KR100274881B1 - Focus Unbalance Adjuster for Color Cathode Ray Tubes - Google Patents

Abstract

A group of G-magnets installed in the upper and lower portions of three electron beams arranged in the inline form emitted from the electron gun, and adjacent to the two electron beams, respectively, to compensate for the deflection force due to the uneven magnetic field of the deflection yoke. It characterized by including the B magnet group.

Description

Focus Unbalance Adjuster for Color Cathode Ray Tubes

The present invention relates to a cathode ray tube employing an inline electron gun, and more particularly, to a focus unbalance adjusting device of a color cathode ray tube for adjusting focus unbalance of an electron beam deflected by a deflection yoke and landing on a fluorescent film. will be.

Generally, in the color cathode ray tube employing the inline electron gun, three electron beams emitted from the electron gun enclosed in the neck portion are selectively deflected by the deflection yoke to excite the phosphor of the fluorescent film formed on the inner surface of the panel. In order to obtain a clear image, the electron beams must be accurately landed on each phosphor of the fluorescent film, but the deflection yoke causes pin-cushioned deflection and barrel deflection fields to be formed by vertical and horizontal deflection coils for self-convergence of the electron beam. do.

This non-uniform deflection magnetic field distorts the cross section of the electron beam when deflecting to each part of the screen surface of the electron beam. In more detail, the deflection magnetic field of the deflection yoke for deflecting the electron beam includes a pincushion magnetic field 11 formed by a horizontal deflection coil and a barrel magnetic field formed by a vertical deflection coil as shown in FIG. 12). However, as shown in the drawing, three electron beams emitted from an electron gun (not shown), that is, three electron beams for exciting red, green, and blue phosphors (hereinafter R electron beam R, G electron beam G, and B). Since they are arranged inline, the magnetic fields applied to each of the electron beams are not the same. Accordingly, the non-uniform pincushion magnetic field 11 and the barrel magnetic field 12 pass through the deflection force, and R, G, and B electron beams (R) (G) (B) are landed on the fluorescent film of the panel (not shown). In this case, the electron beam spot is crushed by the low lens effect, or as shown in FIG. 2, the R and B electron beams R and B located at both sides of the electron beam spot are changed in the size of the cross section of the electron beam at the periphery of the fluorescent film 100. For example, R, B electron beams (R) (B) located on both sides of the pret beam, that is, R, B electron beam (R) emitted from the electron gun 60 to excite the red phosphor and the blue phosphor as shown in FIG. (B) tends to have a smaller cross section of the electron beam due to a difference in deflection force due to the pincushion magnetic field when deflecting in a direction away from the side where the electron beam is located (in the case of the B battery beam, the R electron beam side).

In order to solve such a problem, conventionally, the cross section of the electron beam emitted from the electron gun is distorted in the reverse direction of the nonuniform magnetic field direction of the deflection yoke, and the focal lengths of the electron beam scanned to the center of the fluorescent film and the electron beam scanned to the edge of the fluorescent film are different. An attempt was made.

The method of distorting the cross section of the electron beam in the opposite direction of the non-uniform magnetic field has an electron lens (not shown) provided between the electrodes of the electron gun by having different focusing and diverging forces respectively acting in the vertical direction and the horizontal direction. The cross section of the electron beam passing through) is distorted in the opposite direction to the direction distorted by the deflection yoke. However, since the electron lens distorting the electron beam is made by modifying the shape of the electron beam passing hole formed in the electrode of the electron gun, it is difficult to manufacture the electron gun. Therefore, there is a limit to deforming the cross section of the electron beam by using the difference between the focusing force and the diverging force of the electron lens as described above.

The present invention has been made to solve the above problems, a color cathode ray tube which can improve the focus characteristics of the electron beam landing on the fluorescent film by correcting the non-uniformity of the deflection force of the electron beam emitted from the electron gun to correct the cross-sectional distortion of the electron beam Its purpose is to provide a focus unbalance adjusting device.

