This application claims the benefit of Korean Patent Application No. 2002-65272 filed on Oct. 24, 2002, which is hereby incorporated by reference for all purposes as if fully set forth herein.
1. Field of the Invention
The present invention relates to a color CRT, and in particular to an electron gun for a color CRT.
2. Description of the Prior Art
In general, a color CRT is a display used for a television, an oscilloscope, an observation radar, etc., and it displays an image on the front surface of a panel by controlling an electron beam from an electron gun according to a received image signal and by hitting a phosphor formed at the rear of the panel.
As depicted in
The acceleration grid 132 may include a first acceleration grid 132a and a second acceleration grid 132b installed a certain distance from the control grid 131 and installed a certain distance from the cathode 130 towards the anode 135.
In general, the focusing grid 133 may include two to four grids, as depicted in
In the above-described electron gun 102, when power is applied, an electron beam is generated from the surface of the cathode 130 by heating of the heater, is controlled by the control grid 131, is accelerated by the first and second acceleration grids 132a, 132b, and is focused or accelerated by the first and second focusing grids 133a, 133b and the anode 135. The electron beam focused and accelerated by the focusing grid 133 and the anode 135 is deflected by the deflection yoke 121, and it is emitted to the phosphor screen 104 of the panel 102.
Herein, the control grid 131 is grounded, 500V˜1000V is applied to the acceleration grid 132, high voltage as 25 kV˜35 kV is applied to the anode 135, and an intermediate voltage as 20˜30% of an anode voltage is applied to the focusing grid 133.
In particular, because an electrostatic lens is formed between the second focusing grid 133b and the anode 135, the electron beam 107 generated in the triode unit is focused at the center of the phosphor screen 104.
The focusing state of the electron beam 107 can be described by Equation 1:
Ds=√{square root over ((Dx+Dsa)2+(Dsc)2)}{square root over ((Dx+Dsa)2+(Dsc)2)} (Equation 1)
Where,
As shown in Equation 1, the size of the final pixel (Ds) on the screen is affected by a spherical aberration (Dsa). The main lens directly related to the spherical aberration (Dsa) is formed between the second focusing grid 133b and the anode 135. The corresponding holes 150, 160 are respectively formed at the second focusing grid 133b and the anode 135 so as to face each other. The corresponding hole 150 has an oval shaped rim structure, and the red, green, blue electron beams pass through the hole 150 at the same time.
An electrostatic screen grid 134 is formed at the corresponding holes 150, 160 as an inner grid. An inner grid formed in the second focusing grid 133b is called a first electrostatic screen grid 134a, and an inner grid formed in the anode 135 is called a second electrostatic screen grid 134b. The first and second electrostatic screen grids 134a, 134b are formed in order to have uniformity of the three (R, G, B) electron beams, and they make the three electron beams have the same shape.
As depicted in
In a conventional electron gun 106, the first and second electrostatic screen grids 134a, 134b have the same shape and size, the distance (Lb1) between the first electrostatic screen grid 134a and the corresponding hole 150 is same as the distance (Lb2) between the second electrostatic screen grid 134b and the corresponding hole 160.
In addition, as depicted in
In the conventional electron gun, HRO of the external hole 140a is 2.53 mm, and HLO is 2.90 mm resulting in a horizontal size of 5.43 mm. The vertical size of the external hole 140a is 5.96 mm, and accordingly it has a vertically long shape.
The electron beam convergence is defined as the distance between the red (R) electron beam and the blue (B) electron beam among three electron beams on the screen. As depicted in
In the first and second electrostatic screen grids 134a, 134b, the red electron beam is separated from the blue electron beam by 11 mm, and the distance is about 8–10 mm on the screen. However, it has to be “0” on the screen in order to prevent pixel distortion. Generally, only when the electron beam convergence (OCV) is within 2 mm on the screen, is it possible to adjust. Accordingly, in the conventional art, in order to solve this problem, a pre-convergence is performed between the first accelerating grid 132a and the first focusing grid 133a, and accordingly the electron beam 107 passes the grids from the first focusing grid 133a to the main lens having a potential difference different from each other. However, when the electron beam 107 passes the control grid 131 and the second focusing grid 133b, the electron beam convergence of the first and second electrostatic screen grids 134a, 134b having almost same shape and size is lowered, and accordingly it exceeds the adjustment range.
Accordingly, the present invention is directed to an electron gun for a color CRT substantially obviates one or more of the problems due to limitations and disadvantages of the related art.
