DE2038217A1 - Circuit arrangement for simultaneous monitoring of several voltages for falling below and / or exceeding a specified target level - Google Patents

Description

Circuit arrangement for simultaneous monitoring of several voltages for falling below and / or exceeding a predetermined target level The invention relates to a circuit arrangement for the simultaneous monitoring of several voltages for falling below and / or exceeding a specified target level using a comparator to which the voltages to be monitored are fed via diodes.

Known circuits for plus-minus monitoring of a voltage have the disadvantage that the voltage deviations simultaneously via an inverting and a non-inverting path to a limit value stage. So is for example in the German patent 1 296 211 a limit value detector for Multiple monitoring described in which each input to a differential amplifier with an inverting and a non-inverting output. the Outputs are linked and switched on via an OR circuit made up of diodes, for example a limit value circuit led. The response points are set by Reference voltages and the selected gain.

From the German patent specification 1 289 557 is finally also a circuit known in which the for realizing a positive and negative Sign reversal necessary for the limit value takes place in the module to be monitored. There, however, two DC monitoring voltages must then be applied to the limit value detector be guided.

The object of the present invention is to provide a circuit arrangement for simultaneous monitoring of several voltages for undershoot and / or overshoot to create a predetermined target level, at the corresponding inversion levels not to be terminated and which are at the same time simple in their structure and reliable in the monitoring of the corresponding voltage.

The circuit arrangement is designed according to the invention in such a way that that the reference potentials for the undervoltage and overvoltage limit are each at one Pole of reference diodes are located, which have a jZchc bias voltage via ohmic resistors is supplied that they are permissible in normal operation that according to the number of the voltages to be monitored there is diode pairs for decoupling and the ones on the input side with opposing electrodes and each with one pole of the one to be monitored Voltages are connected and in which the output-side pole of a decoupling diode of a pair of diodes each to the connection point of the reference diode and the ohmic one Resistance for the more positive reference potential and the pole on the output side another decoupling diode of the diode pair to the connection point of the reference diode and the ohmic resistance for the more negative reference potential is performed, eo that the diode pairs are blocked for decoupling in Normaliall, that in parallel to the ohmic resistance for which a reference diode applies a voltage divider whose center tap is led to one input of the comparator, while the other Input of the comparator with the connection point of the other reference diode and the associated Wideratandes is connected.

This has the advantage that all of them are for one carrier frequency system generated carrier pilot and control level with a multiple monitoring joint supervised and can be switched to replacement in the event of failure without that a disproportionate amount of components is necessary. The mutual Influence of the alarm wave by several at the limit of the tolerance range lying input voltages is considerably reduced compared to known arrangements. The low offset voltages and currents that occur result in a high level of accuracy the response points with high reliability and low space requirements. For the plus-minus monitoring of a level is only one DC monitoring voltage required and a special inversion stage for the sign reversal is not necessary.

To compensate for the threshold voltage of the diodes for decoupling and to compensate for their temperature response, it is advantageous to use these compensation diodes, to which an impressed current is fed via ohmic resistors, in the opposite direction To connect pole direction in series.

Instead of the compensation diodes, transistors could also be detached for this purpose use.

If you want to save a response from the comparator that has been triggered, so the circuit arrangement according to the invention can also be designed in such a way that the output of the comparator via a feedback diode with one of the connection points of reference diode and ohmic resistance was connected. Instead of a diode leaves the emitter-collector path of a transistor also use its base can be laid to ground via an ohmic resistor and a nahal ter.

One input of the comparator can be used to cancel the storage via a parallel connection of a capacitor and an ohmic resistor and a button be connectable with burning potential.

For the purpose of short-circuiting interference pulses can be between Switch on another capacitor at the two inputs of the comparator.

To avoid additional voltage dividers for different The circuit arrangement according to the invention can also be designed in this way be that the setpoint values of the monitoring direct voltage output by the assemblies to be monitored are different.

The arrangement according to the invention is also designed so that the Comparator can also be built in integrated circuit technology. It enables to use its special advantages.

Using the exemplary embodiments according to FIGS. 1 and 3 to 5 as well as the diagram of Figure 2, the invention is explained in more detail.

The principle of such a plus-minus limit value monitoring shows Figure 1. The course of the important potentials in the circuit as a function of an input voltage Ui is shown in FIG.

The input voltages U1 to Ui are decoupled via diodes. the Response thresholds for negative and positive deviations from the setpoint are set by the reference potentials V- and V + are set. Are the input voltages U1 ... Ui within the tolerance range, the decoupling diodes D2 ... D5 blocked, while a through the diodes D1 and D6 through the resistors R2 and

R1 certain current flows. The potential V3 is via a voltage divider R3, R4 to the (s) input of the comparator, so that the potential V2 of the an input by the amount #U is more positive than the potential V1 of other input. The output voltage UA is at its positive limit value.

For example, if one of the input voltages moves to more negative ones Values decrease, then the potential V3 assumes the potential of Ui as soon as the voltage IJi becomes more negative than the potential V-. The diode D1 is then blocked. Corresponding the potential V3 also runs the potential V2; the potential V1 remains constant. The potentials V1 and V2 and overlap at the upper response threshold A2 the voltage UA takes its negative limit value (alarm). An analogous consideration applies to the lower response threshold Al.

The threshold voltage of the decoupling diodes and their temperature response can be compensated very precisely with two diodes, D7 and D8. A corresponding The circuit is shown in FIG. 3. These diodes have a largely constant current through which the resistor R5 resp.

