DE756356A - - Google Patents

Description

PA.Pk/R/Ei February 25, 1939.

Re: F 80 609 VIIIa / 21a1 _f 32/50

Einrichtunj ^ to control the

especially for purposes of image transfer or

S '

deii * "television» V "

äK Jr

The invention provides a device for controlling the passage of light, in particular for purposes of television or image transmission. The size of the cathode ray tubes with fluorescent screen used for television purposes, for example, are determined by the size of the image. Since the picture size increases with the development of the television aids, and a complete illusion of fidelity as in film is only possible if the picture size approximates that of the projected pictures, a development in this direction is natural. Thus the size of the cathode ray tube (must fern. Increase luminescent screen according to what would be apart from the technical difficulties uneconomical. Further, the brightness of the TV picture would experience a significant increase if it is to meet the practical requirements, but to no further increase in the Amplifier equipment may be necessary.

The invention aims to meet these requirements in a satisfactory manner. It consists in the fact that instead of the Today, the fluorescent layer used on the bottom of the cathode ray tube is a relaisarx-like arrangement of floating particles is set, which is between two translucent stands

"and exceed their pore size. The light permeability of this arrangement is variable at the points hit by the cathode ray due to the rearrangement of the particles depending on the intensity of the ray.

The cathode ray does not make one layer glow, but controls the flow of light from one of the layers any light source coming light beam, so that images are obtained despite a very small cathode ray tube can, whose size is no longer through the cathode ray tube ,, - but is conditioned by the number of image points ^ - and its brightness no longer depends on the amplifier output, but on the luminous intensity of a light source, which makes the possibility a reduction in amplifier power is given. Also with the advantageous use of the below to be descriptive Cathode ray tube as oscilloscope or electron microscope is to be expected.

The relay effect of the cathode ray is achieved in principle by the following arrangement: instead of the one mentioned above Fluorescent layer enters a space filled with floating small particles at the bottom of the cathode ray tube. These particles fill the room so tightly that the entire bottom surface of the cathode ray tube is opaque. Now hits the Cathode ray hits these particles at one point, so they are due to its kinetic as well as electrical effect removed from its orbit and the more thoroughly the larger it is this effect, i.e. the greater the anode voltage applied to the tube. The light transmission is thereby at this Restored more or less as long as the

Cathode ray exerts its effect. If the bottom surface of the cathode ray tube is now illuminated, for example, from the inside, then light is only emitted at those points through the small particles formed by the floating particles. Pass through the layer which the cathode ray strikes. If the bottom surface of the tube is designed as a ground glass, the image will appear on it. By using a glass plate or a lens as a bottom disk and a common optic, the projection of the television picture can easily be done on a large area with appropriate brightness

A cathode ray tube according to the invention can also be used to advantage in the transmitter, if it is the scanning of a film frame or any other object. The cathode ray is not modulated so that the The brightness of the light beam is constant and a light-sensitive cable can be scanned and controlled. This application of the new cathode ray tube combines the advantage of the Hipkow disk (emission of a wandering light beam) with those of the cathode ray tube.

The figure shows a schematic drawing of the subject matter of the invention: the glass plate 1 forms the bottom of the Cathode ray tube. 4 represents a thin, porous, translucent membrane. The space between 1 and 4 is filled with kl once; en particles 2 that pass through the pores of 4, which are of a smaller order of magnitude, cannot step out. The one coming from 8 and between the baffles 6 passing electron beam 9 can easily penetrate the pores of the membrane and has the effect described above

the floating, small particles 2 between 1 and 4 from »

These particles receive a positive electrical charge through the ring-shaped anode 3 · This becomes Firstly, a mutual repulsion of the particles is achieved, whereby they are kept in motion and so that of the cathode ray quickly close any gaps caused. Second, a sharp demarcation of the Eathode Ray edge and thus of the image point is obtained by an accumulation of particles at the edge of the Eathode ray results. By optics 7 this is of a Light source 5 projected light coming onto the membrane 4. The light beam 10 occurs at the point where the cathode ray 9 hits, from the tube to a screen, projection screen ο & θ *. derglee to hit.

The spatial position of the cathode ray tube according to the invention advantageously takes place in such a way that the bottom surface 1 lies horizontally, whereby a special precaution to keep the particles 2 floating is not necessary inclined mirror, the projection can be done on a vertical surface.

Claims (1)

EFS Pk / w 10/27/1942- F 80 "" 6c9 "~ Vina / 21a1 - g.B. 11/41 Today's claims 1.) Device for controlling the light passage through a Provided inside a cathode ray tube screen, screen or the like., whose Lxchtransparigkeit locally depending on the The intensity of the incident cathode ray is variable, in particular for the purposes of image transmission or television by one enclosed between two translucent boundary walls with floating particles of the pore size The tree filled with the larger size than the walls, the one next to the cathode ray hit points by relocating the particles to a greater or lesser extent depending on the intensity of the beam becomes translucent. 2.) - Device according to claim 1, characterized in that the boundary wall facing the cathode ray is made of an electron-permeable one Membrane, which consists of a glass plate or a lens facing away from the beam « To distinguish the subject of the application from the state of the art are in the grant procedure following publications *) hninii ΤΊιιιιΙιιιΙιιίΠίΐι *) been considered. ? 63 ' ^J *) Delete what does not apply Claims. Λ \ T-, through a screen provided inside a cathode tube, Aperture o4e * d © # gl., Whose light transmission iKFtlieh in Depending on the intensity of the incident cathode ray is variable, in particular for the purposes of image transmission or of television, marked Jlurch between two translucent Particle ^ ons floating on the boundary walls The pore size of these walls is about the same as their light permeability at the points hit by the kajl mode beam depending on the front intensity of the beam Rearrangement of the article is changeable. 2jijr device according to claim 1, characterized gekennzeichneiifaaß the boundary wall facing the cathode ray & VLSjan.neT light- and electron-permeable membrane, which the o oi 3> ^ f device according to claim 2, characterized in that the glass plate is designed as a ground glass. 4-. f " Device according to one or more of the preceding claims, characterized in that the space at the bottom of the tube and filled with small particles is surrounded by an annular anode. 5. ^ "Establishment according to one or more of the preceding Addresses, characterized by such an arrangement, that the bottom surface of the cathode ray tube is horizontal.