Multi-layer common lens arrangement for main focus lens of multi-beam electron gun

Information

  • Patent Grant
  • 6674228
  • Patent Number
    6,674,228
  • Date Filed
    Thursday, April 4, 2002
    22 years ago
  • Date Issued
    Tuesday, January 6, 2004
    20 years ago
Abstract
An inline electron gun for use in a multi-beam electron gun as in a color cathode ray tube (CRT) includes a main focus lens for focusing the electron beams on the CRT's display screen for providing a video image. The main focus lens includes plural charged grids aligned in a spaced manner along the electron gun's longitudinal axis through which plural (typically three) electron beams are directed. One or more of these charged grids includes at least two aligned common apertures for passing the three electron beams. The layered common aperture arrangement allows for increasing the length of the electron gun as well as the effective diameter of the electron gun's main focus lens for improved video image resolution without introducing electron beam astigmatism.
Description




FIELD OF THE INVENTION




This invention relates generally to multi-beam electron guns as used in color cathode ray tubes (CRTs) and is particularly directed to a multi-layer common lens arrangement in one or more charged grids in the main focus lens of a CRT electron gun.




BACKGROUND OF THE INVENTION




A typical color CRT employs a multi-beam electron gun which directs three inline electron beams on the inner surface of the CRT's glass display screen. A magnetic deflection yoke disposed outside of the CRT's glass envelope sweeps the three electron beams in unison across the display screen in a raster-like manner. The three electron beams are aligned generally horizontally, or in the direction of each sweep across the CRT's display screen. The energetic electrons incident upon a phosphor coating disposed on the display screen's inner surface produce a video image.




Electron guns are characterized as having X-, Y-, and Z-axes respectively aligned along the width, height and length of the electron gun structure. These axes are shown in

FIG. 1

which is a longitudinal sectional view of a prior art bipotential inline electron gun


10


incorporating a common lens arrangement in its main focus lens. The Y-axis aligned with the height of the bipotential inline electron gun


10


is perpendicular to the plane of the drawing sheet. In general, the larger the electron gun is along its X- and Y-axes, or the larger its diameter, the better the resolution of the video image presented on the CRT's display screen. Over the past several years, the design of high resolution color CRT electron guns has evolved from the individual beam main lens design to the common lens design for the purpose of increasing the effective size of the electron gun. In the individual beam type of main lens design, each of the three electron beams (red, blue, green) is directed through an individually defined lens space without sharing the space with the other beams. In the common lens design, each of the three electron beams is directed through its own individual beam path as well as through a shared focusing region defined by a common beam passing aperture.




Referring to

FIG. 1

, there is shown a longitudinal sectional view of a prior art bipotential inline electron gun


10


incorporating a common lens arrangement in its main focus lens. Electron gun


10


includes an electron beam source typically comprised of three cathodes: K


R


(red), K


G


(green) and K


B


(blue). Each cathode emits electrons which are focused to a crossover along the axis of the beam by the effect of an electrode commonly referred to as the G


2


screen grid. An electrode known as the G


1


control grid is disposed between the cathodes and the G


2


screen grid and is operated at a negative potential relative to the cathodes and serves to control the intensity of the electron beams in response to the application of a video signal to the cathodes. Each of the G


1


control and G


2


screen grids includes three respective aligned apertures


12




a


,


12




b


,


12




c


and


14




a


,


14




b


,


14




c


, with corresponding apertures in each electrode in common alignment for passing a respective one of the red, green or blue color generating electron beams. The G


2


screen grid is connected to and charged by a V


G


voltage source


33


.




Electron gun


10


further includes a G


3


electrode and a G


4


electrode disposed about the three electron beams and along the path of the energetic electrons as they travel toward a display screen


40


disposed on a forward portion of the CRT's glass envelope (which is not shown in the figure for simplicity). The G


3


grid is connected to and charged by a V


F


focus voltage source


34


, while the G


4


grid is coupled to and charged by a V


A


accelerating, or anode, voltage source


35


. The lower end of the G


3


grid in facing relation to the G


2


screen grid forms, in combination with the G


1


control grid and the G


2


screen grid, a beam forming region for forming the three groups of energetic electrons emitted by the K


R


, K


G


and K


B


cathodes into three spaced electron beams. The lower end of the G


3


grid includes three inline, spaced apertures


16




a


,


16




b


and


16




c


through each of which is directed a respective electron beam.




