RU2239254C1 - Gas panel - Google Patents

Abstract

FIELD: electronic engineering; displays built around gas panels.

SUBSTANCE: proposed gas panel has two insulating plates and pixels formed at intersection points of wire anodes and cathodes made of lengthwise truncated wire. Anodes and cathodes are disposed on insulating plates in easy-melting glass layer; easy-melting glass surfaces are disposed in same plane as effective surface of electrodes formed as result of wire truncation. Wire electrodes are secured in precisely chosen positions on substrate.

EFFECT: enhanced operating reliability, eliminated impact of adjacent wire electrodes on each other.

1 cl

Description

The invention relates to electronic equipment and can be used to create indicator devices on gas discharge indicator panels (GUI).

Known GUI, including two glass plates, each of which is pressed into a system of parallel wire electrodes, display cells formed at the crosshairs of the wire electrodes of the two systems. [s. Germany No. 1764927, 21f-85, 1970].

The disadvantage of this design is that the wire electrodes in the process of manufacturing the GUI are deformed and displaced. In addition, to facilitate the insertion of wire electrodes, the glass plates are heated, as a result of which they become opaque and reduce the brightness of the glow of the display cells. Due to the small area of the working surface of the wire electrodes, the ISU display cells also have a large statistical delay time for the discharge ignition.

Known GUI, containing two dielectric plates forming the display cells, two intersecting electrode systems, the electrodes of one of which are made of wire fixed in a layer of low-melting glass (LPS), the thickness of which is 1/2 of the diameter of the wire. [s. Germany No. 4121878, H 01 J 17/49, 1992).

The disadvantage of this GUI is that the wire electrodes protrude from the LPS layer, therefore, in the display cells, a discharge can burn between adjacent electrodes on their side surfaces.

Closest to the claimed design is a GUI containing two dielectric plates, an LPS layer deposited on the inner surface of one or two dielectric plates, indication cells formed by two intersecting systems of parallel electrodes, and the electrodes of one or two electrode systems are located in the LPS layer, respectively, of one or two dielectric plates [h. Germany No. 2229741, 21f-85, 1972 - prototype].

The disadvantage of this design is that despite the presence of LPS coating on the lateral surfaces of the tape electrodes, its thickness is insufficient for reliable isolation of the side surfaces of the tape electrodes from each other. In addition, the application of LPS on the side surfaces is carried out by pressing tape electrodes into the LPS layer deposited on a dielectric plate or on a non-working surface of the plate. The inaccuracy of this operation leads to LPS getting on the working surface of the tape electrodes, to incomplete insulation of their side surfaces, as well as to the deformation of the tape electrodes. In addition, the presence of communication channels formed by indentation of tape electrodes in LPS makes it difficult to form additional GUI elements - a phosphor, dividing elements with a high degree of accuracy.

The objective of the invention is to create a GUI with wire electrodes with high reliability by increasing the accuracy of fixation of the wire electrodes on the substrate and eliminating the mutual influence between adjacent wire electrodes.

The indicated technical effect is achieved by the fact that in the known GUI containing two dielectric plates, an LPS layer deposited on the inner surface of one or two dielectric plates, indication cells formed by two intersecting electrode systems, the electrodes of one or two systems being located in the LPS layer, respectively, of one or two dielectric plates, the electrodes located in the LPS layer are made of a wire truncated along the length, the surface formed after the wire truncation forms a working the surface of the electrodes and is located in the same plane with the surface of the LPS layer.

The implementation of the GUI electrodes from a truncated wire along the length of the wire and its location in the LPS layer so that the surface formed after the truncation of the wire is in the same plane as the surface of the LPS layer made it possible to increase the accuracy of fixation of wire electrodes and exclude the mutual influence of neighboring electrodes, while using the surface formed after truncation of the wire, as the working surface of the electrodes, provides a low and stable statistical delay time for the ignition of the discharge in the ISU. In addition, the advantage of this design is that the working surface of the wire electrodes and the surface of the LPS layer are located in the same plane, forming a single surface on which it is possible to form additional structural elements of the ISU, such as a phosphor, dividing barriers with a high degree of accuracy, ensuring uniformity of illumination indication cells.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, and the identification of sources containing information about analogues of the claimed invention, allows us to establish that the applicant has not found an analogue characterized by features identical to those of the claimed invention, and a definition from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed to identify the set of essential in relation to the applicant to technical result of the characterizing features claimed in the object set forth in the claims.

