1. Field of the Invention
The present invention relates to a cathode ray tube, more particularly, to a structure of an electron gun for enhancing resolution of a cathode ray tube.
2. Discussion of the Related Art
Referring to
A shadow mask 3 with an electron beam color selecting function is situated at a predetermined distance from the fluorescent screen 11, and the shadow mask 3 is coupled with a mask frame 4.
Also, the mask frame 9, which is connected to a mask spring 5, is connected to a stud pin 6 to be supported to the panel 1.
The mask frame 4 is jointed with an inner shield 7 made of magnetic material to reduce the movement of an electron beam 5 caused by an external magnetic field. Accordingly, the effect of a geomagnetic field at the rear side of the cathode ray tube is reduced.
On the other hand, a convergence purity magnet (CPM) 10 for adjusting R, G and B electron beams emitted from the electron gun 8 to be converged on one spot, and a deflection yoke 9 for deflecting the electron beams are mounted on a neck portion of the funnel.
Also, a reinforcing band 12 is used to reinforce the front surface glass under the influence of a high interval vacuum state of the tube.
To briefly explain how the color cathode ray tube with the above construction operates, the electron beams emitted from the electron gun 8 are deflected in the horizontal and vertical directions by the deflection yoke 9, and the horizontally/vertically deflected electron beams pass through a beam passing hole on the shadow mask 3 and eventually strike the fluorescent screen 11, thereby displaying a desired image.
As illustrated in
The triode unit includes a cathode 21 having a built-in heater 20, a control electrode 22 for controlling electron beams emitted from the cathode 21, and an accelerating electrode 23 for accelerating the electron beams, in which the cathode 21, the control electrode 22, and the accelerating electrode 23 are arranged in-line.
The main lens includes a main focus electrode 26 and an anode 27 for focusing electron beams generated from the triode unit and accelerating the electron beams in the end. More specifically, the main focus electrode 26 includes a cap electrode 261 having a race track shaped rim portion, and an electrostatic field control electrode 26. The anode 27 includes a cup electrode 271 having a race track shaped rip portion and an electrostatic field control electrode 272. Here, the electrostatic field control electrodes 262 and 272 are to equalize convergence force of three electron beams, and recessed to a certain direction from the cap electrode 261 or the cup electrode 271.
The pre-focus lens includes a first pre-focus electrode 24 and a plate-shaped second pre-focus electrode 25.
The control electrode 22 is earthed. A voltage of 500-1000V is applied to the accelerating electrode 23 while a high voltage of 25-35 KV is applied to the anode 27. An intermediate voltage, e.g., 20-30% of the applied voltage to the anode 27, is applied to the main focus electrode 26.
When a designated voltage is applied to each of the electrodes of the electron gun 8, the electron beams generated at the triode unit are focused and accelerated, and later strike the fluorescent screen 11.
In general, for a cathode ray tube using an in-line electron gun, Red, Green and Blue electron beams are aligned horizontally. Thus a self-convergence type deflection yoke 9 that converges three electron beams to one spot is usually used.
As shown in
The magnetic fields can be categorized into diode and tetrode magnetic fields. The diode magnetic field deflects electron beams in horizontal and vertical directions. On the other hand, the tetrode magnetic field converges electron beams in the vertical direction and diverges in the horizontal direction, thereby causing astigmatism. In result, the shape of the electron beam spot is distorted and focusing characteristics thereof are deteriorated.
To elaborate the above phenomenon with reference to
More specifically, a deflection magnetic filed is not applied to the central portion of the fluorescent screen 11, so the electron beam spot has a circular shape. In the peripheral portion of the fluorescent screen 11, however, the electron beams are diverged in the horizontal (H) direction and overly converged in the vertical (V) direction, causing a low-density haze phenomenon to a high-density horizontally elongated core and the upper and lower parts of the core. Especially, deterioration in the resolution is worse at the peripheral portion of the screen. This problem gets worse for large cathode ray tubes and great deflection angles.
