DE1949310A1 - Display device - Google Patents

Description

Patenicmw

Dr.-Ing: Wilhelm Eeichel _6O54>

Frcmkfurt / Mcdn-1 Patkeiiciße 13

BURROUGHS CORPORATION, Detroit, VStA

Display device

The invention relates to gas-filled display devices and display panels and methods of making these devices and boards.

The display device according to the invention is in the form of a panel with a plurality of gas-filled light-generating cells in each of which at least two electrodes are arranged. This panel includes various structural features, including projections on the electrodes that protrude into the cells to facilitate the position adjustment (positioning) of the electrodes and align the electrodes and cells with one another, shaping the electrodes to achieve minimal leakage between cells, structural features to minimize sputtering, etc. Furthermore, various Embodiments for generating different colored light described.

Matrix-like, tabular, flat light-generating devices are already known. These devices act however, they are apparently only laboratory devices as they are not yet commercially available, although there is a strong need after such flat panel light generating devices of all sizes.

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The invention is based on the object of providing a practical, to create commercial light generating panels that are based on relatively can be easily produced in almost unlimited sizes and is capable of emitting single or multi-colored light to create.

liach the invention, this task is based on a Display device with an envelope containing a gas which emits energy when it is electrically excited, detached through an insulating panel component in the shell with several gas-filled openings through it, the light generating. Cells contain a cathode electrode that protrudes into each cell from one end thereof, an anode electrode near the opposite end of each gas cell and in: contact with the gas in the gas cell »a selectable gas : cells for the delivery of light stimulating device with a first group of conductors, each containing several of the cathode electrodes electrically connect and to a second group of conductors that electrically connect several of the anode electrodes, of which the cathode electrodes are firmly connected to the first group of conductors to ensure the alignment of the cathode ; electrodes and the conductor with the gas cells to facilitate.

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The method of manufacturing such a display device is according to the invention that a plate with holes is provided that anode electrodes on top of the plate be attached that cathode electrodes on which a barium ^ connection is applied, attached to the underside of the plate be that the perforated plate and the electrodes are sealed in an envelope that the envelope evacuated and then filled with gas so that the panel is treated so that free barium escapes from the barium compound, and that the panel is subjected to an aging process.

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The invention and its developments are described in more detail below with reference to preferred embodiments of the invention shown in the drawings.

Pig. Figure 1 is a perspective, partially sectioned view of a display panel embodying the invention.

Pig. Figure 2 is a fragmentary view of the Pig device. 1 and shows a gas cell of this device «

FIG. 3 is a perspective view of part of the device according to FIG. 1 and shows a structural modification.

Pig. Figure 4 is a cross-sectional view of a cell and anode structure in accordance with the invention.

Fig. 5 is a plan view of one cell and another Anode design

FIGS. 6-11 show various cathode designs the invention.

Figs. 12 and 13 show a different anode construction.

14- is a sectional view of a cell structure; modified to facilitate photoelectron emission is.

Fig. 15 is a sectional view of a modification of the display panel.

Fig. 16 is a cross-sectional view of a modification of the panel of FIG Fig. 15.

Figure 17 is a partially sectioned view of an electrode in panels according to the invention, particularly those

after the pig. 15 and 16.

Fig. 18 is a sectional view of another embodiment a board according to the invention.

FIG. 19 is a top plan view of the panel of FIG. 18.

Fig. 20 is a side view of another embodiment of the invention.

FIG. 21 is a top plan view of the panel of FIG.

Fig. 22 is a side view of a panel according to the invention and a package or sleeve therefor.

Figure 23 is a side view of a panel according to the invention and associated devices used to manufacture the panel.

Fig. 24 is a sectional view of a modified embodiment according to the invention.

Fig. 25 is a sectional view of a cell of a panel in which light emitting material is used.

Fig. 26 is a schematic plan view of a typical arrangement of cells containing luminescent materials with different light-emitting properties.

The display device 10 shown in Fig. 1 includes a central plate 20 of insulating material such as glass or ceramic, which is provided with holes, openings or cells 30 in rows and columns. The top of the plate 20 is at 40

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and denoted by 50 on the underside. The top 40 is provided with elongated parallel rods 60, each of which has a row of holes 30 is aligned, and the bottom 50 is provided with parallel grooves 70 with columns of holes 30 are aligned. The grooves 60 and 70 are wider than the holes or cells 30, and in the grooves 60 and 70 row and column conductors 120 and 80 are guided along, respectively. The device 10 is covered with a glass plate 72 and 74 at the top and bottom. These glass plates, too like plate 20, can be rectangular. The line and Column conductors protrude beyond the edges of the panels so that they can be used as electrical connections.

