DE3410876C2 - - Google Patents

Description

The invention relates to a circuit arrangement which one or several display units, each with a control anode and has a common fixed voltage anode, each with a controllable switch containing driver circuits for Control of the control anodes and the fixed voltage anodes, wherein each control anode each at the output of it individually associated driver circuit is connected, and with a Selection device for sequential activation of the drivers circuit for the control anodes.

In such a known from US-PS 38 59 559 Circuit arrangement is each display unit of a gas discharge display device with its control anode each controllable switch of a driver circuit with one for all Display units connected to common high voltage source. Each of the controllable switches is with its control input via a decoupling capacitor on a selection circuit connected to the sequential control of the individual Display units the controllable switches assigned to them controls sequentially to a conductive state so that the Control anodes of the relevant display units in succession to be connected to the high voltage source. An all common common voltage anode is a ver Resistance network with each individual with pleasure the controllable switch connected so that whenever one of the controllable switches the control anode assigned to it with the high-voltage source, also the hard voltage anode is subjected to the high voltage.

Another from "R. Saxon: Plasma’s progress: gas-discharge  technology moves into analog realm "in: Electronics, March 7th 1974, pp. 89-93 and known there in FIGS. 6 and 7 Circuit arrangement shown in two modifications Control of a gas discharge display device are flat if the control anodes of two display units via drivers circuits with controllable switches on a common High voltage source connected. In both known Circuit modifications, however, occur when driving the controllable switches in the driver circuits additional Ver pleasures on.

The above known circuitry is common that all display units have a single common High voltage source is assigned, regardless of the actual control duration of the display units required high voltage is generated so that in the high a power loss is constantly implemented, to which in the from the above-mentioned literature "Electronics" known driver circuits that are generated there Add power losses.

To generate a high voltage from a lower DC voltage is from "Dipl.-Ing. J.Wüstehube: DC voltage converter for switching power supplies "in: Electronics, 1987, No. 4, S. 102-107 and there in particular from picture 2 in connection with the footnote on page 103 discloses a flyback converter in which a controllable switch in series with a choke coil a DC power supply unit is connected and a series connection in parallel with the controllable switch a diode and a capacitor, whose connection place the high voltage output of the flyback converter. Because this flyback converter does not contain a transformer, it draws is characterized by a very simple construction, is, however, with respect to that of the above-mentioned U.S. Patent 38 59 559 known circuit arrangement for high voltage generation not to use, because with this circuit  temporarily arrange all display units by the controllable Switches are disconnected from the high voltage source, so that the flyback converter is unloaded on the output side and due to generate a constantly rising high voltage during its construction would.

The invention has for its object to control a Gas discharge display device a circuit arrangement specify which is characterized by a structurally very simple on construction in connection with a particularly low power loss recording excels.

According to the invention the object is achieved in that the circuit arrangement of the type specified each of the Driver circuits for the control anodes each as a one High voltage generating flyback converter is formed in the one inductor each in series with the controllable switch is connected to a DC power supply unit and one row scarf each parallel to the controllable switch device consists of a diode and a capacitor, the Junction of diode and capacitor the output of the respective driver circuit forms that the controllable switch each of these driver circuits with its control input on each an output of the having a clock generating device Selection device is connected to the respective Output for the duration of activation of the relevant display unit emits a pulse train, and that the fixed voltage anode as its own which also works as flyback converter and a high associated voltage generating additional driver circuit is in which also a choke coil in series with the controllable switch on the DC power supply unit is closed and parallel to the controllable switch a series connection of a diode and a capacitor lies, the connection point of diode and capacitor is connected to the fixed voltage anode and the controllable Switch with its control input at an additional one  Continuous pulse train emitting output of the selection device connected.

The main advantage of the circuitry according to the invention order consists in the low power dissipation of your Driver circuits. The reason for this is on the one hand that the driver circuits have no ohmic resistors included, which absorb power losses and convert into heat put; secondly, in the driver circuits only for Duration of driving the respective display unit a high voltage generated and the control anode of the relevant display unit supplied so that even during the activation of a Display unit of the DC power supply unit is removed. Because the additional driver circuit for the Control to ensure a clear ignition of the gas discharge paths in the display units Fixed voltage anode is constructed in the same way as the driver circuits for the control anodes of the gas discharge indicator device, the additional driver circuit also has the same advantages especially in terms of their low Power dissipation on.

