DE1805827B2 - ELECTROSTATIC ELECTRON LENS FOR ELECTRON BEAM TUBES FOR FOCUSING AND CONVERGING OFF-AXIS AND THEIR USE OF ELECTRON BEAMS - Google Patents

Description

The invention relates to an electrostatic electron lens for electron beam picture tubes for Focusing and converging of off-axis electron beams with those in the generic term of claim 1 specified features.

From GB-PS 799533 a color picture tube is known, in which three electron beams are focused and converged on the screen. the The individual bundles of rays are focused in part by the lens action between successive ones Grids of the electron gun that are pre-focussed in this way causes. The lens obtained with the help of two practically circular cylindrical electrodes converges the beams on the screen, d. H. that the three electron beams are in one point meet on the screen.

One of the circular cylindrical electrodes has the shape a conductive covering on the bulb, but this is not essential for the effect of the lens, which can also consist of two cylindrical sleeves of the same or different diameter. This the The beam converging lens also gives each electron beam the required level Refocusing necessary to form a sharp impact spot on the screen. Such a thing Electrostatic convergence system is particularly used when the beams are facing each other are very close, because there is then little space for the pole pieces required for magnetic convergence gives. This can be the case, for example, in a cathode ray tube in which the different Electron beam from a single electro-human gun be generated.

In GB-PS 799 533 it is mentioned that such Lens exerts an astigmatic focusing on the off-axis beam. the Measures taken according to this patent specification, however, have the purpose of greater convergence reach, and you can see the astigma-

Correct the focussing only slightly. It is the object of the invention to provide an electron lens of the type mentioned, in which the aforementioned astigmatism of the off-axis beam bundles is largely avoided.

ίο To solve this problem is an electrostatic Electron lens for electron beam picture tubes of the type mentioned according to the invention designed in such a way as indicated in the characterizing part of claim 1 in detail.

In a further embodiment of the invention, measures can be taken as in the subclaims 2 and 3 specified in more detail.

The invention is based on the following findings:

Those in the plane through the axis of an electron beam and the axis of the cylindrical electrodes lying partial beams of the bundle due to the spherical aberration of the lens to a greater extent in the direction of the axis of the beam focused as the partial rays which lie in the plane through the axis of the bundle which is perpendicular to the first level. A plane through the axis of the cylinder is called a meridional plane of the lens, and said plane through the axis of the

Bundle and the axis of the cylinder is thus the meridional one passing through the axis of the bundle Plane of the lens. The partial rays lying in this plane become meridional partial rays of the bundle called. A plane perpendicular to the meridional

Planes of the lens is called a sagittal plane of the lens. The partial rays in a sagittal The plane lying through the axis of a bundle is called sagittal partial rays of the bundle. The difference in the strength of the refocusing for the meridional partial beams and the sagittal partial beams is canceled by eliminating the rotational symmetry of the converging lens.

The invention is described in more detail using an exemplary embodiment and with reference to the drawings. It shows

1 shows a section through a cathode ray tube,

FIG. 2 shows an enlarged illustration of certain parts of the section according to FIG. 1,

3 shows the shape of convergence electrodes which are not designed according to the invention, FIGS. 4, 5 and 6 cross sections through FIG. 3,
7 shows a schematic representation of the partial beam path in the bundles in the case of the arrangement according to FIG. 3,

8 shows an embodiment of the convergence electrodes for a lens according to the invention,
9, lü and 11 cross sections through FIG. 8.
The cathode ray tube 1 contains a schematically illustrated electron gun 2 which generates three electron beams which lie in planes offset from one another by 120 ° through the axis of the electron beam, and which converges these three electron beams on the screen. The deflection of the electron beams is effected by a deflection device S shown schematically.