In a preferred panel 10, the central panel 20 is about one millimeter thick, while the glass panels are about one to three Are millimeters thick. The cells are about one millimeter (0.04 inch) in diameter with a density of about twelve cells per 25 millimeters. Grooves 60 and 70 are about 1.3 millimeters (0.05 inches) wide and about 0.13 millimeters (5th mils) deep. Other mechanical arrangements can also be used.

The column conductors 80 comprise a plurality of cathode electrodes 90 which are designed in the form of cylindrical elevations or buttons 90 with a smaller diameter than the cells 30 and which protrude into the cells. The column conductors 80 are strip-shaped and serve as cathode connectors. The row conductors 120 are also strip-shaped and serve as anode connections, because they comprise raised anode parts 140 (3-ig. 2) which protrude into the cells 30.

In order to prevent a continuous stretch of atomized cathode metal from forming between the cathodes and anodes in the cells, it is expedient to have an electrode 90 in the plate 20 surrounding each hole or opening

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Provide incision. This can either be a second groove 100, which extends over the entire length of each hat 70 (FIG. 3) or an annular groove 102 (Pig. 1) surrounding each cathode 90. The educated in this way Recess prevents the formation of a continuous metal short-circuit path from a cathode through a Cell 30 to the associated anode. A similar depression can also be provided at the anode-side end of each cell, either in the form of an elongated groove (not shown) or an annular groove 122 (Figs. 1 and 2).

The anode strips are provided with viewing holes 130 through which one can see into the cells 30, and can be raised Include rings * HO surrounding openings or holes 130 and protrude into cells 30. The cathode buttons 90 and anode rings 140 are dimensioned so that the required distance between them results and thereby one of the parameters is determined which influences the operating properties of a cell. Other anode strips 120 can also be used are either narrower than cells 30 (FIG. 4) or have narrowed parts 121 above the cells (FIG. 5) in order to avoid the to be able to see glowing or smoldering gas in the cells. The anodes can also comprise transparent metal films. Other anode arrangements can also be used.

The cathode and anode electrodes can be made of stainless steel, nickel, alloys of nickel-iron-chromium, and so on. In one embodiment, the electrode strips are about 1.065 millimeters (0.042 inches) wide, 0.127 mm (5 x 10 ~ ⁵ inches) thick, and the projections or raised rings about 0.127 millimeters high. - >

The storage of the cathode and anode strips in their respective grooves enables automatic and easy loading. consolidation and alignment of these electrodes and also unites

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good mechanical fit "wipe the electrode strips and the middle plate 20 and the outer plates 72 'and 74 _f so that leak or leaks are prevented between the cells or reduced to a minimum. The anode and cathode strips can also be arranged in grooves in the upper plate 72 and lower plate 74 instead of in the middle plate 20, the raised electrodes on these strips in turn enabling automatic alignment with the cells 30.

The current density in an ignited or switched-on cell generally depends on the size of the active area of the Cathode on the row so that this parameter can be changed by changing the size of the knob 90. Also can Still other changes can be made to the cathode and anode electrodes. According to FIGS. 6 and 7, for example each cathode button 90 can be provided with a recess 134 in the center so that the button is approximately cup-shaped. These Embodiment can still be modified (see Figs. 8 and 9) that the button in the middle with a pin is provided, which is surrounded by an annular recess 150. This corresponds to the arrangement of a pen in the Indentation 134 of button 90 according to FIG. 6.

According to FIGS. 10 and 11, the cathodes can each also be made from a metal strip 160 in which small parts are cut out so that small protrusions or cheeses 170 stop, which can be bent downwards (see Fig. 11) that each pair of noses protrudes into a cell 30 and up the opposite anode is directed. This embodiment is advantageous for attaching and fixing the position of the cathode strips and for facilitating the ignition of the current flow between the anodes and cathodes. The lobes or noses 170 in adjacent cells 30 are preferably offset from one another by approximately 90 ° in order to achieve a complementary positional fixation to allow the strip.

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In another embodiment of the anode electrodes (see FIGS. 12 and 1.3), the anode strips 120 are finely perforated Areas 180 which are arranged above the cells 30 are provided. The surfaces 180 have fine-meshed grids or screens comparable, so that the anode belonging to each cell practically represents a fine-meshed screen. This embodiment is particularly suitable for collecting sputtered cathode metal so that it is formed by plate 72 Window not reached. In cold cathode glow devices such as this one, it is desirable to use a cathode metal that easily emits electrons, particularly photoelectrons, to facilitate the generation of a glow discharge. It has been shown that nickel, stainless steel, alloys of nickel-iron-chromium, etc. as cathode materials are suitable. The cathodes in the panel 10 can also be made of a metal with barium, cesium or similar materials that have good electron emission properties is coated.

