NO129764B - - Google Patents

Description

Display device.

This invention relates to display devices or panels of the type comprising large numbers of gas-filled cells arranged in rows and columns and which can be energized in groups to display or present a sign or a message. Generally speaking, such devices comprise at least two electrodes, an anode and a cathode for each cell and a separate drive circuit for each cathode and each anode to apply to these the voltages necessary to switch on each cell and produce visible light or glow in this.

Although such panel devices can work satisfactorily in this way, it will be seen that in a panel comprising thousands of cells, the arrangement of a separate drive circuit for each cathode

and each anode be prohibitively expensive and complicated.

An improved display has previously been proposed

panel with drive device which means financial savings in the drive circuits. in this improved arrangement, selected cathodes share common drive elements or devices and the display cells are scanned and lit column by column from left to right. This scanning operation is repeated periodically and different cell selection operations can be performed during the scanning operation as desired.

To ensure correct operation during the scanning period, a column is arranged with start or particle supply cells -

hereinafter also referred to as auxiliary cells - near the first column of display cells. When the scan reaches the right end of the panel, the column of auxiliary cells is energized and the scan period is repeated. however, under certain circumstances the auxiliary cells will not be fired and the scan operation cannot be performed as required.

The state of the art can be considered represented by the US patents

No. 2,847,615 and No. 2,984,765 and German Explanatory Document No. 1,026,869. However, these do not show the use of auxiliary cells with low ignition voltage that produce metastable particles (ions and electrons)

which then communicates with cells of small dimensions through gas connection paths to enable easier ignition of individual cells in any X/Y cell array.

The present invention provides a display panel comprising a plurality of gas-filled display cells and a group of auxiliary cells to facilitate the operation of the display cell. The auxiliary cells are specially driven and/or designed to ensure correct ignition and operation. This is achieved by means of the new and distinctive features set out in the patent claims.

The invention will be explained in more detail below with reference to the drawing, where fig. 1 is a view of a display panel according to this invention seen from above. Fig. 2 is a section along the line 2-2 in fig. 1 and shows part of the panel.

Fig. 3 shows the panel of fig. 1 schematically together with an electronic system in which the panel works. Fig. 4 is a section along the lines 4-4 in fig. 1. Fig. 5 is a perspective view of a modification of one of the electrodes in the display panel according to the invention. Fig. 6

is a side view of a modification of the electrode of FIG. 5. Fig. 7

is a perspective view of another modification of the electrode of FIG.

5, and fig. 8 is a perspective view of a further modification of the electrode of FIG. 5.

It will be understood that the display panel as described here can have essentially any desired size and shape and that it can comprise essentially any number of display cells. The panel can also comprise any suitable ionizable gas: such as neon, argon, xenon etc., either alone or several of these in combination. A metal, e.g. mercury, is also usually included in the gas to reduce cathode sputtering to a minimum. In addition to the above, the following description of the operation according to the invention will take place with reference to scanning from cell to cell or annealing transfer from cell to cell. The meaning of this must include either that annealing in one cell is actually transferred from an ON cell to an OFF cell and the OFF cell is thereby turned ON, or that annealing in one cell produces excited particles and metastable atoms that diffuse from an ON cell to an adjacent OFF cell and can be used to facilitate ignition and ON switching of the adjacent cell.

A gas-filled display device 10 according to this invention may have the form of a flat panel and may comprise a layered structure of flat plates comprising a middle plate 20 of glass or ceramic, a top or viewing plate 30 of glass (removed in Fig. 1), and a bottom plate 40 of glass or ceramic. The center plate 20 is provided with rows and columns of holes or cells 50, and it has a top surface 60 and a bottom surface 70. The cells 50 act as information display cells and are filled with a gas of the type that can maintain cathode- annealing. The display cells 50 preferably have identical size and shape.

