DE1219530B - Circuit arrangement for monitoring a large number of voltage sources for the carrier, pilot and / or signal frequencies in multi-channel carrier frequency systems - Google Patents

Description

Circuit arrangement for monitoring a large number of voltage sources for the carrier, pilot and / or signal frequencies in multi-channel carrier frequency systems The invention relates to a circuit arrangement for monitoring a plurality of Voltage sources for the carrier, pilot and / or signal frequencies in multi-channel carrier frequency systems, particularly in multi-channel carrier frequency telephony systems, using a Transistor circuit, the input of which is through a parallel to the power supply source the transistor circuit lying voltage divider and its output through an im Collector circuit lying control element, in particular by a rectifier bridged Relay is formed.

In multi-channel carrier frequency systems, it is used to increase operational reliability required, the individual carrier frequency, signal frequency and pilot voltage sources to constantly monitor their operational safety. It takes too much effort to assign a separate monitoring device to each of these frequencies.

The object of the invention is to create a monitoring device, to which all carrier, pilot and signal frequencies simultaneously for the purpose of monitoring are connected to a certain predetermined nominal value of their amplitude. exceeds only one of these voltage sources has the tolerance limit at which the operational readiness of the carrier frequency system is at risk, an alarm must be triggered. The performance, for the monitoring or alarm triggering of each individual in their amplitude voltage source to be monitored must be applied, should only be in the order of magnitude of a few milliwatts. For the solution of this problem can be advantageous known switching transistor arrangement, which contains an alarm relay in the output, be used.

There are known control arrangements whose control circuit is the base-emitter path of a transistor, a resistor and a control voltage generator with relative contains large internal resistance. The resistor is arranged by a parallel Directional line bridged, the cathode of which faces the transistor electrode The end of the resistor is connected and its anode in the event of activation of the resistance in the base lead to a more positive one, in the case of activation in the emitter path is connected to a more negative potential than that of the end of the resistor facing away from the transistor electrode. The diode is like this switched on that with a large voltage drop at the resistor and at the base-emitter path of the transistor a high resistance and with a small voltage drop across the resistor and there is a low-resistance control circuit at the base-emitter path of the transistor is. Such an arrangement is, however, for the control of alarm and regulating devices, especially for monitoring a large number of sources of spam for the carrier, Pilot and signal frequencies not suitable in multi-channel carrier frequency systems, because with the carrier frequency technology an alarm is issued within very narrow tolerance limits must be done, but with the known circuit, among other things by using only one transistor, cannot be reached. In addition, everyone would have to be monitored Voltage source, as already described above, has its own control circuit be assigned, which would mean a great effort of assemblies.

The above-mentioned object is achieved according to the invention in that the base of a first transistor is connected directly to a voltage dividing point in the vicinity of the positive pole of the power supply source, the collector is connected via a resistor with a voltage dividing point in the vicinity of the negative pole of the power supply source and via a further resistor, in particular a Zener diode, with the base of a second transistor and the emitter of the first transistor either directly with the emitter of the second transistor and via a voltage divider, consisting of a resistor and a Zener diode, with the positive pole of the power supply source - with the midpoint of this voltage divider via a further resistor on the negative pole and the base of the second transistor is connected to the positive pole of the power supply source via resistors or the emitter of the first transistor is connected to the emitter of the second transistor via a Zener diode, a resistor d en emitter of the first transistor - with the negative pole and another resistor connects the emitter of the second transistor with the positive pole of the power supply source and another resistor is arranged between the base and emitter of the second transistor - and at least one tap of the voltage divider at the input one or each Several diodes are connected, via which the voltages to be monitored, in particular DC voltages proportional to the effective value of the carrier voltages to be monitored, are fed.

The collector and / or the base of the first transistor become useful connected to the positive pole of the power supply source by means of capacitors.

