JPH0746617A - Cathode-ray tube and earth magnetism cancelling method - Google Patents

Abstract

PURPOSE:To correct the deviation of landing position of an electron beam to a minimum by cooperating a magnetic field by a neck cancellation coil in addition to the magnetic field by a tube plane cancellation coil. CONSTITUTION:The deviation of landing position of the electron beam L generated when a cathode-ray tube valve 1 is rotated in earth magnetism Bo forms an elliptical moving locus at four corners of the screen of a face panel 6. Such locus is converted to a straight line moving locus facing with a radial direction by a tube plane cancellation magnetic field B1 by the tube plane cancellation coil 7. While, the deviation of landing position of the beam L is converted to the straight line moving locus facing with a vertical direction by a neck cancellation magnetic field B2 by the neck cancellation coil 8. Therefore, micro aberration facing with a horizontal direction forms the straight line moving locus by cooperating the magnetic field B1 by the coil 7 with the magnetic field B2 by the coil 8. In this way, the deviation of landing position of the electron beam can be corrected to a minimum.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cathode ray tube and a geomagnetism canceling method, and more particularly to a cathode ray tube and a geomagnetism canceling method in which the correction of the electron beam landing position generated when the cathode ray tube is rotated in the earth's magnetism is improved.

[0002]

2. Description of the Related Art In a color cathode ray tube, an electron beam L emitted from an electron gun 3 housed in a neck 2 of a cathode ray tube bulb 1 as shown in FIG. While scanning, the fluorescent film formed on the inner surface of the face panel 6 is irradiated with the light. At this time, the electron beam L scanned by the deflection yoke 5 is made to accurately land on the dot-shaped RGB phosphors forming the phosphor film on the inner surface of the face panel 6 via the shadow mask.

However, when the color cathode ray tube is used and the cathode ray tube bulb 1 is rotated in the geomagnetism B ₀ ,
The geomagnetism B is applied to the electron beam L scanned by the deflection yoke 5.
There is a problem that ₀ acts and the landing position of the electron beam L on the fluorescent film is displaced.

In order to solve this problem, as shown in FIG. 7, a coil 7 [hereinafter referred to as a tube surface cancel coil] is attached to the outer peripheral end surface of the face panel 6 of the cathode ray tube bulb 1, and the tube surface cancel coil 7 is attached. Magnetic field generated by B ₁
In has, by canceling the horizontal component of the geomagnetism B _0, and corrects the landing position on the fluorescent film of the electron beams L be rotated cathode ray tube bulb 1 in geomagnetism B ₀ is deviated .

[0005]

By the way, as described above, the deviation a of the landing position of the electron beam L which occurs when the cathode ray tube bulb 1 is rotated in the geomagnetism B ₀ is as shown in FIG. In screen m, the electron beam L is large at the four corners where it is deflected to the maximum. Then, at the four corners, the cathode ray tube bulb 1 is
When rotated by 0 °, the displacement a of the landing position of the electron beam L becomes an elliptical movement locus.

On the other hand, the canceling magnetic field B ₁ by the tube surface canceling coil 7 cancels the horizontal component of the geomagnetism B _0. As a result, on the screen m of the face panel 6, the landing of the electron beam L described above is performed. The current situation is that the positional deviation b is only converted into a linear movement locus directed in the radial direction as shown in FIG. 9, and the landing positional deviation b is still large.

Therefore, the present invention has been proposed in view of the above problems, and an object of the present invention is to provide a cathode ray tube capable of realizing a correction capable of minimizing the deviation of the landing position of the electron beam. And to provide a method of canceling the geomagnetism.

[0008]

As a technical means for achieving the above object, in a cathode ray tube of the present invention, an electron beam emitted from an electron gun housed in the neck of a cathode ray tube valve is mounted on the outer periphery of a funnel. While irradiating on the fluorescent film formed on the inner surface of the face panel while scanning with the deflection yoke, the tube surface canceling coil wound on the outer peripheral end surface of the face panel is used to change the landing position of the electron beam based on the geomagnetism on the fluorescent film. In a cathode ray tube that is designed to correct the deviation, a neck that causes a tube surface canceling magnetic field or a funnel canceling field that cooperates with the tube surface canceling magnetic field by the tube surface canceling coil near the deflection yoke on the neck outer circumference or funnel outer circumference of the cathode ray tube valve. A cancel coil or funnel cancel coil is wrapped around And wherein the door.

Further, the geomagnetic canceling method of the present invention is
When irradiating the electron beam emitted from the electron gun in the cathode ray tube bulb on the fluorescent film inside the face panel,
A method for correcting a landing position shift of an electron beam on a fluorescent film due to terrestrial magnetism, which cooperates with the tube surface canceling magnetic field in addition to the tube surface canceling magnetic field given at the outer peripheral end surface of the face panel. The neck canceling magnetic field or the funnel canceling magnetic field is applied in a barrel shape at the neck portion or near the deflection yoke of the funnel portion.

