DE2457749C2 - Gas discharge indicator - Google Patents

Description

characterized in that the control circuit (100, 110, 120, 130/4, 130S, 130Q applies voltage to the cathodes (50/4, 50fl, 50Q) one after the other during repetitive scanning processes, and at the beginning of each scanning process to the anode (90) applies a signal with a duration which corresponds to the amplitude of the analog signal to be displayed

2. Gas discharge display device according to claim 1, characterized in that the control circuit (100, 110, 120, 130/1, 1305, 130Q controls the cathodes (50Λ 5OS, 5OQ via several busbars (60/4, 60ß, 6OQ) which are cyclically connected alternately to the successive cathodes (5oA, 50 B, 5OQ.

3. The gas discharge display device according to claim 2, characterized in that each third cathode (50/4, 50Ö, 5OQ located respectively on a w common bus conductor (60 / 4,60S, 6OQ.

4. Gas discharge display device according to one of the preceding claims, characterized in that the control circuit (100, 110, 120, 130/4, 1305, 130Q controls all cathodes (50A, 50B, 50C) one after the other during each scanning process.

The invention relates to a gas discharge display device for displaying analog signals in the form of a luminous strip of variable length, consisting of a housing containing ionizable gas with a strip-shaped window, several is cathodes that are essentially parallel to each other in the housing on an insulating base plate at a predetermined distance Area of the window are arranged, an anode at a predetermined distance from the cathodes, a control circuit that controls the cathodes wi and the anode in such a way that starting from a first cathode ignite the following cathodes and the glow discharge of all previously ignited cathodes is maintained as long as there is an electrical signal at the anode. ^h ~>

Cinema such Gascntladungs- display device is known from US-PS 32 83 204, in which several adjacent parallel cathodes on a resistor cluster so that there is a given partial resistance between two adjacent cathodes. To operate this gas discharge display device, the input terminal of the resistance element the analog signal to be displayed is supplied, and the output terminal of the resistance element becomes connected to ground - The voltage difference between the cathodes and the anode is therefore corresponding to the Potential distribution formed along the resistance element. Those cathodes that go to the anode have a voltage difference above a specified ignition threshold value, they are all ignited subsequent cathode fingers, whose voltage difference to the anode is below the ignition threshold value, are not ignited

A disadvantage of this known gas discharge display device it is that the ignition threshold also depends on the degree of ionization of the gas, on the glow discharge pressure and, for example, also depends on the homogeneity of the resistance element, so that the actually ignited number of adjacent cathodes except for the applied analog signal also depends on these parameters.

In contrast, the object of the invention is to provide a gas discharge display device of the type mentioned at the beginning Art to develop in such a way that the length of the ignited gas discharge path is proportional to the is the current value of the measured variable to be displayed.

This object is achieved according to the invention in the case of the gas discharge display device of the type mentioned at the beginning solved in that the control circuit the cathodes during repetitive scanning operations consecutively applies voltage, and at the beginning of each scanning process to the anode a signal with a Time period that corresponds to the amplitude of the analog signal to be displayed.

The advantages of the invention are in particular that the substantially parallel to each other Cathodes are activated one after the other within each scanning process, and that the anode is closed An electrical signal is applied to the beginning of each scanning process, the duration of which in each case is proportional to the current amplitude of the analog signal to be displayed. The number of during each Scanning process ignited cathodes corresponds in this way to the duration and thus to the momentary Amplitude of the analog signal to be displayed. A dependency on the actually existing glow discharge pressure or the degree of ionization is largely eliminated.

Advantageous further developments of the invention are characterized by the features of the subclaims.

In the following, exemplary embodiments of the invention are explained in more detail with reference to the drawing.

F i g. Fig. 1 is a plan view of a first embodiment of the gas discharge display device.

F i g. Figure 2 is a section taken along line 2-2 of Figure 2. 1; and

Fig. 3 is a plan view of a second embodiment the gas discharge display device.

A gas discharge display device 10 has in generally elongated rectangular shape and includes an insulating base plate 20 made of glass, Ceramic or the like. And a front plate 30 made of glass or the like. Which forms a window for the display panel. the Base plate 20 and the front plate 30 are along a

given circumferential line with the help of a glass frit hermetically welded together.

The base plate 20 has an upper edge 22 and a lower edge 24 as well as a left side edge 26 and a right side edge 28. On the front of the base plate 20 is a light-absorbing, opaque, preferably black insulating layer 44 which is provided around a to enable as high-contrast a display as possible. A series of short, closely spaced parallels Leads form cathodes 50A, 50β and 50OC and are on the insulating layer 44 preferably by means of one Screen printing process applied. The lines 50A, 50ß and 5OC are so close together that your Use the glow light from one cathode as the cathode with the glow light from the neighboring cathode merges you own z. B. a width of 0.25 to 03 mm, their distances from each other are 0.125 to 0.2 mm.