In another arrangement to achieve good electron emission properties, as shown in FIG. 14, a layer 182 is made of compounds containing barium or cesium or any other comparable material with a low work function on the cathode electrodes and / or applied to the anode electrodes and / or the walls of the cells 30. Preferably, cathode strips with cup-shaped slectrode elevations 90 are used, the material 182 is reflected in the cups. Usually these connections are insulators. During manufacture however, a scoreboard with one of these connections causes ion and particle bombardment results in the formation of free metallic barium, cesium or a similar material, and this provides the desired photoemissivity.

Referring to Figure 15, a modified panel 10 includes a central one Plate 20 with cells 30 and a top plate 72 and one

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lower plate 74. The cathode electrode strips 200 in this case are wires that are approximately circular Have cross-section and can be aligned with groups of cells as described above, and the anode electrode strips 210 can also be wires or flat strips. In this embodiment, the cathode wires 200 are for reduction the probability of crosstalk resulting from the transmission of light or particles between neighboring cells, between Layers 220 and 230 of a flexible, compliant material such as fiberglass or similar material are arranged. The fiberglass layer 220 is provided either with a suitable opening grid or net or with openings, so that the cathode wires 200 come into direct contact with the gas in the various cells.

If the cathode wires 200 are placed in grooves 235 in the plate 20 (Fig. 16) then there is only a single layer made of fiberglass 230 is required to enclose the cathode wires and prevent crosstalk. The cathode wires can also have a semicircular cross-section and grooves on the underside of the plate 20 (Fig. 16) be inserted so that their flat surfaces are flush with the lower surface of the plate 20. In this The fiberglass layer can be omitted in the case.

If desired · can be used in all of the display boards described here Fiberglass layers are used.

In these designs with wire cathodes, the electrode wires (Fig. 17) may be coated with glass 240 in order to improve the cell isolation, the glass coating only on those Parts of the electrodes 256 removed with the gas work together in cells 30. This cathode construction can be used with or without fiberglass layers, and the Glass coating can be used on any cathode or anode construction can be applied.

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The various sheets of glass from which the display panel is assembled can be covered with a sealing material, e.g. a glass frit, which has a relatively low melting point point and is dispersed in a suitable binder, be tightly joined together. A suitable sealing material or adhesive is the so-called pyroceram. This material is applied in paste form on the edges of the glass plates on the periphery of the board, and then the board is heated to the extent that until the adhesive melts, thus distorting the desired seal between the plates and the electrodes. Normally the middle plate 20 has a smaller area than the top and bottom plates 72 and 74, which are on all protrude four sides over the middle plate. The sealing adhesive may penetrate between the upper and the middle plate and / or between the lower and the middle plate, and if then the assembly is heated during sealing this penetrated adhesive can expand greatly and separate the panels. This is undesirable and can cause leaks or break the panels if the panel is evacuated and baked «

To solve this problem, a is shown in Figs Sealing ring in the form of a cord 250 made of glass fibers or something similar with a diameter that is approximately equal to or preferably slightly greater than the distance between the plates 72 and 74, placed around the middle panel between the top and bottom panels so that it prevents the adhesive 260 from getting between to penetrate the top and bottom panels and the middle panel. This arrangement ensures a good final seal, When the adhesive 260 has melted and the seal is formed is.

In another embodiment of the invention ( FIGS . 20 x 21), the display panel 10 includes an upper plate 72 and an inner plate 74, a perforated middle plate 20 and the anode and cathode electrodes 80 and 120. The electrode strips

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protrude beyond the edges of the rectangular plates. Those parts of the electrode strips which protrude beyond the edges of the plates are bent so that they are at the edges the upper and lower glass plate. The direction in which the electrodes are bent can be selected as desired and would at best be determined by the arrangement used to mount the panel on a chassis or printed Circuit board or the like is used. Four elongated ones rectangular insulating frame plates 270 made of glass or similar material are arranged around the edge of the panel, so that each frame plate contacts an edge of the panel. The thickness of the frame plates depends on the application. They are about as long as the edge of the board with which they are in contact. Their width is chosen so that they touch the top and bottom plates and the electrode strips, which can be in contact with one of the flats.

