DE2265577C2 - Gas discharge indicator - Google Patents

Description

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The invention relates to a gas discharge display device according to the preamble of the claim.

Such a gas discharge display device is, for. B. from US-PS 33 27 154 known In this Display device, the other feed lines are also arranged on the base plate As all feed lines thus lie in one plane, there are restrictions with regard to the connections to the electrodes. In addition, in the case of the known display device provided for direct voltage operation, the Electrode pairs free in the ion ..izable gas of the discharge space.

There are also gas discharges. Display devices known (DE-OS 18 03 213, US-PS 35 59 190), in which a glass plate with holes drilled into it, which form discharge cells, is inserted between a pair of glass base plates. As neon and nitrogen is sealed in the discharge cells included * °. On the outer side of each Glasgrundplat-Ie are arranged in directions perpendicular to each other electrodes for light emission discharge is in the discharge cell at the intersection of selected electrodes produced this known gas discharge * ⁵ display devices are advantageous in that the cells each forming a discharge region are isolated from each that there is no interference between neighboring cells and that the 5 »glass plate inserted between the two glass base plates serves as a spacer between the glass base plates, so that the opposing electrodes can be kept at the same distance. On the other hand, the known display devices are disadvantageous in that the evacuating and sealing the ^ss discharge gas is difficult to avoid this difficulty, it is considered possible to omit the intermediate glass plate with openings and assemble the glass base plates with a spacer or spacers between the ^ω glass base plates are only used on their perimeter. In such a case, however, it is difficult to keep the glass base plates parallel to each other, so that the distances between opposing electrodes become non-uniform, which brings about control of the properties of the respective discharge regions. Furthermore, since the glass base plates must necessarily be mechanically strong enough to withstand the pressure difference between the pressure of the enclosed gas and the atmospheric pressure, they are noticeably thick. Accordingly, arranging the electrodes on the outside of each glass base plate leads to an increase in the distance between the opposing electrodes, which leads to a disadvantage that a high ignition voltage is required. In order to reduce the ignition voltage, it can be considered to provide a flex electrode on the inside of the Glasgnmdplatten and this with a thin dielectric layer, e.g. B. of glass to cover. However, even in this case, it is not easy to keep the glass base plates parallel to each other, and the glass base plates themselves are also somewhat curved, so that the characteristics of the respective discharge areas cannot easily be made uniform. This poses a problem particularly in the construction of large gas discharge display devices.

There is also a gas discharge display device is known in which intersecting electrodes on a Side of a base plate are arranged (GB-PS 11 98 568). In this display device, the necessary distance between the electrodes through recesses of different depths in the base plate achieved The base plate is housed in a gas-filled discharge tube

The invention is based on the object of a gas discharge display device for alternating current operation to create uniform discharges regardless of v *> n of a curvature of a base plate results and in which the electrodes can be connected in a simple manner. This task is solved with a generic gas discharge display device by the characterizing part of the claim specified features.

Even with only one side with respect to the base plate arranged discharge space is thus arranged according to the invention on both sides of the insulating layer Leads enables a simplified, matrix-shaped line routing to the electrode pairs

Exemplary embodiments are explained using the drawing:

F i g. 1 shows a partially broken away perspective partial view of an embodiment of FIG Invention.

Fig.2 shows a cross section of the example according to Fig. 1.

F i g. 3 shows a partially broken away perspective partial view of a second exemplary embodiment the invention.

4 shows a cross section of the example according to Fig. 3.

F i g. FIGS. 5a to 5d explain a sequence of steps in the production of the exemplary embodiment according to FIGS F i g. 1 and 2.

F i g. 6 shows a plan view of the electrode arrangement of a third exemplary embodiment of the invention for a numeric display and

7 shows a part of the electrode arrangement in cross section according to FIG. 6th

According to FIG. 1, parallel X and V leads 2 and 4 are provided on a base plate 1 made of glass, these being isolated from one another by an insulating layer 3 and a further dielectric insulating layer 5, e.g. B. is formed from solder glass on the insulating layer 3. At each intersection of the leads 2 and 4 are

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Electrodes 2a and 4a formed on the insulating layer 3 to create a discharge gap. The electrode 2a is connected to the lead 2 via a through hole connected, which is formed in the insulating layer 3, and a cover 6, e.g. B. made of glass, is on the other Insulating layer 5 attached to form a discharge gas space 7 therebetween, the cover 6 is sealed at its periphery and a discharge gas, such as. B. neon is sealed in the discharge space 7 locked in. In the case of creating an advertisement only on the side of the cover 6, only the cover 6 is formed from transparent glass and the Base plate 1 can be formed from an opaque insulating jacket. In the case of generation a display on both sides, the base plate 1 is also formed from transparent glass

