DE695012C - Ssen by means of alternating current over cordoned off lines in telephone systems - Google Patents

Description

Circuit arrangement for the transmission of current surges by means of alternating current about 'cordoned off lines in telephone systems The present invention relates on a circuit arrangement for the transmission of current surges by means of alternating current on sealed services in telephone systems.

The known arrangements in which the current surges from * one to the frequency of the alternating current used, matched receiving relay are, have the disadvantage that to operate the receiving relay a relatively large energy is required, furthermore the receiving relay only for a certain one Frequency is suitable and finally the duration of a recorded current surge as a result the changing electrical properties between the sending and receiving points lying lines is subject to considerable fluctuations.

The invention is now intended to create the possibility of a sensitive receiving relay that responds to low energy, which also is independent of the frequency of the alternating current. Simultaneously the duration of the recorded power surges inevitably depends on the one at the transmission point generated power surges are made dependent.

For this purpose, the invention makes use of the concept known per se Use to transform the alternating current at the sending point so that half-wave trains in one direction alternating with those in the other direction from the outgoing line end be transmitted to a polarized receiving relay at the incoming line end. Such an arrangement is for a telegraph system with alternating current signals already become known. Alone here the conversion of the alternating current by means of a power distributor controlled by the alternator takes place, the division of which takes place must correspond to the frequency of the machine used, so is the possible application the known arrangement essentially on a single transmission frequency limited. In contrast, the invention allows the facilities of all of the broadcasting station are completely independent of the frequency to use any transmission frequency. The known arrangement is also for the transmission of power surges over telephone lines not suitable because only very specific combinations of half waves are emitted here can be, which also depends on the angular position of the alternator and from are dependent on a marked signal button. In contrast, the invention enables only constant current surges depending on a surge receiving relay to send out with a certain duration of the current surge and the current break. The invention achieves this in that at the outgoing end of the line between the AC power source and the transformer during a current surge rectifier in an alternating sense of direction connected in a bridge to the line cores and thus alternating half-wave trains opposite direction are transmitted over the line, the first of which the armature of the polarized receiving relay at the incoming line end for the purpose of closing of the impulse transmission circuit in the working position and the subsequent half-wave train opposite direction the anchor for the purpose of opening the transmission circle in the Brings rest position.

The accompanying FIGS. I, i a to i c show with omission of all For the invention insignificant circuit details an embodiment the invention.

If the connection line 1! 7L is seized via an upstream selector according to FIG. The relay C closes the following circuit for the delayed releasing relay U by means of its contact ic: earth, contacts ic, 2 a., Winding of relay U, battery, earth. Relay U responds; it opens its contacts 3u, qu and closes its contacts 52c, 61t. As a result, the rectifier GL is placed in the opposite direction in a bridge between the line cores. Relay C causes the transmission of an occupancy current surge via the connecting line VA to the incoming end of the connecting line by temporarily adding a second; -not shown winding of the surge receiving relay A is locally excited; Relay A passes on the current impulse as an alternating current impulse with its contacts 7a and 8a, in the same way; as described below, the setting currents.

The setting current surges, coming from the present group selector, are picked up by the winding 1 of the receiving relay A on the a-wire; In the event of a current impulse, earth is applied to the a-wire in the group selector in pulses. Relay A oscillates when it receives a current impulse: As soon as relay A responds, the alternating current source WQ is applied to the connection line via contacts 7 a and 8 a. The rectifiers GI, which are connected to the line cores via the contacts 511 and 61t, keep the half-waves of one direction away from the transformer winding. The rectifier acts as a shunt for these Hall waves. Thus initially only a few half-waves in the other direction arrive via the. ITL connection line. It is assumed that the rectifier is polarized in such a way that initially only positive half-waves pass through the connecting line. In response to this, the polarized relay J turns its armature at the incoming end of the line and thereby closes contact i. Contact i forwards earth impulses via the a-wire, when the receiving relay A at the outgoing line end responds, the circuit of the relay U is opened by opening the contact 2 a. Relay U drops out after a certain time. The drop-out time of this relay can be set, for example, so that it drops after 30 m / s, assuming a current surge of 60 m / s duration. After the relay U drops out, contacts 5 it -and 6 it are opened and contacts 3 U and 42t are closed. . The rectifier GI is now in the opposite sense as before in the shunt to the transformer winding. There are thus, since the contacts 7 a and 8 a are still closed; now the positive half-waves that were previously transmitted over the line; kept from this and transmitted the half-waves of the opposite negative direction over the line. As a result of these current surges, the polarized receiving relay J is put back again and the current surge is thereby ended. With an alternating current of 50 periods per second: with a current surge duration of 60 mls, ie of 3 periods, as FIG. 1c shows, two positive half-waves and then two half-waves in the opposite direction are transmitted over the line.