A sealant adhesive 280, such as Fyroceram, is applied to the interface between each glass frame panel and panels 12 and 74 and between adjacent ends of the frame panels. After the parts have been held together in a suitable manner, the assembly is heated in order to melt the adhesive and bond all parts together in a gas-tight manner. The panel is pumped dry (evacuated), baked out and filled with a suitable gas via a pipe 290.

The panel made in this way is only between the Frame panels 270 and panel panels 72 and 74 and between adjacent ends of frame panels 270 and adjacent Parts of the plates 72 and 74 are provided with sealing material. This way the problems that arise are avoided may when sealing material is applied between the plates 72 and 74 or penetrates between them.

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By placing the display panels in flasks or envelopes such as those used with vacuum tubes also solve the sealing problem and achieve other advantages. Such an arrangement is shown in FIG. Referring to Figure 22, the panel 10 is in a wrapper and supported therein in any suitable manner, for example by the electrode strips. In this case need The panels of the table do not have to be tightly connected to one another, but they can be by any mechanical Be held together clamping device. The sheath 292 and the Cells 30 of the panel are filled with the desired gas atmosphere via a tube 294. If you want, you can use the upper one Also omit plate 72 and lower plate 74 if there are other means of locating the electrodes on the plate 20 can be used. The omission of the top plate 72 also avoids the problem posed by the possible deposition of atomized cathode metal results.

Mercury is preferably used as the cathode metal in order to counteract the sputtering of the cathode metal. The mercury can be introduced by placing a capsule 296 (Fig. 23) containing a drop of mercury 298 in a glass tube 300 which is attached to one of the plates 72 or 74 of the panel 10. The mercury capsule becomes proportionate far, e.g., about 50 to 75 millimeters, from the board. The capsule 296 is either with a Metal sleeve, which can be heated by induction, or wrapped with a wire 310 through which the capsule can be heated by a current flowing through the wire to cause the capsule to rupture and the mercury releases.

To come back to the process of making a tablet, after the sheets of glass that make up the table are assembled and tightly connected, the

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Panel pumped out and baked out through tube 300 and filled with a gas that enables the formation and maintenance of a cathode glow. Gases such as argon and neon in a mixture of about 5 $> argon and 95 $ neon and a trace of krypton are suitable for this. The gas pressure ranges from about 40 to about 80 torr at room temperature. After the panel has been baked out and filled with gas, the tube 300 below the mercury capsule is sealed off at the point 320. Thereafter, the rows of cells in turn are cycled with about 50 to about 100 milliamps per row of cells (cell row) in order to age the panel. This aging process takes a few hours.

The mercury is then freed from the capsule 296 by heating it so that it ruptures. The mercury beats first settles on the wall of the tube 300 above the capsule, and with it the mercury in all cells of the table penetrates, it is heated in an oven to around 200 ° C.

As soon as a sufficient proportion of the mercury has penetrated from the tube 300 into the cells, that part of the tube 300, containing the mercury capsule, the tablet is preferably kept at this elevated temperature, and the pipe is melted tightly at the point 330. The aging process is then repeated.

If desired, the board can also be heated to around 200 ° C first and then releasing the mercury from the capsule while continuing the heating. After the mercury · in the Panel is distributed, the pipe is melted tightly at the increased temperature.

The aging process can also be repeated several times, but one aging process is usually sufficient.

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The display panels can be made more versatile by providing auxiliary control electrodes so that one or three receives multiple electrodes for each cell. A device of this type (Fig. 24) consists of several stacked one on top of the other Plates, a lower glass plate 334 with a pipe socket 336, a horizontal row (or row) of cathode electrodes 338, an insulating plate 340 with holes 350 and associated sputtering traps 351 (Figs. 1 and 2), column electrodes 352 with holes 353, an insulating plate 356 with holes 358 and sputtering traps 359, double anode electrodes 360 with holes 362 and a top glass plate 380. By connecting to the center electrodes 352 and selected cathodes 338 and anodes 360 voltages can be applied, different Cause control operations.

These display devices can be made even more versatile in that the cells 30 contain fluorescent material that creates different light. Avenge Pig. 24, in the a single cell 30 is shown, the top surface of the cathode button 90 or the recess of a cup-shaped Button, if such is used, be coated with a phosphor 390. The phosphor 390 can also on the wall of the cell "30 or on the inner surface of the top plate 72 in alignment with the cell 30.

