Electric lamp and discharge devices: systems – Cathode ray tube circuits – Cathode-ray deflections circuits
Reexamination Certificate
2002-01-16
2003-02-25
Wong, Don (Department: 2821)
Electric lamp and discharge devices: systems
Cathode ray tube circuits
Cathode-ray deflections circuits
C315S369000
Reexamination Certificate
active
06525494
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an electron gun for a color cathode ray tube (CRT), and, more particularly, to an in-line electron gun for a color CRT having improved electrodes that form at least one quadrupole lens.
2. Description of the Related Art
A typical electron gun for a color CRT is installed in a neck portion of the CRT and emits thermal electrons. The performance of the color CRT depends on the state of electron beams emitted from the electron gun and landing on a fluorescent film. Thus, numerous electron guns have been developed to improve focus properties and reduce aberration of an electron lens so that the electron beams emitted from the electron gun accurately land on phosphor dots of the fluorescent film. In particular, to reduce the total length of a CRT, the deflection angle of the electron beams is increased and the length of the electron gun is reduced. Since the focusing distance of an electron beam landing on a peripheral portion of a fluorescent film is larger than that of an electron beam landing on a central portion of the fluorescent film, the focus of the electron beams at the peripheral portion of a screen is inferior to the focus at the central portion of the fluorescent film.
As deflection angle increases, an incident angle of an electron beam with respect to the fluorescent film decreases. Accordingly, the distortion of the electron beam increases exponentially with deflection angle so that the diameter of a spot produced by an electron beam landing on the fluorescent film increases. The electron beam emitted from the electron gun is converged throughout the entire surface of a screen by a non-uniform electric field including a pincushion horizontal deflection electric field and a barrel vertical deflection electric field generated by a deflection electric field of the electron gun. This non-uniform electric field diverges the beam horizontally and focuses the beam vertically, forming a horizontally elongated beam at the periphery of a screen, lowering resolution. Of three in-line electron beams lying in a horizontal plane and produced by an electron gun for a color CRT, the two outside electron beams are more affected by astigmatism than is the central electron beam that is disposed between the outside beams. It is advantageous to increase a correction force applied to the outside electron beams of the three in-line electron beams relative to the force applied to the central electron beam. Conventional electron guns adopt quadrupole lenses, the operation of which is described below, to adjust the length of focus and compensate for the distortion of an electron beam.
When a dynamic voltage applied to an electrode is increased as an electron beams emitted from a triode portion of the electron gun pass a pre-focus point and arrive at a quadrupole lens, the electron beams move in an electric field direction of the quadrupole lens. The electrons of the electron beams receive a divergent force in the vertical direction and a focusing force in the horizontal direction. Thus, when the beams are deflected toward the peripheral portion of a screen, the distortion of the electron beams due to the deflection electric field, the incident angle of the electron beams, and the curvature of a surface of the screen, is compensated. However, when the dynamic voltage applied to the electrode forming the quadrupole lens increases, the focal lengths and the distortions of each of the electron beams, among the three in-line electron beams, are different, because of corrections due to the diameter of a large diameter electron lens and a difference in the magnifying power of the outside electron beams as compared to the central electron beam.
Electron guns correcting astigmatism of an electron beam deflected toward the peripheral portion of a screen are disclosed in U.S. Pat. No. 4,701,677, U.S. Pat. No. 4,814,670, and U.S. Pat. No. 5,027,043.
Electron guns described in these publications include a means for converting an electron beam from a linear path, including a quadrupole lens, to correct astigmatism with a self convergence deflection yoke. The quadrupole lens has different voltages applied to electrodes where vertically elongated electron beam passing holes or horizontally elongated electron beam passing holes are located. This electron gun can converge the three in-line electron beams at one point and correct distortion of the beam due to vertical and horizontal deflection magnetic fields deflecting of the electron beam.
As the surface of a CRT becomes flatter and the deflection angle of electron beams increases, the difference in the focal lengths between the central and peripheral portions of a screen increases toward the periphery. Astigmatism of the electron beams at the periphery of the screen is thus produced by the deflection yoke. Therefore, an electron gun needs strong astigmatism and focal length correction forces to avoid loss of resolution at the periphery of the screen.
To obtain the strong astigmatism and focal length correction forces, a large difference in electric potential between electrodes forming the quadrupole lens and, accordingly, a high voltage, is needed. However, the high voltage may cause a problem in circuit reliability and withstand voltage between the electrodes of an electron gun. Also, when an electron beam is incident on the periphery of a screen, the incident angle of the beam decreases horizontally and increases vertically due to the function of the quadrupole lens adjacent to the main lens, that is, focusing the beam horizontally and diverging the beam vertically. Thus, the horizontal dimension of a spot at the periphery of a screen increases. The astigmatism varying with the deflection of an electron beam becomes serious as the deflection angle of the electron beam by the deflection yoke increases. Also, convergence is deteriorated.
A color CRT having a quadrupole lens compensating for these problems is disclosed in U.S. Pat. No. 6,051,919. In this CRT, the length of a plate of each plate electrode, at surfaces forming a quadrupole lens and facing each other, is different. The length at the central electron beam is longer than at the outside electron beams. Thus, the central electron beam has a stronger focus correction for correcting convergence and astigmatism at the peripheral of a screen than the outside electron beams. However, in the CRT having this quadrupole lens, as the deflection angle of an electron beam increases, the dynamic voltage applied to the electrode of the quadrupole lens is increased. As the dynamic voltage increases, the difference in the astigmatism correction of the central electron beam and of the side electron beams increases at the periphery of a screen, so that the focus property deteriorates.
In particular, this differential astigmatism correction phenomenon occurs severely in an electron gun with a large diameter electrode and a main lens. That is, when a dynamic voltage synchronized with a deflection signal is applied to the large diameter electrode, since the ratio of change in focusing of an electrostatic lens in vertical and horizontal directions for the central electron beam is greater than that for each of the side electron beams, the differential astigmatism correction is severe. This phenomenon occurs because equipotential lines
2
(see
FIG. 2
) are gradually distributed in the horizontal direction, compared to equipotential lines
1
(see
FIG. 1
) in the vertical direction, in an area through which the central electron beam passes, as shown in
FIGS. 1 and 2
. Thus, the effective diameter of the electrostatic lens in the horizontal direction is greater than in the vertical direction. When the strength of the main lens changes in response to a change in the dynamic voltage, the rate of change in the vertical direction is greater than in the vertical direction.
However, since the side electron beams are positioned at the side of the large diameter lens, when the dynamic voltage is changed, the effect of the change of the equipo
Bae Min-cheol
Hong Young-gon
Huh Woo-seok
A Minh D
Leydig , Voit & Mayer, Ltd.
Samsung SDI & Co., Ltd.
Wong Don
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