US2300951A - Telephone system - Google Patents

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US2300951A
US2300951A US404109A US40410941A US2300951A US 2300951 A US2300951 A US 2300951A US 404109 A US404109 A US 404109A US 40410941 A US40410941 A US 40410941A US 2300951 A US2300951 A US 2300951A
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relay
contacts
conductor
ground
circuit
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US404109A
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William A Malthaner
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q3/00Selecting arrangements
    • H04Q3/0004Selecting arrangements using crossbar selectors in the switching stages

Definitions

  • This invention relates to telephone systems and particularly to small capacity telephone systems in which crossbar switches are employed.
  • An object of the invention is to provide means whereby line stations equipped with different types of call devices may operate common apparatus with which to set up desired connections as, for instance, between a station equipped with a dial sender to transmit a series of impulses designating a called number and a station that utilizes an alternating current generating device to generate and transmit combinations of different frequencies to designate the called line number.
  • a feature of the present invention is an arrangement in a system of the above kind in which a connection may be established between two subscriberslines by means of a link which, on the one hand, is adapted to respond to dial pulses produced at an originating station equipped with a dial to set up a connection to the station indicated by the pulses and, on the other, is also adapted to respond to combinations of currents of-dverent frequencies generated at an originating station, to set up the connection to the station indicated by such combinations of frequencies.
  • the link is provided with suitable registers for response to either type of pulses,
  • the direct current register is the one which, in all cases, operates the hold magnet of the called line in the crossbar switch.
  • a translator is provided whereby, in response to the settmg of the grster that respfinds to the albeen given a numerical designation 2! while line ternating current pulses designating the digits of the called line, the direct current register is set for those which then controls means for operating the hold magnet of the called line.
  • Figs. 1 and 2 show, diagrammatically, a crossbar switch frame of known construction having ten horizontal outlets and twenty verticals to each of which a subscribers station is connected.
  • the first vertical, assigned to station A, has a line number designation 2t
  • the last vertical, assigned to station B has a number designation 39
  • station A being provided with a dialing device LD and station B being provided with an alternating current or key pulsing generating device LG;
  • Fig. 3 in the left portion thereof, shows a link allotter circuit, while the rest of this figure, together with Fig. 4 show the call allotter circuit;
  • Figs. 5, 6, 7, 8 and 9 show the details of the link circuit
  • Fig. 10 shows, in diagrammatic form, two other links and a power generating, tone and alarm circuit; while Fig. 11 shows the manner in which Figs. 1 to 10, inclusive, should be arranged with respect to each other to completely disclose the invention.
  • connection originating at station A for station 13 in which the number designation 39 of station B will be dialed at station A through the manipulation of dialing device LD thereat, and a connection originating at station B for station A in which the number designation 2%) of station A will be set up on device LG by the depression thereon of keys (not shown) corresponding to the digits of the designated station.
  • the dial LD is the ordinary impulse dial well known in automatic telephony and its manipulation interrupts the line to produce a series of pulses the number of which corresponds to the digit to which the dial is pulled over to the stop attachment prior to releasing it for its return to normal in the course of which the train or series of impulses is produced.
  • the device LD is an alternating current generator which, for example, may be of the type shown in Patent No. 2,147,710 granted to R. F. Mallina on February 21, 1939. It comprises a number of reeds which may be plucked in pairs to produce vibrations within a magnetic field and thereby cause the generation of currents having frequencies determined by their several physical constants. These currents are transmitted over the link into registers therein for use in causing the link to complete the connection to the desired line.
  • link I (the circuit of which is shown'in detail in Figs. to 9, inclusive) occupying the two uppermost outlets controlled, for selective purposes, by select magnets 8 and 9; link 2 occupying the two horizontal outlets immediately below those of link I and controlled by select magnets 6 and I, while link 3 occupies the two horizontal outlets immediately below those of link 2 and controlled by select magnets 4 and 5.
  • the remaining four outlets of the switch may, if desired, be used as outgoing trunks or links. However, since the invention is not concerned with outgoing connections, these outlets are not shown connected either to links or trunks.
