KR20020036587A - Deflection yoke for cathode ray tube - Google Patents

Abstract

PURPOSE: A deflection yoke of a cathode ray tube is provided to avoid reduction of landing correction due to an element and improve work efficiency of ITC(integrated tube components). CONSTITUTION: A deflection yoke of a cathode ray tube comprises a separator(6), a horizontal and a vertical deflection coils(10), a core(12), a cross arm(14), and many magnets. The separator(6) is mounted on outer boundary of a funnel(4). The horizontal and the vertical deflection coils(10) are mounted on the outside surface and the inside surface of the separator(6). The core(12) is mounted on the outside of the vertical deflection coil(10). The cross arm(14) is mounted at an aperture of the separator(6). The magnets are mounted on the separator(6). The cross arm(14) forms pin cushion type magnetic field between two extended lines(14b) so as to correct horizontal pin cushion linear distortion due to Barrel type vertical magnetic field.

Description

Deflection yoke for cathode ray tube}

The present invention relates to a deflection yoke for a cathode ray tube, and more particularly, a landing correction magnet is provided at a predetermined portion of a separator to prevent a reduction in landing correction amount caused by an element and to improve ITC working efficiency. It relates to a deflection yoke for a cathode ray tube.

In general, a cathode ray tube emits a fluorescent screen by using an electron beam emitted from an electron gun to display a predetermined screen. The three-stem electron beam emitted by an electron gun is deflected by a magnetic field in which a deflection yoke is generated, and thus a raster is placed on a fluorescent screen. While forming the raster, the R, G, and B fluorescent films are separated by the shadow mask to realize accurate colors and screens.

Here, the work to adjust the color purity and convergence of the electron beam by mounting the deflection yoke and the CPM in the tube completed through the cathode ray tube manufacturing process is called ITC (Integrated Tube Components). Since the path is influenced by external factors such as the geomagnetic field, it is possible to use a method of locally correcting the landing change of the electron beam by installing a landing correction magnet.

7 is a partial cutaway cross-sectional view of a cathode ray tube according to the prior art, and FIG. 8 is a cross-sectional view of the AA line of FIG. 7, wherein the deflection yoke 1 is mounted on the outer peripheral surface of the funnel 3 and deflects horizontally and vertically on the path of the electron beam 5. A magnetic field is generated to deflect the electron beam 5 passing through the bar. In the drawing, a cross arm type having a CROSS (Cold Rolled Silicon Steel) arm 7 attached to one opening facing the screen part is shown. It was.

The cross arm type deflection yoke 1 is effective for correcting the pincushion type distortion in the east-west direction by the barrel type vertical deflection magnetic field using the leakage magnetic field of the vertical deflection magnetic field, and the cross arm type deflection yoke 1 is provided. In this case, the landing correction magnet 9 is integrally attached to the outer peripheral surface of the funnel 3 as shown.

The landing correction magnet 9 is mainly attached to four diagonal portions of the funnel 3 one by one, and changes the magnetic field distribution around the N pole and S pole components thereof to compensate for the landing of the electron beam. The correction magnet 9 is integrally attached to the outer circumferential surface of the funnel 3 facing the inner shield 11.

However, when the landing correction magnet 9 is fixed at the position, a problem arises in that the landing correction amount of the electron beam by the magnet 9 after the element decreases due to the magnetic properties of the inner shield 11.

That is, when a magnetic material such as an inner shield 11, a shadow mask 13, and a mask frame 15 is built in the cathode ray tube and the electron distribution in the magnetic material is not constant or the magnetic domain is biased, This causes the electron beam path to be changed, resulting in poor purity and convergence.

As a result, an alternating magnetic field is generated by using an element coil (not shown) installed in the tube before the ITC operation, thereby degaussing a process of dispersing the electron distribution and magnetic domain state in each magnetic body to remove the uncomfortable magnetic field.

Therefore, since the magnetization component of the inner shield 11 is changed in the above-described device process, the influence of the landing correction magnet 9 on the electron beam 5 is reduced, thereby reducing the amount of landing correction of the electron beam, thereby reducing ITC work efficiency. Problem occurs.

Therefore, the present invention is designed to solve the above problems, an object of the present invention is to install a landing correction magnet in the separator does not affect the magnetic shielding function of the inner shield to prevent the reduction of landing correction amount by the device, ITC operation It is to provide a deflection yoke for a cathode ray tube to improve the efficiency.

Another object of the present invention is to provide a deflection yoke for a cathode ray tube that provides a special structure for mounting a landing correction magnet to the separator and the cross arm, thereby preventing the landing correction magnet from being separated and generating noise due to flow.