The phosphor can be painted, sprayed, or deposited be applied. As a phosphor can be different Species, e.g. the species Sylvania 151, 161, 131 and various P-types manufactured by General Electric can be used. '

In the case of a device suitable for color display Uses phosphors (also called phosphors), which generate the three basic colors red, green and blue. These

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Phosphors are applied in "adjacent cells," see above that they form so-called Parb threes, as in color television picture tubes and as shown in FIG. A red glowing phosphor is zinc phosphate activated with manganese, a green luminous phosphor is zinc orthosilicate and a blue luminous phosphor is zinc sulfide.

Zinc orthosilicate pi phosphor and a gas mixture of argon, Cells containing neon and xenon can be operated to produce light of two different colors. When on When a relatively low voltage of around volts is applied to a cell, the phosphor in the cell is emitted largely green light due to the ultraviolet excitation from the gas. When a higher voltage of about 400 volts is applied to a Cell is applied, the phosphor is excited to emit white light.

The gas filling, which is particularly suitable for producing color, contains argon, neon, xenon and mercury. Argon is emitted in the ultraviolet range to excite certain phosphors such as zinc sulfide and zinc oxide. Mercury emits in the ultraviolet range and is particularly suitable for exciting phosphors such as zinc sulfide and zinc sulfate. Xenon emits in the ultraviolet range and is particularly suitable for stimulating oxides and silicate phosphors. It is also possible, To use a first fluorescent substance in a cell, which is caused by argon, neon or mercury to emit ultraviolet Light can be excited, which in turn excites a second phosphor to emit the desired light. Typical phosphors G.E.X-80 and JEDEC P-16 are types for this operating mode.

The one in Pig. Panel 332 shown in FIG. 24 can also be fluorescent be provided. It can contain two different phosphors in each cell, with one phosphor 400 in holes 358 of plate 356 and the other phosphor 410 in holes

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350 of the plate 340 is provided.

If, during operation of the device 332 containing phosphors, the phosphor 410 is to be excited to emit colored light, then the electrodes 352 are operated as anodes and the electrodes 338 as cathodes. If the phosphor 400 is to emit light, then the electrodes 360 are operated as cathodes and the electrodes 352 as anodes. Assuming that the phosphors 400 and 410 can be excited in such a way that they together emit light of a third color, this can be achieved by placing the two electrodes 338 and 360 at positive potential and thus as anodes and the central electrodes 352 as cathodes operated on negative potential or vice versa.

How matrix or blackboard displays are operated with electrodes arranged in rows and columns is. per se known. The information to be reproduced or displayed on a board can be obtained from a digital computer, a decoder or a similar device, and the received signals are applied to respective X and Y electrodes, whereby the cells are turned on at the intersections of these electrodes and display the information you want, which is letters, numbers, characters, messages, images and similar symbols.

These multi-cell display panels are essentially the first practically useful devices of this type which can be manufactured in virtually unlimited dimensions and in large numbers. The numerous features essential to the invention include the configuration of the perforated central plate and the anode and cathode electrodes and the relationship between these parts. This applies in particular to the formation of grooves in the top and bottom of the central

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leren plate and protrusions on the anode and cathode electrodes, that are aligned with the cells.

In electrical terms, it makes it easier to create opposing ones Anode and cathode protrusions create a glow discharge. It also causes the glow discharge Forms inside the cell around the cathode and contributes to the mutual influencing of the cells (also called interference or crosstalk). In mechanical terms, the protrusions form on the electrodes a means for local fixation and attachment of the electrodes, which is particularly important when attaching elongated, flexible and relatively weak electrodes in panels of large dimensions is critical. The grooves in the middle Plate also prevent mutual interference (interspersion) of adjacent rows or columns of Cells, since a barrier is formed which prevents the movement of ions or particles. Make the grooves easier also attaching the anode and cathode electrodes to the middle plate.

Another essential feature of the invention is the use of a substance that is light-sensitive and easily electrons emitted, when excited by radiation. This feature ensures rapid formation of a glow discharge. The procedures for hermetically sealing the parts of the panel and introducing the mercury into the cells are also essential features of the invention.

On the basis of the numerous exemplary embodiments and features of the invention, it is readily possible to use the features of the invention to modify without deviating from the basic idea of the invention. This is how the cells are needed in a multicellular table according to the invention not to be arranged in any particular position relative to one another, i.e. in rows or columns,

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and likewise, the electrodes need not be attached in any particular arrangement or relationship to one another be. In addition, the materials, such as glass, metals, fluorescent materials, "gases, can be chosen differently, whatever for the different manufacturing and processing steps of the multi-cell table applies.

