DE3027398A1 - Electrical indicator deriving power from measurement current - using evaluation circuit consuming less than quiescent current - Google Patents

Abstract

An electrical indicator without auxiliary power is esp. for explosive atmospheres and displays a measurement current modified by a measurement parameter and contg. a quiescent current component. It is a highly accurate device which is easily read and insensitive to shocks. The measurement current passes through a measurement resistor and the indicator shows the resistor voltage drop using the energy contained in the current. A voltage regulator in series with the measurement resistor provides a constant voltage independent of the measurement current. The voltage powering an evaluation circuit is derived from the regulator constant voltage. The evaluation circuit contains an analogue-to-digital converter driving an indicator and consumes less current than the quiescent current component. The resistance voltage drop is input to the converter.

Description

Electric display device without auxiliary energy

The invention relates to an electrical display device without auxiliary power, especially for rooms at risk of explosion, for displaying a value representing a measured variable impressed measuring current, which has a quiescent current component, and via a measuring resistor is conducted and its voltage drop caused at the measuring resistor by means of a display unit, deriving the energy required for the display the measuring current is displayed.

A known display device of this type is a conventional moving coil measuring device. This is not very accurate. It can reading errors can easily occur.

It is also sensitive to vibrations.

The invention is based on the object of a display device to specify the generic type, which has a high display accuracy, easier can be read and is insensitive to shocks.

According to the invention this object is achieved in that in series with the wet resistance is a voltage regulator to which independent of the measuring current a constant voltage can be tapped, that of this voltage the operating voltage an evaluation circuit is derived, which is an analog / digital converter as well as a downstream digital display unit and its power requirements is smaller than the quiescent current component, and that the voltage drop across the measuring resistor is fed to the input of the analog / digital converter.

With this design of the display device, the measured value is on Due to the digital representation displayed very precisely. Ss can also have no reading errors appear. Vibrations cannot falsify the display. Through appropriate Selection of the components of the evaluation circuit, this can be designed with low power, that their operation with the help of the voltage that can be tapped off at the voltage regulator and one Part of the quiescent current component is guaranteed. If one of the usual in practice Measuring currents that vary between 4 mA and 20 mA represent the supply the evaluation circuit has a current of slightly less than 4 mA available. The on Voltage that can be tapped off by the voltage regulator depends on the supply voltage of the measuring circuit and is to be selected so that the operation of the measuring circuit is not impaired will. Since the digital display is thus without the additional Auxiliary energy source makes do, measurements can be made at any point in the measuring system be made. In addition, there is a high level of explosion safety because in the display device only has the small amount of energy derived from the measuring current is. The display device can therefore also be used in rooms at risk of explosion use.

In the simplest case, the voltage regulator consists of a Zener diode.

So that the display unit works with as little power as possible they are preferably capacitively controlled display elements. In particular, the display unit be a liquid crystal display unit.

In a preferred embodiment, it is ensured that the am Voltage regulator tapped voltage at the input of a DC voltage converter is supplied, the output voltage of which is greater than its input voltage and forms the operating voltage of the analog / digital converter and the display unit. The display device can therefore also be used in measuring circuits whose Supply voltage is so small that the maximum that can be tapped at the voltage regulator Voltage is less than the operating voltage of the analog / digital converter and the Display unit. This is the case, for example, where the operating voltage 6 V is, because of a supply voltage of the measuring current circuit of only 10 to 15 V but only a lower voltage can be tapped from the voltage regulator.

The DC voltage converter can, for example, be a blocking oscillator with downstream transformer and rectifier or another known design exhibit. Since electrical isolation is usually not required, we recommend a voltage converter with an adding circuit in which the voltage tapped at the voltage converter Voltage connected in series with a voltage derived from this voltage is. This results in a very simple structure. You can also do without inductors get by, the additional measures when used in explosion-proof rooms would require.

In a preferred embodiment the connection point is between Voltage regulator and measuring resistor with the reference voltage input of the analog / digital converter connected and with reference to its potential that is an output potential of the voltage converter positive and the other negative. This measure, which is particularly easy with the Can accomplish the aforementioned adding circuit, has the advantage that the for the measured variable displayed by the voltage drop across the measuring resistor to the digital / analog converter can be fed in without reshaping, although he is potential-wise is outside the voltage that can be tapped at the voltage regulator.

