DE907786C - Circuit arrangement for telephone systems with dialer operation and several exchanges in series - Google Patents

Description

Circuit arrangement for telephone systems with dialer operation and several In-line exchanges The invention relates to a circuit arrangement for telephone systems with dialer operation and several exchanges in a row, between those connecting lines that can be reached via connection selector with free choice run, the setting of which is assigned by a switch assigned to the desired exchange Evaluation devices that take up target identifiers and are shared by several connection dialers is controlled. This destination identifier will be used after setting the connection selector on a connection line leading to the next exchange from the evaluation device to the next exchange and immediately forwarded, if via the respective Connecting line not yet the exchange corresponding to the destination identifier is reached. After the respective transfer, the evaluation device will be the upstream switching center by dependent on the termination of the transfer Switching means released. In order to enable the evaluation device in the upstream switching center after reaching the corresponding to the destination identifier To achieve downstream switching center, one could, for example, also use In this case, let the target identifier come to the transmission again and thereby after completion of this transmission, as well as otherwise, the approval of the evaluation device cause. This repetition of the target identifier is used for the voter setting ineffective in the switching center reached stay as the Voters of this exchange, for example, without evaluation devices Recording of a normal number dialing following the destination identifier can be set or are only ready to receive after receiving a pre-current surge.

In order to obtain such a clearance only for the evaluation device To avoid the necessary repetition of the target identifier, the present one proceeds Invention another way, which is characterized in that after the in destination identifier recorded by the evaluation device of an exchange corresponding determination of the switching center corresponding to the next, the destination identifier leading connection path switching means in the evaluation device to the effect come, which after setting the connection selector on this Connection path preventing the destination identifier from being repeated to the next Initiate the exchange to release the evaluation device.

To explain the invention, an excerpt from a telephone system with several in-line exchanges is selected as an exemplary embodiment, which comprises two connection paths (Fig 2) is preset. Such connection paths can be provided in each exchange. The connection path shown in FIG. I can be reached by a remote officer FB, provided that the associated exchange forms the outgoing exchange for the connection to be established; it ends in a first group selector, not shown here (connection selector with free choice), by setting it, for example, a further group selector (connection selector with free choice) and, after setting the latter, either a transmission Ue can be reached via this one connection line FL to a downstream one To occupy switching center, or voters of a local network can be reached, through the appropriate setting of the desired participant can be selected. The setting of the group selector, not shown here, is controlled with the aid of the evaluating device of FIG. 2, which is switched on in preparation. The connection path shown in FIG. 3 is occupied by means of the transmission Ued indicated schematically here, which can be reached via a connection line F1 from an upstream exchange. This connecting line FL in the upstream exchange is occupied by a first and second group dialer and a transmission Ue after the group dialers in the upstream exchange have been set using a common evaluation device provided there in accordance with FIG. After the connection path shown in FIG. 3 has been reached, an evaluation device connected via the associated mixer selector Wwd, as shown in FIG. 2, is influenced by the identifier of the desired exchange. Under their influence z. B. set a first and a second group selector, un by appropriately setting the latter ent neither a transmission with a connecting line FL to the next exchange or Wählei of a local network to select the desired subscriber to achieve.

In detail, the operation of the excerpt of the telephone system shown in FIGS. I to 3 is as follows: Occupied z. B. a remote officer FF the connection shown in Fig. I via a preselection device, not shown here, the relay Cl is excited. Since the relay Spb is energized via the wire c i b (Spb I, 1I, 33 spb; 34ub, -f-) when the connection path is idle and the first group selector is ready for operation, after the contact 25gb is closed, the current is amplified when the winding II of the is shorted Relay Spb an assignment of the first group selector, not shown. As a result of the preparatory setting of the mixed selector Mwb on a free evaluation device, e.g. B. Fig. 2, the relay Tb is excited about -, Wi io, 8i ca, 77 sPa, 3, mw 3 b, Wi i, 62 tb, TbII, - @ -. Thus, after the contact 58g is closed, the