The release time of the relay U can of course also be set in this way be that, for example, with an alternating current of 50 Hz: initially three half-waves one t direction and then only a half-wave in the opposite direction about the Line is transferred. The release time of the relay U should -in this case be 50 m / s.

In Fig. I a an arrangement is shown in which the relay U of the Fig. I, which causes the switching of the rectifier Gl, when a Electricity surge is not brought to waste, but to respond. It is then only necessary to achieve a corresponding effect, the response time of the Relay U to be delayed accordingly.

Fig. I b shows an embodiment of the invention in which the polarized receiving relay J of Fig. i by two ordinary DC relays, each provided with a rectifier connected in parallel, is replaced.

The arrangement works in such a way that at the beginning of the current surge over the line given half waves of one direction one of the relays, for example Actuate relay J1 during these half-waves from the second relay, the relay J2, through the rectifier Gl2 connected in parallel to this; about which this Half-waves run, are held.

The half-waves of the opposite one arriving at the end of the current surge Direction then actuate the relay J2 in a corresponding manner, since the to this Relay connected in parallel - rectifier Gl, which blocks the path against these half-waves. They take their way via the rectifier Gll, which is so parallel to the rough relay J1 is connected so that it lets through half waves in this direction.

The transmission of the current surges takes place in that at the beginning of each In the event of a current surge, relay J1 closes its contact il and earth to the a wire applies. Irrespective of whether relay J1 drops out, the current surge is ended by that relay J2 opens its contact i2 at the end of the current impulse and thereby the earth disconnects from the a-wire.

If the current is used as a power supply - frequencies other than 50 Hz, in particular higher frequencies are used, the ratios will become as the frequency increases always cheaper; because, as the Fig. i c can be seen, received the receiving relay with increasing frequency, more and more rectified pulses per current surge, so that the pauses that the relays have to bridge during the half-waves are getting smaller and smaller will.

The principle underlying the invention can not only be used for the ac power choice per se, but also for one in the ac power choice field special task, namely for the identification of different directions of traffic over sealed lines.

Figs. 2, 3, q. and FIG. 5 represent exemplary embodiments for the marking different directions of traffic.

Fig. 2: The connection line VL can be occupied via different accesses will. The test leads of these accesses are marked with cl to c5. These entrances correspond to directions i to 5 at the incoming end of the connection line.

When the connection line is assigned via access cl on the part of of an upstream voter is a short occupancy current surge lasting about 6o m / s given over the connecting line. As Fig. 3a shows, this exists Current surge from an alternating current oscillating in full waves.

If the connection line VL is occupied via the access c2, then again an alternating current surge to identify the direction of traffic 2 over the Connection line given. Fig. 3 b shows that this current surge from a train of half-waves of a certain direction, which is called such a positive direction exist.

If the connection line is occupied via access c3, then comes in AC surge to identify traffic direction 3 via the connecting line, which according to FIG. 3 c from a train of half-waves of the opposite negative Direction exists.

If the connection line VL is occupied via access c4, go, as FIG. 3 d shows, at the beginning of the occupancy current surge, initially a few half-waves positive direction and then a half-wave in negative direction the connecting line.

If the connection line is occupied via wire c ,, go to Marking of the traffic direction 5 at the beginning of the power surge initially a few Half waves in a negative direction and then such a positive direction over the line (Fig. 3 e).

In detail, the switching processes are as follows: When the connection line is occupied via the test wire cl, the relay Cl is energized. Relay Cl closes the following circuit for relay A: earth, contact i cl, winding 1I of relay A, contact 12d, battery, earth. Relay A responds and applies its contacts 3 a and q. a the alternating current source W0 to the transformer Uel. This alternating current surge pulsates in full waves. It reaches the relays J1 'and J2 via the connection line TAL, the transformer Ue. As a result of the rectifiers Gll and Gl connected in parallel to these relays in a certain sense of direction, relay J1 is energized by one half-wave of the alternating current and relay J2 by the other half-waves. Relays J1 and J2 do not drop out during the pauses between the individual half-waves. The pauses are 10 m / s at the frequency of 50 Hz that is usually used for the selection of alternating current. The rectifier lying parallel to each of the surge receiving relays represents a short circuit for the relay, through the effect of which surge pauses of the length mentioned are easily bridged. The alternating current surge. is terminated by relay A closing the following circuit for relay D at the outgoing end of the line: earth, contact 6a, windings of relay D, battery, earth. The relay D responds with a delay after about 60 m / s, so that the current surge is given a sufficient duration. Relay D interrupts the circuit of relay A by opening its contact 12d. Relay A drops out, thereby ending the current surge. Re @ -lais D remains in the following circuit after relay r4 drops out: earth, contacts 7d, 8 cl, winding of relay D, battery, earth.