Another advantage of the circuit arrangement according to the invention consists in the low component requirement of your driver circuits, if you consider the generation of high voltage in this consideration with so that the circuit arrangement economically Lich and because of the low power dissipation and the associated minimal heat emission even at the lowest Can build space.

According to an advantageous embodiment of the Invention according to the circuit arrangement it is provided that the selection direction including the clock generating device Computer contains a clock output and can be controlled for each de display unit each has a control output that each control output is assigned a NOR gate, the  Inputs with the respective control output or the Clock output of the computer are connected and its output forms the respective output of the selection device, and that the additional output of the selection device with the clock the computer is connected.

The clock output of the computer emits a pulse train, ent speaking the frequency of the choke in each driver circuit Coil for high voltage generation alternately magnetized and is demagnetized. To control the individual display the corresponding control output of the computer enters units Output signal from, so that by connecting the clock output and the respective control output of the computer via NOR gate with the control input of the assigned driver scarf device this a high voltage for the duration of the control testifies and the control anode of the display unit concerned leads. At the control input of the controllable switch additional driver circuit, however, is a continuous pulse follow, so that the additional driver circuit is a constant High voltage generated for the fixed voltage electrode.

To in cases where the gas discharge indicator via a plug connection with the circuit according to the invention arrangement is connected when releasing this connector a Danger in particular to the controllable switches and the diodes to avoid overvoltages in the driver circuits, are the driver circuits and the additional driver circuit advantageously at their respective output with another diode connected, being at the junction of the other diodes a voltage regulator working as a shunt regulator is closed. This is a particularly simple and Stabilization of the high voltage at the fixed voltage anode completely sufficient structure of the voltage regulator thereby he is enough that this one voltage divider from two cons stands, to which a further series connection from a  Transistor and a Zener diode is connected in parallel, wherein the control terminal of the transistor with the voltage tap is connected between the two resistors. As soon as the Voltage at the fixed voltage anode a predetermined value exceeds, the transistor conducts part of the Charging the capacitor of the additional driver circuit, until the voltage on the fixed voltage electrode on the pre given value decreases.

To explain in the invention is in the figure before zugtes embodiment of the circuit according to the invention arrangement with a gas discharge controllable by this display device shown.

In the exemplary embodiment shown, a gas discharge display device 1 consists of a light-band display instrument with two display units 2 and 3 , as described in the literature "Electronics" already mentioned above. Each display unit 2 and 3 consists of a large number of display segments 4 and 5 , which merge into a continuous band when viewed from a short distance. To control the length of the band section that is lit, the display unit 2 contains a control anode 6 and the display unit 3 contains a control anode 7 ; an additional fixed voltage anode 8 is assigned to the display units 2 and 3 together. The gas discharge display device 1 further includes a cathode driver circuit 9 with a control clock input 10 and a reset input 11 .

The illustrated embodiment of the circuit arrangement according to the invention contains a driver circuit 12 , the output 13 of which is connected to the control anode 6 of the display unit 2 via an anode resistor 14 . The driver circuit 12 has a controllable switch 15 , which in the embodiment shown consists of a VMOS field effect transistor and is connected in series with a choke coil 16 at the connection 17 of a DC power supply unit, not shown here, with a low DC voltage V +. The gate terminal of the VMOS field effect transistor is led out as a control input 18 of the controllable switch 15 . A series circuit comprising a diode 19 and a capacitor 20 is arranged parallel to the drain-source path of the VMOS field-effect transistor forming the controllable switch 15 . The junction of the diode 19 with the capacitor 20 forms the output 13 of the driver circuit 12 .

The circuit arrangement shown contains a driver circuit 21 of identical construction to the driver circuit 12 , the output 22 of which is connected to the control anode 7 of the display unit 3 via an anode resistor 23 . The driver circuit 21 , like the driver circuit 12, contains a controllable switch 24 consisting of a VMOS field effect transistor, the control input 25 of which is formed by the gate connection of the VMOS field effect transistor and which is connected in series with a choke coil 26 to a terminal 27 of the one not shown DC power supply unit is connected. In parallel to the controllable switch 24 , a diode 28 is connected in series with a capacitor 29 , the connection point of the diode 28 and the capacitor 29 forming the output 22 of the driver circuit 21 .