1 is a view showing a magnetic field formed by the vertical and horizontal deflection coils of a general deflection yoke.

2 is a view showing the size of a cross section of an electron beam deflected by deflection yoke and landing in a horizontal direction of a fluorescent film in a cathode ray tube employing a conventional inline electron gun.

3 is a view showing the size of electrons when the conventional R, G, B electron beam landing on the fluorescent film,

4 is a partially cutaway side view showing a color cathode ray tube equipped with a focus unbalance compensation means according to the present invention;

5 is a partial ablation perspective view of the deflection yoke equipped with the focus unbalance compensation means according to the present invention;

6 is a front view showing a focus unbalance compensation means, showing a magnetic field with respect to a magnet;

7 is a view showing a visualized magnetic field on the R, B electron beam.

In order to achieve the above object, the present invention, the G-magnet group is installed in the upper and lower portions of the electron beam located in the center of the three electron beams emitted from the electron gun and arranged in-line, and is installed adjacent to the both electron beams, respectively, non-uniformity of the deflection yoke It is characterized by including the R, B magnet group to compensate for the deflection force by the magnetic field.

In the present invention, the G-magnet group and the R, G-magnet group are composed of a plurality of electromagnets in which coils are wound around a silver core, and the current applied to the coils of the electromagnets is applied with a current synchronized with a deflection signal.

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

4 and 5 show an embodiment of a color cathode ray tube equipped with a focus unbalance adjusting device according to the present invention.

As shown in the drawing, the color cathode ray tube is a panel 20 having a fluorescent film 21 formed on an inner surface thereof, and a neck part encapsulated with the panel 20 and provided with an electron gun 60 and a deflection yoke 34 respectively. 31 and a funnel 30 having a cone portion 32. The deflection yoke 34 is provided with a focus unbalance compensation device 50 which is a characteristic component of the present invention.

The focus unbalance correction device 50 is installed in the separator 34a of the deflection yoke 34 to compensate for the non-uniform magnetic field formed by the deflection yoke 34 to prevent the focus from being deteriorated due to the cross-sectional distortion of the electron beam. .

In addition, the focus unbalance compensation means 50 may be fixed to the neck portion 31 between the electron gun and the deflection yoke by bonding or a separate fixing member (not shown).

The configuration of the focus unbalance adjusting device is shown in FIG. Referring to the drawings, the compensating means 50 includes a G-magnet group 51 provided above and below the G electron beam in the electron beam emitted from the electron gun in the separator 34a of the deflection yoke, and an R magnet installed adjacent to the R electron beam. A group 52 and a B magnet group 53 provided adjacent to the B electron beam are provided.

The G-magnet group 51 includes first and second magnets 51a and 51b provided at the vertical upper and lower portions of the G electron beam, and the first and second magnets 51a and 51b are respectively provided at the vertical upper and lower portions of the G electron beam. It is installed vertically so that pole and N pole are located. The R magnet group 52 includes third and fourth magnets 52a and 52b that are inclined at upper and lower sides of the R electron beam, respectively, and the B magnet group 53 is inclined to the upper and lower sides of the R electron beam, respectively. The fifth and sixth magnets 53a and 53b are provided. The third and fifth magnets 52a and 53a are installed such that the N pole is positioned at the side corresponding to the first magnet, and the fourth and sixth magnets 52b and 53b correspond to the second magnet 51b. It is preferable that the S pole is located at the side. As shown in FIG. 6, the first to sixth magnets may be manufactured by continuously winding a single coil 54 on each core 55. In addition, the current applied to each coil is preferably applied in synchronization with the deflection signal of the deflection yoke.

Referring to the operation of the cathode ray tube according to the present invention configured as described above are as follows.