While the G


1


control and G


2


screen grids are generally flat, the G


3


grid and a G


4


grid are cup-like in shape. Disposed within the G


3


grid is a second trio of beam passing apertures


20




a


,


20




b


and


20




c


, through each of which is directed a respective one of the electron beams. The G


3


and G


4


grids form the electron gun's main focus lens. Disposed on the upper portion of the G


3


grid in facing relation to the G


4


grid is an elongated common beam passing aperture


18


through which all three electron beams are directed. Beam passing aperture


18


extends substantially the entire width and height of the G


3


grid and typically has a chain link shape. This chain link shape includes three spaced curvilinear enlarged portions through each of which is directed a respective one of the electron beams. This chain link shaped common beam passing aperture is shown in figures discussed in the following paragraphs and is described in detail below. The common beam passing aperture may take on other common forms, e. g., race track, dog bone or elliptical, although these other shapes are not shown in the figures for simplicity.




The G


4


grid also includes an elongated common beam passing aperture


22


in facing relation to the beam passing aperture


18


of the G


3


grid. Disposed within the G


4


grid in spaced relation are three inline beam passing apertures


24




a


,


24




b


and


24




c


through each of which is directed a respective one of the electron beams. Disposed on the upper end portion of the G


4


grid is a conductive support, or convergence, cup


26


which includes plural bulb spacers


28


disposed about its circumference in a spaced manner. The support cup


26


and bulb spacer


28


combination is conventional and serves to securely maintain electron gun


10


in position in the neck portion of a CRT's glass envelope. Each of the aforementioned grids is coupled to and supported by glass beads (also not shown for simplicity) disposed in the glass envelope's neck portion.




After being subjected to the electrostatic fields produced by the accelerating and focusing voltages applied by the aforementioned grids, the focused electron beams are then directed through a magnetic deflection yoke


30


for deflecting the electron beams in a raster-like manner across a phosphor coating, or layer,


40


on the inner surface of the CRT's display screen, or glass faceplate,


42


. Disposed adjacent the inner surface of the CRT's display screen


42


is a shadow mask


36


having a larger number of apertures


36




a


therein and serving as a color selection electrode.




By directing all three electron beams through a common beam passing aperture, the effective width and height, i.e., diameter, of the electron gun is increased to provide improved video image resolution. Because the electron gun is disposed within the narrow neck portion of the CRT's glass envelope, the common lens design overcomes prior limits on the size, i.e., height and width, of the individual lens-type electron gun.




The length of the electron gun along its Z-axis may also be increased. However, increasing the length of the electron gun along its Z-axis creates a large asymmetric astigmatism which reduces video image resolution. Electron beam astigmatism is defined in terms of the difference between the horizontal focus voltage and the vertical focus voltage, or:






astigmatism=


V




FH




−V




FV








where




V


FH


=horizontal focus voltage, and




V


VF


=vertical focus voltage.




The present invention addresses the aforementioned limitations of the prior art by increasing the effective electrostatic focusing field applied to the electron beams by increasing the effective diameter of the electron gun and compensating for this increase in size by increasing the gun's length. By electrostatically compensating for the electron gun's increased effective diameter, electron beam astigmatism is also compensated for and video image resolution is improved.




OBJECTS AND SUMMARY OF THE INVENTION




Accordingly, it is an object of the present invention to provide improved electron beam focusing in a multi-beam electron gun such as incorporated in a color CRT.




It is another object of the present invention to electrostatically increase the effective diameter of the main focus lens of an electron gun to compensate for increased electron gun length without increasing electron beam astigmatism for improved electron beam focusing on the display screen of a CRT.




Yet another object of the present invention is to provide a layered common lens arrangement in a multi-beam electron gun including one or more charged grids each having plural common apertures through which the electron beams are directed for improved focusing of the electron beams on a display screen upon which a video image is presented.




