JPH056744A - Electromagnetic focusing device - Google Patents

Abstract

PURPOSE:To improve the efficiency in a high deflecting frequency by using a soft ferrite of a polycrystalline sintered body which is a composite compound of Fe2O4 and a divalent metal as at least either one material of a center yoke and a side yoke. CONSTITUTION:As materials of a center yoke 12 and side yokes 8, 15, not soft iron but a soft ferrite represented by the general formula MFe2O4 is used. In the general formula, M corresponds to a divalent metal such as manganese, nickel copper and zinc. Since the soft ferrite has an extremely high resistivity, compared with other metal magnetic bodies, with respect to electric characteristic, the equivalent resistance can be suppressed low also in a high current frequency area difficult to generate an eddy current.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic focusing device used in a CRT display device, and more particularly, it is an object of the present invention to provide an efficient electromagnetic focusing device even if the scanning frequency (deflection frequency) is high. There is.

[0002]

2. Description of the Related Art Generally, an image plane of an electron beam in a cathode ray tube (CRT) is on a spherical surface. Therefore, in a normal CRT having a flat fluorescent screen as an image plane, defocusing occurs in proportion to almost the square of the deflection distance from the center of the fluorescent screen. In order to prevent defocus, a CRT display device using electromagnetic deflection uses a dynamic focus circuit. Such a CRT display device is called an electromagnetic focus type display.

FIG. 5 shows a CRT peripheral portion of a general electromagnetic focus type display. Reference numeral 1 is a CRT, 2 is a deflection yoke, 3 is a focus yoke, 4 is a deflection circuit, and 5 is a focus circuit. The focus circuit 5 is composed of a DC focus circuit for focusing the electron beam evenly on the entire screen, and horizontal and vertical dynamic focus circuits for adjusting the focusing power according to each part of the screen.

FIG. 6 shows a detailed view of an electromagnetic focusing device including the focusing yoke shown in FIG. The electromagnetic focusing device 6 shown in FIG. 6 is a conventional general device used for a CRT having a neck diameter of 29φ. In the figure, 7 and 16 are bands for attachment to a CRT, and 8 and 15 are side yokes arranged on both sides of the permanent magnets 10 and 14. The side yokes 8 and 15 are for reducing leakage of magnetic flux generated from the permanent magnets 10 and 14. 9
Is a horizontal dynamic focus coil for correcting the horizontal dynamic focus. 1
1 is a holder and 12 is a center yoke.
1. The center yoke 12 and the side yokes 8 and 15 serve as paths for magnetic flux generated from the permanent magnets 10 and 14. Reference numeral 13 denotes a main coil, which is often used for both static focus correction and vertical dynamic focus correction. The permanent magnets 10 and 14, the center yoke 12, and the side yokes 8 and 15 each have a concentric cylindrical shape. A horizontal dynamic focus coil 9 and a main coil (static coil) 13 are concentrically wound inside a concentric cylindrical magnetic body composed of permanent magnets 10 and 14, a center yoke 12, and side yokes 8 and 15. Are arranged. The neck of the CRT is inserted inside the horizontal dynamic focus coil 9 and the main coil 13. The main circuit of the DC focus circuit is a concentric cylindrical magnetic body composed of permanent magnets 10 and 14, a center yoke 12, and side yokes 8 and 15. In addition to this, a horizontal dynamic focus coil 9 for horizontal dynamic focus correction and a main coil 13 for static focus correction are generally added.

Here, for the permanent magnets 10 and 14, alloys of cobalt and samarium, which are rare earth elements having excellent temperature characteristics, are used. Center yoke 12 and side yokes 8,
15 also uses soft iron, which has excellent temperature characteristics. Figure 7
The equivalent resistance frequency characteristic of the electromagnetic focusing device 6 is shown in FIG.
As shown in FIG. 7, as the frequency of the current flowing through the horizontal dynamic focus coil 9 increases (that is, the horizontal scanning frequency increases), the equivalent resistance of the coil 9 increases. In FIG. 7, the measurement value described as the whole (6) indicates that the electromagnetic focusing device 6 is not disassembled.
The equivalent resistance of the whole is measured, and the measurement value described as only the coil (9) is obtained by taking out only the horizontal dynamic focus coil 9 and the other is the same.