At the incoming end of the line, as already mentioned, the relays J1 and J2 are energized by the occupancy current surge. This closes the following circuit for relay Z: earth, contacts 649, 42 il, 44y, 5 0 a2, 52 x, winding of relay Z, battery, earth. When relays J1 and J2 respond, the following circuit for occupancy relays B and E is also closed: earth, contacts 69i ,. or parallel 70i., 68e, winding of: relay B; Contacts 66 b; 65 e, resistance Wi; Battery, earth. Relay B interrupts the short circuit for relay E by opening its contact 66 b, which now also responds in series with relay B. After relays J1 and J2 drop out, relays B and E are kept in the following circuit: earth; Contact 71 b, windings of relays B and E; Resistance Wi, battery, earth. After the end of the current surge, relay Z remains in the following circuit independently of relays J1 and J2: Earth, contacts 58 e, 57z; Winding of relay Z, battery, earth. Relay Z closes its contact 59.- and thus occupies the direction of traffic z. Relay G also responds in this circuit. By opening its contact 64g, relay G prevents the switching means provided for identifying the traffic directions from being further influenced by the setting current impulses that continue to arrive during the establishment of the connection: Due to the following current impulses for setting the selector, the winding I of relay A at the outgoing line end of the present Voters excited from impulsively. The current surges are passed on via the connecting line VL as alternating current surges, pulsating in full waves, by temporarily closing the contacts 3 a and 4a. At the incoming end, the relays J1 and J2 are excited by the current surges and the current surges are passed on to the following selectors in a way that is not of further interest here, for example via the a-wire.

The triggering takes place in the usual way with alternating current selection by a long trigger pulse. This is initiated when the occupancy relay C drops out; the relay A is energized in a manner not shown via the winding II for a long time. The contacts 3 a and 4 a give a long alternating current pulse over the connecting line TAL. This will energize relays J, and J2 at the incoming end of the line for a long time. Relay B is short-circuited via contacts 69i and 7o i2 and released. Relay B also interrupts the holding circuit of the relay E in series with it. Relay E therefore drops out after the triggering impulse has ended and initiates the triggering of the holding circuit of relay Z and all other switching means of the transformer Ue.

When the connection line VL is assigned via the wire c2 by an upstream selector, the relays C2 and Cl are energized in series. Relay Cl closes a circuit for the winding TI of relay A. Relay A applies alternating current to the connecting line via its contacts 3 a and 4a: Furthermore, relay A switches on relay D via contact 6 a, which interrupts the occupancy current surge again. Relay C2 closes its contact 13 c2 and thereby bridges the rectifier Gl between the line wires. This creates a short circuit for the negative half-waves of the Wecliselstrom, the current flow of which is as follows: AC power source WQ, contacts 3 a, 32 d, 13 c2, 14c3, 2ok; 16na, rectifier Gl; Resistor Wr, contacts 22 na, 241z, 28c3, 4a, alternating current source WO. The positive half-waves go over the winding of the transformer Uei and thus via the connecting line liL to the transformer Ue, at the incoming end of the line.

These half-waves flow via the relay J2, the rectifier Gll and back to the secondary winding of the transformer Ue2. The rectifier Gl2, which is parallel to relay J2, blocks these half-waves. Relay J2 closes the following circuit. Earth, contacts 649, 40.i1, 41 i2, winding of relay Y, battery, earth. At the same time, via Kon-. clock 70 i2 energizes relays B and E, which are maintained during the entire connection. After waste. -of relay J2, relay Y is in the following circuit: earth, contacts 43 e, 48y, 73 q, winding of relay Y, battery, earth. The relay Y closes its contact 6o y and thus occupies the traffic direction 2. Relay G again responds in the occupancy circuit. By opening its contact 649, relay G prevents the relay provided for directional identification from being influenced by the further current surges.