Basically the haze phenomenon at the peripheral portion of the screen occurs because the influence of deflection aberration is greater at the center of the deflection yoke 9. For example, the electron beams in the horizontal direction are almost circular because the divergence force of the deflection magnetic field and the convergence force by a distance difference are cancelled out or counterbalanced with each other. On the contrary, in the vertical direction the convergence force by the deflection aberration and the convergence force by the distance difference are superposed, resulting in the occurrence of the haze phenomenon.
Therefore, to get rid of the haze phenomenon, the triode unit should be adjusted properly.
Referring to
Now referring to an accelerating electrode 23 in
As shown in
In general, among other design characteristics of an electron gun 8, lens magnification, repulsive space charge (electric force), and spherical aberration of the main lens are major factors that influence spot size of an electron beam formed on the fluorescent screen 11.
The lens magnification actually does not have much effect on the spot size (Dx) and its utility as a design element of the electron gun is very low because there are several fixed conditions like a voltage, a focal length, and a length of the electron gun.
On the other hand, the influence of the repulsive space charge force on the spot size (Dst) indicates a phenomenon that the spot size (Dst) is enlarged due to the repulsion and the collision between electrons in the electron beam. To obviate such phenomenon, a special designing is needed to increase an angle to which the electron beams travel (hereinafter, it is referred to as ‘emission angle’).
The influence of the spherical aberration of the main lens on the spot size (Dic) indicates a phenomenon that the spot size (Dic) is enlarged due to the difference between focal lengths of an electron that passed through a short axis of the lens and an electron that passed through a long axis of the lens. Unlike the repulsive space charge force, if the beam emission angle on the main lens is small, the spot size on the fluorescent screen 15 can be reduced.
To summarize the above, the spot size (Dt) on the fluorescent screen 15 can be expressed as follows:
Dt={square root}{square root over ((Dx+Dst)2+Dic2)}
When it comes to the electron gun of the related art, the size (Db) of an electron beam incident on the main lens is approximately 2.5 mm-3.0 mm. When Db is greater than the range, the spot size is increased due to spherical aberration, and when Db is less than the range, the spot size is again increased due to repulsive space charge (electric) force.
As shown in
As the slot of the accelerating electrode 23 is deeper, an electron beam incident on the main lens is horizontally elongated, reducing a vertical size of the electron beam. As a result, the influence of deflection aberration is lessened, and the haze phenomenon at the peripheral portion of the screen is suppressed. Meanwhile, repulsive space charge (electric) force is increased, and thus the vertical size of the electron beam is increased. Accordingly, vertically elongated beam spots are created at the central portion of the screen, and spots at the peripheral portion of the screen are less influenced by the haze phenomenon.
However, the above schemes are not sufficient to obtain a satisfactory resolution at the peripheral portion of the screen. Therefore, to manufacture a cathode ray tube having a high resolution, a dynamic voltage with a parabolic waveform is applied, as shown in
However, to apply the dynamic voltage, a separate circuit is needed. This consequently raises the manufacture cost of an electron gun, and lowers price competitiveness of a cathode ray tube.
An object of the invention is to solve at least the above problems and/or disadvantages and to provide at least the advantages described hereinafter.
Accordingly, one object of the present invention is to solve the above problems by providing a structure of an electron gun for a cathode ray tube, in which resolution is much improved although a dynamic voltage is not applied.
The foregoing and other objects and advantages are realized by providing a cathode ray tube comprising a panel having a fluorescent screen formed on an inner surface, a funnel connected to the panel, an electron gun for emitting electron beams, a deflection yoke for deflecting the electron beams in horizontal and vertical directions, and a shadow mask with a color selecting function, wherein the electron gun comprises a triode unit for generating electron beams; pre-focus lenses for preliminary focusing and accelerating the electron beams generated by the triode unit; and a main lens for finally focusing and accelerating the focused and accelerated electron beams through the pre-focus lenses, and wherein a control electrode forming the triode unit has horizontally elongated electron beam passing holes, and an accelerating electrode forming the triode unit has vertically elongated electron beam passing holes or vertically elongated slots that are formed around the electron beam passing holes.