It is very favorable for the implementation of the adder circuit if the voltage converter has a transmission capacitor and an output capacitor and the transmission capacitor alternately to the voltage regulator and can be switched to the output capacitor.

By one located on the input side of the voltage converter Buffer capacitors can cause fluctuations in the digital display due to switching surges can be avoided in the voltage converter.

The voltage drop across the measuring resistor can affect the analog / digital converter via an adjustable voltage fed by the voltage tapped at the voltage regulator Be supplied bias generator. This bias generator allows easy Way a shift of the zero point of the analog / digital converter and display unit, what for a measuring circuit with an impressed constant quiescent current component of It is advantageous if this quiescent current component is to be suppressed in the display. In addition, this zero point shift enables measured variables to be displayed, whose measured value is outside the display range of the display unit.

The bias generator preferably has a negative feedback differential amplifier high gain, its operating voltage connections at the output of the voltage converter lie.

Such a differential amplifier has a high input resistance and therefore represents only a low load on the measuring circuit. In connection the voltage regulator ensures a high level of zero point stability.

Around the zero point by a fixed amount, corresponding to a constant Quiescent current component of the measuring current, alli easy way to move, the negative feedback factor of the differential amplifier can be switchable.

The bias generator can then have a voltage divider at the output of the differential amplifier and the input of the analog / digital converter with the input of the differential amplifier, with the output of the differential amplifier and be connectable to the output of the voltage divider. Leave that way at least three different zero points are set, for each setting the same zero point stability as for the low-drift differential amplifier is ensured is.

Then it can be ensured that the voltage divider is a potentiometer, two resistors in series and parallel to the potentiometer and one den Potentiometer tap with the connection point forming the output of the voltage divider of the two resistors connecting resistance and that the adjustment range this voltage divider is chosen so that it is twice the maximum voltage drop at the measuring resistor. This can have very high resistance, represent low load on the measuring circuit, can be used in the voltage divider. The potentiometer enables a constant shift of the zero point. Yet ensures the wiring of the potentiometer by means of the additional resistors, that minor adjustments of the potentiometer tap due to vibrations do not affect the display, especially in the lowest decimal place.

An adjustable voltage divider can be used in parallel to the voltage regulator lie, the output of which corresponds to the transmission factor of the analog / digital converter determining control input of the analog / digital converter is connected. With help this voltage divider can be the transmission factor of the analog / digital converter can be changed so that the measurement or display range corresponds to the setting of the voltage divider is changed, for example so that too the entire available range of numbers is used for smaller measured quantities will.

In this case, too, the voltage divider connected in parallel can be activated Potentiometer, two resistors in series and parallel to the potentiometer and one of the potentiometer tap with the forming the output of the voltage divider Have connection point of these two resistors connecting resistance.

Here too, the voltage divider can have a correspondingly high resistance train without minor adjustments of the potentiometer tap due to vibrations affect the display.

It is then advantageous if the Zener diode has a control connection and its Zener voltage with increasing voltage between the anode and the control terminal decreases and if there is a voltage divider on the Zener diode, its tap with is connected to the control terminal of the Zener diode. Such a Zener diode can not only easily set to the desired operating voltage of the display device, but also ensures high stability of the operating voltage at the same time, as desired for an accurate measurement and reading. If namely the Zener voltage the Zener diode tends to increase, this increase causes negative feedback Via the voltage divider and the control connection in the sense of a reduction and thus stabilization of the Zener voltage.

The reverse would be the negative feedback over the control connection, with a Efforts to decrease the Zener tension also have a stabilizing effect.

At least one further Zener diode can be used in parallel with the Zener diode with a higher Zener voltage. This has the advantage that in the event of a breakthrough the first Zener diode has the second, and if the second breaks down, the second third, etc., would remain effective.

