KR850001389B1 - Deflection yoke for a color cathode ray tube - Google Patents

Abstract

A deflector yoke for a color cathode-ray tube is disclosed, which does not cause raster distortion and avoids electron-beam convergence errors. Both horizontal and vertical deflection coils generate fields having a pincushion distribution. Front-end magnetic members extend the pincushion-type vertical deflection magnetic field toward the viewing screen of the tube. Rear-end magnetic members deform one portion of the magnetic field generated by the vertical deflection coils into a barrel type so that the sum of the vertical deflection magnetic field is effectively a barreltype distribution.

Description

Deflection yoke device of color television receiver

1, 2, and 3 are front views, rear views, and side views showing one example of a deflection yoke device of a color television receiver according to the present invention.

4 is a curve diagram showing the deflection characteristics of a vertical deflection magnetic field.

5 is a schematic diagram showing a raster deformation of a conventional vertical deflection coil.

Fig. 6 is a schematic diagram for explaining the corrective action of raster deformation caused by the vertical deflection coil and the rear cross arm in the present invention.

7 and 8 are perspective views showing rear cross arms and front cross arms.

9 (a) to 9 (c) are perspective views showing magnets for linearity correction.

10 is a schematic diagram showing the linear deformation of the raster.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a deflection yoke device of a color television receiver, and more particularly, to an improvement in correction of raster deformation.

In this type of deflection yoke device, various correction methods have been studied in the past for correcting raster deformation. First, in general, as a magnetic field of a deflection yoke device, a uniform magnetic field is difficult to obtain, and when the magnetic field is uneven, the linearity of the raster is lost, and the pincushion or barrel type is severely deformed.

In order to compensate for this nonlinearity, conventionally, measures have been taken such that the deflection current flowing in the deflection coil is deformed in advance so that nonuniformity does not occur in the generated magnetic field, or a correction coil is provided separately from the deflection coil.

Secondly, the screen surface of the receiving tube generally has a curved surface different from the spherical sphere at equidistant points, which causes pincushion deformation in the raster. In order to correct this pincushion deformation, measures have been taken to deform the deflection magnetic field by modifying the deflection current appropriately in advance. In this case, the pincushion deformation of the raster becomes larger because the deflection angle becomes wider as the larger wide-angle water tube becomes larger, and therefore, the amount of correction cannot be avoided.

As described above, in the conventional correction of the deformation of the raster, an appropriately modified correction current is prepared by using a dynamic pin cushion correction circuit (hereinafter, referred to as a DPC circuit), and the center of the deflection coil is subjected to the deflection current. However, in a large wide-angle water tube, a large amount of correction is required, so that a complicated large size is required as a DPC circuit, and the effort for manufacturing and adjusting this is indispensable. Therefore, it is necessary to correct the raster deformation without using this DPC circuit. desirable.

The present invention intends to propose a deflection yoke device capable of effectively realizing such a requirement, by correcting a deflection magnetic field by a magnetic piece and a permanent magnet in correcting deformation such as linear deformation or pincushion deformation occurring in a raster. In order to realize this and to do this, the convergence of the longitudinal axis in the center of the raster is not shifted.

Hereinafter, an example of the present invention will be described in detail with reference to the accompanying drawings. In Figs. 1 to 3, reference numeral 1 denotes a deflection yoke device as a whole, having a funnel coil separator 2, and having a saddle-shaped horizontal deflection coil on the inner surface of the coil separator 2 (1). 3) is mounted, and a core 4 almost conical cylindrical on the outer surface of the coil separator 2 is suddenly inserted, and the toroidal vertical deflection coils 5A and 5B are positioned at the upper and lower positions of the core 4. Is recommended.

The magnetic field distribution of the vertical deflection coils 5A and 5B in the conventional general deflection yoke device in obtaining a raster by only such horizontal deflection coils 3 and the vertical deflection coils 5A and 5B. As shown by the curve B ⁰ in the figure, the one showing nearly the distribution of the batter's magnetic field almost over the entire neck and corner portions is used. Thus, as shown in FIG. 5, a raster with a large pincushion deformation was generated.