Such a circuit arrangement only loads the voltage sources to be monitored to a very low degree and guarantees a multiple carrier alarm that is largely independent of fluctuations in the supply voltage or the ambient temperature, whereby the voltage sources to be monitored, decoupled from one another, can be connected to different taps of the input voltage divider according to the desired sensitivity are. If one of the resistors of the input voltage divider is designed as a temperature sensor, the circuit arrangement can at the same time also be used for alarming temperature fluctuations.

In a further embodiment of the invention, the circuit arrangement is designed so that the DC voltages to be applied to the input voltage divider are derived from the carrier voltages by a full wave rectification and are applied to the input of the transistor circuit via a changeover switch in such a way that the positive pole of these direct voltages with the positive pole of the power supply source and the negative pole of the rectifier circuit is connected to a voltage divider point corresponding to the desired response sensitivity via the associated changeover switch and a diode in each case and can be switched to a voltage measuring device, preferably with compensation voltage, if necessary, especially in the event of a fault. For the carrier voltage, a double full-wave rectification can also be provided in such a way that at the output towards a midpoint there is a DC voltage potential which is symmetrical to the midpoint and which is fed to the input voltage divider of the transistor circuit in such a way that the midpoint is connected directly to a voltage divider point, in particular to that voltage divider point which is also the base of the first transistor, while the symmetrical starting points are connected to further voltage divider points via rectifiers and, if necessary, via additional changeover switches Use the setpoint of the voltage to be monitored. Furthermore is. It is expedient to provide a calibration voltage source which can be connected either via a diode to a voltage divider point of the transistor circuit or to a measuring direction. It is also advantageous to switch on a Zener diode between the first point of the voltage regulator at the input, which is at the negative pole, and the positive pole of the power supply source.

The invention is illustrated with reference to the FIGS. 1 to 3 schematically illustrated embodiments explained in more detail.

The base-emitter paths of the transistors T1 and T2 of the circuit according to FIG. 1 are biased against the positive pole of the power supply source -B, + B by the Zener diode RL1 by a constant amount. As a result, in addition to reducing the temperature dependency of the circuit, a considerable increase in responsiveness is achieved compared with previously known circuit arrangements for voltage monitoring. If no alarm is triggered, the transistor T 1 works in the steep part of its characteristic curve and carries collector current. Its operating point is set for this operating case by the divider ratio of the resistors R 1 + R 1 'to R 2 ... R5. Due to the dividing ratio of the resistors R6 + R6 to R7, the base of the transistor T2 is slightly positively biased against its emitter for this operating state, so that the transistor T 2 is reliably blocked. The alarm relay Rs, which is bridged by a Glei #, hrieliter G, is located in its collector circuit. Wiffl by the divider ratio of the resistors R 1 and R 2. , R 5 specified voltage distribution changed from the outside, z. B. by an additional current through a branch of the voltage divider, the base of the transistor Tl against its emitter is negative. As a result, the collector current of the transistor Tl drops sharply, and the voltage applied to the voltage divider R 6, R 7 increases voltage drop across resistor R8, which is a more rapid decline waste is negative whereby the Einitter of the transistor T 1 to the base, causing its collector current. By appropriate selection of the resistor R8 one can achieve a very steep steepening of the switching process of the transistor T2, so that it works in pure switching mode.