A further object of the present invention is to compensate for electron beam astigmatism in a video image produced by plural electron beams directed by an electron gun on a display screen such as in a color CRT, where the astigmatism arises from increasing the length of the electron gun without increasing the electron gun's diameter.




A still further object of the present invention is to improve resolution of a video image produced by plural electron beams directed by an electron gun onto a display screen by increasing the electron gun's length without increasing its diameter or the focus voltage.




The present invention contemplates a charged electrode in an electron gun forming an electrostatic focusing field for focusing plural electron beams on a display screen of a color cathode ray tube (CRT) in forming a video image on the screen, wherein the plural electron beams are directed along respective parallel axes, the electrode comprising a hollow housing including a first wall for defining three inline apertures and a thin side wall forming lateral portions of the housing, wherein each of the inline apertures is aligned with a respective one of the axes for passing a respective one of the electron beams; plural second walls disposed in the hollow housing and extending inwardly toward the electron beam axes from the side wall, wherein the plural second walls are disposed in a spaced manner along the electron beam axes; and an elongated common aperture in each of the second walls, wherein the common apertures are aligned in a spaced manner along the electron beam axes and the electron beams are directed through the aligned common apertures, and wherein the plural walls increase the effective radius of the electrostatic focusing field of the electrode and the length of the electrostatic focusing field along the axes for improved electron beam focusing on the display screen.











BRIEF DESCRIPTION OF THE DRAWINGS




The appended claims set forth those novel features which characterize the invention. However, the invention itself, as well as further objects and advantages thereof, will best be understood by reference to the following detailed description of a preferred embodiment taken in conjunction with the accompanying drawings, where like reference characters identify like elements throughout the various figures, in which:





FIG. 1

is a longitudinal sectional view of a prior art inline bipotential electron gun incorporating a common lens focusing arrangement for plural electron beams produced by the electron gun and directed onto a display screen for providing a video image;





FIG. 2

is a longitudinal sectional view of an inline bipotential electron gun incorporating a multi-layer common aperture arrangement in its main focus lens in accordance with the principles of the present invention;





FIGS. 2



a


and


2




b


are perspective views, shown partially in phantom, respectively of the G


3


and G


4


grids used in the bipotential electron gun of

FIG. 2

;





FIG. 3

is a partial perspective view shown partially in phantom of the inventive inline bipotential electron gun shown in

FIG. 2

;





FIG. 4

is a longitudinal sectional view of an electron gun having a quadrupole lens and incorporating a multi-layer common aperture arrangement in its main focus lens in accordance with another embodiment of the present invention;





FIGS. 4



a


and


4




b


are perspective views, shown partially in phantom, respectively of the G


6


and G


5


grids used in the QPF electron gun of

FIG. 4

;





FIG. 5

is a partial perspective view shown partially in phantom of the inventive QPF-type electron gun shown in

FIG. 4

;





FIGS. 6



a


and


6




b


are partial sectional views of the prior art electron gun of

FIG. 1

respectively taken in the XZ-plane and the YZ-plane showing the equipotential lines in a portion of the electron gun, as determined by a computer program, where the view shown in

FIG. 6



b


is taken along site line


6




b





6




b


in FIG.


1


and the view shown in

FIG. 6



a


is in the plane of the figure; and





FIGS. 7



a


and


7




b


are partial sectional views of the inventive electron gun shown in

FIG. 2

respectively taken in the XZ-plane and in the YZ-plane showing the equipotential lines in a portion of the electron gun, as determined by a computer program, where the view shown in

FIG. 7



b


is taken along site line


7




b





7




b


in FIG.


2


and the view shown in

FIG. 7



a


is in the plane of the figure.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Referring to

FIG. 2

, there is shown a longitudinal sectional view of an inline bipotential electron gun


50


incorporating a multi-layer common lens arrangement in its main focus lens in accordance with the principles of the present invention. A partial perspective view of the inventive inline bipotential electron gun


50


shown partially in phantom is shown in FIG.