The impulses and tripping are carried out in the same way as already described. When the connection line VI is occupied via the wire c3, the relays C3 and Cl are energized at the outgoing end of the line. Relay Cl energizes relay A. Relay A applies alternating current to transformer winding Uel by means of its contacts 3a and 4a. Relay C3 switches the rectifier Gl in a bridge to the two line cores, but this time in the opposite direction as when the traffic direction is marked 2. The rectifier thus represents a shunt for the positive half-waves (FIG. 3c). The shunt runs as follows: alternating current source WQ, contacts 4a, 33d, i8 c3, 2o k, 16m, rectifier Gl, resistor ff / r, contacts 22m, 24 k, 27 c3, 3 a, alternating current source WQ. Only negative current surges pass through the transformer windings Uel. These energize relay J at the incoming end of the line, in the following circuit: Secondary transformer windings Ue2, winding of relay J1, rectifier Gl2, secondary transformer windings Ue, the rectifier Gl lying parallel to relay J, blocks the incoming half-waves in this case . Relay J, closes the following circuit: earth, contacts 64 g, 42 i1, 44Y, 45 i2, winding. of relay X, battery, earth. Relay J1 also energizes occupancy relays B and E via contact 69i1. Relay X remains in the following circuit after relay J has dropped out: Earth; Contacts 47 e, 46 x, 72 h, winding of relay X, battery, earth. Relay X occupies traffic direction 3 by closing its contact 61 x. Relay G is again excited in this occupancy circuit. The further switching processes when establishing the connection are carried out as already described.

When the connection line VZ is assigned via wire c4, relays C4 and Cl are energized in series. Relay C1 energizes relay A. Relay A in turn applies alternating current to the connecting line. At the same time the delayed response relay D is energized, which ends the occupancy current surge. Relay C4 bridges the rectifier Gl between the conductors so that a shunt is initially established for the half-waves in the negative direction. The shunt runs as follows: AC power source WQ, contacts 3 , 17, 33, d, 15 c4, 14 c3, 2o h ,. 1 6 m ,. Rectifier Gl, resistor Wr; Contacts 2.2M, 24h, 28c3, 4a, AC power source WQ. Thus, initially only half waves in a positive direction pass through the connecting line (Fig. 3 d). Relay C4 has now closed the following circuit for relay K when it responds: earth, winding of relay K, contacts 9 a, 10 c4, iid, battery, earth. Relay K is a relay that responds with a slight delay. "Its response time is set so that it responds after about 40 m / s. Relay K switches the rectifier Gl after this time in the opposite direction between the line wires ,, i.e. after the relay! I (, responds, the rectifier G1 now forms a shunt for the half-waves in the positive direction (Fig. 3 d). This runs as follows: AC power source WQ, contacts 4a , 21h, 16m , Rectifier Gl, resistor Wr, contacts 22 m, 25 k, 3 a, alternating current source WQ. Subsequent to the train of positive half-waves, those in a negative direction are passed via the connecting line.

At the incoming end, relay 1 is excited by the positive half-wave of relay 1 and then by the negative half-wave of relay J. Relay J2 closes a circuit for relay Y via its contact 41 i2. Relay Y has a response time of approx. 15 m / s. Since relay J2 is energized for a long time, it can respond in this case. At the same time, relays B and E are energized by relay J2. As already described, relay Y is independent of relay J2 via its contact 48y. The negative half-wave arriving after the positive half-waves excites the relay Ji in the incoming transformer Ue2. This closes the following circuit for relay 0: earth, contacts 649, 42 il, 49y, winding of relay 0, battery, earth. Relay O remains in the following circuit after it has responded: earth, contacts 54e, 53 q, winding of relay Q, battery, earth. By closing the contact 62q, the traffic direction 4 is occupied. Relay - Q interrupts the hold circuit of relay Y by opening its contact 73 q.