It is also beneficial if the tapped on the voltage regulator over a multi-pole changeover switch arrangement and a gate circuit fed by the same voltage, the one derived from the digitization cycle of the analog / digital converter Clock signal is periodically keyed, predetermined characters (A, V, m, pH, 0C ...) assigned display triggering inputs can be fed to the display unit. Means the changeover switch arrangement can be used to preselect the display of the predetermined characters, e.g., characters representing units of measurement so that the display device can display various physical measurands can be used. At the same time is ensures that in the liquid crystal display unit, which is usually only to be operated in a pulsed manner the display of the characters selected by means of the wrapper arrangement is also pulsating (with a correspondingly high frequency).

Then it can be ensured that the output of a voltage drop at the measuring resistor monitoring limit value indicator and the output of a through the Digitization clock acted upon by frequency divider, the output frequency of which is one Flashing frequency, via a gate circuit with a light-dark control input the display unit is connected, and that limit monitor, frequency divider and gate circuit are fed by the voltage tapped at the voltage regulator. This has the advantage that there is a separate display unit for the limit indicator and also on the one provided Liquid crystal display unit additional display places for but or falling below of a limit value do not apply. If the limit monitor responds, it will signaled by the display unit flashing.

The limit monitor can have two high-gain differential amplifiers have, one of the inputs common to one side of the measuring resistor and their other inputs each via a voltage divider with the other side of the measuring resistor are connected, the outputs of these differential amplifiers linked by a gate circuit forming the output of the limit indicator are. This limit indicator is also comparatively high resistance and provides therefore only a small load on the measuring circuit.

Then there is an advantageous embodiment that the Auftasteingang the gate circuit switching the clock signal through from the output signal of the frequency divider it is applied that this gate circuit has an inverse function with respect to the clock signal has that the clock signal is the input of the frequency divider and a common Connection of display segments can be fed directly to the display unit and the output the gate circuit downstream of the frequency divider with the other connections can be connected via the switch arrangement preselectable display segments and that the output of the limit monitor is connected to an enable input of the frequency divider is.

Only the preselected display segments are shown when responding of the limit monitor with a low, reduced relative to the clock signal frequency Flashing frequency operated, but still during each low-frequency flashing pulse switched on and off invisibly to the eye with the high clock signal frequency. In contrast, the clock signal frequency is applied to the connections of the display segments that have not been preselected periodically the same potential is applied so that these display segments do not display any cause.

It is particularly favorable if the display device is integrated Has circuits. These have a particularly low power requirement correspondingly small space requirements.

The drawing represents a simplified circuit diagram of an exemplary embodiment the display device.

The display device is used for a measuring system in which the measured physical quantity, e.g. an electrical voltage, a pH value, a temperature or an electric current, a measuring current I independent of interference permanently assignedi.> StEin in this way the current is permanently assigned to the measurand is also referred to as "impressed" current. It is a direct current and exists superimposed.

here from a constant quiescent current of 4 milliamps and the measured variable rigidly proportional portion from 0 to 16 milliamps.

This current I is fed to the display device from the measuring point a transmission line (not shown) and an input 1 are supplied. Above an output 2 and the transmission line it flows back to the measuring point.

A controllable Zener diode is located between input 1 and output 2 3 and a low-resistance measuring resistor 4 in series.

A voltage divider 5 is located parallel to the Zener diode 3 80 switched so that the Zener voltage of the Zener diode receives a predetermined value, which is around 3 volts here. Lying parallel to the Zener diode 3 two further, but not controllable Zener diodes 6 and 7, their Zener voltages slightly higher than that of the Zener diode 3, here at around 4 volts.

As long as the Zener diode 3 is not defective, the Zener diodes are 6 and 7 ineffective. On the other hand, should the Zener diode 3 be destroyed, so that they represents an interruption, then the Zener diodes 6 and 7 are effective in order to prevent an excessively high voltage from occurring between input 1 and output 2.

Even if the second Zener diode 6 should be destroyed, the third Zener diode 7 alone ensure a corresponding voltage limitation. This multiple security is particularly desirable in areas at risk of explosion, in order to avoid overvoltages that trigger flashovers and thus an explosion can. In addition, the Zener diodes 6 and 7 can spatially opposite other parts the device, in particular the plate supporting it, be separate or isolated, to avoid moisture bridges and thus leakage currents or short circuits.