The fixed voltage anode 8 of the gas discharge display device 1 is connected via an additional anode resistor 30 to an output 31 of an additional driver circuit 32 of the circuit arrangement according to the invention. This additional driver circuit 32 , like the two driver circuits 12 and 21 described above, contains a controllable switch 33 consisting of a VMOS field effect transistor, the control input 34 of which forms the gate connection of the VMOS field effect transistor and which is in series with one Choke coil 35 is connected to a terminal 36 of the DC power supply unit, not shown. In parallel with the controllable switch 33 there is a series circuit comprising a diode 37 and a capacitor 38 , the connection point of which forms the output 31 of the additional driver circuit 32 .

In order to protect in particular the controllable switches 15, 24 and 23 and the diodes 19, 28 and 37 in the driver circuits 12, 21 and 32 against overvoltages, the outputs 13, 22 and 31 of the driver circuits 12, 21 and 32 are each via another Diode 39, 40 and 41 connected together; At the connection point 42 of the further diodes 39, 40 and 41 , a voltage regulator 43 working as a shunt regulator is connected, which contains two resistors 44 and 45 connected to a voltage divider. In parallel to the voltage divider, a field effect transistor 46 is arranged with its drain-source path in series with a zener diode 47 , the gate terminal of the field effect transistor 46 being connected as the control terminal thereof to the voltage tap between the two resistors 44 and 45 of the voltage divider.

The circuit arrangement shown also has a selection device 50 for selective activation of the driver circuits 12 and 21 , which are connected to an output 51 and 52 with the control input 18 and 25 of the display units 2 and 3 associated driver circuits 12 and 21 and is connected to an additional output 53 at the control input 34 of the additional driver circuit 32 . The selection device 50 contains a computer 54 , which has a clock output 55 as part of a clock generator and has a control output 56 and 57 for each display unit 2 and 3 of the gas discharge display device 1 to be controlled. The control outputs 56 and 57 are each assigned a NOR gate 58 or 59 , which is connected on the input side to the respective control output 56 or 57 and the clock output 55 of the computer 54 and whose output has the respective output 51 or 52 of the selection device 50 forms. Another NOR gate 60 has its inputs on the clock output 55 of the computer 54 and on a zero potential connection of the circuit arrangement and its output is connected to the additional output 53 of the selection device 50 . The further NOR gate 60 can optionally also be omitted. The computer 54 also has a control clock output 61 , which is connected to the control clock input 10 of the cathode driver circuit 9 of the gas discharge indicator 1 ; A reset output 62 of the computer 54 is connected to the reset input 11 of the cathode driver circuit 9 .

Since the gas discharge display device 1 shown together with the exemplary embodiment of the circuit arrangement according to the invention is described in detail in the abovementioned literature "Electronics", only the functional features of the gas discharge display device 1 which are essential in connection with the circuit arrangement according to the invention are explained below.

In order to operate, the gas discharge display device 1 requires a constant high voltage of approximately 230 volts at its fixed voltage anode 8 . As soon as one of the control anodes, e.g. B. 6 , an approximately the same voltage is applied, the bottom display segment 4 of the relevant display unit 2 lights up. With each control clock pulse that is supplied to the cathode driver circuit 9 at its control clock input 10 , the cathode driver circuit 9 activates the next higher display segment 4 of the relevant display unit 2 for lighting up and deactivates the previously illuminated display segment 4 below. If the cathode driver circuit 9 is supplied with a sequence of control clock pulses, the “lighting event” moves from the bottom to the top display segment 4 ; the bottom display segment 4 is then activated again by a reset pulse at the reset input 11 of the cathode driver circuit 9 . With a sufficiently high repetition frequency of the control clock pulses - for example of 50 Hz - the individual "lighting events" merge into a continuous light band. The processes take place simultaneously in both display units 2 and 3 , as long as a high voltage is applied to their control anodes 6, 7 . To control the length of the lighting portion of the light band of a display unit, for. B. 2 , are counted from each reset pulse to the control clock pulses at the control clock input 10 to a predetermined value that speaks ent the desired length of the lighting portion of the light strip; then the control anode 6 of the relevant display unit 2 is separated from the high voltage until the next reset pulse occurs, so that the remaining display segments 4 from the last light up to the top display segment 4 of the display unit 2 do not light up.

