DE916183C - Circuit arrangement for two-way connections - Google Patents

Description

Circuit arrangement for two-way connections With the previously common Two-way connection circuits is in the wires of the two to the subscriber stations of the Two-way connection leading branch lines each switched on a switch relay, the for reasons of symmetry, usually two identical windings distributed over the two cores owns. This relay is necessary in order to establish a connection with one of the two participants or when initiating a connection on the part one of these participants the other participant from the common connection line to disconnect for mediation, to keep it disconnected during the conversation and finally to restore the idle state when the call is ended, d. H. a State in which both participants are equally capable of an outgoing Initiate a call or can be called. As in the usual mode of operation In these systems, the call circuit also runs over the windings of the switch relay, which do not yet respond in this circuit and, on the other hand, the switch relay The switch relays must not drop out during the dialing pulse interruptions be dimensioned in a very specific way in order to meet the various requirements. Since the relays for bridging the pulse interruptions work with a delay must, there is inevitably a winding resistance for them that is below a certain value cannot be reduced, but which is already a considerable one Causes weakening of the microphone supply current. As a result, two-way connections cannot be operated over the same maximum length of the connecting cable how normal single connections. It is primarily this disadvantage that has so far been widespread Use of two-way connections counteracted this.

Attempts have already been made to make this resistance as small as possible, the suggestions made in this regard, however, are not of any importance Improvement. In addition, circuits are known in which the switch relay is not in the speech arteries, but in a grounded branch. These circuits but make the subscriber loop highly asymmetrical and, as a result of the associated disadvantages have been found to be inexpedient in practice.

The invention is based on the object of a two-way connection circuit to create at softer without affecting the symmetry of the subscriber loop a weakening of the microphone feed current is avoided. This is according to the invention achieved by using latching relays as switch relays, their windings can be switched over when excited so that they do not or consume a current that practically does not weaken the microphone feed current. as Latching relay is a relay that also has its armature after excitation when the excitation current is switched off, it is kept attracted by magnetic interference.

In order to throw off such a relay, a certain one is required Counter-excitation, which must not be so strong that the relay drops out responds again immediately. Relays have already been proposed and tested in practice that fully meet these requirements. When using such relays too The above purpose, it is therefore only necessary, the relay after his when the connection is switched through, responding to the connection line to connect that the supply current, whose direction yes for each of the two connections is fixed, none of the associated switch relay windings flow through. This task can be solved in a variety of ways, e.g. B. by the fact that the discard winding in series with means acting as blocking for direct current on a wire or between switches both wires. Such means are, for example, capacitors or rectifiers. The release, d. H. the switch relay drops out again by reversing the direction of the current on the connection line or by a corresponding capacitor charge or discharge or reloading. Some embodiments of such circuits are in following with reference to the circuit diagrams of FIGS. i to q. described in more detail.

Since in all examples the way in which the operating and supply voltages in the office is practically the same, the relevant were Office facilities are shown only schematically, and only in Fig. I on the right side of the schematic. This part was used in all other figures omitted from the circuit. The switching devices of the so-called changeover switch Urn or additional box, which is arranged at the subscriber-side end of the connection line are, on the other hand, fully reproduced. The basic principle of the invention is shown in Fig. i. Of the official facilities, only relay R is shown, about its. Windings in the idle state on both wires of the connection line negative potential is applied, as well as the feed relays of the first group selector, via which the Microphone feed current is fed to the subscriber stations. Instead of an R relay can also have two separate ones depending on the requirements of the transmission circuit Relay kick. There are also contacts of the through switch relay T, not shown shown and indicated that the veins in the transmission depending on which of the two places of the two-way connection is to be connected, switched through smoothly or be crossed.

The external switch consists of only one switch relay U ,. or U @ for the two subscriber lines; whose tasks are well known and two capacitors and two resistors. The turnout relay are designed as latching relays, which is indicated by the in the relay symbol black triangle is expressed.

