DE580964C - Circuit arrangement for automatic and semi-automatic telephone systems with bypass dialers - Google Patents

Description

The present invention relates to automatic and semi-automatic telephone systems of the kind in which a connection in an electoral stage initially has a number of Bypass dialers is set up, whereupon a speech path is established and the bypass dialers are triggered. In previously proposed arrangements of this type, the bypass selectors are arranged separately from the voice selector and the complete bypass route has been maintained until the Speech was completed.

It is readily understandable that the bypass devices are relatively expensive and that a saving in the time that these facilities are used need to be, and as a result, a saving in tackling a particular Voice traffic required number of these facilities means a significant saving.

In order to achieve such a saving, according to the present invention is for automatic and semi-automatic telephone systems with bypass dialers, a circuit arrangement is provided, which is characterized in that the number of to establish a connection Bypass dialer used between a calling and a desired subscriber is equal to the number of voters in the speech connection path and that the connection from electoral stage to electoral stage from

the bypass dialers are switched to the voice dialers during the establishment of the connection will.

In the embodiment of the invention described in detail below, bypass and speech dialers are used that can be set by a single movement, since such dialers allow great mobility in the wiring arrangement. The various groups of outputs of the bypass selector being arranged course sequentially in a single contact bank, and while the group selector ⁴ S, the switching arms have a group of contacts at each overflow emitted by the calling subscriber number surge.

In the case of large groups, it is impractical to have the voter who selects the group directly to operate by the Nununernstrompulses, since the bypass selector simultaneously a Search for a free output in the desired group of outputs and use this to create a surge circuit must establish before the next, digit sent out by the calling party will.

Further features of the invention therefore relate to convenient means of control the setting of the bypass dialers and to ensure that the establishment of the bypass route is within the permissible Time limits is completed.

These and other features of the invention will be more readily understood from the following Description given on the basis of the drawings. In Figs. Ι to 4 and 5 to 8 5 two exemplary embodiments of the invention are shown, while FIG. 9 schematically shows one Overview plan for three choice levels shows which are designed according to the invention.

Fig. Ι shows a speech ^{group selector S 1} and, below the dashed line, a bypass selector BP ¹ common to a group of group selectors. The outputs of the bypass dialer are multiple switched with those of the speech dialer.

! 5 Fig. 2 shows a voice line selector S ² . Fig. 3 shows two call relay groups RG ¹ and RGK common to a group of voice line selectors

Fig. 4 shows a bypass selector BP ^% common to a group of voice line selectors. The outputs of the bypass selectors are multiple switched with those of the voice line selectors.

FIG. 5 shows a ^{talk group selector S 3} and, below the dashed line, a bypass dialer BP ³ common to a group of talk group selectors.

Fig. 6 shows a voice line selector S ⁴ .

Figs. 7 and 8 show a bypass selector BP ⁴ common to a group of voice line selectors:

It is now the establishment of a connection

briefly described using the overview plan shown in Fig. 9. Beforehand it should be mentioned that the voice dialers S ¹ , S ² or FS are divided into groups in each selection level and each of these groups is assigned a bypass dialer BP ¹ , BP ² or FBP in a parallel multiple circuit.

+0 is ordered.

When a calling subscriber CP picks up his receiver, he is connected to a first group dialing stage by preselection devices, preferably one or more call seekers. A free talk group selector S ¹ , to which a free bypass selector SP ^{1 is} assigned, is selected. If the other speech group dialers in the same group are blocked at the same time, SP ^{1 is} temporarily connected to S ¹ . The bypass selector BP ¹ is now set as a function of the first dialed digit to select a speech group selector S ² and its associated bypass selector BP ² in the second selection stage, the test circuit running through these two selectors in series. A circuit is now closed via the bypass selector SP ¹ and the voice line to the second bypass selector BP ^Z , which is set by the second digit.

In the meantime, the selector S ^{1 has} been set to the selected outgoing trunk line under the influence of SP ^1. Immediately after setting S ¹ , the connection is switched ^{from SP 1} to S ¹ regardless of the state of the partially established connection. The bypass selector BP ² · selects a voice line selector .FS and the bypass selector FBP assigned to it. Above

5 ¹ (or BP ¹ ), the voice connection line, SP ² and the subsequent voice connection line, a surge circuit is closed to the bypass selector FBP , which is set by the tens and units to select the desired subscriber TFP. Meanwhile, the connection from J5P ^{2 is} on

5 ² and finally switched from FBP to .FS.

Let it now be that shown in Figs Embodiment described. Fig. 3 is below Fig. 2 and Fig. 4 below of Fig. 3 to be arranged.

. If the speaker selector S, shown in Figure 1 ¹ is occupied by a pre-arranged selection of known type, the following circuit is closed: Earth in upstream selection, Prüfader T, break contact 3 of the relay H, both windings of the relay K, closed contact 7 of the relay K Break contact 8 of relay 4, break contact 2 of relay 4, break contact 4 of relay Q, lower winding of relay P and parallel to this via break contact 5 of relay P, break contact 2 of relay 3, upper winding of relay P, battery. The relay P responds and interrupts the circuit via its upper low-resistance winding, whereby the control circuit BP ^{1 is} blocked against other occupancy. The relay K also responds and interrupts the circuit via its lower winding. Via contacts 1 and 2 of relay K , lines + and - are switched through to relay ι of the control circuit, which is excited via the following circuit: battery, normally closed contact 1 of relay 0, winding of relay i, normally closed contact 1 of relay 82, normally closed contact 1 of relay 81, normally open contact 2 of relay K, line -, subscriber loop, line -f, normally open contact 1 of relay K, normally closed contact 2 of relay 81, normally closed contact 2 of relay 82, earth. Relay 1 closes the following circuit for relay 4: battery, winding of relay 4, normally open contact 1 of relay 1, normally open contact 2 of relay P, earth. The relay 4 responds and remains independent of the relay P via the contact 5 of the relay 4. When dialing is started, the relay 1 drops correspondingly often according to the number sent, and the following Sfromkreis for the relay Q is closed with the first current surge : Battery, winding of relay Q, normally closed contact 3 of relay R, normally open contact 4

