KR20030072887A - Deflection Yoke for CRT - Google Patents

Abstract

PURPOSE: A deflection yoke is provided to allow the deflection yoke to correct X-axis mis-convergence by constituting the deflection yoke with the main core and auxiliary core. CONSTITUTION: A deflection yoke comprises horizontal and vertical deflection coils for deflecting electron beams in horizontal and vertical directions; a ferrite core for achieving improved magnetic efficiency by reducing losses of the magnetic force generated from the horizontal and vertical deflection coils; and a holder for fixing the horizontal and vertical deflection coils and the ferrite core at predetermined positions, and allowing for an insulation between the horizontal deflection coil and the vertical deflection coil. The ferrite core includes a main core(20) and an auxiliary core(30). The auxiliary core is fixed at an auxiliary core holder(31), and the auxiliary core holder is coupled to the main core.

Description

Deflection yoke for cathode ray tube {Deflection Yoke for CRT}

The present invention relates to a deflection yoke for a cathode ray tube having a saddle-shaped deflection coil. More specifically, the deflection yoke is used in a state in which a deflection yoke is mounted on a CRT using a deflection yoke. The present invention relates to a deflection yoke for cathode ray tubes, which allows correction in the manufacturing process and improves the quality of the product.

In general, a color cathode ray tube uses an in-line electron gun, and in the cathode ray tube using the in-line electron gun, red (R), green (G), and blue (B) electron beams are arranged side by side horizontally. In order to converge the three electron beams at one point of the fluorescent surface, the deflection yoke of the cathode ray tube applies a self-converging using a non-uniform magnetic field.

As shown in FIG. 1, the color cathode ray tube has a panel 1 mounted on the front surface of the cathode ray tube and a phosphor of red (R), green (G), and blue (B) on the inner surface of the panel 1. And a shadow mask 4 having a color discrimination function of the electron beam 7 incident on the fluorescent surface 3 behind the fluorescent surface 3 and the rear surface of the panel 1. And a funnel 2 mounted to maintain the interior in a vacuum state, an electron gun 5 and the funnel mounted inside the tubular neck portion retracted to the rear of the funnel 2 to fire the electron beam 6. It consists of a deflection yoke 10 which surrounds the outside of 2) and is installed to deflect the electron beam 6 in the horizontal or vertical direction.

In particular, the deflection yoke 10 vertically shifts the pair of horizontal deflection coils 12 and the electron beams 6 in order to deflect the electron beam 6 emitted from the electron gun 5 in the cathode ray tube in the horizontal direction. It is used to improve the deflection efficiency by reducing the loss of the magnetic force generated by the pair of vertical deflection coil 13, the horizontal deflection coil 12, the current flowing through the vertical deflection coil 13 to deflect The conical ferrite core 11, the horizontal deflection coil 12, the vertical deflection coil 13, and the ferrite core 11 are mechanically fixed and coupled while determining the relative positions of the horizontal deflection. The holder 14 which serves to insulate the coil 12 and the vertical deflection 13 and to be coupled to the cathode ray tube to be applied at the same time, the neck side of the holder (14) Mainly installed in vertical COMA free coil to improve the comma aberration generated by the magnetic field, and is installed at the end of the neck side of the holder 14, the cathode ray tube and the deflection yoke 10 of FIG. It consists of a ring band for coupling, and a magnet mainly installed at the end of the opening of the deflection yoke 10 and used to correct raster distortion (hereinafter referred to as distortion) on the screen.

In particular, in the deflection yoke 10 illustrated in FIGS. 2 and 3, the horizontal deflection coil 12 forms a horizontal deflection magnetic field by applying a horizontal deflection current to the upper deflection coil and the lower deflection coil, and thus, in the electron gun 5. It serves to deflect the emitted electron beam 6 in the horizontal direction.

