KR0133390Y1 - Separator for deflection yoke - Google Patents

Abstract

The present invention relates to a separator for deflection yoke provided for insulation and assembly of a vertical coil and a horizontal coil of a deflection yoke mounted on a neck portion of a cathode ray tube for landing an electron beam emitted from an electron gun at a predetermined position of a screen. In order to provide a compact mounting structure capable of winding a coil for compensating raster rotation with a distortion correction magnet of a plurality of magnets, a plurality of magnet high-mounted magnets are mounted on the outer periphery of the collar part 33 of the separator 31. By forming the winding groove 37 to receive the raster rotation correction coil 27 by forming the protruding portion 35 and protruding radially extending protrusions 39 on the front outer peripheral side of the collar portion 33. In addition to correcting the raster rotation generated by the horizontal component of the external magnetic field, that is, the geomagnetic field, the configuration is compact and IT .C Easy to work with

Description

Separator for deflection yoke

1 is a side view showing a deflection yoke equipped with a separator according to the present invention.

Figure 2 shows the main part of the present invention, a partial cutaway cross-sectional view showing part A of FIG.

3 is a front view showing a video display device composed of a theoretical chassis and a cathode ray tube.

4 is a front view of a deflection yoke device viewed from the screen side of a cathode ray tube for compensating rotation of a phase appearing in a conventional cathode ray tube.

5 is a rear view of a cathode ray tube showing a geomagnetic field correction apparatus of a color brown tube according to another conventional embodiment.

* Explanation of symbols for main parts of the drawings

31 separator 33 color portion

35: magnet fixing part 39: protrusion

27: coil 37: winding groove

The present invention relates to a deflection yoke separator, and more particularly, to a deflection yoke separator provided with a mounting structure capable of winding a coil for correcting raster rotation appearing in an image of a cathode ray tube.

A video display device including computer video terminals has a cathode ray tube, that is, a CRT. The CRT has an electron gun that emits an electron beam towards the screen. The electron beam is deflected in the form of being scanned across the screen by a controlling method, the intensity of which is varied to form an image on the screen.

On the other hand, the deflection yoke mounted on the neck of the cathode ray tube is formed by R, G, and B phosphors formed inside the panel of the CRT by electron beams emitted from the electron gun by horizontal and vertical magnetic fields generated by a current flowing through the horizontal and vertical coils. It is a main part that deflects up, down, left, and right so as to land well. A separator is disposed between the horizontal coil and the vertical coil for mutual insulation and assembly.

A problem associated with such a cathode ray tube is a raster rotation in which the projected image appears in a rotated form about the horizontal axis of the screen. Raster rotation is often caused by the horizontal component of an external magnetic field, and one type of external magnetic field is a geomagnetic field. The amount of rotation of this phase depends on the geographical position of the display, the orientation of the display relative to the external magnetic field, and the like.

One solution to the raster rotation problem is to simply disassemble the display device and manually adjust its deflector. For example, when the display device includes a yoke magnetic deflection yoke, it is possible to manually rotate the yoke with respect to the CRT to offset the rotation generated by the external magnetic field. However, this technique has several drawbacks, one of which usually requires trained technicians to make adjustments and must be dispatched to the location of the user. This is very costly for the user.

Secondly, disassembling the display device is accompanied by a fear of damaging its inner surface. Moreover, even if the display device is later moved to a geographically different position or changes direction only with respect to the external magnetic field, readjustment is necessary due to the change in the direction or degree of the external magnetic field accompanying this.

Another solution to the raster rotation problem described above is to place the shield around the CRT assembly. Shields are typically problematic in that they are very expensive. For example, in order to install a shield, in many cases, the technique of the chassis or housing in which the CRT assembly is disposed must be used a lot. Moreover, if the CRT assembly needs to be repaired or repaired, the shield will interfere when the hand is inserted into the assembly.

The problem according to the conventional raster rotation as described above with reference to the drawings in more detail as follows. 3 is a front view showing a video display device 5 composed of a chassis 1 and a cathode ray tube, that is, a CRT 3.

As shown, the conventional CRT 3 displays the image 7 in a known manner.

When the CRT 3 is operating properly, the image 7 is oriented in the form shown in the solid rectangle. However, when the CRT 3 is affected by an external magnetic field such as a geomagnetic field, the phase is rotated by the horizontal component of the external magnetic field, as shown by the dotted rectangle. The magnitude of this rotation direction depends on the direction and strength of the external magnetic field.

In order to compensate for the raster rotation generated by such an external magnetic field of the cathode ray tube, Japanese Patent Laid-Open No. 63-250988 discloses a device for compensating for rotation of a phase appearing on a CRT display.

4 is a front view of the deflection yoke 11 viewed from the screen side, showing a compensation device for substantially canceling the rotation of the phase generated by the external magnetic field.

As can be seen from the figure, the hollow region 13 in which the CRT 3 is normally arranged extends in the longitudinal axial direction passing through the deflection yoke 11. A narrow groove 15 is formed at the front end of the hollow region 13, which has a winding 21 such that the front end of the winding 21 is substantially flat with the collar 17. To house. In addition, the deflection yoke 11 and the winding 21 can be separated and replaced separately from the CRT 3.

The winding 21 surrounds the CRT 3 and is preferably shaped to fall within a vertical plane substantially transverse to the path of the beam. In addition, the winding 21 is connected to a controller having two terminals, and current is applied by the above control for adjusting the magnitude and direction of the current to generate a magnetic field. Thus, when a conventional CRT assembly is subjected to an external magnetic field such that raster rotation occurs, the user adjusts the controller while looking at the image on the screen, so that the appropriate size and orientation substantially cancels the external magnetic field and eliminates the raster rotation. Compensation can be made by generating a current of.

However, in the method of attaching the coil 21 surrounding the cone of the cathode ray tube, that is, the device for compensating the rotation of the phase as described above, a separate winding must be provided to energize the compensation coil. In order to prevent the flow of the compensation coil, the bonding process has to be performed, which causes inconvenience in separate separation and replacement.

5 is a rear view of the cathode ray tube showing the geomagnetic field correction device of the color CRT tube disclosed in Japanese Patent Laid-Open No. 64-58189.

As can be seen from the figure, geomagnetic field correction coils 23 and 25 are provided on the rear surface of the CRT 3. The coils 23 and 25 are arranged symmetrically with respect to the neck portion of the CRT 3, and the inclined portions of the coils are arranged to be parallel to the electron beam toward each corner portion of the CRT 3.

However, the geomagnetic field correction device of the color CRT has a problem in that the coil becomes large and needs to be attached to the cathode ray tube, that is, the CRT 3, resulting in poor assembly and mounting.

The present invention was devised to overcome the above-described problems, and a deflection yoke provided with a compact mounting structure capable of winding a coil for correcting raster rotation appearing in an image of a cathode ray tube together with a conventional distortion correction magnet. The purpose is to provide a separator for this.

In order to realize the above object, the present invention is equipped with a distortion correction magnet on the outer periphery of the collar of the separator to provide a compact mounting structure capable of winding a coil for correcting the raster rotation together with a normal distortion correction magnet. Provided are a plurality of magnet fixing parts for protruding, and a deflection yoke separator comprising a winding groove for receiving a raster rotation correction coil by forming a protruding portion extending radially on the front outer peripheral side of the collar portion.

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

1 is a side view showing a deflection yoke equipped with a separator according to the present invention.

Usually, the deflection yoke 11 mounted on the neck portion of the cathode ray tube includes a separator 31 formed by coupling two half-trumpets to each other for insulation and assembly, and a pair of horizontal coils (not shown) disposed therein. And a pair of ferrite cores (not shown) having a high permeability in which vertical coils 19 arranged outside the separator 31 are wound.

Here, the deflection yoke separator 31 according to the present invention has a magnet for mounting a plurality of magnets (not shown) on the collar part 33 of the separator 31 to correct distortion of the screen, that is, distortion. In addition to providing the government 35, a winding groove 37 radially extended with respect to the center axis of the cathode ray tube at the front end (lower side of the drawing) of the collar portion 33 is formed. The winding groove 37 houses a coil for compensating raster rotation by an external magnetic field, that is, a geomagnetic field.

Therefore, when the coil is wound radially in the winding groove 37, a variable DC current flows to the coil, thereby generating a magnetic field, thereby substantially canceling the external magnetic field and correcting the raster rotation. do.

FIG. 2 is a view illustrating a magnet mounting portion and a winding groove of a deflection yoke separator according to the present invention, and is an enlarged cross-sectional view of part A of FIG. 1.

Distortion correction magnets are disposed on the plurality of magnet mounting portions 35 protruding from the collar portion 33 of the separator 31 at an approximately right angle to the outer circumferential side, and approximately 'V' shaped on the front outer circumferential side of the collar portion 33. A coil 27 for correcting the distortion, i.e., raster rotation, by the external magnetic field is wound around the radially protruding portion 39 extending and bent downward to form the winding groove 37.

As described above, according to the deflection yoke separator of the present invention, by providing a winding groove for winding a raster rotation correction coil, it eliminates the inconvenience of a separate winding and bonding process, which has been a problem in the past, Mounting of the distortion correction magnet and winding of the coil is easy, as well as compact, there is an advantage that the assembly and mounting excellent.

Moreover, the I.T.C (Integral Tube Components) process performed at the end of the cathode ray tube assembly has the advantage that the I.T.C operation is considerably easier because the separate winding is unnecessary and the configuration is compact as described above.

As described above, the deflection yoke separator of the cathode ray tube according to the present invention provides a compact mounting structure capable of winding a coil for correcting the raster rotation appearing in the image of the cathode ray tube together with a normal distortion correction magnet. In addition to correcting the raster rotation generated by the horizontal component of the external magnetic field, that is, the earth's magnetic field, the configuration is compact and the ITC operation is easy.

Claims (1)

In the separator for deflection yoke, which is mounted to the neck portion of the cathode ray tube and is provided for the insulation and assembly of the vertical coil and the horizontal coil of the deflection yoke for landing the electron beam emitted from the electron gun at a predetermined position on the screen, the separator 31. Protruding a plurality of magnet fixing portions 35 for mounting the distortion correction magnet on the outer circumference of the collar portion 33, and forming a radially extending protrusion 39 on the front outer circumference side of the collar portion 33 A deflection yoke separator, comprising a winding groove 37 for storing a raster rotation correction coil 27.