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Claims (62)

Claims il display device with an envelope containing a gas, IaB emits energy when it is electrically excited, characterized by an insulating panel component in the shell with several gas-filled openings or holes through them that contain light-generating cells, a cathode electrode projecting into each cell from one end thereof, an anode electrode near the opposite one At the end of each gas cell and in contact with the gas in the cell, an optional gas cell for delivery of A light stimulating device having a first group of conductors each electrically connecting a plurality of the cathode electrodes and a second group of conductors electrically connecting a plurality of the anode electrodes, one of which is the cathode electrodes are firmly connected to the first group of conductors, relative to the alignment of the cathode electrodes and the conductors to facilitate the gas cells. 2. Display device according to claim 1, characterized in that the inner wall surface each Gas cell is interrupted by a surface discontinuity located between the cathode and anode electrodes of the cell is. 3. Display device according to claim 1 or 2, characterized in that the wall of each gas cell between the cathode and anode electrodes are recessed so that a discontinuous path for any Material is formed which emerges from the cathode electrode by sputtering. 009317/1371 4. Display device according to claim 1, 2 or 3, characterized in that the wall of each gas cell next to at least one of the electrodes is provided with a recess. 5. Display device according to one of the preceding claims, characterized in that it is at the first and second group of conductors by row and column conductors, respectively acts and that the row conductors are elongated strip-like conductors, on the surface of which the cathode electrodes are formed as elevations in the areas of successive gas cells. 6. Display device according to claim 5, characterized in that that the row conductors are wider than the corresponding transverse dimension of the gas cells and one end close the gas cells. 7. Display device according to claim 5 or 6, characterized in that the cathode electrodes as from the strip-shaped conductors protruding noses or tabs from parts of the strip-shaped conductors by cutting and Bending the strips are formed. 8. Display device according to one of the preceding claims, characterized in that at least two rabbits or lobes protrude into each cell and the noses or Lobes in each cell are oriented at an angle to those in adjacent cells. 9. Display device according to claim 1, 2, 3 or 4, characterized in that the first and second group of conductors each row and column conductors and the row conductors are rod-shaped. 009817/1371 10. Display device according to claim 9 »characterized in that. the rod-shaped row conductors except in the area of the gaseous cells are coated with insulating material. 11. Display device according to one of the preceding claims, characterized in that the insulating Panel component several. Contains grooves or grooves formed line by line on a surface of the board, and that the row conductors are arranged in these grooves or grooves. 12. Display device according to one of the preceding claims, characterized in that the raised Cathode electrodes each contain a central recess and are approximately cup-shaped. 13. Display device according to claim 12, characterized in that that a pin is arranged in each of the central depressions. 14. Display device according to claim 12 or 13, characterized characterized in that each cell has an electron emissive photocathode material in the central recess contains. 15. Display device according to one of the preceding claims, characterized in that the raised or protruding cathode electrodes taper inwardly from a diameter which is at least so as large as the diameter of the gas cells and that the outer surface of the tapered or tapered projections or attacks bumps on the edge of the gas cells to facilitate the alignment of the cathodes, 009817/1371 16. Display device according to one of the preceding claims, characterized in that the electrodes protrude into the cells. .17. Display device according to one of the preceding claims, d a d u r c, h characterized in that the anode electrodes -are provided with holes or openings to allow the light generated in the cells to be seen. 18. Display device according to one of the preceding claims, characterized in that the second Ladder group contains strip-shaped ladder that extends in the field each of the gas cells are narrowed to form the anode electrodes and the light generated in the gas cells can be seen. 19. Display device according to one of the preceding claims, characterized in that the second Conductor group contains strip-shaped conductors that have multiple openings contained in the area of each of the gas cells, and that the strip-shaped Conductors serve as anode electrodes in the areas next to the gas cells. . 20. Display device according to one of the preceding claims, characterized in that the anodes are mesh, grid or screen-like components. 21. A display device according to claim 1, characterized in that the insulating panel member includes line-wise formed grooves or grooves on one surface and column-wise formed grooves or grooves on the opposite surface, that each gas-filled hole extends between a row and a column groove that the stimulating device a first group of conductors extending along the row grooves and a second group of conductors extending along the column grooves ₉ 009817/1371 for applying a predetermined electric field to selected ones Contains cells, and that the row and column conductors are in contact with the gas atmosphere of the gas cells. 22. Display device according to claim 21, characterized in that the grooves or grooves and the Row and column conductors much wider than the transverse dimensions the gas cells are. 23. Display device according to claim 21 or 22, characterized in that the conductors in the grooves or Grooves of at least one surface of the panel component in the shape of a rod are. 24. Display device according to claim 23, characterized in that that a flexible layer touches the rod-shaped conductors intimately to mutual influence of the cells (interference or crosstalk). 