In the embodiment shown, the cathodes 50A, 50B and 50C are arranged perpendicular to the longitudinal axis of the base plate 20 and are connected to one another in groups, the cathodes 50A, 50β and 50C in each case forming separate groups. In each case two cathodes 50A are separated by cathodes 50OB and 50OC, furthermore two cathodes 50β are separated by cathodes 50A and 50OC and two cathodes 50OC are separated from one another by cathodes 50A and 50β.

All cathodes 50A are connected to a single common first busbar 6OA, which runs parallel to the longitudinal axis of the base plate 20 up to the lower edge 24, where it ends in a first contact plate 70A. In a similar way, the third cathodes 5OC are connected to a common third busbar 6OC, which ends in a third contact plate 70C at the lower edge 24 of the base plate 20. An insulating layer 80 covers the first bus bar 60a, with openings 84 each over the cathode 50 β. A single busbar 60β is arranged on the insulating layer 80, which is in contact with the cathodes 50β and terminates in a second contact plate 70S. Insulation 80 '(FIG. 2) covers the second bus bar 60 [deg.].

A similar further insulating layer 83 is over the third bus bar 6OC and portions of the cathodes 5OC arranged. The insulating layer 80 and the similar further insulating layer 83 have such a distance that that a piece of the desired length from cathodes 50A, 503 and 50C is visible between them. The pieces of these cathodes 50A, 50β and 50C drawn as thick black lines in Fig. 1 are those Parts that light up when the gas discharge display device 10 is in operation.

The gas discharge display device 10 also contains an auxiliary cathode 5OR, which is arranged parallel to the first cathode 50A of the row and adjacent to it. The auxiliary cathode 50 /? is connected to a contact pad 7OR and is scanned on before the adjacent first cathode 50A to provide ionized particles which ensure that the first cathode 50A will ignite when electrically energized. Furthermore, the gas discharge display device 10 contains an exciter cell 85 with a small surface anode 50KA and a small surface cathode 50KK, which are arranged in the vicinity of the lower edge 24 of the base plate 20 and connected to terminals (X) KK and 60AvA. The flat anode 50XA and the flat cathode 50KK of this excitation cell 85 are arranged in close proximity to the auxiliary cathode 5OR in order to continuously supply excited particles for them. Usually they are

ί Flat anode 50 / CA and flat cathode 50KK connected to a voltage source V and constantly switched on so that they continuously supply the excited particles.

The front plate 30 of the gas discharge display device 10 contains on its underside a transparent conductive film 90 as an anode, which consists of NESA or the like and is designed as a rectangular strip that extends from the upper edge 22 to the lower edge 24 of the gas discharge display device 10 extends and lies over the visible parts of the cathodes 50A, 50β and 5OC. The anode 90 also cooperates with the auxiliary cathode 5OR .

If necessary, covers can be provided to protect the exciter cell 85 and the auxiliary cathode 507? shield from sight. These covers can be arranged as an opaque layer on the window plate or mechanical shields can also be provided inside the display panels.
The base plate 20 and face plate 30 of the gas discharge display device 10 are spaced apart on the order of 0.5 to 0.63 mm, and the gas in the gas discharge display device 10 has a pressure on the order of 400 Torr. The gas filling can, for. B. a gas mixture with 99.8%

contained in neon and 0.2% xenon. It can also be pure Neon can be used as a gas filling. With this dimensioning of the gas pressure and the distance between the base plate 20 and the front plate 30 can when turning on the cathodes 50A, 50β and 50C and the

υ anode 90 the cathode glow to the immediate Neighborhood of each turned-on cathode 2 can be restricted even if the cathode 2 is in Groups are connected, and as the glow progresses from cathode to cathode, none results

• to annoying glow in undesired places. this has Its reason is that the ionized particles including those that are in the metastable State, are limited in their diffusibility and by the closely spaced base plate

■> 5 20 and front panel 30 are neutralized.

A suitable control circuit for operating the gas discharge display device 10 is shown schematically shown in FIG. 1 and contains a signal source 100 for the analog signal to be displayed, which is sent to a

'· (> Differential amplifier 110 is connected to that too a control voltage is supplied from a signal source 120. Separate cathode amplifiers 130A, 130ß, 130C are connected to each group of cathodes 50A, 50ß and SOC via one of the associated cathode plates.