The turnout relays each have two windings, one of which (i / z) is used as a pick-up winding, the other (A) as a disconnecting winding. For the reasons given below, a capacitor is connected in parallel to the pull-in winding, while the drop-out winding is connected in series with a high-value resistor between a wire of the connecting line AL and earth. Both windings are on the same wire and are switched in opposite directions. Briefly, the operation of the circuit is as follows: When the system is idle, negative potential is present via the windings of the R relay on both wires of the connection line and thus also on the dropping windings of the switch relay. As a result of the high-ohmic resistances W or W., whose resistance value is in the order of magnitude of the insulation resistance of the connection line, the switch relays in this circuit cannot respond. If a participant, e.g. B. Participant Tizl, from, the following circuit is created: negative voltage in the transmission, R, t ', a-wire of the AL, ' t2 ', Tnl, 2t2 ' , 1t ''; Ul (2 / i), earth.

Depending on how the transmission is switched, the relay U1 can respond in this circuit, or it must first carry fault current. In most known circuits, the latter is common, since the ground connection at the subscriber station must remain as an incentive criterion until the connection to the subsequent connecting element has been carried out in the transmission. If U1 were to respond immediately in such a circuit, the connection to earth would not be guaranteed due to the associated ground disconnection. It is therefore assumed here and in the following examples that the switch relay initially carries fault current. In the above-mentioned circuit, the R-relay responds only in the transmission, which brings a T-relay into effect in a manner not shown and thus switches the connection line through to the feed relays A and .B of the group selector. As a result of the lower resistance of the feed relay compared to the R relay, the turnout relay in the circuit -, A, t ', a-wire, u2 ", Tnl, u2"', u'1, U1 (2 / i), Address earth, whereupon it immediately disconnects its excitation winding by switching the follow-up normally open contact ui. In order to ensure a reliable pull-through of the relay, a capacitor of suitable rating is connected in parallel to the pick-up winding, which is already charged to a partial voltage in the stimulus circuit and is charged to practically the full supply voltage when switched through, before the relay responds and as soon as the pick-up circuit is activated Contact u1 'is opened, discharging in the sense of pick-up excitation via winding i / 2 of relay U1. After the switch has been activated, the switch relay is de-energized, but as a latching relay it keeps its armature attracted by means of magnetic remanence. The subscriber line is now switched through to contact u1 '. The second subscriber line, however, is separated by the contacts ui 'and ui ". The subscriber station Tnl is supplied with the full supply current, since there are no relay windings in the voice wires and the branch with the holding winding is so high-resistance that it practically does not weaken the supply current Since the discarding windings are connected to the common connecting line before the fork, namely one winding for each wire, the circuit of the speech loop is also completely symmetrical.

Since the drop winding is grounded and connected to the wire to which the im Office is also earth potential, it is due to the loop interruptions occurring during the election unaffected. In the call state, the branch forms with the discarding winding a voltage divider, the branch point of which is about half the supply potential. Since the discharge winding is switched in the opposite direction to the pull-in winding, it is thereby already pre-tensioned in terms of throwing off. But the potential mentioned is not enough from throwing off the relay, this only happens when the relay is triggered caused voltage increase to almost full supply voltage. The release takes place by hanging up the subscriber, which on the one hand creates the speech loop at the subscriber station is interrupted and thus the lanyards are released in the office. The T-relay also drops out in the transmission, so that instead of the earth potential Negative potential is switched to the b-wire. This voltage is provided by the turnout relay to fall, whereby the rest position is restored. The processes involved in the Connection establishment with the second subscriber station are the same, only are in this case the veins crossed in the office, so that on the a-vein earth and on the b-core negative potential is.

Another implementation option, in which the trigger criterion such as in the arrangement just described, a change in polarity in the transmission of the office is used, but during the call the discharge winding is also de-energized, shows Fig. 2. In this circuit, the pull-in winding is connected exactly as before. The discarding winding, on the other hand, is in a grounded branch next to it Winding in series connection a capacitor C3 or C4 and the parallel connection from a high-resistance resistor W. or W2 and a rectifier Grl or Gr, contains. These ejector windings are also connected in the opposite direction to the pull-in winding. The switching processes when a connection is initiated up to the excitation of the switch relay when switching through to the group selector are the same as before and are therefore not repeated in detail. Is in the call state if subscriber Tnl speaks, negative potential on the a-wire and earth potential on the b-wire. The capacitors C3 and C4 prevent the supply current from weakening. Here is the capacitor C3 charged to about half the supply voltage as a result of the voltage division. In the Choice has the interruption of the loop via the intercom a further drop the charging voltage, which is carried out via the very high resistance W1, because the rectifier Grl has a blocking effect on the discharge current. As a result, goes discharge takes place very slowly and is interrupted when the loop closes again, whereby the capacitor quickly opens again via the rectifier in the forward direction its previous potential is brought. The election impulses only arise slight voltage fluctuations on the dropout winding of the switch relay which this winding remains unaffected.

