DE2248146C3 - Gas discharge indicator - Google Patents

Description

The invention relates to a gas discharge display device with a plurality of display units, with a transparent cover plate and a base plate, with anodes and cold cathodes, with ignition electrodes, which are arranged between anodes and cathodes, with between the electrodes and one above the other arranged insulating plates, which have aligned holes and so a plurality of gas-filled discharge cells.

A display device of this type is known from US Pat. No. 3,042,823. Between one There is a large number of top and bottom plates at the intersection of wire-shaped electrodes Arranged by discharge centers. In addition to the indispensable anodes and cathodes, you will find here additional ignition electrodes that facilitate the ignition process. The electrodes on top of each other are separated from each other by insulating plates; pass through the insulating plates Holes that form the individual discharge cells.

However, this display device is not a visual display, but rather one Type of memory that is read by the fact that the ionization state is determined by a special sensing electrode the single cell is queried.

In the German Offenlegungsschrift 21 23 686 was already proposed a storage display device in which addressable ignition cells of a row are arranged with (visual) display cells. The ions generated in the ignition cells can have two functions exercise: Either they diffuse into an adjacent ignition cell and facilitate the ignition process there; or they diffuse via an intermediate cell into the actual display cell, where they discharge the gas

.20 trigger. The electrode and plate arrangement is but in such a way that the diffusion process delays the switching on of the display cell.

After all, it is from the German Offenlegungsschrift 20 56 881 known to use ignition anodes in parallel with a whole series of anodes run, each serving a whole row of cells. The cold cathodes are between the two anodes and divide the cells into front and rear chambers, which have an opening in the cathode are in communication with each other. The rear chambers are so connected that Ions can migrate from one to the other. However, this display device has none Memory effect.

The object of the present invention is to provide a gas discharge display device of the type mentioned at the beginning To create a kind that ignites quickly and safely, has a storage effect and so in terms of manufacturing technology as simple as possible.

This is achieved according to the invention in that the ignition electrodes act as conductive lateral surfaces of bores are formed in a further insulating plate, these holes on the holes of the remaining insulating plates are aligned, and that the anodes are each connected to a resistor are.

It is advantageous if the ignition electrodes have equivalent discharge cells of the display units a common terminal are connected, the insulating at the edge of the ignition electrodes supporting Plate are arranged.

Appropriately, the anodes are thin metal layers, each one in a bore of a insulating plate cover introduced resistance material, each of these holes on one Discharge cell is aligned and the resistors on the ends facing away from the anodes are jointly connected to a continuous sliding layer. It is actually from the German Offenlegungsschrift 19 55 275 known the protective resistances of electrodes than with resistance material Form filled bores, which are closed to the discharge space by a circular electrode are.

Finally, it can be advantageous to form the anode on cuboid resistor blocks which resistive material on one side with the anode and on the other side with a conductive one

Layer is covered, with the resistor blocks having grooves intersecting at right angles, see above that the individual unloading points assigned: Elevations of individual anode surfaces and behind them Show resistance.

The invention is described below using two exemplary embodiments with reference to the drawing explained in more detail; it shows

Fig. 1 is an exploded view of an embodiment of the gas discharge display device.

F i g. 2 a plan view of an ignition electrical subsiral, as it is used in the device according to FIG. 1,

Fig. 3 is a section through the in F i g. 1 shown anode substrate according to line ii,

F i g. FIG. 4 shows a partial sectional view of a shichisirukiur built up from the elements shown in FIG. 1;

F i g. 5 shows an equivalent circuit diagram for the gas discharge display device with a small cathode shown in FIG. 1, F i g. 6 the waveform of an anode signal,

7 is a perspective exploded view of a second embodiment of the gas discharge display device with cold cathode, whereby the anodes and anode resistors are of a different design exhibit,

8 shows an enlarged perspective illustration of an anode substrate according to FIG. 7 and

FIG. 9 shows a section through one in FIG. H shown anode substrate along the line IX-IX.