When connecting line 1% 'L is occupied via access c5, relays C ,, and Cl are energized in series. Relay Cl closes a circuit for winding II of relay A. Relay A applies alternating current to connecting line hL. Relay C5 connects the rectifier Gl in a bridge between the lines, in such a way that initially a shunt is formed for the half-waves in the positive direction (Fig. 3e): The shunt runs as follows: AC power source WQ, contacts 4a, 33d, I gc "2o k, 16 on; rectifier Eq., Resistance Wr, 22m, 24k, 26c5, 3a, alternating current source WO .. So first half-waves in a negative direction arrive via line VL. When relay C5 responds, the following circuit for relay M formed: earth, winding of relay IN; contacts 29 a, 30 c5, 31 d, battery, earth. Relay 11i1 has the same response time as relay 1i, i.e. about 40 mls. It switches rectifier Gl after a number of negative half-waves Direction via the line is transmitted in such a way that now a shunt is formed for these half waves and half waves of positive direction run over the connecting line Ative direction runs as follows: Earth, contacts 3 a, 17 In, rectifier dl, resistor IIJr, contacts 23M, 4a, AC power source: At the incoming end of the line, the half-waves in the negative direction at the beginning of the current surge initially energize relay J, . Relay J1 closes a circuit for relay X via its contact 42 i1 . Its response time, like that of relay 1 ', is about 15 in / s. Relay J1 also wrestles relay B and E via contact 69i to respond. After relay J1 has dropped out, relay X is held, as already described, via its contact 46: e. As soon as a positive half-wave arrives after the negative half-waves, relay J is energized. The following circuit is now closed for relay H: earth; Contacts 64g, 42i1, 44y, 50i-, 51x, winding of relay H, battery, earth. Relay H remains in the following circuit after relays J and J have dropped out: earth, contacts 55 e, 561r., Winding of relay H, battery, earth. Relay H closes its contact 631a and thus occupies traffic direction 5. At the same time, relay H interrupts the hold circuit of relay X through its contact 721r.

It should be mentioned here that instead of the parallel rectifier dl or Gl polarized relays J, and J2 also have two eleli: troinagnetically polarized Receive relays can be used.

It should also be noted that the principle of the invention, namely a number of traffic directions by alternating current of a given frequency mark, of course on the marking of further traffic directions as shown in the exemplary embodiment a or 3 a to 3 d; For example, in order to mark a 6th traffic direction, control relays would have to be used be provided on the outgoing auxiliary relay or on the incoming line end, which following the half-waves shown in FIG. 3 d, first positive and then negative Direction transfer and implement another wave train in positive direction. One 7. Direction of traffic can then be correspondingly more negative with the addition of a wave train Reach direction to the half-wave trains shown in Fig. 3e. For the occupancy impulse Of course, a longer period of time must then be available.

FIGS. 4 and 5 tend to have further exemplary embodiments for the marking different directions of traffic, 3n the basic mode of operation these arrangements do not differ from that of FIGS. 2 or 3 a to 3 e. The order according to FIG. 4 shows a different one only at the outgoing 11th end of the connecting line Arrangement, which serves the transformer Uel before each identification pulse Pre-magnetize in a certain sense. This is necessary because the remanent resulting from the trigger pulse of a previous connection Magnetism of the transformer can have the same direction as the first half-waves nies subsequent identification pulse. The latter would be the magnetization of the transformer then already bring it into the saturation range, which in the absence of sufficient Field change in the secondary winding of the transformer only more current impulses of insufficient Voltage would be induced. For this reason, FIGS. 4 and 5 show arrangements has been taken, by which a pre-magnetization briefly before each occupancy pulse of the outgoing transmitter in each case in one of the following half-waves opposite Sense of direction takes place.

According to Fig. 4, the pre-magnetization of the outgoing transformer takes place by battery direct current, in Fig. 5 by rectified alternating current with the aid the already existing rectifier.

In Figs. 4 and 5, there is only one arrangement for the sake of simplicity shown in which the bias of the outgoing transformer is not occurs before all identification pulses, but only before those power surges, which indicate the directions: 4 and 5 (Fig. 3d, 3e). The expert. results but the way to a corresponding premagnetization is straightforward even to be reached before the other identification pulses.

Fig. Q .: It should be said in advance that for the sake of clarity Two rectifiers GR, and GR2 are provided in place of a single rectifier. However, as in FIG. 3, these can be provided by a single rectifier, which must then be switched accordingly, be replaced.

If the connection line I'L is occupied via the access c4, the relays C4 and Cl located in series respond at the same time. Relay Cl switches on relay A via its contact i cl, which by means of its contacts 3a and 4a applies the alternating current source W0 to the primary windings of the outgoing transformer Uel. Before that, contacts 34c4 and 35 C4 of relay C4. a direct current circuit is closed via the primary winding of the transformer Uel: earth, battery, contacts 34c4, 36c,;, 2a, primary windings of the transformer Ue, contacts 5 a., 39 c, "3 5 C4, resistance, earth Transformer Ue, pre-magnetized in a certain sense, namely the direction of the current is opposite to the direction of the positive half-waves that now follow. The magnetizing circuit is interrupted by the response of relay A, which opens its contacts 2 a and 5 a. At the same time, contact 8ia is also closed, so that the rectifier GR is in a bridge between the lines via the contacts 32 d, 8 1 a, 2o k, 24 k, 1 5 C4.The rectifier GR blocks the positive half-waves and allows the negative half-waves of the alternating current Thus, initially only positive half-waves are transmitted via the transformer Uel and the connecting line i; 'L. Since after some time the delayed responding relay K in follows em circuit is excited: earth, winding of the relay IL, contacts 9a, io c4, iid, battery, earth, the rectifier GR, now via contacts 2 1 k and 25 k in the opposite sense, is connected in a bridge between the lines. As a result, instead of the positive half-waves, negative half-waves are now transmitted via the transmitter target and the connecting line. The delayed response relay D, which is switched on by relay A via contact 6 a, then terminates the pulse.