25. Display device according to claim 24, characterized in that that the layer is made of fiberglass. 26. Display device according to claim 23, 24 or 25, d a through characterized in that the rod-shaped Conductors are arranged between the fiberglass layers so that these closely enclose the conductors to prevent mutual interference of cells to prevent. 27. Display device according to one of the preceding claims, characterized in that the conductive Wires are covered with insulating material except in the areas of the gas cells. 009817/1371 28. Display device according to claim 21 or 22, characterized characterized in that the row and column conductors are strip-shaped. 29. Display device according to one of claims 21 to 28, characterized in that the row conductors Contain raised parts that are in the longitudinal direction of the ladder in the areas of the gas cells and "in the gas cells protrude. 30. Display device according to one of claims 21-29 »characterized in that the column conductor are provided with holes in the area of each of the gas cells so that the light generated in the cells can be seen from outside. 31. Display device according to one of claims 21-30, characterized in that the inner surface is discontinuous in each of the gas cells between the interconnected row and column grooves. 32. Display device according to one of the preceding claims, characterized in that the inner walls of the cells are indented. 33. Display device according to claim 32, characterized in that that the recesses are formed along the inner walls of the gas cells by an auxiliary group of grooves which are connected to the grooves on at least one side of the panel component. 34. Display device according to one of the preceding claims, characterized by one on one side of the panel component adjoining delimitation plate and one on the opposite side adjoining second delimitation plate. 0098 17/137 1 35. Display device according to one of the preceding claims characterized in that each gas cell contains phosphor and that the selected gas cell exciting device for the excitation of the selected gas Cells, which in turn stimulates the phosphor. 36. Display device according to one of the preceding claims, characterized in that each cell contains an electron-emitting photocathode. 37. Display device according to claim 36, characterized in that that the photocathode in each cell is supported on the wall of the cell. 38. Display device according to one of the preceding claims, characterized in that each cell an electron-emitting photocathode with a compound of barium or cesium containing free barium or cesium gives off as the cell is aged. ■ 39. Display device according to claim 38, characterized in that the compound is a barium compound from which barium is released under particle bombardment into the cells. 40. Display device according to claim 1, characterized in that that it contains a middle plate with several of these cells, that on top of the middle one Plate an insulating plate and below the middle plate also an insulating plate rests and that this insulating Plates have a larger area than the middle plate, that between the middle plate and the lower plate the cathode electrodes and between the middle plate and * 009817/1371 the upper plate the anode electrodes are arranged that the middle plate is surrounded by a flexible sealing ring that seals the space between the upper and lower plate, and that a sealing material between the upper and lower plates in the vicinity of the sealing ring all plates connects with each other, but is prevented by the sealing ring from entering the space between the middle and one of the two to penetrate other panels. 41. Display device according to claim 1, characterized in that the insulating panel component is a middle panel, that a first delimitation panel rests on one side of the central panel and a second delimitation panel on the opposite side of the central panel and that the two delimitation panels oine a larger area than the middle panel that a plurality of row conductors are arranged between the middle panel and the first delimitation board in depressions or grooves which are located in one of the panels, that a plurality of column conductors are arranged between the middle panel and the second delimitation board in depressions or grooves which are located in at least one of the panels that the middle panel is surrounded by a sealing ring which surrounds the two boundary panels and forms a gas seal, and that an adhesive is provided in the area of the sealing ring and between the two boundary panels to maintain the gas seal. 42. Display device according to claim 41, characterized in that the row and column conductors are each arranged in grooves of the two delimitation boards. 43. Display device according to claim 41 or 42, since d u r cn g ~ e indicates that the sealing ring is formed from compressible material in the uncompressed state and one 009817/1371 Has transverse dimension that is larger than the space between the two Boundary panels is. 44. Display device according to claim 41, 42 or 43, characterized in that the sealing ring is string-shaped. 45. Display device according to claim 1, characterized in that the stimulating device is several row conductors resting on one surface of the panel and a plurality of column conductors resting on the opposite surface contains and that the conductors are in contact with the gas in the cells that the panel component from one to the Conductors adjacent gas-tight envelope is surrounded and that the panel and 'adjacent conductors in the envelope to one of the Walls of the shell spaced location are supported. 