In Fig. 2 the neck portion of the tube is partially in

Section shown. Only one of the three cathodes, 6, is visible from the electron beam generation system. The three cathodes are located in the corners of an isosceles triangle perpendicular to the axis 7 of the electron beam generating system , that is to say they are arranged offset from one another by an angle of 120 °. The electron beam generation system contains a common first grid 8 which is provided with an opening 9 for the electron beam coming from the cathode 6 , a common second grid 10 which is provided with an opening 11 for the said bundle, and a common third grid 12, which is provided with an opening 13 for the said bundle. The centers of the openings 9, 11 and 13 are located on an axis 18 parallel to the axis 7 of the electron gun. The electron gun also contains a common fourth grid 14 and a common circular-cylindrical fifth grid 15. The fourth grid 14 consists of two interconnected circular-cylindrical parts 16 and 17 (only the cross-sectional lines of the grids 14 and 15 are shown) for each of the electron beam between the second grid 10 and the fourth grid 14, while refocusing takes place in the converging lens, which is an accelerating lens with the fourth grid 14 and the fifth grid 15, the lens field between the circular cylindrical part 17 and the circular cylindrical part 15. have the same diameter, is generated.

Fig. 3 shows the shape of a fourth and fifth grid not according to the invention. The fourth grid 20 consists of two interconnected circular cylindrical parts 22 and 23. The fifth grid 21 is circular cylindrical and has the same diameter as the part 23. The facing ends of the grids 20 and 21 lie in planes, perpendicular to the axis of the cylinder. The axes of the bundles at the point in the middle of the gap are indicated by 24, 25 and 26. To explain the mutual position of the bundles, lines 27, 28 and 29 are drawn through points 24, 25 and 26, parallel to the axis of the cylinder. A plane perpendicular to the axis of the cylinder intersects these lines at points 30, 31 and 32, which form the corner points of an equilateral triangle.

Fig. 4 shows a section perpendicular to the axis of the convergence lens according to Fig. 3; Fig. 5 shows a plan view of the convergence lens of Fig. 3; Fig. 6 shows a front view of the convergent lens of FIG. In FIG. 4, the circular-cylindrical part 23 is shown of the grating 20. The three bundles are indicated at 33, 34 and 35.

5 shows a cross section of the conyergence lens in which the intersections of some equipotential surfaces with the sagittal plane through the axis of the bundle 33 are indicated by the reference numerals 36, 38, 39, 40, 41 and 42 . From Fig. 5 it can be seen that these cuts are symmetrical on both sides of the gap.

6 shows a cross section of the convergence lens in which the intersections of some equipotential surfaces with the meridional plane through the axis of the bundle 33 are indicated by the reference numerals 43, 45, 46, 47, 48 and 49. From Fig. 6 it can be seen that these cuts are symmetrical on both sides of the gap.

Since, in the case described in FIGS. 3, 4, 5 and 6, the axis of each bundle in the lens field between the fourth and fifth grating lies outside the axis of the cylinder, this lens field causes an aberration when each bundle is refocused. In Figure 7, 50 is the axis of the electron gun. Each bundle is focused by the lens effect between the second grid 10 and the fourth grid 14 approximately at point 51 on the th axis of the electron beam generation system. The point 51 must be imaged in a point on the screen by the lens action between the fourth, 14, and fifth grids, 15. The lens effect must therefore converge and refocus the bundles uniformly. In reality, the above-mentioned aberration occurs in the focusing, which results from the beam path shown in full for only one bundle. Circle 53 is the cross-section of this bundle with the major surface of the converging lens. The mendional partial beams lying in the plane through the axis 54 of this bundle and the axis 50 of the electron beam generating system, of which the partial beams 55 and 56 are shown in FIG. 7, are focused approximately at point 57. The partial rays lying in the sagittal surface through the axis of this Bjndels, of which partial rays 58 and 59 are shown in FIG. 7, are focused on this axis at point 60 because of the rotational symmetry of the lens field about axis 50. The meridional partial rays of the bundle are therefore focused to a greater extent in the direction of the axis of the bundle than the sagittal partial rays. In this way, two focal lines 61-62 and 63-64 are formed, which cause astigmatism of the electron spot obtained on the screen. Of the other two bundles, the cross-sections 65 and 66 are shown with the main plane of the converging lens and the circle 67 through the centers of the rays in this plane, as well as a part of some ray paths, all of which originate from point 51.

