KR20040073077A - Color cathode ray tube - Google Patents

Abstract

PURPOSE: A color CRT is provided to correct XBV(X Axis Bending Vertical) due to the error of encapsulation angle by adhering an XBV correction magnet at the aperture-screen side. CONSTITUTION: A color CRT comprises a panel, a funnel, an electron gun, and a deflection yoke for deflecting the electron beams. The deflection yoke includes a horizontal deflection coil(271) for deflecting horizontally the electron beams, a vertical deflection coil(272) for deflecting vertically the electron beams, a holder(273) for supporting and insulating the deflection coils, a ferrite core(274) for reducing leakage flux on the feedback path of the magnet field created at the deflection coils, and a correction magnet(275) adhered to a neck side of a holder flange.

Description

Color Cathode Ray Tube {COLOR CATHODE RAY TUBE}

The present invention relates to a color cathode ray tube, and in particular, a deflection yoke to correct an X-axis bending vertical (XBV), which is a misconvergence item caused by an error in encapsulation angle during encapsulation of an electron gun and a cathode ray tube in a color cathode ray tube. The present invention relates to a color cathode ray tube in which a convergence characteristic and a focus characteristic can be ensured without deteriorating the focus quality by providing an XBV correction magnet at the opening (screen portion) side of the lens.

A schematic configuration of a general colored cathode ray tube is shown in sectional view in FIG. The cathode ray tube is provided with a phosphor screen on the front surface of the vacuum tube, and has an electron gun and a deflecting device in the neck portion facing the vacuum tube, and deflects the electron beam output from the electron gun so that the electron beam strikes the phosphor screen.

In general, as shown in FIG. 1, the color cathode ray tube is combined with the panel 11 and the funnel 12 and sealed so that the inside thereof is kept in a vacuum state and forms a vacuum tube.

A phosphor screen 13 is formed on the inner surface of the panel 11, and an electron gun 14 is installed on a portion of the funnel neck opposite to the screen 13. Between the phosphor screen 13 and the electron gun 14, a shadow mask 15 for color-selective action in close proximity to the phosphor screen is provided at predetermined intervals, and the neck portion of the funnel is emitted from the electron gun 14 A deflection yoke 17 is provided for deflection of the electron beam 16. In addition, a CPM (Center Purity Magnet) 18 is installed in the neck portion close to the electron gun 14.

Briefly look at the operation of the color cathode ray tube configured as described above. The electron beam 16 output from the electron gun 14 is appropriately deflected in the vertical and horizontal directions by the deflection yoke 17, and the horizontal and vertical deflected electron beam 16 passes through the beam passing hole of the shadow mask 15. By hitting the front phosphor screen 13 to display a predetermined color image.

The deflection yoke 17 includes a horizontal deflection coil 171 for deflecting the electron beam in a horizontal direction, a vertical deflection coil 172 for deflecting the electron beam in a vertical direction, and the horizontal and vertical deflection coils; A holder 173 for supporting the core and ensuring insulation between the cores, a core 174 for reducing losses on the return path of the magnetic field generated by the deflection coil, and an opening of the deflection yoke (screen And a XBV correction magnet 176 provided in the neck portion of the deflection yoke.

The horizontal deflection coil 171 is generally supplied with a horizontal deflection current having a frequency of 15.75 kHz or higher, and an electron beam inside the cathode ray tube using a magnetic field generated by the horizontal deflection coil 171 according to the horizontal deflection current. 16) is deflected in the horizontal direction, and a vertical deflection coil 172 flows a vertical deflection current having a frequency of 60 Hz, and uses a magnetic field generated by the vertical deflection coil 172 according to the vertical deflection current. The electron beam 16 inside the cathode ray tube is deflected in the vertical direction. As such, the electron beam 16 is deflected in the vertical and horizontal directions to be collected at a point on the screen so that the image can be displayed.

A common color cathode ray tube generally uses an inline electron gun. In the cathode ray tube using the inline electron gun, three electron beams converge at one point of the phosphor screen because the electron beams of R, G, and B are arranged side by side. The deflection yoke of cathode ray tubes uses self-convergence using a non-uniform magnetic field.

That is, when looking at the deflection yoke, three electron beams of R, G, and B do not use a separate additional circuit and an additional device by using a non-uniform magnetic field by the horizontal deflection coil 171 and the vertical deflection coil 172. Self-convergence-type deflection yokes that allow convergence on the screen are being developed. In the self-convergence type deflection yoke, three electron beams are generated by adjusting the winding distribution of the horizontal deflection coil 171 and the vertical deflection coil 172 to generate barrel or pin-cushion type magnetic fields for each of the opening, the middle part, and the neck part. According to this position, different deflection forces can be experienced so that three electron beams can be collected at the same point even at different distances from the starting point of the electron beam to the screen of the arrival point so that the phosphor can be hit precisely.

