RU2069410C1 - Gas-discharge data display indicator for composition screens - Google Patents

Abstract

FIELD: indication devices technology; production of array indicators. SUBSTANCE: gas-discharge data display panel has the first transparent and lower dielectric plates, between which the inversely perpendicular electrode systems ( anodes and cathodes) are disposed in gap. Anodes and cathodes form array assembly of cells. There vertical rectangular partitions. Phosphor layer is applied onto lower dielectric plate. Top transparent dielectric plate is made with variable perimeter of edge surface, depth of which in relation to the edge is equal to width of the partition filled with sealing material. EFFECT: reduced distortions of images; stability of edge surface of the panel. 2 dwg

Description

 The invention relates to techniques for indicating devices and can be used to create matrix indicators for typesetting screens, in particular, when creating matrix gas-discharge indicators that ensure joining of panels entering the screen without compromising image quality.

 Known gas-discharge indicator panels containing two dielectric plates, one of which is transparent, and a phosphor layer is deposited on the other. A gap (plasma discharge gap) is formed between the plates, in which there are two groups of mutually perpendicular electrodes (cathodes and anodes) that form a matrix of cells to which voltage is supplied through the control device from the source. At the same time, the end parts of the plates are sealed, forming a gas tight seal in the form of a seam around the entire perimeter of the panel (see Japanese application N 3-34177, class N 01 J 9/02, 17/34, publ. 27.05.86; ed. USSR N 1593499, class N 01 J 17/49, publ. 1992 application EPO N 382260/90, class E 01 J 17/49, publ. 1990; US patent N 3900752, class 313/188, publ. 1975 ) However, when assembling such panels into a dial screen, it is difficult to ensure the accuracy of their joining due to differences in the seam thickness of individual panels, i.e. instability of the dimensions of the panels. As a result, in the assembled screen, the panels are offset from each other and, as a result, the quality of the initiated image deteriorates due to the occurrence of intersecting stripes where there is no image, and the displacement of individual parts of the image at the junction of the panels.

где lср поперечный размер некрайних индикаторных ячеек в направлении, перпендикулярном соответствующему шву герметизации, м,
h_шва толщина шва герметизации, м,
h_пер ширина перемычки между электродами, м
Однако выполнение прилегающих к шву герметизации ячеек увеличенного размера в направлении, перпендикулярном шву герметизации, усложняет технологию изготовления устройства. Кроме того при стыковке таких панелей возникает "мозаичность" изображения на границах панелей, что улучшает восприятие изображения.Known gas discharge indicator panel (ed. Certificate. USSR N 15005321, class N 01 J 17/49, publ. 1992), selected for the prototype, containing the upper transparent and lower dielectric plates connected by a sealing seam around the perimeter, electrode systems located between them forming indicator cells in the crosshairs, characterized in that to improve the quality of reproduced information in the peripheral region of the sealing joint by reducing the unevenness of the image brightness of the indicator cells adjacent to the sealing cell made of increased size lcr. in the direction perpendicular to the sealing joint, in accordance with the inequality

where lav the transverse dimension of the non-edge indicator cells in the direction perpendicular to the corresponding sealing joint, m,
h _{seam the} thickness of the sealing seam, m,
h _lane jumper width between electrodes, m
However, the execution of oversized cells adjacent to the sealing seam in the direction perpendicular to the sealing seam complicates the manufacturing technology of the device. In addition, when docking such panels, a “mosaic” image occurs at the borders of the panels, which improves the perception of the image.

 The objective of the invention is to reduce the "mosaic" in the image that occurs at the borders of the panels when they are docked in the screen and ensuring stable dimensions of the end surface of the panel.

 The solution to this problem is provided in a gas-discharge indicator panel containing the upper transparent and lower dielectric plates, between which a gap is formed, in which there are placed systems of mutually perpendicular electrodes forming the matrix system of cells, while a phosphor layer is deposited on the lower dielectric plate, and the electrode systems are connected to a control device associated with a voltage source, the differences of which is that between the dielectric plates there are vertical rectangles partitions, and the upper dielectric plate is sampled along the perimeter of the end surface with a depth relative to the end face, commensurate with the width of the partition filled with sealing material.