A capacitive voltage converter is then connected to the Zener diode 3 8. This converts the voltage drop caused at the Zener diode 3 by the measuring current I. to a higher voltage between its output 9 and input 1. Preferably causes the voltage converter 8 a voltage doubling, so that it on the one hand with lower input voltage can be applied and on the other hand its output voltage for the operating voltage supply for all other devices of the display device is sufficient if its operating voltage is higher than the Zener voltage of the Zener diode 3 is. At the same time it is achieved by doubling the voltage that the potential of output 9 is more negative than that of output 2 with respect to the potential of the connection point (0) between Zener diode 3 and measuring resistor 4 is. The voltage drop across the measuring resistor 4 is therefore in terms of potential in the range of the output voltage of the voltage converter.

The voltage converter 8 has a acting as a buffer capacitor Input capacitor 10 between the input terminals forming the input of the voltage converter 11 and 12, to which the voltage drop across the Zener diode 3 is fed. Parallel there is also an oscillator and switching logic unit 13, the electronic one, to make it easier the understanding of the mechanical design shown switches 14, 15, 16 and 17 opens and closes at a predetermined frequency. This is where the switches 14 and 17 operated in push-pull to switches 15 and 16. That way will a transmission capacitor 18 with switches 14, 17 closed and open Switches 15, 16 charged to the voltage drop at the Zener diode 3 and in the illustrated position of the switches 14 to 17 with reversed polarity in a Output capacitor 19 between the connection point (0) and the output 9 of the voltage converter 8 discharged. The input capacitor 10, the capacitance of which is, for example, 10 microfarads higher than that of the capacitors 18 and 19 each with, for example, 4.7 microfarads is, for smoothing the slight ripple caused by the recharging current surges of the voltage drop occurring at the measuring resistor 4 and to be displayed Way becomes an unnecessary change of the in the lowest digit of the digital display shown figure avoided.

The charging voltage of the output capacitor 19 causes a shift of the potential at the output 9 compared to that of the connection point (0) by an amount in the negative direction, which is approximately equal to the voltage drop across the Zener diode 3 is. The voltage between input 1 and output 9 is therefore twice that Voltage drop across the Zener diode 3.

The output voltage of the voltage converter, which is around 6 volts 8 (the voltage between input 1 and output 9) becomes the power supply connections an analog / digital converter 20 and a downstream liquid crystal advertisement unit 21 fed. At the same time, the current I generated at measuring resistor 4 is generated Voltage drop on the one hand over a bias generator 22 and on the other hand over a high-resistance current limiting resistor 23 inputs 24, 25 of the digital / analog converter 20 supplied. This sets the voltage between its inputs 24 and 25 into a digital variable, which is digitally in the downstream display unit 21 is shown.

Another reference voltage input 26 of the analog / digital converter 20 is at the potential of the connection point (0), and a control input 27 of the analog / digital converter 10 is connected to the output 29 of a voltage divider 28 in connection, which is also fed by the voltage drop across the Zener diode 3 will.

The bias generator 22 includes a differential amplifier 30 very much high gain (also called arithmetic or operational amplifier), which also is fed by the output voltage of the voltage converter 8. Its not repentant The input is with the connection point (0) and its reversing input via a Input resistor 31 to input 1 and via a feedback resistor 32 connected to the output of the differential amplifier 30. Furthermore, he is not repentant Input of the differential amplifier 30 via a resistor 33 and a three-stage Switch 34 either with the output of the differential amplifier 30 and at the same time with the output 35 of the bias generator 22 - in the illustrated position of the changeover contact 36 of the switch 35, in which a wiper of the changeover contact 36 is stationary Contacts 37 and 38 bridged - or connected directly to their output 35, if the wiper of the switchover contact8 36 assumes the middle position in which it only touches contact 38. The changeover contact 36 can have a third position occupy a fixed contact 39, which is the output of a voltage divider 40 forms.