of relay P, normally open contact ι of relay 4, normally closed contact ι of relay 1, normally open contact 5 of relay 4, earth. Relay 3 is also energized via this circuit. When the relay Q responds, the original holding circuit for the relay P, which is powered by the battery via the winding of the relay P, the normally closed contact 6 of the relay Q, the normally closed contact 3 of the relay 5, the normally closed contact 4 of the relay 3 and the normally open contact 6 of the Relay 4 went to earth, switched so that it runs via the make contact 6 of the relay Q, the make contact 7 of the relay P and the break contact 3 of the relay 1 to earth. When the surge receiving relay responds again after the first current surge has ended, the relay P drops out, whereas the relay Q is kept energized via its own holding circuit, which now runs to earth at the normally open contact 5 of the relay 3. With the second current impulse, the relay R is excited via the following circuit: battery, winding of relay R, contact 3 of relay Q, normally closed contact 4 of relay P, normally open contact 1 of relay 4, normally closed contact 1 of relay 1, normally open contact 5 of relay 4, earth . The relay R switches the holding circuit for the relay Q to the second holding circuit running to earth via the make contact 6 of the relay R, the make contact 7 of the relay Q and the break contact of the relay 3. Therefore, if the relay 1 responds after the end of the current surge, the relay Q drops out. With the third current surge, relay P is re-energized via the following circuit: battery, winding of relay P, normally open contact 4 of relay R, normally closed contact 3 of relay Q, normally closed contact 4 of relay P , normally open contact 1 of relay 4, normally closed contact ι 'of relay 1, normally open contact 5 of relay 4, earth. When relay P is energized, this circuit is switched to normally open contact 4 of relay P and normally open contact 3 of relay R. After the end of the third current impulse, the relay 1 interrupts the circuit for the relay R, which drops out. Further current surges cause the successive excitation of the relays Q, R and P etc. If the relay 3 responds with the first current surge, the following circuit is closed for the rotary magnet RM : battery, winding and break contact of the magnet, normally open contact 3 of relay 4, normally closed contact 2 of the Relay 5, normally closed contact 1 of relay 72, normally closed contact 6 of relay 82, normally closed contact 1 of relay 71, normally closed contact 5 of relay 81, normally open contact 3 of relay P, normally open contact 3 of relay 3, earth. When relay P drops, this circuit is maintained via contact 2 of relay Q or contact 2 of relay R. The first bank contact of the first group of the contact bank io 'is connected to the first bank contact of the fourth, seventh and tenth groups, and when the relay Q responds, these contacts are connected to the normally closed contact 8 of the relay 81 and the normally closed contact 9 of the relay 82 Relay 5 connected. In a corresponding manner, the first contacts of the second, fifth and eighth groups are connected to one another through contact 1 of relay R , while the third, sixth and ninth groups are interconnected through normally open contact 1 of relay P. When the selector reaches a contact that is switched through to relay 5, the following excitation circuit for relay 5 is closed: battery, winding of relay 5, normally closed contact 9 of relay 82, normally closed contact 8 of relay 81, normally closed contact ι of relay P, Q or make contact 1 of relay R, bank contact and switching arm 10, break contact 1 of relay 72, break contact 6 of relay 82, break contact 1 of relay 71, break contact 5 of relay 81, contact 3 of relay P or make contact 2 of relay Q or J? , Normally open contact 4 of relay 4, switching arm and contact of contact bank g, earth. The relay 5 breaks at the contact. 2 the drive current circuit for the rotary magnet and thereby prevents the selector from being switched on before a further current surge is received. It should be noted that the size of the various trunk groups can be different in order to meet the requirements of the traffic. and if one of the groups is very large it may be necessary to add one or more relays to the combination of relays P, Q and R to prevent the voter from getting so far behind the control circuit that he incorrectly gets three Groups after the selected digit is stopped. When all current surges have been received and the selector reaches the first contact of the desired group, the relay 5, as already described, is energized. When relay 5 responds and relay 3 drops out after the end of the series of impulses, the first holding circuit of the last relay in the chain coming through contact 3 of relay 5 and contact 5 of relay 3 is interrupted. As a result, relays P, Q and 22 are all de-energized, and the following circuit is closed for relay 2: battery, winding of relay 2, normally closed contact. 2 of the relay R, normally closed contact 2 of the relay Q, normally closed contact 3 of the relay P, normally open contact 4 of the relay 4, earth at the contact bank 9. The circuit for the relay 5 is through the contact 1 of the falling relay. P, Q or R open and the circuit for. the rotary solenoid is now closed via the

Make contact 3 of relay 4, break contact of relay 5, break contact 1 of relay 72, break contact 6 of relay 82, break contact 1 of relay 71, break contact 5 of relay 81, make contact 5 of relay 2, make contact 9 of relay 4, earth. Furthermore, the circuit for the two test relays 71 and 72 is closed, which is connected to earth via the normally closed contact 9 of the relay 81, the normally closed contact 3 of the relay 0, the normally open contact 3 of the relay 2, the winding of the relay 72, the normally closed contact 3 of the relay 82 Test wire 5 and at the same time from earth via the normally closed contact 2 of the relay 0, the normally open contact 4 of the relay 2, winding of the relay 71, the normally closed contact 4 of the relay 82, the normally closed contact 3 of the relay 81 to the test wire 6. If all lines are occupied, the selector is switched to the last contact of the group, where a via the normally closed contact 9 of the relay 82, the normally closed contact 8 of the relay 81, the normally open contact 2 of the relay 2, the bank contact and switching arm 10 to earth on Working contact 9 of the relay 4 running circuit for the relay 5 is closed. Relay 0 responds in the following circuit: battery, winding of relay o, normally closed contact 3 of relay 9, normally open contact 3 of relay 5, normally closed contact 4 of relay 3, normally open contact 6 of relay 4, earth. Relay 0 is a slow responding relay and does not interrupt the circuits for test relays 71 and 72 until these relays, if the last contacts are free, have time to respond. The relay 0 applies the busy signal to the line - via its contact 1 and the winding of the feed bridge relay 1. When the relay 71 responds, it interrupts the circuit for the drive magnet through its contact 1 and closes the circuit for the relay 81 via the same contact, which is via the normally closed contact 5 of the relay 81, the normally open contact 5 of the relay 2 and the normally open contact 9 of relay 4 runs to earth. The relay 81 holds on to its contact 5, grounds the test wire at contact 3 and interrupts the test circuit via the relay 72 at contact 9. At contacts 1 and 2, the lines -) - and - are switched through to the following selector and the circuit interrupted for relay 1. The holding circuit for relay 4 is now switched so that it runs via the following path: battery, winding of relay 4, normally closed contact 2 of relay 1, normally closed contact 1 of relay 5, normally open contact 6 of relay 3, normally open contact 4 of relay 81, earth . The relay 3 is excited in a circuit running through the normally open contact 1 of the relay 4, the normally closed contact 1 of the relay 1 and the normally open contact 5 of the relay 4. The relay 81 closes the following circuit for the rotary magnet R of the group selector S ¹ : battery, winding and break contact of magnet R , normally open contact 6 of relay K, normally closed contact 1 of relay 5, normally open contact 6 of relay 3, normally open contact 4 of relay 81, earth. At the same time the test circuit for the relay 5 is closed via the normally closed contact 9 of the relay 8, the normally open contact 8 of the relay 81 and the normally open contact 5 of the relay K to the control switch arm M , and when the control switch arm M is on the same line as the control switch BP ¹ , is the circuit is switched through via the switching arm 8 and the normally open contact 7 of the relay 81 to earth, whereby the relay 5 is energized. The relay 5 interrupts the drive circuit at contact 1 and closes the circuit for the relay H, which operates via the normally open contact 4 of the relay K , which responds and is held by its contact 4 and the test wire. The relay H with its contacts 1 and 2 switches the lines + and - through to the following selector, whereupon the bypass selector can be triggered. The relay 5 also interrupts the holding circuit for the relay 4, which drops out and the circuit for the rotary magnet ZM for switching the bypass selector to the rest position, which runs via the normally closed contact 3 of the relay 4, the normally closed contact 4 of the relay 4 and the switching arm and the contact bank 9 closes. At the same time, a circuit for the relay Q running from the battery via the winding of the relay Q, the normally closed contact 4 of the relay 4 and the contact bank and switching arm 9 is closed. The test circuit is interrupted by the normally open contact 4 of the relay Q in order to keep the control circuit locked against other occupancy until it has reached its rest position. When the relay 72 responds, a circuit for the relay 82 is closed, which switches the calling line to the other switch arm set of the bypass selector and controls the setting of the group selector in the corresponding manner described for the relay 81.

The relay 9 is a step relay, which is influenced by the earth applied to the line TP from time to time, and when the relay 4 responds when the earth is applied to the line TP for the first time, an operating contact 7 of the relay 4 and the break contact 5 are activated of the relay 9 running circuit for the relay 9 is closed and the relay 9 is partially excited. When the earth is switched off again, the relay 9 is fully excited via its two windings, its contact i, the normally closed contact 1 of the relay 3 and the normally closed contact 1 of the relay 2.

