Electron gun in CRT

Information

  • Patent Grant
  • 6635982
  • Patent Number
    6,635,982
  • Date Filed
    Wednesday, August 15, 2001
    23 years ago
  • Date Issued
    Tuesday, October 21, 2003
    21 years ago
Abstract
Electron gun in a CRT including a main lens electrode having a focus electrode and an anode for focusing electron beams emitted from cathodes onto a screen, an electrostatic field controlling body fitted in each of the focus electrode and the anode each having three electron beam pass through holes, wherein each of outer holes in the electrostatic field controlling body fitted to each of the focus electrode and the anode has a form of a combination of a circle and a rectangle with reference to a vertical axis through a center of the hole in a direction opposite for facing outer holes of the focus electrode and the anode, thereby enlarging a main lens diameter, and providing a spot substantially circular and smaller.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to an electron gun in a cathode ray tube (CRT), and more particularly, to an electron gun in a CRT, in which electron beam pass through holes in an electrostatic field controlling body provided both to a focusing electrode and anode of a main lens electrode are changed, for improving a screen focusing characteristic.




2. Background of the Related Art




The CRT, a device for forming a picture by landing electron beams emitted from the electron gun on a screen, is illustrated in

FIG. 1

, schematically.




Referring to

FIG. 1

, the CRT is provided with a panel


2


fitted to a front for acting as a screen, a fluorescent surface


4


of red R, green G, and blue B fluorescent materials coated on an inside surface of the panel


2


, a shadow mask


8


for selecting a color as electron beams


6


incident on the fluorescent surface


4


pass therethrough, a funnel


10


fitted to rear of the panel


2


for sustaining an inner space of the CRT at a vacuum, and a deflection yoke


12


surrounding an outer circumference of a neck part


10




a


of the funnel


10


for deflecting the electron beams


6


.




The electron gun


20


is placed in the neck part


10




a


of the funnel


10


of the CRT, and provided with three independent cathodes


201


, a first electrode


21


spaced a distance away from the cathodes


201


, a second electrode


22


, a third electrode


23


, a fourth electrode


24


, a fifth electrode


25


, and a sixth electrode


26


spaced at fixed intervals from the first electrode


21


, and a shield cup


27


above the sixth electrode


26


having a bulb space contact (B.S.C)


28


fitted thereto for electrical connection of the electron gun


20


to the funnel


10


and fastening the electron gun


20


to the neck part


10




a


of the funnel


10


.




The electron gun


20


emits electrons as heaters


203


in the cathodes


201


are heated by a power supplied from respective stem pins


202


at rear end thereof, and the electrons form electron beams, which are controlled by the first electrode


21


, a controlling electrode, and accelerated by the second electrode


22


, an accelerating electrode. Then, the electron beams are partly focused and accelerated by a pre-focus lens formed between the second electrode


22


, the third electrode


23


, the fourth electrode


24


, the fifth electrode


25


(a focus electrode), finally focused and accelerated by the sixth electrode


26


(anode), a final accelerating electrode, pass through the shadow mask


8


, and land on the fluorescent surface


4


on an inside surface of the panel


2


, to make the fluorescent surface to emit a light.




The focus electrode


25


and the anode


26


collectively called as a main lens


200


, and a related art main lens


200


will be explained with reference to FIG.


2


.

FIG. 2

illustrates a perspective view with a partial cut away view of the focus electrode


25


and the anode


26


in the main lens electrode.




Referring to

FIG. 2

, the focus electrode


25


is provided with a drum formed housing


252


externally, having an fore end facing the anode


26


with an opened central part and a rim


252




a


in a form of a racing track in a periphery, and a plate of electrostatic field controlling body


254


spaced a distance away inward from rim


252




a


with three electron beam pass through holes


254




a,




254




b,


and


254




c


for passing the three electron beams from the cathodes. The anode


26


is also provided with a drum formed housing


262


having a rim


262




a


at one end, and an electrostatic field controlling body


264


with electron beam pass through holes


264




a,




264




b,


and


264




c


inside thereof.





FIGS. 3



a


and


3




b


illustrate a plan view of the electrostatic field controlling bodies


254


and


264


of the focus electrode


25


and the anode


26


, respectively.