In the illustrated left end position of the changeover contact 36 (the is limited by a stop) the resistors 32 and 33 are in the return of the differential amplifier 30 in parallel, and at the output 35 occurs opposite the input 41 has a negative voltage, here about 40 millivolts, which corresponds to the voltage drop of the Measuring current I corresponds to 4 milliamps at the measuring resistor 4, which is about 10 ohms here having. The voltage drop is then present at the input 24, 25 of the analog / digital converter 20 of the measuring resistor 4, reduced by the output voltage of the bias generator 22. For example, if the measurement current is 16 milliamperes, that is the real one The portion of the measured current I representing the measured variable is only 16 milliamps minus 4 milliamps equal to 12 milliamps. The voltage drop caused by the measuring current I at the measuring resistor 4 16 milliamps times 10 ohms equals 160 millivolts. This tension is the in the illustrated position of the switch 34, the output voltage is forty millivolts of the bias generator 22 in the opposite direction, so that between the inputs 24, 25 a voltage of 120 millivolts. This amount is exactly proportional to the Measured variable and is digitized by the analog / digital converter 20 and by the display unit 21 displayed.

When the changeover contact 36 assumes the middle position on contact 38, its voltage at output 35 corresponds to the input voltage of the differential amplifier 30. This input voltage is practically zero or equal to the reference voltage at the input 26 of the analog / digital converter 20. In this case, the full Voltage drop at measuring resistor 4 (160 millivolts) is displayed.

The voltage divider 40 contained in the bias generator 22, whose Input side between input 1 and the output of differential amplifier 30 is, has a potentiometer 42 and parallel to this two connected in series Resistors 43 and 44. The connection point of resistors 43 and 44 is on the one hand with the contact 39 forming the output of the voltage divider 40 and on the other hand via a further resistor 45 is connected to the tap of the potentiometer 42. With This voltage divider 40 can help when the changeover contact 36 is in the right position at contact 39 assumes the bias voltage at input 25 by an adjustable amount adjusted. In this way the zero point of the display is adjusted to a corresponding one Amount corresponding to the entire display range from here plus / minus 200 millivolts can, postponed. This enables measured variables to be displayed outside of the Display area.

The wiring of the potentiometer 42 by means of the resistors 43 to 45 has the consequence that the output voltage of the voltage divider 40 at the output 39 changes more slowly than the voltage when the potentiometer tap is adjusted at the potentiometer tap. This has the advantage that vibrations of the potentiometer 32 does not cause an undesirable change in the display, especially in the lowest Decimal place, lead. The potentiometer 42 and the resistors 43 to 45 are proportional high resistance, the resistors 43 to 45, however, higher resistance than the potentiometer 42, so that the voltage divider 40 as well as the differential amplifier 30 the measuring circuit practically not burdened.

The voltage divider 28 is essentially the same as the voltage divider 40 formed. It also contains a potentiometer 46 and parallel to it two series-connected resistors 47 and 48, their connection point on the one hand the output 29 of the voltage divider 28 forms and on the other hand via a resistor 49 is connected to the tap of the potentiometer 46.

With the help of this voltage divider 28, the control input 27 of the Analog / digital converter 20 are supplied with a variable control voltage, the the transmission factor or gain factor of the analog / digital converter 20 controls. This enables the measurement or display range to be changed in such a way that that smaller measured quantities are assigned a larger display area, and vice versa. Here, too, the wiring of the potentiometer 46 has the advantage of being less sensitive to vibrations.

In addition to the measured value display, a multi-digit or multi-pole Changeover switch arrangement 50 made up of several changeover switches, each with a changeover contact and have two fixed contacts, different measuring units, respectively the respective measured variable, are preselected for display, for example the units of measurement A (amps), V (volts), mA (milliamps), mV (millivolts), pH values and 0C. aside from that three different positions DP1, DP2 and DP3 for the decimal point or the decimal comma can be selected in the display.

The fixed contacts of the Switch arrangement 50 are all with a clock output 51 for the internal digitization clock of the analog / digital converter 20, the pulse frequency of which is approximately 50 KHz. The clock output 51 is also connected to an input 52 of the display unit 21, the one operating voltage connection of all display segments of the display unit 21 is common. The input lines shown as multiple lines 53 and 54 of the display unit 21 lead to the second operating voltage connection in each case other Display segments, the multiple line 53 being the measured value display segments and the Multiple lines 54 are assigned to the meter display segments. So if a Voltage (of the required level) between input 52 and one of the input lines of the multiple lines 53 or 54, the associated display segment lights up on.