3


. Elements shown in

FIG. 2

which are common to corresponding elements shown in the prior art inline bipotential electron gun


10


of

FIG. 1

are identified by the same element number or identifying indicia. Thus, the inventive inline bipotential electron gun


50


shown in

FIG. 2

also includes three inline cathodes K


R


, K


G


and K


B


. A G


1


control grid and a G


2


screen grid each include respective trios of inline beam passing apertures


52




a


,


52




b


,


52




c


and


54




a


,


54




b


,


54




c


. A lower portion of a G


3


grid in facing relation to the G


2


screen grid similarly includes three inline spaced beam passing apertures


56




a


,


56




b


and


56




c


. The G


3


grid further includes three inner inline beam passing apertures


60




a


,


60




b


and


60




c


each of which is aligned with a respective aperture on the lower portion of the G


3


grid and passes a respective electron beam. A V


G


voltage source


33


is coupled to and charges the G


2


screen grid, while a V


F


focus voltage source


34


is coupled to and charges the G


3


grid. The G


1


control and G


2


screen grids in combination with the low end portion of the G


3


grid comprises a beam forming region (BFR) of electron gun


50


.




In accordance with the present invention, disposed on the upper portion of the G


3


grid is an end wall


57


having therein a first elongated common beam passing aperture


58


. In addition, a second elongated common beam passing aperture


59


is formed in an inner wall


63


disposed within the G


3


grid and in alignment with the first common beam passing aperture


58


. Referring to

FIG. 2



a


, there is shown partially in phantom a perspective view of the G


3


grid incorporated in the bipotential electron gun


50


of FIG.


2


. As shown in

FIG. 2



a


, the first elongated common beam passing aperture


58


has a chain link shape with three spaced enlarged curvilinear portions disposed along its length. Each enlarged portion of the first elongated common beam passing aperture


58


is aligned with a respective one of the G


3


grid's inner beam passing apertures


60




a


,


60




b


and


60




c


. Each electron beam is thus directed through a respective one of the inner electron beam passing apertures


60




a


,


60




b


and


60




c


in the G


3


grid as well as through a respective one of the enlarged portions of the first elongated common beam passing aperture


58


in alignment with a respective one of the inner beam passing apertures. The G


3


grid's second elongated common beam passing aperture


59


may be of the same size and shape as the first elongated beam passing aperture


58


.




The inventive bipotential electron gun


50


further includes a G


4


grid coupled to and charged by a V


A


anode, or accelerating, voltage source


35


. The high end of the G


3


grid in combination with the G


4


grid forms the main focus lens of bipotential electron gun


50


. The G


4


grid also includes a first elongated common beam passing aperture


61


disposed in an end wall


65


on its lower end portion in facing relation to the G


3


grid as well as a second elongated common beam passing aperture


62


disposed in an inner wall


67


within the grid. The G


4


grid further includes three generally circular, inline, spaced beam passing apertures


64




a


,


64




b


and


64




c


each aligned with a respective curvilinear enlarged portion of the chain link shaped first and second elongated common beam passing apertures


61


and


62


which are arranged in common alignment. Referring to

FIG. 2



b


, there is shown partially in phantom a perspective view of the G


4


grid incorporated in the bipotential electron gun


50


of FIG.


2


. As shown in

FIG. 2



b


, the first common beam passing aperture


61


in the G


4


grid includes three inline curvilinear portions, each aligned with a respective one of the inner beam passing aperture


64




a


,


64




b


and


64




c


located in the G


4


grid. The second elongated common beam passing aperture


62


located in an inner portion of the G


4


grid has a size and shape similar to that of the first elongated common beam passing aperture


61


. As in the case of the prior art bipotential inline electron gun


10


shown in

FIG. 1

, a conductive support cup


26


is affixed to the upper end portion of the G


4


grid and a glass display screen


42


is disposed in spaced relation from the bipotential inline electron gun


50


for receiving the scanning electron beams and providing a video image as previously described. Other elements of the inventive bipotential inline electron gun


50


shown in

FIG. 2

common to corresponding elements shown in

FIG. 1

are assigned the same identifying numbers, although these conventional CRT and electron gun elements are not described herein for simplicity.