From the equivalent resistance frequency characteristic curve of only the horizontal dynamic focus coil 9 (this coil is a single winding of copper) shown in FIG. 7, there is no significant copper loss even with a single wire of copper up to a current frequency of around 35 kHz. However, it can be seen that when the current frequency becomes higher than that, the skin effect loss of the coil copper wire increases, and the equivalent resistance increases sharply.
Further, as can be seen from FIG. 6, in the immediate vicinity of the coil 9,
Since the metal magnets of the permanent magnets 10 and 14, the center yoke 12, and the side yokes 8 and 15 are present, the magnetic field generated from the coil 9 causes eddy current loss in the metal magnets. Therefore, the equivalent resistance of the coil 9 increases 100 times at the current frequency of 100 kHz as compared with the current frequency of 120 Hz. As described above, the conventional electromagnetic focusing device is very inefficient.

[0007]

SUMMARY OF THE INVENTION The problem to be solved by the present invention is to provide an electromagnetic focusing device which is efficient even if the horizontal scanning frequency becomes high and the current frequency flowing through the horizontal dynamic focus coil becomes high. Is
The point is what kind of measures should be taken.

[0008]

Therefore, in order to solve the above-mentioned problems, the present invention is designed so that the focus of the electron beam in the cathode ray tube is substantially proper at any point in the horizontal direction on the screen. A horizontal dynamic focus coil, a static coil for adjusting static focus, a permanent magnet arranged in the vicinity of the static coil, a center yoke serving as a magnetic flux path of the permanent magnet, and both sides of the permanent magnet. An electromagnetic focusing device that is arranged and includes a side yoke that serves as a path of a magnetic flux of the permanent magnet, wherein the permanent magnet, the center yoke, and the side yoke each have a concentric cylindrical shape. Concentric cylindrical magnet composed of the center yoke and the side yoke In the electromagnetic focus device, wherein the horizontal dynamic focus coil and the static coil are arranged and wound in concentric circles, and the neck of the cathode ray tube is inserted into the concentric cylindrical magnetic body. An electromagnetic focus device in which at least one of the center yoke and the side yoke is made of a soft ferrite of a polycrystalline sintered body which is a composite compound of at least iron oxide Fe ₂ O ₄ and a divalent metal. Is provided.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION In the electromagnetic focus device of the present invention, the materials of the center yoke 12, side yokes 8 and 15, and permanent magnets 10 and 14 shown in FIG.
Since the configuration of the entire device is the same as the conventional one, only the material will be described here. 1 is a diagram showing the equivalent resistance frequency characteristic of the first embodiment, FIG. 2 is a diagram showing the equivalent resistance frequency characteristic of the second embodiment, and FIG. 3 is a diagram showing the equivalent resistance frequency characteristic of the third embodiment.

In the first embodiment, the materials of the center yoke 12 and the side yokes 8 and 15 are not soft iron but general formula M.
The soft ferrite is represented by Fe ₂ O ₄ (here, Mn—Zn based soft ferrite is used). M in the general formula corresponds to a divalent metal such as manganese, nickel, copper or zinc. Practically used soft ferrite is a polycrystalline sintered body which is a compound compounding iron oxide Fe ₂ O ₄ and several kinds of divalent metals. In terms of electrical characteristics, this soft ferrite has a much higher resistivity than other metal magnetic materials, so eddy currents are less likely to occur,
The equivalent resistance can be kept low even in the high current frequency range. The equivalent resistance of the entire device using the conventional soft iron shown in FIG.
As can be seen from comparison with the equivalent resistance of the entire device of this embodiment shown in FIG. 1, the equivalent resistance of the embodiment is greatly reduced, and the loss reduction effect due to soft ferrite formation is great. In addition, the coils 9 and 13 which are focus coils
The central magnetic field of, for example, 7 inches C with a neck diameter of 29φ
At RT, about 330 gauss is the optimum magnetic field. The saturation magnetic flux density of soft ferrite is one digit lower than that of soft iron,
There is more than 4000 gauss, and even with soft ferrite, the optimum magnetic field of the focus coil of 330 gauss is sufficiently satisfied.
Even if only one of the center yoke 12 and the side yokes 8 and 15 was made into a soft ferrite, a sufficient loss reduction effect was obtained.