When tripping, the capacitor is first opened by disconnecting the The loop at the intercom continues to be discharged as soon as it is in the trunk transmission the T-relay drops out, the earth potential is separated from the b-wire and for it Negative potential switched on. This results in rapid charging of the capacitor to practically full voltage, with the counter-winding U1 (3 / q.) becoming effective and throws off the anchor held by remanence. The idle state is now restored.

The two circuits described above achieve the desired result A goal with an extremely low cost of switching elements, which is practically not goes beyond what has been customary up to now. But they also have the known ones Circuits also suffer from the disadvantage that by changing the polarity when the alarm capacitor is triggered in the subscriber station that is not connected when they are switched on again is charged relatively quickly and a short striking of the alarm clock. This alarm clock can be used with the practically hardly avoid the triggering principle described. This disadvantage can be but avoid using any other trip principle, such as the one below show the circuit examples described.

The box circuit according to FIG. 3 also has only one switch relay per subscriber station, whose pull-in winding as before to a wire of the assigned Subscriber line is connected and grounded via its own contact. These However, as will be shown, the winding also serves as a discarding winding. Furthermore, a Graetz circuit of dry rectifiers is provided in which Diagonal a holding winding of the respectively energized turnout relay placed is, while the corner points of the other diagonal with the interposition of a Capacitor are connected to the two wires of the connecting line. The mode of action this Schaltuni is the following: When hanging a participant, z. B of the participant i, the associated switch relay Ui is excited in the following way: earth, uiIII 2, Ui (1/2), Tni, u21 2, a-wire, minus in the transmission.

Relay Ui closes the subscriber loop at contact% III i, opens the subscriber line of the subscriber Tn2 with contact uiI 2 and interrupts its own excitation circuit by switching off the earth at contact% III 2. Das Relay U1 is still held by magnetic remanence. The safe anchor passage is achieved as before by the parallel capacitor C1. This capacitor can if the circuit containing the holding winding is suitably dimensioned, this is also omitted. The safe passage of the relay is then activated when the contact ulII resp. u2II achieved by the corresponding holding winding. By closing the contact uiI i is the pull-in winding 1/2 via a high-resistance Wl in a bridge laid to the wires of the connecting cable.

The resistance of W, is in the order of magnitude of the derivative the entire speech line. During the speech connection, therefore, flows over the cross-branch as a result of the parallel connection of the relatively low-resistance subscriber loop a vanishingly small current, which is contrary to the pick-up current of the switch relay is directed, but in no way can throw off the relay and also no noticeable Weakening of the supply current for the intercom. The relay is however dimensioned so that it is increased when the intercom loop is interrupted by the Electricity is shed.

However, this does not apply to the impulsive interruptions the loop takes place during the selection, the switch relay must during these interruptions being held. The rectifier bridge mentioned above is provided for this purpose, in whose diagonal a holding winding when the relay U1 is excited via contact uIII Ui (5/6) has been switched. The holding winding is due to the selection on the capacitor resulting alternating voltage flowed through by a direct current in a manner known per se, which affects the relay in the same way as before the pick-up current, namely by appropriate dimensioning of this holding winding to such an extent that the counter-excitation via the winding i / 2 cannot have any effect. When hooking up the participant however, which represents a permanent loop break, is after doing this generated a simple direct current pulse in the holding relay, the counter-excitation in the winding U1 (1/2) effective and relay U1 is dropped.

At this point in time there is still earth potential on the b-wire in the office, so that after the second subscriber station is switched on again, on its a-wire as well The alarm clock capacitor has not been charged. This only occurs then on, if there is negative potential again during the subsequent tripping of the exchange facilities is placed in the transmission to both wires of the connecting cable. Thereby leaves But you can easily prevent the alarm from going off if you do this in a known manner Turns on potential gradually.

In this circuit, too, there is a weakness in the supply current Avoided during a call The switching of the holding circuit does not consume anything Current, since it is blocked for direct current by the capacitor C3.