following circuit is established: -, Wi 8, 75 sPa, Wi7, Cal, 72 ci a, i, mw ib, Qb I, 1I, 58 g, 57 qib, -E-. In this circuit, the relays Qb and Ca respond. By closing the contact 6oqb, the relay Qb with its winding I is independent of the contact 58g and short-circuiting the winding II in a hold circuit. After the contact 54qb is closed, the relay Q i b is energized. After the relay Ca has been energized, the relay Cia responds as a result of the closing of the contact 8gca, while the relay Ya is energized after the contact i45ca has closed. By opening the contact 8ica, the winding II of the relay Tb is switched off, while by closing the contact 7o ca after opening the contact 72 c i a, the winding II of the relay Ca is switched on. After the relay C i a has been energized, the relay Ka is energized as a result of the closing of the contact 2o7 ci a, because the connection path shown in FIG. 1 is connected to an operational first group selector, not shown here. Then there is a plus potential on the wire d i b , which affects the relay Ka via 22 qb, 23 spb, yizw 5 b, 5, 2o5 Z '3 a, Ka I, 207 ci a, Wi i5, -. The remote officer FB now sends the target identifier, which is used to identify the desired exchange and consists of three rows of current impulses, by means of a dial or a numeric encoder via the dib wire. Since the contact is closed 6QB, incoming from the remote official surges influence from this contact and the switching arm mw2b the relay Aa of the evaluation device shown in FIG. 2, in order in this succession to the rotary magnetic De to the switching operation of switching arms de i -de 4 and to operate the switching solenoids Mi and M2 of the motor selector Me. The motor selector Me picks up two series of current impulses, of which the first row sets the selector arms in front of a certain group and the second row to a certain contact in this group. So z. B. the target identifier is sent out, the relay Aa is temporarily energized five times by the first series consisting of five current pulses. With the first excitation, the relay Va speaks via -, VaI, II, 85aa, 84u3a, +. As a result of a short circuit in its winding II via the contact 87, the relay Va remains va during this series of current impulses. After the contact g? Va is closed, the relay Wa is excited via -, Wa I, 94 u i a, 92 va, go xa, 89 ca, +. Corresponding to the first series of current impulses consisting of five current impulses, the rotary magnet De is influenced via -, De, i28uia, 127aa, +. The contact arms dei-d64 come to contact 5. After the end of the first series of impulses, the relay Va is caused to drop out due to prolonged de-excitation of the relay Aa , so that the following circuit is closed via the contact g3va: -, U i a I, Wall, g6 wa, g3 va, go xa, 89 ca, +. In this circuit, the relay U i a responds, while the relay Wa is held by its winding II. Closing the ioi uia contact affects the winding II of the Uia relay in the following circuit: -, UiaII, 325u2a, ioiuia, goxa, 8gca, +. The rotary magnet De is switched off by opening the i28uia contact. Because now closed, inter alia, the contact iiguia, the next surge row causes an adjustment of the switching arms me i me 13 of the motor voter 1VIe before a specific contact group. The contact bank required for this and to be swept by the switching arm me i is wired in the first contact group comprising the contacts ii-io according to FIG. In the remaining contact groups, the contacts 17 and 1o corresponding to the contacts 17 and 1o, which is not shown here, are connected to these contacts in a corresponding manner, that is to say, the contacts 20, 30, 40 etc. are connected to the contact io and the contacts 27, 37, 47 etc. are wired to contact 17. In addition, the mechanically operated contact io6mie in positions i, 12, 14, 16, 18 etc. and the mechanically operated contact 1o7 m 2 e in positions o, 11, 13, 15, 17 etc. are closed . If the relay Aa is excited when the first impulse of the second series of impulses is picked up, the relay Va responds again and, by opening the contact g3 va, causes the relay Wa to be excited, the switching magnets Mi and M2 are excited at the same time, namely the switching magnet M i via -, M i, 112 aa, 113 ca, me i in o, 117va, iiguia, 12oya, 121u3a, +, while the switching solenoid M2 is energized via -, M2, io7mae, 117va, iiguia, i2oya, 121u3a, + . The motor selector Me remains in position o as a result of the excitation of both switching magnets. If the relay Aa is de-energized after the end of the first current impulse, the switching magnet Mi is de-energized by opening the contact ii2aa, while the switching magnet M2 remains energized in the circuit already mentioned. As a result, the motor selector 111e takes one step and comes to the position i. After this position has been reached, the contact io6m ie is closed, so that the switching magnet M i is excited via -, M i, io6mie, 117va, iiguia, i2oya, 12iu3a, +. The switching magnet M2 is excited via -, M2, iiiu2a, i z5 aa, 116 ca, me i in 1, 117 va, i zg ui a, 12o ya, 12i u3 a, +. Since both solenoids are energized again, the motor selector Me remains in position i. If a second current surge were to arrive, that is, the relay Aa would be energized for the second