To generate the constant high voltage at the fixed voltage anode 8 of the gas discharge display device 1 , the computer 54 emits a continuous pulse sequence via its clock output 55 . The pulses are inverted in the further NOR gate 60 and fed to the control input 34 of the controllable switch 33 in the additional driver circuit 32 . The controllable switch 33 is alternately closed and opened in accordance with the frequency of the continuous pulse sequence, ie the drain-source path of the VMOS field-effect transistor forming the controllable switch 33 is alternately conductive and non-conductive. When the controllable switch 33 or the conductive VMOS field effect transistor is closed, the choke coil 35 is connected to the DC supply unit (not shown) with the voltage V +, so that a constantly increasing current flows through the choke coil 35 and magnetizes it. As soon as the controllable switch 33 opens or the drain-source path of the VMOS field-effect transistor is blocked, the inductor 35 is magnetized by charging the capacitor 38 via the diode 37 with a demagnetizing current to high voltage. This high voltage is applied to the fixed voltage anode 8 of the gas discharge display device 1 via the additional anode resistor 30 . When thereupon the controllable switch 33 closes again, the diode 37 prevents the capacitor 38 from being discharged via the controllable switch 33 , so that an almost constant high voltage is applied to the latter due to the negligibly low discharge of the capacitor 38 via the fixed voltage anode 8 .

In order to protect in particular the controllable switches 15, 24 and 33 and the diodes 19, 28 and 37 in the driver circuits 12, 21 and 32 against overvoltages, the outputs 13, 22 and 31 of the driver circuits 12, 21 and 32 are each via another Diodes 39, 40 and 41 are connected to one another, voltage regulator 43 being connected to connection point 42 of further diodes 39, 40 and 41 . The gas discharge display device 1 is namely for the driver circuits 12, 21 and 32, a load is that limits the high voltages at the outputs 13, 22 and 31 of driver circuits 12, 21 and 32 necessary for operation of the gas discharge display device 1 values. However, if the gas discharge indicator 1 is not connected to the driver circuits 12, 21 and 32 of the circuit arrangement according to the invention, the high voltages at the outputs 13, 22 and 31 of the driver circuits 12, 21 and 32 can rise to values which could destroy them the controllable switches 15, 24 and 33 and the diodes 19, 28 and 37 result. Such a voltage surge at the outputs 13, 22 and 31 of the driver circuits 12, 21 and 32 is prevented by the voltage regulator 43 working as a shunt regulator; as soon as the high voltage across at least one of the capacitors 20, 29 and 38 exceeds a predetermined value at which the voltage drop across the resistor 45 of the voltage regulator 43 exceeds the sum of the zener voltage of the zener diode 47 and the threshold voltage of the VMOS field effect transistor 46 , this will conductive and conducts part of the charge of the respective capacitor 20, 29 or 38 via the Zener diode 47 until the voltage at the respective output 13, 22, 31 of the driver circuit 12, 21, 32 in question drops to the predetermined value.

The length of the strip section along which the light strip of the respective display unit is to light up is controlled with the aid of the driver circuits 12 and 21 assigned to the respective control anodes 6 or 7 . Since the control of the two display units 2 and 3 takes place independently of one another in the same way, the control of the display unit 2 is to be explained below on behalf of the display unit 3 . If, for example, an analog measured variable is to be represented by a correspondingly long illuminating section of the light strip of the display unit 2 , a numerical value is formed in the computer 54 from this measured variable, for example by an analog / digital conversion, which represents the number of display elements 4 to be illuminated from the lowest to the uppermost still illuminating display segment 4 indicates. After each delivery of the reset pulse via the reset output 62 of the computer 54 to the reset input 11 of the cathode driver circuit 9 , the control clock pulses are subsequently counted via the control clock output 61 of the computer 54 until the numerical value derived from the measured variable is reached. In the period from the transmission of the reset pulse to reaching the numerical value, the computer 54 outputs a control signal at its control output 56 . This control signal is linked in the following the NOR gate 58 with the continuous pulse sequence emitted by the clock output 55 of the computer 54 in such a way that a pulse sequence arises at the output 51 of the selection device 50 only for the duration during which the display unit 2 is to be controlled . With this pulse sequence, the controllable switch 15 in the driver circuit 12 is driven; the choke coil 16 is magnetized alternately in accordance with the pulse repetition frequency for the duration of the pulse train, as in the additional driver circuit 32 already described, so that a high voltage is produced at the output 13 of the driver circuit 12 . This high voltage is supplied via the anode resistor 14 to the control anode 6 of the display device 2 , so that its display segment 4 lights up one after the other from the bottom display segment 4 . As soon as the number of control clock pulses counted in the computer 54 reaches the numerical value derived from the measured variable to be represented, the control pulse is ended at the control output 56 of the computer 54 , so that there is no more pulse sequence at the control input 18 of the driver circuit 12 . As a result, the controllable switch 15 remains in the open state until, at the same time as a new reset pulse at the reset output 62 of the computer 54, the latter also outputs a new control signal at its control output 56 . In this period of time, therefore, no high voltage is generated in the driver circuit 12 and the control anode 6 leads, so that the remaining display segments 4 from the last light up to the uppermost display segment 4 of the display unit 2 do not light up.