Another aspect of the present invention provides a cathode ray tube comprising a panel having a fluorescent screen formed on an inner surface, a funnel connected to the panel, an electron gun for emitting electron beams, a deflection yoke for deflecting the electron beams in horizontal and vertical directions, and a shadow mask with a color selecting function, wherein the electron gun comprises a triode unit for generating electron beams; pre-focus lenses for preliminary focusing and accelerating the electron beams generated by the triode unit; and a main lens for finally focusing and accelerating the focused and accelerated electron beams through the pre-focus lenses, and wherein a static voltage is applied to the electron gun, and astigmatism at a center of a screen is greater than 600V.
In the above embodiment of the cathode ray tube, a control electrode forming the triode unit has horizontally elongated electron beam passing holes, and an accelerating electrode forming the triode unit has vertically elongated electron beam passing holes or vertically elongated slots that are formed around the electron beam passing holes. Also, a vertical size of the electron beam passing hole on the control electrode is 40-70% of a horizontal size of the electron beam passing hole, and a horizontal size of the electron beam passing hole on the accelerating electrode is 80-90% of a vertical size of the electron beam passing hole on the accelerating electrode.
Another aspect of the present invention provides a cathode ray tube comprising a panel having a fluorescent screen formed on an inner surface, a funnel connected to the panel, an electron gun for emitting electron beams, a deflection yoke for deflecting the electron beams in horizontal and vertical directions, and a shadow mask with a color selecting function, wherein the electron gun comprises a triode unit for generating electron beams; pre-focus lenses for preliminary focusing and accelerating the electron beams generated by the triode unit; and a main lens for finally focusing and accelerating the focused and accelerated electron beams through the pre-focus lenses, and wherein a static voltage is applied to the electron gun, and a main focus electrode forming the main lens comprises at least two auxiliary electrodes.
Still another aspect of the invention provides a cathode ray tube comprising a panel having a fluorescent screen formed on an inner surface, a funnel connected to the panel, an electron gun for emitting electron beams, a deflection yoke for deflecting the electron beams in horizontal and vertical directions, and a shadow mask with a color selecting function, wherein the electron gun comprises a triode unit for generating electron beams; pre-focus lenses for preliminary focusing and accelerating the electron beams generated by the triode unit; and a main lens for finally focusing and accelerating the focused and accelerated electron beams through the pre-focus lenses, and wherein a static voltage is applied to the electron gun, and a horizontal direction crossover of the electron beams is formed between an accelerating electrode and a first pre-focus electrode or after the first pre-focus electrode, and a vertical direction crossover of the electron beams is formed between a control electrode and the accelerating electrode.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objects and advantages of the invention may be realized and attained as particularly pointed out in the appended claims.
The invention will be described in detail with reference to the following drawings in which like reference numerals refer to like elements wherein:
FIGS. 19 to 21 respectively illustrates an exemplary embodiment of a first pre-focus electrode according to the present invention;
FIGS. 22 to 28 respectively illustrates an exemplary embodiment of a second pre-focus electrode according to the present invention;
The following detailed description will present a cathode ray tube according to a preferred embodiment of the invention in reference to the accompanying drawings.
Referring to
The triode unit includes a cathode 41 having a built-in heater 40, a control electrode 42 for controlling electron beams emitted from the cathode 41, and an accelerating electrode 43 for accelerating the electron beams, in which the cathode 41 is arranged in-line.