time, the switching magnet M2 is switched off as a result of the break contact of the contact 115 aa, so that the switching magnet Mi brings the motor selector Me into position i1. The mechanically operated contacts 1o7 m 2 e or io6 m i e now alternately switch on the switching magnets M2 and Mi from selector position to selector position, so that the motor selector Me progresses continuously to position 17. In this position, since the relay Aa is still excited by the second current surge, the switching magnets Mi and M2 are excited simultaneously, namely M i via -, M i, 112 aa, me i to 17, 117va, iiguia, 12oya, 121u3a, +, and M2 over -, M2, 107m2e, 117va, iiguia, 12oya, 121u3a, +. The motor selector Me remains in this position until the relay Aa is de-energized after the end of the second current impulse, so that the switching magnet M i is switched off by opening the contact 11: 2 aa. The energized switching magnet M2 switches the motor selector Me to the next switching position, whereby the switching magnet M1 and the switching magnet M2 are now alternately influenced by the alternating closing of the contacts io6mie and 107m2e up to position 1o. In this position, both solenoids M1 and M2 are energized again. The switching magnet M i is excited via -, M i, io6 mie, ii7va, iiguia, i2oya, 121u3a, +, while the switching magnet M 2 is excited via -, M 2, 111 u 2 a, ii5aa, 116ca, mei in io , ii7va, iiguia, i2oya, 12iu3a, +. After two power surges, the motor selector Me is in front of the second contact group. Should further current surges follow, the motor selector Me will be switched up to the contact group identified by the number of current surges. However, since the target identifier 516 is sent in the present case, that is to say the second series of current impulses consists only of one current impulse, the switching arm me i of the motor selector Me is in front of the first contact group, that is to say on contact i. Since the relay Aa remains de-energized for a long time after the end of the second series of impulses, the relay Va is de-energized by opening the contact 85 aa. By opening the contact Mva, the switching magnets M1 and M2 of the motor selector Me are switched off at the same time. After the contact g3 va is closed, the relay U 2 a is excited via -, U2aI, g8uia, g7wa, g3va, goxa, 8gca, +. After opening the contact 325u 2a , the winding II of the relay Uta is brought to excitation in series with the already energized winding II of the relay U ia. If the third series of current impulses, consisting of six current impulses, is transmitted, the relay Aa is temporarily excited six times, while the relay Va remains continuously excited during the current impulse series. After the contact g2va is closed, the relay Wa is excited via -, WaI, g5u2a, g2va, goxa, 8gca, +. In the motor selector Me, the switching magnets Mi and <'l12 are initially excited, namely the switching magnet M i via -, Mi, io6mie, 117v9, 119uia, i2oya, i21u3a, -f-. The switching magnet M2 is excited over-, M2, 1iou2a, io4na, 117 va, 1i9 u i a, 12o ya, i21 u 3 a, -f-. As soon as the relay Na is excited via -, Na, i54ha, 1539a, i5ou2a, -; - after the contact i53 aa is closed, the switching magnet M2 is switched off by opening the contact 104n9, so that the switching magnet M i, which is still excited, controls the motor selector Me in the position ii brings. In this position the switching magnet Mi remains excited via the contact io8na, while the switching magnet M2 is influenced via the now closed contact 107m2e. If the relay Aa is de-energized after the end of the first impulse of the third series of impulses, the relay Ha is also energized via -, Na, 1529a or 154h9, Ha I, 151 na, 15o and 2 a by removing the short circuit at contact I53 a , +. The relay Na remains affected in the circuit mentioned. By closing contact i55ha, winding II of relay Ha is also switched on. If the relay Aa now picks up the second impulse of the third series of impulses, then by opening the contact: 1529a the relay Na is de-energized, while the relay Ha keeps itself above -, HaI, 155h9, 1539a, 15ou2a, +. By opening the contact io8na, the switching magnet Mi is de-energized, while the switching magnet M 2 remains energized via the contact 107m2 e or iogna. The motor selector Me is therefore advanced by a further step. When the second impulse of the third series of impulses has ended, the relay Ha is de-energized by opening the contact 1539a. With the third current surge, the switching operations described for the first current surge are repeated, which are then followed by the switching operations described for the second current surge at the fourth current surge, and so on. The switching arms of the motor selector Ale are therefore after receiving the third series of current impulses consisting of six current impulses on contact 16. Since the switching arms de i -de 4 have reached contact 5 through the five current impulses of the first series of current impulses, the switching arm is therefore dei the Switching arm me6 selected. After the de-energization of the relay Va , the relay U3a is energized at the end of the third series of impulses via -, U39, ioou4a, 99u29, 96w9, 93v9, goxa, 89c9, +. Via the switching arms de i