The device 10 is provided with an upper set of parallel electrodes 80 and a lower set of parallel electrodes 100, which sets are perpendicular to each other and are so arranged that each cell has two electrodes, one at the top of the cell and one at the bottom of the cell. The two electrode parts assigned to each display cell 50 are preferably identical from cell to cell, both mechanically and electrically. A cell 50 is ignited and made to glow by applying suitable voltages to the electrodes 80 and 100 which cross each other in the cell in question. In the following description, the upper electrodes shall be regarded as anodes, and the lower electrodes as cathodes, and likewise in this description the device 10 shall be oriented so that the anodes are row electrodes and each of these is arranged with a row of cells, while the cathodes are columnar electrodes and each is arranged with a column of cells. Of course, the electrode functions can also be the reverse of this. ... The electrodes "80 and 100 can be "flat metal strips or they can have the form of wires and. they can be inserted into slots or recesses either in the middle plate or in the top or bottom plate as desired. strips, be provided with holes 90 where they lie above the cells 50, to allow a glowing or lit cell to be seen by an observer looking through the top plate 30 when the device 10 is operating. The upper electrodes 80 are, however, wires which are narrower than the cells 50 so that consideration of an annealing in the cells is possible through the top plate 30. The bottom electrodes 100, which work as cathodes, can suitably have the form of flat strips.

The center plate 20 as well as the top and bottom plates 30 and 40 of glass or the like are usually rectangular, the top and bottom plates generally being made somewhat larger than the center plate to allow a sealing material 42 (Fig. 2), such as a glass frit is placed between these to seal all the plates together into a gas-tight unit. The row and column conductors or electrodes 80 and 100 extend beyond the edges of the plates so that they can be easily connected to electrical circuits.

It is known that a gas cell that ignites and glows generates excited particles including gas ions, metastable atoms and the like. The initially mentioned patent exploits this phenomenon to sense and ignite cells and for this purpose physical gas communication slots or channels 120 are designed in the plate 20" between the display cells. In one arrangement each cell is in a column by means of a channel or slit 120 connected to the corresponding cell in the adjacent column. In this way, each column of cells is connected by slits to the adjacent column of cells, so that excited particles in any cell in a column can diffuse to the corresponding cell in the adjacent column Preferably the channels 120 are placed close to the cathodes 100.

The display panel 10 also comprises a column of auxiliary cells 52, referred to as starter cells or particle supply cells, which are used not for display, but to supply excited particles to facilitate the switching on of the information display cells 50. In one embodiment, the column is of particle-to pre-cell cells 52 located to the left of the first column of display cells 50. Each cell 52 is connected to the corresponding adjacent cell 50 in the first column through a channel 120. The cells 52 have their own column cathode 128 connected to a suitable energy source or drive circuit 161 , and they have the anode electrode 80 in common with the display cells 50. The particle supply cells 52 need not and preferably cannot be seen by an observer and can be covered by means of the upper anode electrodes which are provided for them.

The panel 10 also includes a "sustain Ises" mechanism or a source for first electrons which - as is well known in the art - is required to initiate glow or glow discharge in a gas cell. In the panel 10, this mechanism comprises eri' gas cell 123 which is placed in functional connection with the particle supply cells 52 and has its own anode 124 and cathode 125. This cell 123 is permanently energized and is constantly glowing, but is hidden as such that it cannot be seen. More than one cell 123 or a complete column of such maintenance cells may be arranged near the column of particle supply cells. In the drawing, only one cell 123 is shown and this is, for practical reasons, only shown in fig. 3.

When operating the panel in a typical scanning mode and as described in the aforementioned patent, the column of supply cells 52 is switched on or on, and then each column of display cells is switched on in sequence starting on the left side of the panel and continuing towards the right. The scanning of the panel and the switching on of each new column of cells 50 is facilitated by the availability of excited particles in the channels 120. When each cell in a column is switched on, it can have its current modulated in accordance with information in the input signal to vary the intensity of the glow. When the scanning operation reaches the right end of the panel, the period or cycle is repeated beginning with the starting cells 52, and the entire cycle may be repeated continuously at such a rate or frequency that a stationary but variable message may be displayed by the panel.

In a typical circuit for carrying out this working mode, as shown schematically in fig. 3, the cathode electrodes 100 are connected in groups, with the cathodes in each group separated from each other by a selected number of columns, as shown, to provide the necessary isolation. Each group of cathodes is connected to a drive circuit 150, and each anode electrode is connected to a drive circuit 160 with suitable synchronizing circuits 170 arranged to effect the desired sequence of operations. Of course, the drive circuits include all the current circuits that are necessary to achieve the desired operating mode. This mode is described in detail in the initially mentioned patent and therefore does not need further mention beyond what appears above.

