CRT electron gun with reduced stray electron flow between electrodes

Information

  • Patent Grant
  • 6653772
  • Patent Number
    6,653,772
  • Date Filed
    Tuesday, July 12, 1994
    30 years ago
  • Date Issued
    Tuesday, November 25, 2003
    21 years ago
Abstract
A cathode ray tube comprising an electron gun. The electron gun has electrodes which are secured to supports by connecting elements. The width of the connecting elements varies. As a result, the high-voltage behavior of the cathode ray tube is improved.
Description




BACKGROUND OF THE INVENTION




This invention relates to a cathode ray tube comprising a display screen and an electron gun having a means for generating electrons, a number of electrodes and a support which is composed of an insulating material, said electrodes being provided with connecting elements which are secured in the support.




Cathode ray tubes are used, inter alia, in television receivers, computer monitors, oscilloscopes etc.




A cathode ray tube of the class mentioned in the opening paragraph is of the conventional type. The electron gun comprises a means for generating electrons, for example, a cathode. The electrodes are provided with connecting elements which are pressed into the support. The support is generally made from glass which can be softened. In the manufacture of the electron gun, the electrodes of the electron gun are stacked on top of each other, whereafter the support is (or are, if more than one support is used) heated. By virtue thereof, the support and the projections can be interconnected. This is generally achieved by pressing the support against the projections. Since the glass has been softened by heating, the connecting elements can be inserted into the support. The connecting elements may be integral with the electrode or they may be secured to the electrode as a separate part. After cooling, the electrodes and the support are secured to each other.




In operation, voltages are applied to the electrodes. Due to said voltages, electro-optical fields are formed between the electrodes. The electrons generated are accelerated and focused by means of said electric fields. Ever higher demands are imposed on the quality of the electron-optical fields. As a result thereof, the number of electrodes in the electron gun and the value of the applied voltages increase. A problem which arises is that sometimes the electrodes themselves can generate electrons. These electrons may hop between the electrodes. Due to this, the cathode ray tube may be damaged, which leads to failure. Such electrons may also land on the display screen, thereby adversely affecting the contrast of the image displayed. These phenomena occur, in particular, at locations where high voltages are applied to the electrodes.




SUMMARY OF THE INVENTION




It is an object of the invention to provide a cathode ray tube of the type mentioned in the opening paragraph, in which one or more than one of the above problems is reduced.




To this end, the cathode ray tube in accordance with the invention is characterized in that the electron gun comprises a pair of electrodes which are arranged one behind the other, said electrodes having connecting elements extending in a plane transverse to the electron beam, the width of the connecting elements of one of the electrodes of the pair of electrodes differing from the width of the connecting elements of the other electrode of the pair of electrodes.




Hopping of electrons between two electrodes can be reduced by varying the width of the connecting elements. In well-known electron guns, the connecting elements of successive electrodes are equal width.




The invention is, inter alia, based on the insight that electrons can readily hop from one electrode to a proximate electrode via a connecting element and to a connecting element of a nearby electrode via the support, and that in this process the edges the connecting elements form an important source of electrons. By making the widths of the connecting different elements, the shortest distance, via the support, between the edge of connecting element of one electrode, and the next electrode is increased.




In a preferred embodiment, the cathode ray tube comprises means for applying voltages to the pair of electrodes, and the voltage applied to the electrode having the widest connecting elements is lower than the voltage applied to the electrode having the narrowest connecting elements.




In particular in this embodiment hopping of electrons is reduced.











BRIEF DESCRIPTION OF THE DRAWINGS




These and other aspects of the invention will be explained in greater detail by means of the accompanying drawing which shows a number of exemplary embodiments of the invention.




In the drawing:





FIG. 1

is a partly perspective view of a cathode ray tube;





FIG. 2

is a partly perspective view of an electron gun;





FIGS. 3A and 3B

are sectional views of a detail of an electron gun; and





FIG. 4

is a view of a detail of a further example of an electron gun.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




The Figures are diagrammatic. In the Figures, like parts generally bear like reference numerals.