1 and 2 are front and left side views of the deflection yoke according to the present invention, respectively.

3 is a right side view of the deflection yoke, optionally showing a cross arm.

4 is a schematic diagram of a magnetic field distribution in which cross arms occur.

5 is a partial cutaway sectional view of a cathode ray tube equipped with a deflection yoke according to the present invention;

Fig. 6A is an exploded perspective view of a magnet mounting portion for landing correction.

6B is a sectional view of the landing correction magnet in a fixed state;

7 is a partial cutaway sectional view of a cathode ray tube according to the prior art;

8 is a cross-sectional view taken along a line A-A of FIG. 7.

In order to achieve the above object, the present invention,

A separator mounted on the outer circumferential surface of the funnel,

Horizontal and vertical deflection coils disposed inside and outside the separator, respectively, to generate horizontal and vertical deflection magnetic fields to deflect the electron beam;

A cross arm which is provided in one opening of the separator facing the screen part and forms an extension part with four diagonal parts of the separator to absorb and discharge the vertical leakage magnetic field,

Provided is a deflection yoke for a cathode ray tube including a plurality of landing correction magnets that are integrally mounted to a portion where the cross arm and the separator face each other.

Thus, the present invention has an advantage that the change in the magnetization state of the inner shield by the device does not affect the magnetic field generated by the landing correction magnet, so that the landing correction amount by the landing correction magnet can be maintained even after the device.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are respectively a front view and a left side view of the deflection yoke according to the present embodiment, and Fig. 3 is a right side view selectively showing only a cross arm mounted on the deflection yoke.

As shown, the deflection yoke 2 is perpendicular to the separator 6 mounted on the outer circumferential surface of the funnel 4, and to the horizontal and vertical deflection coils 8 and 10 respectively provided inside and outside the separator 6, respectively. Ferrite core 12 fixed to the outer side of the deflection coil 10, the cross arm 14 provided in the one side opening part of the separator 6 facing the screen part, and the separator 6 which contact | connects the cross arm 14 It consists of a plurality of landing correction magnet (16) fixed to a predetermined portion of.

The horizontal deflection coil 8 forms a pincushion type magnetic field in the vertical direction on the electron beam path to deflect the electron beam in the horizontal direction, and the vertical deflection coil 10 forms a barrel type magnetic field in the horizontal direction on the electron beam path to form the electron beam. To deflect in the vertical direction.

The ferrite core 12 is connected so that the magnetic flux directions generated from the respective coils are reversed to each other in the magnetic path to improve magnetic efficiency generated at each coil, and the opposite side of the separator 6 facing the neck portion 18. The opening is provided with a color-purifying magnet assembly 20 composed of a pair of two-pole, four-pole and six-pole magnets to serve to match and concentrate the electron beam emitted from the electron gun in one place.

The CROSS (Cold Rolled Silicon Steel) arm 14 which absorbs and discharges the vertical leakage magnetic field has a main body portion 14a fitted to the outside of the separator 6 and a separator at the main body portion 14a. (6) Consists of extension portions 14b extending into four diagonal portions, and the silicon steel sheet constituting the cross arm 14 is characterized by high permeability and low residual magnetization.

Thus, as shown in FIG. 4, the cross arm 14 forms a pincushion type magnetic field shown by a dotted line between the pair of extension portions 14b facing in the horizontal direction to vertically up and down the electron beam path. Weakens the magnetic field Accordingly, the pincushion distortion of the screen in the east-west direction of the screen is corrected by the barrel-type vertical magnetic field to straighten the left and right ends of the screen.

In addition, the landing correction magnet 16 is a kind of bar magnet, and locally corrects the landing of the electron beam by deflecting the electron beam passing through the magnetic field in a specific direction due to the magnetic field generation. It may be made of a magnetic material or a soft magnetic material having a high permeability, or may be made of an iron-based alloy containing 28% by weight of nickel and 18% by weight of aluminum.

At this time, the deflection yoke 2 according to the present embodiment lands at a predetermined position of the separator 6 to which the cross arm 14 is attached so that the magnetic field emitted from the landing correction magnet 16 does not interfere with the inner shield. It provides a structure in which the correction magnet 16 is mounted.

That is, as shown in Figure 5, the deflection yoke (2) is mounted on the outer peripheral surface of the funnel (4) and located behind the inner shield 24 relative to the face panel 22, the magnetic shield function of the inner shield 24 Since the deflection yoke 2 is not affected, by fixing the landing correction magnet 16 to the separator 6, mutual interference between the landing correction magnet 16 and the inner shield 24 can be prevented.