Referring to

FIGS. 3



a


and


3




b


, it can be known that the electron beam pass through holes


254




a


,


254




b


, and


254




c


in the electrostatic field controlling body


254


of the focus electrode


25


are similar, or identical to the electron beam pass through holes


264




a


,


264




b


, and


264




c


, respectively.




One of the most important parameter to be taken into account in design of an electron gun is a spot diameter Dt on a screen. There are three factors that influence the spot diameter on the screen, i.e., a magnification of the lens, a spatial charge repulsive power, and a spherical aberration of the main lens. Since voltage conditions, focal distances, a length of the electron gun, and etc., are already defined basically, the influence of the magnification of the lens to the spot diameter Dx has a small portion for utilizing as design parameter of the electron gun, and minimal effect.




The spatial charge repulsive power is a phenomenon in which the collision and repulsion between the electrons in the electron beam enlarge the spot diameter. For reducing enlargement of the spot diameter Dst caused by the spatial charge repulsive power, it is favorable to design an angle (a diverging angle) of the electron beam travel greater.




The spherical aberration of the main lens can form the smaller spot diameter on the screen, as the diverging angle of the electron beams is the smaller. In general, the spot diameter Dt on the screen may be expressed as a sum of three factors as follows.








D




t


={square root over ((


D





x





+D





st


)


2





+D





ic





2


)}






The best method for reducing the spherical aberration as well as the spatial charge repulsive power is enlargement of the main lens diameter, which reduces enlargement of the spot caused by the spherical aberration even if electron beams with a great diverging angle are incident thereon, and reduces the spatial charge repulsive power after electron beams pass through the main lens, thereby forming a small diametered spot on the screen. However, an enlargement of the rim, and spacing the distance from the rim to the electrostatic field controlling body greater for enlargement of the main lens diameter form the spot to be almost triangular with partial halo as a focusing of the outer main lens is in a 45° direction, with a difference between a central main lens side and an opposite side.





FIG. 4

illustrates the foregoing triangular spots S


1


on the screen.




The rim


252




a


of the focus electrode


25


focuses the outer beam weak in a 45° direction on the central beam side, and strong in a 45° direction on an opposite side of the central beam side, to form a triangle greater vertically in the 45° direction on the central beam side, and smaller vertically in the 45° direction on an opposite side of the central beam side. There are halos on sides opposite to the central beam in 45° directions. Of course, though forms of the outer spots can be slightly corrected at the anode as the anode acts opposite to the focus electrode, since an action of the main lens is significantly greater at the focusing side than the acceleration side, eventually a state at the focusing side is maintained as it is, due to which, because spot is formed not circular at a periphery of a picture, realization of focusing for meeting requirements of high definition, large sized screen, flat screen, and wide angle is difficult.




Moreover, in comparison to the electron gun with circular outer spots, alignments between apertures of electrodes of electron gun and one sided halo inducing characteristic dependent on assembly of electron gun related to a flatness of the electrode are sensitive, assembly of the electron gun is unfavorable.




SUMMARY OF THE INVENTION




Accordingly, the present invention is directed to an electron gun in a CRT that substantially obviates one or more of the problems due to limitations and disadvantages of the related art.




An object of the present invention is to provide an electron gun in a CRT, which can enlarge a main lens diameter and form an excellent spot that is almost circular and has a reduced size.




Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.




To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described, the electron gun in a CRT includes a main lens electrode having a focus electrode and an anode for focusing electron beams emitted from cathodes onto a screen, an electrostatic field controlling body fitted in each of the focus electrode and the anode each having three electron beam pass through holes, wherein each of outer holes in the electrostatic field controlling body fitted to each of the focus electrode and the anode has a form of a combination of a circle and a rectangle with reference to a vertical axis through a center of the hole in a direction opposite for facing outer holes of the focus electrode and the anode.




It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.