For operational reasons, it is desirable that the threshold for triggering an alarm is not shifted in the event of fluctuations in the supply voltage -B, + B or in the event of fluctuations in the ambient temperature. For this purpose it is advantageous to stabilize the supply voltage for the transistor T2 and the voltage divider RI, R2 ... R5 by means of the further Zener diode RL 2. The temperature response of the circuit arrangement can be compensated for by inserting the temperature-dependent resistors R 1 'and R 6'. If a carrier voltage source T falls only very slowly, then when the alarm threshold of the circuit arrangement is reached, the alarm relay Rs could flutter. The capacitors C1 and / or C2 are provided in order to prevent this and always ensure precise switching. The carrier voltage sources T emit, at a separate output, a direct voltage proportional to their effective value, parallel to the resistor Ra, to the transistor circuit. In the course of the cable are inserted blocking diodes D 1 ... D n, which prevent Rückwärtsbeeinftussung of the individual, the carrier voltages proportional DC voltages required for Alan triggering power u2 should be small so that the WiderstandRa Jiaeinen large resistance value must be obtained. The blocking resistances of the diodes D1 ... Dn must also be very large, so that it is advisable to use silicon diodes for these diodes, as long as the carrier voltage proportional DC voltage U across the resistor Ra is equal to the voltage between the The positive pole and the associated tap on the voltage divider R 1 ... R 5 flows through the diodes D 1 . . - D n no power. Decreases the DC voltage proportional to the resistance Ra from such flows via the corresponding diode D 1 ... D n, a compensating current, whereby the voltage at the base-emitter path of the transistor T 2 is changed so that the collector current decreases, and thus a Alarm triggered. If the DC voltage at the resistor Ra, which is proportional to the carrier voltage, is greater than the equilibrium state, no equalizing current can flow due to the high blocking resistance of the diodes D 1 ... D n , which also explains that the alarm triggering for one voltage to be monitored is another cannot influence the voltage to be monitored. For operational reasons, it is desirable that carriers, pilots and signal frequencies trigger alarms when the percentage dip is different. This is achieved by applying the individual voltages to be monitored to different taps on the voltage divider R2 ... R5 via the corresponding decoupling diodes DI ... D n . For example, the direct voltages to be monitored derived from the carrier frequency sources will be connected to terminals Tr, the corresponding voltages of the signal frequencies to terminals S and those of the pilots to terminals P.

If an alarm is triggered, it is initially unknown which carrier or pilot frequency is the cause. In order to find the alarming carrier, the direct voltages corresponding to the individual carriers are successively separated from the Alann device by the keys Ta. If the defective carrier is separated. the alarm goes off immediately. If the keys Ta are provided with changeover contacts, the respective carrier voltage can also be measured using the instrument J against a reference voltage generated by the Zener diode R 10, R 10 ', R 10 " and Rv 3 zero-point occurs, the carrier voltage source T by measuring at the nominal level is not at all and otherwise negligibly strained. z. B. supplied through a separately from the outside, taken from the calibration voltage source e calibration voltage 10 volts can be across the series diode D 1 ... D n check the threshold point of the alarm device from time to time by short-circuiting e.g. at pr Characteristic curves of the decoupling diodes DI ... D n from their blocking to their transmission range, the alarm device has the property that at the same time itigen reaching the alarm threshold by several carriers and triggering the alarm by a carrier, the alarm cannot be easily deleted again when the defective carrier is found, because the circuit is subject to a more or less large hysteresis depending on the size of R 8. This indicates to the operating personnel that further carriers are standing at the Alann threshold and must be readjusted.

For pilot voltage sources in particular, both a negative and a positive deviation alarm is required. With the circuit arrangement according to F 1 g. 2, according to which two oppositely polarized DC voltages + A, -A proportional to the pilot voltage are applied to the switching transistor arrangement according to FIG. 1 via the decoupling diodes Dl ... Dn, a multiple-plus-minus alarming of pilot voltages can be implemented. In those cases in which a reliable function of the circuit must still be guaranteed by specifying the size of the supply voltage -B, + B or its minus tolerance of the power loss of the transistor T2 and the alarm relay sensitivity, it is advantageous to use a circuit arrangement according to FIG. 3 , because in the switched-through state, practically the full supply voltage is then applied to the relay coil of the alarm relay Rs and not a voltage reduced by the Zener voltage of the diode RL 1. In order to achieve approximately the same sensitivity with the circuit according to FIG. 3 as with the circuit according to FIG. 1 , a further Zener diode RL7 must be used in the voltage divider for the base-emitter path of the transistor T2 because of its steepening effect instead of an ohmic resistance use.