To this end, this embodiment provides a special structure for mounting the landing correction magnet 16 to the contact portion of the cross arm 14 and the separator 6, Figure 6a is an exploded perspective view of the magnet mounting portion for landing correction, Figure 6b Is a cross-sectional view in a fixed state, for example, a bent portion 14c between the main body portion 14a and the extended portion 14b of the cross arm, and landing on one side of the separator 6 facing the bent portion 14c. By providing a structure for mounting the correction magnet 16, it is possible to integrally fix the landing correction magnet 16 to it.

More specifically, the bent portion 14c of the cross arm has a through hole 14d formed therein corresponding to the shape of the landing correction magnet 16, and the separator 6 facing the bent portion 14c. On one side of the fixing groove (6a) for fixing the landing magnet 16 for correction is formed.

Thus, in the deflection yoke fabrication process, the cross arm 14 is provided outside the separator 6 so that the through hole 14d formed in the bent portion 14c of the cross arm and the fixing groove 6a formed in the separator 6 coincide with each other. In addition, the landing correction magnet 16 may be inserted into the fixing groove 6a of the separator 6 through the through hole 14d and may be integrally mounted to the deflection yoke 2.

At this time, in order to prevent the landing correction magnet 16 from being separated from the separator 6, the landing correction magnet 16 is fixed with an adhesive, or the bend portion of the landing correction magnet 16 surface and the cross arm. (14c) attaching an adhesive tape (not shown) between the surfaces or properly adjusting the dimensions of the fixing groove 6a and the magnet so that the landing correction magnet 16 can be forcibly fitted in the fixing groove 6a. It is preferable.

Accordingly, the landing correction magnet 16 may be firmly attached to the separator 6, thereby preventing noise from being separated by the flow of the landing correction magnet 16 while preventing the separation from the separator 6.

Thus, this embodiment including the landing correction magnet 16 at the contact portion of the cross arm 14 and the separator 6 provides a structure for mounting the magnet at the portion where the landing correction of the electron beam is required, and landing there. The magnets for correction 16 are integrally attached. For example, four magnets for landing correction are provided as shown in FIG. 3, and the 45 °, 135 °, and 225 ° of the cross arms around the tube axis of the cathode ray tube are provided. And 315 ° positions, respectively.

Each landing correction magnet 16 has a magnetic pole position determined according to a direction of a magnetic field previously calculated to apply a force to a traveling electron beam in a specific direction, and accordingly, the funnel is generated by a magnetic field generated by the landing correction magnet 16. (4) The path of the electron beam passing through the inside is changed to locally correct the landing of the electron beam.

Thus, in this embodiment, the landing correction magnet 16 is connected to the inner shield 24 by attaching the landing correction magnet 16 to the portion of the separator 6 where the magnetic shielding function of the inner shield 24 is not affected. The landing of the electron beam can be corrected by itself without effect.

Therefore, since the change in the magnetization state of the inner shield 24 by the device does not affect the magnetic field generated by the landing correction magnet 16, the landing correction amount of the electron beam by the landing correction magnet 16 can be maintained even after the device. Has an advantage.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

As described above, the present invention allows the landing correction magnet to correct the landing of the electron beam by attaching the landing correction magnet to the separator portion where the magnetic shielding function of the inner shield is not affected. As a result, the change in the magnetization state of the inner shield by the device does not affect the magnetic field of the landing correction magnet, so that the landing correction amount of the electron beam by the landing correction magnet can be maintained even after the device, thereby improving ITC working efficiency. .

Claims (5)

A separator mounted to an outer circumferential surface of the funnel; Horizontal and vertical deflection coils disposed inside and outside the separator, respectively, to generate horizontal and vertical deflection magnetic fields to deflect the electron beam; A cross arm provided in one opening of the separator facing the screen unit, the extension arm being formed at four diagonal portions of the separator to absorb and discharge the vertical leakage magnetic field; A deflection yoke for a cathode ray tube including a plurality of landing correction magnets that are integrally mounted to a portion where the cross arm and the separator face each other. The method of claim 1, The landing yoke deflection yoke is fixed to the bent portion between the main body portion and the extension portion of the cross arm and the separator facing the bent portion. The method of claim 2, A deflection yoke for cathode ray tubes, wherein a through hole for penetrating the magnet is formed in correspondence with the landing correction magnet shape at the bent portion of the cross arm. The method of claim 2, A deflection yoke for a cathode ray tube having a fixing groove for fixing the magnet corresponding to a landing correction magnet shape in a separator facing the bent portion. The method of claim 1, And said landing correction magnet is fixed to 45 °, 135 °, 225 ° and 315 ° positions of the cross arm about the tube axis of the cathode ray tube respectively.