Referring to the operation of the prior art, the conventional deflection yoke 10 shown in FIG. 2 supplies a current having a frequency of 15.75 kHz or more to the horizontal deflection coil 12, and thus generates A magnetic field is used to deflect the electron beam inside the cathode ray tube in a horizontal direction, and a current having a frequency of 60 Hz is generally flowed into the vertical deflection coil 13, thereby generating an electron beam in the vertical direction using a magnetic field generated accordingly. It is biased.

And by using the non-uniform magnetic field by the horizontal deflection coil (12) and the vertical deflection coil (13) of the self-convergence type that allows the three electron beam to achieve convergence on the screen even without using a separate additional circuit and additional device The deflection yoke 10 is mainly developed.

That is, the windings of the horizontal deflection coils 12 and the vertical deflection coils 13 are adjusted to produce barrel or pincushion type magnetic fields for each part (opening part, middle part, and neck part), and three electron beams are deflected differently according to their positions. The force is experienced so that the light can be collected at the same point at different distances from the starting point of the electron beam to the fluorescent surface 3 which is the arrival point.

In addition, when a current is applied to the deflection coils 12 and 13 to create a magnetic field, it is difficult to deflect the electron beam to the front of the screen only by the magnetic field by the coil, and the ferrite core 11 of the high permeability is used on the return path of the magnetic field. By minimizing the loss, the magnetic field is increased to increase the magnetic force.

In addition, the pair of horizontal deflection coils are composed of an upper horizontal deflection coil and a lower horizontal deflection coil made of a saddle shape as shown in FIG. 3, and after connecting the upper and lower horizontal deflection coils in parallel, a horizontal deflection current having a sawtooth wave shape. By passing through to form a pincushion-like horizontal deflection magnetic field as shown in FIG.

When three electron beams 6, ie, three red, green, and blue beams emitted from the electron gun 5 pass through the horizontal deflection magnetic field region, the force received by the electric electron beam by Fleming's left-hand law is determined by the inner surface of the horizontal deflection coil. It is deflected in the horizontal direction in inverse proportion to the square of the distance between the electron beam and the electron beam.

The recent development of CRTs is flattened, so when the three-color electron beam reaches the fluorescent surface, the distance between the center and the outside of the screen is much different than that of the general CRT, so the raster of the screen forms pincushion distortion at the top and bottom.

For this reason, the distortion is corrected by the magnets attached to the upper and lower sides of the holder opening of the deflection yoke.

In addition, the electron beam 6 radiated from the electron gun passes through the electrode portion of the electron gun and passes through the deflection section of the deflection yoke 10. At this time, the electron beam does not have an abnormality in the mechanical alignment of the tricolor portion of the electron gun itself, or the electron gun is not abnormal. In this case, deflection coils of the deflection yoke or other deflection yoke correction parts, and misconvergence occurring on the deflection yoke assembly are usually present.

This kind of misconvergence can be classified into many kinds in fact, but it can be classified into two cases, namely, occurring on the axis of the screen and occurring on the outside of the screen.

This misconvergence is basically a form that compensates for misconvergence by taking the primary responsibility in the deflection yoke manufacturing process and going through its own post-process. After the deflection yokes are introduced into the ITC process, the misconvergence arising from unmatching when the CRT and deflection yoke are combined is secondarily compensated in the ITC process.

As a method of correcting when the above-described X-axis lateral symmetry misconvergence occurs on the screen as shown in FIG. 4, the deflection yoke is conventionally used to separate the deflection yoke from the CRT and to fix the ferrite material near the inner side of the horizontal deflection coil 12. The solution is to change the shape of the horizontal deflection field as shown in FIG.

This problem of the prior art is as follows.

In order to improve the X-axis transverse symmetry misconvergence on the screen as shown in FIG. 4, the characteristics of the winding product itself before the assembly of the deflection yoke coil should be basically corrected, but the phenomenon occurring after the assembly occurs even in the correct state. This is a problem experienced by conventional deflection yoke manufacturers.

Although the above problem can be corrected to some extent in the deflection yoke manufacturing process, it is also a problem that there is a limit to completely eliminate the amount of misconvergence.