On the other hand, in the deflection yoke device 1 according to the present invention, the magnetic field distribution by the vertical coils 5A and 5B is represented by the neck portion or the corner portion as indicated by the curve B ₁ in FIG. It is used that exhibits a sufficient pincushion magnetic field distribution as compared with the conventional magnetic field distribution curve B ₀ over the entire region. The magnetic field distribution of the pincushion can be obtained, for example, by narrowing the winding width of the vertical deflection coils 5A and 5B to the core 4. Thus, barrel deformation R ₁ is generated in the raster as shown in FIG. Therefore, whenever a deviation of the convergence of the longitudinal axis (Y _H ) in the center of the raster occurs, barrel deformation occurs on both the left and right sides of the raster, but such rear deformation is the rear cross arm 11 and the front cross. The arm 12 is corrected as indicated by the curve R _{2 in} FIG. For this purpose, the distribution of the vertical deflection magnetic field (R ₂ ) as the entire deflection yoke device 1 as a fourth degree is the barrel direction from the conventional magnetic field distribution curve (B ₀ ) at the neck portion (B ₂₁ ) and the corner portion at the same time. In (B ₂₂ ), a correction is made with a distribution sufficiently in the pincushion tendency compared with the conventional magnetic field distribution curve B ₀ .

This, by the ordinate converter yesterday's displacement and the neck portion a barrel magnetic field distribution portion of the vertical deflection magnetic field by mainly a barrel modification of the right and left sides of the (Y _H) (B ₂₁₎ in said raster center with respect to Figure 6 The correction is possible, and mainly by the pincushion deformation of the diagonal portion of the raster, the pincushion magnetic field distribution portion B ₂₂ of the corner portion of the vertical deflection field can be corrected.

The rear cross arm 11 is constituted by a pair of magnetic plates 11A and 11B curved at almost the same curvature as the outer surface of the neck of the coil separator 2, as shown in FIG. And as shown in FIG. 3, they are arranged so as to oppose each other at the inner center positions of the vertical deflection coils 5A and 5B on the neck outer surface of the coil separator 2. As shown in FIG.

Here, the rear cross arm 11 forms a magnetic path with a relatively low magnetic resistance along the upper and lower outer edges of the neck portion of the water pipe on the center line L _{V in} the vertical direction of the deflection yoke device 1. Therefore, the magnetic flux in the center upper part and the lower part of the raster diffuses to the upper part and the lower part, respectively, and as a result, the deflection magnetic field B caused by the vertical deflection coils 5A and 5B ₁ ) The magnetic field distribution of the neck part is canceled and the barrel distribution is corrected as shown by the curve (B ₂₁ ).

On the other hand, as shown in FIG. 8, the front cross arm 12 has the arm main body 13 A) curved at the same curvature as the curvature of the outer circumferential surface of the corner end of the coil separator 2, and the left and right ends thereof. The rear end portion extending from one side to the rightward direction is composed of a pair of magnetic plates 12A and 12B composed of a pair of protruding pieces 13L and 13R that are bent at right angles. By the way, the coil separator 2 has a flange 2A extending outward at the front end of the corner, and the pair of front cross arms 12A and 12B have an arm body 13A at the left and right sides of the flange 2A. Are mounted so as to face each other facing each other from behind. Thus, the arm body 13A of the front cross arms 12A and 12B extends between the upper and lower vertical deflection coils 5A and 5B so that the upper and lower ends are on the vertical deflection coils 5A and 5B. It is fixed so as to cover the leakage magnetic flux of the deflection magnetic field generated in the left and right directions by the vertical deflection coil (5A), (5B) to the pair of protruding pieces (13L) and (13R) through the arm body (13A). have. Thus, when a vertical deflection magnetic field is generated from the left to the right in FIG. 1 along the horizontal center line L _H , the magnetic flux passes through the arm body 13A of the front front arm 12B on the right side thereof ( 13L) and 13L, and the protruding piece 13L through the flange 2A portion on the inner side of the protruding piece 13L and 13R of the front cross arm 12A on the opposite side (left side) from the inner side thereof. And 13R to the arm body 13A, thereby forming a closed loop to the vertical deflection field.