Referring to

FIGS. 6



a


and


6




b


, there are respectively shown partial sectional views of the prior art electron gun


10


of

FIG. 1

respectively taken in the XZ-plane and the YZ-plane showing the equipotential lines


32


in a portion of the electron gun. The location of the equipotential lines


32


shown in

FIGS. 6



a


and


6




b


was determined by means of a computer simulation program. The view shown in

FIG. 6



b


is taken along site line


6




b





6




b


in

FIG. 1

, while the view shown in

FIG. 6



a


is taken at the same location in the electron gun, but is in the plane of FIG.


1


. Adjacent portions of the G


3


and G


4


grids in the prior art electron gun


10


are shown in the partial sectional views of

FIGS. 6



a


and


6




b


where the common electron beam passing apertures


18


and


22


are shown in facing relation. Also shown in the partial sectional views of

FIGS. 6



a


and


6




b


are beam passing apertures


20




a


and


20




b


in the G


3


grid and beam passing apertures


24




a


and


24




b


in the G


4


grid. The third beam passing aperture in each of these grids is not shown in these figures for simplicity. Each of the electron beams travels first through the G


3


grid and then through the G


4


grid, or in an upward direction as viewed in the sectional views of these figures. Thus, separate electron beams transit the beam passing apertures


20




a


and


20




b


(as well as the third beam passing aperture which is not shown in FIGS. for simplicity) and then transit the elongated common beam passing aperture


18


in the G


3


grid. Electron beams then transit the elongated common beam passing aperture


22


in the G


4


grid and the electron beam passing apertures


24




a


and


24




b


. The equipotential lines


38


represent the electrostatic focus field applied by the G


3


and G


4


grids to the electron beams. The outer equipotential lines


32


generally conform with the inner surfaces of the conductive G


3


and G


4


grids between the three inline electron beam passing aperture arrays in each of these grids. The intensity of the electrostatic focusing field is greatest in the space between the G


3


and G


4


grids, with the inner equipotential lines more closely spaced than the outer equipotential lines to represent this change in electrostatic focusing intensity on the electron beams.




Referring to

FIGS. 7



a


and


7




b


, there are shown partial sectional views of the inventive electron gun shown in

FIG. 2

respectively taken in the XZ-plane and the YZ-plane showing the equipotential lines in a portion of the electron gun. The location of the equipotential lines shown in these figures were also calculated using a computer program. The view shown in

FIG. 7



b


is taken along site line


7




b





7




b


in

FIG. 2

, while the view shown in

FIG. 7



a


is in the plane of the figure. The electron beams first transit the G


3


grid and then the G


4


grid in traveling toward the CRT's display screen. As shown in these figures, the outer equipotential lines


66


closely conform to the inner surfaces of the G


3


and G


4


grids between the three inline beam passing aperture arrays in each of these grids. The electrostatic focusing field applied to the three electron beams is greatest in the region between the G


3


and G


4


grids where the equipotential lines are most closely spaced. In the inventive electron gun as shown in

FIGS. 7



a


and


7




b


, the inclusion of the inner common beam passing apertures in the form of the second elongated common beam passing aperture


59


within the G


3


grid and the second elongated common beam passing aperture


67


within the G


4


grid extend the length of the electron beam focus field along the X-axis, i.e., in the direction toward the CRT's display screen, of the electron gun. A comparison of

FIGS. 6



a


and


6




b


with

FIGS. 7



a


and


7




b


shows that the equipotential lines


66


formed by the G


3


and G


4


grids in accordance with the present invention are elongated in the direction of travel of the electron beams as compared with the electron beam focus field shown by the equipotential lines


32


of the prior art electron gun in

FIGS. 6



a


and


6




b


. Incorporating the multi-layer common lens arrangement of the present invention in the G


3


and G


4


grids as shown in

FIGS. 7



a


and


7




b


has the effect of lengthening the main focus lens of the electron gun along its longitudinal axis. The equipotential lines


66


shown in

FIGS. 7



a


and


7




b


also more closely approach the shape of the inner surfaces of the G


3


and G


4


grids than the equipotential lines of the prior art electron gun. This increases the effective diameter of the electron gun's main focus lens. By increasing the length of the electrostatic focusing field along the electron gun's Z-axis, astigmatism arising from an increase in the effective diameter of the electrostatic focus lens in the XY-plane is compensated for and essentially eliminated. The multi-layer common lens arrangement of the present invention thus achieves improved video image resolution by improving electron beam focusing by increasing the effective size of the electron gun's main focus lens without increasing its physical size. The present invention represents an improvement over prior attempts to improve video image resolution which increased the depth of the common lens as well as its equivalent diameter, but were unable to correct for the large astigmatism typically encountered.




