DE1139212B - Direct view storage tubes for generating an image that also contains intermediate zones - Google Patents

Description

GERMAN

PATENT OFFICE

H35256VIHc / 21g

A N M E LD E T A G: DECEMBER 31, 1958

NOTICE
THE REGISTRATION
AND ISSUE OF
EDITORIAL:

NOVEMBER 8, 1962

The invention relates to a direct view storage tube for generating intermediate tones containing image, in which the writing controlled by an image signal with the aid of a control grid Electron beam a charge pattern corresponding to the transmitted image onto a storage screen writes, which is penetrated by flood electrodes that make the charge image visible on the screen.

In known tubes of this type there is the writing electron beam generating device an electron current of a few microampere strength, as long as the control grid with a voltage is operated from a few volts below a voltage causing the tube to block. at moderate scanning speed of the write beam on the storage screen, ζ. B. with radar, it only needs a relatively small change in the current strength of the electron beam to a dark one To let the point of the screen shine brightly across all intermediate tones. So if you can avoid it wants all information to be recorded very brightly with full luminosity and one instead If you want tinted brightnesses, this is the case with known devices for generating the writing electron beam necessary to apply only very small signals to their control grid. Such little signals, like they are necessary in known write beam generators, but are very difficult to keep under control, because the smallest fluctuation in the signal amplitude or the DC potential at the control grid is the Loss of nuances.

The invention thus relates to an arrangement in a direct view storage tube of the aforementioned type Art. It avoids the above-mentioned difficulties by fully preserving the writing beam modulation imposed by the control grid will decrease its density or intensity. this is achieved according to the invention in that in addition to the control electrode in the path of the write beam and outside the path of the flood electrodes, the intensity of the write beam by at least 95% reducing electrode is arranged.

Such a weakly permeable electrode captures a substantial part of the electrons of the Write beam, but the modulation of the write beam by the image signal is fully preserved remain. Only about 5% of the electrons in the beam can pass through and reach the electrode the storage screen. The percentage of electrons that pass through this intermediate electrode, depends on the ratio in which the sum of the recessed areas to the total area of the Direct view storage tube

to create one also intermediate tones

containing image

Applicant:

Hughes Aircraft Company,
Culver City, Calif. (V. St. A.)

Representative: Dipl.-Phys. R. Kohler, patent attorney,
Stuttgart, Marienstrasse 19th

Claimed priority:
V. St. v. America 2 Jan 1958 (No. 706 842)

Kenneth R. Hesse, Grenada Hills, Calif.,
and Leon Sprunger Yaggy, Los Angeles, Calif.

(V. St. Α.),
have been named as inventors

Electrode is standing. The holes in the electrode are very small compared to the cross-sectional area of the Writing electron beam. The number of holes within the area on which the electron beam hits the Intermediate electrode is so large that the electron beam behind the intermediate electrode, which passes through the electrons that have penetrated through the individual openings are formed essentially is homogeneous. If the current strength of the electron beam changes, the cross-sectional area of the electron beam changes in the plane of the weak permeable electrode. Because the individual recesses in the electrode evenly over the electrode surface are distributed, so the current emerging behind the electrode is always directly proportional to the current impinging on the intermediate electrode. The modulation of the emerging behind the intermediate electrode The write beam is therefore always directly proportional to the image signal applied to the control grid generated modulation of the writing electron beam impinging on the intermediate electrode. The described Tube can be operated without special care and without special circuits that the DC potential and the amplitude of the image

209 680/273

Keep signals at the control grid of the electron beam generating device within narrow limits.

The device described is based on the embodiment in conjunction with the drawings described:

Fig. 1 shows schematically a cross section through an embodiment of the storage picture tube;

Fig. 2 shows a cut-away diagram of the device in the tube shown in FIG

gate 34 can be generated. Under normal operating conditions, these positive pulses exhibit voltages from 5 to 10 volts.

The cylindrical part 15 of the evacuated envelope 10 5 contains a device 35 for generating the writing Electron beam and a deflection device 36, the writing electron beam on aligns the selected surface elements of the storage screen 28. The device 35 for generating the

generated electron beam used for writing; io electron beam contains a cathode 37 and a

3 to 5 show top views of various grids controlling the strength of the electron beam

Shapes of a perforated intermediate electrode in 38, pointing to rest potentials on the order of

this device shown in FIG. held at -3000 or -3025 volts to ground

The picture tube shown in Fig. 1 may be included. This can be achieved, for example

an evacuated envelope 10, which will have a cylindrical part 15 that the control grid 38 via a resistor

11 with a relatively large diameter, 39 stood with the negative pole of a variable chip

which is connected by a flat face 12 and a rear wall voltage source 40, the positive pole of which

13 is completed on the opposite side. with the cathode 37 and the negative terminal one

The rear wall 13 of the case 10 has a 3000 volt battery 41 connected to it, the positive of which is connected

pressed on section 14, the center of which is the flat 20 pole to ground. A signal generator 40

Front wall 12 is opposite. On the rear wall is the signal via a capacitor 42 on the

another tubular part 14 attached, the longitudinal control grid 38 of which generates the electron beam

axis given the longitudinal axis of the cylindrical telescope 11 in device 35.

cuts at an angle, as shown in the drawing The electron beam generating device

25 35 contains, as FIG. 2 shows, a cathode 37 which

is shown.

The pushed-out portion 14 of the evacuated envelope 10 contains an electron source 16 with a Emission cathode 18 for the flood electrodes. In operation, the flood cathode 18 of the electron source 16 is on

is heated by a filament 44. The control grid 38 consists of a metallic disc that in its center contains a circular recess which is concentric to the central axis of the emitting

a substantially fixed reference potential maintained, 30 surface of the cathode 37 is located. On the control grid, for example at ground potential. The flood electron source 38 follows, seen in the direction of the electron beam, and the source 16 conducts with the support of the electrodes 20
and 22 a stream of tide electrons uniformly

against the flat face 12 of the evacuated envelope

which are arranged concentrically around the electron beam, the diameter of the electrodes 52, 56 and 53 is about twice the size of the through a cylindrical anode 49 and a lens array 48. The anode 49 has an opening 50 at its end facing the control grid 38. the

10. The electrodes 20 and 22 are arranged on the inner surface 35 of the lens arrangement 48 on the other side of the anode of the cylindrical part 11 of the shell, which consists of cylindrical electrodes 52, 56 and 53, electrode 20 on the one adjacent to the rear wall
Part of the cylindrical inner wall, the electrode 22
on the part of the adjacent front surface 12

cylindrical inner wall. The electrode 20 extends 40 meters of the anode 49. The mutually facing away also extend over the rear wall 13 and into the ends of the electrodes 52 and 53, respectively, are cylindrical in shape Approach 15 into it, as completed in the drawing 54 and 55, respectively. The aperture 54 is shown in the left part of the evacuation also at the adjacent end of the anode 49 th shell 10 attached to an area with the same potential. In operation, the anode 49 and the right. In operation, the electrodes 20 45 electrode 52 have a potential of about 10 volts to the and 22 to about 10 and about 40 volts, respectively, across electrode 56 to about -2400 volts Ground potential held. and electrode 53 has a voltage of about 10 volts

On the inner surface of the front end wall 12 of the against ground.

Cover 10 is applied to a screen 24, which has an addition to the above-mentioned elements

contains fluorescent layer 25, which is covered with a thin 50 the electron beam generating device an NEN aluminum layer 26 is covered. Towards electrode 58, which consists of a thin metallic electron source 16 following the image plate and which has a number of holes or screen 24 the same size as the screen recesses over the surface of the screen 24 Storage screen 28 and a collective recess in the disk 54 in the path of the electrical grid 30. The storage screen 28 contains a beam of electrons. The electrode 58 may stand on derjeni- which about 1600 holes per square centimeter gen side is vapor-deposited, which contains the Flutelektronen- from troformierten metallic screen 31 on which a an electroformed metallic screen 58 α bedünne layer 32 of magnesium fluoride. Also this electrode faces from a photo source 16 and the storing etched upper disc 58 b (Fig. 4), forms a metal wire surface. In operation, the metallic 60 fabric 58c (FIG. 5) or a homogeneous layer 26 of the screen 24 consists of a voltage from the disk that for most electrons is up to about 5000 volts, the metallic layer 31 of the memory to a few, evenly Cherschirmes 28 distributed over the surface have a voltage of 5 volts and the electrons are impermeable. The permeability of the collecting grid 30 about a voltage of about electrode 58 is less than 5% and preferably 120 volts to ground. The metallic screen 31 is 65 of the order of 1%. The electrode 58 can

connected to its voltage source via a resistor and receives positive impulses through a suitable pulse generator connected to it in some plane perpendicular to the path of the electron beam be arranged in which the electron beam is not focused and its strength by the

Amplitude of the image signal is determined. The electrode 58 is thus behind the control grid 38 in the path of the Arranged electron beam. Because of its low permeability, it is expedient to use the electrode 58 not to be arranged in a position in which it can capture part of the tide electrons. As above mentioned, it is convenient and convenient to place the electrode 58 in the opening of the disc 54 through which the electron beam passes before entering the focusing field. Of course you can the beam can be bundled electrostatically or magnetically. The electrode 58 can also be in a Be arranged plane behind the electric lens before a diffraction of the beam occurs, or immediately past the plane in which such diffraction occurs.

During operation of the direct view storage tube, which also displays intermediate tones, the capacity between the metallic screen 31 and the storage surface of the storage screen 28 an initial Increase the potential on the storage surface to about 5 volts with respect to ground. The tide electrons which are emitted by the cathode 18, which is held at ground potential, start immediately, however Discharge storage surface to ground potential. With the following application of pulses to the metallic Screen 31 of the storage screen 28 increases as a function of the potential of the storage surface periodically from the amplitude of the applied pulses to + 5 to + 10 volts with respect to ground. While these periodic pulse intervals and as long as the storage surface is positive with respect to ground, the negative tide electrons hit the storing surface and strive to bring this to ground potential bring to. The storage surface therefore assumes a resting potential in the pulse pauses, the is negative to ground up to the magnitude of the pulse amplitude. With this negative resting potential Essentially all of the tide electrons are repelled and prevented from passing through the storage screen 28 step through and get to the screen 24.

When from the signal generator 43 to the control grid 38 of the device 35 for generating the Writing electron beam is given a signal and the electron beam through the deflection device 36 is guided over the storage surface synchronously with the signal, occurs near the storage surface an after-image of the cargo. In order to obtain a representation with semitones on the screen 24, the variation within the potentials forming the charge replica is reduced to 1 to 3 volts. In known devices of this type, in order to achieve such a reduction, it was necessary to block the writing electron beam almost completely, whereupon an image signal with relatively smaller Amplitude was required in order to obtain a charge afterimage with the desired variation of the potentials. In the case of the tube described here, however, the strength is practically of the entire electron beam initially determined by the tension of the grid 38 of the beam generating device 35, and a substantial part of the electron beam then passes through the perforated intermediate electrode intercepted. In this way, an image signal of a usual and easy-to-use amplitude can be obtained can be used to generate a charge simulation, in which the variation of the potentials is only 1 to 3 volts, so that you get intermediate tones in the visible representation. As a result of that the metallic screen 31 constantly receives pulses from the pulse generator, the flood electrons put in a position to extinguish the afterimage of the charge generated in this way in the course of time.

Claims (4)

PATENT CLAIMS: 1. Direct view storage tube for generating an image that also contains intermediate tones, in which the writing electron beam, controlled by an image signal with the aid of a control grid, writes a charge pattern corresponding to the transmitted image on a storage screen, which is penetrated by flood electrons, which make the charge image visible on the screen make, characterized in that an electrode reducing the intensity of the write beam by at least 95% is arranged in the path of the write beam in addition to the control electrode and outside the path of the flood electrons. 2. Storage tube according to claim 1, characterized in that the weakly permeable electrode consists of a thin metallic plate having a number of openings, wherein the area of one of the openings is small compared to the cross section of the one passing through the plate Electron beam is. 3. Storage tube according to claim 1 or 2, characterized in that the weakly permeable Electrode consists of an electroformed metallic screen with more than 1600 openings per square centimeter. 4. Storage tube according to claim 1 or 2, characterized in that the weakly permeable Electrode consists of a metal wire mesh. Documents considered: German Patent No. 740 028; U.S. Patent No. 2,644,906; British Patent Nos. 673 502, 727 739, 391, 762137. 1 sheet of drawings © 209 680/273 10.