On the other hand, in the case of making a magnetic field by flowing current to the deflection coils (171, 172) as described above, it is difficult to deflect the electron beam 16 to the front of the screen only by the magnetic field of the coil using a high permeability ferrite core 174 By minimizing the loss on the return path of the magnetic field, the magnetic field efficiency is increased and the magnetic force is increased.

That is, in the case of making a magnetic field by flowing current to the deflection coils 171 and 172, it is difficult to deflect the electron beam 16 to the front of the screen only by the magnetic field of the coil. Therefore, the ferrite core 174 of high permeability uses the ferrite core 174 to return the magnetic field. By minimizing the loss of the phase, the magnetic field efficiency is increased and the magnetic force is increased.

Therefore, ferrite core 174 is basically composed of iron oxide (Fe ₂ O ₃ ) and some additives (Mn, Mg, etc.) to secure a high permeability. The shape of the ferrite core 174 is mostly conical cores used in cathode ray tube products, and recently, rectangular cores are also used to further increase efficiency. Since it has a great influence on the leakage magnetic field, proper design is an important factor that greatly affects the quality of the deflection yoke.

As described above, since the ferrite core 174 is installed, the deflection yoke increases the deflection efficiency of the yoke and reduces the leakage magnetic field. Thus, the shape becomes a closed shape surrounding the deflection yoke. . In order to satisfy the good characteristics of the ferrite core 174, the permeability must be high (μ ₀ 300 or more) and have a high electrical resistance to reduce the loss caused by the eddy current.

In the color cathode ray tube described so far, miss convergence occurs due to an error in the sealing angle between the electron gun and the cathode ray tube. XBV, a misconvergence item caused by the sealing angle error between the electron gun and the cathode ray tube, uses a method of correcting by attaching a magnet 176 to the neck portion of the deflection yoke.

That is, when the electron beam radiated from the electron gun 14 passes through the CPM and the main lens, tilt of the R / B electron beam occurs in the Y axis. To adjust this tilt, the four poles of the CPM 18 are excessively adjusted. This is done by using a magnet 176 attached to the neck of the deflection yoke to generate a local magnetic field to adjust the path of the electron beam through it. However, the magnet 176 attached to the neck of the deflection yoke has the advantage of correcting the miss convergence XBV caused by the error of the encapsulation angle between the cathode ray tube and the electron gun, but it is a fatal deterioration of white uniformity and focus quality. The problem is that it acts as a factor.

That is, when the magnet 176 is attached to the neck portion of the deflection yoke as in the prior art, through artificial adjustment of the four poles of the CPM 18 to correct the tilt of the R and B beams generated while passing through the main lens. Tilt correction needs to be made, which forces a forced tilt adjustment of the R / B electron beams, thereby reducing the unbalance of the R / B electron beams in mis-landing, which is important for the white uniformity of the cathode ray tube. This results in a fatal adverse effect on the white uniformity of the cathode ray tube.

In addition, the ITC also makes it difficult to adjust mislanding, resulting in deterioration of productivity.

In particular, if the magnet 176 is not attached to or attached to the neck of the deflection yoke, the 4-pole B / R magnet mounted on the deflection yoke is excessively used to compensate for the sealing angle of the cathode ray tube itself and XBV correction due to the distribution of cathode ray tube production. This increases the amount of OCV in the Y-axis direction, which increases the amount of free spot position (F-SP) tilt, thereby adjusting the 4 and 6 pole adjustments of the CPM 18 and the 4 pole B / R magnets. An increase in adjustment occurs.

When the adjustment amount increases as described above, the amount of V-side halo is increased, which causes deterioration in focus characteristics and deterioration in image quality.

The present invention provides a color cathode ray tube capable of correcting misconvergence XBV at the deflection yoke caused by an error in the sealing angle between the cathode ray tube and the electron gun by attaching an XBV correction magnet to the opening-screen side of the deflection yoke of the color cathode ray tube. Its purpose is to.

In addition, the present invention by attaching the XBV correction magnet to the opening-screen side of the deflection yoke of the color cathode ray tube to correct the XBV, R / B generated when the electron beam previously emitted from the electron gun passes through the cathode, CPM and the main lens It is an object of the present invention to provide a color cathode ray tube which can prevent the generation of the tilt of the electron beam on the Y axis and thus prevent the unbalance of the R / B electron beam, thereby improving white uniformity.