Referring to

FIG. 4

, there is shown a longitudinal sectional view of a quadrupole focusing (QPF)-type electron gun


70


incorporating a multi-layer common lens arrangement in accordance with another embodiment of the present invention. A partial perspective view shown partially in phantom of the QPF-type electron gun


70


is shown in FIG.


5


. As in the previously described embodiment, the QPF-type electron gun


70


includes three cathodes K


R


, K


G


and K


B


, each of which directs respective groups of energetic electrons toward three inline apertures


72




a


,


72




b


and


72




c


in the electron gun's G


1


control grid. The electron gun


70


further includes a G


2


screen grid also having three inline electron beam passing apertures


74




a


,


74




b


and


74




c


each aligned with a respective one of the apertures in the G


1


control grid. A G


3


grid includes three inline apertures


76




a


,


76




b


and


76




c


on its lower portion in facing relation with the G


2


screen grid. The G


1


control and G


2


screen grids in combination with the lower portion of the G


3


grid comprise the beam forming region of QPF-type electron gun


70


. The G


3


grid further includes three inline beam passing apertures


78




a


,


78




b


and


78




c


in its upper end portion in facing relation to a G


4


grid. The G


4


grid also includes three inline beam passing apertures


80




a


,


80




b


and


80




c


. The G


4


grid in combination with an upper portion of the G


3


grid forms a prefocus lens of the. QPF-type electron gun


70


. Electron gun


70


further includes a G


5


grid having on a lower end portion thereof three inline beam passing apertures


82




a


,


82




b


and


82




c


in facing relation to the G


4


grid. The G


5


grid further includes three inner inline beam passing apertures


84




a


,


84




b


and


84




c


, each of which is aligned with a respective one of the inline beam passing apertures in the G


3


and G


4


grids as well as with the inline beam passing apertures in the G


1


control and G


2


screen grids.




In accordance with this embodiment of the present invention, an upper end portion of the G


5


grid includes a first elongated common beam passing aperture


86


disposed in an end wall


85


and an inner second elongated common beam passing aperture


88


disposed in an inner wall


83


within the G


5


grid. Each of the first and second elongated common beam passing apertures


86


,


88


is provided with three enlarged, curvilinear portions each aligned with a respective one of the inner beam passing apertures


84




a


,


84




b


and


84




c


within the G


5


grid. Also in accordance with this embodiment of the present invention, a lower portion of a G


6


grid in facing relation to the upper portion of the G


5


grid includes a first elongated common beam passing aperture


90


disposed in an end wall


95


. The G


6


grid further includes an inner second elongated common beam passing aperture


92


disposed in spaced relation from the first elongated common beam passing aperture


90


. The inner second elongated common beam passing aperture


92


is disposed in an inner wall


93


within the G


6


grid. Also disposed in the G


6


grid are three inline, spaced, generally circular beam passing apertures


94




a


,


94




b


and


94




c


each adapted to pass a respective electron beam as it travels toward and is incident upon the CRT's glass display screen


42


. The G


5


and G


6


grids form the main focus lens of QPF-type electron gun


70


.




Referring to

FIG. 4



a


, there is shown another sectional view of the QPF-type electron gun


70


shown in

FIG. 4

taken along site line


4




a





4




a


therein. As shown in

FIG. 4



a


, the first elongated common beam passing aperture


90


in the lower portion of the G


6


grid is chain link shaped having three enlarged, curvilinear portions disposed along its length in a spaced manner. Each enlarged portion of the first elongated common beam passing aperture


90


is aligned with a respective one of the generally circular electron beam passing apertures


94




a


,


94




b


and


94




c


disposed in an inner portion of the G


6


grid. The second elongated common beam passing aperture


92


disposed in an inner portion of the G


6


grid is essentially the same size and shape as the first elongated common beam passing aperture


90


, although this is not shown in

FIG. 4



a


because the second elongated common beam passing aperture is disposed behind the first elongated common beam passing aperture in this view of the G


6


grid.