BRIEF DESCRIPTION OF THE DRAWINGS




The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention:




In the drawings:





FIG. 1

illustrates a section showing a related art CRT, schematically;





FIG. 2

illustrates a cut away perspective view showing a main lens part having a focus electrode and an anode in an electron gun of a related art CRT, schematically;





FIGS. 3



a


and


3




b


illustrate plan views of electrostatic field controlling bodies of a related art focus electrode and an anode;





FIG. 4

illustrates a plan view of spots on a screen in an electron gun of a related art CRT;





FIGS. 5



a


and


5




b


illustrate plan views of electrostatic field controlling bodies of a focus electrode and an anode in an electron gun of a CRT in accordance with a preferred embodiment of the present invention;





FIG. 6

illustrates a plan view showing spots on a screen formed by an electron gun of the present invention;





FIG. 7

illustrates plan views of an electrostatic field controlling body and a rim related to the present invention for comparison; and,





FIG. 8

illustrates a graph showing a difference of horizontal diameters of main lenses according to a center distance P


1


between a central hole and an outer hole of an electrostatic field controlling electrode of a focus electrode in a case a horizontal distance P


2


between points from a center of the rim of the focus electrode to a point the rim changes from straight to curve is 5.5 mm.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. For reference, parts of the present invention identical to the related art will be given the same reference symbols. FIGS


5




a


and


5




b


illustrate plan views of electrostatic field controlling bodies of a focus electrode and an anode in an electron gun of a CRT in accordance with a preferred embodiment of the present invention. With regard to the related art main lens electrode,

FIG. 2

will be referred.




An electrostatic field controlling electrode


54


provided to a focus electrode


25


is a planar electrode body fitted in an external housing


252


thereof spaced a distance away from a rim


252




a


having three electron beam pass through holes formed therein inclusive of central hole


54




a,


and outer holes


54




b


and


54




c.


The central hole


54




a


is circular, and the outer hole


54




b


or


54




c


is a combination of a circle and a rectangle.




The outer hole


54




b


is a circle combined with a rectangle extended outward from a vertical axis of the circle, a height of which rectangle is the same with the diameter of the circle. The extended portion of the rectangle has a width ‘H’ at least smaller than a radius of the circle. Eventually, the electrostatic field controlling electrode


54


of the focus electrode has the outer hole with a rectangular part


54




e


projected in a direction opposite to the central hole with reference to a vertical axis of the outer hole, for improving the triangular spots in FIG.


4


.




Referring to a lower drawing in FIGS


5




a


and


5




b


, similar to the electrostatic field controlling electrode


54


of the focus electrode, an electrostatic field controlling body


64


of an anode


26


includes one central hole


64




a


and two outer holes


64




b


and


64




c


each in a form of a combination of a circle and a rectangle, but a rectangular part


64




e


of the outer hole is extended toward the central hole with reference to a vertical axis of the outer hole. That is, the outer holes


54




b


and


54




c


in the electrostatic field controlling electrode


54


of the focus electrode


25


and the outer holes


64




b


and


64




c


in the electrostatic field controlling body


64


of the anode


26


are symmetry with respect to the vertical axis.




The operation of the electron gun improved by the present invention will be explained.




For compensating for the weak focusing power in a 45° direction on the central beam side at the rim


252




a


of the focus electrode


25


, the rectangular part


54




e


is formed in the outer hole


54




b


or


54




c


in a 45° direction on an opposite side of the central beam side, for weakening a focusing power thereof to compensate for a difference of focusing powers in the rim.




Also, in a case it is intended to correct the problem that the outer spots are formed triangular on the screen, the electrostatic filed controlling body


64


in a form as shown in FIGS


5




a


and


5




b


is formed at the anode


26


, and, for compensating a weakened diverging power in a 45° direction on the central beam side at the rim


262




a


of the anode


26


, the rectangular part


64




e


is formed in the outer hole


64




b


or


64




c


in a 45° direction on the central beam side thereof in the electrostatic field controlling body


64


, for compensating for a weakened diverging power.





FIG. 6

illustrates a plan view of spots on a screen formed by an electron gun of the present invention. As can be known from the drawing, the electrostatic field controlling body


54


of the focus electrode


25


and the electrostatic field controlling body


64


of the anode


26


compensate for focusing powers of the outer beams, to form substantially circular spots, and to eliminate halos caused by a difference of focusing powers in the related art.