Here, the leakage magnetic flux of the vertical deflection magnetic field is guided to the upper and load cores of the vertical deflection magnetic field by a pair of front cross arms 12A and 12B, and between the protruding pieces 13R and 13L opposed to this position. Form a correction magnetic field. However, the correction magnetic field is formed between the four diagonal portions of the vertical deflection field, and as a result, the four diagonal portions of the raster are pushed in the center direction, thereby correcting the deformation of the left and right edges of the raster.

In the above configuration, the flange 2A of the coil separator 2 is provided with a linear correction magnet 15 composed of a pair of research magnets 15A and 15B. As the permanent magnets 15A and 15B, a ring which can be rotated in the center of the boxed stone as shown in FIG. 9 (a) or the arm-shaped arm 16 as shown in FIG. 9 (a) is shown. A patient seat with an arm formed by attaching the magnet 17 can be used. The pair of research magnets 15A and 15B are sandwiched by a vertical deflection magnetic field at the upper and lower edge centers on the upper surface of the vertical center line L _V on the rear surface of the flange 2A.

Therefore, the upper half and the lower half of the vertical deflection magnetic field are partially corrected by the magnetic field generated between the respective magnetic poles of the upper and lower permanent magnets 15A and 15B, respectively. 20 is a terminal circuit board.

In the above configuration, the vertical deflection magnetic field generated in the pincushion type by the vertical deflection coils 5A and 5B makes the raster barrel-shaped as indicated by the curve R ₁ in FIG.

The vertical deflection magnetic field of the neck portion of the deflection yoke device 1 is pincushioned by the rear cross arms 11A and 11B according to the barrel-shaped raster, as indicated by the curve R ₂ of FIG. Similarly, the deviation of the convergence of the vertical line Y _H in the center portion of the raster is corrected.

In addition, the front cross arms 12A and 12B are used to correct the vertical deflection magnetic field of the corner portion of the deflection yoke device 1 in a pincushion type, so that the four diagonal portions of the raster are pushed inward. . Here, this correction is made at the corner of the deflection yoke device 1, so that the deformation of the left and right sides and the upper and lower portions of the raster is corrected. In this way, the converter of the vertical line Y _H at the center of the raster The occurrence of misalignment can be prevented.

In addition, the upper and lower portions of the vertical deflection magnetic field in the corner portion of the deflection yoke device 1 are smoothly corrected by the magnetic flux generated by the permanent magnet by the linear correcting magnets 15A and 15B. The relatively small deformation remaining in the horizontal direction of the raster is corrected. For example, in the correction of the rear cross arms 11A and 11B and the front cross arms 12A and 12B, as shown in FIG. Nominal), deformations in the inner portion excluding the left and right sides of the raster (called Inner Kissen deformation), T / B deformation, etc., but such linear deformation is applied to the permanent magnets 15A and 15B. Cannot be corrected.

As described above, according to the present invention, the vertically deflected magnetic fields extending from the neck portion to the nose portion of the deflection yoke device are not corrected as in the prior art, but the rear cross arms 11A, 11B and the front cross arm 12A. 12B and the permanent magnets 15A and 15B, the correction amount can be obtained even in a large wide-angle water pipe. Therefore, the conventional strain correction circuit is not required, and the configuration of the deflection yoke device can be further simplified, and at the same time, the assembly and adjustment work, which is quite complicated in the past, can be omitted at once. This eliminates the need for a particularly complex winding of the vertical deflection coils.

Claims (1)

In the deflection yoke device 1, which is formed by mounting a vertical deflection coil 5 recommended for a normal core on an outer side of a pyrophary coil separator 2 having a horizontal deflection coil 3 mounted therein, the coil separator. In the nose portion of the coil separator 2, a rear cross arm 11 composed of a pair of magnetic pieces disposed at an up-and-down position in the neck portion of (2) and a leakage magnetic flux of the vertical deflection coil 5 Color including a straight cross correction magnet (15) composed of a front cross arm (12) leading to four diagonal portions of a pair, and a pair of permanent magnets disposed at upper and lower positions in a corner of the coil separator (2) Deflection yoke device of a television receiver.

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