46. Display device according to claim 1, characterized in that the stimulating device is several Row ladder adjoining one side of the board and several Column conductors adjoining the opposite side of the panel for application of a predetermined electrical Field of selected cells contains that the conductors are in contact with the gas atmosphere of the gas cells, that the conductors are rod-shaped on at least one side of the panel that a flexible layer extends over the rod-shaped Ladder extends on one side of the panel and that this layer touches this ladder intimately, so that a mutual Influencing the cells (interference or crosstalk) is avoided. 47. Display device according to claim 46, characterized in that the rod-shaped conductors have a smaller diameter than the cells. 009817/1371 48. Display device according to claim 46 or 47, characterized gekennzei chnet that the rod-shaped conductors are embedded between two flexible layers, one of which rests on the surface of the board and is perforated in the area of the gas cells. 49. Display device according to claim 46, 47 or 48, d a through characterized in that all conductors are rod-shaped. . ■ 50. Display device according to claim 1, characterized in that that the cells are arranged in groups of three, with one cell in each group of three a fluorescent substance emitting blue light, the second a fluorescent substance emitting green light and the third a red one Light emitting phosphor contains that the display device has a selected gas cell for emitting colored light and a stimulating device for producing a colored image on the board, and that said device comprises a plurality of row conductors on one side of the panel and several column conductors on the other side of the panel, those with the gas atrcosphere of the gas cells are in contact in order to apply an electric field to selected gas cells. 51. Display device according to claim!, Characterized by two phosphors in each of the cells, at least three electrodes associated with each cell, two of which Electrodes are arranged at opposite ends of the cell in contact with the Oasatmosphäre of the cell, a Between two of the three electrodes for the excitation of one of the two phosphors an electrical voltage generating device to generate a first colored light in selected cells and one between two other electrodes of the three electrodes for the excitation of the second phosphor one 009817/1371 Electrical voltage generating device for generating a light with a second color in selected cells. 52. Display device according to claim 50, marked net by one of the two phosphors in selected cells at the same time to emit a light with a third Color stimulating device in selected cells. 53. Display device according to claim 51 or 52, characterized in that at least one of the phosphors is applied in each cell on the inner wall of the cell. 54. Display device according to claim 51, 52 or 53, characterized in that at least one of the phosphors in each cell are applied to one of the electrodes is. 55. Display device according to one of claims 51-54, characterized in that the inner wall each of the gas cells is recessed to prevent a continuous path of atomized material from spreading forms between two electrodes of the three electrodes. 56. Display device according to claim 1, characterized in that a plurality of electrodes are operationally related to the panel component, that the panel component and the electrodes contain structural means by which they are in contact with one another and are connected so that. the electrodes are in the correct operational relation to the gas-filled cells and are evenly separated from one another and spatially fixed to one another and to the panel component, and that at least two electrodes are in contact with the panel component and the gas in each cell, one of which is an anode and the other can be operated as a cathode. 009817/1371 ^; 57. Display device according to claim 1, dadur ch g e indicated that a plate is provided with the gas-filled openings or holes that on the top and bottom of this plate each have a further plate is attached that between the-upper and the middle plate a first group of electrodes is in contact with selected cells, so that between the lower and the middle plate a second group of electrodes is in contact with other cells, so that the electrodes in one or the other plate are embedded in such a way that they - flush with the plate surface and that the plates are in contact with one another. and sandwiching the electrodes such that at least one electrode of the first group and one electrode of the second group is in contact with each cell. 58. Display device according to claim 57 »characterized in that the top and bottom of the middle plate contains grooves in which the electrodes are arranged are. 59. Display device according to claim 57 or 58, d a d u r ch characterized in that the electrodes are arranged in grooves in the upper and lower plates. 60. Display device according to claim 1, characterized in that three interconnected plates are stacked one on top of the other, of which the middle plate contains the cells, that the cathode electrodes are arranged between the lower and upper plates and the anode electrodes are arranged between the middle and upper plates, that the electrodes protrude beyond the edge of the plates and are bent so that they run perpendicular to the plane of the plates and are in contact with the plates, that glass plates are attached to the edges of the plates and completely enclose this plate and that the glass plates with the Panels are connected by an insulating adhesive. 61. A method for producing a display device according to one of the preceding claims, characterized in that a plate is provided with holes or openings, that anode electrodes are attached to the top of the plate, that cathode electrodes, to which a barium compound is applied, on the underside of the plate that the perforated plate and the electrodes are sealed in an envelope, that the envelope is evacuated and then filled with gas, that the panel is treated so that free barium escapes from the barium compound, and that the panel is subjected to an aging process will. 62. The method according to claim 61, characterized in that the treatment of the panel comprises the formation of a glow discharge in the cells, so that the barium compound in the cells is bombarded by particles and free barium is dissolved out of the barium compound. 009817/1371