DE852424C - Electric discharge tubes with an electron mirror - Google Patents

Description

The invention relates to electric discharge tubes, in which the electrons emitted from an elongated cathode in a direction perpendicular to the length of the cathode S to be bundled. This bundle experiences on its way from the cathode to one or more Collecting electrodes under the influence of the field of an electron mirror a change of direction, and the electron flow is controlled

ίο by distraction.

The electron beam in the tubes described here has an elongated cross section and is called a flat bundle in the description below. However, this does not mean that all electron orbits are parallel. The electron orbits can converge in the bundle or diverge, and above all in a direction perpendicular to the longitudinal direction of the cathode or to the Length of the cross-section of the bundle.

Discharge tubes are already known in which a flat bundle, before it reaches the anode or Reached anodes, is reflected by an electron mirror. In a specific embodiment of such a discharge tube, it is electron-reflecting Field produced by means of a rod-shaped electrode, which is approximately parallel to the The length of the cathode runs.

Furthermore, a discharge tube with a flat beam has been proposed in which a Mirror electrode is designed as a curved surface or consists of several flat parts that form a broken surface, the creation of which

which run parallel to the longitudinal direction of the cathode ver, whereby a converging after the mirroring greedy bundle is obtained.

In these tubes, the electron current is controlled by deflection. Possibly can be applied to the mirror electrode itself such a voltage that they simultaneously the Causes distraction. The deflected electron bundle is reflected by an or »Ο collected several collecting electrodes, and for almost all purposes require that in the plane this electrode or electrodes a sharp delimitation of the cross section in the deflection direction is available. For tubes in which increased voltages are taken from the collecting electrode only then will there be a large change in current in the collecting electrode or in the collecting electrode troden if the above-mentioned condition is met. If namely the edge of the bundle cross-section passes the edge of the collecting electrodes or electrodes, one more must in a moment large number of electrons are captured, while in the following instant the current is in this electrode must be practically zero. Also for discharge tubes in which the collecting electrode consists of a fluorescent screen, a sharply delimited bundle cross-section is necessary because only in this case a sharp separation of the dark and the illuminated part of the screen is obtained.

A sharp delimitation of the cross-section of the bundle can be achieved in a simple manner with the aid of diaphragms achieve. There are, however, great disadvantages associated with the use of diaphragms, especially in the case of diaphragms the usable opening angle of the focusing system is smaller, thus reducing the current in the bundle is more restricted. It is also used when building tubes with one or more apertures very difficult to arrange them in the right place in the tube and to cut them in such a way that they do not accept any surface charge themselves and thus have a detrimental effect on the electron flow.

By using a converging electron mirror, as already proposed, in this relationship has already improved, but still requires diaphragms. The above-mentioned disadvantages become apparent in an electric discharge tube according to the invention avoided in which a flat electron beam, which is controlled by deflection, on its way from an elongated cathode to one or more collecting electrodes the field of a converging electron mirror experiences a change in its original direction and the focal distance from one end of the electron mirror to the other is smaller or becomes larger and in which the suspension electrode or electrodes are so arranged with respect to the mirror is or are that the focal points are partly in front of and partly behind the collection electrode (s) lie.

The electron mirror can be formed by several flat electrodes that represent a broken surface. Furthermore, the electron mirror can consist of a curved surface or of several parts with decreasing curvature. In all types of mirror electrode it forms a regular surface, and the generators are approximately parallel to the longitudinal direction of the cathode. The Spiegelei ektrode preferably has such a curved shape that the curvature increases steadily from one end to the other. In general, the change in direction of the bundle will be at least 90 ^0th

The collecting electrode or electrodes can form part of a composite anode, which are built so that the bundle in its outermost layers either on one part of the Anode or the other. The dividing line between these parts can be either be a straight, broken, or curved line. As noted earlier, the collection electrode can also be a fluorescent screen with a sharp intensity edge in the bundle as well is particularly important. The great advantage that can be achieved with electrical discharge tubes according to the invention is the one-sided sharply delimited cross-section of the electron beam at the point of the collecting electrode or electrodes.

It should also be noted that the fact that the collecting electrode or electrodes with respect to the mirror are arranged in such a way that the focal points are partly in front of, partly behind the collecting electrode or the collecting electrodes, does not exclude that on this electrode or these electrodes there is also a focal point. In general, the collection electrode intersects the geometric one Location of focal points.

The invention is explained in more detail with reference to the drawing, in which

Fig. Ι shows the course of the trajectories of electrons from an electron mirror with a come from the same focal distance over the whole surface;

FIG. 2 shows a family of intensity curves of the electron current in a system according to FIG. 1; Fig. 3 shows the course of the electron current in a tube according to the invention with a Electron mirror with variable focal distance;

FIG. 4 shows the intensity profile of the electron current for an electron profile according to FIG. 3; Fig. 5 illustrates an electrode system in a tube according to the invention;

6 shows an electrode system according to the invention with an anode as a collecting electrode, and in

Fig. 7 is a tube system according to the invention with a fluorescent screen as a collecting electrode shown.

In Fig. Ι the electrons come from an electron mirror (not shown) and follow Orbits indicated by solid lines in the direction of the arrows. As from the figure It is clear that not all electrons are concentrated in the same plane. The focal point of the

Claims (7)

The electron near the axis lies in plane a, while the focal points of the electron orbits further out lie in planes b and C. In the plane the intensity at the focal point is very great, but a large number of scattered electrons still occur on both sides of the focal point, so that the intensity decreases only gradually on both sides. This intensity profile is shown schematically in FIG. 2 by the curve. In the level /; In Fig. 1 one finds a lower electron intensity in the middle than in the electron intensity curve, but the course of the electron intensity shows. on both sides a much steeper flank, as in FIG. 2 by the curve /; is shown. In the plane c in Fig. 1 there is a relatively constant intensity intensity over a fairly large part, which, however, is very much, less than the maximum intensity in the plane. This is shown by curve c in FIG. The slope is greatest where the two branches of the caustic line of the electron bundle intersect planes b and C in FIG. 1. Due to the residual current occurring next to the caustic line, however, this edge sharpness is significantly reduced. This residual current could be reduced by using diaphragms, but only at the expense of the overall intensity in the electron bundle. In Fig. 3 the course of the electron trajectories J in a basic discharge tube is shown! posed. The difference from the course shown in Fig. 1 is that the asymmetrical mirror structure, i. H. by the course of the focal point distance from one end of the mirror to the other, it is achieved that there is only one caustic line which intersects the image bcnc b at χ. The course of the current density in this plane is shown in FIG. 4 by the curve rf. This figure shows that at χ there is a very sudden transition from a high current density to a current density which is practically zero. A residual current now only occurs on one side of χ. In FIG. 5, an electrode system is shown schematically with which an electron curve according to FIG. 3 is achieved. The electron mirror is formed here by the electrode 1, which has a steadily increasing curvature from one end to the other and therefore an ever smaller focal distance. In this figure, a collecting electrode 2 is shown schematically, in which the electron intensity runs, as shown in FIG. In FIG. 6, the electron mirror is denoted by 3, the cathode by 4 and the collecting electrode, which is here a plate-shaped anode, by 5. Behind this anode 5 there is also an electrode 6 on which the electrons impinge if they are not picked up by the electrode 5. In this tube, the control takes place by deflecting the electron beam by means of electrodes 7. Since the electron mirror 3 has a changing focal distance, there is a sharp transition from a high electron intensity to a value that is practically zero at the location of the anodes 5 and 6. When the electron beam waggles back and forth over the anodes under the influence of the voltage of the deflection plates 7, a relatively large steepness can thus occur in these electrodes. 7 shows an electrical discharge tube according to the invention, in which the electrons emitted by the cathode 8 are combined into a bundle which is directed onto a fluorescent screen 10 by an asymmetrical mirror electrode 9. Deflecting electrodes 11 are located between the cathode 8 and the mirror electrode 9, as a result of which the bundle waves back and forth over the luminescent screen 10. Since the electron mirror is constructed asymmetrically, a sharp brightness edge is created on the screen 10. In all of the figures, the electron bundle and the structure of the electrode system are only shown schematically. In reality, both the bundle and the electrodes extend over a certain width perpendicular to the plane of the drawing. P A T L- X T A N S I> I! Ci CHE: 1. Electric discharge tube with a bundled, flat electron stream that travels through the field from a cathode to one or more collecting electrodes of a converging electron mirror undergoes a change in its original direction and controlled by deflection, characterized in that the focal distance from one end of the electron mirror to the other becomes smaller or larger and that the collecting electrode or electrodes are arranged in such a way that the focal points are partly in front of, partly behind this electrode or these electrodes. 2. Electrical discharge tube according to claim i, characterized in that the Curvature of the electron mirror from one end to the other of the mirror electrode is steady increases. 3. Electrical discharge tube according to claim i, characterized in that the reflective Electrode consists of several flat parts that form a broken surface. 4. Electrical discharge tube according to claim ι or 2, characterized in that the mirror electrode consists of several curved parts and that the curvature of each Part is constant, but in a single direction for successive electrodes or increases. 5. Electrical discharge tube according to claim i, 2, 3 or 4, characterized in that that the collecting electrode is a luminescent screen. 1 sheet of drawings 1 5412 10.