and me 6 , after the contact 1o5 u 3 a has been closed, the contact 5 is identified in the contact bank that can be reached by the switching arm mai via the resistor Wi 2i according to the target identifier 516. After closing the contact i22u3a, the switching magnets M4 and M3 of the motor selector 3Vla are now alternately influenced via the mechanically operated contacts i25m4e and i26m3e, in order to incrementally advance the switching arms ma i-ma 14 of this motor selector. As soon as the switching arm ma i reaches contact 5, the relay K i a is excited via -, K 2 a, K z a, ma i to 5, Wi 2r, 516, me6 to 16, de i to 5, 105U39 , -f-. The relay KZa does not respond due to the resistance Wi2i. By closing the contact 124kia, the two solenoids M3 and M4 are kept excited so that the motor selector Ma is not advanced any further. After the contact 103kia is closed, the relay U4a is excited over-, U4a, 103kia, io2ya, 9oxa, 89c9, +. The relay U4a remains independent of this via its contact 104u49. By opening the contact iooU4a, the relay U3a is de-energized, so that by opening the contact 122 u3a , both switching magnets M3 and M4 of the motor selector Ma are switched off. As a result of this setting of the motor selector Ma , a current surge transmission is intended for setting a first and second group selector, not shown, in order to reach a connection path (main path) that is to be used first. The current surge transmission, however, first checks whether this connection path, referred to here as the main path, still has a free line. As long as this is the case, contact 18igh is closed, so that if it is assumed in the present example that point li connected to contact 5 (switching arm maio) is wired to point i, after the relay U4a has been energized, das Relay Qha responds via-, QhaI, i8zgh, i-li, maio on 5, 262h29, 264u49, 265n29, 266x9, 267x29, d93 in o, +. By closing the contact 26i qha, the relay Qha and its winding 1I are placed in a holding circuit via -, N2a, Nia, QhaII, 261qha, 25oxa, 247c9, +. The relays Nia and N2a are also energized in this circuit. After closing the contact 242n29 is initially about standing on the contact 5 times shifting the contact i in the shift arm. marked as accessible contact bank. After closing the contact 165 n ia, the relay responds Yes in the charging circuit of the capacitor Ko i, which runs via -, Ja, 16i pa, 1620a, 163m9, 165 nia, Ko i, 167x9, -f-. By closing the contact 172i9, the capacitor Ko 2 charged via the relay A79 is discharged. If the relay Ja is de-energized after the capacitor Ko i has been charged, the relay Ma is excited as a result of the closing of the contact i7iia in the charging circuit of the capacitor Ko 2 until this capacitor is charged. During this time the relay Ja is switched off by opening the contact 163 ma and the capacitor Ko i is discharged by closing the contact 164m9. If the relay Ma is de-energized after the capacitor Ko 2 has been charged, after the contact 163m9 closes in the manner already described, the relay Ja is re-energized in the charging circuit of the capacitor Ko i, whereupon the interplay with the relay Ma continues. When the relay Yes is excited for the first time, the relay V 3 a is generally excited via contact 158. By short-circuiting the winding II via the contact 159v 3 a, the relay V 3 a is delayed so that it remains continuously energized during the interplay between the relay Ja and the relay Ma. The relay Ka is switched off at contact 2o5 v 3 a. After the contact 315 ka has been closed, the Via relay and after the contact 314v has closed, generally the V2a relay . Due to the interplay of the relays Ja and Ma , the rotary magnet Da is influenced accordingly via the contact i4oia, so that the switching arms da i - da 3 are advanced by a corresponding number of steps. While the switching arms da i-da 3 are switched on, a corresponding current impulse is sent by means of the contact 2o6ia for setting the first group selector, not shown here, via the wire di b. The switching arms da i - da 3 are switched on until the winding I of the relay Pa is excited via the switching arm. This happens after a switching step over -, Wi 16, 2q.3 ya, 242n 2 a, 2q 0 qpa, 235 q 3 a, 229q 2 a, 225 qia, 222 h i a, ma 2 to 5, since i to i , Pa I, i36 oa, -f-. In accordance with this one switching step, a current surge is transmitted. Opening the contact 16ipa prevents further excitation of the relay Yes after it has been actuated once; Relay Ma also initially no longer responds. As a result of the prolonged de-energization of the relay Yes , the relay V 3 a is de-energized when the contact i58 is opened. By closing the contact 2o5 v 3 a, the relay Ka is switched on again to the wire d i b in order to be excited by this when the first group selector, not shown, has found an operational second group selector. By opening the contact 315ka, the relay Via is deenergized. After the contact 320 vi a is closed, the relay H i a is excited via -, HiaI, 324hia, V2aII, 323v2a, 32ovia, KaII, 316ka, +. The relay V2a lasts for a short time over its winding II; its winding I is generally switched off at contact 314v. By closing the contact 22o h i a , the relay H ia places itself with its winding II in a holding circuit. In series with