Claims (4)

1. Circuit arrangement for controlling a gas discharge display device ( 1 ), which has one or more display units ( 2, 3 ), each with a control anode ( 6, 7 ) and a common fixed voltage anode ( 8 ),
each with a controllable switch ( 15, 24 or 33 ) containing driver circuits ( 12, 21 or 32 ) for controlling the control anodes ( 6, 7 ) and the fixed voltage anodes ( 8 ), each control anode ( 6, 7 ) each at the output ( 13, 22 ) the driver circuit ( 12, 21 ) individually assigned to it, and
with a selection device ( 50 ) for the sequential activation of the driver circuits ( 12, 21 ) for the control anodes ( 6, 7 ),
characterized by
that each of the driver circuits ( 12, 21 ) for the control anodes ( 6, 7 ) is designed as a high-voltage flyback converter, in each of which a choke coil ( 16, 26 ) in series with the controllable switch ( 15, 24 ) on one The same power supply unit is connected and a series circuit comprising a diode ( 19, 28 ) and a capacitor ( 20, 29 ) is connected in parallel to the controllable switch ( 15, 24 ), the connection point between the diode ( 19, 28 ) and the capacitor ( 20 , 29 ) forms the output ( 13, 22 ) of the respective driver circuit ( 12, 21 ),
that the controllable switch ( 15, 24 ) of each of these driver circuits ( 12, 21 ) with its control input ( 18, 25 ) each having an output ( 51, 52 ) having a clock generating device, the selection device ( 50 ), which is connected to the respective Output ( 51, 52 ) for the duration of the control of the display unit ( 2, 3 ) emits a pulse train, and
that the fixed voltage anode ( 8 ) as its own which also works as a lock-up converter and generates a high voltage additional union driver circuit ( 32 ) in which a choke coil ( 35 ) is also connected in series with the controllable switch ( 33 ) to the DC power supply unit and in parallel with the controllable switch ( 33 ) there is a series circuit comprising a diode ( 37 ) and a capacitor ( 38 ), the connection point between the diode ( 37 ) and capacitor ( 38 ) being connected to the fixed voltage anode ( 8 ) and the controllable one Switch ( 33 ) with its control input ( 34 ) is connected to an additional output ( 53 ) of the selection device ( 50 ) which emits a continuous pulse sequence. 2. Circuit arrangement according to claim 1, characterized in
that the selection device ( 50 ) contains a computer ( 54 ) containing the clock generator device, which has a clock output ( 55 ) and a control output ( 56, 57 ) for each display unit ( 2, 3 ) to be controlled,
that each control output ( 56, 57 ) is assigned a NOR gate ( 58, 59 ), the inputs of which are connected to the respective control output ( 56, 57 ) or the clock output ( 55 ) of the computer ( 54 ) and the output of which forms the respective output ( 51, 52 ) of the selection device ( 50 ), and
that the additional output ( 53 ) of the selection device ( 50 ) is connected to the clock output ( 55 ) of the computer ( 54 ). 3. Circuit arrangement according to claim 1 or 2, characterized in that the driver circuits ( 12, 21 ) and the additional driver circuit ( 32 ) at their respective output ( 13, 22 or 31 ) via a respective further diode ( 39, 40 or . 41 ) are connected to each other and that at the connection point ( 42 ) of the further diodes ( 39, 40, 41 ) a voltage regulator ( 43 ) working as a shunt regulator is connected. 4. A circuit arrangement according to claim 3, characterized in that the voltage regulator ( 43 ) contains a voltage divider comprising two resistors ( 44, 45 ), to which a further series circuit comprising a transistor ( 46 ) and a Zener diode ( 47 ) is connected in parallel, the control terminal of the transistor ( 46 ) being connected to the voltage tap between the two resistors ( 44, 45 ).