[0010]

In the present invention, in addition to the tube surface canceling magnetic field by the tube surface canceling coil, the neck canceling magnetic field by the neck canceling coil or the funnel canceling magnetic field by the funnel canceling coil applied in cooperation with the tube surface canceling magnetic field in the same phase. The deviation of the landing position of the electron beam caused by the rotation of the cathode ray tube bulb in the geomagnetism can be corrected to a minimum.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a cathode ray tube and a geomagnetism canceling method according to the present invention will be described with reference to FIGS. The same parts as those in FIGS. 7 to 9 are designated by the same reference numerals, and a duplicate description will be omitted.

In the color cathode ray tube of the embodiment shown in FIGS. 1 and 2, an electron beam L emitted from an electron gun 3 housed in a neck 2 of a cathode ray tube bulb 1 is deflected by being attached to an outer periphery of a funnel 4. While scanning with the yoke 5, the fluorescent film formed on the inner surface of the face panel 6 is irradiated, and the horizontal component of the geomagnetism B ₀ is canceled on the outer peripheral end surface of the face panel 6 of the cathode ray tube bulb 1. Tube surface canceling coil 7 for generating tube surface canceling magnetic field B ₁
And a neck canceling magnetic field B ₂ cooperating in the same phase as the tube surface canceling magnetic field B _{1 on} the outer circumference of the neck _2.
The neck canceling coil 8 for generating is attached.

[0013] In this embodiment, when rotating the cathode ray tube bulb 1 in geomagnetism B _0, with a tube surface canceling magnetic field B ₁ produced by the tube surface cancel coils 7, geomagnetism B ₀
The residual landing position deviation b (see FIG. 9) when canceling the horizontal component of the above can be minimized by the neck canceling magnetic field B ₂ cooperating in phase with the tube surface canceling magnetic field B _1. it can.

That is, the displacement a of the landing position of the electron beam L, which occurs when the cathode ray tube bulb 1 is rotated in the geomagnetism B ₀ , is at the four corners of the screen m of the face panel 6.
The elliptical movement locus [see FIG. 8] is the displacement b of the landing position converted into a linear movement locus directed in the radial direction by the tube surface canceling magnetic field B ₁ by the tube surface canceling coil 7 [FIG. 9]. reference〕. On the other hand, according to the neck canceling magnetic field B ₂ by the neck canceling coil 8,
The deviation c of the landing position of the electron beam L due to the geomagnetism B ₀ is converted into a linear movement locus which is oriented in the vertical direction as shown in FIG. Therefore, when the neck canceling magnetic field B ₂ by the neck canceling coil 8 is made to cooperate in addition to the tube canceling magnetic field B ₁ by the tube canceling coil 7,
As shown in FIG. 4, the landing position deviation d can be set as a minute linear movement trajectory that is oriented in the horizontal direction, the horizontal component of the geomagnetism B ₀ can be largely canceled, and the landing position deviation of the electron beam L can be canceled. Can be further corrected.

Next, in the color cathode ray tube according to the second embodiment shown in FIGS. 5 and 6, the outer surface of the face panel 6 of the cathode ray tube bulb 1 has a tube surface canceling function for canceling the horizontal component of the geomagnetism B _0. with mounting the tube surface cancel coil 7 for generating a magnetic field B _1, the deflection yoke 5 near the periphery of the funnel 4, funnel cancellation for generating a funnel cancellation magnetic field B ₃ cooperating with the tube surface canceling magnetic field B ₁ and the same phase Attach the coil 9. The funnel canceling coil 9 may be incorporated inside the front end of the deflection yoke 5, or may be arranged close to the front end of the deflection yoke 5. In order to make the funnel canceling magnetic field B ₃ by the funnel canceling coil 9 into a barrel shape, a curved core 10 is attached along the outer circumference of the funnel 4.

[0016] In this embodiment, when rotating the cathode ray tube bulb 1 in geomagnetism B _0, with a tube surface canceling magnetic field B ₁ produced by the tube surface cancel coils 7, geomagnetism B ₀
Of the deviation of the landing position remaining in canceling b [see Figure 9] a horizontal component, the tube surface canceling magnetic field B ₁
It can be completely canceled by the funnel canceling magnetic field B ₃ cooperating in phase with.

