DE1112761B - Circuit arrangement for telecommunication, in particular telephone systems - Google Patents

Description

Circuit arrangement for telecommunications, in particular telephone systems The invention relates to telecommunications systems, in particular telephone systems, in which the monitoring of switching elements by current and / or voltage-dependent Switching means, preferably relays, takes place.

In telephony systems, central switching devices, z. B. central adjustment members used in the course of a connection establishment can only be used for a short time. Monitoring devices are used in such central setting elements are used to control the duration of use. So it is already known switch off a drop-out delayed monitoring relay over the entire occupancy time. Normally, however, the monitoring relay must not drop out. The corresponding Fall time delay is achieved with the help of a charged capacitor. the The fall time delay is at least as great as the central setting element in the In the worst case scenario, the setting process takes time. Long-term occupancies the central adjusting member, e.g. B. if no connection due to an error comes about are ended when the monitoring relay drops out.

Furthermore monitor the used in the central adjusting elements Monitoring devices the re-allocation of the relevant central device. After completing the setting functions, the central setting elements should if possible will soon be activated again for a new occupancy. But before that can happen can, the above-mentioned capacitor must be recharged so that the required The release time delay of the monitoring relay is guaranteed. This requirement was previously through a fixed release time delay of the occupancy relay by means of Fulfilled field attenuation, which is so strong that a completely discharged capacitor could be recharged with certainty during this time.

The delay determined by the maximum charging time of the capacitor the ability to re-assign the central adjustment member presents a certain disadvantage because with the largest part of all assignments the capacitor actually only for Part is unloaded, depending on the different occupancy time of the central adjusting member. The occupancy time of the central facility is thereby unnecessarily extended. In order to keep the charging time of the capacitor as short as possible, the aim was to keep the ohmic resistance of the charging circuit as small as possible to choose. However, this increased the switching capacity of the switching contact again, for which it had to be interpreted.

The invention is based on the object of shortening the duration of the use of central switching devices. According to the invention, this is achieved in that the switching elements, which determine the maximum occupancy time of the connection device through their time constant, act individually or in groups on the monitoring relays dominating the occupancy circuit in such a way that the change in state (discharge, charge, heating) that occurred during an occupancy, depending on its duration ) this switching element is compensated for the initial state after the specimen and the monitoring relay, which automatically regulates the re-assignment of the connection device, is delayed at most by the duration of this compensation.

To explain the invention, exemplary embodiments of the invention are described with reference to FIGS. 1 to 6. All circuit details that are not necessary for an understanding of the invention have been omitted for the sake of better clarity.

1. In the idle state of the central setting element E , the first monitoring relay ü is switched on via the contact b 1 of the occupancy relay B and the winding 1 of the second monitoring relay AN . The capacitor C is charged. The second monitoring relay AN receives fault current and remains in the rest position. The contact ü of the first monitoring relay ü switches the starting wire an1 of the setting element E through. If a starting pulse arrives via the starting wire at1, the occupancy relay B is switched on. +, p, B, an1, ü, ..., -. Contact b 2 switches on winding II of the second monitoring relay AN . The contact b 1 switches off the first monitoring relay 0 , which, however, is held for the time being due to the discharge current of the capacitor C connected in parallel. The drop-out delay caused by the discharge current of the capacitor C is as great as a successful occupation of the central setting element E lasts as a maximum. When the second monitoring relay AN responds, the contact at 1 disconnects the starting wire, and the contact at 2 closes the holding circuit for the occupancy relay B.

After completion of the setting process of the setting element E , the test relay P, not shown, responds and with its contact p interrupts the holding circuit of the occupancy relay B. The contact b 1 switches on the first monitoring relay Ü and the winding 1 of the second monitoring relay AN . The capacitor C is charged again via contact b 1 and, due to the charging current, causes the second monitoring relay AN to continue to be held. If the current falls below a certain value, at which on the one hand the second monitoring relay AN is still held and, on the other hand, the charging of the capacitor C is almost complete, the second monitoring relay AN drops out and sends the central setting element E by closing the contact to 1 for a renewed assignment free.

In the case of a shorter than the maximum occupancy time of the central setting element E, and this should be the case for the majority of the occupancies, the capacitor C has only been partially discharged. It therefore takes less time to compensate for the loss of charge than if it had been completely discharged. This results in a correspondingly shorter drop-out time of the second monitoring relay AN. The central setting element E can thus be occupied sooner than was possible after the previously customary rigid fall time delay. The lower the charge loss of the capacitor C , the sooner the setting element E will be activated.