The preferred embodiment of the gas discharge display device I with a cold cathode shown in FIG. 1 has a cover plate 2 and a base plate 3, both of which are made from a translucent and electrically insulating plate material, for example from glass plates, and also includes a cathode plate 4, a first insulating plate 5 as a spacer, an ignition electrode plate 5. a second insulating plate 7 as a spacer and an anode plate 8. The plates 4, 5, 6, 7 and 8 are between the upper cover plate 2 and the base plate 3 arranged and each provided with a plurality of groups of bores 9, which are arranged in matrix form. The bores of the corresponding groups of the various components are aligned in the vertical direction, as shown in FIG. On the opposite edge areas of the lower surface of the anode plate 2, ie the surface facing the cathode plate 4, a plurality of ignition electrode terminals 10 and a cathode terminal ti are formed, which are connected to the electrodes in the manner described below and in an electroplating process, a vapor deposition process or another suitable process. The upper surface of the cathode plate 4, which faces the cover plate 2, and the entire inner walls of the bores 9 of the cathode plate 4 are coated with a thin metal layer 12, which is applied by the same method as the terminals 10 and 11.

The inner walls of the corresponding bores 9 of the ignition electrode plate 6 are provided with platings 13 extending through the hole, which act as ignition electrodes and are connected to terminals 14, as shown in FIG. The terminals 14 are formed on the upper and lower surfaces of the board 6 at opposite edges by means of printed wiring or other technique. The anode plate 8 has an insulating plate; their bores are filled with solid-state resistors 15 made of pressed glass or ceramic powder (see. Fig. 3). The end faces of the resistors 15 facing the insulating plate 7 are leveled with nickel or a similar material and the thin metal layers 16 that are plated on are used as anodes. The other end faces of the resistors are each connected by thin conductive layers 17a to 17c / which are separated from one another and which are provided for the individual groups of perforations and are made of one material. for example 42-6 alloy, which has essentially the same coefficient of thermal expansion as the base plate 3 made of glass or ceramic; each of these layers covers a group of wells. In the edge area of the insulating base plate, a large number of ignition electrode terminals 18, which can be connected to the terminals 13 of the Zürideleklroden-Plalif 6, and a row of anode terminals 19a to 196 are provided, each with the conductive layers I7j to 17t / on the anode plate 8 te can be connected.

The plates are used to form a layered structure. as shown in FIG. 4 is shown. on top of each other layered; the extent of the layer structure is with Solder glass or similar material sealed. The cover plate 2 and the base plate 3 thus form part of the wrapping. Thereafter, the interior of the envelope is evacuated and with an inert gas. such as neon or argon or a similar gas. with which the gas discharge device is completed is.

The equivalent circuit of this gas discharge display device is shown in FIG. In detail are a matrix excitation circuit 20 and Schutzwklersiände 21a to 21/7 provided with the output terminals of the matrix excitation circuit 20 on the one hand and with ilen corresponding slart electrode terminals 14.7 to 14 /; the display device on the other hand are connected. • which has two display units. The distances between the cathode 12 and the ignition electrode 1 3 and between the ignition electrode 13 and the anode 16 are chosen so that the following conditions are met:

A. The ignition voltage between the anode 16 and the cathode 12 is greater than that between the anode and the ignition electrode 13.

B. The discharge sustaining voltage between anode 16 and cathode 12 is smaller than that between anode 16 and ignition electrode 13. Preferred values for these voltages are the following: through voltage between anode 16 and cathode 12: 200 volts; Operating voltage between anode 16 and cathode 12: 140 volts; Breakdown voltage between anode 16 and Ignition electrode 13: 190 V; Burning voltage between anode 16 and ignition electrode 13: 180 V.

In detail, the operation of the gas discharge display device described below.

After applying an input signal, the matrix excitation circuit 20 converts this signal into a negative one Voltage (- 30 V) and applies this voltage z. B. to the ignition electrode 13a, which is in the input signal corresponds to the sample information contained. Depending on the output signal of the matrix excitation circuit 20, an anode voltage is applied to the anode terminal 19a of the first display unit 22a, the is slightly less than the breakdown voltage (200 V)