If the connection line VL is occupied via the access c ,, then the relays C and Cl located in series respond at the same time. Relay Cl switches on relay A via its contact i cl. Relay C ;, includes the following direct current circuit through the primary windings of the outgoing transformer Uel: earth, battery, Wi-lerstand, contacts 38 c ", 5 a, primary windings of the transformer Uel, contacts 2a, 37c5, Earth The direction of this direct current through. which the transformer Uel is premagnetized, is opposite to the direction of the subsequent half-waves of the helegungs, iinpulses. The direct current circuit is interrupted by the response of the relay A, which opens its contacts 2 a and 5 a. At the same time, the contact 8o a is closed, so that the rectifier GR, "via the contacts 33 d, 8o a, 16» b, 22m, i 9 c, "is located in a bridge between the line cores. The rectifier GR2 allows the positive half-waves of the alternating current to pass, while the negative half-waves via the transformer Ue , and the connecting line VL. Since after a while the relay 11 responds in the following circuit: earth, winding of relay 11i1, contacts 29 a, 30 c5, 31 cd, B Atterie, earth, the contacts 16m and 22m are opened, at the same time the contacts i7 iia and 23m are closed. The rectifier GR2 is now in the opposite sense as before in a bridge between the line wires. This has the consequence that now, instead of the negative half-waves, one or more positive half-waves are transmitted via the transformer Ue and the connecting line VL. At the incoming end of the connection line, traffic direction 6 is identified by a sequence of negative and positive half-waves. The identification pulse is terminated by the relay D, which responds with a long delay, as already described.

Fig. 5: If the connection line VL is seized via the access C4, the relays C4 and Cl located in series respond at the same time. Relay C4 closes its contacts 34 c4 and 35 C4 and thereby applies the alternating current source WQ to the line cores via high-ohmic resistances of, for example, 500 ohms each. Since the contacts I2 C4, I5 C4 and 28C4 are also closed at the same time, the rectifier GL is in a bridge to the line cores, in such a way that the positive half-waves via the rectifier GL, the negative half-waves on the other hand via the primary winding of the transformer Ue, get lost. The circuit for the positive half-waves via the rectifier is as follows: AC power source WQ, resistor 5ooo Ohm, contacts 34.c4, 36c, 2a, 32d, 1: 2C4 I8 a1, I 5c4, I6 na, rectifier GL, resistor Wr, contacts 22 , n2, 84.a1, 28C4, 5 a, 39 cs, 35 C4, resistance 5oo ohms, alternating current source WQ. The negative half-waves running over the primary windings of the transformer Uel, which due to the high-ohmic resistances connected upstream of the alternating current source are not so strong that effective current surges reach the connecting line; magnetize the transformer Uel in a certain sense, which is opposite to the subsequent half-waves. The pre-magnetization circuit is interrupted as soon as relay C has energized relay A via contact ic. A relay interrupts open by seinerKontakte2 a and 5 a denvorgenanntenStromkreis: By closing of the contacts 3 a and 5 a is applied anew the Wechselstrornquelle WQ on the conductors, but this time have smaller resistances, for example, each iooo ohms. Relay A also responds in parallel to relay A. This includes its contacts iga, and 85a ,. The rectifier GL is now in the opposite sense as before in a bridge between the line cores. It thus forms a shunt for the negative half-waves: AC source WQ, resistance 100 ohms, contacts .4 a, 13 c5, 22 k 1 9 a, 15 c4, 16m, rectifier Gl, resistance bl'r, contacts 22m, 85a ,, 2.5k, 27c5, 3a, resistance 100 ohms, AC source IVQ. The positive half-waves, which run over the primary windings of the transmitter Ue, induce current surges of sufficiently high voltage, which actuate the receiving relay via the connecting line hL at the incoming end. Relay A restores relay K after a while. Response: End, winding of relay K, contacts 9 a; io c4, iid, battery, earth. Contacts 21k and 24k are closed; the rectifier Gl is now again in a bridge between the line cores that the positive half-waves run through the rectifier, while the negative ones are transmitted through the transformer Ue and the connecting line VL. As can be seen from FIG. marked. The identification pulse is terminated as in Fig. 3 or .4 when relay D responds.