Fig. 8 shows an example of the fourth and fifth grids formed according to the invention. The fourth Grid 70 consists of two interconnected circular cylindrical parts 72 and 73. The fifth Grid 71 is circular cylindrical and has the same diameter as the part 73. The facing Ends of the grids 70 and 71 are sinusoidal, in a complementary manner, so that the gap has a constant width and the center line of the gap is sinusoidal in the same way. The axes of the bundles at the location of the center of the gap are indicated by 74, 75 and 76. In order to explain the mutual position of the bundles are indicated by points 74, 75 and 76 lines 77, 78 and 79 drawn parallel to the axis of the cylinder. A plane perpendicular to the axis of the cylinder intersects these lines at points 80, 81 and 82, which form the corner points of an equilateral triangle. The course of the mentioned ends of the (jitter 70 and 71 is such that over the circumference in the axial direction Sine can be described, three pieces because of the fact that there are three bundles, while the greatest deviations in the direction of the cathode lie at the point of the bundle.

In Fig. V) the circular cylindrical part 73 is do Lattice 70 (part 73! Shown in which the three bundles 83. 84 and 85 at the point of the gap / between the grids 70 (part 73) and 71, of which federal

the axes at this point in Fig. S through 74, 75 and 76 are indicated.

Fig. 10 shows a cross section of the convergence lens, in which the intersections of some equipotential surfaces with the sagittal plane through the Axis of the bundle 83 with 86, 87, 88, 89, 90, 91 and 92 are indicated. It can be seen from the figure that these cuts are not symmetrical on either side of the gap. Compared to the They are intersections 36 to 42 inclusive from FIG. 5 at the point of the axis of the bundle with the concave side in the direction of the fifth grid 71 curved. This results in a stronger focusing of the sagittal partial beams.

Fig. 11 shows a cross section of the convergence lens, in which the intersections of some equipotential surfaces with the meridional plane through the Axis of the bundle 83 with 93, 94.95, 96, 97, 98 and 99 are indicated. It can be seen from the figure that these cuts are not symmetrical on either side of the gap. Compared to the Cuts 43 up to and including 49 from FIG. 6 they are at the point of the axis of the bundle with the convex side in the direction of the fifth lattice 71 curved. This will result in a weaker focus of the meridional partial rays.

In a certain case, the round opening 9 has a diameter of 0.75 mm, the round opening 11 has a diameter of 0.75 mm and the round opening 13 has a diameter of 2.0 mm. The distance between the line 18 through the centers of the openings 9, 11 and 13 and the axis 7 of the electron gun is 2.5 mm. The clear width of the part 72 of the fourth grating 70 is 14 mm and that of part 73 is 22 mm. The clear width of the fifth grating 71 is also 22 mm The dimension of the part 72 in the direction of the axis of the electron gun is 7 mm, the mean dimension of the part 73 in this direction is 22 mm and the mean dimension

ίο of the fifth grid 71 in this direction 10 mm. Of the The distance between the part 73 and the fifth grid 71 is 2 mm. The sinusoidal shape of the ends of part 73 and grating 71 has an amplitude of 0.25 mm. This electron gun can be operated with the voltages below:

Cathode between 0 V and 80 V.

First grid 0 V

Second grid 750 V

Third grid 350 V

Fourth grid between 3 400 V and 4 200 V Fifth grid 25 000 V

The variable voltage on the cathode is used to control the bundle and that on the fourth gate to converge the bundles depending on their meeting point on the screen. At a maximal Current of 2500 μΑ per beam has been found

that the slit shape of the convergence lens is a reduction in the electron spot of about 15%

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Electrostatic electron lens for electron beam picture tubes for focusing and converging off-axis electron beams, which has two circular cylindrical electrodes coaxial with one another and such is not designed to be rotationally symmetrical that the astigmatism of the lens in the areas of the The course of the beam bundle is corrected, characterized in that the two lens electrodes are arranged at a distance one behind the other and are designed such that the distance from the center line of the gap formed by the two electrodes from the screen into the one each through the axis Electron beam with the axis of the lens electrodes has certain levels maxima. 2. Electrostatic electron lens according to claim 1, characterized in that the center line is sinusoidal in shape. 3. Use of an electrostatic electron lens according to claim 1 or 2 in a color picture tube with three electron beams for converging all three beams in one Point in the plane of the color selection electrode.