Is replaced in the circuit of Fig. 1 or 3, the voltage divider resistors R2 ... R5 or a portion thereof by a strong negative temperature dependent resistor, which is led out as the temperature sensor from the circuit arrangement, one obtains a temperature regulator which z. B. is well suited for keeping the temperature of quartz thermostats constant to a few tenths of a degree. In order to make such a control circuit completely relay-free, the winding resistance of the relay coil can also be replaced directly by the heating resistance of the thermostat.

The sensitivity of the circuit arrangements according to FIGS. 1 to 3 can be increased considerably for special applications of voltage monitoring by the fact that the voltage to be monitored via voltage-dependent resistors, e.g. B. Zener diodes, turns on.

Claims (2)

Claims: 1. Circuit arrangement for monitoring a large number of voltage sources for the carrier, pilot and / or signal frequencies in multi-channel carrier frequency systems, in particular in multi-channel carrier frequency telephone systems, using a transistor circuit, the input of which is through a parallel to the power supply source of the The voltage divider lying in the transistor circuit and the output of which is formed by a control element in the collector circuit, in particular by a rectifier-bridged relay, characterized in that the base of a first transistor (T1) is directly connected to a voltage divider point near the positive pole of the power supply source, the collector via a resistor (R9) with a voltage dividing point near the negative pole of the power supply source and via a further resistor (R7), in particular a Zener diode (RL7), with the base of a second transistor (T2) and the emitter of the first transistor (T1) either d is directly connected to the emitter of the second transistor (T2) and via a voltage divider, consisting of a resistor (R 8) and a Zener diode (RL1), to the positive pole of the power supply source - with the midpoint of this voltage divider (R8, RL 1 ) via another resistor (Rv 1) on the negative pole and the base of the second transistor (T 2) via resistors (R 6, R 6) on the positive pole of the power supply source or the emitter of the first transistor (T1) - via a Zener diode with the Emitter of the second transistor is connected, with a resistor (Rv 1!) The emitter of the first transistor (T1) to the negative pole and a. Another resistor (R8 ') connects the emitter of the second transistor (T2) to the positive pole of the power supply source and another resistor (R 6 ") is arranged between the base and emitter of the second transistor (T2) - and at at least one tap of the voltage divider on input are each one or more diodes (D 1 ... Dn) is turned on, on the which are to be monitored voltages, in particular the effective value of proportional voltages to be monitored carrier DC voltages fed. 2. Circuit arrangement according to claim 1, characterized in that the collector and / or the base of the first transistor are connected to the positive pole of the power supply source by means of capacitors. 3. Circuit arrangement according to one of claims 1 and 2, characterized in that to be applied to the input voltage dividing DC voltages from the carrier voltages derived by full-wave rectification, and are applied via a respective change-over switch in such a way to the input of the transistor circuit, that the. The positive pole of these DC voltages is connected to the positive pole of the power supply source and the negative pole of the rectifier circuit via the associated changeover switch and a diode each in operation at a voltage divider point corresponding to the desired response sensitivity and can be switched over to a voltage measuring device, preferably with compensation voltage, if necessary, especially in the event of a fault. 4. A circuit arrangement as claimed in claim 1 or 2 characterized eichnet that a zweimahge full-wave rectification is provided so as for the carrier voltage that appears at the output to a center point, depending an the center of symmetry lying DC potential that is supplied to the input voltage divider of the transistor circuit so that the The center point is connected directly to a voltage divider point, in particular to that voltage divider point at which the base of the first transistor is also connected, while the symmetrical starting points are connected to further voltage divider points via rectifiers and, if necessary, via additional changeover switches. 5. Circuit arrangement according to one of the preceding claims, characterized in that a calibration voltage source is provided which can be connected either via a diode to a voltage divider point of the transistor circuit or to the measuring device. 6. Circuit arrangement according to one of the preceding claims, characterized in that a Zener diode (RL2) is connected between the first point of the voltage divider at the input and the positive pole of the power supply source. Documents considered: German Auslegeschrift No. 1075 714.