If a disturbance occurs in the setting element E , the capacitor C can discharge to such an extent that its discharge current is less than the holding current value of the first monitoring relay ü. The first monitoring relay ü drops out and disconnects the starting circuit by opening the contact Ü. The setting element E can only be occupied again when the occupancy relay B is switched off, the first monitoring relay U is switched on and the second. monitoring relay AN has dropped out after capacitor C has been charged.

The circuit described causes not only a shortening of the occupancy time of the setting element E, but also a reduction of the charging peak current as a result of the connection of the effective inductance of the winding I of the second monitoring relay AN. The reduction in the peak charging current depends on the duration of the excitation gap between the excitation of winding II and winding I of the second monitoring relay AN. The excitation gap results from the operating sequence between the contact b 1, which switches on the charging circuit for the capacitor C, and contact b 2, which switches off the holding winding II of the second monitoring relay AN. Switching time differences between 1 and 4 milliseconds can be achieved. These times are sufficient for an undamped relay to reduce the field to such an extent that there is a noticeable inductive influence. The charging current peak can also be reduced if the contacts bl and b2 switch at the same time. The winding 1 of the second monitoring relay AN is then dimensioned such that a stronger excitation occurs in it than in the holding winding 11.

Fig. 2. In the idle state of the central setting element E , the first monitoring relay ü via the contact b 1 of the occupancy relay B is switched on. The contact ü switches through the starting wire ani. The capacitor C is discharged. When the setting element E is assigned, the assignment relay B is switched on as in the circuit according to FIG. 1 (cf. current flow). The contact b2 closes the charging circuit for the capacitor C, whose charging current continues to hold the first monitoring relay ü , which was switched off by opening the contact b 1 . Contact b 4 switches on the second monitoring relay AN . The occupancy relay B can hold on to 2 via the contact.

The first monitoring relay ü is held by the charging current of the capacitor C until the waste current value of its winding is undershot. The drop-out time delay of the first monitoring relay ü caused by the charging current of the capacitor C is as great as a successful occupation of the central setting element E lasts as a maximum. At the end of the setting process, a relay P, not shown, responds, the contact p of which interrupts the holding circuit of the occupancy relay B. With contact b 1 , the first monitoring relay ü is switched on again, whereby the second monitoring relay AN, which was switched off by opening contact b 4, remains through contact b 3 through the discharge current of capacitor C until the discharge current is less than the Holding current of its winding. The second monitoring relay AN then drops out and, with contact at 1, switches through the starting wire to 1 of the setting element E to receive a new starting pulse.

If the setting element E is occupied beyond the point in time at which the first monitoring relay ü drops out because the charging current of the capacitor C is less than its holding current, then the starting wire an1 is disconnected by opening the contact Ü. Only after the occupancy relay B has dropped, the capacitor C has discharged and the second monitoring relay AN has dropped, the starting wire an1 is released for a new occupancy.

The arrangements according to FIGS. 1 and 2 allow automatic control of the re-allocation. Depending on the duration of the assignment of the setting element E , the re-assignment is delayed. This delay in re-allocation can of course also be used for other purposes, e.g. B. Activation of other switching means and the like Fig. 3. This circuit arrangement differs from the one described in Fig. 1 and 2 fundamentally in that one instead of two monitoring relays and two current-time-dependent switching elements are used instead of one. Since the two current-time-dependent switching elements are used alternately each time the central setting element E is occupied, there is no need to monitor the compensation.

In the idle state of the central setting element E , the capacitor C 2 is switched on and charged via the resistor Wi and the contact w 4. The changeover contacts w llw 2 and w 3lw 4 belong to a switching device, for. B. a selector relay that is switched on after each assignment and controls the switchover.

If a starting pulse arrives via the starting wire at1, the occupancy relay B is energized. With its contact b, it switches the monitoring relay ü parallel with the capacitor C 1. The capacitor C 1 has been charged in the previous assignment. By the discharge of the capacitor Cl the monitoring relay ü responds and closes its contact u 2 the holding circuit for the assignment relay B. After completion of the setting does not open the contact p of an illustrated test relay P the holding circuit of the assignment Relay B. The assignment Relay B opens and switches off the monitoring relay ü with its contact b . The not shown "voters relay öff- net the Kontaktew1. and w4 and closes the contacts w2 and w3. A new assignment of the setting element E can take place immediately via the line an1, because the charged capacitor C2 is immediately available via contact w2 for the excitation of the monitoring relay ü. In the meantime, the capacitor C 1 can be charged via contact w 3 .