If the connection line L'L is occupied via the access c5, the relays C5 and C, which are in series, respond at the same time. Relay C5 closes its contacts 37 c5 and 38 c5 and thereby applies the alternating current source IhQ to the line wires via the high-resistance resistances of 5000 ohms. Since relay C5 also closes its contacts i 9c5, 20c5 and 26c5 at the same time; so the rectifier GL is in a bridge between the line cores, this time in such a way that the negative half-waves run through the rectifier, while the positive half-waves run through the primary winding of the transformer Uel. The circuit for the negative half-waves is as follows: AC power source WQ, resistor Sooo Ohm, contacts 38c5, 5a, 33d, 14c4, i8 a ,, 2o c5, 16 in, rectifier G1, resistor Wr, contacts 22m, 84a, 1, 29c4, 2 a, 37c5, resistance 5oo ohms, AC power source WQ. As a result of the high-value resistors connected upstream of the alternating current source WQ, the positive half-waves do not transmit any effective current impulses to the line VL, but they are sufficient to pre-magnetize the transformer Uel. The aforementioned magnetizing circuit is interrupted as soon as relay C, via contact ic, energizes relay A. This interrupts the circuit by opening his contacts. 2 a and 5 etc. By closing the contacts 3a and .4a the AC source WQ is applied to the conductors again, but this time Dcalc smaller - resistors such. B. of iöoo ohms each. Since relay A, which opens its contacts iSal and 8.Iat, and closes its contacts igal and 85 a, also responds in parallel with relay A, the rectifier GL is now connected in the reverse direction as before in a bridge between the line cores. It forms a shunt for the positive half-waves: AC source GVQ, resistance iooo Ohm, contacts ß a, 19 c5, 22 lz, 19 a1, 2o c5, 1 6 m, rectifier Gl, resistor Wr, contacts 22 ryc, 85 a ,, 25 h °, 26c5, qa, resistance iooo Ohrn, alternating current source WQ. The negative half-waves are transmitted via the transformer Ue. These induce current surges in the secondary winding, which are transmitted via the connection line to the incoming end and there activate the receiving relay: After a while the relay 1'17 responds: Earth, winding of the relay ill, contacts 29 a, 30 c5, 31 d, Battery, earth. Relay 21 opens its contacts 16 M, 22 m and closes its contacts i7 m and 23 irr. The rectifier G1 is now again in the opposite sense between the line cores, so that the negative half-waves run through the rectifier and the positive ones run through the transformer Uel. However, as FIG. 3 e shows, the traffic direction 5 is identified by a train of half-waves of initially negative and then positive inn pulses. The identification pulse is transmitted through relay D as previously described; completed.

Claims (3)