When earth is connected to the line TP for the second time, the relay ο responds, and since both the relay 9 and the relay 0 are now energized, the relay 5 via the normally closed contact ι of the relay 5, the normally open contact 2 of the Relay 9 and normally open contact 2 of relay ο running drive circuit for group selector S ¹ closed. At the same time, the circuit for relay 5 is prepared on working contact 6 of relay 9 and working contact 5 of relay 0, while a ground potential is applied to control switch arm 8 via working contact 4 of relay 0 and working contact 4 of relay 9. When the group selector reaches the position indicated by the bypass selector in its rest position, the relay 5 is energized and this interrupts the drive circuit. The following circuit for relay H of the group selector is now closed: battery, winding of relay H, working contact 4 of relay K, working contact 1 of relay 5, working contact 2 of relays 9 and o, earth. The relay H holds to earth on an alarm line, which is connected to the contact occupied by the switching arm T , and triggers the control circuit BP ¹ in the manner already described.
When the conversation is over, earth is disconnected from the test wire. The relay H drops out and causes the group selector S ¹ to switch to the rest position. When the normally closed contact 3 of the relay H closes, the test wire is switched through by the upstream selector via the relay K to the test circuit running to the control circuit. However, if the control circuit is already in use, relay 4 is energized and the test circuit at contact 8 of relay 4 is interrupted. The through-switch relays of the upstream voters cannot be excited via the reduced potential, which identifies a control circuit as occupied. This potential reduction is caused by the fact that the relay K of the group selector, which occupies the control circuit, interrupts the circuit via which the control circuit is first put into use at its contact 7 and instead switches this circuit so that it switches over via the normally open contact 2 of relay 4 and a high resistance to battery runs. This high resistance essentially reduces the potential in this circuit to a ground potential, as a result of which the control circuit is blocked; but this ground potential cannot be applied to the test lead of the group selector in the existing connection, since at this time its re-

Ro lais K de-energizes and the normally closed contact 8 of the relay 4 is open.

The connection can be made in a corresponding manner via one or more further group dial levels be switched through to a line selector.

Reference will now be made to the last option level shown in FIGS. 2, 3 and 4. The test circuit in this selection stage runs in the following way: earth on test wire T, one winding of relay K of speech selector S ² , normally closed contact 3 of relay BB, normally closed contact I of relay HA, normally closed contact 2 of relay 4, normally closed contact 2 of relay Q, normally closed contact 3 of relay Q, winding of relay P, battery and at the same time via normally closed contact 5 of relay P, normally closed contact 3 of relay 3, via a non-inductive resistor to battery. The relays K and P respond, and the relay P switches off the battery and the non-inductive resistor through its contact 5, whereby the control circuit BP ^{2 is} blocked against being seized by another line selector. Relay K switches the line through to relay AA and battery via its normally open contact 1. The relay AA is energized via the subscriber loop to earth at the normally closed contact 1 of the relay BB . Relay AA closes the following circuit for relay 4: battery, winding of relay 4 , normally open contact 2 of relay AA, normally closed contact 3 of relay HA, normally open contact 1 of relay P, earth. The relay 4 is independent of the relay P via its contact 3. When the current impulse is given, the circuit for the relay AA is often interrupted according to the transmitted current impulses, and the following circuit is then closed: earth, normally open contact 3 of relay 4, normally closed contacts of the relay HA, break contact 2 of relay AA, break contact 2 of relay HB, break contact 2 of relay AB, make contact 1 of relay 4, break contact 3 of relay 7, break contact 1 of relay 2, make contact 2 of relay P, break contact 2 of relay R, Winding of relay Q, battery. The relay Q responds and switches the circuit for the relay P in such a way that it is connected to the normally open contact 3 of the relay Q , the normally open contact 4 of the relay P, the normally closed contact 8 of the relay HA, the normally closed contact 1 of the relay AA and the normally closed contact 1 of the relay AB runs to earth. The relay Q is held by the normally closed contact 2 of the relay R, normally open contacts 5 of the relays Q, 3 and 4 to earth. After the end of the first current impulse, the relay AA responds again, the relay P drops out, since its circuit is interrupted at the contact ι of the relay AA , but the relay Q remains energized. When the second current surge occurs, the following excitation circuit for relay R is closed: earth, normally open contact 3 of relay 4, normally closed contacts 2 of

Relay HA, AA, HB and AB, normally open contact ι of relay 4, normally closed contact 3 of relay 7, normally open contact ι of relay Q, normally closed contact 3 of relay P, winding of relay R, battery The relay R switches the via contact 2 of the relay R and 4 of the relay Q running holding circuit for the relay Q to the above-described holding circuit for the relay P, and as a result, the relay Q drops out when the relay AA responds after the end of the current surge. With the third current surge, relay P is made to respond again via the following current surge: earth, normally open contact 3 of relay 4, normally closed contacts 2 ^T of relays HA, AA, HB and AB , normally open contact 1 of relay 4, normally closed contact 3 of relay 7, normally open contact 1 of relay R, normally closed contact 3 of relay Q, winding of relay P, battery. The contact 3 of the relay P switches the holding circuit for the relay R so that this relay comes to waste when the power surge relay AA responds again. The successive energization of the relays P, Q and R is continued by further current surges. A circuit for relay 3 parallel to relay P, Q or R is closed with each current surge. If the relay 3 is energized with the first current impulse, the following circuit for the rotary magnet RM is closed: battery, winding of the magnet RM, normally closed contact 4 of relay 2, break contact of the rotary magnet, normally closed contacts 2 of relays 7 and 5, normally open contact 2 of relay 3, Earth. After the first turning step, the circuit for the rotary magnet is switched over so that it runs independently of the relay 3 via the switching arm and the contact bank JV. The contacts 7 of the relays P, Q and R switch the relay 5 via the normally open contact 9 of the relay 4 to control contacts of the contact bank C, and when the switching arm reaches one of these marked contacts, the circuit for the relay 5 is via the contact 6 of the relay 2 and contact 6 of relay 7 closed to earth. The relay 5 responds and interrupts the drive circuit via the magnet RM. The voter can therefore never run over the position indicated by the rush relay P, Q and R , while the speed of the voter to the maximum speed in the succession of rushes is in such a relationship that it is impossible for the voter to switch over in this way falls far behind the identification switching processes caused by the relays P, Q and R that it is controlled by the subsequent identification switching processes and as a result the correct functioning of the selector is disturbed.

After the end of the series of impulses, the selector is on the marked contact and the relay 5 is energized. When relay 3 drops out, the following circuit for relay 2 is closed: battery, winding of relay 2, normally closed contact 4 of relay 3, normally open contact 2 of relay 5, switching arm and contact in contact bank N, earth. When relay 3 drops out, the holding circuit via which one of the relays P, Q or R was kept energized after the end of the first series of impulses is also interrupted at its contact. At the same time, the following circuit for relay P is closed: battery, winding of relay P, normally closed contact 3 of relay Q, normally closed contact ι of relay R, normally closed contact 1 of relay 8, normally open contact 1 of relay 5, normally closed contact 5 of relay 3, normally open contact 5 of the Relay 4, earth. As already described, when the contact 6 of the relay 2 is actuated, the circuit for the relay 5 is interrupted and the relay 5 drops out as a result. The relays 5 and 2 are coordinated so that the relay 5 does not drop off until the relay P has time to respond and to put itself in a holding circuit, which is via the normally closed contact 3 of the relay Q and the normally open contact 5 of the relay P and after Drop of the relay 5 via the contact 1 of the relay 5, the normally closed contact 5 of the relay 3 and the normally open contact 5 of the relay 4 runs to earth. The relay 2 remains independent of the relay 5 via the normally closed contact 1 of the relay 7, the normally open contact 2 of the relay 2 and the normally open contact 3 of the relay 4 to earth. If relay AA drops out during a second series of impulses, the following circuit is closed for relay 3: earth, normally open contact 3 of relay 4, normally closed contacts 2 of relay HA, AA, HB and AB, normally open contact 1 of relay 4, winding of relay 3, Battery. When relay 3 responds, the following circuit for relay Q is closed: battery, winding of relay Q, normally closed contact 2 of relay R, normally open contact 2 of relay P, normally open contact 1 of relays 2 and 3, earth. The relay Q switches the first holding circuit of the relay P to the second holding circuit, which is dependent on contact 1 of the relay AA , and after the end of the first current surge, the relay P drops out. At the second current impulse the relay R is energized via the circuit already described via the normally closed contact 3 of the relay 7, the normally open contact ι of the relay Q and the normally closed contact 3 of the relay P, and after the end of the current surge, the relay Q drops out. At the third current surge, the relay P is energized via the circuit already described, via the normally open contact 1 of the relay R and the normally closed contact 3 of the relay Q , and since both the relays P and R are energized, an over is activated

the working contact 4 of the relay 2, the working contact 5 of the relay R and the working contact 6 of the relay P to earth running circuit for the rotary magnet R closed, whereby the advancement of the selector is brought about by one step. After the end of the third current impulse, the relay R drops out, the relay P holds itself via the circuit already described, and the circuit of the relay Q is closed again, via the normally closed contact 2 of the relay P, the normally open contact 2 of the relay P and the normally open contacts 1 of relays 2 and 3 to earth. Relay Q interrupts the holding circuit for relay P. With the fourth current surge, the relay is energized again and relay Q is brought to drop out. With the fifth current impulse, the relays P and Q are energized and the relay R is de-energized. Every time the relays P and R are energized at the same time, the selector is switched one step. This forwarding takes place only with the third, fifth, seventh and ninth current impulse. If the ones digit is odd, relay Q will remain energized, while relay R will remain energized even if an even number is selected. This arrangement of these two relays determines which of the switching arms of the control switch is to be checked. During the switching of the control switch BP ² in Fig. 4 caused by the units digit, the test switch arms ^{T 1} and T ^{2 are} alternately connected to relay 6 and battery via contact 6 of relay Q, working contact 5 of relay 2 and working contact 6 of relay 3 switched through. If the desired line is occupied, there is a ground potential on the test wire, whereby the relay 6 is energized, and when the relay 3 drops out, the relay 6 holds itself via the normally closed contact 6 of the relay 3, the normally closed contact 4 of the relay 7 and the normally open contact 6 of the relay 4 via the switching arm and the contact bank N. The test circuit for a multiple connection is now closed via the following path: earth, normally closed contact 7 of relay 7, winding of relay 8, normally closed contact 1 of relay 0, normally closed contact 5 of relay 7, normally closed contact 7 of relay 3, normally open contact 6 of relay 6, contact 8 of relay Q to the multiple connection switch arm X ¹ or X ^z . If the selected line is the first line of a multiple connection group, there is a battery on this contact, whereby, if the first line is busy, the relay 8 is made to respond, which is via its own contact 4 and the normally open contact 7 of the relay 4 to the battery holds. Via contacts 2 and 3 of relay 8, the drive circuit is closed again via the rotary magnet and the circuit for relay ο is also closed. Contact 1 of relay 0 switches the multiple connection switch arm X ¹ or X ^z to relay 5 via normally open contact 5 of relay 8. The selector is switched on until the circuit for the relay 5 6g to earth at the last contact of the multiple connection group is closed. The test circuit for relay 7 remains prepared during this transfer, but if no free line is found, the response of relay 5 prevents further actuation of the rotary magnet and the circuit for relay 0 is interrupted. Relay 0 drops out with a delay and closes the following circuit: earth, normally closed contact 3 of relay 0, normally open contact 1 of relay 6, normally closed contact 3 of relay AB, winding of relay GA, battery. The relay GA responds and applies the busy signal to the line via its contact 2. Contact 1 of relay GA closes a circuit for relay HA that runs through contact 1 of relay AA. The relay HA responds and switches off the control switch BP ² from the line ^selector S2. If the control switch finds a free line, the relay 7 responds in the following circuit: Battery ■ at contact 6 of relay Q , normally open contact 5 of relay 2, normally closed contact 6 of relay 3, normally closed contacts 2 of relays 0 and 6, upper winding of the relay 7, contact 9 of relay 4, earth. The test wire is grounded via the normally open contact 6 of the relay 7 and is thereby marked as occupied. Via its contact 4, the relay 7 closes its own holding circuit running through its lower winding. The holding circuit for relay 2 is interrupted by contact 1 of relay 7. The relay 8 is de-energized by opening the contact 7 of the relay 7 *. Through the contact 8 of the relay 7, a dial tone is applied to the line via the normally closed contact 9 of the relay HA, the normally closed contact 2 of the relay GA and the normally open contact 1 of the relay K. The relay 7 also applies a ground potential to the identification switch arm W ¹ or T ^ ² via its working contact 7, and the drive circuit for the line selector S ² is closed via the following path: battery, winding and break contact of the rotary magnet R, working contact 9 of the relay K , Normally closed contact 4 of relay HA, normally closed contact 3 of relay 2, normally open contact 2 of relay 7, normally closed contact 2 of relay 5, switching arm and contact in contact bank N, earth. When the switch arm of the line selector comes to stand on the line selected by the control switch, earth from the identification switch arm via the control switch arm C, the normally open contact 8 of the relay K, the normally closed contact 3 of the relay HA, the normally closed contact 5 of the relay 8, the normally open contact 9 of the Relay 4 connected to relay 5

switches. Relay 5 responds and closes the following circuit for relay HA: battery, winding of relay HA, normally open contact 1 of relay AA, normally closed contacts of relay HA, normally open contact 1 of relay 7, normally closed contact 4 of relay 3, normally open contact 2 of relay 5, Switching arm and contact bank N ¹ , earth. The relay HA is held at its contact 8 via earth and switches the line selector from the control switch SP ² by opening the circuit for the relay 4, which causes the relay 5 to drop. A circuit is now closed for the magnet RM for switching the control switch BP ² to the rest position, which runs via the contact bank N, the normally closed contacts 2 of the relays 5 and 7, the break contact of the magnet and the normally closed contact 4 of the relay 2. In parallel, the relay Q is excited via the normally closed contact 6 of the relay 4 ao, which at the contact Z interrupts the test circuit while the control switch is switched to the rest position. The relay HA further includes the ringing circuit, which as runs follows: earth, alternating-current winding of the relay FA, normally open contact 10 of the relay HA, closed contact 4 of the relay GA, break contact 2 of the relay FA, make contact 5 of the relay K, line -, subscriber loop line -J-, normally open contact 6 of relay K, normally closed contact 3 of relay GA , normally open contact 7 of relay HA to ringing current source RR after battery. When the called subscriber answers, the relay FA responds, and it holds itself to earth via its contact 3 and contact 6 of the relay HA. The relay FA also closes the following circuit for the relay B : battery, winding of relay B, normally open contact 2 of relay K, normally open contact ι of relay FA, earth. The relay jB brings the relay BB to respond. The relay BB causes the relay K to drop out and switches on the relays A and D to the calling and the desired line. Relay A responds and closes a holding circuit for relay B. Relay D switches the speech lines through. If the relay K drops out, the line ^{selector S 2 is} switched off by the call relay group RG ¹ , whose relays then drop out. When the receiver is hung up after the call is over, relays ^ 4 and D drop out and shortly afterwards also relays B and BB . If the called subscriber does not hang up, a circuit running from earth to the normally closed contact 2 of the relay BB and the normally open contact 3 of the relay D to the signal line CSH is closed, which triggers an alarm. The holding circuit of relay B is switched to normally open contact 1 of relay A. If the relay BB drops out after the end of a call, its contact 2 disconnects the ground from the Pxüfader, which triggers the upstream voter; on the other hand, the test circuit to the control switch is only closed when contact 3 of relay BB closes.

If the called line is a single line and is busy, the relay 6 responds as above, which is held when the relay 3 drops. The relay 8 is not energized, and the circuit described above for the relay GA is immediately closed. The relay GA applies a busy signal to the line - and closes a circuit for the relay HA, which switches off the control switch. If the desired line is free, the relay 7 responds, and the other switching operations proceed in the same way as when a free multiple connection line is occupied.

The relay 9 is a timer relay which is to be excited in stages. When earth is applied to the time switch line TP for the first time, the relay 9 is partially energized and it only closes its contact 1. When the earth is switched off again from the line TP, the relay 9 is fully energized via the following circuit: Battery , upper winding of relay 9, normally open contact 8 of relay 4, lower winding of relay 9, normally open contact 1 of relay 9, normally closed contact 8 of relay 3, earth. When earth is switched back on to the line TP , the relay 6 responds. Since both the relay 6 and the relay 9 are now energized, a via the make contact 4 of the relay 6, the make contact 4 of the relay 9, the break contact 3 of the 95 relay 2, the break contact 4 of the relay HA and the make contact 9 of the Relay K running circuit for the magnet · R of the line selector closed. Via the contacts 5 of the relays 6 and 9, an identification potential is switched on to the normally closed contact of the contact bank W ² , and when the line selector reaches this contact, the relay 5 is energized, which via the normally open contact 1 of the relay AA, the normally open contacts 3 of the relay 6 and 9, the normally closed contact 1 of the relay 8, the normally open contact 1 of the relay 5 and the normally open contact 5 of the relay 4, the circuit for the relay HA closes. The relay HA interrupts the drive circuit, the control iw switch is triggered, and the line selector is switched through in the manner already described. An alarm circuit is closed via the line PG via the test ^{switch arm of the line selector S 2} as long as the selector is held in the PG position.

Fig. 3 shows two call relay groups RG ¹ and RG ² , of which the first comprises the relays AA, FA, GA, HA and the second the relays AB, FB, GB, HB. The description given above relates to the mode of operation of the relay group RG ¹ . How the second works

The relay group is the same, with the exception that certain switchings are made in it if the first relay group is already in use when the control switch BP ^{Z is used.} The line selectors operated by the control switch are divided into two subgroups to which the two relay groups are assigned, accessible via lines T to Z or T ¹ to Z ^1. While

ίο the time when a relay group, for example the relay group 22G ¹ comprising the relays AA, FA, GA and HA , is connected to a specific line selector and makes the call to a specific subscriber line, the control switch, which has been released in the manner described above is to be taken into use by a free line selector of the other subgroup, to which the relay group RG ^Z comprising the relays45, FB, GB and HB is ^{assigned via the lines T 1 MsZ 1} . The test circuit runs over the line T ¹ and the normally closed contact 1 of the relay HB, and the relay group AB, FB, GB, HB (RG ^S ) works essentially in the same way as the other relay group AA, FA, GA, HA (RG ¹ ), the mode of operation of which has been described in detail. If the call relay group RG ^{1 is put} into use while the other call relay group is in operation, the earth normally used for current impulses at break contact 1 of relay AB is replaced by earth at make contact 1 of relay GB or make contact 8 of relay HB . If the call relay group i? G ^{2 is taken} into use while the other group is free, the earth used for the impulse emission is switched through by the normally closed contact 1 of the relay AB via the normally closed contact 1 of the relay AA and the normally closed contact 8 of the relay HA , if, on the other hand, the Rufreläisgruppe RG ^{1 is} in operation at this time, this switching takes place via the normally open contact 11 of the relay HA . In a corresponding way. relay groups can be used to activate the busy signal on calling lines.

The embodiment shown in FIGS. 5 to 8 will now be described. Fig. 8 is to the right of Fig. 7 and Fig. 7 below Fig. 6.

Reference is first made to the group selector shown in Fig. 5. A free group selector is characterized by the fact that the battery is connected to the test wire via a low-resistance resistor. If the group selector S ^{3 is occupied} by a preselector of a known type, is a circuit for the relayi? closed, which of the test wire via the normally closed contact 2 of the relay H, the winding of the relay K and parallel to this via the normally closed contact 3, a non-inductive winding of the relay if, normally closed contact 4 of the relay K, normally closed contact 7 of the relay 4, normally closed contact 6 of the relay 4 and the normally closed contact 3 of the relay 9 runs after the battery. The relay K responds and closes the following circuit via its contacts 1 and 2: battery, winding of relay 1, normally closed contacts 4 of relays 82 and 81, normally open contact 2 of relay K, line -, subscriber loop, line -f, normally open contact 1 of the relay K, normally closed contacts 1 of relays 81 and 82, earth. The relay 4 is energized via a readily identifiable circuit, and since it is a delayed releasing relay, it remains energized when the relay 1 opens its contacts during the surge. When the first current surge occurs, a circuit for the relay 5 is closed via the normally open contact 1 of the relay 4 and the normally closed contact 2 of the relay 1. When relay 1 responds again after the first current impulse has ended, the following circuit for rotary magnet R of bypass selector BP ^{3 is} closed: battery, winding and break contact of the rotary magnet, normally closed contact 4 of relay 2, switching arm and first contact of the contact bank /, 8g make contacts 4 of relays 1 and 3, break contact 2 of relay 9, break contact 6 of relay 82, break contact 3 of relay 81, break contact 1 of relay 5, make contact 2 of relay 4, earth. The magnet R, which interrupts its own circuit, causes the switching arms to advance by one step to position 2, where its circuit is closed again when the impulse relay drops at the start of the second impulse via contact 4 of relay 1. The selector therefore goes to position 3, where the circuit of the rotary solenoid is independent of contact 4 of relay 1, and the selector is switched to position 4, and since this is wired to position 3, the circuit for the rotary solenoid is switched from closed again, whereby the selector is switched to position 5.

The circuit for the rotary solenoid is in position 5 again dependent on contact 4 of relay 1, and if this relay after termination of the second current impulse responds again, the circuit for the rotary magnet closed again, and the selector goes to position 6. In position 6, the rotary magnet circuit is not closed again until the impulse relay drops out again and when a third impulse is picked up, the voter is switched to position 9 in a similar way as already described. After the end of the third current impulse, the voter goes to position 10. In this position Way, the voter stores the current impulses recorded by the impulse relay ι. If it is desirable to divide the group selector outputs into ten equal groups, is the position of the voter at the end

IO

58Ö964

the current impulse delivery either 2.6, ίο, 14, i8 etc. depending on the selected digit. Should it happen that when the subscriber loop is interrupted for the purpose of submitting another digit, the voter is in one of the positions 5,9,13 17 etc., then the impulse relay 1 is kept energized via the following circuit: battery, winding of relay 1, normally open contact 3 of relay 3, non-inductive resistance, normally open contact 3 of relay 1, break contact and winding of the rotary magnet, normally closed contact 4 of relay 2, switching arm and contact bank, normally open contact 4 of relay 1, contact 4 of relay 3, earth. Relay 1 remains energized via this circuit until the rotary magnet, which is currently in the process of switching the selector to the next position, opens its breaker contact. In the next position, the rotary solenoid circuit is closed again as soon as relay 1 drops out. This arrangement is therefore provided in order to make the switching of the selector independent of the relative length of the opening and closing times of each current surge. The non-inductive resistance between the contacts 3 of the relays 3 and 1 is provided to eliminate the possibility that the magnet R is excited via the subscriber loop. After the end of the last current impulse, relay 3 drops out and closes the following circuit: battery, winding of relay 2, normally closed contact of relay 5, normally closed contact 6 of relay 3, normally open contact 8 of relay 4, earth. The relay 2 closes the following circuit for the rotary solenoid R : battery, winding and break contact of the rotary solenoid, working contact 4 of relay 2, switching arm and contact in contact bank IV, earth. The selector is switched on until the relay 5 is excited via the following circuit: battery, winding of relay 5, normally closed contact of relay 9, contact 2 of relay 6, bank contact and switching arm of contact bank D, normally closed contact 5 of relay 3, earth. The relay 5 interrupts the circuit already described for the relay 2, which in turn opens the circuit for the magnet R.

In the drawing, the numbers below the contacts of the contact bank D indicate the position of the switching arms after the various numbers have been sent, and the numbers above the contacts indicate the beginning of each group of outputs. The contacts that terminate the redirection of the voter are the first contacts of each group of outputs, and it is evident that if any of the digits 6, 7, 8 or 9 is dialed, the voter will be over the hold contact of some 'others Groups must run away before the first contact of the desired group is reached. For this reason, the stop contacts of groups 1, 2, 3, 4, 6, 8, 0 and those of groups 5, 7, 9 are connected to one another in multiple ways, and they can either be via normally open or normally open contacts of relay 6, depending on the Position in which the voter is brought by the current surges, either energized or de-energized, can be connected to the relay 5. If one of the digits 1, 2, 3, 4, 6, 8 or ο is dialed, the relay 6 remains de-energized, and after the digit has been sent, the voter can get to the beginning of the corresponding group without being interrupted by another group connected to relay 5 to be disturbed. If, however, one of the digits 5, 7 or 9 is selected, a via the normally closed contact 1 of the relay 6, the normally closed contact 6 of the relay 2, the normally closed contacts 9 of the relays 81 and 82, the bank contact of the position in which the voter is dialing a 5, 7 or 9 is stopped, the switching arm D and the normally closed contact 5 of the relay 3 running circuit for the relay 6 is closed. The relay 6 holds itself via its contact 1 and switches the circuit for the relay 5 from the stop contacts of groups 1, 2, 3, 4, 6, 8 and 0 to the stop contacts of groups 5, 7 and 9 through its contact 2 so that when one of these numbers is selected, the selector can be switched to the beginning of the desired group without being disturbed by a stop contact of another group connected to the relay 5. The relay 2 is designed as a delayed responding relay so that the relay 6 has time to respond before the voter starts immediately after the election has ended. The relay 2 then interrupts the circuit for the relay 6, so that this, if it does not have its own, extend to earth via its contact 1, the normally closed contact 4 of the relay 9, the normally closed contact 6 of the relay 3 and the normally open contact 8 of the relay 4 Holding circuit has closed, cannot be energized when the selector is switched if the switching arm D runs over a contact in which the relay 6 would normally be energized.

When relay 5 responds, relay 2 is de-energized in the manner already described, and the following circuit for relay 9 is closed: battery, winding of relay 9, normally closed contact 5 of relay 2, normally open contact 3 of relay 5, normally closed contact 6 of the Relay 3, normally open contact 8 of relay 4, earth. The relay 9 closes the following drive circuit for the magnet R : battery, winding and break contact of magnet R, normally closed contact 2 of relay 5, rest cycle 1 of relays 72 and 71, work cycle 2 of relay 9, normally closed contact 6 of relay 82, normally closed contact 3 of relay 81, rest

contact ι of relay 5, normally open contact 2 of relay 4, earth. At the same time a test circuit is prepared, from earth via the normally closed contact 1 of the relay 3, winding of the relay 71, normally closed contact 2 of the relay 2, normally closed contact 5 of the relay 82, normally closed contact 7 of the relay 81, switching arm and contact in the contact ^{bank Γ 1} over the test wire to a subsequent group or line selector. A similar circuit is closed for the relay 72 via the switching arm T ^z. If a subsequent selector S ⁴ is checked as free, the relay 71 (or relay 72) responds and interrupts the drive circuit by opening its normally closed contact 1. At the same time, the relay closes the circuit for the relay 81 (or relay 82) via the normally open contact ι. This relay maintains its own contact to earth at contact 2 of relay 4, applies earth to the test wire via contact 7, interrupts the test circuit at contact 5, switches the line - at contact 4 and the + line at contact 1 through and switches the circuit for the relay 5 through the normally open contact 7 (or 8) of the relay K to the switching arm M ² (or M ¹ ) of the group selector S ² at the contact 9.

Via contact 3 of relay 81 (or contact 6 of relay 82), normally open contact 5 of relay K and the break contact of magnet J? ^{1 of} the group selector S ³ , earth is connected to this magnet, whereby the group selector is switched on until its switching arms M ¹ or M ^{2 are} on the bank contact, which corresponds to the one on which the control ^{switch SP 3} is, and the switch arm M through contact 6 of relay 81 or contact 3 of relay 82 is grounded. Then relay 5 responds and closes the following circuit for relay H : earth, normally open contact 8 of relay 4, normally closed contact 6 of relay 3, normally open contact 3 of relay 5, normally open contact 5 of relay 9, normally open contact 8 of relay 81 (or 82) , Normally open contact 6 of relay K, winding of relay H, battery. The relay H responds and switches through the lines -f- and - and the test wire to the switching arms. When relay 81 (or 82) responds, the circuit for relay 1 is interrupted and this relay drops out. In contrast, the circuit for the relay 4 is maintained via the normally closed contact ι of the relay 1, the normally open contact 3 of the relay 81 (or the normally open contact 6 of the relay 82), the normally closed contact 1 of the relay 2 and the normally open contact 2 of the relay 4 to earth. When the relay 5 responds, this circuit is opened and the relay 4 is brought to drop. This causes the relays 81 (or 82), 9 and 5 to drop out and the completion of a circuit for switching the bypass selector SP ³ to the rest position.

The switching arms - and - and the test switching arm of the group selector consist of electrically connected pairs of switching arms, the switching arms of each pair being offset from one another by 180 ° and running over different sets of contacts during one full rotation of the selector. The identification switch arms M ¹ and M ² are also offset from one another by 180 °, but are not electrically connected to one another, and they run over the same row of contacts with one full revolution. As can be seen from the above description, the correct identification switch arm is switched on by the through switch relay 81 or 82 suitable for this purpose. This arrangement saves a row of contacts in the group selector S ³ and an identification switch arm in the bypass selector BP ^3.

If all outputs of the desired group are occupied, when the switching arms of the bypass selector reach the last contact set of the group, the following circuit for relay 5 is closed: battery, winding of relay 5, normally open contact 6 of relay 9, normally closed contacts 9 of relays 81 and 82, normally open contact 7 of relay 9, contact and switching arm in contact bank D, normally closed contact 5 of relay 3, earth. In the event that the selector is switched to the last contact of the fifth group, this circuit does not run via contact 7 of relay 9, but directly, since this position is also reached when digit 7 is selected and in this case the Excitation of relay 6 caused. When relay 5 is energized via one of the last contacts of the group of outputs, the following circuit for relay 2 is closed: battery, winding of relay 2, normally closed contacts 8 of relays 82 and 81, normally open contact 5 of relay 9, normally open contact 3 of relay 5 , Normally closed contact 6 of relay 3, normally open contact 8 of relay 4, earth. The relay 5 interrupts the drive circuit for the magnet R through its contact 2, and the busy signal on the line is switched on via the normally open contacts 1 of the relays 2 and 9.

Since the number of steps to be carried out by the group selector to reach the contacts identified by the control switch BP ² is different in each case, it is possible that the next digit has already been executed. is sent before the group selector has reached the marked contacts. During this time, the impulse circuit is activated by the following control switch via the contacts and switching arms of the control switch that controls the further switching of the group selector S ^3.

ters BP ^S and the contact of the relay K switched through to the subscriber loop. If the relay H accidentally responds during a current surge, each wire of the subscriber loop is switched through both to the switching arms of the group selector and via a branch to the control switch SP ³ until the relay 4 of the control ^{switch SP 8} drops out, whereby the relays 81 or 82 are de-energized and thereby the branch is interrupted. In a corresponding manner, the connection is switched through to the line selection level via one or more further group selection levels. Reference will now be made to the line selection stage shown in FIGS. 6, 7 and 8. The line ^{selector S 4} is assigned via the following circuit: Earth on test wire T, inductive winding of relay K and parallel to this, normally closed contact 4 of relay K and non- inductive winding of relay K, normally closed contact 3 of relay BB, normally closed contact 2 of relay 4, normally closed contact 1 of relay W, non-inductive resistance, battery. Relay K responds and closes the following circuit for relay 1: battery, resistor, normally closed contact 2 of relay 6, winding of relay 1, normally open contact ι of relay K, line -, subscriber loop, line +, normally closed contact 1 of relay BB, earth . The relay 1 responds and closes an easily recognizable circuit for the relay 4. At the first current surge, the relay 1 drops out and closes the following circuit for the magnet i? ^{2 of} the selector BP ^: battery, winding and break contact of magnet R ² , switching arm and first bank contact of the selector, normally closed contact 1 of relay i, normally closed contact 2 of relay 5, normally closed contact 4 of relay 7, normally open contact 4 of relay 4, earth. In position 2 the bank contact is earthed, and therefore the selector goes to position 3 and then to position 4. If relay 1 responds again after the current surge has ended, is the circuit for magnet 2? ^{2 is} closed again via normally open contact 1 of relay 1, and the selector is switched to position 5. In this position, the magnet R ^{z is} again dependent on the normally closed contact of the relay 1, and in the event of a further current surge, the selector is switched to position 9. Depending on the number chosen, the voter comes to a standstill in either position 1, 5, 9, 13, 16, 20, etc. If the selected digit is either 1, 3 or 7, the following excitation circuit is closed for relay Y : Earth, normally open contact 4 of relay 4, normally closed contact 4 of relay 7, normally closed contact 2 of relay 5> switching arm and contact in contact bank D, Normally closed contact 6 of relay W, upper winding of relay Y, battery. Similarly, if either a 5 or a 9 is selected, the following excitation circuit for relay Y is closed: earth, normally closed contact 5 of relay W, lower winding of relay Y, lower winding of relay 2, battery. So if an odd number is selected, relay Y responds and selects between the two switch arm sets. If relay 3, which drops out with a delay, is de-energized after the end of the current impulse, the following circuit for relay W is closed: battery, winding of relay W, normally closed contact 1 of relay 3, normally open contact 5 of relay 4, contact bank and switching arm N, earth. The relay W holds itself via its contact 3. It has already been stated that when one of the digits 5 or 9 is dialed, the relay 2 is energized, and in a similar manner the relay 2 is activated via its other winding and the normally closed contact 2 of the relay W energized when one of the digits 6 or 0 is dialed. This circuit comes about before the relay 3 has dropped out, and the relay 2 holds itself to earth via its contact 3 and the normally closed contact 3 of the relay 3. Furthermore, the relay 2 closes another holding circuit for the relay W via its contact 6. Since the relay Y distinguishes between even and odd numbers, the ten groups of subscriber lines are characterized by only five holding contacts. These are in positions 2, 12, 22, 32 and 42 (which correspond to the beginning of groups 9 and ο, ι and 2, 3 and 4, 5 and 6 and 7 and 8), and as soon as the relay W responds, the voter is switched to one of these positions. The circuit for the drive magnet R ^z runs as follows: battery, winding and breaker contact of the magnet

² , normally open contact 8 of relay W, normally closed contact 2 of relay 5, normally closed contact 4 of relay 7, normally open contact 4 of relay 4, earth. When one of the digits 5, 6, 9 or ο has been selected, relay 2 switches relay 5 from positions 22 and 42 and applies it to contacts 2 and 32. This enables the selector to stop contacts of the groups overflows, which it must exceed in order to reach the group indicated by the control switch. The holding circuit for relay Y runs from the battery and its upper winding via its normally open contact 2 and normally closed contact 3 of relay 3 to earth. When selecting the one digit, the circuit for magnet R ^{z is} as follows: battery, winding of magnet R ² · , normally open contact 4 of relay W , normally open contact 3 of relay 4, normally closed contact 2 of relay 1, earth. The voter takes a number of steps corresponding to the number of pulses forming the one digit. Relay 3 responds with the first current surge,

which causes relay 2 (if energized) to drop out. The relay 6 checks the contacts of the subscriber lines, specifically via the normally open contact 2 of the relay 3, the contact 3 of the relay Y and the test wire T ¹ or T ² . If the relay 3 drops after the end of the series of single currents, the relay 6 responds, and it holds itself to earth via the normally closed contact 2 of the relay 3, the normally open contact 3 of the relay 6 and the normally open contact 4 of the relay 4. The busy signal is applied to the line to the calling subscriber via contact 2 of relay 6 and the line relay. If the desired line is not busy, when relay 3 drops out, the following circuit for relay 7 is closed: earth, normally closed contact 1 of relay 6, upper winding of relay 7, normally closed contact 2 of relay 3, contact 3 of relay Y to test wire T. ¹ or T ² . The relay 7 responds in series with the switch-off relay and holds itself via its lower winding and its contact 3 to earth on the working contact 4 of the relay 4. Through the contact 4 of the relay 7, earth is sent to the identification switch arm M via the contact 1 of the relay Y. ¹ or M ^{2 is} applied, and the following circuit for the rotary magnet R of the line selector S * is closed via the normally open contact 3 of the relay 7: earth, normally open contact 4 of relay 4, normally open contact 3 of relay 7, normally closed contact 1 of relay 5, break contact and winding of magnet R, battery. When the switching arms of the line selector S ^{4 are brought} into the position corresponding to the position of the control switch, the following circuit for the relay 5 is closed: battery, winding of relay 5, working contact 8 of relay K, control switching arm C and bank contact of the line selector, identification switching arm M ¹ or M ^{2 of} the control switch, contact 1 of relay Y, working contacts 4 of relays 7 and 4, earth. When it responds, relay 5 interrupts the drive circuit for line selector S ⁴ and closes the circuit for relay 2 that runs via normally open contact 2 of relay W. Relay 2 closes the following ringing circuit: AC power source at contact 1 of relay 2, normally open contact 1 of the relay 7, normally closed contact 1 of relay F , normally open contact 6 of relay K, line -f-, subscriber line of the called party, line - , normally open contact 5 of relay K, normally closed contact 2 of relay F, normally open contact 2 of relays 2 and 7, upper winding of the relay ! ⁷ , back to the AC power source and earth. The dial tone is transmitted to the calling subscriber via a capacitor located between the winding of the relay 1 and the contact 2 of the relay 7. When the called subscriber answers, the relay F responds, which is maintained over an easily recognizable circuit. The relay F also closes a circuit for the relay B ₁ running via the normally open contact 2 of the relay K, which causes the 5s relay BB to respond. The relay BB interrupts the circuit for the relay K, which opens the circuit for the relay 1. Relay 1 triggers the control switch. The relay BB places the relay A in the subscriber loop of the caller and the relay D in the loop of the called party. Relay A reverses the direction of the current across the caller's loop. The relay B is dependent on the normally open contact 1 of the relay A and therefore remains energized when the relay K drops out. Relay B holds ground on to the forward and reverse test lead.