A maintenance AC voltage is applied to all electrodes and a write voltage is applied to selected X and Y leads. If the voltage at the discharge gap exceeds the required ignition voltage, a discharge point is created between electrodes 2a and 4a, as shown in FIG G. 2 is shown. The further insulating layer 5 maintains the conversion generated by the discharge, so that a continuous discharge point is generated by a subsequent maintenance voltage, as is the case with known gas discharge display devices. B. by the technology of printed circuits, and formed on the same side of the insulating layer 3 on the base plate 1 so that the discharge gaps do not change even if the base plate 1 is curved the degree of parallelism of the electrodes with the base plate 1 is not important and the characteristics of the discharge cells formed with the discharge gaps become uniform and the manufacture of the display device becomes very easy.

The electric field in the discharge gas space 7 is related to the thickness of the further insulating layer * 0 5 and the distance between the electrodes 2a and 4a, ie the discharge gap length, but by selecting the thickness of the further insulating layer 5, it can be smaller than about half the discharge gap length of the Discharge point can be generated completely in the discharge gas space 7. An advertisement, ζ. Π. of letters, can be generated by combining the positions of the discharge points, ie selected intersection points of the X and Y leads 2 and 4.

The F i g. 3 and 4 show another example play the invention with the X-leads 12, which on the base plate 11: are formed, the y-leads 14 of the further insulating layer 15, the cover 16 and the discharge gas space 17.

According to FIGS. 5a-d. based on which the production the gas discharge display device according to FIG. 1 and 2 will first be through holes 102 is formed by punching in a plate 101 constituting the insulating layer, and the plate 101 is heated (Fig. 5a). A conductive paste is filled into the through holes 102, ^ leads 103, which connect with the conductive paste filled in the through holes 102 are on one face of the Plate 101 attached by means of the technology of printed circuits, y-leads 104 and the aforementioned electrodes are on the other surface of the plate 101 by means of the technique of printed circuits and the arrangement is heated (Fig.5b). Then another Insulating layer 105 by means of a printing, reaming, atomizing, vapor deposition process on the Formed surface of the plate 101 on which the y-leads 104 have been formed (Figure 5c). Next will a base plate 106 attached to the surface of the plate 101 on which the ^ leads 103 are located, and a cover 108 is placed on the surface of the plate 101 provided with the further insulating layer 105 attached to form a discharge gas space 107, the cover 108 being attached at its periphery to the further insulating layer 105. The discharge gas space 107 is evacuated and then a gas mixture of neon and nitrogen is sealed in the Enclosed discharge gas space 107, thus producing a finished gas discharge display device i (Fi5d ^

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35

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65 (Fig. 5d ^

F i g. 6 shows a further example χ a numeric display and FIG. 7 shows its cross section. B. made of glass, lines 90 to 98 and connecting lines 88 and 89 are provided and an insulating layer 83 is formed on these 98 and connecting lines 88 and 89 are connected via holes formed in the insulating layer 83. Another insulating layer 85 is formed on these electrodes, and a discharge gas space 87 is provided between the further insulating layer 85 and a cover 86.

The electrodes 82a and 82b are connected to one another by the connecting line 89 and to the line 90 via the connecting line 88. The line 90 is used for digit selection and the lines 91 to 98 are connected to selection electrodes 84 of the respective segments for segment selection.

By applying a writing voltage, i. H. a voltage higher than the ignition voltage, via cables, z. 91, 93, 94, 96, 97 and 98, with a sustaining AC voltage on all lines 91) to 98, as is customary with gas discharge display devices a number »3« is displayed and this display is only continuous when the maintenance voltage is applied sustained due to the backup effect by the wall charges until an extinction voltage is created.

In this case, a discharge occurs between the electrode 84 and the common electrodes 82a and 826 on both sides in each selected segment and the display is due to the 3 Electrodes widened per segment, which makes the display easier to read. You further the connecting lines 88 and 89, the lines 90 and 98 and the electrodes 82a, 82 £> and 84 are formed in the same manner as in two-layer wiring so that the segment selection electrodes for each digit can be easily connected by the wires and making the display device becomes easy. The lines 90 to 98 are connected to the ports on the peripheral area the base plate are provided.

For this purpose 3 sheets of drawings

Claims (1)

Claim: Gas discharge display device with a base plate and a cover plate, which enclose an ionizable gas, with a number of electrode pairs on an insulating layer covering the base plate and with one and other supply lines for these electrode pairs, one of which is supply lines for one of the electrodes of the electrode pairs on the base plate arranged to and connected to one of the electrodes through the insulating layer, characterized in that the other leads (4) for the other electrodes (4a) of the electrode pairs (2a, 4a) are arranged on the insulating layer (3) and that another insulating layer (5) covers the electrode pairs (2a, 4aj)