FIG. 1

is a partly perspective view of a cathode ray tube


1


. Said cathode ray tube


1


comprises an evacuated envelope


2


having a display window


3


, a cone


4


and a neck


5


. In the neck there is provided an electron gun


6


for generating, in this example, three electron beams


7


,


8


and


9


. A luminescent display screen


10


which, in this example, comprises phosphor elements luminescing in red, green and blue is situated on the inside of the display window


3


. On their way to the screen


10


, the electron beams


7


,


8


and


9


are deflected across the screen


10


by means of a deflection unit


11


which is located at the junction between the neck and the cone, and pass through the shadow mask


12


which comprises a thin plate having apertures


13


. The electron beams


7


,


8


and


9


pass through the apertures


13


at a small angle with respect to each other and each electron beam impinges on phosphor elements of only one colour. The means


14


for applying voltages to the electrodes of the electron gun are also diagrammatically shown.





FIG. 2

is a diagrammatic, partly perspective view of an electron gun


6


. Electron gun


6


comprises a common control electrode


21


, also referred to as G


1


. electrode, in which three cathodes


22


,


23


and


24


are secured. The G


1


, electrode is secured to supports


26


by means of connecting elements


25


. Said supports are made of glass. An example of such supports are the supports which are commonly referred to as “beading rods”. In this example, the electron gun


6


further comprises a common plate-shaped electrode


27


, also referred to as G


2


electrode, which is secured to the supports by connecting elements


28


. In this example, the electron gun


6


comprises two supports


26


. One of said supports is shown, the other is situated on the side of the electron gun


6


which is invisible in this perspective view. The electron gun


6


further comprises the common electrodes


29


and


31


which are also secured to supports


26


by means of connecting elements (


30


and


32


, respectively). In this example, the supports are secured on feed-through pins


35


by means of brackets


34


. The electrical connections between the feed-through pins and the electrodes are not shown.





FIGS. 3A and 3B

are side views of a detail of the electron gun


6


. Electrodes


36


and


37


are secured in the support


26


by means of securing elements


38


and


39


. Said securing elements


38


and


39


are shown in detail in FIG.


3


B. The width of the securing element


39


exceeds that of securing element


38


, for example 8 mm (securing element


39


) and 5 mm (securing element


38


). The distance between the electrodes (in the z-direction) is approximately 1.5 mm. In this example, the voltage applied to electrode


37


is lower than the voltage applied to electrode


36


during operation. Due to this, an electric field is generated between the electrodes. This electric field may cause electrons to hop from electrode


37


to electrode


36


. This phenomenon, in which the electrons hop via the support


26


, occurs in particular at the edges of the securing elements


39


of electrode


37


. In cathode ray tubes in accordance wit the invention, this distance is greater than the distance between the electrodes. In this example, the shortest distance between an edge of securing element


39


and electrode


36


, via the support


26


, is 2.1 mm, which is more than the distance between the electrodes (=1.5 mm). This reduces the risk of electron hopping.

FIG. 4

diagrammatically shows a detail of a further example of an electron gun for a cathode ray tube in accordance with the invention. This electron gun comprises a stack of


4


electrodes


41


,


42


,


43


and


44


having securing elements


41


A,


42


A,


43


A and


44


A, respectively. In operation, voltages V


1


, and V


2


(V


1


<V


2


) are applied to the electrodes, V


1


, being applied to electrodes


41


and


43


and V


2


being applied to electrodes


42


and


44


. The width of the connecting elements


41


A and


43


A is greater than the width of the connecting elements


42


A and


44


A. In this example, the widths are 8 mm (


41


A and


43


A) and 5 mm (


42


A and


44


A), respectively. Preferably, the difference in width between the connection elements is greater than the distance between the connecting elements, viewed along the electron beams.




Since the likelihood of electrons hopping between the connecting elements is substantially reduced or absent, damage to the electron gun or contrast reduction does not occur or is reduced in a cathode ray tube in accordance with the invention. A further advantage is that sparking of the electron gun is enhanced. A customary step in the manufacture of an electron gun is the sparking of the electrodes. To this end, very high voltage differences between electrodes are generated. As a result, a flashover is generated between electrodes. By virtue thereof, burrs and loose particles are removed from the electrodes. Flashover between the connecting elements during sparking has two adverse effects. First, flashover between the electrodes does not take place or is less likely to take place and, second, loose particles can be formed. In a cathode ray tube in accordance with the invention, the risk of flashover between the connecting elements is reduced.




It will be obvious that within the scope of the invention further variations are possible.



