiliary electrode. It is improved by about twice as much as the conventional one, and the manufacturing cost is reduced to about one third, and the inner diameter of the sleeve that becomes the lens portion can be large, so that an extremely excellent effect that can significantly improve the function as an inline electron gun is obtained. Lose.

Claims (1)

In an inline electron muzzle having a sleeve-shaped electrode, the electrode has a sleeve length of about 50% or more of the inner diameter of the sleeve, and gradually starts to expand its inner diameter toward the open end at a portion of the sleeve length. In-line electron muzzle, characterized in that the dimensions are enlarged to 1/2 the length of the sleeve.

Images