The second embodiment is a permanent magnet 1 of the first embodiment.
The material of Nos. 0 and 14 was changed from a rare earth composite to hard ferrite. The hard ferrite is a composite compound of barium and iron oxide Fe ₂ O ₃ , a composite compound of strontium and iron oxide Fe ₂ O _3, and the like. Comparing the equivalent resistance of the entire device of the first embodiment shown in FIG. 1 with the equivalent resistance of the entire device of the second embodiment shown in FIG. 2, the equivalent resistance of the second embodiment is smaller. , Permanent magnet 1
It can be seen that the loss reduction effect is further enhanced by making 0 and 14 into hard ferrite. Even if the center yoke 12 and the side yokes 8 and 15 were made of soft iron as in the conventional case and only the permanent magnets 10 and 14 were made into hard ferrite, a sufficient loss reduction effect was obtained.

In the third embodiment, the winding of the horizontal dynamic focus coil 9 of the second embodiment is replaced with a single copper winding to a litz wire. By making the coil 9 a litz wire, the skin effect loss at a current frequency of 35 kHz or more can be significantly reduced. As can be seen by comparing the equivalent resistance of the second embodiment shown in FIG. 2 with the equivalent resistance of the third embodiment shown in FIG. 3, the equivalent resistance of only the coil 9 of the third embodiment and the equivalent of the entire device are shown. Both of the resistances are lower than the equivalent resistance of the second embodiment, and the loss reduction effect by using the litz wire is great.
Of course, in the first embodiment, the loss reduction effect can be obtained even if the coil 9 is made into a litz wire.

Further, the side yoke is required to be thin and to be provided with a hole or the like through which the lead wire of the coil is inserted. Therefore, it is preferable that the side yoke is easy to process. Therefore, the side yoke may be made by injection molding a ferrite-based bonded magnet in which soft ferrite is used as a powder and a nylon-based resin is mixed with the powder. This side yoke is not only easy to process, but also has good dimensional accuracy. A similar method may be used to improve the dimensional accuracy of the center yoke and the permanent magnet.

An electromagnetic focus type display provided with such an electromagnetic focus device is often used as a projection display. In that case, the sensitivity of the horizontal dynamic focus differs for each display due to the number of inches of the CRT, the deflection angle, the difference between front projection and rear projection, the performance of the magnifying lens, and the like. Therefore, the optimum inductance value and the like of the horizontal dynamic focus coil of the electromagnetic focusing device also differs from display to display. Therefore, the optimum electromagnetic focusing device for each display may be selected from each embodiment in consideration of the problems such as the manufacturing cost and the number of manufacturing processes.

Here, a case where the horizontal dynamic focus circuit is the resonance circuit shown in FIG. 4 will be described.
The input signal to this circuit is a horizontal flyback pulse. L1 is a variable inductor for adjustment (whose inductance value is L1), C1 is a resonance capacitor (whose capacitance value is C1), L is a horizontal dynamic focus coil (whose inductance value is L),
R1 is a damping resistance, and R2 is an equivalent resistance of the horizontal dynamic focus coil L. The variable inductance value L1 is obtained by the resonance capacitor C1, the focus coil L, and the variable inductor L1 at the horizontal scanning frequency fH.
It is set to resonate. The resonance condition is as follows. 2πfH C1 = (1 / L + 1 / L1) / (2πfH) When the above condition is satisfied, the waveform of the current flowing through the focus coil L becomes a cosine waveform with the same phase as the flyback pulse of the input signal. Therefore, when the equivalent resistance R2 of the focus coil L increases according to the current frequency as shown in FIG. 7, it becomes difficult for the current to flow through the focus coil L, and a large input signal voltage (wave High price) is required. However, if the input signal voltage is increased, the power consumption increases accordingly. The present invention is designed to reduce the power consumption, and the power consumption can be reduced by an amount corresponding to the improvement of the equivalent resistance frequency characteristics shown in FIGS. 1 to 3 (a reduction in the equivalent resistance). Therefore, in each of the embodiments, even if the current flowing through the focus coil L has a high frequency (the horizontal scanning frequency of the CRT is a high frequency), an efficient electromagnetic focusing operation can be performed.