For example, if the switch associated with the measuring unit A the If the (upper) position is OFF, the digitization cycle from output 51 is not only the entrance 52, but via the Unit of measure switch A also to the input of the display unit 21 assigned to the unit of measurement A via the Multiple line 54 supplied so that at both operating voltage connections of the the display segment assigned to the unit of measurement A has the same potential. At this There is therefore no operating voltage in the display segment, so that it does not cause any display.

The digitization clock from output 51 of the analog / digital converter 20 is also the clock input 55 of a frequency divider 56 in the form of a counter and one input with the other input at the output of the frequency divider 56 horizontal gate circuit 57 supplied with reverse function. The output of the gate circuit 57 is with the fixed contacts assigned to the (lower) ON position Switch of the switch assembly 50 connected.

A release and reset input 58 of the frequency divider 56 is with connected to the output of a limit indicator 59, the voltage across the measuring resistor 4 monitors. If the voltage at measuring resistor 4 has reached an upper limit value (here 200 Millivolts) or falls below a lower limit value (here 40 millivolts), the limit indicator gives the clock input 55 of the frequency divider 56 via the release input 58 free. If, on the other hand, the measured voltage drop across the measuring resistor 4 lies between the two Limit values (within the normal range), then the clock input 55 is above the Release input 58 blocked and the frequency divider 56 reset.

In the case of a normal measured variable, there is consequently at the output of the frequency divider 56 constantly an AuStastsignal (here a 1-signal), which the gate circuit 57 gates holds. The digitization clock fed to the inverting input of the gate circuit 57 therefore appears in phase opposition at the output of the gate circuit 57 and simultaneously at all ON contacts of the switch assembly 50. Only via the one in the ON position Changeover switch and the connected Management of the multiple line 54 however, the antiphase digitization clock is assigned to that of the unit of measurement A. Display segment fed. As a result, with each pulse of the digitization clock a voltage is applied to this display segment and causes the display "A". Because the very high clock frequency of around 50 KHz, however, this display has a completely flicker-free effect. At the same time the In the case of these display units, it is sufficient to not display the display with a constant, but to operate pulsating current.

However, if the limit indicator 59 exceeds or falls below the limit value reports, causes the release of the clock input 55 of the frequency divider 56 that on Output of the frequency divider 56 pulses occur whose pulse frequency is a fraction the pulse frequency of the digitization clock is, here about 1 Hz, and its duty cycle is 1: 1. As a result, the gate circuit 57 becomes periodic for half a second long keyed and locked for half a second. In every keying interval of half a second, the gate circuit 57 leaves the digitization clock out of phase so that the unit of measurement selected for the display periodically half a Is displayed for a second, i.e. flashing. This blinking of the unit display means for the operator that a set limit value has been exceeded or not reached became.

The limit indicator 59 contains two adjustable voltage dividers 60 and 61, which are in series with a common resistor 62 between the anode of the Zener diode 3 or the connection point (o) forming the neutral conductor and the das output 9 of voltage converter 8 supplying negative potential. The tap of the voltage divider 60 is connected to the inverting input of a resistor 63 negative feedback differential amplifier 64 high gain and the tap of the Voltage divider 61 with the inverting input of a counter-coupled via a resistor 65 Differential amplifier 66 high gain connected.

The non-inverting inputs of differential amplifiers 64 and 66 are Via a common high-resistance current limiting resistor 67 with the current output 2 connected.

The output of differential amplifier 64 is non-inverting Input and output of the differential amplifier 26 with an inverting input a gate circuit 68, the output of which is the output of the limit monitor 59 forms.