In addition, the present invention by attaching the XBV correction magnet to the opening-screen side of the deflection yoko of the color cathode ray tube to correct the XBV, so as not to excessively use the 4-pole B / R correction magnet at the time of ITC and thus the focus of the cathode ray tube The aim is to provide a color cathode ray tube for improved performance and improved ITC productivity.

1 is a cross-sectional view showing a schematic configuration of a conventional color cathode ray tube including a deflection yoke.

2 is a cross-sectional view showing a schematic configuration of a color cathode ray tube including a deflection yoke according to the present invention;

Figure 3 is a front view showing the configuration of the deflection yoke according to the present invention

4 is a diagram schematically illustrating the XBV correction principle of a deflection yoke according to the present invention.

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

21: Panel 22: Funnel

23: phosphor screen 24: electron gun

25: shadow mask 26: electron beam

27: deflection yoke 28: 4-pole magnet

271: horizontal deflection coil 272: vertical deflection coil

273: holder 274: ferrite core

275 calibration magnet 276 XBV calibration magnet

In the cathode ray tube of the present invention for achieving the above object is a cathode ray tube having a panel, a funnel and an electron emission means and a deflection yoke for deflecting the electron beam emitted from the electron emission means,

A horizontal deflection coil for horizontal deflection of the electron beam, a vertical deflection coil for vertical deflection of the electron beam, a holder supporting the horizontal deflection coil and the vertical deflection coil and insulating each other, and a magnetic field generated by the deflection coil. And a deflection yoke composed of a ferrite core for reducing the leakage magnetic flux on the return path, and a correction magnet attached to the neck-side surface of the holder flange portion.

In addition, the correction magnet in the color cathode ray tube deflection yoke of the present invention for achieving the above object is characterized in that attached to the 3 o'clock and 9 o'clock directions, respectively.

In addition, in the color cathode ray tube deflection yoke of the present invention for achieving the above object, the correction magnet is characterized in that the same polarity is attached to face each other toward the deflection central axis.

In addition, in the color cathode ray tube deflection yoke of the present invention for achieving the above object, the correction magnet is characterized in that the S poles are attached so as to face the deflection central axis with respect to three R, G, and B electron beams on the inline.

In addition, in the color cathode ray tube deflection yoke of the present invention for achieving the above object, the correction magnet is characterized in that the N poles are attached to face the deflection central axis with respect to the three R, G, B electron beams on the inline.

In addition, the correction magnet in the color cathode ray tube deflection yoke of the present invention for achieving the above object is characterized in that the magnetic permeability is made of a sheet (sheet) or plate hard magnet (Hard Magnet).

Hereinafter, with reference to the accompanying drawings, the configuration of the deflection yoke of the present invention configured as described above and the color cathode ray tube including the same and its working effects will be described in detail by way of examples.

First, the configuration of the color cathode ray tube according to the present invention will be described with reference to FIG.

As shown in FIG. 2, the color cathode ray tube according to the present invention is coupled to and sealed with the panel 21 and the funnel 22, and the inside thereof is maintained in a vacuum state and forms a vacuum tube.

A phosphor screen 23 is formed on the inner surface of the panel 21, and an electron gun 24 is installed at the funnel neck portion facing the screen 23. Between the phosphor screen 23 and the electron gun 24, a shadow mask 25 is provided at a predetermined interval in close proximity to the phosphor screen at predetermined intervals, and the neck portion of the funnel is emitted from the electron gun 24. A deflection yoke 27 is provided for deflection of the electron beam 26. In addition, a CPM (Center Purity Magnet) 28 is installed in the neck portion close to the electron gun 24.

Briefly look at the operation of the color cathode ray tube configured as described above. The electron beam 26 output from the electron gun 24 is appropriately deflected in the vertical and horizontal directions by the deflection yoke 27, and the horizontal and vertical deflected electron beam 26 passes through the beam passing hole of the shadow mask 25. By hitting the front phosphor screen 23 to display a predetermined color image.

The deflection yoke 27 may include a horizontal deflection coil 271 for deflecting the electron beam in a horizontal direction, a vertical deflection coil 272 for deflecting the electron beam in a vertical direction, and the horizontal and vertical deflection coils; A holder 273 for supporting the core and securing insulation between the core, a core 274 for reducing the loss on the return path of the magnetic field generated by the deflection coil, and an opening of the deflection yoke (screen And a XBV correction magnet 276 provided on the neck-side surface of the holder flange portion.