Claims
  • 1. A cathode ray tube comprising: a display screen and an electron gun having a means for generating an electron beam, a number of electrodes and a support means which is composed of an insulating material, said electrodes being provided with respective connecting elements which are secured in the support means, wherein the electron gun comprises a pair of electrodes which are arranged one behind the other, said electrodes having the connecting elements extending in a plane transverse to the electron beam, and wherein the width of said connecting elements of one of the electrodes of the pair of electrodes differs from the width of the connecting elements of the other electrode of the pair of electrodes;said cathode ray tube further comprising means for applying voltages to the pair of electrodes such that, in operation, the voltage applied to the electrode having the widest connecting elements is lower than the voltage applied to the electrode having the narrowest connecting elements.
  • 2. The cathode ray tube as claimed in claim 1 wherein said support means comprise first and second parallel arranged elongate support members extending parallel to a longitudinal axis of the electron gun.
  • 3. A cathode ray tube comprising: a display screen and an electron gun having a means for generating an electron beam, a number of electrodes and a support means which is composed of an insulating material, said electrodes being provided with respective connecting elements which are secured in the support means, wherein the electron gun comprises a pair of electrodes which are arranged one behind the other, said electrodes having the connecting elements extending in a plane transverse to the electron beam, and wherein the width of said connecting elements of one of the electrodes of the pair of electrodes differs from the width of the connecting elements of the other electrode of the pair of electrodes; wherein the difference in width between the connecting elements is greater than the distance between the connecting elements, viewed along the support means.
  • 4. A vacuum tube apparatus comprising:an evacuated envelope containing display means and an electron gun for generating an electron beam along a longitudinal axis of the electron gun, wherein said electron gun comprises; at least one support member made of an insulating material; first and second electrodes each including a connecting element secured in one of the at least one support member so as to mount said first and second electrodes in spaced apart relationship in the direction of the longitudinal axis of the electron gun, wherein the connecting elements extend in planes which are transverse to the electron beam and the connecting element of one of said first and second electrodes is wider than the connecting element of the other one of said first and second electrodes in a direction transverse to the electron beam; and means for applying respective voltages to the one electrode and the other one of said electrodes wherein the voltage applied to the one electrode having the wider connecting element is lower than the voltage applied to the other one of said electrodes which has the narrower connecting element.
  • 5. The vacuum tube apparatus as claimed in claim 4 wherein the distance from one transverse edge of the connecting element of the one electrode to the corresponding transverse edge of the connecting element of the other one of said electrodes is greater than the distance between said connecting elements in a direction parallel to the longitudinal axis.
  • 6. A vacuum tube apparatus comprising:an evacuated envelope containing display means and an electron gun for generating an electron beam along a longitudinal axis of the electron gun, wherein said electron gun comprises: at least one support member made of an insulating material; first and second electrodes each including a connecting element secured in one of the at least one support member so as to mount said first and second electrodes in spaced apart relationship in the direction of the longitudinal axis of the electron gun, wherein the connecting elements extend in planes which are transverse to the electron beam and the connecting element of one of said first and second electrodes is wider than the connecting element of the other one of said first and second electrodes in a direction transverse to the electron beam; wherein the difference in width between the connecting elements of the one and the other one of said first and second electrodes is greater than the spacing between the connecting elements viewed in a direction parallel to the longitudinal axis of the electron gun.
  • 7. A vacuum tube apparatus comprising:a. an evacuated envelope containing a display screen and an electron gun for generating an electron, said electron gun including first and second electrodes arranged along an axis; b. at least one insulating support member extending along said axis; c. at least one conductive connecting element extending from each of the first and second electrodes and having an end portion secured in the insulating support member, said end portion having a width defined by respective outer edges; each of said end portions being dimensioned and arranged such that the shortest distance via the insulating support member between any end portion outer edge conductively connected to the first electrode and any end portion outer edge conductively connected to the second electrode is larger than the axial distance between the respective end portions.
Priority Claims (1)
Number Date Country Kind
09300720 Jul 1993 BE
US Referenced Citations (12)
Number Name Date Kind
4096408 Bozzay et al. Jun 1978 A
4119884 Blumenberg et al. Oct 1978 A
4137480 Torre et al. Jan 1979 A
4181870 Stevens Jan 1980 A
4499402 van der Heijden Feb 1985 A
4595858 Hale Jun 1986 A
4609848 Takenobu Sep 1986 A
4678964 Peels Jul 1987 A
4853584 Inoue Aug 1989 A
4990822 Guzowski et al. Feb 1991 A
5140218 Van Eck Aug 1992 A
5479067 van der Wilk et al. Dec 1995 A
Foreign Referenced Citations (2)
Number Date Country
2526210 Dec 1976 DE
967260 Aug 1964 GB