For this reason, the X-axis lateral symmetry misconvergence as shown in FIG. 4 attaches a correction material made of a soft ferrite material to the inner surface of the horizontal deflection coil 12 to artificially form the horizontal deflection magnetic field as shown in FIG. 6 by unbalance. The electron beam is affected by the change of the magnetic field, and the horizontal symmetric misconvergence as shown in FIG. 4 can be corrected, but this causes another misconvergence in other parts of the screen. There is a limit and it can be said that it also adversely affects work productivity.

6, the horizontal deflection magnetic field of the deflection yoke is assumed to be normal when the electron gun is properly arranged. For example, when the left deflection field is shown, the upper portion is a strong pincushion magnetic field and the lower portion is unbalanced in the form of a weak pincushion magnetic field. When the R Grace Chap occurs as shown in FIG.

Conversely, in the deflection yoke fabrication check process, the correction of the soft ferrite material is attached to the coil to the coil to correct the X-axis transverse symmetry misconvergence by artificially changing the shape of the unbalanced magnetic field as shown in FIG. 11. It can be said that the above-mentioned problem occurs in this process,

In addition, even though the magnetic field emitted by the deflection yoke is normal without unbalance, the radiated electron beam basically passes through the deflection yoke section by the mechanical rotation of the electron gun in front of the deflection yoke. Generates type misconvergence.

This phenomenon mainly occurs when many CRTs and deflection yokes are matched and matched in the ITC process. In this case, a method for correcting the misconvergence is to use a yumi-correction circular magnet attached to the neck of the deflection yoke. In this case, since the magnet is located ahead of the coil yoke of the deflection yoke, even when the deflection yoke is subjected to the force of the deflection magnetic field, it directly affects the shape of the electron beam near the electron beam in the previous stage. However, there is a problem that the corner of the screen is broken by causing the electron beam to be distorted.

As described above, there is a problem in the manufacturing check process of the deflection yoke, and in ITC process, there is a problem of focus deterioration after adjusting the circular magnet. Therefore, there is a problem in the conventional method of correcting the X-axis transverse symmetry misconvergence as shown in FIG. have.

In order to improve the above problems, the present invention is to improve the shape of the ferrite core to increase the magnetic efficiency by reducing the magnetic force loss of the horizontal deflection coil and the vertical deflection coil is composed of a main core and an auxiliary core that can be arbitrarily adjusted in combination with it. Therefore, an object of the present invention is to provide a deflection yoke for a cathode ray tube that can correct an X-axis transverse symmetric misconvergence correction by a deflection yoke itself.

1 is a schematic configuration diagram of a CRT.

2 is a partial cross-sectional view showing a conventional deflection yoke configuration.

3 is a cross-sectional view taken along line AA ′ of FIG. 2 showing a conventional deflection yoke configuration;

4 is X-axis Grace Misconvergence

5 is a case where the gun alignment is misaligned

6 is a case where the magnetic field of the deflection yoke is distorted

7 is a front view and a side view of a conventional core shape.

8 is a front view and a side view of the core shape of the present invention.

9 is an exploded perspective view of the main core and the auxiliary core of the present invention.

Figure 10 is a perspective view of the coupling state of the main core and the secondary core of the present invention.

11 shows a normal magnetic field in a conventional coil and core.

12 is a normal magnetic field in the core of the present invention.

Figure 13 is a R-grace Chapel forming magnetic field as the core of the present invention

Figure 14 is a B-grace chapel forming a magnetic field of the present invention

* Explanation of symbols for main parts of the drawings

1: Panel 2: Funnel

3: fluorescent surface 4: shadow mask

5: electron gun 6: electron beam

10: deflection yoke 11: core

12: horizontal deflection coil 13: vertical deflection coil

14: holder 20: jucoa

21: coupling portion 30: auxiliary core

31: auxiliary core holder 32: holder handle

In order to achieve the above object, in the present invention, the ferrite core of the deflection yoke is composed of a main core and an auxiliary core, and the coupling part is formed to be coupled to each other, and the auxiliary core is fixed to the auxiliary core holder. The auxiliary core holder is coupled to the main core, and the auxiliary core fixed to the auxiliary core holder is characterized by consisting of two or more.