The voltage divider 60 is used to set the upper and the voltage dividers 61 the setting of the lower limit value of the measured variable. When the upper limit 200 millivolts and the lower 40 millivolts is the potential of the The tap of the voltage divider 60 by 200 millivolts and that of the tap of the voltage divider 61 by 40 millivolts below zero (O). As long as the voltage drop across the measuring resistor 4 less than 200 millivolts (the current I with a measuring resistor of 10 ohms is less than 20 milliamps), the potential of output 2 or

of the non-inverting input of differential amplifier 64 is higher than the potential of the tap of the voltage divider 60 or the reversing input of the differential amplifier 64. The output voltage of the differential amplifier 64 is therefore to a high value, which corresponds to a 1-signal at the non-inverting input of the Gate circuit 68 corresponds. If the voltage drop across the measuring resistor 4 is between the two limit values of 40 millivolts and 200 millivolts, i.e. within the permissible Range, then is the potential of the inverting input of the differential amplifier 66 higher than that of its non-inverting input, so the output voltage of differential amplifier 66 is low and represents a 0 signal. The gate circuit 68 is keyed in, and the release input 58 of the frequency divider 56 is a blocking signal (in the form of a 1 signal). If, on the other hand, one or the other limit value exceeded or fallen short of, then the output signal of the gate circuit 68 changes to "0" so that the frequency divider input 55 is enabled and the counter resp.

Frequency divider 56 begins to count.

The current limiting resistor 67 is the same as the current limiting resistor 62 and the Zener diodes 3, 6 and 7 spatially from neighboring ones for reasons of explosion protection Parts separated (isolated).

The analog / digital converter 20 and the display unit 21, the voltage converter 8, the frequency divider 56, the gates and differential amplifiers are preferred designed as integrated circuits. The other components can, as far as it is.

are not mechanically moving parts, as integrated circuits be trained.

Modifications of the illustrated embodiment are within the scope the invention. The gate circuits 57 and 68 can also consist of EXCLUSIVE-OR gates be educated.

Claims (23)