Referring to

FIG. 4



b


, there is shown a sectional view of the QPF-type electron gun


70


shown in

FIG. 4

taken along site line


4




b





4




b


therein. As shown in

FIG. 4



b


, the first elongated common beam passing aperture


86


in the upper end portion of the G


5


grid is chain link shaped having three enlarged, curvilinear portions disposed along its length in a spaced manner. Each enlarged portion of the first elongated common beam passing aperture


86


is aligned with the respective one of the generally circular electron beam passing apertures


84




a


,


84




b


and


84




c


disposed in an inner portion of the G


5


grid. The second elongated common beam passing aperture


88


within the G


5


grid cannot be seen in the sectional view of

FIG. 4



a


as the second elongated beam passing aperture is disposed aft of, or behind, the first elongated common beam passing aperture


86


in the view of the G


5


grid. First and second elongated common beam passing apertures


86


and


88


within the G


6


grid are substantially the same size and shape.




There has thus been shown a multi-layer common lens arrangement for the main focus lens of a multi-beam electron gun which allows for increasing the size of the electron gun, either both physically and equivalently, to provide improved focusing of the electron beams incident upon a CRT display screen for presenting a video image thereon. The multi-layer common lens arrangement is disposed in one or more focusing grids within the electron gun's main focus lens and is in the form of a pair of aligned, elongated apertures within the grid through which the three electron beams are directed for focusing. Although the present invention is described herein in the form of a pair of aligned elongated common beam passing apertures disposed within each of adjacent charged grids in the main focus lens, virtually any number of aligned common beam passing apertures may be disposed in one or more charged grids in the electron gun's main focus lens. The common beam passing apertures may take on various forms such as the chain link shape including three, curvilinear, spaced portions arranged along the length of the grid through which the three electron beams are directed as described above. Other common forms that the elongated common beam passing aperture may take include the dog bone, race track and elliptical shapes. While increasing the length of the electron gun, the present invention does not require an increase in the diameter of the electron gun, thus making an electron gun incorporating the present invention compatible with the narrow neck portion of conventional CRT glass envelopes.




While particular embodiments of the present invention have been shown and described, it will be obvious to those skilled in the relevant art that changes and modifications may be made without departing from the invention in its broader aspects. Therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention. The matter set forth in the foregoing description and accompanying drawings is offered by way of illustration only and not as a limitation. The actual scope of the invention is intended to be defined in the following claims when viewed in their proper perspective based on the prior art.



