DE1043538B - Electron discharge tubes with cathode and fluorescent screen - Google Patents

Description

GERMAN

The invention relates to an improved form of cathode and luminescent screen Electron discharge tube for disassembling, composing or converting images for Television or similar purposes. According to the invention, a homogeneous one coming from the cathode runs Electron beams through a mosaic electrode, which is designed so that they carry electrical charges that can correspond to the brightness values of an image to be imaged, so that the charge image the mosaic electrode controls the local density of the electron stream passing through it, which creates the image generated by the fluorescent screen.

An electron source for generating an electron beam that is homogeneous in density and speed can be placed on one side of the lattice so that an electron distribution on the other side which varies from point to point according to the potentials of the grid. Everyone As a result, the point of the grid works similarly to the grid of a normal electron tube. Hereinafter this grid should always be referred to as the "storage grid".

Since it is generally required that the electron beam thus generated is directed towards some surface focus, the nature of which depends on the intended use, the electron velocities must im Area of the storage grid must be low. If this is not the case, the electron velocities show there are considerable differences from point to point, which depend on the potentials that prevail there and result in a distortion or blurring of the image. Furthermore, the highest potential must be on each point of the storage grid must be lower than the cathode potential, otherwise the electrons will go to this Flow point and immediately equalize the charge accumulated there.

It is therefore necessary to bias the storage grid negatively towards the cathode, a fact which causes difficulties insofar as a grid, which consists of sufficiently fine fabric, in order to enable a large image resolution, the passage of the electrons can be very difficult.

According to a further embodiment of the subject matter of the invention, a uniformly positively biased auxiliary grid is therefore provided, which guides the electrons, so to speak, through the storage grid. This auxiliary grid is preferably arranged parallel to and in the vicinity of the storage grid and can be located in front of or behind it. Such an auxiliary grid can also be arranged on both sides of the storage grid. The arrangement of the two grids can be made so that a plurality of small electron lenses is formed, so that the electro-electron discharge tube
with cathode and luminescent screen

Applicant:

TV G. mb H.,
Darmstadt, Am Alten Bahnhof 6

Claimed priority:
Great Britain May 11, 1936 and May 4, 1937

Victor Angel Jones and Peter William Willans,

London,
have been named as inventors

concentrated on the gaps between one or the other of the two grids. However, it can a strong (magnetic) guiding field can also be used. In this case it is possible to do that To keep the storage grid at cathode potential or even slightly higher potential.

The storage grid can be produced by any of the known methods for producing mosaic electrodes, wherein the mosaic surface can be photoelectrically sensitive or also insensitive, depending on the way in which the tube is to work. The word "photoelectric" is to be understood in its most general sense. Grids in which the conductivity changes during exposure or in which an electromotive force then arises should also fall under this. The storage grid can be applied to the surface of the mentioned auxiliary grid if a very small distance is required between the stored charges and the auxiliary grid. The charges can be generated on the storage grid in that an optical or an electron image is thrown onto it or by a modulated cathode ray being swept over it.

In the first of these three cases the mosaic must be photoelectric, which is not the case in the other two cases is required. In the second case, the electron image must be obtained with the help of another source, e.g. B. a separate Photocathode onto which an optical image is thrown can be generated, and according to the invention provides means through which an electron beam corresponding to an image in a second is converted with greater intensity. In the third

W9 674/319

Case can be the cathode ray scanning the storage grid be modulated with received television or other characters, and reproduce the image Electron strands are directed onto a fluorescent screen. So it will be the characters received converted into a visible image in a more advantageous way, with a higher brightness, a lower one Flicker (because the charges are retained on the storage grid) and less distortion and blurring due to space charge effects (since the electron flow over the entire image field distributed and not concentrated in one point) are available.

Means are expediently provided in order to discharge the elements of the storage grid again, so that the potentials of the individual points always have the right value. In some cases the mosaic elements be placed on a conductor that is connected to a suitable voltage source, and the insulation resistance of the elements is chosen so that some leakage takes place. In other In some cases, it may be desirable to provide an auxiliary electron source within the tube, which on there is such a potential that electrons can pass from it to the storage device during operation. That The degree of discharge of the grid elements can be adapted to different operating conditions, and at Using a second electron source, the discharge can be carried out continuously or intermittently will.

Between the mosaic elements and the carrier grid can with a storage grid on the one optical or an electron image is directed, e.g. B. be a constant resistance, the Grid is connected to a bias voltage that just extinguishes the image when the grid is unlit is. When an optical image is projected onto the photoelectric grid in this case, electrons become emits according to the local lighting, so that a state of equilibrium is established, the is caused by the charge due to the emission of electrons and the discharge due to the discharge. The potentials of the elements then correspond to the local lighting.

In another embodiment with a storage grid on which an optical or electrical Image is thrown, an auxiliary cathode can be provided to neutralize the charges, which in is effective for a short time at certain intervals and completely removes the charges. The elements of the Storage grids can then be arranged completely isolated.

In a third embodiment, in which the storage grid is swept over by a cathode ray for image composition, the operating conditions are selected so that the storage grid is positively charged by the scanning beam (by secondary emission), and an auxiliary cathode is provided, the emission of which is continuous and straight sufficient to discharge the grating elements during one image period. Conversely, the storage grid can be charged directly by the primary electrons and discharged again by secondary emission. In this case, of course, a negative image signal must be used. Another possibility is that the mosaic elements, as already described above, have a constant resistance to the negatively biased carrier, the time constant of the discharge being chosen so that the charges are held for a sufficiently long time, but still the movements of the the transferred object. In this case, the storage grid can also be discharged by an intermittently acting cathode.
The invention is explained in more detail with reference to the drawing, in which FIGS. 1 to 3 show some exemplary embodiments. Corresponding parts are always provided with the same reference symbols. In Fig. 1 with the help of a lens 2 is an optical

ίο Image of the object 1 on a photoelectric grid 3 thrown. The grid 3 consists of photosensitive elements on an insulating or semiconducting coating are arranged over a metal grid. The grid 3 so stores electrical Charges, so that each point assumes a potential value against the metal substrate that corresponds to Corresponds to the brightness value of the object 1.

A cathode4 sends out a substantially uniform stream of electrons, part of which passes through the grid 3 passes through, the current passing through each opening of the grid being deprived of the potential of the element located there. The electron distribution emerging from the grid 3 gives that Image again and is directed onto a fluorescent screen 5 to produce a visible image. A normal metal grid 6 is arranged parallel to and close behind the mosaic grid 3 and against this positively biased. The grid 6 can also be arranged in front of the mosaic or on both sides of the storage grid be.

For the sake of simplicity of illustration, the means for acceleration and electron-optical Figure (which can consist of electric or magnetic fields) between the grid 3 and the screen 5 and between the cathode 4 and the grid 3 are omitted.

FIG. 2 shows a modification of the tube according to FIG. 1. In this case, the grating 3 is not through Photoelectrons, but rather charged by electron impact, triggered either by secondary electrons • or directly by the primary electrons. In one case there are positive, in the other negative Pictograms required. An image of the object 1 is projected onto a photocathode 7, and the photoelectrons generated there are accelerated and concentrated on the grid 3, so that they are there Trigger secondary electrons and generate the required charge image.

Fig. 3: shows a television receiving tube. Its mode of operation is the same as that of the tube Fig. 2, but the charging of the grid3 by a sharply focused cathode ray emanating from the beam generating system 8 is effected. The beam is modulated with image signals and is guided back and forth across the grating 3 in a known manner. Instead of television characters, other characters can of course also be registered with the tube. As before, the grid 6 can be in front of or behind the storage grid and the cathode 8 can be on the Grid 6 facing away from the storage grid 3 can be arranged. Another possibility is to to arrange an auxiliary grid in front of and behind the storage grid 3. In this case the beam must be the grating 3 through the spaces in the grid 6. This embodiment can also go there be modified that instead of an immediate scanning of the storage electrode an auxiliary electrode is swept over by the beam, so that the electrons emanating from this auxiliary electrode onto the storage electrode 3 be accelerated and focused.

In all cases, the cathode 4 can be, for example, an indirectly heated flat electrode which is sufficient Glow electrons are generated, or a uniformly illuminated photocathode is used.

Numerous modifications of the arrangements described above are of course possible. The fluorescent screen 5 can, for. B. by a mosaic electrode, as used in scanning tubes with charge storage is used, or by a scanning aperture (scanning tube according to D i e c k m a η η - H e 11 ίο and Farnsworth). In the latter case, the electron beam emanating from the grid 3 becomes articulated back and forth over this scanning opening.

The grids mentioned, in particular the mosaic grid 3 and the grid 6, can somehow be electron-permeable be trained. You can e.g. B. consist of a series of parallel wires, wherein the wires of the grid 3 can be at right angles to those of the grid 6. The spaces in between can are appropriately chosen different, so that the mosaic grid 3 has a stronger influence on the of the cathode 4 exerts coming electron stream. Another embodiment z. B. that shown in FIG Tube is that the beam generating system 8 is arranged so that the scanning beam hits the grid 3 approximately perpendicularly. The beam can then z. B. through an opening in the cathode 4 enter.

Claims (11)

Patent claims: 1. Electron discharge tube with cathode and fluorescent screen, characterized by an between Cathode and luminescent screen arranged mosaic electrode, which the local density of a through controls the homogeneous electron stream entering the mosaic electrode by applying electrical, charges corresponding to the brightness values of an image are applied. 2. Tube according to claim 1, characterized by one or more closely parallel to the mosaic electrode arranged auxiliary grid. 3. Tube according to claim 1, characterized in that the mosaic electrode is charged by photoemission. 4. Tube according to claim 1, characterized in that the mosaic electrode by electron impact being charged. 5. Tube according to claim 4, characterized in that the mosaic electrode of one of them sweeping cathode ray is charged. 6. Tube according to claim 4, characterized in that the mosaic electrode by an electron image being charged. 7. Tube according to claim 1, characterized in that the mosaic electrode discharges periodically will. 8. Tube according to one of the preceding claims, characterized in that the through Electrons entering the mosaic electrode emanate from a uniformly illuminated photocathode. 9. Tube according to claim 1, characterized in that the electrons from a hot cathode go out. 10. Tube according to claim 2, characterized in that the or each auxiliary grid is on a uniform potential lying above the potential of the mosaic electrode. 11. Tube according to claim 1, characterized in that the mosaic electrode against the Cathode is negatively biased. 1 sheet of drawings © «09 674/319 11.58