KR800000934B1 - Color picture tube - Google Patents

Abstract

A color misalignment correction device for the use in a color picture tube, in which at least two magnets are disposed rotatably and adjustably on the outer peripheral surface of the cathode-ray bulb so as to correct and arc-shaped convergence error appearing in a horzontal direction of the phosphor screen due to the mounting errors of either electron guns the deflection coil assembly on the color picture tube.

Description

Color

1 is a sectional view showing the main parts of an example of a conventional color water pipe.

2A and 2B are a cross-sectional view of a main part and a front view of a main part showing an electron beam array and a dynamic convergence pattern of a conventional delta type color water pipe.

3A and 3B are a sectional view of a main part and a front view of a main part showing an electron beam arrangement and a dynamic convergence pattern of a conventional inline type color receiver.

4A and 4B are main part sectional views and main part front views showing the sealing twist of the electron gun of the conventional inline type color receiving tube and the bow-shaped convergence error caused by the sealing twist of the electron gun.

5A and 5B are sectional views showing the principal parts of one embodiment of the color water pipe according to the invention.

6 is a sectional view showing the principal parts of another embodiment of a collar water tube according to the invention.

7 is a sectional view showing the principal parts of still another embodiment of a color water pipe according to the invention.

The invention relates to a color receiver, in particular a collar receiver having a color stabilization magnet at the periphery of the recall. In general, the color receiving tube emits a panel portion 1, a nipple head 2, and three electron beams having a fluorescent surface and a shadow mask as shown in FIG. It consists of the neck part 4 which has the electron gun 3, and forms the bulb 5 in which the inside was kept in vacuum.

A deflection coil 7 deflecting three electron beams 6 emitted from the electron gun 3 is disposed on the outer circumferential surface of the nut head 2 of the bulb 5, and a magnetic field is formed on the outer circumferential surface of the neck 4. The magnet cooking sphere 8 is arranged to guide the three electron beams 6 to the correct deflection center position by changing the intensity and the direction.

In the color water pipe configured as described above, the three electron beams 6 emitted from the electron gun 3 are deflected by the deflection coils 7 and are provided through a shadow mask (not shown) disposed on the inner surface of the panel 1. It hits the fluorescent surface and emits red, green, and blue colors. In this case, the three electron beams 6 need to be exactly matched on the fluorescent surface in order to obtain an image without color mismatch.

This is called convergence.

This convergence has a static convergence that matches three electron beams 6 at the center of the screen and a dynamic convergence that matches three electron beams 6 at the periphery of the screen.

Static convergence is performed to match the three electron beams 6 at the center of the screen, and the deflection received by the electron beams 6 by the deflection coil 7 is extremely small.

For this reason, it is designed so that static convergence can be attained by inclining the electron gun 3 to some extent.

In order to correct the static convergence error due to the slight error of the color water pipe, the permanent cone is disposed on the outer periphery of the neck portion 4 of the electron gun 3 portion and the strength of the magnetic field of the permanent magnet is varied. It is configured to adjust the vergence so that the three electron beams are concentrated in one point.

However, even if the three electron beams are aligned at the center of the screen by the static convergence magnet, the three electron beams deflected by the deflection coil 7, that is, the three electron beams at the periphery of the screen, must be constantly concentrated. I can do it.

In order to correct such a dynamic convergence error, in the case of a delta type electron gun, as shown in FIG. 2A, an external force generated by the convergence coil 9 disposed on the outer circumferential surface of the neck 4 is used. The magnetic field is applied to the three electron beams 6 in the electron gun 3 and corrected.

However, as shown in FIG. 2B, the pattern on the screen due to the dynamic convergence has a characteristic of being larger at the periphery of the screen and decreasing as it gets closer to the center, so that a paraboloid shape is formed on the inner surface of the panel 1. You must correct it.

Therefore, in order to obtain this correction magnetic field, the convergence coil 9 is wound around the iron core 10 disposed on the outer circumferential surface of the neck 4 of the electron gun 3, and the parabolic current is applied to the conversion coil 9. It is necessary to install a dynamic convergence correction circuit having a variable section for flowing and adjusting this parabolic current.