this winding, the relay H i'a is energized. By opening the contact 222h I a and closing the contact 223 h I a , the switching arm ma3 is now provided for the next impulse transmission instead of the switching arm times. In the meantime, after the contact 27o v I a has been closed, the relay 0a is excited via -, 0a, 270 via, 269 pa, since 3 on segment i - io, +. By closing the contact 1440a, the rotary magnet Da is under the influence of the interrupter U, so that it is influenced to continue switching the switch dai-da3 as long as the switch arm da2 sweeps the segment i-io; ie after reaching the rest position the rotary magnet Da is switched off; the switching arms da i -da 3 are therefore stopped in the rest position. Since the relay 0a is also de-energized by leaving the segment i-io through the switching arm da3, a new interplay between the relay Ja and the relay Ma for switching the switching arms da i - da 3 can start after the contact 1620a is closed. The relay V 3 a is energized again. A corresponding current surge is sent in the manner already described for the emission of the first series of current pulses, the number of current pulses now being determined by the switching arm ma3. Since the contact 5 reached by him is wired to the contact 2 of the switching arm da i, two current surges are emitted. The second group selector (contact 2o6ia), not shown here, is brought to the setting by these two current surges; he then reaches z. B. a transmission Ue, not shown here, via which a connecting line FL is accessible to a downstream exchange. At the beginning of the second current impulse transmission , the winding I of the relay Ka has again been switched off by opening the contact 205 v 3 a, so that the relays Via and V 2 a are again excited during the same. If the setting of the second group selector is finished and the already mentioned transmission Ue is reached, the relay Ka is again excited via its winding I. After the contact 316ka is closed, the relay H2a is excited via -, H2a I, 322hIa, 32rvia, Ka 1I, 316ka, +. The relay H2a sets itself with its winding II via the contact 221h2a in a hold circuit. In this holding circuit, the relay H 2 'a is excited. In the manner already described, the switching arms da i -da 3 are brought back into the rest position. Since contact 5 reached by switching arm ma i2 is now connected to relay Xa after contact 2o9 h 2 a has closed, the following circuit is established: -, Ub, mw4b, 4, 196via, 197qpa, i99q2a, 2oiqia, mai2 on 5, 209h2a, Xa I, II, -j--. In this circuit only the relay Xa responds. If the impulse transmission should be terminated after a single series of impulses, since the connection path in question can already be reached via a first group selector, contact 5, which can be reached by switching arm mai2, is wired to contact 2o8hia; the relay Xa is then already excited after a single series of current impulses. By opening the contact go xa, the relays U i a, U 2 a and U4a are now switched off. After the contact 25I xa is closed, the relay X i a is excited via -, X i a I, 252 n i a, 251 xa, 247 ca, +. With its winding II, relay X ia is placed in a hold circuit via contact 246 x i a. Since the contacts 147 x I a and 148 ka are now closed, the relay Ya is short-circuited and, after some time, de-excited. The target identifier 516 is now transmitted from the evaluation device shown in FIG. 2 via the first and second group selectors, not shown here, for transmission Ue, also not shown. A seizure current surge has now been sent from this transmission via the connecting line F1 to the downstream exchange. If one assumes, to facilitate understanding, that a connection path has been reached in the downstream exchange as shown in FIG affects what this relay lays with its winding II in a holding circuit, not shown. By closing the contact 275 dd the relay Ed is excited after some time in order to provide the relay Hd instead of the winding I of the relay Dd by closing the contact 274ed for receiving the target identifier now coming from the evaluation device of the upstream exchange. The transmission of the target tag from the upstream switch is now in the following manner is: Since the relay Yeh has come into the position shown in Figure 2 evaluation device by short-circuiting to deenergization, a charging circuit for the capacitor Ko i is closed, which extends over -. , yes, 16ipa; 162oä, 163ma, 165n1 «, Koi, 168zc3a, 169u4a, i7aya, +. The relay yes responds while the capacitor Ko i is charging and works, as already described above for the group selector setting, in interplay with the relay Ma, so that the rotary magnet Da is intermittently influenced. While the relay is being influenced, the relay Va is excited via the contact 83i and remains excited during each series of current impulses, as in the case of the described recording of the target identifier by the evaluation device. Also, the relay Y3 is a ßreiheerregt via the contact 158i "during each Stromsto and brings about his contact 156v 3" relay Y4a for excitation. After the excitation of the relay Va, the relay W «responds via its winding I as when the first series of current impulses were picked up. The current surges generated by the relay are generally sent via the contact 2o6 to the transmission Ue (not shown) and from there via the connecting line Fl to the downstream switching center, ie, according to the above assumption, to the relay Hd. The number of current impulses in this series of current impulses is determined by the number of switching steps that the switching arm d «i carries out until it reaches the contact identified by the switching arm de 2. There, the switch arm de? is on contact 5 and this contact is wired to contact 5 on the switching arm because i , this occurs in the present case after five power surges. Then the following circuit is created: -, Wiii, 13oya, 13ix2a, I33uia, de2 to 5, da 1 to 5, Pa 1, 136 oa, - [-. In this circuit, the relay Pa is excited and prevents further influence on the relay by opening the contact i6ipa . After the contact 269p «is closed, the relay 0a is energized as before. If relay Y3a is de-energized after some time after contact i58ia has opened, the rotary magnet Da is influenced to switch the switching arms d « i - da 3 into the rest position via -, Da, da 2 to i-io, x41 n i a , 143v 3 a, 14409, U, -j-. After reaching the rest position this Fort switching circuit is interrupted at the switching arm there ?,. In the meantime, relay Va has also generally deenergized by opening contact 83 and, via its contact 93, has excited relay U ia via its winding I, especially after the described recording of the first series of impulses of the target identifier. The relay Uia places itself in a hold circuit. By opening the contact 133 zc ia, the switching arm de 2 is switched off and, instead, by closing the contact 132u ia, the switching arm me i2 is made effective for determining the second series of current impulses. The switching arms d « i - da 3 are switched again with a corresponding impulse transmission to the downstream switching center, with a current impulse now, since the contact i in the contact bank reachable by the switching arm da i is identified by the switching arm me 12 on the contact 16 comes to the broadcast. After the second series of current impulses has elapsed, the switching arms da i -da 3 are switched to the rest position, while the relay Uta is excited via its winding I as a result of the re-excitation of the relay Va as after the described recording of the second series of impulses of the target identifier . The relay U2 «is also placed in a hold circuit. By opening the contact 134u2a, the switching arm mw12 is switched off and by closing the contact 135u2a, the switching arm me x3 is made effective for determining the number of impulses in the third series of impulses. Since contact 6 is identified via this switching arm standing on contact 16 in the contact bank that can be reached by switching arm da i, the third series of current impulses consists of six current impulses. After the third series of impulses has been sent out, the relay U3a is energized, as after the described recording of the third series of impulses of the target identifier, so that after the contact 214u3a is closed, the relay Spa responds via -, Sp «, 214U3«, 2i2 va, -f-. By opening the contact 75 sP «, the windings I and II of the relay C« and the winding I of the relay Qb are switched off, so that after de-energizing the relay Qb the following circuit is established: -, W14, RI or II, 38 t, 63 bab, x6 qib, 15 qb, 14y i b, 13 bb, -f-. Relay R responds in this circuit. By closing the contact 46r, the rotary magnet Daw is excited, with the rotary magnet Daw operating with the relay S by means of the contact 48 daw in an interplay with the step-by-step advancement of the selector AW. If the switching arm aw 3 reaches the connection path marked by the contact x8 qb i, the following circuit is established: -, Wi 6, 17 qb, 18 q i b, Bb I, II, 2ibb, igrib, 2obzb, aw3, T 1, 1I, 44.r, +. In this circuit, apart from the relay T, which stops the selector AW by opening the contact 451, the relay Bb is excited. By closing the contacts lobb and i2bb, since the contacts 40t and 41t are also closed, the tone signal receiver (signal receiving device) Ts is applied to the wires a 2 b and b 2 b via the switching arms aw i and aw 2 in order to transmit the Record the return signal causing the subscriber number as soon as such is sent back from there after reaching the exchange corresponding to the sent destination identifier. After the contact 37 bb is closed, the relay B ib is excited and applies a buzzer Su to the wires 12b and beb via the contacts 7 b ib and 8 b i b in order to give the remote officer a signal that the target identifier is still to be sent goes. The relay Ca , which has become de-energized in the evaluation device of FIG. 2 by opening the contact 75sPa, now triggers this evaluation device into the rest position. As a result of the audio signal device which is separate from it, the evaluation device can therefore be released before the return signal is recorded. Instead of connecting the audio signal receiver Ts via the selector AW only after the target identifier has been repeated by the evaluation device (FIG. 2), this connection can also take place with the assignment of this evaluation device. The contacts i5qb and 17qb are then bridged so that the connection is initiated as soon as the relay Q ib is excited.

The destination identifier sent by the evaluation device influences a corresponding evaluation device in the downstream exchange by means of the relay Hd in order to induce a setting of group selectors in this exchange; this setting is then in turn followed by a repetition of the destination identifier by the evaluation device of the downstream exchange. These processes are repeated from exchange to exchange until a connection line to the exchange corresponding to the destination identifier is reached. Then, as will be explained later with reference to FIG. 2, there is no repetition of the target identifier; rather, a return signal is transmitted via the established connection path to the tone signal receiver Ts, which, as already described, is connected to the connection path in FIG. x occupied by the officer. The audio signal receiver Ts responds. After the contact 43 ts is closed, the relay R xb responds via its winding I; it lays itself with its winding II in a holding circle over-, R ib II, 53 yib, 55 gb, 56 qib, -I-. The relay Bb is de-energized by opening the contact igrib and the relay B ib is de-energized by opening the contact 37 bb. By opening the contacts robb and xibb, the audio signal receiver Ts is switched off from the wires a 2 b and b 2 b ; these wires are switched through to the officer FB at contacts g bb and xi bb. The buzzer Su is switched off at contacts 7 bxb and 8 b i b . In the meantime, by opening the contact igy ib, the selector AW has also been released, while the wire d i b is switched through to the officer FB at contact 327 ri b , so that from the transmission Ue, not shown here, an incentive for the transmission of the subscriber number by the Payers or other facilities of the Fernbeamtin FB is given. The desired connection can thus be completed.

In the preceding description it was assumed that the first connection path (main path) corresponding to the destination identifier 516 is free, since the contact 18igh is closed. However, if this connection path no longer contains a free connection line, the corresponding cut-off relay Gh, not shown here, is de-energized, ie contact 18ogh is closed instead of contact 18igh. Accordingly, point i is then, depending on whether the first, second or third detour is free or occupied, i.e. a non-shown cut-off relay Gi, G: z or G 3 is excited or de-excited, via correspondingly actuated contacts gi, g2, 93 with the winding I of the relay Q i a, Q 2 a or Q 3 a connected. Instead of relay Qha, either relay Q ia or Q 2 a or Q 3 a is excited. As a result, instead of the switch arms ma 2 and ma 3, other switch arms, maq. and like or ma6 and mal or measure and like, made effective for the determination of the impulse transmission, so that different contacts in the impulse transmitter (switching arm da i) are marked depending on the line group corresponding to the target identifier 516 and available as a main or detour. If all possible paths of the destination identifier mentioned are occupied, so that the contacts x8ogh, i82gi, 188g2 and 19293 are closed, the relay Qpa is energized. After the contact 79 qPa closes, the relay B 2 b responds via -, Wi io, 8oca, 79 qpa, 6, mw 6 b, B 2 b I, +. The relay Beb places itself with its winding II in a holding circuit via -, B 2 b II, 52b 2 b, 55 gb, 56 qx b, +. By opening the contact 59 b 2 b , the relays Qb and Ca are de-energized. The relay Ca causes the evaluation device of FIG. 2 to be triggered, so that the group selector is not set. A setting of the selector AW does not take place now, since the contact 63 b 2 b is open. By closing the contacts 262b and 362b, the officer FB receives a busy signal. She can now handle the connection in one way or another. It can therefore be seen that when the evaluation device of FIG. 2 is occupied via a connection path according to FIG. On the other hand, other switching processes occur when the evaluation device of FIG. 2 is seized by a connection line according to FIG. 3 which is reached from an upstream exchange. This connection line is occupied by an upstream switching center due to a seizure current surge. As has already been indicated elsewhere, this current surge causes the relays Dd and Ed to be energized. The relay Hd for receiving the target identifier is provided via the contact 274ed; it later transmits the same to relay Aa by means of its contact 28ohd. Since the selector Mwd of this connection path is, for example, on the evaluation device shown in Fig. 2, i.e. the relay Td is energized via -, Wiio, Sica, 77sPa, 3mw3b, Wi18, 287td, Td II, +, occurs after contact 282dd is closed an occupancy of this evaluation facility. In the circuit running over the wire i, in addition to the relay Ca , the relay Qd is also excited via its windings I and II. After the contact 29o qd is closed, the relay Q i d responds. The relay Q xd is placed in a hold circuit via its contact 289 qid. The other switching processes correspond to the processes which have already been described with reference to FIG. The switching processes in the evaluation device also take place in the manner already described. The evaluation device also causes a first and second group selector to be set depending on whether the paths available for the destination identifier are free. If a connection line available as the main path to the desired exchange can already be reached via the set first and second group selector, i.e. there are no more intermediate exchanges to go through, then in FIG Point 2 wired so that, since contact 177gh is closed when the main path is free, relay Ba is energized in series with relay Qha. The relay Ba places itself by closing its contact 326 ba with its winding II in a hold circuit and by opening the contact 146 ba prevents a short-circuit of the relay Ya that would otherwise occur after the setting of the group selector, in order to repeat the target identifier, which would otherwise occur when the Relay Ya is required for further construction in the intermediate exchanges to prevent. After setting the selector, Xa and X = a energized, the relay Spa responds; since the contacts 215 ba and 217 xa are closed. Since the contact 74ba is closed, a current gain comes about after energizing the relay Spa at the end of the selector setting via -, TI'i8, 76spa, Wi 9, 74 ba, i, mw i d, Qd I, Rd, 285 qd, - 1 -. The relay Rd responds and switches the tone signal Tsi to the winding II of the relay Hd at its contact 294vd; so that after energizing the relay Hd by means of the winding III on the wires a 2 d and b 2 d it reaches the tone signal receiver Ts, which is switched on in the output exchange in the manner already described with reference to FIG. Open to the excitation of the relay Ca, 75sPa the evaluation device is released.

If no line is free in the main path, since contact 176gh is then closed, another impulse transmission is identified via contact 1 85 gi to set up a detour via an intermediate exchange. Since now the relay Ba does not respond, the relay Ya is caused to drop by short circuit after the selector setting, so that a repetition of the target identifier takes place.

If all paths are occupied, the relay Qpa is energized via contact 184 '' 1 . Now it causes the group selector to be set to an auxiliary position and not, as before, the transmission of a busy signal, since a relay corresponding to relay B 2 b of FIG. After the contact 241 qpa is closed, a certain current impulse transmission is identified, the first series of impulses from a current impulse due to the identification of the contact i (da i) via the contact 173 h = 'a and the second series of current impulses from three current impulses due to the identification of the contact 3 (da i ) is determined via contacts i74hi'a and 175k2'a. The remaining switching operations for setting the group selector, not shown, carried on an auxiliary space in a corresponding manner as described already in connection with Fig. I after the starting stimulus to selector setting by energizing the relay Ni a and N 2 a via contact 2550A given is. Since the relay Qpa is energized, there is no de-energization of the relay Ya after the two series of impulses have been emitted by opening the contact 149 qpa, since a repetition of the target identifier by the evaluation device of FIG. 2 is not required when an auxiliary station is switched on. After closing the contact 2i7 xa, after the relay Xa is energized after the selector setting, the relay Spa is energized, the excitation circuit of which is prepared at contact 216 qpa - "s ar. It now comes after contact 76spa is closed, since contact 73qPa is closed is, the following circuit is established: -, Wi 8, 76 spa, Wi 9, 73 qpa, i, mw i d, Qd I, Rd, 285 qd, -f-. The relay Rd responds in this circuit and gives that again Tone signal Tsi back to retrieve the subscriber number. The connection can then be cleared in any way. To enable the evaluation device, the relay Ca on contact 75 sPa has been switched off.

If one looks again at the case that the evaluation device of FIG. 2 is occupied from FIG. is reached, the current amplification via the resistor Wi9, 75spa and 74ba closed, excitation of the winding III of the relay R ib, provided that the switch-on selector AW has set itself immediately, 15qb and 17qb short-circuited, i.e. the relays Bb and B i b are excited, so that the contact 61 b i b is open. The contact 327 vi b switches through and initiates the transmission of the subscriber number (wire d i b) through this stimulus within its own exchange, while the relay Bb and thus the relay B ib is switched off by opening the contact igrib. The buzzer Szs is switched off.

Claims (1)

PATENT CLAIMS: i. Circuit arrangement for telephone systems with dialer operation and several exchanges lying in series, between which connecting lines that can be reached via connection dialers with free dialing run, the setting of which is controlled by a number of connection dialers common evaluation devices which are assigned to the desired switching center, characterized in that according to the in the Evaluation device of an exchange recorded destination identifier corresponding determination of the connection path leading to the next, the destination identifier corresponding exchange switching means (Ba) in the evaluation device come into effect, which after appropriate setting of the connection selector on this connection path, preventing a repetition of the destination identifier to the next exchange Initiate evaluation facility. z. Circuit arrangement according to Claim i, characterized in that the switching means (Ba) withdraw from this influence and otherwise from them under the influence of switching devices (Xa, Xia) which come into effect after the connection selector has been set and which cause a repetition of the target identifier Relay for the release of the evaluation device after the repetition of the target identifier. 3. Circuit arrangement according to claim i, characterized in that the switching means (Ba) with the cooperation of the auxiliary relays (Spa) cause the transmission of a signal (Tsi) leading to the completion of the connection via the connection path running through several exchanges or cause the connection to be completed Generate incentives within your own exchange.