LT4703B - Deflection yoke - Google Patents

Abstract

The invention is intended to be a deflection system. The deflection system consists of the coil separator, which has a mouth and display; the coil separator isolates the initial and second coils of deflection equipped in the outer and inner surfaces of its circles, intended for electro radius direction, correspondingly in a vertical and horizontal direction; ferrite core equipped coils in the outer circular surface are made from magnetic material for reinforcement of the magnetic fields and protection from fluctuation medium, placed in the coil separator's circular outer surface in two or more positions, intended for ferrite core protection from fluctuation in the direction of its connection.<IMAGE>

Description

The invention relates to a deflection system which improves the dispersion of the image by the dispersion of the vertical deflection coil assembly.

Typically, the deflection system used in a television receiver cathode ray tube (CRT) or monitor consists of a saddle-to'roid and saddle-type deflection systems, and is designed to direct the radiation emitted from electronic cannons to the fluorescent layer of the cathode ray tube screen. Electronic beam deflection correction systems of this design are widespread and are described, for example, in U.S. Pat. 5557165, 5397968, 4764705, and European patent no. 689223.

In other words, as shown in FIG. 1, the conventional deflection system 1 is arranged around the neck of the cathode ray tube 2. The deflation system 1, as described above, consists of a saddle-saddle type deflection system shown in FIGS. toroidal type deflection systems shown in Figures 4 and 5 depending on the coil winding design.

The deflection system 1 deflects vertically and horizontally the electronic rays emitted from the BGR electronic cannons 4 mounted in the neck 3 of the cathode ray tube 2 and precisely focuses the electronic rays into the fluorescent layer of the cathode ray tube 2.

Figures 2 and 3 show a typical saddle-to-saddle deflection system. As shown in Figures 2 and 3, in this type of deflection system, the horizontal deflection coils 5 having a saddle shape are arranged at the top and bottom of the circumferential inner surface of the tapered coil separator 6, and the vertical deflection coils 7 having a saddle shape. the left and right sides of the circular outer surface of the separator 6 screen.

The cylindrical ferrite core 8 is disposed on the circumferential outer surface of the screen of the coil separator 6 and is intended to enhance the magnetic field of the vertical deflection coils 7.

Furthermore, the coma-free coils 9 are arranged adjacent the circumferential surface of the neck of the coil separator 6 and are intended to compensate for the coma generated by the vertical deflection coils 7.

Figures 4 and 5 show a typical saddle-toroid deflation system. As shown in Figures 4 and 5, in this type of deflection system, the horizontal deflection coils 5 are disposed at the top and bottom of the circumferential inner surface of the tapered coil separator 6, the cylindrical ferrite core 8 is positioned on the circumferential outer surface of the coil separator 6, 10 having a toroidal shape are arranged in the upper and lower portions of the ferrite core 8.

Furthermore, the coma-free coils 9 are arranged adjacent the circumferential surface of the neck of the coil separator 6 and are intended to compensate for the coma generated by the vertical deflection coils 10.

However, conventional deflection systems have the disadvantage that the ferrite core 8 may be displaced by attaching the ferrite core 8, which is wrapped around the vertical deflection coils 7, to the circumferential outer surface of the coil separator 6 having a horizontal deflection coil 5 mounted on a circular inner surface. dimensional variances, vertical deflection coils 7 coil variances, and so on thanks. That is, the ferrite core can be shifted even transversely or longitudinally by the surface of the coil separator 6 even with a slight impact.

As mentioned above, if the ferrite core 8 wrapped around the vertical deflection coils 7 is displaced by the surface of the coil separator 6, the vertical deflection coils 7 and the coil separator 6 cannot be accurately concentric, and thus will not have a stable axial balance and image distortion.

Specifically, in a saddle-to-saddle deflection system, there is a difference between left and right magnetic fields resulting from the relative variance between left and right vertical deflection coils and is therefore geometrically distorted when violating image convergence.

Similarly, in the saddle-toroidal deflection system, there is a difference between left and right magnetic fields due to relative dispersion and / or relative current between vertical deflection coils 10 arranged on the upper left and lower right portions of the ferrite core 8 and vertical deflection coils 10, arranged on the ferrite core 8 on the upper right and lower left portions on the Χ-Y axes, so that it is geometrically distorted when the image convergence is violated.

The convergence violation is distinguished between the YV convergence violation and the YHC convergence violation. The YV convergence lesion exhibits a vertical convergence lesion where the red R transverse line does not coincide with the blue B transverse line in the upper and lower Y axis, as shown in Figures 6 and 7, and the YHC convergence lesion exhibits a horizontal convergent lesion the line intersects the blue line B as shown in Fig.8.

Geometric distortion is manifested by the fact that the image is not normal but trapezoidally distorted as shown in Figs. 9-12.

To solve this problem, a plurality of elastic wedges made of porous material, not shown in the drawings, are attached to the circumferential outer surface of the spool separator 6, spaced at equal intervals in the circumferential direction. Yes ferrite core 8; mounted on the circumferential outer surface of the coil separator 6, elastically deflected outwards, thereby reducing assembly dispersion.

However, the vertical deflection coils 7 cannot be precisely axially balanced because the elastic wedges, many of which are used in this method, exhibit significant self-deflection, which increases dimensional dispersion and is indeed difficult to balance the vertical deflection coils in the axial direction.

In addition, many elastic wedges are glued to the circumferential surface of the spool separator 6, their position of attachment and hence the size of the dispersion depend on the worker, making it difficult to determine a stable axial balance of the vertical deflection coils 7.

Furthermore, the use of multiple elastic wedges increases the amount and cost of components, as well as the labor-intensive work involved in bonding multiple elastic wedges results in reduced productivity and productivity.

SUMMARY OF THE INVENTION The present invention is directed to the above problems and is directed to a deflection system that can accurately position a ferrite core wrapped around a vertical deflection coil and a coil separator, thereby reducing the impact of assembly dispersion on image quality and reducing cost and productivity. .

The object of the present invention is a deflection system comprising: a coil separator having a neck and a screen, the coil separator having horizontal deflection coils disposed on its circumferential inner surface: the ferrite core connected to the circumferential surface of the coil separator has a vertical deflection coil disposed on its circumferential outer surface; and anti-fluctuating means disposed on the circumferential outer surface of the coil separator in two or more positions to protect the ferrite core from fluctuating in the direction of attachment.

Another object of the present invention is a deflection system comprising: a coil separator having a neck and a screen, the coil separator having horizontal deflection coils disposed on its circumferential inner surface; a ferrite core connected to a circumferential outer surface of a coil separator, the ferrite core having vertical deflection coils disposed on its circumferential outer surface; and anti-fluctuating means arranged on the coil separator screen in two or more positions to prevent the ferrite core from fluctuating in a direction perpendicular to its direction of engagement.

Yet another object of the present invention is a deflection system comprising: a coil separator having a neck and a screen, the coil separator having horizontal deflection coils disposed on its circumferential inner surface; a ferrite core connected to a circumferential outer surface of a coil separator, the ferrite core having vertical deflection coils disposed on its circumferential outer surface; first anti-fluctuation means located at two or more positions on the circumferential outer surface of the coil separator to protect the ferrite core from fluctuating in the direction of attachment; and second anti-fluctuating means disposed on the coil separator screen to prevent the ferrite core from fluctuating in a direction perpendicular to its attachment direction.

The above objects and other features and advantages of the present invention will be explained in more detail in the following description according to the accompanying drawings in which;

Fig. 1 is a side view of a conventional deflection system;

Figures 2 and 3 are longitudinal and transverse views of a conventional saddle-saddle deflection system:

Figures 4 and 5 are longitudinal and transverse views of a conventional saddle-toroidal deflection system:

Figures 6-12 are views for explaining image convergence and geometric distortion;

Figure 13 is a front view of the main components of a conventional deflection system;

FIG. 14 and 15 are front elevation and enlarged perspective views of a deflection system of the first embodiment of the present invention;

Fig. 16-19 is a front elevation and enlarged perspective view of a deflection system of the second embodiment of the present invention; and

Figures 20-24 are a front elevation and an enlarged perspective view of a deflection system of a third embodiment of the present invention;

The preferred embodiment of the present invention will now be described in more detail with reference to the accompanying drawings. Wherever possible, the same or similar parts will be denoted by the same numerals.

The deflation system according to the first embodiment of the present invention will be described with reference to Figures 14 and 15.

A saddle-toroid-type deflection system will be described below for illustrative purposes with reference to Figures 1-13.

As shown in the drawings, the deflection system 1 of the present invention consists of a coil separator 6, a ferrite core 8, and a flocculation guard.

The coil separator 6 has a neck and a screen. The first and second deflection coils 5 and 7 for deflecting the electronic beams in the horizontal and vertical directions are arranged on the circumferential inner and outer surfaces of the coil separator 6.

In this case, the horizontal deflection coils 5, which direct the electronic beams in the horizontal direction, can be used as deflection coils, which are arranged on the circumferential inner surface of the coil separator 6. Conversely, the vertical deflection coils 7, which direct the electronic beams in the vertical direction, can also be used as deflection coils, which are arranged on the circumferential inner surface of the coil separator 6.

In the following, it will be explained, by way of example, when the first deflection coils arranged on the circumferential inner surface of the coil separator 6 are used as horizontal deflection coils 5 to direct the electronic rays in the horizontal direction.

The ferrite core 8 is disposed on the circumferential outer surface of the coil separator 6 and is made of magnetic material to enhance the magnetic fields of the vertical deflection coils 7.

Flux preventive means are provided to prevent the ferrite core 8 connected to the coil separator 6 from moving up and down and, in particular, being disposed on the circular outer surface of the coil separator 6 so as to deflect portions of the ferrite core 8 wrapped vertically reels 7.

The anti-fluctuation means comprise a plurality of elastic protrusions 11 disposed on the circumferential outer surface of the coil separator 6, which are designed to act on the ferrite core 8 in an elastic force in the direction opposite to the ferrite core 8 connection direction.

A plurality of elastic protrusions 11 are disposed on the circumferential outer surface of the coil separator 6 in two or more positions. It is advisable to place a plurality of elastic projections 11 in pairs symmetrically with respect to each other.

In this case, the plurality of elastic protrusions 11 is formed by at least one pair of left and right elastic protrusions 12 and 13 symmetrically disposed on the circumferential outer surface of the coil separator 6.

Since the plurality of elastic protrusions 11 is formed by at least one pair of left and right elastic protrusions 12 and 13, at least one pair of left and right elastic protrusions 12 and 13 are disposed opposite to the circular outer surface of the two ferrite cores to the coil separator 6. are symmetrical to each other. Thus, there is no interference when connecting both sides of the ferrite core to the circumferential outer surface of the coil separator 6 and finally forming the ferrite core 8.

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In addition, at least one pair of left and right elastic protrusions 12 and 13 is provided on the left and right sides of the connecting surface of the two sides of the coil separator, which finally forms the coil separator 6.

This is done to reduce the amount of variation in the castings, since the contours of the left and right coil separator sides change due to the large number of elastic protrusions 11, i.e. at least one pair of left and right elastic projections 12 and 13 being injection molded together with the two sides of the coil separator.

On the other hand, as shown in FIG. 15, a plurality of elastic protrusions 11 may be disposed in the middle of the spool separator 6 in two or more positions, with the second spaced symmetrically with respect to the first.

However, the locations of the plurality of elastic protrusions 11 are not limited to those described above, but as shown in FIG. By the dashed lines 15, a plurality of elastic protrusions 11 may be disposed in the upper if lower portions of the spool separator 6 in a vertical direction, thereby obtaining a uniform fluctuation protection effect.

In other words, a plurality of elastic protrusions 11 are positioned at appropriate positions to accommodate the size of the deflection system and so on.

In that case, as shown by the dashed lines in FIG. 15, the plurality of elastic protrusions 11 in the upper and lower portions of the spool separator 6 preferably have different widths of elastic protrusions 11 disposed at the top of the spool separator 6 and elastic protrusions 11 at the lower part of the spool separator 6.

This is due to the fact that the upper and lower parts of the coil separator 6 have different curves. Therefore, the elastic protrusions 11 disposed at the screen of the spool separator 6 must be wider than the elastic protrusions 11 positioned at the neck of the spool separator 6.

The procedure for assembling the deflection system of the above construction will be described in more detail below.

First, the two halves of the coil separator, arranged symmetrically to each other, are assembled to form the coil separator 6, and then the horizontal deflection coils 5 are disposed on the circular inner surface of the coil separator 6.

The vertical deflection coils 7 are then positioned on the circumferential outer surface of the coil separator 6, and then two symmetrically spaced sides of the ferrite core are placed on the circumferential outer surface of the coil separator 6, forming the ferrite core 8.