An advantage of the present invention to provide an electron gun for a color CRT capable of making a uniform electron beam by preventing distortion of a pixel and improving the resolution by attaining an electron beam convergence within 2.0 mm.
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, in an color CRT, an electron gun for the color CRT includes a triode unit for generating three electron beams and controlling and accelerating the generated electron beams; a main focusing lens unit that focuses the electron beams generated by the triode unit; a first electrostatic screen grid installed in the main focusing lens unit having three electron beam through holes linearly-arranged for passing the three electron beams and two of the holes are external holes, and the first grid having a first oval shaped hole that passes all three electron beams, the first oval shaped hole spaced a distance d1 from the through holes; and a second electrostatic screen grid installed in the main focusing lens unit having three electron beam through holes linearly-arranged for passing the three electron beams and two of the holes are external holes, and the second grid having a second oval shaped hole that passes all three electron beams, the second oval shaped hole spaced a distance d2 from the through holes; wherein the first grid external holes have an external distance HL1 and an internal distance HR1 and the second grid external holes have an external distance HL2 and an internal distance HR2; and wherein HL1 is greater than HR1, HL2 is greater than HR2, d1 is greater than d2, HL2 is greater than HL1, and HL2+HR2 is greater than HL1+HR1.
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.
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:
Reference will now be made in detail to an embodiment of the present invention, example of which is illustrated in the accompanying drawings.
As depicted in
The main lens unit includes: a first focusing grid 133a installed among the plurality of accelerating grids 132 of the triode unit; a second focusing grid 5 installed a certain distance from the accelerating grid 132; and an anode 6 installed a certain distance from the second focusing grid 5.
The second focusing grid 5 and the anode 6 respectively include a first electrostatic screen grid 2a having a line-arranged electron beam through holes 3 for passing three electron beams; and a second electrostatic screen grid 2b having a line-arranged electron beam through holes 4 for passing the three electron beams. The electron beam through holes 3, 4 respectively formed at the first and second electrostatic screen grids 2a, 2b consist of the central holes 3b, 4b which are holes at the center of the three holes; and a pair of external holes 3a, 4a to the outside of the central hole 3b, 4b.
The center of the hole is the central point of the vertical line having the largest vertical extent within the external holes 3a, 4a. In the horizontal direction, a distance from the center of the external holes 3a, 4a to the side of the external holes toward the central hole 3b, 4b is an internal distance HR1, HR2; a distance from the center of the external holes 3a, 4a to the side of the central hole 3b, 4b away from the central hole is an external distance HL1, HL2. The ratio HL1/HR1 of the external distance HL1 to the internal distance HR1 of the first electrostatic screen grid 2a is different from the ratio HL2/HR2 of the second electrostatic screen grid 2b.
In the electron gun of the present invention, the improvement of the electron beam convergence through holes 3, 4, of the first and second electrostatic screen grids 2b will be shown by test results.
When HR1 is same as HR2, HL1 and HL2 may be adjusted.
When the electron beam reaches the effective screen, as depicted in
When HL2/HL1 is uniformly determined as 1.03 in order to have an electron beam convergence of 2 mm, and HR1/HR2 is 1.0, as depicted in (A) of
In order to solve the above-mentioned problem, in the present invention, a horizontal distance HR1+HL1 and is less than a horizontal distance HR2+HL2. At the same time, HR1 is different from HR2.
As depicted in (B) of
In the embodiment of the present invention, HL2/HR2 is approximately 2.13, HL1/HR1 is approximately 1.49, and a horizontal distance ratio of the external hole is 1.05 of a horizontal distance of the second electrostatic screen grid 2b over the first electrostatic screen grid 2a.
In the electron gun for the color CRT in accordance with the present invention, as depicted in
In addition, a magnetic field may be applied to the electron beams between the triode and the main lens. This may further help to focus the electron beams down to a small size on the phosphorus screen.
In addition, by forming the external electron beam through hole 4a of the second electrostatic screen grid 2b by using a jig in an electron gun assembly, the assembly can be performed more smoothly.
In the meantime, in the embodiment of the present invention, the external holes of the first and second electrostatic screen grids 2a, 2b have different oval shapes. However, as depicted in (A) of
In the electron gun in accordance with the present invention, by making uniform electron beams and obtaining an electron beam convergence within 2.0 mm by the optimum-design of the size of the external hole of electron beam through holes, resolution can be improved. Further, by making the haze and core have a symmetric shape, pixel distortion may be reduced.
It will be apparent to those skilled in the art that various modifications and variation can be made in 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.
Number | Date | Country | Kind |
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10-2002-0065272 | Oct 2002 | KR | national |
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