It will be seen that in the above-described mode of operation of the panel 10, it is important that the starting cells 52 always fire to ensure correct scanning operation of the panel. In order to make the operation of the starting cells 52 as safe as possible, according to the invention, these are designed so that they have as low an ignition voltage as possible. In one arrangement to achieve this property, the electrodes in the starting cells are placed as close together as possible and this reduced mutual distance is most conveniently achieved (see Figs. 4 and 5) by forming protruding arms or protrusions on the surface of the cathode 128 180 which extends into each cell 52 towards the associated part of the cell's anode 80. The shape of each projection and its distance from the anode is adjusted to achieve

the desired ignition voltage for the cells 52 and an advantageous current density to trigger and contribute to the ignition of the adjacent cells 50.

The protrusions 180 can be located generally along the center line of the cathode 128 or along the left edge at a distance from the cells 50, as shown in fig. 5. Also, the effect of the protrusions 180 can be achieved by corrugating the cathode to form protruding portions 200, as shown in fig. 6. The protrusions can also have any other suitable shape, e.g. a rectangular shape as in fig. 5 or a triangular shape, as shown in fig. 7. In addition to this, the cathode portion to which the protrusions are attached may be of uniform width, as shown in

fig. 5 and 7, or it may be narrowed at the protrusions, as shown in fig. 8. This construction results in optimal current density on the cathode part, where it is available to the adjacent cells 50.

Of course, the desired mutual distance between anode and cathode can be provided by arranging protrusions on the anodes in the cells 52.

Regardless of whether a cathode deconstruction is used as just described or cathodes identical to those in the display cells 50 are used, i.e. with protrusions 180, a pulse source 190 (fig. 3) can possibly be connected between the anodes and cathodes that are assigned the starting cells 52, and this pulse source is used to apply a pulse of suitably high voltage to the supply cells to ensure that they start and fire at the beginning of each scan cycle during operation of the panel.

The panel 10 described here can also be used in an embodiment with several layers, as described in the initially mentioned patent.

Claims (12)

1. Display device comprising a plurality of gas-filled display cells with associated electrodes, characterized in that the display cells are designed as discrete cells (50) and are arranged in an X/Y matrix, that discrete auxiliary cells (52) are arranged, each located in flight with and communicates (120) with a number of display cells (50), that the auxiliary cells (52) are mechanically constructed in the same way as the display cells (50), but have different operating characteristics than these to facilitate their ignition, and that at least two electrodes (80, 128) are assigned to the auxiliary cells (52). 2. device according to claim 1, characterized in that the ignition voltage for the auxiliary cells (52) is lower than that for the display cells (50) 3. device according to claim 2, characterized in that the anode/cathode distance in the auxiliary cells (52) is smaller than in the display cells (50) in order to achieve a lower ignition voltage. 4. device according to claim 3, characterized in that on each cathode (128) in the auxiliary cells (52) there is arranged at least one projection (180) which extends from the cathode (128) in the direction towards the associated anode (80). 5. device according to claim 3, characterized in that at least one projection is arranged on each anode in the auxiliary cells (52) which extends from the anode in the direction towards the associated cathode, 6. device according to claim 4 or 5, characterized in that the projections (180) are designed to be largely rectangular. (Fig. 5). 7. Device according to claim 4 or 5, characterized in that the projections (180) are sharply pointed (figures 7 and 8). 8. device according to one of claims 1-3, characterized in that each cathode in the auxiliary cells (52) is corrugated and that wave crests (200) on the corrugated cathode protrude in the direction towards the anode, respectively the anodes (80). 9. device according to one of the preceding claims, characterized in that the X/Y matrix with display cells (50) is arranged in rows and columns in an insulating plate (20), that a group of first electrodes (100) is placed at the bottom surface (70) of the plate (20), with each first electrode (100) flush with a column of cells (50), and that a group of second electrodes (80) is placed at the top surface (60) of the insulating plate (20) ), with every other electrode (80) flush with a row of cells (50)„ 10. device according to claim 9, characterized in that at least one cathode (128) is assigned to the auxiliary cells (52) and that said cathode is designed as a metal strip that extends on or at the bottom surface (70) of the insulating plate (20) and lies flush with the auxiliary cells (52). 11. device according to claim 10, characterized in that the part of an electrode (128) that lies flush with an auxiliary cell (52) is designed narrower in order to increase the current density on this part when an auxiliary cell (52) is ignited (Fig. 8 ). 12. Device according to one of the preceding claims, in which drive circuits for ignition are assigned to the display cells, characterized in that a pulse circuit (190) is connected to the electrodes in the auxiliary cells (52) in order to apply ignition pulses to it during an operating cycle in the display device and to -effect dispersion of excited particles from the auxiliary cells (52) through gas connection paths (120) to the adjacent display cells (50).