[0016]

As described above, the electromagnetic focusing device of the present invention can perform an efficient electromagnetic focusing operation even when the horizontal scanning frequency becomes high. Further, the present invention can provide an optimum electromagnetic focus device according to various usage conditions and various CRTs.

[Brief description of drawings]

FIG. 1 is a diagram showing an equivalent resistance frequency characteristic of the first embodiment.

FIG. 2 is a diagram showing an equivalent resistance frequency characteristic of a second embodiment.

FIG. 3 is a diagram showing an equivalent resistance frequency characteristic of a third embodiment.

FIG. 4 is a diagram showing a general circuit of a horizontal dynamic focus circuit.

FIG. 5: CRT of conventional electromagnetic focus display
It is a figure which shows a peripheral part.

FIG. 6 is a diagram showing a structure of a conventional electromagnetic focusing device.

FIG. 7 is a diagram showing an equivalent resistance frequency characteristic of a conventional electromagnetic focusing device.

[Explanation of symbols]

8, 15 Side yoke 9 Horizontal dynamic focus coil 10, 14 Permanent magnet 12 Center yoke 13 Main coil (also serves as a static coil and a vertical dynamic focus coil)

Claims (3)

[Claims] 1. A method for focusing an electron beam on a cathode ray tube at any point in the horizontal direction on a screen,
A horizontal dynamic focus coil that is adjusted so as to achieve substantially proper focus, a static coil that adjusts static focus, a permanent magnet that is arranged in the vicinity of the static coil, and a center yoke that serves as a magnetic flux path of the permanent magnet. The permanent magnets are arranged on both sides of the permanent magnet, and are composed of side yokes that are paths of magnetic flux of the permanent magnets, and the permanent magnets, the center yokes, and the side yokes are concentric cylinders, respectively. Inside the concentric cylindrical magnetic body consisting of the center yoke and the side yoke, the horizontal dynamic focus coil and the static coil are arranged in concentric windings, respectively, the concentric cylindrical magnetic body, Electromagnetic focus device into which the neck of the cathode ray tube is inserted In, at least one of the material of said center yoke and said side yoke, and characterized in that a soft ferrite of at least iron oxide Fe ₂ O ₄ with a complex compound of a divalent metal polycrystalline sintered body Electromagnetic focusing device. 2. A polycrystalline sintered body in which the material of the permanent magnet is a composite compound of at least iron oxide Fe ₂ O ₃ and barium, or a composite compound of at least iron oxide Fe ₂ O ₃ and strontium. The electromagnetic focus device according to claim 1, wherein the electromagnetic focus device is a hard ferrite. 3. Focusing the electron beam on the cathode ray tube at any point in the horizontal direction on the screen,
A horizontal dynamic focus coil that is adjusted so as to achieve substantially proper focus, a static coil that adjusts static focus, a permanent magnet that is arranged in the vicinity of the static coil, and a center yoke that serves as a magnetic flux path of the permanent magnet. The permanent magnets are arranged on both sides of the permanent magnet, and are composed of side yokes that are paths of magnetic flux of the permanent magnets, and the permanent magnets, the center yokes, and the side yokes are concentric cylinders, respectively. Inside the concentric cylindrical magnetic body consisting of the center yoke and the side yoke, the horizontal dynamic focus coil and the static coil are arranged in concentric windings, respectively, the concentric cylindrical magnetic body, Electromagnetic focus device into which the neck of the cathode ray tube is inserted In the material of the permanent magnet, the composite compound of barium and at least iron oxide Fe ₂ O _3, or a hard ferrite polycrystal sintered body is a complex compound, and at least iron oxide Fe ₂ O ₃ and strontium An electromagnetic focus device characterized in that