Should the holding current value for the monitoring relay ü in the discharge circuit of the capacitor C 1 or C 2 rather fall, z. B. when a fault occurs in the setting member E, as the contact opens p, the opening contact Ü2 separates at the fall of the monitoring relay ü to the hold current circuit of the relay B occupancy. The occupancy relay B releases the setting member in a manner not shown. The selector relay switches the changeover contacts w 1 to w 4 into the opposite switching position. A new occupancy incentive can take place via contact ü 1 via the starting wire an1.

While in the circuit arrangements according to FIGS. 1 and 2, the capacitor C, which delays the fall time of the first monitoring relay Ü, must first be brought back into the state after each occupancy, which is the prerequisite for its function, namely the delay in the fall of the first monitoring relay Ü is, and therefore the Wiederbelegbarkeit of EinsteRgliedes e must be delayed until the capacitor C has again reached its initial state, FIG. 3, when using the circuit according to by using a second current-time-dependent switching element, that a second capacitor, also the Time can be used for a new assignment, which was previously required for restoring the initial state of the capacitor. After each assignment, a fully charged capacitor is made available for the release time delay of the monitoring relay ü . The second capacitor, which was used in the previous occupancy and discharged to a greater or lesser extent, now has the opportunity to recharge. When using two current-time-dependent switching elements, maximum utilization of the setting element E is achieved.

4. Compared to the arrangement according to FIG. 3 , this circuit differs in that the excitation of the monitoring relay ü is not caused by the discharging current of one of the two capacitors C 1 and C2 , but by the charging current of these capacitors. For this purpose, the monitoring relay ü is connected in series with the capacitors C 1 and C 2 via the contacts w 3 and w 4. Is z. If, for example, the relay ü is excited via the contacts b and w 3 and the capacitor C 1 , the capacitor C 2, which was able to charge during the previous assignment, can be discharged via the resistor Wi and the contact w 2.

Fig. 5. NTC thermistors can also be used as current-time-dependent switching elements, which are connected in parallel to the relay whose drop-out time they are to determine. In the circuit shown, the monitoring relay ü after excitation of the occupancy relay B is turned b upon arrival of a firing pulse on the occasion vein an1 by closing of the contact. The contact U2 includes the holding circuit of the relay B. occupancy b with the Contact was also via the contact w 1 with the monitoring relay ü parallel thermistor 1 H turned on. Normally, as already described several times, contact p disconnects the holding circuit for occupancy relay B. Contact b switches off relay U , contact w 1 opens, and contact w2 closes. The contacts wl and w2 are controlled by a selector relay that responds after each assignment. Longer occupations, e.g. B. in the event of a fault, are terminated by the fact that the thermistor H1 becomes conductive after a certain time and brings the monitoring relay ü to waste by short circuit. The contact 112 then switches off the occupancy relay B, whereupon the contact b switches off the relay ü and the thermistor.

While the contacts wl and w2 of the selector relay connect the second NTC thermistor in parallel to the monitoring relay ü , the first NTC thermistor, which was in action when the setting element E was previously assigned, can cool down.

Fig. 6. With the use of PTC thermistors as stroinzeitabhängige switching elements, the control is carried out of the monitoring relay ü in the following manner: The PTC K 1 and K 2 are connected via the changeover w 1 and w 2 with the relay ü connected in series. The switched-on PTC thermistor heats up when current flows through to a certain temperature at which its resistance becomes so great that the relay U receives fault current and drops out. All other processes correspond to those of the circuit according to FIG. 5.

Of course, the circuits in Fig. 5 and 6 can be arranged in such a way that only one thermistor or old conductor is used, analogous to the representations in Fig. 1 and 2. The thermistor or PTC thermistor would have to be cooled in a suitable manner after each assignment, corresponding to the charging process in FIG. 1 or the discharging process in FIG. 2, and the cooling process would have to be monitored in a suitable manner so that the setting element E is only released when the starting temperature is reached.

Claims (2)

