DE918753C - Storage cathode ray scanner with a continuous photocathode layer separated from the mosaic screen - Google Patents

Description

Issued on the basis of the First Transitional Act of July 8, 1949

(WiGBl. P. 175)

FEDERAL REPUBLIC OF GERMANY

ISSUED OCTOBER 4, 1954

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ¹ GROUP 3235

E 2359 VIII aj 21a ¹

Electric & Musical Industries Limited, Hayes, Middlesex

(Great Britain) *)

Storing cathode ray scanner with one from the mosaic screen separately arranged coherent photocathode layer. Patented in the territory of the Federal Republic of Germany from May 12, 1935 Patent application published by the Reich Patent Office on January 4, 1940,

Published again by the German Patent Office on July 10, 1952

Patent issued August 26, 1954

The priority of the application in Great Britain on May 12, 1934 has been claimed

The term of protection of the patent is extended according to Law No. 8 of the Allied High Commission Beginning of the 3rd patent year on May 12, 1937, beginning of the 6th patent year on June 9, 1950

There are already storage cathode ray scanner known, one of the two-sided mosaic screen have separately arranged contiguous photocathode layer. These scanners were operated with such a suction voltage in front of the photocathode layer that the photoelectrons triggered fewer secondary electrons on the mosaic elements of the mosaic screen than

Photoelectrons hit each of the mosaic elements. During the storage period, i. H. while the time between two successive scans of each mosaic element, thus moved the potential of each element in the negative direction.

According to the invention are in a one or two-sided mosaic screen and separate from this

') The patent seeker stated that the inventors were:

Hans Gerhard Lubczynski, Hillingdon, Middlesex, and Sidney Rodda, Entield, Middlesex

(Great Britain)

arranged coherent photocathode layer accelerates the photoelectrons released from the photocathode when the image is cast in such a way that when they strike the mosaic electrode they release more secondary electrons, at least twice the number, than photoelectrons strike. Thus, the potential of each mosaic element moves in a positive direction during the storage time. This is a step forward in that ίο as one then has it in hand, namely by appropriate choice for the voltage accelerating the photoelectrons and by choosing an appropriate material for the mosaic screen surface, to generate greater elementary charges than the number of during correspond to the number of photoelectrons allotted to the individual mosaic element. This gives the possibility of obtaining image brightness signals of the same amplitude as in the known case at lower light intensities in the original image to be transmitted, or also (with the same brightness of the original image) to work with light-optical lenses with a lower relative aperture for image projection. ^a 5 Regardless of the size of the image signal generated, the object of the invention is also characterized by a particularly low susceptibility to interference of the image converter part, because the higher electron speed stiffening and thus less influencing of the electron trajectories by external interference fields.

There is also known a secondary emission photocell composed of two opposed to each other Cathodes, between which there is a network anode. The mode of action This photocell is based on a multiple wandering back and forth of photoelectrons or secondary electrons. However, it cannot be taken as obvious in the case of a cathode ray scanner of the type mentioned at the beginning, in which not two cathodes, but only one only cathode is present, and in which also not the entire photocathode area is equally brightly illuminated, but in which a detailed light image is designed on the photocathode becomes, through the use of a single secondary electron release process, that on the To reinforce the resulting charge image. It should also be noted that this Obtaining a more intensive charge image is practically possible without any effort, since namely, the voltage with which the photoelectrons are accelerated is just something has to be measured differently than it is without achieving a single-stage increase in secondary emissions was the case. It can therefore very well still be described as an inventive step that the Secondary emission amplification process that only applies to two opposing cathodes a so-called macroscopic photocell is known, initially on the image converter part of a storing cathode ray scanner applies, so that the whole remote photoelectron image to be transmitted experiences a reinforcement. In fact, a highly surprising effect is also achieved, because only through a somewhat different dimensioning the voltage accelerating the photoelectrons has a stronger charge pattern the mosaic screen can be achieved than was previously the case. It is about that too For this reason alone, it is not an obvious one compared to the known secondary emission photo cell Measure because there were two cathodes with a grid anode in between.

It should be noted that a one-sided mosaic screen in the arrangement according to the invention also made of a sheet-like material of high resistance in the transverse direction, z. B. may consist of a mica sheet, on which facing away from the photocathode Side is the metal layer connected to the acceptance resistance for the image signals (so-called. Signal plate).

Claims (1)

PATENT CLAIM: A storing cathode ray scanner in which on one of a contiguous Photocathode spatially separated one or two-sided mosaic screen creates a charge image, characterized in that that the photoelectrons released when the image is thrown from the photocathode are accelerated in such a way that they do so when they strike trigger more secondary electrons, at least twice the number, on the mosaic electrode, hit as photoelectrons. Referred publications: French Patent No. 715,912; British Patent No. 369,832; Zeitschrift für Physik, Vol. 80, 1933, pp. 305 ff. (Article by Ka 1 ckhο f f); Journal "Hochfrequenztechnik und Elektroakustik", Vol. 41, 1933, pp. 195 ff .; Annals of Physics, 5th episode, vol. 12, 1932, Pp. 607 to 661, pp. 635 to 639; Fractions »Electron microscopic image with photoelectric electrons« (from the Research Institute of the AEG, pp. 448 to 450). 1 9552 9.54