Pn # rerr # rnNsrRÜCHR: i. Circuit arrangement for the transmission of current surges by means of alternating current via cordoned off lines in telephone systems, characterized in that that at the outgoing end of the line between the alternating current source (Il'Q) and the Transformer (Uel) during a current surge rectifier (G1) in alternating sense of direction connected in a bridge to the line cores and thus alternating half-wave trains opposite direction are transmitted over the line, the first of which the armature of the polarized receiving relay at the incoming line end for the purpose of closing of the impulse transmission circuit in the working position and the subsequent half-wave train opposite direction the anchor for the purpose of opening the transmission circuit in the Brings rest position. 2. Circuit arrangement according to claim i, characterized in that a changeover relay (U) places the rectifier (G1) between the conductors in the opposite direction at the beginning of the occupancy current surge and after some time, but before the termination of the current surge, in the opposite direction. 3. Circuit arrangement according to claim2, characterized in that the rectifier (G1) forms a shunt at the beginning of the a current impulse a number of short pulses in the same direction and then a number of short pulses in the opposite direction. q .. Circuit arrangement according to Claim 2, characterized in that the switching relay (U) is either switched off from a closed circuit by the surge receiving relay (A) at the beginning of a current surge and drops out with a delay or in = an excitation circuit is switched on and responds with a delay (Feg. i , ia). 5. Circuit arrangement according to claim i, characterized in that two DC relays polarized by parallel rectifiers (T1, T2) are influenced (Feg. Ib) by the half-waves transmitted over the connecting line during a current surge at the incoming line end. 6. Circuit arrangement according to Claim 5, characterized in that: ß the relays (1l, T2) lying in series below are in a bridge between the conductors and the rectifiers (Gll, Gl2) are connected in parallel to the relay in such a way that the relay is parallel to the A rectifier connected to a relay blocks the half-waves that are allowed through by the rectifier connected in parallel with the other relay. 7. Circuit arrangement according to Claim 5, characterized in that the relays (h, l2) act as delay relays as a result of the rectifiers (GLl, GL2) connected in parallel and remain energized during the pauses between the individual half-waves. 8. Circuit arrangement according to claim i, characterized in that at the outgoing end of a connecting line (VL) switching means (Cl to C5, GL; A, K, 111) are provided, which are used to identify different traffic directions at the incoming line end depending on the occupied access (cl bis, c5) emit different identification current pulses, consisting of several half-wave trains alternately in opposite directions (FIGS. 2 and 3). G. Circuit arrangement according to Claim 8, characterized in that the current impulses emitted when the connection line is occupied serve to identify the direction. ok Circuit arrangement according to Claim 8, characterized in that the switching means (C4, Q) for the identification of two different traffic directions (q., 5) emit identification current pulses which consist of several half-waves in one direction and subsequent half-waves in the opposite direction (Fig. 3 d; 3 e). ii. Circuit arrangement according to Claim io, characterized in that the switching means for identifying one traffic direction (C4) transmit positive half-waves and then a negative half-cycle, while the switching means for identifying the other traffic direction (C5) transmit negative half-waves and then one cause positive half-wave. 12. Circuit arrangement according to claim 8, characterized in that the half-waves to be transmitted in different succession by means of a single rectifier (G1) which is switched alternately in different senses between the conductors; be generated. 13. Circuit arrangement according to claim 5, 6 and 8, characterized in that switching means are provided at the outgoing and incoming line end which enable the use of the existing alternating current source (WO) to identify further traffic directions (i to 3). 1q .. Circuit arrangement according to claim 13, characterized in that; that the switching means at the outgoing line end (Cl to C3), depending on the occupied access, each characterize a further traffic direction by transmitting full-wave alternating current or by transmitting half-waves in one direction or half-waves in the other direction (Fig. 3 a to 3 c). 15. Circuit arrangement according to claim io and 14, characterized in that the polarized receiving relays (J1; J2) act on the incoming line earth on a relay arrangement (X, Y, Z, H, Q) to identify five different traffic directions. 16. Circuit arrangement according to claim 15, characterized in that a relay is provided in the relay arrangement for 'each traffic direction, wherein (read in each case by the first half-wave (positive or negative) of a identification pulse switched on relay (_Y or Y) a delayed, the duration 17. Circuit arrangement according to claim 1 6, characterized in that the delayed responding relays (X, Y) are excited by a sequence of several half waves in the same direction, whereby when half waves arrive they only have one direction within the identification pulse 18. Circuit arrangement according to Claim 17, characterized in that the relays (X, Y) when they are excited by half-waves in one direction each have an excitation circuit for a further relay (0 or H ) prepare, which in the event of further half-waves in the opposite direction g is closed within an identification pulse and causes the identification of a further traffic direction or 5) by canceling the occupancy of the first traffic direction. . r9. Circuit arrangement according to Claim 9, characterized in that the switching means (C4, C5) at the outgoing line end briefly send direct current via the primary windings of the outgoing transformer (LT, -,) prior to the emission of the identification pulses, each of which has a direction opposite to the first half-waves of the subsequent identification pulse (Fig. 4 and 5). 2o. Circuit arrangement according to Claim i9, characterized in that the switching means connect battery direct current to the primary windings of the outgoing transformer in a direction opposite to the first half-wave, depending on the direction of the first half-waves of the subsequent identification pulse (Fig. 4). 21. Circuit arrangement according to claim ig, characterized in that the switching means (C.1, C5) briefly send half-waves by means of the rectifier provided for rectifying the identification pulses (Gl before the occupancy pulses via .die primary windings of the outgoing Cbertragers (Uel), the direction of each the direction of the first half-waves of the subsequent identification pulse is opposite (Fig. 5). 22. Circuit arrangement according to claim 2r, characterized in that high resistances (e.g. 500 ohms) in the alternating current circuit briefly closed before the beginning of the identification pulses via the outgoing transmitter ; but in the alternating current circuit closed during the transmission of the identification pulses via the outgoing transformer, lower resistances (e.g. 100 ohms) are switched on: