KR20050076361A - Deflection yoke and method for winding v-coil - Google Patents

Abstract

Disclosed are a deflection yoke and a vertical deflection coil winding method capable of improving screen characteristics by maximizing E / W quality characteristics and C / G characteristics. The disclosed deflection yoke includes a coil separator having a screen portion and a neck portion; A ferrite core installed on an outer circumferential surface of the coil separator to form a magnetic field; A vertical deflection coil wound around the ferrite core, part of which is wound by applying an inclination winding and at the other part of which is wound without applying an inclination winding; And a horizontal deflection coil provided on an inner circumferential surface of the coil separator.

Description

Deflection yoke and winding method of vertical deflection coil {DEFLECTION YOKE AND METHOD FOR WINDING V-COIL}

The present invention relates to a deflection yoke and a vertical deflection coil winding method, and more particularly, to a deflection yoke and a vertical deflection coil winding method capable of improving screen characteristics by maximizing E / W quality characteristics and C / G characteristics. .

In general, cathode ray tubes (CRTs) used in TV receivers or monitors are provided with deflection yokes to precisely deflect the three-color beams scanned from the electron gun to the fluorescent film applied to the screen surface of the cathode ray tubes. One of the most important elements of the cathode ray tube magnetic device is to deflect an electron beam emitted from an electron gun so that an electrical signal transmitted in time series can be reproduced as an image on the cathode ray tube screen.

That is, since the electron beam emitted from the electron gun goes straight onto the screen by the high voltage, only the central phosphor of the screen emits light, so the deflection yoke is deflected to reach the screen in the order of scanning from the outside. The yoke forms a magnetic field so that the electron beam is precisely deflected to the fluorescent film coated on the screen of the cathode ray tube by using a force that is changed when the electron beam passes through the magnetic field and its traveling direction is changed.

FIG. 1 is a view schematically showing a conventional deflection yoke 101. As shown therein, the deflection yoke 101 is located in the RGB electron gun of the cathode ray tube 102 and screens an electron beam scanned from the electron gun 103. As shown in FIG. It is deflected by the fluorescent film applied to the surface.

The deflection yoke 101 is made up of a pair of coil separators 113 which are largely symmetrical and combined into one.

The coil separator 113 is provided to insulate the horizontal deflection coil 113a and the vertical deflection coil 113b and to assemble their positions to a sufficient degree, and is coupled to the screen surface side of the cathode ray tube 102. A neck 111 is formed from the cover 111, the rear cover 112, and the center surface of the rear cover 112, and is coupled to the electron gun 103 of the cathode ray tube 102. However, the front cover 111 and the rear cover 112 may be integrally connected to the coil separator 113, and this phenomenon is more likely to occur in large sized deflection yokes.

The inner and outer circumferential surfaces of the coil separator 113 are provided with horizontal deflection coils 113a and vertical deflection coils 113b for forming a horizontal deflection magnetic field and a vertical deflection magnetic field by power applied from the outside.

A pair of ferrite cores 114 are formed of a magnetic material to be mounted to surround the vertical deflection coil 113b and to reinforce the vertical deflection magnetic field generated by the vertical deflection coil 113b.

The deflection yoke 101 configured as described above is mounted on the neck portion of the cathode ray tube 102, and when a sawtooth pulse is applied to the horizontal deflection coil 113a and the vertical deflection coil 113b, a magnetic field is generated based on Fleming's left hand law. The red (R), green (G), and blue (B) electron beams emitted from the electron gun 103 of the CRT are deflected by a predetermined angle to determine dice on the screen.

On the other hand, the deflection yoke is roughly divided into a saddle-saddle type and a saddle-toroidal type according to the winding structure of the coil. In the present invention, the saddle-toroidal type will be described for convenience.

The general saddle-toroidal deflection yoke has a horizontal deflection coil 113a installed on the upper and lower inner circumferential surfaces of the substantially conical coil separator 113 and a ferrite core 114 having a substantially cylindrical shape on the outer circumferential surface thereof. A vertical deflection coil 113b is wound along the upper and lower sides of the vertical deflection coil 113b.

In addition, a coma precoil 115 is further provided around the neck outer periphery of the coil separator 113 to correct a coma generated by the vertical deflection coil 113b.

However, in the conventional conventional deflection yoke as described above, a problem occurs in that distortion on the screen, that is, deterioration occurs, which is mainly due to unevenness of coil turns and distribution of the vertical deflection coil wound around the horizontal deflection coil and the ferrite core. This is due to the coil's inductance (L) and resistance (R) values, which causes geometric distortion (G / D) such as N / S distortion, E / W distortion, and convergence (C / G). Will result.

2A is a perspective view illustrating a ferrite core of a conventional toroidal deflection yoke, and FIG. 2B is a perspective view of a ferrite core to which a conventional inclination winding is applied, and is generally a vertical deflection coil ( When winding 11), as shown in FIG. 2A, the vertical deflection coil 11 is uniformly wound in proportion to the vertically extended angle of the ferrite core 10.

However, the ferrite core 10 winding the coil 11 as described above has a problem such that E / W correction is not easy and miss convergence occurs. In the related art, the amount of E / W correction is induced by inducing a barrel magnetic field in the neck portion. As shown in FIG. 2B, the inclination winding is applied when the vertical deflection coil 21 is wound on the ferrite core 20 to maximize the induction and maximize the convergence (C / G) characteristics.

When the coil is wound, the coil 21 is wound so as to be opposite to the vertically extended angle of the ferrite core 10 when the coil 21 is wound on the ferrite core 20, that is, the coil spacing of the neck portion is wider than that of the screen portion. It means winding by twisting the angle of (21) slightly.

FIG. 3 is a front view schematically showing a ferrite core wound with a conventional vertical deflection coil, and is a schematic view for explaining an inclination winding. For reference, in FIG. 3, the screen portion of the ferrite core 20 is placed on the upper portion and the neck portion is placed on the lower portion.

In general, when winding the vertical deflection coil 21 to the ferrite core 20, winding from one side of the ferrite core 20 to the other side in the order of 1 → 2 → 3 → 4 in FIG. 3, the coil spacing a of the center neck portion of the ferrite core 20 is wider than the coil spacing b of the screen portion side.

When the inclination winding is applied in this way, the neck portion coil spacing (a) is widened, thereby inducing a barrel magnetic field in the neck portion to maximize the amount of E / W correction.

4A is a perspective view showing a general vertical deflection coil winding apparatus, in which no inclination winding is applied, and FIG. 4B is a perspective view showing a general vertical deflection coil winding apparatus in which a inclination winding is applied.

As shown in the figure, the vertical deflection coil winding device holds the ferrite core 10 on which the coil 11 is wound upright with the jig 12 standing vertically so that the screen portion is upward, while winding the coil 11 thereon. do.

In this case, when the inclination winding is applied, the jig 12 and the ferrite core 10 may be erected at an angle to each other, and the coil 11 may be wound thereon to wind the coil to which the inclination winding is applied.

However, the ferrite core 20 to which the conventional inclination winding is applied can maximize the amount of E / W correction, but since the TRI is induced to 'positive', the reversal characteristics in S2V and S3V tend to be deteriorated in large models.

TRI is the sum of XH and YH minus the V pin / barrel value at the corner.When TRI is guided positively, the screen quality deteriorates, and S2V is the center point of each small square when the monitor is divided into four. S3V refers to the center point of the right end of each small square when the monitor is divided into four. In the case of the ferrite core 20 to which the conventional inclination winding is applied, the inversion of the R and B beams has a positive value at the horizontal end. Deterioration of the characteristics requires convergence correction.

Therefore, the ferrite core to which the conventional warp winding is applied can maximize the amount of E / W correction, but since the TRI is induced to 'positive', the reversal characteristic tends to deteriorate in large models, and a solution for this has been required.

An object of the present invention is to provide a deflection yoke that can improve the quality of the screen by improving the screen characteristics can be maximized while at the same time maximizing the amount of E / W correction while solving the above problems. .

The above object of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

In order to achieve the above object, the present invention provides a coil separator having a screen portion and a neck portion; A ferrite core installed on an outer circumferential surface of the coil separator to form a magnetic field; A vertical deflection coil wound around the ferrite core, part of which is wound by applying an inclination winding and at the other part of which is wound without applying an inclination winding; And a horizontal deflection coil provided on an inner circumferential surface of the coil separator.

Here, the vertical deflection coil is wound by applying an inclination winding to the center of the ferrite core, it is characterized in that the winding is not applied to both edges.

In addition, the vertical deflection coil is wound in multiple layers on the ferrite core, one layer is wound by applying a warp winding, and one of the layers is wound without applying a warp winding and selectively repeating the above process. It is also possible.

Here, the ratio of the layer winding by applying the inclination winding and the layer winding without applying the inclination winding is characterized in that the ratio of 8: 2.

In addition, as a vertical deflection coil winding method for achieving the above object, in the process of winding a vertical deflection coil on a ferrite core installed for forming a magnetic field on the outer circumferential surface of the coil separator, the winding edge of one side of the ferrite core is inclined. A first step of winding without applying; A second step of winding by applying an inclined winding to a central portion of the ferrite core; There is provided a vertical deflection coil winding method comprising a third step of winding without applying an inclined winding to the other edge of the ferrite core.

In addition, as a vertical deflection coil winding method for achieving the above object, in the process of winding the vertical deflection coil in a multi-layer on the ferrite core installed for forming a magnetic field on the outer peripheral surface of the coil separator, the winding winding on the ferrite core A first step of winding by applying; A second step of winding the ferrite core without applying a warp winding after the first step; A third step of winding the ferrite core by applying a warp winding after the second step; And winding the multilayer vertical deflection coil by selectively repeating the first to third steps.

Hereinafter, the deflection yoke and the vertical deflection coil winding method of the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

The deflection yoke of the present invention includes a coil separator having a screen portion and a neck portion, a ferrite core provided for forming a magnetic field on an outer circumferential surface of the coil separator, a vertical deflection coil wound around the ferrite core, and an inner circumferential surface of the coil separator. It is configured to include a horizontal deflection coil is provided, the part of the vertical deflection coil wound on the ferrite core is characterized in that the winding while applying the inclination winding and the other part is wound without applying the inclination winding.

Since some of the vertical deflection coils of the present invention are wound by applying a slope winding, the E / W characteristics are maximized, and the screen is induced by inversion characteristics and inverse TRI due to the portion that does not apply the slope winding of the vertical deflection coil. To improve.

5 is a front view schematically showing an embodiment of a ferrite core wound with a vertical deflection coil according to the present invention, and includes a ferrite core 30 used in a saddle-toroidal type deflection yoke. , Shows a vertical deflection coil 31 wound thereon.

For reference, in FIG. 5, the screen portion of the ferrite core 30 is placed on the upper side and the neck portion is placed on the lower side. As shown in the drawing, one embodiment of the present invention has a vertical deflection coil ( 31), in the winding of the ferrite core 30 is applied to the inclined winding in the center of the coil spacing (a) of the neck portion is wound wider than the coil spacing (b) of the screen portion, the inclined winding on both edges Winding without application.

That is, the neck portion of the ferrite core 30 is wound opposite to the direction in which the ferrite core 30 extends by widening the neck portion coil spacing a and widening the screen portion coil spacing b. Both edges of 30) are wound without applying the inclination winding to narrow the coil spacing of part (c) and wide coil spacing of part (d) to induce reverse TRI to maximize the reversal characteristics.

Therefore, the present invention maximizes the amount of E / W correction by inducing a barrel magnetic field to the neck by applying the inclination winding in the coil winding of the center of the ferrite core 30, and inverting the winding by not winding the coil at both edges. Maximize E / W and reversal at the same time by improving characteristics and inducing reverse TRI.

The vertical deflection coil 31 is wound from one side of the ferrite core 30 to the other side and wound in the order of 1 → 2 → 3 → 4 in FIG.

First, after winding without applying the inclination winding to one side edge of the ferrite core 30, the jig and ferrite core 30 holding the core 30 in the vertical deflection coil winding device at an angle to an angle up thereon By winding the coil 31, the center portion of the ferrite core 30 is wound by applying an inclination winding.

Then, in the vertical deflection coil winding device, the jig holding the core 30 and the ferrite core 30 are erected vertically, and the coil 31 is wound thereon without applying an inclination winding to the other edge of the ferrite core 30. Winding in proportion to the vertically extended angle of the ferrite core 30.

6 is a perspective view showing an embodiment of a ferrite core wound with a vertical deflection coil of the present invention, wherein the vertical deflection coil 31 wound by the method as described above is wound in a V-shape at the center and has both edges. Is wound in proportion to the vertically extended angle of the ferrite core 30.

On the other hand, as another embodiment of the present invention, when winding the vertical deflection coil in a multi-layer on the ferrite core, one of the layers is applied to the winding winding the coil side of the neck portion wider than the screen portion side, Any one of the remaining layers may be wound without applying the warp windings, and by selectively repeating the above process, the layer to which the warp windings are applied and the layer to which the warp windings are not applied may be wound in multiple layers.

Here, it is preferable that the ratio of the layer wound by applying the tilt winding and the layer winding without applying the tilt winding is 8: 2, and the present invention is not limited thereto.

According to another embodiment of the present invention, in the process of winding a vertical deflection coil in a multilayered manner on a ferrite core installed for forming a magnetic field on the outer circumferential surface of the coil separator, the first step of winding by applying an inclination winding to the ferrite core and A second step of winding the ferrite core without applying a warp winding after the first step; and a third step of winding the ferrite core by applying the warp winding to the ferrite core after the second step and the first to third steps. Selectively repeat to wind a multi-layered vertical deflection coil.

The description above is directed to specific embodiments and, of course, the technical spirit of the present invention is not limited thereto, and unless the invention essentially changes the spirit of the present invention as defined in the claims, the preferred embodiments of the present invention described It will be apparent to those skilled in the art that various changes in embodiments can be made.

As described above, in the deflection yoke of the present invention, when the vertical deflection coil is wound on the ferrite core, part of the deflection yoke is wound by applying an inclination winding and at the same time, the remaining part is wound without applying the inclination winding. And screen characteristics may be improved by maximizing C / G characteristics.

In particular, it is possible to maximize the amount of E / W correction while at the same time maximizing both the inversion characteristics has the effect of improving the quality of large models by improving the screen characteristics.

1 is a schematic diagram of a conventional general cathode ray tube,

Figure 2a is a perspective view showing a ferrite core is not applied to the conventional warp winding,

Figure 2b is a perspective view showing a conventional ferrite core is applied to the inclined winding,

3 is a front view schematically showing a ferrite core wound with a conventional vertical deflection coil;

4A is a perspective view illustrating a general vertical deflection coil winding device, in which a slope winding is not applied;

Figure 4b is a perspective view showing a typical vertical deflection coil winding device, when the inclination winding is applied,

5 is a front view schematically showing an embodiment of a ferrite core wound with a vertical deflection coil of the present invention,

6 is a perspective view showing an embodiment of a ferrite core wound with a vertical deflection coil of the present invention.

♣ Explanation of symbols for main part of drawing ♣

30: ferrite core 31: vertical deflection coil

Claims (6)

A coil separator having a screen portion and a neck portion; A ferrite core installed on an outer circumferential surface of the coil separator to form a magnetic field; A vertical deflection coil wound around the ferrite core, part of which is wound by applying an inclination winding and at the other part of which is wound without applying an inclination winding; And Deflection yoke, characterized in that it comprises a horizontal deflection coil provided on the inner peripheral surface of the coil separator. The method of claim 1, The vertical deflection coil is wound by applying an inclination winding to the center of the ferrite core, and a deflection yoke is wound around both edges without applying the inclination winding. The method of claim 1, The vertical deflection coil is wound in multiple layers on the ferrite core, and one of the layers is wound by applying a warp winding, and one of the layers is wound without applying a warp winding and selectively repeating the above process. Deflection yoke characterized by. The method of claim 3, The deflection yoke, characterized in that the ratio of the layer winding by applying the inclination winding and the layer winding without applying the inclination winding is 8: 2. In the process of winding a vertical deflection coil on a ferrite core installed for forming a magnetic field on the outer circumferential surface of the coil separator, A first step of winding without applying an inclination winding to one edge of the ferrite core; A second step of winding by applying an inclined winding to a central portion of the ferrite core; And winding a third edge of the ferrite core without applying an inclination winding to the other edge of the ferrite core. In the process of winding a vertical deflection coil in multiple layers on a ferrite core installed to form a magnetic field on the outer peripheral surface of the coil separator, A first step of winding by applying a warp winding to the ferrite core; A second step of winding the ferrite core without applying a warp winding after the first step; A third step of winding the ferrite core by applying a warp winding after the second step; And And selectively repeating the first to third steps to wind a multi-layer vertical deflection coil.