By attaching the ferrite core 8 to the coil separator 6, a plurality of elastic protrusions 11 disposed on the circumferential outer surface of the coil separator 6 as an anti-fluctuation means elasticly retain the ferrite core 8, thereby providing an outward displacement, such that the ferrite core 8 is securely attached circular outer surface without any fluctuation.

The elastic force acts on the ferrite core 8 through a plurality of elastic protrusions 11 in the direction of attachment of the ferrite core 8 to the coil separator 6 so that the ferrite core 8 is protected against fluctuation up or down on the circumferential outer surface of the coil separator 6.

For this reason, it is possible to avoid deflection of the assembly dispersion due to flocculation of the ferrite core 8 during its connection to the coil separator 6, and thus vertical deflection coils can be steadily axially balanced, thereby improving the image dispersion, i.e. avoiding image distortion.

Because of the plurality of elastic projections 11 disposed on the circumferential outer of the coil separator 6. surface facing the portion of the ferrite core 8 around which the vertical deflection coils 7 are wound, it is possible to prevent the sheaths of the vertical deflection coils 7 from being damaged during the connection of the ferrite core 8 to the coil separator 6 and thereby short circuit.

The above-described deflection system having anti-fluctuation measures, i.e. a plurality of elastic protrusions 11 disposed in pairs symmetrically to one another on the circumferential surface of the coil separator 6, characterized in that the axial balance of the ferrite core 8 and the vertical deflection coils 7 which are wound around the ferrite core 8 is constant.

Consequently, since it is not necessary to attach a plurality of elastic protrusions separately to the circumferential surface of the coil separator 6, in order to maintain axial balance, the amount of components is reduced, thereby reducing production costs and increasing productivity.

In addition, improved dispersion of capture and so on avoids image distortion, thereby increasing the reliability of the deflection system.

A deflation system according to a second embodiment of the present invention will be described with reference to Figs.

As shown in the drawings, the deflection system 1 of the present invention consists of a coil separator 6, a ferrite core 8, and a flocculation guard. The coil separator 6 consists of a neck and a screen. The first and second deflection coils 5 and 7, which are intended to direct the electronic beams in horizontal and vertical directions, are arranged on the circumferential inner and outer surfaces of the coil separator 6.

In this case, the horizontal deflection coils 5, which direct the electronic beams in the horizontal direction, can be used as deflection coils arranged on the circumferential inner surface of the coil separator 6. Conversely, 'vertical deflection coils 7 for directing electronic beams in a vertical direction may also be used as deflection coils arranged in a coil ^; on the circumferential inner surface of the separator 6.

The case in which the first deflection coils' mounted on the circumferential inner surface of the coil separator 6 are used as horizontal deflection coils 5 for directing the electronic rays in the horizontal direction will be described in more detail below.

The ferrite core 8 is mounted on the circumferential outer surface of the coil separator 6 and is made of magnetic material for vertical magnetic deflection coils 7 to reinforce the magnetic fields.

The anti-fluctuation means are disposed on the inner surface of the screen of the coil separator 6 and are intended to resiliently maintain the ferrite core 8 in the direction perpendicular to its connection direction.

A plurality of elastic members 14 formed together with the inner surface of the screen of the coil separator 6 are used to prevent fluctuation.

A plurality of elastic members 14 are disposed on the inner surface of the screen of the coil separator 6 so that they are directed to the vertical deflection coils 7 wrapped around the ferrite core 8 and are intended to contact the vertical deflection coils 7.

A plurality of elastic members 14 as shown in FIG. 17, are arranged in a circumferential direction on the inner surface of the screen of the coil separator 6 so that they have the same curvature.

However, the locations of the plurality of elastic members 14 are not limited only to those listed above, but as shown in FIG. 18 and 19, a plurality of elastic members 14 may be directed radially inwardly or outwardly of the inner surface of the screen of the coil separator 6.

On the other hand, when the plurality of elastic members 14 are arranged in a circumferential direction as shown in Fig. 16, it is desirable that the plurality of elastic members 14 be disposed on the inner surface of the screen of the coil separator 6 so as to intersect the joining surface.