That is, the landing position deviation a of the electron beam L caused when the cathode ray tube bulb 1 is rotated in the geomagnetism B ₀ is an elliptic movement locus at the four corners of the screen of the face panel 6. 8], the landing position b is converted into a linear movement locus directed in the radial direction by the tube surface canceling magnetic field B ₁ by the tube surface canceling coil 7 (see FIG. 9). Therefore, in addition to the tube surface canceling magnetic field B ₁ by the tube surface canceling coil 7, the funnel canceling magnetic field B ₃ by the funnel canceling coil 9 is added.
6 shows that the deviation b of the landing position of the electron beam L is a linear movement locus directed in the radial direction.
Since the funnel canceling magnetic field B ₃ has a barrel shape as shown in FIG. 5, it can be applied in the direction opposite to the landing position shift direction, and the landing position shift b of the electron beam L can be completely canceled.

[0018]

According to the present invention, the neck canceling magnetic field by the neck canceling coil or the funnel canceling magnetic field by the funnel canceling coil applied in addition to the tube surface canceling magnetic field by the tube surface canceling coil has the same phase as the tube surface canceling magnetic field. Since the deviation of the landing position of the electron beam caused by the rotation of the cathode ray tube valve in the geomagnetism can be corrected to a minimum, the position of the electron beam landing position can be corrected even if the cathode ray tube is rotated in the geomagnetism. It is possible to provide a high-quality cathode ray tube capable of maintaining high accuracy.

[Brief description of drawings]

FIG. 1 is a plan sectional view showing an embodiment of a cathode ray tube according to the present invention.

FIG. 2 is a sectional view taken along the line II of FIG.

FIG. 3 is an explanatory view of a face panel screen showing a deviation of the landing position of an electron beam due to a neck canceling magnetic field.

FIG. 4 is an explanatory diagram of a face panel screen showing a deviation of a landing position of an electron beam when a neck canceling magnetic field is made to cooperate with a tube surface canceling magnetic field.

FIG. 5 is a front sectional view showing another embodiment of the present invention.

6 is a sectional view taken along line II-II in FIG.

FIG. 7 is a sectional view showing a conventional cathode ray tube equipped with a tube surface canceling coil.

FIG. 8 is an explanatory diagram of a face panel screen showing a displacement of an electron beam landing position due to geomagnetism in the absence of a tube surface canceling magnetic field.

FIG. 9 is an explanatory diagram of a face panel screen showing a deviation of an electron beam landing position due to a tube surface canceling magnetic field.

[Explanation of symbols]

1 cathode ray tube valve 2 neck 3 electron gun 4 funnel 5 deflection yoke 6 face panel 7 tube surface canceling coil 8 neck canceling coil 9 funnel canceling coil B ₀ geomagnetism B ₁ tube surface canceling magnetic field B ₂ neck canceling magnetic field B ₃ funnel canceling magnetic field L Electron beam

Claims (4)

[Claims] 1. A face for irradiating a fluorescent film formed on the inner surface of a face panel with an electron beam emitted from an electron gun housed in the neck of a cathode ray tube bulb while scanning with a deflection yoke mounted on the outer periphery of a funnel. In the cathode ray tube in which the deviation of the landing position of the electron beam on the fluorescent film due to the earth's magnetism is corrected by the tube surface canceling coil wound around the outer peripheral edge of the panel, the tube surface canceling coil is placed around the neck of the cathode ray tube valve. A cathode ray tube having a neck canceling coil for generating a neck canceling magnetic field that cooperates with the tube surface canceling magnetic field. 2. A fluorescent film formed on the inner surface of the face panel is irradiated with an electron beam emitted from an electron gun housed in the neck of a cathode ray tube bulb while being scanned by a deflection yoke mounted on the outer periphery of the funnel. In the cathode ray tube that is designed to correct the deviation of the landing position of the electron beam due to the geomagnetism on the fluorescent film by the tube surface canceling coil wound around the outer peripheral edge of the panel, in the vicinity of the deflection yoke on the outer periphery of the funnel of the cathode ray tube valve, A cathode ray tube, comprising: a funnel canceling coil that generates a funnel canceling magnetic field that cooperates with the tube canceling magnetic field generated by the tube canceling coil. 3. When the electron beam emitted from the electron gun in the cathode ray tube bulb is irradiated onto the fluorescent film on the inner surface of the face panel, the deviation of the landing position of the electron beam on the fluorescent film due to geomagnetism is corrected. The method is characterized in that, in addition to the tube surface canceling magnetic field applied at the outer peripheral end surface of the face panel, a neck canceling magnetic field cooperating in phase with the tube surface canceling magnetic field is applied at the neck portion. Geomagnetic cancellation method. 4. When the electron beam emitted from the electron gun in the cathode ray tube bulb is irradiated onto the fluorescent film on the inner surface of the face panel, the deviation of the landing position of the electron beam on the fluorescent film due to geomagnetism is corrected. In this method, in addition to the tube surface canceling magnetic field applied at the outer peripheral end surface of the face panel, a funnel canceling magnetic field cooperating in phase with the tube surface canceling magnetic field is applied in a barrel shape near the deflection yoke of the funnel portion. A method for canceling the geomagnetism characterized in that