PATENT CLAIMS: 1. Circuit arrangement for telecommunication, in particular telephone systems, in which for monitoring preferably the availability of connection devices, eg. B. central setting sets, markers or the like, delay relays are used, the switching time of which is influenced by a certain initial state (charge, discharge, cooling) presupposing current-time-dependent switching elements, characterized in that the maximum occupancy time of the connecting device (E) by their Time constant determining switching elements (C, Fig. 1, 2; C 1, C 2, Fig. 3, 4; H 1, H 2, Fig. 5; K 1, K2, Fig. 6) individually or in groups on the Occupancy circuit dominating monitoring relays (ü, An) act in such a way that the change in state (discharge, charging, heating) of these switching elements that occurred during an occupancy, depending on their duration, is compensated for after the occupancy to the initial state and the monitoring relays, the re-assignability of the connection device self-regulating, delayed at most by the duration of this compensation. 2. Circuit arrangement according to claim 1, characterized in that the switching times of the monitoring relays are influenced by capacitors, NTC thermistors or PTC thermistors (C, C 1, C 2, H 1, H 2, K 1, K2). 3. Circuit arrangement according to claim 1, characterized in that when using only one current-time-dependent switching element, in particular a capacitor (C), and two monitoring relays (Ü, An), the re-assignment of the connecting device by the duration of the compensation of the change in state of the switching element (Fig 1, 2), on the other hand, when using two switching elements (C1, C2 or Hl, H2 or KI, K2) and a single monitoring relay (ü), to which the switching elements are switched on alternately, the connection device is reassigned without a time delay (Fig 3, 4, 5, 6). 4. Circuit arrangement according to claim.3, characterized in that when the connection device to be monitored (E, Fig. 1) is occupied, an occupancy relay (B) is switched on, which switches off the first monitoring relay (U) and switches on the second monitoring relay (AN) . 5. Circuit arrangement according to claim 4, characterized in that the second monitoring relay (AN) closes a holding circuit of the occupancy relay (B), which is interrupted when the second monitoring relay (AN) drops or at the end of an occupancy that is shorter than the maximum permissible occupancy (Contact at 2 or p). 6. Circuit arrangement according to claim 5, characterized in that the monitored connection device (E) can only be occupied when the second monitoring relay (AN) has dropped out and the first monitoring relay (ü) has responded (Fig. 1 and 2). 7. The circuit arrangement according to claim 6, characterized in that a parallel capacitor (C) determines the decay time of the first monitoring relay (UE) and the Wiederbelegbarkeit the monitored connection means (E) by means of the second monitoring relay (AN) is delayed with said capacitor (C ) and the first monitoring relay (t7) is connected in series in a charging circuit (Fig. 1). 8. Circuit arrangement according to claim 7, characterized in that a holding winding (II) of the second monitoring relay ( AN) is switched on during the discharge of the capacitor (C) and switched off during the charging process of the capacitor (C) (Fig. 1). 9. Circuit arrangement according to claim 6, characterized in that a series capacitor (C, Fig. 2) determines the fall time of the first monitoring relay (ü) and the re-assignment of the monitored connecting device (E ) is delayed by means of the second monitoring relay (AN) , which in the discharge circuit of the capacitor (C) is switched. 10. Circuit arrangement according to claim 9, characterized in that the second monitoring relay (AN, Fig. 2) is excited in a holding circuit during the charging process of the capacitor (C). 11. Circuit arrangement according to claim 3, characterized in that two parallel capacitors (C1, C2) determine the fall time of the monitoring relay (ü), one of which is connected to a charging circuit and the other depending on the occupancy relay (B) via the monitoring relay (ü) can discharge (Fig. 3). 12. Circuit arrangement according to claim 11, characterized in that the two parallel capacitors (C 1, C 2) are switched over after each occupancy of the monitored connecting device (E) in such a way that the discharged capacitor is charged and the charged capacitor can be discharged (Fig. 3) . 13. Circuit arrangement according to spoke 3, characterized in that two thermistors (H 1, H2) determine the fall time of the monitoring relay (Ü) , of which only one is always switched on (Fig, 5). 14. Circuit arrangement according to claim 13, characterized in that the two thermistors (H1, H2) are switched over after each occupancy of the monitored connecting device (E) in such a way that the thermistor that is not connected in parallel to the monitoring relay (U) can cool down (Fig. 5). 15. Circuit arrangement according to claim 3, characterized in that two current-time-dependent switching elements (C 1, C 2, K 1, K 2) determine the release time of the monitoring relay (ü), which are alternately connected in series with the monitoring relay (ü) (Fig . 4 and 6). 16. Circuit arrangement according to claim 15, characterized in that two capacitors (C 1, C 2) determine the fall time of the monitoring relay (ü) that in each case one of the two series capacitors (C 1, C 2) via a resistor (Wi) discharged and the other can charge via the monitoring relay (ü) connected in series with it in dependence on the occupancy relay (B) and that after each occupancy of the monitored connecting device (E) the capacitors are switched in such a way that the charged capacitor can discharge and the discharged capacitor can be charged (Fig. 4). 17. Circuit arrangement according to claim 15, characterized in that two PTC thermistors (Kl, K2) are alternately connected in series with the monitoring relay (0 ) for each occupancy, of which the switched on the release time of the relay (Ü) determines and the other can cool down (Fig. 6). Documents considered: German Auslegeschrift No. 1057 662.