This is because the coupling surface of the coil separator 6 defines the portions around which the vertical deflection coils 7 are wound, and although not shown in the drawings, compensating means for compensating, for example, convergence or the like, are located on the lower surface of the coil separator 6. in parts where no vertical deflection coils are wound. In this way, no interference occurs by connecting both sides of the ferrite core to the circumferential outer surface of the coil separator 6 to form the ferrite core 8.

The procedure for assembling the deflection system of the present invention, the construction of which is described above, will be described in more detail below.

First, the two symmetrically arranged left and right sides of the coil separator are assembled to form the coil separator 6, and then horizontal deflection coils 5 are arranged on the circumferential inner surface of the coil separator 6.

In this position, the two halves of the ferrite core, about which the vertical deflection coils 7 are wound, are disposed on the circumferential outer surface of the coil separator 6, forming the final ferrite core 8.

At present, when the ferrite core 8 is connected to the coil separator 6, a plurality of elastic

Elements 14 14 elastically support the ferrite core 8 by tilting it upwards so that the ferrite core 8 is firmly attached to the circular outer surface of the coil separator 6 without any fluctuation.

As the elastic force guides the ferrite core 8 up through its plurality of elastic members 14 during its connection to the coil separator 6, the ferrite core 8 is protected from fluctuation by the circumferential outer surface of the coil separator 6.

Thus, it is possible to avoid deflection of the assembly dispersion due to fluctuation of the ferrite core 8 during assembly, and therefore the axial balance of the vertical deflection coils 7 may be constant, thereby improving the image dispersion, i.e. image distortion is avoided.

The axial balance of the ferrite core 8 and the vertical deflection coils 7, which are wound around the ferrite core 8, are constant on the inner surface of the screen of the coil separator 6 and directed to the underside of the ferrite core 8 by a plurality of elastic members 14.

Thus, without having to separately attach a plurality of elastic ribs to the circumferential surface of the coil separator 6 to maintain axial balance, the amount of components is reduced, thereby reducing production costs and increasing productivity.

In addition, improved dispersion of capture avoids image distortion, which increases the reliability of the deflection system.

A third embodiment of a deflection system will be described with reference to Figs. 20-24.

This embodiment of the invention is intended to prevent the ferrite core 8 from fluctuating not only in its direction of connection but also in the direction perpendicular to its direction of connection to the coil separator 6.

As shown in the drawings, the deflection system 1 according to this embodiment of the invention consists of a coil separator 6, a ferrite core 8 and first and second anti-fluctuating means.

The coil separator 6 consists of a neck and a screen. The first and second deflection coils 5 and 7 for deflecting the electronic beams in the horizontal and vertical directions are arranged on the circumferential inner and outer surfaces of the coil separator 6, respectively.

The horizontal deflection coils 5, which direct the electronic beams in the horizontal direction, can be used as deflection coils arranged on the circumferential inner surface of the coil separator 6. Conversely, the vertical deflection coils 7, which direct the electronic beams in the vertical direction, can also be used as deflection coils in the circumferential inner surface of the coil separator 6,

The case in which the first deflection coils arranged on the circumferential inner surface of the coil separator 6 are used as horizontal deflection coils 5 for directing the electronic beams in the horizontal direction will be described in more detail below.

The ferrite core 8 is mounted on the circumferential outer surface of the coil separator 6 and is made of magnetic material for vertical deflection coils 7 for reinforcing the magnetic fields.

The first anti-fluctuation means are arranged on the circumferential outer surface of the coil separator 6 and are intended to prevent the ferrite core 8 from fluctuating in the direction of its connection.

A plurality of anti-fluctuation measures are disposed on the circumferential outer surface of the coil separator 6 and are directed respectively to the portions of the ferrite core 8 around which the vertical deflection coils 7 are wound.

The anti-fluctuation means are a plurality of elastic protrusions 15 formed together with the circumferential outer surface of the coil separator 6, acting on the ferrite core 8 in an elastic force in the opposite direction of its connection direction,

A plurality of elastic projections 15 are disposed in two or more positions on the circumferential outer surface of the spool separator 6. Preferably, the plurality of elastic protrusions of each pair have one elastic protrusion arranged symmetrically at the same angle relative to the other.

The plurality of elastic protrusions 15 are formed by at least one pair of left and right elastic protrusions 16 and 17 which are disposed symmetrically to one another on the circumferential outer surface of the coil separator 6.

Since the plurality of elastic protrusions 15 are formed by at least one pair of left and right elastic protrusions 16 and 17, they are arranged symmetrically opposite to each other in that two ferrite cores are connected to a circumferential outer surface of the coil separator 6, both ferrite cores symmetrical to each other. . In this way, no interference occurs by connecting both sides of the ferrite core to the circumferential outer surface of the coil separator 6 to form the ferrite core 8.

In addition, the left and right elastic projections 16 and 17 of at least one pair are disposed on the left and right sides of the connecting surface of the two sides of the coil separator, the brine of which is finally formed by the coil separator 6, respectively.

This is due to the necessity to reduce the amount of casting variations by varying the left and right sides of the coil separator, bearing in mind that the plurality of elastic protrusions 15, e.g. at least one pair of left and right elastic protrusions 16 and 17 being molded together with the two sides of the coil separator respectively.

On the other hand, a plurality of elastic protrusions 15, as shown in FIG. 20, are arranged vertically in two or more positions at the center of the spool separator 6, and each pair of elastic protrusions are arranged symmetrically with respect to each other.

However, the plurality of positions of the plurality of elastic protrusions 15 is not limited to the examples described above, but as shown by the dashed lines in FIG. 21, the plurality of elastic protrusions 15 may be positioned vertically on top and bottom of the spool separator 6.

In other words, a plurality of elastic protrusions 15 are positioned at appropriate positions to accommodate the size of the deflection system and so on.

Furthermore, as shown by the dashed lines in FIG. 20, it is desirable that the widths of the elastic protrusions 15 be different in the upper and lower portions of the spool separator 6.

This is due to the fact that the upper and lower parts of the coil separator 6 have different curves. Therefore, the elastic protrusions 15 disposed adjacent to the screen of the spool separator 6 must also be wider than the elastic protrusions 15 disposed adjacent the neck of the spool separator 6.

The second anti-fluctuation means for protecting the ferrite core 8 from fluctuating in a direction perpendicular to its attachment direction are located on the inner surface of the screen of the coil separator 6 to resiliently maintain the ferrite core 8 by providing an upward direction perpendicular to its attachment direction.

The second anti-fluctuation means comprises a plurality of elastic members 18 formed in conjunction with the inner surface of the screen of the coil separator 6.

A plurality of elastic members 18 are disposed on the inner surface of the screen of the coil separator 6 so that they are directed to the vertical deflection coils 7 wrapped around the ferrite core 8 and are intended to contact the vertical deflection coils.

7th

The plurality of elastic members 18 are, as shown in Fig. 20, disposed on the inner surface of the screen of the coil separator 6 in a circumferential direction such that they have the same curvature.

However, the positioning positions of the plurality of elastic members 18 are not limited only to those mentioned above, but as shown in Figures 23 and 24, the plurality of elastic members 18 may be directed radially or from the inner surface of the screen of the coil separator 6.

On the other hand, when the plurality of elastic members 18 are arranged in a circumferential direction as shown in FIG. 22, they are preferably disposed on the inner surface of the screen of the coil separator 6 so as to intersect the joining surface between the two sides of the coil separator.

This is necessary because the coupling surface of the coil separator 6 practically defines the parts around which the vertical deflection coils 7 are wound and, although not shown, compensating means for compensating, for example, convergence or the like, are located at the lower surface of the coil separator 6. Thus, there is no interference by connecting the two sides of the ferrite core to the circumferential outer surface of the coil separator 6 and finally forming the ferrite core 8.

The procedure for assembling the deflection system of the present invention, the construction of which is described above, will be described in more detail below.

First, the two symmetrically arranged coil separator halves are assembled to form the coil separator 6, and then the horizontal deflection coil 5 is disposed on the circumferential inner surface of the coil separator 6.

In this position, the two halves of the ferrite core, about which the vertical deflection coils 7 are wound, are disposed on the circumferential outer surface of the coil separator 6, forming the final ferrite core 8.

By attaching the ferrite core 8 to the coil separator 6, a plurality of elastic protrusions 15 disposed on the circumferential outer surface of the coil separator 6 as first means of anti-fluctuation elastically support the ferrite core 8 by providing an outward displacement, on the inner surface as a second anti-fluctuation means, resiliently supports the ferrite core 8, giving it an upward direction perpendicular to its direction of engagement with the coil separator 6. In this way, the ferrite core 8 is securely and elastically attached to the circumferential outer surface of the coil separator 6 without any fluctuation beyond the direction of the joint; but also perpendicular to its direction of connection.

