DE1144786B - Circuit arrangement for the correction of direct current surges in telecommunication, in particular telephone systems - Google Patents

Description

Circuit arrangement for the correction of direct current surges in telecommunication, in particular telephone systems The invention relates to a circuit arrangement for the correction of dialing pulses through a relay circuit in which a first Relay after each received pulse via a capacitor and a second relay via a second capacitor after the first relay has dropped out in pulses be excited in telecommunications, especially telephone systems.

There are already known surge amelioration devices which can also be referred to as pulse correction circuits.

Among these there are also those who work "elastically", i. That is, which of incoming pulses of unequal duration match the outgoing pulses to one another.

In known circuits of this type two relays are connected to the battery voltage in series with individual capacitors which follows the incoming dialing pulses corresponding to respond in a pulsed manner: During each incoming pulse is a lying with a first of the two relays in series charged retired capacitor via a The rectifier lying parallel to the relay coil is discharged and, after the pulse, as a result of current reversal, it is recharged via the relay coil, whereby the first relay is energized; it responds and drops again after the charging current has subsided. This circuit measure already has the advantage that variations in the duration of the pulses due to different pulse beginnings have no further effect. During the service life of the first relay, a second capacitor connected in series with a second relay and discharged in the idle state is charged and, after the first relay has dropped out, via the winding of the second relay, with which a normally open contact of the second relay and a normally closed contact of the first relay parallel to it is connected in series, discharged again, whereby the second relay responds and drops again after the discharge current of the second capacitor has decayed.

The duration of the corrected transmitted pulse is equal to the idle time of the second relay, through whose contacts the impulses are sent, it is so constant. The duration of the transmitted following each transmitted pulse In these circuits, pause results from the total duration of the received pulse following received pause and the subsequent second received Pulse minus the duration of the transmitted pulse. Time spreads of this total duration affect only the transmitted pause, so that in extreme cases it is the same the response time of the second relay, i.e. too small for impulses and that Impulses can be lost.

Therefore, in further known circuit arrangements, a capacitor and / or resistor is arranged in series in the circuit of the windings of the second relay with the normally open contact of the second relay. If the total duration of the pause following a first received pulse and the subsequent second pulse is particularly short, so that the first relay already responds after the second pulse received by discharging the associated capacitor, while the second relay is still to deliver the first pulse is excited in the discharge circuit of its associated capacitor, a series resistor consisting of the capacitor and / or the resistor is included in this circuit through the opening break contact of the first relay in this discharge circuit, through which the fall time of the second relay and thus the duration of the transmitted pulse is shortened. Since this measure does not guarantee compliance with the required minimum duration for breaks, in other known circuits a holding circuit consisting of normally open contacts connected in series is formed for the first relay, which also prevents premature charging of the capacitor belonging to the first relay will. If the first relay now responds after the second pulse picked up by charging the associated capacitor, while the second relay is still energized in the discharge circuit of its associated capacitor to deliver the first pulse, the first relay is activated via # the series connection of the working contacts energized held and nac 'h drop of the second relay, the charging of the corresponding the first relay capacitor initiated, so that the duration of the emitted subsequently break is determined by the entire corresponding charging fall time of the first relay and by this added response time of the second relay . The measure for the duration of the pause to be sent is therefore the sum of these two times. More precisely, the maximum amount of a pause to be transmitted is given by the lower limit of the total time consisting of a received pulse and a subsequent pause at which the pulse correction circuit should still work properly. This results in the requirement that the fall time of the first relay does not exceed the maximum amount of the pause to be sent minus the response time of the second relay.

The release time of the first relay depends, among other things, on the Number of turns of its winding and the size of the associated capacitor used.

Since the circuit for the drop-out delay of the first relay is also the The response circuit of the same can reduce the discharge caused by the capacitor caused fall time the number of turns of the winding of this relay and the size of the this associated capacitor can only be reduced to such an extent that there is still sufficient response reliability for the relay is guaranteed. The two demands, one of them Compliance with the upper limit of the fall time and the other, compliance with the lower Limits of the reliability of the relay are therefore opposite. That results in use the usual for pulse correction switching relays to ensure that both requirements can only be inadequately fulfilled by a compromise solution and that as a result the armature of the relay does not reach its end position when responding, but what is to be assumed for the formation of a defined release time of the relay.

Therefore, in known circuits, in which for the purpose of degradation the fall time of the first relay, its number of turns and / or the capacity of the assigned capacitor are / is to maintain or even increase A second winding is provided on the first relay to ensure the reliability of the response, via which, the relay During the duration of the received pulses, i.e. during the discharge of the capacitor, is pre-excited. This is a disadvantage in these circuits the expense of a second winding with regard to those in pulse correction circuits commonly used relays provided with step windings. Also can the above-mentioned deficiencies are only insufficiently reduced by this measure.

The release time of the first relay is also dependent on a short circuit which is formed from the winding of the first relay and a rectifier bridging this. 'In all hitherto known circuits, a short circuit is increased by a winding of the first relay whose fall time. This short circuit consists of a winding of the first relay and the rectifier parallel to it, which bridges the winding of the first relay during the received pulses by the discharge current of the associated capacitor flowing through it (see above).

