KR200228980Y1 - Deflection yoke adjustment - Google Patents

Abstract

The present invention uses a servomotor to automatically move and rotate the deflection yoke mounted on the cathode ray tube to the left and right and up and down sides, so that the deflection yoke assembly work is accurate and the workability is improved. In particular, a pair of holders and a support for holding a deflection yoke fitted vertically in the upper portion of the base and fitted to the neck portion of the cathode ray tube at the rear of the frame, respectively, and each of the support in front of the frame A first servo motor having a pinion for rotating the deflection yoke by shifting the racks formed at the bottom of each other is provided, and is fastened to a nut formed at the lower portion of each support in front of the frame to elevate the respective support parts. A second servo motor having a screw for elevating and adjusting the deflection yoke is provided, and in front of the frame A third servo motor is provided to rotate each support part about a hinge part to allow the deflection yoke to flow left and right.

Description

Deflection yoke adjustment

The present invention relates to a control device for the deflection yoke, more specifically, the deflection yoke is mounted in the neck portion of the cathode ray tube, and then the deflection yoke is left and right in the process of adjusting the horizontal and vertical states of the R, G and B beams. The present invention relates to a device for adjusting the deflection yoke, by which the right side, the upper side, the lower side, and the rotation are automatically adjusted, thereby improving productivity.

In general, the deflection yoke is mounted on the cathode ray tube, and deflects the beam emitted from the electron gun to the left and right and up and down on the screen to scan the fluorescent surface. The deflection yoke should be mounted on the neck of the cathode ray tube in the manufactured state, and then inspect the gaps and distortions of the horizontal and vertical lines of R, G, and B, and fix it to the neck of the cathode ray tube with adhesives when there is no abnormality. do.

Conventionally, the deflection yoke is inserted into the neck portion of the cathode ray tube mounted on the mold, and then the gap is distorted and distorted between the horizontal and vertical lines of R, G, and B while the neck portion is flown and rotated. The magnetite was used to adjust the magnetic field of the required part of the deflection yoke to correct gaps and distortions. However, since the deflection yoke is flowed manually and the gap and distortion of the horizontal line and the vertical line are examined, workability is reduced and productivity is reduced.

The present invention is conceived in view of the conventional problems, the object of the present invention is to use the servo motor to automatically move and rotate the deflection yoke mounted on the cathode ray tube to the left and right and up and down, It is to provide a deflection yoke adjusting device which is accurate in assembly work and improves workability.

1 is a front view of the subject innovation adjusting device,

2 is a left side view of the subject innovation adjusting device,

3 is a right side view of the subject innovation adjusting device,

Figure 4 is a plan view of the subject innovation adjusting device.

<Description of the symbols for the main parts of the drawings>

10: base 11: frame

12: support 13: holder

14: 1st servo motor 15: pinion

16: rack 17: second servo motor

18: screw 19: nut

20: third servo motor 21: hinge part

22 cathode ray tube 23 neck portion

24: deflection yoke

In order to achieve the above object, the present invention is provided with a pair of holders and a support for holding a deflection yoke fitted in the neck portion of the cathode ray tube vertically placed on the upper portion of the base, respectively, the front of the frame The first servo motor having a pinion for rotating the deflection yoke by shifting the racks formed in the lower portion of each of the support to each other, is fastened to a nut formed in the lower portion of each of the support in front of the frame each support A second servo motor having a screw for elevating and adjusting the deflection yoke is provided, and a third servo motor for rotating the support yoke around the hinge part in front of the frame to allow the deflection yoke to flow left and right. It is equipped with features.

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

The frame 11 is vertically mounted on the base 10. A pair of support portions 12 are placed in the rear of the frame 11, and holders 13 corresponding to each other are provided on both sides of the upper ends of the support portions 12. The holder 13 serves to hold both sides of the deflection yoke 24, and the front of the frame 11 is provided with a first servo motor 14 for moving each support 12 up and down to cross each other. . In the first servo motor 14, a pinion 15 is formed at an end of the rotation shaft, and a rack 16 engaged with the pinion 15 is formed below each support 12.

In addition, a second servo motor 17 for simultaneously lifting and lowering each support 12 in front of the frame 11 is provided. When the second servo motor 17 is rotated, the screw 18 formed on the rotation shaft thereof is fastened to the nut part 19 connected to each support part 12. Accordingly, when the screw 18 is rotated, the support 12 is lifted through the nut 19, and at this time, the deflection yoke 24 is lifted and adjusted with respect to the neck 23 of the cathode ray tube 22 through the holder 13. do. In addition, the third servo motor 20 for rotating the deflection yoke 24 is provided in front of the frame 11. When the third servo motor 20 is rotated forward and backward, the holder 13 flows to the left and right about the hinge portion 21 formed at the lower center of the support 12, and the deflection yoke 24 is moved to the neck 23. The relative assembly position is adjusted while flowing to the left and right side slightly.

The present invention configured as described above uses a deflection yoke 24 by inserting the deflection yoke 24 into the neck portion 23 of the cathode ray tube 22 fixed to the frame and using the holders 13 formed at both ends of the pair of support portions 12. 24) Then, the first servo motor 14 is operated to reverse and rotate the pinion 15 formed on the rotation axis thereof, and the supporting members 12 are lifted so as to cross each other by the racks 16 engaged therewith and deflected in this process. Yoke 24 is rotated. When the second servo motor 17 is operated, the support 12 is lifted and adjusted by the screw 18 formed on the rotation shaft thereof and the nut 19 formed on the support 12, and the deflection yoke 24 is the cathode ray tube. The lifting and lowering is adjusted with respect to the neck portion 23 of (22).

In addition, when the third servo motor 20 is operated, the support part 12 is rotated about the hinge part 21, and the deflection yoke 24 is adjusted to the left and right sides with respect to the neck part 23. As a result, when the first, second, and third servomotors 14, 17, and 20 are operated, the deflection yoke is rotated and the flow is controlled to move up and down and to the left and right. This is inspected and finally fixed by using a magnet sheet, and then the deflection yoke 24 is fixed to the neck portion 23 using an adhesive or the like.

As described above, according to the present invention, when each servomotor is operated, the horizontal yoke is adjusted to the left and right sides of the neck portion with the cathode ray, and the elevating control is also performed. That is, since the flow of the deflection yoke is automatically adjusted, workability is improved and productivity can be improved because one worker can assemble the deflection yoke to several cathode ray tubes.

Claims (1)

A frame is vertically placed on the upper part of the base, and a pair of holders and a support part for holding a deflection yoke fitted to the neck portion of the cathode ray tube are provided at the rear of the frame. A first servo motor having a pinion for rotating the deflection yoke is provided in the front of the frame to move the rack formed in the lower portion of each of the support to cross each other, A second servo motor having a screw fastened to a nut formed at a lower portion of each support part at the front of the frame to lift and lower the respective support parts to adjust the deflection yoke is provided. And a third servo motor provided at the front of the frame such that each of the supporting parts rotates around the hinge part to allow the deflection yoke to flow from side to side.