When the electron beam emitted from the electron gun 60 is deflected by the deflection yoke 34 and scanned to the edge of the fluorescent film 100, a current synchronized with the deflection signal is applied to each coil of the compensation means 50. When a voltage is applied to the coil 54, a magnetic field is formed around each of the first to sixth magnets 51a to 56a, 51b to 56b, and the electron beam emitted from the electron gun 60 is affected by the magnetic field. As shown in FIG. 7, the upper and lower portions of the cross section 100 are forced outward by the magnetic field distribution of the horizontal component in the electron beam, so that the cross sections of the R and B electron beams extend in the vertical direction. When the electron beam is deflected in the left and right directions of the screen, the electron beam can compensate for the degree of distortion of the cross section of the electron beam according to the deflected side.

More specifically, as shown in FIG. 6, when the R electron beam R is deflected to the left when the R electron beam R is deflected to the left and the right of the fluorescent film, the third, In the case where the R electron beam R is focused in the vertical direction by the magnetic field formed by the four magnets 52a and 52b, it is focused in the vertical direction and is scanned to the right side of the fluorescent film 100. Since the electron beams formed by the third and fourth magnets 52a and 52b pass through a region having a relatively low magnetic flux density, the electron beam receives less focusing force in the vertical direction. Therefore, the electron beam emitted from the electron gun 60 and passed through the compensation means has a different electron beam cross section when scanned to the left and scanned to the right. That is, the cross section of the electron beam when scanned to the left becomes smaller than the cross section of the electron beam when scanned to the right.

The differentiated cross section of the R electron beam is compensated for the nonuniformity of Lorentz force received during deflection while passing through the nonuniform pin cushion magnetic field of the deflection yoke, thereby compensating for the nonuniformity of the electron beam cross section on the left and right sides of the fluorescent film.

As described above, since the first and second magnets 51a and 51b of the first magnet group 51 are vertically installed above the G electron beam G in the process of compensating the electron beam, the second and third magnets are provided. The reverse magnetic field formed by the third to sixth magnets of the groups 52 and 53 is neutralized so that the centrally located G electron beam is influenced by the third to sixth magnets 52a, 52b, 53a and 53b. It is possible to prevent distortion of the cross section of the G electron beam.

The same applies to the above-described scanning by the fifth and sixth magnets 53a and 53b of the B electron beam.

As described above, in the focus unbalance compensation device of a color cathode ray tube according to the present invention, the electron beam emitted from the electron gun is corrected in advance by applying an inverse magnetic field to the electron beam to compensate for the influence of the uneven pin cushion magnetic field of the deflection yoke. This allows the distortion of to cancel each other out. As a result, it is possible to compensate the uneven state of the cross section of the electron beam as the electron beam is scanned to the left and right sides of the screen, thereby improving the focus characteristic.

In addition, the present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the technical scope to which the present invention belongs.

Claims (6)

A group of G-magnets installed in the upper and lower portions of three electron beams arranged inline from the electron gun, which are located in the center, and adjacent to the two electron beams, respectively, R and B for compensating a deflection force due to a nonuniform magnetic field of the deflection yoke. Focus unbalance adjusting device of a color cathode ray tube, characterized in that the magnet group. The method of claim 1, The G-magnet group and the R and G-magnet groups are composed of a plurality of electromagnets in which coils are wound around a silver core, and the voltage applied to the coils of the electromagnets is a voltage in synchronization with a deflection signal. Tube unbalance adjuster. The method of claim 2, The G-magnet group has first and second magnets installed in the vertical upper and lower portions of the electron beam located at the center, and the R-magnet group includes third and fourth magnets inclined at the upper and lower sides of one electron beam, respectively, and the B-magnet group. And the fifth and sixth magnets which are inclined on the upper and lower sides of the other electron beam, respectively. The method of claim 3, The first and second magnets are installed vertically so that the S pole and the N pole are respectively positioned above and below the vertically located electron beam. The third and fifth magnets are installed so that the N pole is positioned on the side corresponding to the first magnet, and the fourth and sixth magnets are the S poles located on the side corresponding to the second magnet. Focus unbalance adjuster. The apparatus of claim 4, wherein each of the first to sixth magnets is formed by winding a single coil on each core in succession. 6. The apparatus of claim 5, wherein the current applied to the coil is synchronized with a deflection signal.