In the embodiment according to FIG. 4, there is a side box circuit as before from two switch relays with one pick-up and one release winding each; a high resistance resistor, a rectifier and three capacitors, one of which two in the manner already described to support the pull-in of the relay while the third is used to effect the release. They also have Turnout relay has a third winding, the meaning of which is explained below target.

As in all other examples, the pick-up winding 5/6 of the switch relay is connected to a wire of the subscriber connection cable to earth. The drop winding i / 2 is in series with the capacitor C3 and the parallel connection of the high-ohmic resistor W with the rectifier Grr between the wires of the connecting line, the capacitor preventing a direct current flow over this shunt arm. The series connection of a capacitor with a third winding 3/4 connected in opposition to the pull-in winding is parallel to the pull-in winding.

The mode of operation of the arrangement is as follows: If subscriber Tnl unhooks, voltage is applied to the pull-in winding Uz 5/6. At the same time, the Capacitor Cl charged. The charging current causes a counter-excitation in the winding 3/4 of the relay Ui and thus delays its pick-up. As soon as relay Ui its anchor starts to pick up and contact% I opens, the excitation circuit becomes interrupted for Ui 5/6. By the: discharge current of the capacitor, which is now both Windings 3/4 and 5/6 flows through in the same direction, but becomes a safe passage of the relay armature achieved because the winding -3/4 increases the pull-in ampere turns brings with it. This measure can also be used in all other exemplary embodiments be applied. After it has picked up, the relay is held in place by its magnetic Remanence. In a manner already described several times, when the turnout relay is activated the disconnection of the second microphone unit and the activation by switching it on the discard winding Ui i / 2 (via contacts uiIII,% II i and u2III). in the Conversation status there are no switching means in the speech loop, which one could cause additional weakening of the microphone memory current.

After the connection to the feed relay has been switched through the a-wire negative potential and the b-wire earth. This will make the capacitor C3 via the high-resistance parallel resistor to the rectifier, which is blocking in this state slow charged because of the existing loop connection via the call station due to the voltage drop at this only to one potential, which is a fraction of the supply voltage. With the usual supply voltage of 6o V and assuming normal line and call station resistances are closed In the loop with a voltage of about 10 V between points x and y. As soon as the participant begins to vote, there is another one with each interruption slow charging via the high-ohmic resistor, but it does so with each subsequent one Loop closure is interrupted and a rapid re-discharge of the grain capacitor on the output voltage via the rectifier permeable to the discharge current leads. However, these discharge currents are too small to have an effect on the discarding winding bring to.

The connection is triggered in the following way: If the subscriber hangs up and thus permanently interrupts the speech current loop, the capacitor C is first charged further via the resistor W. The charging current flowing has the same direction as the pick-up current, i.e. the relay can don't make them fall off. However, as soon as the tripping has progressed so far in the central office that the T relay of the transmission moves back its contacts, a discharge circuit is closed for the capacitor C3, which has meanwhile been charged almost to full battery voltage, which is dependent on the positive assignment of the capacitor via Gr, Ui i / 2, u1111, b-wire, t ", both R-windings in series, t ', a-wire, u2III, ulII x runs to the negative assignment of the capacitor. Since the resistance of this discharge circuit is considerably lower than that of the charge circuit, it flows in Strong discharge current in the charging current in the opposite direction through the dropping winding of the switch relay, which overcomes the remanence and throws off the relay. A renewed response of the relay due to the discharge current that may still be present is prevented by opening the discharge circuit at the contacts ulIII and ulII i If the switch relay Ui drops out, the idle state is restored.

An alarm clock in the second call station can also be triggered on this one Circuit in a simple way by gradually applying the negative voltage to the both cores in the transmission are prevented.

In the circuit examples described above, in which the drop winding in series with a high resistance (W1, WZ in Fig. i and 3) during the conversation is on one wire or between the two wires, this resistance can also be called voltage-dependent resistance can be formed when in the call state applied voltage is very high resistance, but at the higher release voltage becomes low resistance. Rectifiers or, for example, come as such resistors temperature-dependent resistors (NTC thermistors) in question, their starting voltage is higher lies than the voltage occurring during the conversation, but is lower than the voltage that occurs during tripping. Besides those described above Circuits for two-way connections are further such circuit arrangements With the help of latching relays, which also weaken the microphone feed current by the ones required for switching between the two connection points Switching means is avoided.