/ wipe anode 16 and cathode 12 and those after one predetermined Inlcrviill lowered to a voltage which is a little higher than the sum of the anode voltage and that of the ignition electrode applied voltage (- 30 V). Hin typical example 5 of the anode voltage waveform is shown in FIG l'ig. t), the voltage after a predetermined time interval is lowered from 180 V to 150 V. After that the tension between the selected ignition electrode 13, 7 and the anode 16 increased to 210 V, i.e. to a voltage which is greater than the breakdown voltage (200 V) between Anode 16 and cathode 12 is. This leads to the build-up of an electrical discharge between the ignition electrode 13.7 and the anode 16. which is connected to the anode terminal 19.7 via the resistor 15.7, whereby only the part / wipe the electrodes 13.) and 16 emits light. Because the to maintain the discharge voltage required between the anode 16 and the cathode 12 is set to 140 V, i.e. H. on a voltage that is less than that to maintain a charge reversal / wipe of the anode 16 and the Ignition electrode 13 required voltage of 180 V. The discharge initiated as described above will result the anode 16 and the cathode 12 shifted towards. While the discharge shifted in this way the discharge current increases from a very small value, which is caused by the 13.7 until 13 /? connected high-ohmic protective resistances 21.7 to 21 /; is intended to have a great value: this increased current flows directly through the grounded cathode 12. This results in the Anode voltage to approximately 140 V or the voltage between anode and cathode as a result of the voltage drop across the resistor 15.7 is lowered so that the discharge between the Anode and cathode is maintained. In this way, the discharge automatically pushes itself off from the horn / wipe the anode and ignition electrode to the point of fire / wipe the anode and cathode: afterwards if the discharge is maintained regardless of the input voltage, then there is a storage function will echo.

Hei dem in the Ii g. 7. 8 and 9 gceigicn Aiisfühiungsbeispieles is the anode plate 8 of the previous embodiment in a variety of Anode plates 8.7 to 8 </ divided; a disk is assigned to each display unit. How best from the E ig. 8 and 9 can be seen. looks at the single anode plate, e.g. B. the plate 8.7, from a square Resistance block 25. give away its upper throat with a large number of projections 25.7 to 25n by providing a plurality of grooves intersecting at right angles is. The anodes 16 are on the individual projections by the application of layers of nickel or formed from a different material. As in the first embodiment, this plurality of electrodes is shown in FIG arranged in a matrix, which is the matrix of the bores 9 of the cathode plate used in the display unit 4 corresponds. The other parts of the resistors 25 have thin conductive layers 17.7 to 17cj coated, again using a material such as the 42-6 alloy, which is essentially the same coefficient of thermal expansion as the bottom plate made of glass or ceramic 3 has. In this embodiment, the resistance protrusions are 25.7 to 25n. the anodes 16 and the thin layers 17.7 to 17c / by Elächenkonlaktc connected with each other with great operational reliability. Another advantage of this embodiment is that the manufacture of the anodes and the anode resistors has been simplified as much as possible.

Since the anode electrodes and the anode resistors are formed integrally with one another, is not only their manufacture is very simple, but the reliability of the entire arrangement is also essential has been improved. It is therefore possible to use a variety of anodes and anode resistors with large To summarize packing density.

In addition 5 sheets of drawings

Claims (4)

Patent claims: 1. Gas discharge display device with a plurality of display units, with a transparent one Cover plate and a base plate, with anodes and cold cathodes, with ignition electrodes, which are arranged between anodes and cathodes, with between the electrodes and one above the other arranged insulating plates, which have aligned holes to so one Variety of gas-filled discharge / cells too form, characterized in that the ignition electrodes (13) as conductive lateral surfaces of Bores (9) are formed in a further insulating plate (6), these bores (9) on the holes (9) of the remaining insulating plates (5, 7) are aligned and that the anodes (! 6) are each connected to a resistor (15). 2. Gas charge display device according to claim I, characterized in that the ignition electrodes (13) of equivalent discharge cells of the display units (a, b, c, d) are connected to a common terminal (14) which is insulating on the edge of the ignition electrodes (13) Plate (6) are arranged. 3. Gas discharge display device according to one of claims 1 or 2, characterized in that that the anodes (16) are thin metal layers, each one in a bore (9) of an insulating Cover plate (8) introduced resistance material, each of these bores (9) on a Discharge cell is aligned and the resistors (15) facing away from the anodes (16) Ends are jointly connected to a continuous conductive layer (17). 4. Gas discharge display device according to one of claims 1 or 2, characterized in that that the anodes (16) are formed on cuboid resistor blocks (25) in which Resistance material on one side with the anode (16) and on the other side with one conductive layer (17) is covered, wherein the resistor blocks (25) are at right angles have cutting grooves, so that the individual discharge cells associated elevations (25a to 25n) have individual anode surfaces and resistors behind them.