The object of the invention is to remedy the disadvantages mentioned above. This is achieved in that the winding of the first relay with a first Connection to one on the other hand connected to a first pole of the voltage source Resistor and also to a second resistor and to a second terminal Via a further resistor to a second pole of the voltage source on the other hand connected capacitor and that the second connection of the winding and the opposite connection of the second resistor via two individual ones relay own normally closed contacts or via a common relay own normally closed contact and two individual rectifiers connected to these terminals through one Pulse transmission contact can be connected to the other pole of the voltage source.

The invention makes it possible to use the first of the two relays a pulse correction circuit is required if the response reliability is sufficiently high to give a short drop-out time and, in the event of a shortened service life of the relay, the for a defined release time of the relay necessary armature stop with certainty guarantee.

In FIGS. 1 and 2, embodiments of the invention are shown only in the constituent parts that make a significant contribution to the understanding of the invention.

In Fig. 1 , pulses are received via a signal line Z , which are transmitted via a pulse contact i of an upstream switching device S not described in detail. In the idle state, the adjustable capacitor C 1 is charged via the following circuit: 1. +, C 1, W 6, H, W 1, During each pulse, the capacitor C 1 is discharged via the following circuit: 2. +, i, z, h3, G2, W6, Cl, -.

During each pulse, relay H is pre-excited via the following circuit, which means that it does not yet respond. After the end of each pulse, this circuit is at the contact ! separated, and the capacitor C 1 is recharged in circuit 1. Relay H, which was pre-excited via circuit 3 , now responds quickly. After the capacitor C 1 is discharged, relay H drops out again. During the service life of the relay H, the adjustable capacitor C 2, which is discharged in the idle state, is charged via the following circuit: 4. +, hl, k2, W5, C2, After the relay H has dropped out, the capacitor C 2 is charged via the winding of the relay K in discharge in the following circuit: 5. +, C2, h2, K, RelayK responds and drops out again after the capacitor C 2 has discharged. The corrected pulse is transmitted via contacts (not shown) of relay K.

If relay H responds via capacitor C 1 after each received pulse and drops out again after it has been charged, rectifier Gl is in the following short-circuit circuit: 6. W2, Gl, G2, H.

By decay of the charging current in circuit 1, as previously described, a voltage is induced in the windings of the relay H, which would cause an induction current in the short-circuit circuit 6 mentioned, if this were not prevented by the rectifier Gl, which is blocking in this case. This prevents short-circuit damping via the winding of the relay H and thus an additional drop-out delay caused at the drop-out time of the same relay by the charging current through capacitor C 1-.

If, as a result of shortened pulses and shortened pauses, the relay H already responds after a pulse picked up by the discharge of the capacitor Cl , while the relay K is still energized to deliver the previous pulse in the discharge circuit of the capacitor C2 , its fall time is shortened by contact k3, the resistor W4 and the capacitor C3 are included in the circuit 5 , which was disconnected at the contact h 2 when the relay H responded. As a result, the release time of the relay K is shortened in a known manner. During the remainder of the relay K dropping time, which is shortened by the response of the relay H, capacitor C 1 is bridged by contacts h 1, k 1 and via resistor W 3 , so that it is charged via the windings of relay H until after the relay, K has dropped out , d. i.e., until after the end of the transmitted pulse there is a delay. The relay H is meanwhile energized via the following circuit: 7. 1-, hl, kl, W3, H, Wl, After the relay K has dropped out, the capacitor C 1 is charged via the windings of the relay H, as described, causing it to become is delayed to the required extent.

FIG. 2 shows a circuit arrangement similar to that shown in FIG. 1 , in which the effect of the rectifiers G 1, G 2 shown in FIG. 1 is exerted by the contacts h 3 and h 4. These contacts are always open at the same time when the rectifier's blocking property takes effect.

If, as a result of shortened pulses and shortened pauses, the relay H already responds after a pulse picked up by the discharge of the capacitor C 1 , while the relay K is still energized to deliver the previous pulse in the discharge circuit of the capacitors C 2 and C 3 connected in parallel in FIG , the release time of the relay K can be shortened in that when the relay H responds, the capacitor C 3 is switched ineffective by contact h 2.

The further switching operations are not part of the subject matter of the invention and are therefore not explained in more detail.

Claims (2)

PATENT CLAIMS. 1. Circuit arrangement for the correction of dialing pulses by a relay circuit, in which a first relay after each received pulse via a capacitor and a second relay via a second capacitor after each dropping of the first relay are energized in pulses, in telecommunication, in particular telephone equipment, characterized that the winding of the first relay (H) with a first connection (1) to a resistor (W1) connected on the other hand to a first pole (-) of the voltage source and also to a second resistor (W2) and a second connection (2 ) is connected via a further resistor (W 6) to a capacitor (C1) connected on the other hand to a second pole (+) of the voltage source and that the second terminal (2) of the winding and the terminal of the second resistor (W2) facing away from it two individual relay own normally closed contacts (h4, h5) or via a common relay own normally closed contact (h 3) and two i Individual rectifiers connected to these connections can be connected to the other pole of the voltage source through a pulse transmission contact. 2. Circuit arrangement according to claim 1, characterized in that the capacitor (C 1) can be bridged by a series circuit formed from working contacts (hl, kl) of the two relays (H, K) and a resistor (W3).