Claims
  • 1. A charged electrode in an electron gun forming an electrostatic focusing field for focusing plural electron beams on a display screen of a color cathode ray tube (CRT) in forming a video image on said screen, wherein said plural electron beams are directed along respective parallel axes, said electrode comprising:a hollow housing including first wall means for defining three inline apertures and a thin side wall forming lateral portions of said housing, wherein each of said inline apertures is aligned with a respective one of said axes for passing a respective one of said electron beams; plural second wall means disposed in said hollow housing and extending inwardly toward the electron beam axes from said side wall, wherein said plural second wall means are disposed in a spaced manner along the electron beam axes; and means defining an elongated common aperture in each of said second wall means, wherein said common apertures are aligned in a spaced manner along the electron beam axes and the electron beams are directed through said aligned common apertures, and wherein said plural wall means increase the effective radius of the electrostatic focusing field of the electrode and the length of the electrostatic focusing field along said axes for improved electron beam focusing on the display screen.
  • 2. The electrode of claim 1 wherein said electron gun includes a main focus lens and wherein said electrode is disposed in said main focus lens.
  • 3. The electrode of claim 2 comprising a G3, G4, G5 or G6 grid in the electron gun.
  • 4. The electrode of claim 1 wherein said elongated common aperture is chain link, dog bone, race track or elliptical in shape.
  • 5. The electrode of claim 1 wherein each of said inline apertures is generally circular.
  • 6. The electrode of claim 1 wherein one of said second wall means and an elongated common aperture therein is disposed on an end of said hollow housing.
  • 7. A charged electrode in an electron gun forming an electrostatic focusing field for focusing a center and two outer electron beams on a display screen of a color cathode ray tube (CRT) in forming a video image on said screen, wherein said three electron beams are directed along respective parallel axes, said electrode comprising:a hollow housing including first wall means for defining three inline apertures and a thin side wall forming lateral portions of said housing, wherein each of said inline apertures is aligned with a respective one of said axes for passing a respective one of said electron beams; second wall means disposed on an end of said hollow housing and extending inwardly toward the electron beam axes from said side wall for defining a first elongated common aperture aligned generally transverse to said axes, wherein the center and two outer electron beams are directed through said first elongated common aperture; and third wall means disposed within said hollow housing between said first and second wall means and extending inwardly toward the electron beam axes from the side wall for defining a second elongated common aperture aligned with said first elongated common aperture for passing the center and two outer electron beams, wherein said second and third wall means increase the effective electrostatic focusing field radius of the electrode and the length of the electrostatic focusing field along said axes for improved electron beam focusing on the display screen.
  • 8. The electrode of claim 7 wherein said elongated common aperture is chain link, dog bone, race track or elliptical in shape.
  • 9. The electrode of claim 7 wherein each of said first and second common apertures is generally chain link shaped and has a center enlarged portion and first and second outer enlarged portions each aligned with a respective electron beam axis for passing said center and two outer electron beams, respectively.
  • 10. The electrode of claim 9 wherein said three inline apertures include a center aperture and two outer apertures disposed on opposed sides of said center aperture, and wherein said center and two outer apertures are aligned respectively with the center enlarged portion and the first and second outer enlarged portions of said first and second common apertures.
  • 11. The electrode of claim 10 wherein said inline apertures and the enlarged portions of said first and second common apertures are generally circular.
  • 12. The electrode of claim 7 wherein said electrode is disposed in a prefocus lens or a main focus lens of the electron gun and is charged by a focus voltage or an anode voltage.
  • 13. For use in an electron gun in a multi-electron beam video display device, wherein said electron beams are directed along respective parallel axes onto a display screen for providing a video image thereon, a focus lens through which said electron beams are directed for focusing the electron beams on the display screen, said focus lens comprising:a first charged grid including a first hollow housing with first and second opposed ends and a first thin side wall disposed about said first housing and forming lateral portions thereof, said first charged grid further including first plural wall means disposed in said first hollow housing in a spaced manner along the electron beam axes and extending inwardly toward the electron beam axes from said side wall for defining first plural spaced common apertures, and wherein said first plural common apertures are aligned with the electron beam axes for passing the electron beams; and a second charged grid including a second hollow housing with first and second opposed ends and a second thin side wall disposed about said second housing and forming lateral portions thereof, said second charged grid further including second plural wall means disposed in said second hollow housing in a spaced manner along the electron beam axes and extending inwardly toward the electron beam axes from said second side wall for defining second plural spaced common apertures, and wherein said second plural common apertures are aligned with the electron beam axes for passing the electron beams and said first and second plural common apertures are in facing relation.
  • 14. The focus lens of claim 13 wherein said first and second charged grids further respectively include third and fourth wall means defining first and second sets of plural inline apertures, respectively, and wherein each of said inline apertures passes a respective one of the electron beams.
  • 15. The focus lens of claim 14 wherein said video display device includes three inline electron beams and each of said charged grids includes three inline apertures, and wherein each inline aperture in each of said grids passes a respective electron beam.
  • 16. The focus lens of claim 15 wherein each of said elongated apertures is generally chain link shaped having a center enlarged portion and first and second outer enlarged portions each aligned with a respective electron beam axis for passing a center and an outer electron beam, respectively.
  • 17. The focus lens of claim 16 wherein each of said first and second sets of three inline apertures includes a center aperture and two outer apertures disposed on opposed sides of said center aperture, and wherein each of said center apertures and two outer apertures are aligned with the center enlarged portion and the first and second outer enlarged portions of said elongated common apertures, respectively.
  • 18. The focus lens of claim 17 wherein said inline apertures and the enlarged portions of each of said elongated common apertures are generally circular.
  • 19. The focus lens of claim 18 wherein said first and second charged grids are charged by either a focus voltage or an anode voltage.
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