R6 is imprinted. The falling compensation voltage is also corresponding precisely defined.

If one leads according to the arrangement of FIG. 3, the output voltage UA back to the input via a further diode D9, a once triggered Response of the comparator stored. This is essential when you are dealing with the tension UA triggers an alarm that is not allowed to release itself.

By pressing the T key you can use the capacitor 02 for a short time Plus potential sn put the (+) input of the comparator and thereby the normal stand restore. Are one or more of the input voltages still present? Ui outside the response limits, then after a substantially through the Dimensioning the charging time constant of the capacitor C2 Address the comparator's check-up time again. The resistor R7 enables the discharge of the capacitor- 2 after opening the button T. The capacitor C1 has the task of short-circuit the input of the comparator to interference pulses and thus increases the interference immunity.

The one-time check avoids the circuit indicated in Fig. 4, in which the output voltage is fed back via a transistor Tr2. By pressing the delete key U, the feedback is interrupted and the circuit only returns to normal if all input voltages are within the thresholds are located. In Fig. 4 it is also shown how the temperature compensation a transistor Tr1 can be made with the emitter-base path. This circuit variant allows the voltage divider R3, R4 to be designed with low resistance and thus the influence of the offset Stromesf to keep the response threshold even lower.

In Figure 5 it is shown how all the voltages in a carrier frequency system necessary assemblies monitored simultaneously with the aid of the arrangement according to the invention can be. The first five modules represent pilot amplifiers PV, the The following seven modules control frequency amplifier StV, the following Assembly the carrier amplifier TV, followed by the other two Assemblies the auxiliary frequency amplifier BV and the last assembly the frequency control FK represents.

The response limits for U1 ... U5 range from - 0.2 to - 0.5 dB the lower, from + 0.2 to + 1.0 dB on the upper side. At U6 to U8 and U10 up to U15 only the lower response limits are monitored, those at - 2.0 to - 4.0 dB and the response limit of U9 is - 1.0 to - 3.0 dB. It will also only those below Eligibility limit monitored.

The different lower response thresholds for carrier, pilot and control levels are, as indicated in FIG. 5, different setpoint values achieved by the monitoring equal voltages emitted by the amplifiers. You need therefore no additional voltage dividers for different ones in the multiple monitoring Response thresholds and can control the monitoring voltages with optimally low internal resistance lead to the control lines V1, V3.

9 claims 5 figures

Claims (9)

Claims 1. Circuit arrangement for simultaneous monitoring several voltages for falling below and / or exceeding a specified target level using a comparator to which the voltages to be monitored are transmitted via diodes are supplied, that is, that the reference potentials (V +, V-) for the undervoltage and overvoltage limit each at one pole of reference diodes (D1, D6), which Huber ohmic resistors (R1, R2) have such a bias is supplied that they are permeable in normal operation, that according to the Number of voltages to be monitored (U1 ... Un) Diode pairs for decoupling (D2, D4 ... D3, D5) are present, the input side with opposing electrodes and each connected to one pole of the voltages to be monitored (U1 ... Un) and where the output-side pole of one decoupling diode (D4, D5) a pair of diodes (D2, D4, ... D3, D5) each to the connection point of the reference diode (D6) and the ohmic resistance (Ri) for the more positive reference potential (V +) and the output-side pole of the other decoupling diode (D2, D3) of the diode pair (D2, D4 ... D3, D5) to the connection point of the reference diode (D1) and the ohmic Resistance (R2) for the more negative reference potential (V-) is performed, so that the diode pairs for decoupling (D2, D4 ... D3, D5) are normally blocked, that parallel to the ohmic resistor (R2) for a reference diode (D1) a voltage divider (R3, R4) is, to whose center tap the one input of the comparator (K) is led is, while the other input of the comparator (K) with the connection point of the other reference diode (D6) and the associated ohmic resistor (R1) is. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n show that the diodes of the same polarity for decoupling (D2, D3 ... D4, D5) Compensation diodes (D7, D8), to which an impressed one via ohmic resistors (R5, R6) Current is supplied, 'are connected in series in the opposite pole direction. 3. Circuit arrangement according to claim 2, d a d u r c h g e k e n n show that instead of the compensation diodes (D7, D8) transistors (Tr1) are switched. 4. Circuit arrangement according to claim 1 or 2, d a -d u r c h g o k e n n z e 1 c h n e t that the output of the comparator (K) via a feedback diode (D9) with one of the connection points of reference diode (D1, D6) and ohmic resistor (R2, R1) is connected. 5. Circuit arrangement according to one of claims 1 or 2, d a d u r c h g e k e n n n z e i c h n e t that the output of the comparator (K) via the Emitter-cathode path of a transistor (Tr2) with one of the connection points of reference diode (D1, D6) and ohmic resistor (R2, Ri) is connected and that the base of the transistor (Tr2) via an ohmic resistor and a switch (T2) can be connected to ground. 6. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n n z e i c h n e t that each one input of the comparator (K) via a parallel connection of capacitor (C2) and ohmic resistor (R7) and a key (Ti) can be connected to earth potential. 7. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n z e i o h n e t that between the two inputs of the comparator a capacitor (C1) is connected. 8. Circuit arrangement according to one of the preceding claims, d a d u r c h e k e n n n z e h e t that the components to be monitored output setpoints of the DC monitoring voltage are different. 9. Circuit arrangement according to one of the preceding claims, d a d u r C h e k fl e s e n Q h n e t that the comparator (K) in integrated circuit technology is constructed.