The auxiliary core holder is formed with a holder handle portion to easily rotate the position of the auxiliary core, the auxiliary core is characterized in that the magnetic permeability of equal or more than the permeability of the main core.

Hereinafter, embodiments of the present invention will be described in detail.

The ferrite core of the deflection yoke 10 according to the present invention is composed of a main core 20 and an auxiliary core 30.

8 illustrates a core shape of the present invention, and FIG. 9 illustrates a state in which the present main core 20 and the auxiliary core 30 are separated from each other, and the auxiliary core 30 has an auxiliary core holder 31. It is fixed to, and the secondary core holder 31 is configured to be coupled to the main core (20).

The main core 20 has a coupling portion 21 is formed to be coupled to each other and the secondary core 30.

Two or more auxiliary cores 30 fixed to the auxiliary core holder 31 may be configured.

The auxiliary core holder 31 has a holder handle 32 is formed to easily rotate the position of the auxiliary core 30, the auxiliary core 30 is equal to or equal to the magnetic permeability of the main core 20 It has more than permeability.

In the present invention, to solve the conventional problems as described above, by changing the shape of the ferrite core applied to the deflection yoke (2) and to install the auxiliary core of a separate design in the upper end of the changed core to solve the conventional problems.

First, Fig. 7 is a diagram showing the shape of a conventional core, and the core has a round shape.

The core according to the present invention has the shape as shown in Fig. 8, and the end portion is scraped off a portion of the outer circumferential surface of the core, rather than an extension of the thickness continuous to the upper end of the core, and is processed like a portion of a small cylinder. Of course, this part is also processed as a part of the whole body.

Next, in FIG. 9, in addition to the main core 20 of FIG. 8, there are related articles related to the auxiliary core 30 that are to be separately coupled to the upper portion of the main core 20.

First, the auxiliary cores 30 are positioned to face each other in a line of 180 degrees, and the auxiliary core holder 31 for moving the auxiliary cores 30 is manufactured as a plastic injection molding so that the auxiliary cores 30 It can be inserted and fixed inside.

At this time, the auxiliary core 30 is configured to use a material having excellent permeability than the material of the main core 20.

Since the size is small compared to the total area of the main core, the material having excellent permeability is used to increase the variation of the magnetic field shape according to the position rotation.

Next, by forming a holder handle 32 on one side of the auxiliary core holder 31 was configured to rotate the auxiliary core 30 in a circular position.

The magnet 1 for correction, which can correct the upper and lower inner pincushion distortion to the center of the screen, adheres closely to the opening flange of the horizontal deflection coil, and the magnet 2 for correction has the polarity opposite to that of magnet 1. The upper and lower inner pincushion raster distortion characteristics of the electric deflection yoke are attached to the upper and lower sides of the openings of the electric deflection yoke, and the deflection yoke 10 is configured to greatly improve the characteristics of the upper and lower inner pincushion raster distortion.

Such operation of the present invention will be described.

Conical ferrite core of deflection yoke focuses on magnetic flux and improves the efficiency of magnetic field, and since it is usually in a circular state, it is known that the position does not break the shape of magnetic field at the time of assembly during rotation in deflection yoke process. ought.

However, the core rework also suffers from the problem of dispersion, so the entire core product is not the epicenter.

In fact, as a result of dimensional measurements, it is a plastic product, and is formed in the form of a rounded circle, ie, a fine oval, strictly speaking.

If the phenomenon worsens a little, the magnetic field of the normal deflection yoke can be changed, and this causes the X-axis transverse symmetry misconvergence described in FIG. 4.