3 shows a detailed structure of the deflection yoke according to the present invention. As shown in Fig. 3, the deflection yoke according to the present invention includes a horizontal deflection coil 271 for deflecting the electron beam in the horizontal direction, a vertical deflection coil 272 for deflecting the electron beam in the vertical direction, and the horizontal and A holder 273 for supporting the vertical deflection coil and the core and ensuring insulation therebetween, a core 274 for reducing the loss on the return path of the magnetic field generated by the deflection coil, and the deflection yoke A correction magnet 275 provided in an opening portion (screen portion) of the opening, an XBV correction magnet 276 attached to the neck side of the holder flange portion, and a ring for mechanically coupling the deflection yoke with the cathode ray tube. A band 277, a coma free coil 278 mainly installed at the neck portion of the holder for correcting coma aberration caused by a vertical barrel type magnetic field, and for adjusting B / R balance. A 4-pole B / R magnet 219 installed on the neck of the holder is mounted, and a CPM including 4-pole and 6-pole is mounted on the outer surface of the electron gun, and the angle formed by the 4-pole and the 6-pole is 20 Calibration can be done within degrees, resulting in a significant reduction in vertical unilateral halo in screen characteristics, as well as improved focus performance and ITC yield.

The XBV correction magnet 276 is attached to the rear of the holder on the opening side of the horizontal deflection coil. The XBV correction magnet 276 is installed to face each other with respect to the deflection center axis, that is, the tube axis of the cathode ray tube, and forms a magnetic field for correction for three R, G, and B electron beams arranged inline within the yoke. give. The XBV correcting magnet is formed by attaching a hard magnet having a magnetic permeability of 3000 G / Oe or more in a sheet or plate shape, and is selected from a value of 15 Gauss or more.

The XBV correction magnet is a stable metal oxide mainly composed of iron oxide (Fe ₂ O ₃ ), and is a ferrite produced by mixing and reacting with divalent metal oxides (AO, A: divalent metal ions) at a constant ratio. Magnets can be classified into hard magnets and soft magnets. Hard magnets are easily magnetized by an external magnetic field and return to their original state when there is no magnetic field, such as ferrite rods and ferrite sheets. By magnetization and difficult and once magnetization is made, the permanent magnet is a magnet that maintains a certain amount of magnetism even if the magnetic field disappears.

As described above, the deflection yoke with the XBV correction magnet attached to the screen part has a fluorescent screen formed on the inner surface, a panel provided with a shadow mask, and a funnel equipped with an electron gun on the neck portion of the deflection yoke. It is installed as a deflection device for deflecting to form a color cathode ray tube.

In this color cathode ray tube, as described above, the electron beam output from the electron gun is deflected appropriately in the vertical and horizontal directions by the deflection yoke, and the horizontal and vertically deflected electron beam passes through the beam passing hole of the shadow mask to form a phosphor on the front surface. The predetermined color image is displayed by hitting the screen.

In the deflection yoke, the horizontal deflection coil 271 is generally supplied with a horizontal deflection current having a frequency of 15.75 kHz or higher, and the inside of the cathode ray tube using a magnetic field generated by the horizontal deflection coil 271 according to the horizontal deflection current. To deflect the electron beam in the horizontal direction, and to the vertical deflection coil 272 to flow a vertical deflection current having a frequency of 60 Hz, by using a magnetic field generated in the vertical deflection coil 272 according to the vertical deflection current. The electron beam inside the cathode ray tube is deflected in the vertical direction. In this way, the electron beam is deflected in the vertical and horizontal directions so that the image is displayed at one point on the screen.

When looking at the deflection yoke, three electron beams of R, G, and B do not use an additional circuit and an additional device by using a non-uniform magnetic field by the horizontal deflection coil 271 and the vertical deflection coil 272. Self-convergence-type deflection yokes that allow convergence on the screen are being developed. That is, by adjusting the winding distribution of the horizontal deflection coil 271 and the vertical deflection coil 272 to create a barrel or pin-cushion type magnetic field for each of the openings, the middle part, and the neck part, three electron beams are positioned according to their positions. By experiencing different deflection forces, three electron beams are collected at the same point at different distances from the starting point of the electron beam to the screen of arrival, so that the phosphor can be hit precisely.

On the other hand, as described above, when a current is applied to the deflection coils 271 and 272 to create a magnetic field, it is difficult to deflect the electron beam to the front of the screen only by the magnetic field of the coil. Therefore, the magnetic field is returned by using a ferrite core 274 having a high permeability. By minimizing losses on the path, the magnetic field efficiency is increased and the magnetic force is increased.

Therefore, ferrite core 274 is basically composed of iron oxide (Fe ₂ O ₃ ) and some additives (Mn, Mg, etc.) to secure a high permeability. The shape of the ferrite core 274 is mainly conical cores used in cathode ray tube products, and recently, rectangular cores are also used to further increase efficiency. The thickness and position of the ferrite core 274 have a sensitivity of the deflection yoke. Since it has a great influence on the leakage magnetic field, proper design is an important factor that greatly affects the quality of the deflection yoke.