On the other hand, in the in-line color receiving tube, the electron beams 6 in the electron gun 3 are arranged in a line in the horizontal direction as shown in FIG. 3A, and the dynamic convergence pattern at this time is vertical as shown in FIG. 3B. The dynamic convergence error in the direction is reduced, and as a result, the dynamic convergence correction circuit in the vertical direction can be omitted, and the variable portion of the correction circuit is greatly reduced. Furthermore, the dynamic convergence pattern of the in-line color receiving tube shown in FIG. 3b shows a one-dimensional error only in the horizontal direction with respect to the two-dimensional error of the delta-type convergence pattern shown in FIG. 2b. By dynamically distorting the magnetic field of the deflection coil 7 with respect to the dynamic convergence, the correction circuit is not required in principle and it is possible to match three electron beams.

As a result, the circuit in the horizontal direction can also be omitted, making it possible to completely eliminate the dynamic convergence correction circuit.

On the other hand, as for the dynamic convergence error caused by the assembly error of the bulb 5 and the deflection coil 7, the relative position between the electron beam 6 and the deflection coil 7 is determined when the deflection coil 7 is mounted. Although the correction is carried out by adjusting the voltage, the dynamic convergence pattern generated by this assembly error has a drawback that can be completely corrected by the relative positions of the deflection coil 7 and the electron beam.

In other words, as shown in Figs. 4A and 4B, when the electron gun 3 is sealed in a state of being rotated in a horizontal direction, that is, in a horizontal line arrangement, the so-called mount rotation is also shown. If the deflection magnetic field is staggered in the direction of rotating the three electron beams 6 due to the assembling error of the uneven deflection coil 7, the electron beam 6 is deflected only in the horizontal direction, and the horizontal direction on the screen, that is, the transverse direction When the light shines in a straight line, as shown in FIG. 4B, the red (R) and blue (B) baselines show a dynamic convergence error in which the base line is bowed.

The bow-shaped dynamic convergence error can be corrected by rotating the deflection coil 7 with respect to the three electron beams 6, but in this case, the image on the fluorescent surface is inclined. Condition occurs.

In addition, the dynamic convergence error caused by the assembly error is remarkably larger as the deflection angle becomes larger, and becomes a problem that cannot be ignored as the large color water pipe.

Accordingly, the present invention is to improve the above-mentioned drawbacks, and to provide a color receiving tube which corrects the bow-shaped dynamic convergence error in the horizontal direction caused by the assembly error of the bulb 5 and the deflection coil 7. It is.

In order to achieve the above object, the color water pipe according to the present invention is provided with at least two balls of magnets on either or both of the external or deflection coils of the neck between the distal end of the electron gun and the deflection center of the deflection coil. The electron beams form a magnetic field acting in the direction of rotation.

EMBODIMENT OF THE INVENTION Hereinafter, the color water pipe according to this invention is demonstrated in detail based on drawing.

Figures 5a and b show an embodiment of the color misalignment correction magnet disposed on the outer surface of the color receiver according to the present invention, in particular the tip 4 of the electron gun 3 and the neck 4 in the section of the deflection coil 7; The principal part cross section and the same reference numerals in FIGS. 1 to 4 refer to the same elements, and thus description thereof is omitted.

In the same diagram, the configuration of the color shift correction magnet is performed in the section from the distal end portion of the electron gun 3 to the deflection center of the deflection coil 7, that is, the neck portion in the section AA ′ and BB ′ indicated by a dashed-dotted line in FIG. 5B. On the outer circumferential surface of 4), a non-magnetic thick cylindrical support member 11 is formed and fixed, and at the same time as the horizontal direction of the electron beam 6, Two screw grooves 11a and 11b penetrating in the direction toward the center are formed, and the screw grooves 11a and 11b have N and S poles, and the outer circumferential surface of the circumference is the screw groove 11a, The two screw-shaped permanent magnets 12a, 12b having a pitch corresponding to (11b) are appropriately tightened so that the ends of the N poles are close to the outer diameter of the neck 4, respectively.

At this time, the force generated by the magnetic field generated by the circumferential magnets 12a and 12b and the rotational force of the electron beam 6 relative to the tube axis of the neck 4 in the reverse direction (C direction) acts. The left and right electron beams close to the inner wall of the neck 4 are corrected in the horizontal direction in which the sealing twist is fixed.

As a result, the traveling trajectory of the three electron beams 6 is corrected, so that the three electron beams 6 can be concentrated at the same time, and red (R) and blue (B) bow-shaped conversions in the periphery of the firing thread are performed. Can be completely corrected.

In addition, in the above-described embodiment, although the magnet is inserted into the support member 11 and the neck portion 4, the magnet is inserted in a part of the deflection coil. When the arrangement is arranged, it is possible to reduce the number of people in the mounting park without the need for a separate support member.