In view of the above, the present invention has been configured such that the core of the deflection yoke can be corrected without using a separate ferrite attachment material on the inner shaft of the deflection coil as necessary or according to the screening phenomenon.

First, the main core 20 is made in the form of an entire circle, assuming that the whole provides efficiency to the magnetic field evenly, and the part where the auxiliary core 30 is positioned by the auxiliary core 30 coupled thereon The magnetic field efficiency of the entire core is strongly applied.

Using the same principle, the following operation is described.

In FIG. 11, the conventional deflection yoke shown in FIG. 7 uses a conventional core, and this state is used as a convergence form when a normal magnetic field is generated. In this case, it is a convergence form when a normal magnetic field is generated. The X-axis transverse symmetry misconvergence is almost zero.

Next, FIG. 12 shows that the main core 20 and the sub core 30 of the present invention are in the basic position, and of course, the basic characteristics of the deflection yoke 10 are optimized in the magnetic field or convergence at the basic positions of the cores. have.

Again, the electrical X-axis transverse symmetry misconvergence can be called zero.

13 is a form in which the auxiliary core 30 of the present invention is rotated about 45 degrees counterclockwise with respect to the main core 20. In this case, the auxiliary core 30 is positioned at the upper and lower limits of the first and third positions. Since the magnetic field efficiency of the magnetic field is strong, the shape of the magnetic field is as shown in FIG. 13. As a result, when B is left deflected, R shows a convergence deformation of R upward. This results in a change in convergence that is relatively higher than B.

Next, in FIG. 14, the auxiliary core 30 of the present invention is rotated about 45 degrees in the counterclockwise direction. In this case, the magnetic field efficiency of the second and fourth quadrants becomes stronger as opposed to FIG. The magnetic field shape has a strong pincushion shape, which changes the convergence of the part. In the case of the left deflection, B is relatively biased upward than R, resulting in a change in convergence.

Due to this operation, the deflection yoke can be easily compensated for beauty misconvergence by using the main core and the auxiliary coil of the present invention from the outside without detaching from the CRT.

According to the present invention as described above, the deflection yoke to which the main and auxiliary cores for the X-axis transverse symmetry misconvergence correction are attached can obtain the following two effects.

First, the deflection yoke employing the main and auxiliary cores for the X-axis transverse symmetry misconvergence correction according to the present invention saves time for correcting the misconvergence and also causes the miss to worsen when the misconvergence is corrected. You can reduce the point of convergence.

Another can be used for additional use in ITC processes.

Cost reduction and elimination of misconvergence of other parts can be restrained due to the elimination of grace correction magnet.

Claims (5)

Horizontal and vertical deflection coils for deflecting the electron beam in the horizontal or vertical direction, and ferrite cores to increase magnetic efficiency by reducing the loss of magnetic force generated from the horizontal and vertical deflection coils, and the horizontal deflection coils, the vertical deflection coils, and the ferrite cores. In a deflection yoke for a cathode ray tube fixed in a predetermined position and consisting of a holder for insulation between a horizontal deflection coil and a vertical deflection coil, The ferrite core of the deflection yoke 10 is composed of a main core 20 and an auxiliary core 30, the auxiliary core 30 is fixed to the auxiliary core holder 31, the auxiliary core holder 31 is Deflection yoke for a cathode ray tube, characterized in that configured to be coupled to the main core (20). The method of claim 1, Deflection yoke for the cathode ray tube, characterized in that the secondary core 30 is fixed to the secondary core holder 31 is composed of two or more. The method of claim 1, Deflection yoke for a cathode ray tube, characterized in that the handle portion 32 is formed in the auxiliary core holder (31). The method of claim 1, The auxiliary core (30) is a deflection yoke for cathode ray tubes, characterized in that the magnetic permeability of the main core 20 or more than or equal to. The method of claim 1, The main core 20 is a yoke for a cathode ray tube, characterized in that the coupling portion 21 is formed to be coupled to each other and the auxiliary core (30).