DE910904C - Saving image decomposition tube - Google Patents

Description

l. P. 17S)

ISSUED MAY 6, 1954

F4613 Villa / 21a ¹

(Ges. V. July 15, 51)

With the usual image splitting tubes with one-sided mosaic electrode, the mosaic elements returned by the scanning beam to an equilibrium potential that corresponds to the The potential of the suction electrode for the triggered secondary electrons is almost the same. It is Occasionally the suggestion has been made to achieve greater suction field strengths between the Apply a voltage to the signal plate and the suction electrode. However, this suggestion is based on a mistake, since a voltage difference is maintained between these electrodes can be, but is ineffective for the mosaic elements, since the equilibrium potential of the Elements is still conditioned by the suction potential, regardless of which potential owns the signal plate. When applying a high voltage between the signal plate and the suction electrode In the first moment there is also between the elements and the suction electrode »° a strong field present. However, after the beam sweeps over the screen once all elements practically assumed suction electrode potential, so that the total voltage difference between the signal plate and the mosaic elements, the rest of the space on the other hand becomes almost field-free. This state does not bring any advantages for the company, but at most those Risk of flashovers through the dielectric.

Since a significant potential is not maintained between the elements and the suction electrode can be, the potential differences between the elements play a different

Relatively large role, so that a considerable part of the secondary electrons released by the beam falls back on the mosaic elements and gives rise to the known interference pulse. It can easily be overlooked that due to the photo-charging and the potential differences arising in the plane of the mosaic electrode as a result of the successive scanning of the mosaic surface, field strengths occur that are of the same order of magnitude or even considerably greater than the field to the suction electrode. As a result, the probability that an electron in the vicinity of the original location will fall back onto the mosaic surface is very high. It is known to provide a shield between every two adjacent mosaic elements, which is intended to prevent the transfer of electrons between them. The previous arrangements of this type caused considerable difficulties in the manufacture of the mosaic electrode or in the operation of the tube. A known method of this type can only be carried out using a light beam for scanning, for example. In addition, it should be borne in mind that an extensive ^a 5 mutual shielding of the elements alone does not guarantee that no electrons will actually pass between different elements. A direct transition on a straight path is then impossible, but falling back on a curved path is not. The invention provides an arrangement which, with a much simpler structure, makes an electron transfer between the elements completely impossible and in which the normal operating method can be maintained unchanged with voltages remaining constant. It makes it possible not only to shield the mosaic elements from one another, but also to maintain a tensile field of any strength in principle in the space in front of the mosaic electrode, which immediately sucks off all electrons entering this space. According to the invention, the signal plate is designed as a perforated metallic electrode exposed on the side swept by the cathode beam, while the mosaic elements are arranged in a plane behind the signal plate in the direction of the beam.

Fig. Ι shows as an embodiment part of the mosaic electrode according to the invention in section. An insulating plate 1 is provided with z. B. cylindrical recesses 2 provided. The webs 3 remaining between these form a coherent one reticulated surface. On this coherent surface is a sign that serves as a sign metallic layer 4 arranged, while the mosaic elements 5 the flat bottom of the wells cover. The manufacture of such an electrode can e.g. B. by vapor deposition of metal done in a single operation so that the metal is on both the bottom of the wells as well as on the contiguous surface. Any leading bridges on the side walls can be eliminated by subsequent heating. The mosaic elements must then be trained for high photosensitivity.

If you take silver for the vapor deposition of the metal layers, so it will be in the formation of the Under certain circumstances, mosaic elements cannot avoid that the signal electrode also has a high Photosensitivity assumes what an additional photocurrent and a increased shot level due. To avoid this, it can be useful to start with a Metal that is difficult to oxidize, e.g. nickel, molybdenum or platinum, is vapor-deposited onto the insulating plate 1. As in the case described above, the vapor deposition is expediently carried out from a small-area or punctiform evaporation source the end. A second vapor deposition is then carried out, this time with a light one oxidizable metal, especially silver, but in front of the insulating plate a mesh or a Another template is arranged in which the position of the holes with that of the wells 2 everywhere matches. When using a small-area evaporation source then arise sharp shadows through the net wires, so that no silver gets onto the signal electrode 4, but rather only through the openings onto the mosaic elements 5. Instead of a network, a z. B. with a jet blower perforated mica foil serve as a template for the evaporation. When operating the tube is between the signal plate and the suction electrode for the Secondary electrons formed in the usual way as a wall covering and connected to the anode of the Beam generating system can be conductively connected, a voltage applied so that the suction electrode for example 50 volts more positive than the signal plate. The ones taking place on the mosaic elements Processes are to be described below with reference to FIG. 2, which shows the potential distribution in the area of a single element. In the unexposed state this will be Potential of the elements initially coincide with that of the signal plate, so that the tensile field the suction electrode engages in the openings and extends up to the entire surface of the element. So the suction conditions are also more favorable for the photoelectrons than with a normal one Storage tube. If you now throw the picture onto the mosaic electrode, photoelectrons are released, which go over to the suction electrode, so that the element slowly becomes more positive. The potential distribution is then about as in Fig. 2 b, Since the element is positive against the signal plate, A potential surface running in the space between the signal plate and the suction electrode engages the opening and insert here at the upper "° surface of the mosaic element. If the element becomes more positive, the state of Fig. 2 c, in which an even more positive potential surface attaches to the element, but only at a point in the middle of the element. There is already one from this figure

The constriction of the potential surfaces can be seen approximately in the plane of the signal plate. In In this state there is only a tension field in the middle of the element. Will the element now if it is more positive, a potential saddle appears, as indicated in FIG. 2d. The signal plate is now so strongly negative against the element that a potential barrier is created approximately in its level, which the photoelectrons can no longer overcome.

From this illustration it can be seen that, in the present arrangement, the potential of the mosaic element do not approach the potential of the suction electrode as you would with normal tubes can, but that even before this state is reached, the flow of electrons is constricted occurs, which makes a further shift in potential to the positive impossible. The suction electrode not only remains against the Signaiao panel, but also against the mosaic elements always positive. The operating conditions must be chosen so that overdriving is avoided will, d. H. that with the greatest brightnesses occurring, the potential distribution of FIG. 2 c is about to be reached. The conditions can be compared with the beam generation system of a Braunsche Tube can be compared, the mosaic element being the cathode, the signal plate being the Wehnelt cylinder and the suction electrode correspond to the anode, but with the difference that no longer that Potential of the Wehnelt cylinder (signal plate), but that of the cathode (mosaic element) is variable is.

It is a structurally similar arrangement from the early days of television development known, in which in the beam direction behind a grid electrode, namely in its openings, the Mosaic elements are located. However, this arrangement works with a light beam for scanning. Because now the electrons released by this light beam have the same properties as those when the image is thrown generated photoelectrons, this arrangement is only functional when storing and the sampling can be carried out separately from one another in time and also a special one The elements are returned to the initial potential. Since the Scanning light beam triggered photoelectrons in the state of FIG. 2 d do not find a tensile field would, a different potential must be applied to the upstream of the mosaic elements during the scanning Lattice to be laid. However, this mode of operation, which is necessary in the known method, is necessary a considerable technical effort and is moreover with a loss of memory effect and associated with the further disadvantage that the transmission is not continuous, but only intermittent can take place.

The invention is based on the knowledge that such an arrangement in a tube with Cathode ray scanning without electrical voltage switching and while maintaining the during Today's practical television normal conditions are operational and very essential Benefits leads. In particular, the adhering to the known tubes with cathode ray scanning, in contrast, this does not play a role in the arrangement which works with light beam scanning Interference pulses can be completely suppressed in this way. The fact is used for this purpose, that, as described, there is a braking field in front of the mosaic element with high photo charges adjusts so that the secondary electrons released by the scanning beam fall back onto the element have to. It is theoretically conceivable that the secondary electrons by virtue of their higher ones Exit speed overcome the potential saddle of FIG. 2 d; but this is opposed by the fact that the cross-section of the incident beam represents a space charge, which in any case is a repulsive one Has an effect on the electrons emerging from the element. The emergence of a strong In the present case, space charge is also favored by the lateral closure of the mosaic element. In addition, with the arrangement according to the invention, far higher beam currents than is usual can safely be used so that the state of equilibrium after the scan can always be set lower than the one that the elements aspire to in exposure. By appropriately dimensioning the jet stream can therefore be achieved that the element after the sweep about the potential of the signal plate possesses, so that the state of FIG. 2 a is established again. There can also be such a thing from the start Ratios are chosen so that the beam generates only a few secondary electrons and on the Way makes the item more negative.

If the beam hits a strongly positive element, all beam electrons are first removed from the mosaic element absorbed, and only after partial compensation of the photo-charge does the beam become one Identify excess electricity that has to be removed from the element. While Now with normal tubes this excess is due to a considerable extent to other mosaic elements falls back and causes the known glitch, the inventive arrangement is hereof completely free. This results from the fact that all electrons released on the mosaic screen be held back, since they do not emerge from the recess at all, the level of the signal plate so cannot enforce or, if they enforce this level, under all circumstances in a Get a pulling field that immediately leads you away in the direction of the suction electrode. So it is too indirectly not possible that any electron, starting from a mosaic element, on another falls behind. This is why large jet currents, which, from the standpoint of the iao Considered the charge balance, appear much too high, are harmless in the present case.

Claims (7)

Patent claims: i. Device for image decomposition with one-sided mosaic electrode and cathode ray scanning, characterized in that the signal plate as an openwork, on the from Exposed metallic electrode is formed while the beam swept side Mosaic elements arranged in a plane lying behind the signal plate in the direction of the beam are. 2. Device according to claim i, characterized in that that the mosaic plate consists of a recessed, serving as a dielectric insulating layer, in which the Mosaic elements are located on the bottom of the wells while the signal plate by a metal layer on the interconnected webs between the depressions is formed. 3. Device according to claim 1, characterized in that that the photoelectric sensitivity of the signal plate surface is much lower than that of the mosaic elements. 4. Device according to claim i, characterized in that that the signal electrode consists of a metal that is difficult to oxidize. 5. Device according to claim i, characterized in that that between the signal plate and the suction electrode for the secondary electrons a tensile stress of the order of 10 to 100 volts. 6. Device according to claim 5, characterized in that that on the side of the tube there are constant potentials. 7. Device according to claim 5, characterized in that the jet flow is substantial is stronger than for discharging an element charged to the maximum photovoltage would be required. 1 sheet of drawings © 9517 4.54