As described above, since the ferrite core 274 is installed, the deflection yoke increases the deflection efficiency and decreases the leakage magnetic field. Therefore, the shape of the ferrite core 274 is a closed shape surrounding the deflection yoke. . In order to satisfy the good characteristics of the ferrite core 274, the permeability must be high (μ ₀ 300 or more), and have high electrical resistance to reduce the loss caused by the eddy current.

On the other hand, when deflection of the R, G and B electron beams emitted from the electron gun is made as described above, XBV, which is a misconvergence caused by an error in the sealing angle between the electron gun and the deflection yoke, is corrected in the deflection yoke. That is, XBV is corrected by a pair of mutually opposing XBV correction magnets 276 attached to the neck side surface of the holder flange portion, thereby improving white uniformity and focus performance of the cathode ray tube.

Fig. 4 schematically shows the principle that XBV correction is performed by a pair of XBV correction magnets 276a and 276b attached to the neck side surface of the holder flange portion in the present invention.

The XBV correction magnets 276a and 276b are attached at 3 o'clock (# 3) and 9 o'clock (# 9), respectively, and form correction magnetic fields for R, G, and B electron beams, and have the same polarity. They are arranged to face each other toward the deflection central axis, that is, the tube axis.

4 shows a case where the S poles face each other. In this case, the R electron beam is moved downward in the 3 o'clock direction (# 3) and the B electron beam is moved upward in the 9 o'clock (# 9) direction. On the contrary, when the N poles face each other, the R electron beam moves upward in the 3 o'clock direction (# 3) and the B electron beam moves downward in the 9 o'clock (# 9) direction.

In Fig. 4, the XBV correction magnets 276a and 276b attached to the neck-side surface of the holder flange portion are arranged so that the S poles are directed in the direction of the center of the cathode ray tube. Therefore, according to Fleming's left-hand law, the Miss Convergence XBV improves XBV + (R Yumi) because the R beam moves under the magnetic force in the downward direction and the B beam moves upward.

On the contrary, if the N poles of the XBV correction magnets 276a and 276b attached to the neck side of the holder flange are arranged in the direction of the cathode ray tube center, the misconvergence XBV is the R beam upward, B The XBV- (B Grace) is improved because the beam moves under the magnetic force in the downward direction.

The present invention corrects the XBV in the deflection yoke by attaching a magnet to the neck side of the holder flange. Therefore, when the XBV is corrected by using a magnet attached to the neck portion of the deflection yoke, the tilt of the R / B electron beam generated when the electron beam passes through the cathode, the CPM, and the main lens does not occur. One-sided halo protection is possible.

In addition, since the XBV is corrected on the screen of the deflection yoke, it is not necessary to use excessive 4-pole B / R correction magnet during ITC, thereby improving the focus performance of the cathode ray tube and improving the ITC workability and productivity. do.

Claims (8)

A cathode ray tube having a panel, a funnel, and an electron emitting means, and comprising a deflection yoke for deflecting an electron beam emitted from the electron emitting means, A horizontal deflection coil for horizontal deflection of the electron beam, a vertical deflection coil for vertical deflection of the electron beam, a holder supporting the horizontal deflection coil and the vertical deflection coil and insulating each other, and a magnetic field generated by the deflection coil. And a deflection yoke comprising a ferrite core for reducing leakage flux on the return path and a correction magnet attached to the neck side of the holder flange portion. The color cathode ray tube according to claim 1, wherein the correction magnet is attached at 3 o'clock and 9 o'clock directions, respectively. The color cathode ray tube according to claim 1, wherein the correction magnets are attached so that the same polarities face each other toward the deflection central axis. The color cathode ray tube according to claim 1, wherein the correction magnet is attached so that the S poles face each other toward the deflection central axis with respect to three R, G, and B electron beams on the inline. The color cathode ray tube according to claim 1, wherein the correction magnet is attached to the R, G, and B electron beams on the inline so that the N poles face each other toward the deflection central axis. The color cathode ray tube according to claim 1, wherein the correction magnet is made of a sheet or a plate-shaped hard magnet having a permeability of 3000 G / Oe or more. The color cathode ray tube of claim 1, wherein the magnet is selected from a value of 15 Gauss or more. The color cathode ray tube according to claim 1, wherein a CPM including four poles and six poles is mounted on an outer surface of the electron gun, wherein an angle formed by the four poles and the six poles is 20 degrees or less.