The main lens includes a main focus electrode 46 and an anode 47 for focusing electron beams generated from the triode unit and accelerating the electron beams in the end. More specifically, the main focus electrode 46 includes a cap electrode 461 having a race track shaped rim portion, and two auxiliary electrodes 462, 463. The anode 47 includes a cup electrode 471 having a race track shaped rip portion, an auxiliary electrode 472, and an anode astigmatism correction electrode 473. Here, the auxiliary electrodes 462, 472 are to equalize convergence force of three electron beams, and recessed to a certain direction from the cap electrode 461 or the cup electrode 471.
The pre-focus lens includes a first pre-focus electrode 44 and a plate-shaped second pre-focus electrode 45.
Unlike the related art in which a dynamic voltage is applied to an electron gun, a static voltage is applied to the electron gun of the invention. More specifically, a voltage of 400-1000V is applied to the accelerating electrode 43 and the second pre-focus electrode 45, respectively. Further, a voltage corresponding to 20-30% of an anode voltage is applied to the first pre-focus electrode 44 and the main focus electrode 46, respectively. Here, the anode voltage ranges from 22 kV to 35 kV.
As shown in
The control electrode 42 and the accelerating electrode 43 have a plate shape.
FIGS. 19 to 21 respectively illustrates a front view and a side view of an exemplary embodiment of a first pre-focus electrode according to the present invention.
Referring to
An outside electron beam passing hole of the electron beam passing hole 444 formed on the relatively small electrode 443 is horizontally elongated.
A distance (S1) from the center of a central electron beam passing hole on the small electrode 443 to the center of an outside electron beam passing hole on the small electrode 443 is greater than a distance (S2) from the center of a central electron beam passing hole on the large electrode 441 to the center of an outside electron beam passing hole on the large electrode 441. This is because to adjust electron beams to be incident upon the center of main lens.
In the first embodiment shown in
In the second embodiment shown in
In the third embodiment shown in
Although the first pre-focus electrode 44 illustrated in FIGS. 19 to 21 is divided into the large electrode 441 and the small electrode 443, it is also possible to make them into one body.
Preferably, thicknesses of the first pre-focus electrode 44, the control electrode 42, and the accelerating electrode 43 satisfy a relation of the control electrode 42<the accelerating electrode 43<the first pre-focus electrode 44.
FIGS. 22 to 28 respectively illustrates an exemplary embodiment of a second pre-focus electrode according to the present invention.
As described before, the second pre-focus electrode 45 is a pre-focus lens forming electrode.
For a proper alignment of electrodes during the assembly of an electron gun, each of the electrodes should be supported. In case of the second pre-focus electrodes 45 illustrated in FIGS. 22 and 23, since the pre-focus electrodes have an oval shape, it is not easy to support the electrode even by using a support called “Mandrel”. Accordingly, instead of supporting the electrode through the electron beam passing hole 451, an outer surface of the electrode is used to support the electrode.
FIGS. 24 to 27 respectively illustrates a second pre-focus electrode 45 that is supported through an electron beam passing hole 451 by using Mandrel. In case of the second pre-focus electrode 45 shown in
The operation of an electron gun is now described below.
As mentioned before with reference to
Accordingly, the vertical size of an electron beam, Db (V), on the main lens should be reduced as much as possible while maintaining the same horizontal size of the electron beam, Db (H), with one in the related art shown in
In case of a related art electron gun in
According to the present invention, however, as
To have the H-crossover between the accelerating electrode 43 and the first pre-focus electrode 44, as discussed with reference to
Also, as mentioned before with reference to
When the control electrode 42 and the accelerating electrode 43 are formed as above, the vertical electron beam diameter, Db (V), is reduced while the horizontal electron beam diameter, Db (H), is increased.
In the meantime, in order to reduce spherical aberration of electron beams in the horizontal direction, Db(H) should also be reduced. To this end, the pre-focus lens should be reinforced, centering the second pre-focus electrode 45. This is accomplished by increasing a gap between the first pre-focus electrode 44 and the second pre-focus electrode 45 and between the second pre-focus electrode 45 and the main focus electrode 46, respectively.