5 'th 70A', 70β and 70C connected and are therefore connected to one of the common busbars 6OA, 60ß and 6OC in connection. Furthermore, another cathode amplifier 130D is connected to the auxiliary cathode 707? connected, and the voltage source V is between the

bo surface cathode 50KK and the surface anode 50XA of the exciter cell 85. When a gas discharge display device 10 connected in this way is operated, the exciter cell 85 continuously supplies excited or ionized particles, and when a scanning process starts, the next

t> 5 cathode amplifier 130D active, so that it supplies an operating potential to the auxiliary cathode 5OR and causes it to glow and to supply excited particles. Then the operating potential is passed to each

of the other cathodes 504, 50 ß and SOC are laid sequentially through the cathode amplifiers 130A, 130S and 130C, starting with the first cathode 50/4 near the auxiliary cathode 50R. At the same time, the anode 90 is supplied with an electrical signal from the output of the differential amplifier 110. As long as an output voltage is supplied from the differential amplifier 110, the ignition of the cathodes 504, 50β and 504 from the first cathode 504 at the beginning of the row continues along the row until the analog signal and the control signal, which has a rising profile, are equal. At this point in time, the differential amplifier 110 no longer supplies an output voltage and the anode 90 is switched off. The row of cathodes 504, 50β and 5OC is however energized to the end in order to \; ensure that the same scan occurs every time cathodes 504, 50β and 50C are ignited. During this scanning process, the cathodes 504, 50β and 50C glow up to a point within the cathode row, which depends on the size of the analog signal and thus on the length of time during which the anode 90 is energized. The cathodes 504, 50 [beta] and 50 [beta] in this way produce a glowing strip, the extent of which corresponds to the amplitude of the analog signal. This scanning process is repeated cyclically at such a rate that strips of various lengths appear on the gas discharge display device 10.

Other control circuits can also be used to operate the gas discharge display device 10. For example, a digital clock, which is controlled by the analog signal can be used to drive the cathodes 504, 505 and SOC of the series to turn on and to simultaneously energize the anode 90 to J5. When the analog signal stops, the Anode 90 switched off in order to extinguish the cathode glow in the manner described above bring.

In a modified embodiment according to FIG. 3, the gas discharge indicator 10 includes two Rows of cathodes 504, 50Ö and 5OC, one of which on each of the opposite long sides the base plate 20 is arranged. As in the case of the gas discharge display device 10 according to FIG. 1 and 2, the cathodes 50A 50β and 5OC are divided into groups, with the first cathodes 504 having a common first busbar 604 are connected.

which runs around the circumference of the base plate 20 and ends in a first connection plate 704, while the second cathodes 50β are connected to one another via the base plate 20 and are connected to a common second conductor 60S and to a second connection plate 70S. The third cathodes 50C, which are in communication with each other through the base plate 20, are connected to a common third busbar 60C and a third terminal plate 70C. With the aid of a screen printing process, the various cathodes 504, 50 [beta] and 5OC and their bus bars 604, 60 [beta] and 6OC can be produced simultaneously and from the same material. As in the example above, insulating layers 140 are provided to separate the second cathodes 50β from the first cathodes 5OC and to cover the cathodes 504, 50β and 5OC and two rows of cathodes 504, 50β and 50C of appropriate length along the longitudinal sides of the base plate 20 to manufacture. In this case, the front plate 30 has two layered anodes 90, one of which each covers a row of cathodes 504, 50 [beta] and 50 [deg.]. In addition, the front plate 30 can be provided with an opaque layer (not shown) in order to make only a desired section of the cathodes 504, 50β and 50C visible and to e.g. B. the auxiliary cathode 50 R, which is next to the first cathode 504 and to cover the exciter cell 85, including the two flat cathodes 50KK and the two flat anodes 50AK, which are in the vicinity of the two auxiliary cathodes 50 /? are arranged.

The gas discharge display device 10 according to Figure 3 is essentially in the same way operated like the gas discharge display device 10 according to FIG. 1 and 2 and gives two corresponding Stripes of light that correspond to an analog signal.

The construction of the gas discharge display device 10 can be modified according to the purpose of use will. For example, it is possible to place the anodes 90 on the faceplate 30, or they can be arranged on one of the insulating layers of the base plate 20. The anodes 90 '(after Fig. 3:90) are z. B. indicated in dashed lines on the layers 80 'and 83 in Fig.2. In addition, a single Exciter cell 85 in the gas discharge display device 10 according to FIG. 3 may be provided, which are so arranged is that they have excited particles for the two ignition electrodes supplies.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: L gas discharge display device for displaying of analog signals in the form of a luminous strip of variable length, consisting of a housing containing ionizable gas with a strip-shaped window,
several cathodes, which are arranged in the housing on an insulating base plate at a predetermined distance essentially parallel to one another in the area of the window, an anode at a predetermined distance from the cathodes, a control circuit which controls the cathodes and the anode so that of one starting with the first cathode, ignite the following cathodes and the glow discharge of all previously ignited cathodes is maintained as long as one is connected to the anode there is an electrical signal,