Claims (15)

80 claims: 1. Circuit arrangement for automatic and semi-automatic telephone systems with bypass dialers, characterized in that the number of bypass dialers used to establish a connection between a calling and a desired subscriber {BP ¹ , BP ² , FBP in Fig. 9) is equal to the number of voters (S ¹ , S ² , FS in Fig. 9) is in the voice communication path and that the connection from dial to dial from the bypass ^{dialers (SP 1} , SP ² , FBP) to the voice dialers (S ¹ , S ² , FS) during the Establishing the connection is switched. 2. Circuit arrangement according to claim 1, characterized in that the bypass selectors (SP ¹ , SP ² , FBP in Fig. 9) are triggered one after the other from selection level to selection level. 3. A circuit arrangement according to claim 2, characterized in that control lines are provided, the number of which is smaller than the largest number of current surges in a number current surge series and each of which with several non-consecutive contacts of a 'control contact bank (10 in Fig. 1 or C in Fig. 4) the bypass selector (BP ¹ in Fig. I, BP ² in Fig. 4) are connected, an assigned current surge receiving device (relay group P, Q, R) applies an identification potential in cyclical succession to these control lines depending on the current surges received so that when the switching arms of the bypass selector (BP ¹ , BP ² ) reach a position indicated by the number of current impulses received, a circuit for a switching means ( Relay 5) is closed, which interrupts the circuit for the drive magnet (RM) of the bypass selector (SP ¹ , SP ² ). 4. Circuit arrangement according to claim 3, characterized in that the surge receiving device comprises a relay group (P, Q, R) to be actuated by two numbered surge series in cyclical succession, which, depending on the first surge series, the setting of the switching arms of the bypass selector (SP ¹ in Fig 1, SP ² in Fig. 4) to a desired line group and, depending on the second series of impulses, controls the setting of the switching arms of the bypass selector to a desired line in the selected group of lines. 5. Circuit arrangement according to claim 4, characterized in that the bypass ^{selector (SP 2} in Fig. 4) is equipped with two switch arm sets (Γ ¹ , X ¹ and T ² , X ^z ) , which run over contacts from different outgoing lines at the same time, and the impulse receiving relay group (P, Q, R) a circuit (magnet RM, normally open contact 4 of relay 2, normally open contact 5 of relay R, normally open contact 6 of relay P) for switching the bypass selector (BP ² ) by one step for each impulse of the second series of impulses closes. 6. Circuit arrangement according to claim 5, characterized in that depending on the operating state of the relay group (P, Q, R) after the end of the second series of impulses from the switching arm sets (T ¹ , X ¹ and T ² , X ^z ) a certain is selected ( via contacts 6 and 8 of relay Q). 7. Circuit arrangement according to claim 1, characterized in that the bypass selector (BP ³ in Fig. 5 or BP ⁱ in Fig. 7 and 8) with a surge transmission device (relay i), which the bypass selector (BP ³ or BP ^) during the Brings current impulses into an initial position by a number of steps exceeding the number of transmitted current impulses, and is provided with switching means (e.g. relay 2 in Fig. 5) which, after the end of the current impulse series, creates a circuit (e.g. magnet R, normally open contact 4 of the Relay 2, switching arm and contact bank N in Fig. 5) to switch the bypass ^{selector (SP 3} , BP ⁴ ) into a position determined by the number of current impulses in the current impulse series. 8. Circuit arrangement according to claim 7, characterized in that the switching arms of the bypass selector (BP ³ in Fig. 5 or BP * in Fig. 7 and 8) at the beginning of a current surge through a break contact (4) of a surge relay (1 in Fig. 3) and a control switching arm (I) of the selector by one step, during the current impulse by a drive circuit running via the control switching arm (J) but independently of the impulse relay by two steps and after the end of the current impulse by a working contact (4) the impulse relay (1) and the control switch arm (I) running drive circuit can be advanced by a further step. 9. Circuit arrangement according to claim 7, characterized in that the bypass selector (BP ⁹ ' in Fig. 7 and 8) is equipped with ■ two switching arm sets (M ¹ , T ¹ and M ² , T ² ) which simultaneously have contacts from different outgoing Cross lines and one or the other of which is switched on by switching means (relay Y) which, depending on the initial position in which the bypass dialer (BP ⁹ ) is brought by the number current impulses, come into effect or not. 10. Circuit arrangement according to claim 7, characterized in that the current impulse transmission device (relay 1) is actuated by a second series of impulses and a circuit (magnet i? ² in Fig. 8, working contact 4 of the relay W in Fig. 7, working contact 3 of relay 4 and normally closed contact 2 of relay 1) closes, via which the bypass selector (BP ⁴ ) is switched one step further with each current surge. 11. A circuit arrangement according to claim i, characterized in that in the group selection stages of the contact banks (1,2,3,4 in Fig. Ι and + ^τ > + ² > - ¹ ^ - ² ^ ¹¹ Fig. 5) of the bypass selector (SP ¹ in Fig.i, BP ³ in Fig. 5) outgoing lines with the outgoing lines from the contact banks (-) - and -) of the assigned talk group dialers (S ¹ , S ^a ) are multiple switched and the bypass dialers (BP ¹ in Fig. I, BP ³ in Fig. 5) a bypass route when selecting a line (e.g. line + in Fig. 1, normally open contact 1 of relay K, contact 2 of relay 81 and line -, normally open contact 2 of relay K , Contact 1 of the relay 81) for the subsequent setting current surges, which is through a direct path (e.g. line + in Fig. 1, working contacts 1 of relays K and H and line -, working contacts 2 of relays K and H) is replaced iao if an assigned talk group selector (S ¹ , S ³ ) is triggered by the bypass - dialer (SP ¹ , SP ³ ) selected line busy. 12. Circuit arrangement according to claim i, characterized in that of the bypass selectors (BP ¹ , BP ² , BP ^S , BP ⁴ ) lines (z. B. A to H in Fig. I) via parallel branches to contacts (i to 7 ) of a relay (K) in each of the speech dialers (S ¹ , S ² , S ³ , S ⁴ ), to which a bypass dialer (BP ¹ , BP ² , BP ³ , SP ⁴ ) is assigned, run and the relay (K ), if a speech selector (S ¹ , S ² , S ³ , S ⁴ ) is occupied by an upstream selection level, is excited and these lines (A to H) via the mentioned relay contacts (1 to 7) with the occupied speech selector (S ¹ , S ² , S ³ , S *) interconnected. 13. Circuit arrangement according to claim 1, characterized in that immediately after the connection to a speech selector (S ¹ , S ² , S ³ , S ⁴ ) "has been switched, switching means (relay H) come into effect, which the bypass selector ( Switch off BP ¹ , BP ² , BP ³ , BP *) and enable it to be used to establish another connection. 14. Circuit arrangement according to claim 1, characterized in that a group of voice dialers (S ² in Fig. 2) of the last selection level, to which a bypass dialer (BP ² in Fig. 4) is assigned, is divided into two or more subgroups and each of them a call relay group (2JG ¹ , RG ² in Fig. 3) is assigned and a switching device (relay HA or HB) is assigned to one of these relay groups (RG ¹ , RG ² ) if a speech selector (e.g. S ² ) is a subgroup a line selected by the bypass selector (BP ² ) seizes, comes into effect, applies ringing current to the selected line and disconnection and release of the bypass selector and the provision for the time when the first ringing relay group controls the connection of ringing current to the selected line another call relay group for use by a voice selector of another subgroup. 15. Circuit arrangement according to claim 1, characterized in that when a desired line is occupied by the bypass selector (z. B. BP ¹ in Fig. 1) switching means (relay 81 or 82) come into effect, which create a circuit for the drive magnet (R ) of the speech selector (S ¹ ), which adjusts to a line selected by the bypass selector (BP ¹ ) , whereupon switching means (relay 5) assigned to the bypass selector via a control switch arm (m) of the speech selector (S ¹ ) and a control switch arm ( 7 or 8) of the circuit including the bypass selector (BP ¹ ) become effective and interrupt the circuit for the drive magnet (R) of the speech selector (S ¹ ). For this purpose 2 sheets of drawings