Claims 1. Electrical display device without auxiliary energy, especially for rooms at risk of explosion, for displaying a value representing a measured variable impressed measuring current, which has a quiescent current component, and via a measuring resistor is conducted and its voltage drop caused at the measuring resistor by means of a display unit, deriving the energy required for the display the measuring current, is indicated, characterized in that in series with the measuring resistor (4) a voltage regulator (3) is connected to which, regardless of the measuring current, a constant Voltage can be tapped, that of this voltage the operating voltage of an evaluation circuit is derived, which has an analog / digital converter (20) and a downstream one has digital display unit (21) and whose power consumption is less than the quiescent current component is, and that the voltage drop across the measuring resistor (4) is the input of the analog / digital converter (20) is supplied. 2. Apparatus according to claim 1, characterized in that the voltage regulator is a Zener diode (3). 3. Apparatus according to claim 1 or 2, characterized in that the display unit (21) has capacitively controlled display elements. 4. Apparatus according to claim 3, characterized in that the display unit (21) is a liquid crystal display unit. 5. Device according to one of claims 1 to 4, characterized in that that the voltage tapped at the voltage regulator is fed to the input (11, 12) of a DC voltage converter (8) whose output voltage is greater than its input voltage and the operating voltage of the analog / digital converter (20) and the display unit (21) forms. 6. Apparatus according to claim 5, characterized in that the voltage converter (8) has an adder circuit in which the voltage tapped off at the voltage converter (3) Voltage connected in series with a voltage derived from this voltage is. 7. Apparatus according to claim 5 or 6, characterized in that the connection point between voltage regulator (3) and measuring resistor (4) with the Reference voltage input (26) of the analog / digital converter (20) connected and with Relation to its potential the one output potential of the voltage converter (8) positive and the other is negative. 8. Apparatus according to claim 6 or 7, characterized in that the voltage converter (8) has a transmission capacitor (18) and an output capacitor (19) and the transmission capacitor (18) alternately to the voltage regulator (3) and can be switched to the output capacitor (19). 9. Apparatus according to claim 6 or 7, characterized in that the voltage converter (8) has a buffer capacitor (10) on the input side. 10. Device according to one of claims 1 to 9, characterized in that that the voltage drop across the measuring resistor (4) to the analog / digital converter (20) an adjustable voltage fed by the voltage tapped at the voltage regulator (3) Bias generator (22) is supplied. 11. Device according to one of claims 4 to 9 and claim 10, characterized in that the bias generator (22) is a negative feedback differential amplifier (30) has high gain, the operating voltage terminals at the output of the Voltage converter (8) lie. 12. The device according to claim 11, characterized in that the The negative feedback factor of the differential amplifier (30) is switchable. 13. Apparatus according to claim 11 or 12, characterized in that that the bias generator has a voltage divider (40) at the output of the differential amplifier (30) and the input of the analog / digital converter (20) with the input of the differential amplifier (30), to the output of the differential amplifier (30) and can be connected to the output (39) of the voltage divider (40). 14. The device according to claim 13, characterized in that the Voltage divider (40) a potentiometer (42), two in series and parallel to the potentiometer (42) lying resistors (43, 44) and a potentiometer tap with the Output (39) of the voltage divider (40) forming the connection point of the two resistors (43, 44) connecting resistor (45) and that the adjustment range of this Voltage divider (40) is chosen so that it is twice the maximum voltage drop at the measuring resistor (4). 15. Device according to one of claims 1 to 14, characterized in that that an adjustable voltage divider (28) is parallel to the voltage regulator (3), its output (29) with a transfer factor of the analog / digital converter (20) determining control input (26) of the analog / digital converter (20) connected is. 16. The device according to claim 15, characterized in that the voltage divider (28) lying in parallel, a potentiometer (46), two in series and resistors (47, 48) lying parallel to the potentiometer (46) and a potentiometer tap with the connection point of the voltage divider (28) forming the output (29) of the voltage divider two resistors (47, 48) connecting resistor (49). 17. Device according to one of claims 2 to 16, characterized in that that the Zener diode (3) has a control connection and its Zener voltage with increasing voltage between the anode and the control terminal decreases and that on the Zener diode (3) has a voltage divider (5) whose tap is connected to the control terminal the Zener diode (3) is connected. 18. Device according to one of claims 2 to 17, characterized in that that parallel to the Zener diode (3) at least one further Zener diode (6; 7) with higher Zener voltage. 19. Device according to one of claims 1 to 18, characterized in that that the voltage tapped at the voltage regulator (3) via a multi-pole changeover switch arrangement (50) and a gate circuit (57) fed by the same voltage, which is controlled by a clock signal derived from the digitization clock of the analog / digital converter (20) is periodically keyed, assigned to predetermined characters (A, V, m, pH, 0C ...) Display trigger inputs (54) of the display unit (21) can be fed. 20. Device according to one of claims 1 to 19, characterized in that that the output of a limit monitor monitoring the voltage drop across the measuring resistor (4) (59) and the Output of one acted upon by the digitalization cycle Frequency divider (56), the output frequency of which corresponds to a flashing frequency, over a gate circuit (57) with a light-dark control input (52, 54) of the display unit (21) is connected, and that limit indicator (59), frequency divider (56) and gate circuit (57) are fed by the voltage tapped at the voltage regulator (3). 21. The device according to claim 20, characterized in that the Limit indicator (59) has two differential amplifiers (64, 66) of high gain, one of its inputs (+) together with one side (2) of the measuring resistor (4) and their other inputs (-) each via a voltage divider (60; 61) with the other side (0) of the measuring resistor (4) are connected, and that the outputs of this Difference amplifier (64, 66) through a forming the output of the limit indicator (59) Gate circuit (68) are linked antivalent. 22. Device according to one of claims 19 to 21, characterized in that that the Auftasteingang of the clock signal through-switching gate circuit (cd7) from Output signal of the frequency divider (56) is applied that this gate circuit (57) has an inverse function with respect to the clock signal that the clock signal the input (55) of the frequency divider (56) and a common connection of display segments the display unit (21) can be fed directly and the output of the frequency divider (56) downstream gate circuit (57) with the other connections via the changeover switch arrangement (50) preselectable display segments can be connected and that the output of the limit indicator (59) is connected to an enable input (58) of the frequency divider (56). 23. Device according to one of claims 1 to 22, characterized in that that it has integrated circuits.