CS244064B1 - Electroluminescent window orthogonal graphical display - Google Patents

Abstract

The display consists of two glass plates with vacuum-applied sight glass layers, the essence of which is that conductive on both plates strips of tin oxide, covered yttrium oxide layer zinc sulfide activated with manganese, and again an oxide layer on it yttrium and on it a layer of gold, taking both glass plates are coated on the side layers and perpendicular to conductive stannous strips together sealed. Display and search selected points, for example in the investigation eyes in healthcare and j.

Description

The invention relates to an electroluminescence viewing orthogonal graphic display consisting of two glass plates with vacuum deposited viewing layers.

Electroluminescent vision panels are widely used in autovisual techniques for surveying, navigation, eye examination in health care, etc. Electroluminescent vision displays are known on one glass plate, in which the assembly consists of two insulating and one luminescent layers enclosed between the strip warp perpendicularly steamed strips of electrodes, i.e. upper and lower electrodes of one and the other polarity, or electric field leads. If an electric field is applied to the electroluminescent assembly by means of perpendicularly arranged electrodes, the electroluminescent layer lights up only at the point where the two electrodes then cross the upper and lower opposite polarities. If a line is formed in such a system, voltage must be applied to one lower electrode and all upper electrodes. By switching the voltage at the lower electrode, this line can be shifted. If a graphical display is to be produced, for example a line of different position and shape, or two lines, in the simplest case perpendicular to each other, it is possible to create this display by stacking the individual luminous points formed in the electrode cross. This requires a sophisticated electronic control enabling the desired addressing via a multiplex selection system. Even the simplest two-line graphical display needs to be controlled by this complex electronic system in the prior art electrode arrangement.

244 064

These previous drawbacks are eliminated by an electroluminescent viewing orthogonal graphical display consisting of two glass plates on which the transparent layers are vacuum-deposited, the principle being that the two glass plates are successively applied with conductive strips of tin dioxide SnOg or indium oxide, on them a layer of yttrium oxide ϊ ₂ ° 3 ^{0 with a} thickness of 200 to 600 nm, on it a layer of zinc sulfide ZnS, activated by 1-5% by weight of manganese Mn with a thickness of 500 to 1 500 nm, on it again a layer of yttrium oxide TgO ^ ⁰ to -600 nm, and on it a layer of gold Au having a thickness of 3.0 to 9.0 nm, the two glass plates being bonded together on the side of the layers and perpendicular to the conductive strips of stannous oxide SnOg.

The main advantage of the electroluminescence viewing orthogonal graphical display is that it allows both simultaneous observation of two or more orthogonal illuminated lines on the display and the ongoing event behind the display, or the orthogonal display can be attached to the image below it, for example a map; and the luminous lines can thus be aligned or guided electronically by the motion below, without the complex, electronically multiplexed, representation of the orthogonal luminous lines.

Another advantage is the high resolution of the displayed lines, because these lines are not composed of individual points as in multiplex control, but their course is continuous.

In the enclosed Fig. 1, one glass panel of the display is shown in axial section; Fig. 2 shows an overall view of the display consisting of two glass panels.

In Fig. 1, a lower electrode warp of transparent conductive strips 2 of tin oxide or indium oxide, or a combination of both, with a resolution of 0.01-0.3 mm with a conductivity of 10 is supported on a glass substrate 6, 2-5 mm thick. - £ 200 per square. The light absorption of the conductive strips 2 is almost negligible. The yttrium oxide layer J, 200-600 nm thick, is preferably vacuum deposited on this warp

244 064, however, 350 nm. An electroluminescent layer of zinc sulfide X, activated by manganese and chlorine with a manganese concentration of 1-5% by weight, having a thickness of 500-1,500 nm, preferably 900 nm, is vacuum deposited on this layer. The layer technology 6 is carried out under temperature, speed and geometric conditions to achieve maximum transparency with light absorption of less than 10%. A yttrium oxide 2 layer, 200-600 nm thick, preferably 350 nm thick, is then applied again under vacuum. The two layers of yttrium oxide 18 increase the electrical strength of the electroluminescent layer 6, prevent its dielectric breakdown, and reduce the capacity of the entire display. In a further operation, a second surface electrode 6 having a thickness of 3.0 - 9.0 nm, preferably 4.5 nm, is deposited under vacuum. The electrode thickness shall be such that, with a conductivity of less than 10 kQ per square, the light absorption when passing therethrough is less than 20%,

FIG. 2 is an overall view of the display. The glass plate χ 3 ^{e is} pressed onto the plate 2 by the vacuum-vaporized layers, so that the lower electrode warp of the transparent conductive strips 2 on the plate X is perpendicular to the lower electrode warp-transparent conductive strips 2 on the plate χ. To prevent contact and mechanical damage to the gold electrodes 6 on both the glass plates X and χ, a thin strip defining the foil 8 is inserted between the two plates X and X. The two plates χ, X are glued together with sealant or glass solder. four wires in total. The conductor 10 is led out of the gold top electrode 6 belonging to the glass plate X and the conductor 12 is led out of the gold top electrode 6 belonging to the glass plate χ. The conductor 11 is led through the connector from the lower electrode warp of the transparent conductive strips 2 belonging to the glass plate χ, and the conductor 13 is also led out of the lower electrode warp of the transparent conductive strips 2 belonging to the glass plate χ. Between conductors 10 and 11. as well as 12 and 13, a voltage of 70-180 V) is applied according to the technology and layer thickness of the assembly. After applying voltage, a line lights on each glass plate X and χ. The two lines are perpendicular to each other, since the electrode warp of transparent conductive strips 2 applied to the glass plates X and X is perpendicular to each other. The brightness of the perpendicular illuminated strips is not

244 064 is exactly the same since the strip that is illuminated on the rear glass plate with respect to the viewing direction always has greater light loss due to light absorption in both the gold electrode itself and the gold electrode of the first plate in the viewing direction. This drawback is eliminated by applying lower stresses to the first plate from the viewing side than to the second, rear plate. By switching the voltage on the wires 11 and 13, the position of the glowing orthogonal lines can be changed. By switching multiple positions on the wire 11 and 13, any network of orthogonal lines can be obtained.

The entire display can be connected to a computer that can control and evaluate the display.

Claims (1)

An electroluminescent viewing orthogonal graphical display consisting of two glass panes with vacuum deposited opaque layers, characterized in that the two glass panes are sequentially provided with conductive strips of tin oxide SnOg or indium oxide IngO2, on which a yttrium oxide Y2 layer is deposited. ° 3 ⁰ thickness will 200-600 nm, the layer of zinc sulfide ZnS activated 1-5% by weight Mn of thickness 500-1500 nm, on which a layer of yttria Ϊ £ θ3 ⁰ tloušŽce 200 to 600 nm, and A layer of gold Au having a thickness of 3.0 to 9.0 nm, the two glass plates being bonded together on the side of the layers and perpendicular to the conductive strips of tin oxide.