DE1539800B2 - cathode ray tube - Google Patents

Description

The invention relates to a cathode ray tube with a vacuum housing, a fluorescent screen, a Beam generating system for generating an electron beam directed onto the luminescent screen, a deflection device with two deflection systems lying one behind the other in the direction of the tube axis for deflection of the electron beam in two mutually perpendicular directions and with a post-acceleration device, consisting of a spherical cap-shaped electrode curved towards the luminescent screen, whose center of curvature coincides with the center of deflection of a deflection system of the deflection device and the one slot parallel to the deflection plane of this deflection system for the passage of the electron beam and further comprising one provided on the inner wall of the vacuum housing conductive coating that extends from the fluorescent screen to the height of the spherical cap-shaped electrode and such is formed and electrically biased that between the spherical cap-shaped electrode and the Luminescent screen a post-accelerating the electrons deflected in the slot direction without changing direction Field emerges.

The post-acceleration of the electrons after their horizontal and vertical deflection in a cathode ray tube has the purpose of increasing the energy of the electrons and thus a to achieve greater brightness. However, it must be ensured that the post-acceleration field does not lead to deflection or raster distortion.

Such distortions can be prevented by forming the post-acceleration field in such a way that it accelerates the electrons emerging from the deflection device without changing direction. With one off the British patent 8 49 600 known cathode ray tube of the type described above is to for this purpose the conductive coating made of resistive material provided on the inner wall of the vacuum housing Material formed and designed so that its resistivity is reversed along the tube proportional to the square of the distance from the deflection center of that deflection system which changes coincides with the center of curvature of the spherical dome-shaped electrode and its deflection plane runs parallel to the slot in the spherical cap-shaped electrode. Since this slot at the known tube must be very narrow, but on the other hand a deflection across the slot also still must be possible, the known tube is designed so that the deflection system deflecting perpendicular to the slot is close to the spherical cap-shaped electrode, while the other deflection system, its deflection center forms the center of curvature of the spherical cap-shaped electrode, this electrode on farthest away. As a result, the radius of curvature of the spherical cap-shaped electrode becomes relative large and thus the curvature of this electrode is relatively weak, so that no large deflection angles possible are.

The object of the invention is, a cathode ray tube to train with post-acceleration of the type described above so that a larger Deflection angle than with the known tube is possible. According to the invention, this object is achieved by that between the spherical cap-shaped electrode and the deflection system closest to it A four-pole electron lens which amplifies the deflection of the electron beam is arranged on the deflection device and that the center of curvature of the spherical cap-shaped electrode is in the center of deflection This deflection lies that further the center line of the slot of the spherical cap-shaped electrode through the bundle knot of the electrons passing through the electron lens during operation of the tube, and that the coating provided on the inner wall of the vacuum housing during operation of the tube on an opposite the spherical cap-shaped electrode has a positive direct voltage potential applied to it.

In the case of the tube according to the invention, the center of curvature of the spherical cap-shaped one falls Electrode with the center of deflection closest to this electrode. The curvature

The radius of the electrode can thus be smaller than with the known one Arrangement, whereby the radii of curvature of the equipotential surfaces of the Post-acceleration field become smaller, so that larger deflection angles are possible. Thanks to the four-pole The electron lens can move the other deflection system, the deflection plane of which is perpendicular to the slit, further away from the spherical cap-shaped electrode without the maximum possible deflection angle in this The plane becomes very small as a result of the limited slit width, because the one running through the four-pole electron lens Electrons have their bundle knot on the center line of the slot. The quadrupole electron lens thus brings about an advance of the apparent deflection center as a result of an amplification of the deflection.

Combinations of post-acceleration and distraction amplification come in various forms per se known. The German Auslegeschrift 11 30 938 shows a cathode ray tube in which the deflection amplification takes place simultaneously in the post-acceleration space, namely by special design of the post-acceleration field, which is an enlarged, radial has outward component. However, this requires a mesh electrode at the entrance of the post-acceleration space, but this leads to a reduction in image brightness and the risk of stimulating Brings secondary electrons with it. In other arrangements known from US Pat. No. 3,042,832 a lot of effort has to be taken into account for amplifying the deflection and post-acceleration, to give the field in the post-acceleration space the correct course, so that the deflection gain remains distortion-free. In some of these arrangements the post-acceleration and deflection gain takes place held practically over the entire length and width of the enlarged tube part, so that extremely large electrodes are required, their holding and adjustment is difficult and the weight of the tube increase considerably. In another embodiment, the deflection is amplified by a two-pole two-hole lens, which, similar to an optical convex lens, shows the electron beam coming from the deflection device enlarged on the screen. The post-acceleration is achieved in that the two electrodes of the lens are concentric are spherically curved towards the bundle node of the lens on the screen side. Although here the combined Post-acceleration and deflection amplification field is spatially limited, the structural effort for this embodiment is not smaller, because behind the lens there is a spacious one that extends over the whole Tube diameter extending funnel must be provided to accommodate the space between the lens and keep the screen free of fields.

Quadrupole electron lenses in cathode ray tubes have heretofore only been used as deflection units (see German Patent 7 49 574). Their use in connection with a spherical cap-shaped electrode and a conductive coating on the inner wall of the tube housing according to the invention enables a distortion-free Post-acceleration even for large deflection angles, without the above-described Disadvantages of the known designs have to be accepted.

In an advantageous embodiment of the invention, the one provided on the inner wall of the vacuum housing is located Deposits when the tube is in operation on an electrode that is positive compared to the spherical cap-shaped electrode DC voltage potential of between 10 and 20 kV. A preferred embodiment of the invention is characterized in that between the two deflection systems of the deflection device second quadrupole electron lens is arranged. This lens can be used to correct the quadrupole through the other Electron lens-induced astigmatism are used.

The invention and its mode of operation are as follows explained using an exemplary embodiment with reference to drawings.

F i g. 1 shows the schematic of a cathode ray tube in longitudinal section;
F i g. 2 shows schematically one in the tube according to FIG. 1 usable quadrupole electron lens;

F i g. 3 shows a front view of the components in the tube of FIG. 1 contained spherical cap-shaped electrode.

The in F i g. 1 shown cathode ray tube has a vacuum housing 1, which for example made of glass consists. Inside the housing 1 is a emissive cathode 2 heated by a heating wire 3, a Wehnelt electrode 4, focusing and acceleration electrodes 5, 6 and 7, vertical deflection plates 8, a first quadrupole electron lens 9, Horizontal deflection plates 10, a second four-pole electron lens 11, a spherical cap-shaped electrode 12 with a slot 13, and a fluorescent screen 14. The inner wall of the housing 1 is with a conductive Covering 15 provided, which consists, for example, of graphite and extends from the luminescent screen 14 to the height of the spherical cap-shaped electrode 12 extends.

The dimensions and position of the spherical cap-shaped electrode 12 are chosen so that its center of curvature substantially coincides with the effective center of horizontal deflection, d. H. with the virtual point of intersection of the electron paths in the plane perpendicular to the plates 10.

A DC voltage source Si is used to provide the various To keep the electrodes of the tube at the desired electrical potentials. The in F i g. 1 registered Stress values are only examples that should be viewed as orders of magnitude.

The fluorescent screen 14 of the tube and the conductive coating 15 are at a high potential with respect to ground from about 10 to 20 kV. This potential is provided by the source 52.

The F i g. FIG. 2 schematically shows the known structure of a quadrupole electron lens, as it is for the lenses 9 and 11 in FIG. 1 is used. It is an electrostatic lens formed by four semi-cylindrical or hyperbolic electrodes 21, 22, 23 and 24. The in F i g. The potentials shown in 2 apply to the lens 11. The axis XX corresponds to the horizontal deflection plane (perpendicular to the plane of the drawing in FIG. 1), while the axis YY corresponds to the vertical deflection plane. The electrodes 21 and 23 are at a potential -I- V and the electrodes 22 and 24 at a potential - V. In this way polarized, the lens has a divergent effect in the direction XX and a convergent effect Y- Y.

The for the lenses 9 and 11 in F i g. 1 specified voltage values of 100 or 300 volts are only examples.
In the tube of FIG. 1, the quadrupole lens 11 is a magnifying lens, while the lens 9 is used to correct the astigmatism caused by the lens 11. In addition, the position of the lens 9 between the two deflection systems 8 and 11 enables

an increase in the vertical deflection generated by the deflection system 8.

The F i g. 3 shows an elevation of the spherical cap-shaped Electrode 12 with its slot 13, which is shown in FIG. 1 is shown in section. The slot 13 is rectangular here drawn, but it can also have an elliptical shape or the like.

When the tube is in operation, the voltages supplied to the quadrupole lens 11 are selected so that all electron paths run through the slot 13. That is between the electrode 12 and the conductive coating 15 The forming electrical field is such that its equipotential surfaces are in the vicinity of the electrode 12 are essentially hemispheres, the center of which is also the center of curvature of the spherical cap-shaped Electrode 12 is. Only in the vicinity of the slot 13 do the equipotential surfaces deviate from the spherical shape, they are curved inwards there and in this way form a thin convergence lens, whose Center is in the plane of the slot.

Since the center of curvature of the spherical cap-shaped electrode 12 and thus also said Equipotential surfaces coincide with the effective center of deflection of the horizontal deflection the electron paths after passing through the slot 13 no further deflection in the horizontal direction more. On the other hand, the one formed at the slot 13 by the inward curvature of the equipotential surfaces thin convergence lens means that even vertically deflected electrons end up in the same direction continue flying in which they got to the slot. Consequently, the overall effect of the by the high Voltage of the luminescent screen 14 and the field 15 formed a pure post-acceleration without Change of direction of the electrons, so that the electrons with increased energy and without deflection distortion hit the luminescent screen. The light spots generated on the screen are therefore of great brightness and make it possible to make temporary processes that occur very briefly visible.

For this purpose 2 sheets of drawings

Claims (3)

15 öuu patent claims: 1. Cathode ray tube with a vacuum housing, a fluorescent screen, a beam generator system for generating an electron beam directed onto the luminescent screen, a deflection device with two deflection systems lying one behind the other in the direction of the tube axis for deflection of the electron beam in two mutually perpendicular directions and with a post-acceleration device, consisting of a spherical cap-shaped electrode curved towards the luminescent screen, its center of curvature with the center of deflection of a deflection system of the deflection device coincides and the one parallel to the deflection plane of this deflection system slot to Having passage of the electron beam, and further consisting of one on the inner wall of the vacuum housing provided conductive coating, which extends from the fluorescent screen to the height of the spherical cap-shaped ' Electrode is enough and is designed and electrically biased that between the spherical cap-shaped electrode and the luminescent screen insert the electrons deflected in the direction of the slot there is a post-accelerating field without a change in direction, characterized in that that between the spherical cap-shaped electrode (12) and the one closest to it Deflection system (10) of the deflection device (8, 10) is a deflection of the electron beam that amplifies four-pole electron lens (11) is arranged and that the center of curvature of the spherical cap-shaped Electrode (12) lies in the deflection center of this deflection, that furthermore the center line of the slot (13) of the spherical cap-shaped electrode (12) through the bundle knot of the during operation the tube passes electrons passing through the electron lens (11), and that of the electrons on the inner wall of the vacuum housing (1) provided covering (15) when operating the tube on an opposite to the spherical cap-shaped electrode (12) positive direct voltage potential is applied. 2. Cathode ray tube according to claim 1, characterized in that said DC voltage potential is between 10 and 20 kV. 3. Cathode ray tube according to claim 1, characterized in that between the two deflection systems (8, 10) of the deflection device a second quadrupole electron lens (9) is arranged.