Claims (24)

PATENT CLAIMS: i. Circuit arrangement for two-way connections with a subscriber loop that is symmetrical in the call state, characterized in that latching relays are used as switch relays, the windings of which are switched when the call is made so that they do not consume any current or a current which practically does not weaken the microphone feed current. 2. Circuit arrangement according to claim i, characterized characterized in that when a latching relay is excited, a winding of the same is carried out in this way Via DC blocking means to one wire or between both wires of the connection line is switched that the supply current for the connected subscriber station this Winding cannot flow through. 3. Circuit arrangement according to claim i and 2 thereby characterized in that rectifiers and / or capacitors are used as blocking switching means and that the excitation of the latching relay winding connected in series with these means (Discarding winding) through current reversal on the connection line or through capacitor charging, - unloading or reloading takes place. q .. Circuit arrangement according to claims i to 3, characterized in that a change in polarity of the over as a trigger criterion the connecting line of transmitted direct current in the transmission at the office serves. 5. Circuit arrangement according to claim i to 3, characterized in that as a triggering criterion, the interruption of the subscriber loop in the connected Subscriber station of the two-way connection is used. 6. Circuit arrangement according to claim z to 3, characterized in that a loop closure in is used for official transfer. 7. Circuit arrangement according to claim i and q :; characterized in that the drop winding has a high resistance is connected to a wire of the connecting cable. B. Circuit arrangement according to Claims i and 7, characterized in that the drop windings of both switch relays to achieve a symmetrical connection to one of the two wires of the connecting cable are connected. G. Circuit arrangement according to Claim 7, characterized in that that the high resistance of the order of magnitude of the insulation resistance Connecting line is. ok Circuit arrangement according to Claim i, characterized in that that the excitation winding of each switch relay between a wire of the associated Subscriber line and earth is connected. ii. Circuit arrangement according to Claim iundio, characterized in that that the switch relay its excitation winding when responding to the subscriber line separates. i2. Circuit arrangement according to Claims 1 to 3 and 5, characterized in that that the same winding serves as the pull-in and drop-off winding. 13. Circuit arrangement according to claim i and io to i2, characterized in that the excitation winding des Switch relay a capacitor of suitable size is connected in parallel. 14. Circuit arrangement according to claims i and io to i2, characterized in that in series with the capacitor another winding of the switch relay is switched in the opposite direction to the excitation winding is. 15. Circuit arrangement according to claim i to 4, characterized in that the drop winding in series with a capacitor and a resistor, consisting of from the parallel connection of an ohmic resistor and a dry rectifier, is connected between a wire of the connection line and earth. 16. Circuit arrangement according to claims i to 4 and 1o to 15, characterized in that the tightening and the dropping windings of the switch relay to the same wire of the subscriber connection or connecting line are connected. 17. Circuit arrangement according to claim i and 12, characterized in that the switch relay has its excitation winding when Response toggles so that it is in series with a high-value resistor between the wires of the subscriber connection line. 18. Circuit arrangement according to claim 12 and 17, characterized by a Graetz circuit of dry rectifiers, in one diagonal there is a winding of the switch relay serving as a holding winding lies, while the corner points of the other diagonal with the interposition of a Capacitor are connected to the two wires of the connecting cable. ig. Circuit arrangement according to claim 18, characterized by the use of the same rectifier bridge for the holding windings of both turnout relays. 2o. Circuit arrangement according to claim i to 3 and 6, characterized in that the dropping windings of the switch relay each in series with a capacitor and the parallel connection of a rectifier and an ohmic resistor connected between the wires of the connecting line are. 21. Circuit arrangement according to claim 2o, characterized in that for Both crossover relays have the same capacitor and the same rectifier resistor arrangement are used. 22. Circuit arrangement according to claim 7 and g or 12 and 17, characterized characterized in that the resistor connected in series with the drop winding is on voltage-dependent resistance is its resistance when in the conversation state occurring voltage high, in contrast to the voltage occurring during tripping is low. 23. Circuit arrangement according to claim 22, characterized in that a temperature-dependent resistor (NTC thermistor) as a voltage-dependent resistor is used, its starting voltage between the in the call state and the Tripping occurring voltages. 24. Circuit arrangement according to claim 22, characterized in that a corresponding voltage-dependent resistor sized rectifier is used.