 The execution of the sealing shell in the sample along the perimeter of the end surface of the upper plate maintains the dimensional stability of the joined part of the panel, since the sealing joint in this case has practically no effect on the accuracy of the joint. In this case, the introduction of partitions and the choice of sampling depth commensurate with the width of the partition ensures the "continuity" of the image when joining the panels and eliminates the "mosaic" at their borders, since the commensurability of the width of the partition with the thickness of the seam minimizes image perception. In this case, the width of the seam is significantly less than the size of the luminous cell of the panel and does not affect the image quality. In this case, there are no additional difficulties in the manufacture of the proposed panel.

 The proposed design of a gas discharge display panel is illustrated by drawings, where in FIG. 1 shows the appearance of the panel in a perspective view with a 1/4 cut-out, in FIG. 2 shows the execution of the sample and the sealing shell in it.

 In accordance with FIG. 1 panel contains an upper transparent 1 and lower 2 dielectric plates, between which a gap 3 is formed. As an example, vertical rectangular partitions 4 are located along the entire length of the lower 2 dielectric plate, and a phosphor layer 5 is deposited on the lower 2 dielectric plate between the partitions. Moreover, as an example, the first group of electrodes 7 (cathodes) is located above the phosphor layer 5, and the second group of electrodes 6 (anodes) is located above the first group of electrodes 7, forming a gap between the groups of electrodes. At the same time, a sample 8 is made along the perimeter of the end part of the upper transparent plate 1, filled with a sealing material 9, which can be used as fusible enamel glasses or vacuum adhesives. In this case, the coefficient of thermal expansion of the weld material should be chosen close to the coefficient of thermal expansion of the dielectric plates. The formed matrix system of electrodes 6 and 7 is connected via a control device to a voltage source (the latter are not shown in the drawing). The sampling depth 8 is selected commensurate with the width of the partition.

 Sample 8 with sealing material along the perimeter of the end surface of the upper plate 1 is shown in FIG. 2, and a general view of the panel in a perspective view, which also shows the execution of sampling 8, is shown in FIG. 1.

 The panel is as follows. To output information between the first 7 and second 6 groups of electrodes (cathodes and anodes) a voltage is applied above the voltage of the occurrence of the discharge in the display cell. The result is a breakdown of the gas gap 3, after which the voltage on the cells decreases to the voltage to maintain the gas discharge. Ultraviolet radiation (UV) discharge excites phosphor 5, providing its glow. As a result, we perceive the total brightness of the glow of the cell and phosphor.

 Further, the process is repeated after time T (period). The reduction and stabilization of the delay time of the ignition of the discharge is achieved due to the emission of electrons from the anode into the gas-discharge gap.

 When implementing the proposed device, sampling can be carried out by known methods, for example, a diamond grinding wheel, and then fill the sample with a sealing material, for example, by pouring or using a "syringe", a spatula or other known method. It should also be noted that when the groups of electrodes are arranged, they can be interchanged and, in addition, one group of electrodes can be located directly on the transparent dielectric plate. Partitioning is carried out by the traditional method.

As a control device, for example, a device can be used (see M. I. Krivosheev collection "Television methods and information display devices", article. A. M. Stolyarova "Displaying information on gas-discharge indicator panels" M. ed. "Sov. radio ", 1975, A. A. Borisyuk" Matrix information display systems ", Kiev, publishing house" Technique ", 1980, F. I. Yablonsky" Gas-discharge devices for displaying information ", M. publishing house" Energy ", 1979)
The voltage source can be a source giving a voltage of 400 V, or ± 200 V with a midpoint.

Claims (1)

 A gas discharge indicator panel for type-setting screens, comprising an upper transparent and lower dielectric plate, between which a gap is formed, in which systems of mutually perpendicular electrodes forming a matrix system of cells are placed, a phosphor layer is deposited on the lower dielectric plate, and an end seam is made along the perimeter of the plates sealing, characterized in that in the gap between the plates are placed rectangular partitions, the upper dielectric plate is made with a selection around the perimeter the front surface with a depth relative to the end of not more than the thickness of the extreme vertical partitions, and the lower dielectric plate is smaller by the depth of the sample than the maximum (overall) dimensions of the upper transparent dielectric plate.

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