FIG. 7

illustrates, when the electrostatic field controlling bodies


54


and


64


in the focus electrode


25


and the anode


26


are formed deeper for increasing diameters of the main lenses, a distance P


1


between centers of the central hole in the electrostatic field controlling body


54


or


64


of the focus electrode or the anode, and a horizontal distance P


2


between points ‘r’ from a center of the rim


252




a


or


262




a


of the focus electrode or anode to a point of the rim changing from a straight line to a curved line.




In this instance, for compensation of a horizontal diameter difference of the main lenses in a central beam direction and an opposite direction of the central beam direction of the main lenses of the outer beams, as shown in

FIG. 7

, P


1


is made greater than P


2


(P


1


>P


2


). In this instance, after combination of the electrostatic field controlling bodies of the focus electrode and the anode, the spots are made circular. This is because the 45° direction focusing power difference of rims in the focus electrode is required to compensate the 45° direction focusing power difference of the electrostatic field controlling body in the anode as centers of the outer hole of the electrostatic field controlling electrode in the focusing electrode becomes far to weaken a correction power of the rectangular part 45° direction focusing power.





FIG. 8

illustrates a graph showing a difference of horizontal diameters of main lenses according to a center distance P


1


between a central hole and an outer hole of an electrostatic field controlling electrode of a focus electrode in a case a horizontal distance P


2


between points from a center of the rim of the focus electrode to a point the rim changes from straight to curve is 5.5 mm.




Referring to

FIG. 8

, as P


1


becomes the greater than P


2


, it can be known that a horizontal lens diameter on the central beam side and an opposite horizontal lens diameter are in conformity. In the case of an embodiment of the electrostatic field controlling bodies of the present invention, by a simple additional step of forming the rectangular parts in the outer holes which are circular in the related art, improved spots can be formed on the screen without any complicated change to a related art process.




When an alignment of holes of the electron gun is adjusted in a beading process in which components of the electron gun are fixed with bead glass at preset distances in an electron gun assembly process, a jig called mandrel is used for holding the electrodes of the electron gun. In general, it is the most favorable that the mandrel has a circular section in view of alignment. Since the present invention permits to use the mandrel without change, the present invention is also favorable for the alignment.




By changing forms of outer holes in the electrostatic field controlling bodies for improving the outer spots caused by increased main lens diameters that give a great influence to a focus, an excellent focusing performance can be provided for entire screen. Since no change to an electron gun fabrication process is required, and round mandrel can be used, a favorable result can be obtained even in an electron gun alignment characteristic. Compared to a sensitive one sided halo characteristic caused by partial halo occurrence in the related art, a less sensitive result can be obtained even for the one sided halo which may be occurred by defective alignment of the electron gun.




It will be apparent to those skilled in the art that various modifications and variations can be made in the electron gun in a CRT of the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.



Claims
  • 1. An electron gun in a CRT comprising:a main lens electrode having a focus electrode and an anode for focusing electron beams emitted from cathodes onto a screen; an electrostatic field controlling body fitted in each of the focus electrode and the anode each having three electron beam pass through holes, wherein each of outer holes in said electrostatic field controlling body has an appearance of a combination of a circle and rectangle taken from a view with reference to a vertical axis through a center of either of said outer holes in a direction opposite for facing outer holes of the focus electrode and the anode.
  • 2. An electron gun as claimed in claim 1, wherein a horizontal distance P2 from a center of rim to a point on a rim of the focus electrode changing from a straight line to a curved line is greater than a center distance P1 of the central hole and the outer hole of the focus electrode.
  • 3. An electron gun as claimed in claim 2, wherein the outer hole in the electrostatic field controlling body of the focus electrode has an appearance of a combined form of a circle and a rectangle in a view extended in a direction opposite to the central beam taken with reference to center of the circle as one axis.
  • 4. An electron gun as claimed in claim 2, wherein the outer hole in the electrostatic field controlling body of the anode has an appearance of a combined form of a circle and a rectangle in a view extended in a direction of the central beam taken with reference to center of the circle as one axis.
Priority Claims (1)
Number Date Country Kind
2000-81160 Dec 2000 KR
US Referenced Citations (5)
Number Name Date Kind
5036258 Chen et al. Jul 1991 A
5414323 Ucida et al. May 1995 A
5635792 Jung et al. Jun 1997 A
5894191 Kim Apr 1999 A
6492767 Bae Dec 2002 B1