Accordingly, when the H-crossover of the electron beam is formed between the accelerating electrode 43 and the first pre-focus electrode 44, the divergence angle of the electron beam before incidenting on the main lens is βH in the horizontal direction and βV in the vertical direction, as shown in
Comparing the divergence angle of the present invention with one in the related art of
In addition, the electron beam diameter at the main lens is 2.5 mm in the horizontal direction and 1.0 mm in the vertical direction. Particularly, the vertical electron beam diameter showed 50% of decrease from that of the related art electron gun shown in
The vertical electron beam diameter can be reduced even further to improve deflection aberration, and additional methods can be employed to resolve the haze phenomenon at the peripheral portion of the screen.
When the electron beam passing hole 451 formed on the second pre-focus electrode 45 is horizontally elongated as illustrated in
Moreover, by increasing the gap between the first pre-focus electrode 44 and the second pre-focus electrode 45, and the gap between the second pre-focus electrode 45 and the main focus electrode 46, it is possible to reduce Db (V) even more, while maintaining Db (H) to be same with one in the related art. Preferably, the gap between the first pre-focus electrode 44 and the second pre-focus electrode 45 and the gap between the second pre-focus electrode 45 and the main focus electrode 46 are in a range of 1.05 mm-1.4 mm, respectively.
Therefore, when the electron beam passing hole 451 on the second pre-focus electrode 45 is horizontally elongated, the vertical direction divergence angle (βV) of the electron beam before incidenting on the main lens becomes almost 0 degree, thereby being a parallel electron beam.
Now referring to
As aforementioned with reference to
Hence, the haze phenomenon at the peripheral portion of the screen is more effectively resolved.
Having the above structure, the H-crossover of an electron beam is formed between the accelerating electrode 43 and the first pre-focus electrode 44, and more electron beams are saturated at the central axis, as shown in
However, in above case, the horizontal size of an electron beam on the screen is increased, caused by repulsive space charge (electric) force of the electron beam.
As illustrated in
The horizontally elongated electron beam passing hole 444 enables the convergence force to work to the horizontal direction, and the divergence force to work to the vertical direction, thereby canceling the horizontal direction divergence force due to the vertically elongated electron beam passing hole 431 on the accelerating electrode 43.
Therefore, the horizontally elongated electron beam passing hole 444 on the first pre-focus electrode 44 can reduce the repulsive space charge force of the electron beam passing hole by distributing electron beams which are saturated at the central axis to outside, and can reduce the horizontal size of an electron beam formed on the screen.
On the other hand, the vertical direction divergence angle of an electron beam emitted from an electron gun with the above design is slightly greater than the horizontal direction divergence angle.
Accordingly, as shown in
As a result thereof, the electron beam formed on the screen is enlarged or magnified to a spot with a high brightness in the horizontal direction, but a low brightness in the vertical direction. This phenomenon is called “lack of astigmatism”.
To improve the lack of astigmatism, it is preferable to insert an anode astigmatism correction electrode 473, as shown in
Also, as shown in
Although the auxiliary electrode 463 can be in a plate shape, it is better to be in a cap shape to maximize correction effect. The electron beam passing hole 4631 formed on the auxiliary electrode 463 is vertically elongated, and the vertical size of the passing hole 4631 is less than 8.0 mm.
As depicted in
To overcome the halo phenomenon, electron beam passing holes 451 on the second pre-focus electrode 45 are vertically elongated, as shown in
In conclusion, different from the spots of the related art electron gun shown in
In other words, the electron gun according to the present invention is capable of resolving the occurrence of the haze phenomenon at the peripheral portion of the screen, and of improving the resolution of the screen without an application of a dynamic voltage.
While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
The foregoing embodiments and advantages are merely exemplary and are not to be construed as limiting the present invention. The present teaching can be readily applied to other types of apparatuses. The description of the present invention is intended to be illustrative, and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those skilled in the art. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures.
Number | Date | Country | Kind |
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10-2003-0074091 | Oct 2003 | KR | national |