In other words, since the elastic force created by the plurality of elastic protrusions 15 and the plurality of elastic members 18 pushes the ferrite core 8 outward and upward during its attachment to the coil separator 6, the ferrite core 8 is protected against fluctuation up and down outward and inward, ie in the direction of its attachment and in a direction perpendicular to its direction of attachment.

Thus, it is possible to avoid assembly deflection due to flocculation of the ferrite core during its attachment to the coil separator 6, and therefore the axial balance of the vertical deflection coils 7 may be constant, and thus the image dispersion can be improved, i.e. image distortion can be avoided.

Since a plurality of elastic projections 15 and a plurality of elastic members 18 are disposed on the circumferential outer surface of the coil separator 6 and the inner surface of the screen of the coil separator 6, respectively, so as to face portions of the ferrite core 8 wrapped around the vertical deflection coils the sheaths of the vertical deflection coils 7 from being damaged during the connection of the ferrite core 8 to the coil separator 6, and also during the short circuit.

In the deflation system of the present invention described above, the first and second anti-fluctuation measures, i.e. the axial balance of a plurality of elastic projections 15 and a plurality of elastic members 18 spaced symmetrically to each other on the circumferential outer surface of the coil separator 6 and the inner surface of the coil separator 6, respectively, of ferrite core 8 and vertical deflection coils 7

Consequently, it is not necessary to individually attach a plurality of elastic ribs to the circumferential surface of the coil separator 6 to maintain axial balance, thereby reducing the number of components, thereby reducing production costs and increasing productivity.

In addition, improved dispersion dispersion, etc., avoids image distortion and thereby increases the reliability of the deflection system.

While the embodiments described above have been illustrated with reference to a saddle-toroidal deflection system, the invention is not limited to this type of deflection system. One skilled in the art will readily appreciate that the invention can also be applied to a saddle-to-saddle deflection system.

The drawings illustrate typical preferred embodiments of the invention, specific terms being used for general and descriptive purposes only, and not by way of limitation, and the scope of the invention is defined by the following definition.

Claims (10)

DEFINITION OF INVENTION 1. A deflation system consisting of: a coil separator having a neck and a screen insulating the first and second deflection coils arranged on the circumferential outer or inner surfaces of the coil separator, deflecting the electronic beams in the vertical and horizontal directions, respectively: ferrite cores mounted on the circumferential outer surface of the coil separator materials for strengthening magnetic fields; characterized in that it has anti-fluctuation means located on the circumferential outer surface of the coil separator in two or more positions which protect the ferrite core from fluctuation in the direction of attachment. 2. Deflection system according to claim 1, characterized in that the anti-fluctuation means are disposed on the circumferential outer surface of the coil separator so that they are directed towards the portions of the ferrite core on which the vertical deflection coils are wound. 3. Deflection system according to claim 1 or 2, characterized in that the anti-fluctuation means comprises a plurality of elastic protrusions formed in conjunction with the circumferential outer surface of the coil separator acting on the ferrite core in an elastic force opposite to the ferrite core connection direction. 4. Deflection system according to claim 3, characterized in that the plurality of elastic protrusions comprises at least one pair of left and right elastic protrusions arranged symmetrically with respect to each other on the circumferential outer surface of the spool separator. 5. Deflection system according to claim 4, characterized in that at least one pair of left and right elastic protrusions are disposed on the left and right sides of the connection surface of the two coil separators, respectively. I sides. 6. Deflection system according to claim 4, characterized in that at least one pair of left and right elastic protrusions is arranged in the middle of the spool separator in a vertical direction. 7. Deflection system according to claim 4, characterized in that at least two pairs of left and right elastic protrusions are arranged in the upper and lower parts of the spool separator respectively in the vertical direction. 8. The deflection system of claim 7, wherein the elastic protrusions disposed adjacent to the reel separator screen are wider than the elastic protrusions disposed adjacent to the reel separator neck. 9. The deflection system of claim 1, wherein the first deflection coils disposed on the circumferential outer surface of the coil separator are vertical deflection coils for directing electronic beams in a vertical direction. 10. The deflection system of claim 1, wherein the second deflection coils disposed on the circumferential inner surface of the coil separator are horizontal deflection coils for directing electronic beams in a horizontal direction: