DE1157713B - Cathode ray storage tubes - Google Patents

Description

The invention relates to a cathode ray storage tube with a write beam, a Flood electron flow, a storage electrode, a screen and with one the flood electron flow comprehensive electron-impermeable ring.

In the case of electronic storage tubes that do not produce a visible image, the flow of electrons is used comprehensive ring as a carrier of a mesh grid, which is arranged close to a grid, behind which in turn the storage disk follows. The inside diameter of this carrier ring is something larger than the inner diameter of the rim of the storage plate, so that the effective flow cross-section of the tide electrons is not determined by this ring.

Direct view display tubes generally use a relatively high electron current Speed with which the storage electrode is swept in accordance with the information signals and thus generates a charge distribution on the storage screen that is to be stored and corresponds to the information to be displayed. The storage screen is flooded by a flood electron stream, which pass through the screen according to the potentials of its individual surface elements, which contain the stored charge distribution and are then accelerated so that they are on hit the screen and create a visible replica of the stored charge distribution there. The operation of such a cathode ray storage tube is known. When flooding the Storage screen by the tide electrons (sometimes also "image" electrons or "sight" electrons called) these should be distributed as evenly as possible over the storage surface. Besides, everyone should Flood electrons should have the same speed as possible, and ultimately the flood electrons should strike the storage surface essentially perpendicularly, otherwise changes in the intensity and the accuracy of the reproduction occur. In order to meet these conditions, such A known system of electrical converging lenses is provided to protect the flood electrons from the tubes to impose the above conditions.

In the operation of the direct view storage tubes mentioned above, the visible image is at its edge often surrounded by a bright ring of light. This illumination of the edge apparently comes in part from Flood electrons from the walls of the lens system contained in the tube and the walls the collecting electrode are reflected. It can also be assumed that this edge lighting Cathode ray storage tube

Applicant:

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

Representative: DipL-Phys. R. Kohler, patent attorney,
Stuttgart S, Hohentwielstr. 28

Claimed priority:
V. St. v. America October 1, 1958 (No. 764 539)

Kenneth R. Hesse, Grenada Hills, Calif. (V. St. Α.), Has been named as the inventor

is caused in part by non-reflected flood electrons that deviated from their orbits are, perhaps because they run on the edge of the current bundled by the converging lenses.

This edge lighting appears, for example, in the case of a storage tube with a diameter of 12.7 cm Ring 0.8 mm wide. Often, however, the width of the ring is not the same over its entire circumference, like this that the image does not seem to be in the center in an undesirable way. You are also observed Radiant wreath about 1 cm wide, created by the inner reflection of the light from the ring in the glass parts the tube arises. This halo reduces the contrast at the edges of the picture.

These disadvantages are avoided if, according to the invention, the electron-impermeable ring as a catching the edge zone of the flood electron flow Aperture is formed.

This masking of the edge zone of the flood electron flow is achieved with the known carrier rings not achieved for a grid arranged in front of the storage electrode.

The device described is explained with reference to the drawings.

1 shows schematically a section through a cathode ray storage tube with a diaphragm ring;

Figs. 2, 3 and 4 each show a section through part of a tube with the one described Aperture ring;

Fig. 5 shows a section through an aperture ring and the mesh of the collector.

309 749/314

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The direct view storage tube shown in Fig. 1 shows information to be stored and imaged an evacuated envelope 2 that adjusts one. As is well known, the writing beam leaves behind Larger cylindrical part or piston 4 and one while it is in the grid over the storage screen 26 Flask neck 6 has. In the flask neck 6 is guided, on this a charge distribution that the cathode 8 of the write beam and the area 5 of the information to be stored and mapped acceleration device 10 for generating a corresponds. The storage screen 26 becomes normal electron beam with a small cross-section on a negative surface with respect to the flood cathode 32. Around the flask neck 6 there is a tive potential. The one from the writing beam known electromagnetic deflection coil 11 hit relatively high speed to deflect the write beam in horizontal io surfaces of the storage screen 26 are therefore and vertical direction. The electron beam positive towards the flood cathode 32 by the Wirgenerating system 10 includes a cathode 8, an effect of secondary electron emission. These Sekun control grids 12 (that the strength of the beam corre- sponding electrons are generated by the collector electrode accordingly the information 24 applied to this grid is bundled. To the stored information visual signals modulated) to make acceleration electrodes 14 15 bar, the flood electrode 20 becomes a and 16 and a focusing electrode 18. In the flow of electrons is relatively lower Piston 4 houses an electron source 20 for velocity and generated by the collecting electrode Flood electrons, a collecting electrode 22, a trode 22 bundled, as is known per se. the Collector electrode 24, a storage screen 26 and a flood electrons are uniform over the whole Screen 28. Screen 28 contains a flat 20 memory surface spread out and step through those Tending layer 30 of, for example, tin oxide, the points of the screen through which are positively charged is covered with the luminescent layer 32. They are through, and hit the screen 28, where they The visible conductive layer 30 serves as an acceleration luminescence at these points on the screen Electrode for the tide electrons that trigger the storage. Those flood electrons that point to negative screen 26, as further below 25 hit charged parts of the storage screen, can still is described in more detail. The "flood" cathode 20 cannot pass through the screen. To this contains a cathode 32 which, of a strength way, can power modulating a variety of information Grid 34 and a ring electrode 36 chert and shown.

is surrounded, which serves as an accelerating electrode. The dashed lines 50 in FIG. 1 represent the

The "flood" cathode 20 generates a broad electron 30 flood electrons, the electrons from the flood cathode 20, which are generated against the storage screen 26. These electrons are made by the is directed. In operating the tube, it is desirable to have collector electrode 22 bundled and substantially hit the "flood" electrons are bundled in such a way that they lend perpendicularly to this storage screen. It approximately perpendicular to the storage screen 26, it is assumed that some of these flood electrons, hit. The bundling of the tide electrons is particularly effective in the peripheral areas of the tide A collecting lens system between the cylindrical flow, the edge part of the storage screen 26 Drischen electrode 22 and the collector electrode 24 can penetrate and reach the screen. In connection with the electrode 22 can hit and there the aforementioned bright ring of light also more than one cylindrical electrode can be provided around the image area. This can be which can then be explained by conductive graphite layers at 4 ° by that the electrons are in the the inside of the piston 4 can be formed. Edge areas of the flood stream on disturbed railways

The storage screen 26 includes an annular move because of the walls of the collecting support member 38, on which an electroformed nickel electrode or the collecting electrodes or the wall screen 40 is welded on. The nickel screen can reflect that of the collector electrode. One for example a thickness of 0.04 mm and about 45 such effect of these electrons is through a Have 60 meshes per square centimeter. The annular diaphragm 52 prevents the material of which the electrolyte Surface is thin, not tronen and cannot penetrate the inside Drawn layer of a secondary electron is attached to the support ring 42. This achieves emitting material formed on the that the electrons on the edge before the The side of the screen facing the write cathode is reached on the storage screen and the screen is worn. The secondary electron emitting will be intercepted. The inside diameter of the ring material can be magnesium fluoride, for example, orifice 52 can be slightly larger than the smallest vaporized or otherwise bare image surface of the screen. When down for example and that is, for example, a thickness of a 12 cm tube with an image diameter of can be from 20,000 to 50,000 angstroms. 55 10 cm, a diaphragm would be required

The collector electrode 24 is more expedient and has a diameter of approximately 10.03 cm. It wise an annular support member 42 having a is generally appropriate to the cathodes electroformed nickel screen 44, the side of the screen facing away from this, i.e. the "lower side" Support member is stretched and is welded to him. bevel so that a cutting edge In the embodiment shown in Fig. 1, 60 electron flow is limited. In addition, the Spandieser can Collector screen 44 to be set on one of the support ring voltage of the bundle electrodes so that the 42 welded narrower ring 46 attached. The cross-sectional area of the tide electron current hardly Collector screen 44 may have a thickness of about 0.001 greater than the aperture diameter of the aperture. up to 0.003 mm and about 60 openings per square- In Fig. 2, another embodiment is shown-

have centimeters. 65 put. In this case, it is impervious to the electrons

During operation, the diaphragm ring 52 on the support ring 42 is permeable through the writing cathode 10 an electron current is generated and its density in the collector electrode above the collector grid to match modulated with the signals that one welded, so that there is no special

wrapping ring for this grid needs. In this embodiment, the diaphragm ring 52 thus fulfills two Functions, namely keeping the electrons from the screen, and at the same time this aperture ring serves for fastening the collector grid to the support ring for the collector electrode.

Fig. 3 shows another embodiment in which the electron-impermeable diaphragm ring 52 is welded onto the carrier ring 38 for the storage screen 26 is. As can be seen from the drawing, the aperture ring 52 is also used to attach the Grid 40 of the storage screen on the support ring 38. The screen 52 can be on the inner surface of the support ring 38 can be arranged separately from the storage grid 40, namely in a manner similar to the i <; Embodiment according to FIG. 1, in which the diaphragm is arranged within the support ring of the collector electrode is.

It is also possible to achieve the desired effect by making the electron impermeable Aperture 52 is arranged on the collecting lens electrode 22, as in the embodiment according to Fig. 4 is shown. In this embodiment, the inner diameter of the diaphragm ring is essential smaller than in the previously described embodiments. On his way from the flood electron source 20 against the bundling and collector electrodes 22 and 24 the flow of electrons runs divergent, as indicated in the various figures, and the lens effect of the Bundling electrode 22 first directs the flood electrode current in a direction that is essentially perpendicular runs towards the storage screen 26. The cross-sectional area of the tide electron flow obviously depends from a distance from its electron source until it is no longer divergent, but runs perpendicular to the storage screen 26 under the action of the converging lens. That's why the inner diameter of the diaphragm ring to some extent on the arrangement of the diaphragm with respect to the Flood electron source 20 dependent. For places where the tide electron flow is still divergent and not bundled runs, for example in the diaphragm arrangement according to FIG. 4, is the inner diameter of the diaphragm ring the smaller the closer the ring is to the electron source of the flood electrodes, and so more the shape of the inner diameter of the diaphragm will adapt to the structure of the flood electron source to have. In areas in which the tide electron stream is now bundled and no longer runs divergent, the inner diameter of the diaphragm ring is relatively independent of the Place the aperture and essentially the same for all layers within this area. In all cases the inner diameter of the diaphragm is chosen so that it catches the electrons in the edge region of the flood electron flow intercepts. So you can know about the relationship between the inside diameter of the diaphragm and the position of the diaphragm in relation to the Flood electron current or its electron source generally say that when the aperture on the bundle electrode or at any location which is closer to the flood electron source than the beam electrode or the bundle electrodes lies, the inner diameter of the diaphragm depend on the location of the diaphragm if the objects of the invention are to be achieved. When the aperture on the collector electrode or is arranged on the storage electrode or on its support or at any location, which is further away from the flood electron source than the bundle electrode or the bundle electrodes, so the inner diameter of the diaphragm is independent of its location.

In other embodiments, it is also possible to have the cover made of one piece with the collector screen 44 or the storage screen 40, as shown in FIG. 5 with respect to the collector screen 44 is shown. This can be achieved, for example, that the edge of the screen in front of the Electroforming of its surface is provided with a mask, so that this screen has a solid, electron-impermeable edge portion 52 is given around the mesh 44, which serves as a diaphragm ring and which can be welded or otherwise attached to a support ring 42. A corresponding one An aperture ring can also be constructed in conjunction with the storage electrode.

Claims (7)

PATENT CLAIMS: 1. Cathode ray storage tube with a write beam, a flood electron stream, a storage electrode, a screen and with a ring encompassing the flood electron stream, characterized in that the ring is designed as an aperture (52) which captures the edge zone of the flood electron stream. 2. Tube according to claim 1, characterized in that the diaphragm (52) at an intermediate the source of the flood electrons (50) and the storage electrode (26) arranged collector electrode (24) is attached (Fig. 1 and 2). 3. Tube according to claim 1, characterized in that the diaphragm (52) on the storage electrode (26) is attached (Fig. 3). 4. Tube according to claim 2 or 3, characterized in that the collector electrode (24) and / or the storage electrode (26) has a conductive mesh (44, 40) which is attached to a Support (42, 38) is arranged, and that the screen (52) is attached to this support (42, 38) is (Fig. 1 and 3). 5. Tube according to claim 3, characterized in that the mesh (44, 40) on the Aperture (52) and this in turn are attached to the carrier (42, 38) (Fig. 2 or 3 and 5). 6. Tube according to claim 4 or 5, characterized in that the diaphragm (52) by a electron-impermeable edge part of a mesh (44, 40) is formed (Fig. 5). 7. Tube according to claim 1, characterized in that the diaphragm (52) on a bundle electrode (22) of the tube is attached (Fig. 4). References considered: U.S. Patent No. 2,660,669. 1 sheet of drawings © 309 749/314 11.63