Therefore, the claimed invention meets the requirement of "novelty."

To verify the conformity of the claimed invention to the requirement of the inventive step, an additional search was carried out for known solutions in order to identify features that match the distinctive features of the claimed invention from the prototype, the results of which show that the claimed invention does not explicitly follow from the prior art, as it does not identified technical solutions in which accurate fixation of wire electrodes on the substrate would be achieved and interaction between osednimi wire electrodes in the GUI by performing on them from the truncated length of wire immersed in LPS to the level of the surface formed after truncation, which is the working surface of the wire electrode providing a low level of statistical discharge delay time of ignition.

Thus, the claimed invention meets the requirement of "inventive step".

The drawing shows one of the options for the GUI. The ISU contains two dielectric plates - upper 1 and lower 2, indication cells 3, formed at the crosshairs of wire anodes 4 and cathodes 5, truncated along the length and located respectively on the lower 2 and upper 1 dielectric plates in the LPS layers 6 and formed on their inner surfaces 7, the surfaces of which lie in the same plane with the surfaces 8, 9 of the wire electrodes located in them, dielectric barriers 10, bounding the display cells. ISU filling is a mixture of inert gases.

The ISU works as follows.

When voltage pulses are applied to the corresponding wire anodes 4 and cathodes 5, gas discharges occur in the display cells 3, the glow of which displays information.

When the GUI is operating, there is no large variation in the control voltages and brightness of the glow of the indication cells.

The implementation of the electrodes from a truncated length of the wire allows you to form the working surface of the anodes and cathodes on a flat surface bounded by LPS, as a result of which the statistical delay time of the discharge ignition in the display cells is reduced and stabilized. As shown by the results of experimental studies, it is advisable to use a wire truncated along the length of 0.25-0.75 diameter. In this case, the statistical delay time of the ignition of the discharge does not depend on the working area of the electrodes and has a minimum value.

An example of a specific implementation.

The ISU contains the upper and lower glass plates measuring 484 × 484 × 5 mm, on the inner surface of each of which is applied a layer of LPS-C82-3 with a thickness of 0.09 mm. Anodes and cathodes made of 47ND wire with a diameter of 0.12 mm, truncated by 1/4 of the diameter of the wire, are located in the LPS layers corresponding to the anodes and cathodes of the glass plates.

The surface formed after truncation of the wire 47 ND is the working surface of the anodes and cathodes and lies in the same plane as the surface of the LPS layer in which these electrodes are immersed.

The width of the working surface of the anodes and cathodes is 0.104 mm.

Dielectric barriers with a width of 0.4 and a height of 0.22 mm are formed between the cathodes on the LPS layer, which determines the magnitude of the interelectrode (anode-cathode) gap. The spread in the application of dielectric barriers is not more than 5% of their height.

It is filled with HIP Ne + 15% Xe at a pressure of 110 mm Hg.

This ISU reliably operates in control mode, which is ensured by high accuracy of fixing of wire anodes and cathodes, reliable isolation of their side surfaces, and the formation of the working surface of cathodes and anodes on the surface formed after truncation of the wire. The statistical time of the ignition delay of the discharge in the display cells of this ISU is two times less than in the ISU with conventional wire electrodes.

Thus, the proposed invention allows to obtain a GUI with wire electrodes with high reliability.

Claims (1)

A gas-discharge indicator panel containing two dielectric plates, a layer of fusible glass deposited on the inner surface of one or two dielectric plates, indication cells formed by two intersecting systems of parallel electrodes, the electrodes of one or two systems being located in the layer of fusible glass, respectively, of one or two dielectric plates characterized in that the electrodes located in the layer of low-melting glass are made of a truncated wire along the length of the surface which, formed after truncation, serves as the working surface of the electrodes.