6 is a main portion showing another embodiment of the color misalignment correction magnet disposed on the outer surface of the neck 4 in the section of the color receiver, in particular, the tip of the electron gun 3 and the rear end of the deflection coil 7 according to the present invention. The cross section differs from the above embodiment in that the ring-shaped magnet 13 is magnetized to N and S poles every 90 degrees and disposed on the outer circumferential surface of the neck portion 4.

In this case, the direction of the N poles is arranged in the same direction as the horizontal arrangement direction of the three electron beams 6, and the same magnet 13 of the same shape is overlapped on the rear of the magnet 13 and the Exposed to be rotating material on the outer circumferential surface, and by rotating this magnet 13, the strength of the magnetic field is adjusted from the north pole to the south pole, and the neck portion in the reverse direction (arrow D direction) and the sealing twist of the electron beam 6 Since the rotational force acts on the outer axis, the pendulum beams on the left and right adjacent to the inner wall of the neck portion 4 are corrected in the horizontal direction in which the torsional distortion is corrected, thereby obtaining the effects as described above.

FIG. 7 is a sectional view showing the main portion of another embodiment of the color receiving tube and the color misalignment correction magnet according to the present invention, wherein six poles are formed on the outer circumferential surface of the neck portion 4 in which the electron beam 6 is disposed in a delta form in the same figure. The ring-shaped magnet 14 having a magnetic pole of magnetic pole is disposed to be a rotating material.

In such a case as well, by adjusting and rotating the ring-shaped magnet 14 as in the above-described embodiment as appropriate, the strength of the magnetic field varies from the N pole to the S pole direction, and the twisting of the three electron beams 6 is sealed. The force which rotates about the tube axis of the neck part 4 in the reverse direction (arrow E direction) acts, and the running trajectory of the electron beam 6 is corrected, and the effect similar to the above is obtained. In the above embodiment, the case where the magnet is disposed through the support member on the outer circumferential surface of the neck portion in the section between the tip end of the electron gun and the rear end of the deflection coil and the case where the ring-shaped magnet are disposed are described. It goes without saying that the same effect can be obtained even when the magnet is disposed in a part of the rearward portion of the deflection center of the deflection coil.

Here, as the mounting position of the magnet, as shown in FIG. 5B, the line AA 'crossing the tip of the electron gun 3 is positioned on the panel portion 1 side, and the line BB' crossing the deflection center is on the electron gun 3 side. Should be

This is because the magnetic beam at the center of the three electron beams is slightly influenced by the low system due to the magnetic field as shown in FIG. 5a or 3, and the three electron beams are horizontal in the direction of the magnetic field. Since the orientation is also affected, the static convergence needs to be readjusted when the magnet is mounted.

Therefore, the static convergence correction magnet needs to be placed on the panel 1 side.

In addition, the three electron beams are deflected and through this magnetic field, the bow-shaped dynamic convergence error cannot be corrected.

Therefore, it is necessary to mount on the electron gun 3 side at the center of the deflection center B-B ', that is, the length of the deflection magnetic field in the direction of the tube axis.

As described above, the color water pipe according to the present invention is disposed on the bulb having the panel portion, the nipple head and the neck, and disposed on the outer surface of the electron gun and the nipple head which radiate three electron beams to the inner surface of the panel. In a color water pipe having a deflection coil deflecting a beam, the outer beam of the neck between the distal end of the electron gun and the deflection center of the deflection coil or one or both of the deflection coils in the rotational direction with respect to the observation of the neck beam. By disposing the magnet for moving, the bow-shaped dynamic convergence error caused by the sealing error of the electron gun and the assembly error of the deflection coil can be easily and surely corrected.

In addition, the workability is improved in the process of adhering the deflection coil to the nut head of the bulb and the process of sealing the electron gun in the neck, and at the same time, it can greatly improve the equipment of the number of parts in the color water pipe. Has

Claims (1)

A bulb 5 having a panel portion 1, a nipple head 2, and a neck portion 4, and an electron gun that is housed in the neck portion 4 and radiates three electron beams 6 to the inner surface of the panel portion 1. (3) and the tip of the electron gun (3) and the deflection of the deflection coil (7) in the color water pipe having a deflection coil (7) disposed on the outer circumferential surface of the noodle (2) and deflecting the electron beam (6). Color water pipe, characterized in that a magnet for rotating the electron beam (6) with respect to the tube axis of the neck portion 4 is disposed on one or both of the outer peripheral portion of the neck portion 4 or the deflection coil (7) between the center. .

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