  • Fig. 3 there are shown three relays, namely, relays CHI, CH2 and CH3, which form a link allotter circuit, the first two relays being shown in an operated position while the last is shown in an unoperated position.
  • the operated condition of relay CHI indicates that the link to which it provides access is in an idle condition, its locking circuit (that is, the locking circuit of relay CHI) extending from battery through the winding thereof, contacts of KYI, conductor 2, No. 1 contacts of relay B of link I, conductor 3, No. 3 front contacts of relay CHI to ground.
  • the locking circuit of relay CH2 which controls access to the second link is traced over a path which extends from battery through its winding, key KY2, conductor 2 in the bracket line 4, through the No. 1 back contacts of relay B in link No. 2 (diagrammatically indicated in Fig. conductor '3 in the bracket line 4, No. 5 contacts of relay CH2 to ground.
  • relay CH3 which provides access to link No. 3, while traceable over its associated key KY3, conductor 2" within bracket line 5, through the No. 1 contact of relay B in link 3 (diagrammatically shown in Fig. 10) and conductor 3" within bracket line 5, terminates in the No. 3 normal contacts of relay CH3 and also in the No. 3 open contacts of relay CHI.
  • relays CHI and CH2 must be operated while relay CH3 must be normal.
  • relay L29 of said line which extends from battery over the upper normal contacts of the hold magnet HOZii associated with vertical 29, winding of relay L20, ring conductor R, over the station loop, tip conductor T, No. 1 normally made contacts of relay L28 to ground on the No. 1 contacts of cut-ofi relay C026.
  • Relay L29 operates. Over its No. 1 contacts, the ground terminal of its circuit is switched from solid ground on the No. 1 contacts of relay CO to ground through the secondary Winding of transformer LBT to the primary of which a source of distinctive tone is connected for transmission to the calling line in the event that no link is available for completing the connection, as will be described shortly.
  • relay L20 causes a circuit to be completed for relay LI of the call allotter circuit (there being one LI relay for each line) and relay ST of link I which, since relays CHI and CH2 of the allotter are assumed to be locked and relay CH3 is assumed to be normal, is the preferred link in the order of selection.
  • the circuit for the relays ST and LI is traced as follows: Ground through the No. 1 contacts of relay EI, winding of relay LI, conductor 6, No. 2 and No. 3 contacts of relay L20, start conductor I, No. 3 contacts of relay CH2, No. 1 contacts of relay CHI, conductor 1, winding of relay ST to battery. Both relays LI and ST operate in this circuit.
  • Relay LI upon operating, opens the locking circuit of all other nineteen LI relays at its No. 4 contacts and completes a circuit for relay N, which circuit may be traced from ground on the No. 1 contacts of relay LI, conductor Ill, No. 1 back contacts of relay M, No. 4 contacts of relay MS, winding of relay N to ground.
  • Relay N operates and completes a circuit for relay M from ground on its No. 2 contacts, No. 1 back contacts of relay MS, winding of relay M to battery.
  • Relay M operates and opens the circuit of relay N at its No. 1 back contact causing it to release while the release of relay N opens the circuit of relay M which, however, remains locked under the control of the No. 1 contacts of relay MS and its own No. 2 contacts to ground on conductor IE1.
  • relay MS When relay MS operates as described below, relay M releases. This cycle for operating relays M and N ordinarily performs no useful function but will perform an emergency function that will be explained in its proper sequence.
  • relay LI completes another circuit for relay E which may be traced from ground on the No. 1 contacts of relay EI, No. 2 contacts of relay L, conductor 3, serially through the No. 1 back contacts of the individual link relays LKS, LKZ and LKI, conductor 9, winding of relay E to battery.
  • Relay E upon operating, locks to ground on the No. 1 contacts of relay LI and at the same time closes a circuit for relays EI and E2 from ground on its contacts, No.
  • relay MS normally made contacts of relay MS to the windings of relays EI and E2 to the other respective terminals of which battery is connected.
  • Relays EI and E2 operate but relay LI, which operated from ground on the No. 1 contacts of relay El, now holds locked on battery through relay SI of the selected link as previously traced to conductor B, winding of relay LI and its No. 2 contacts, conductor 8 as traced to conductor 9, contacts of relay E to ground on the No. 1 contacts of relay LI.
  • relay EI When relay EI operates, it completes a circuit for relay MS, said circuit tracing from ground on conductor It, No. 14 contacts of relay EI, winding of relay MS to battery.
  • Relay MS operates after an interval, opens the path of relay N, supplies holding ground over its No. 2 contacts for relays El and E2 and applies ground on conductor It! to conductor II over its No. 3 contacts.
  • Ground on conductor II is used to complete the circuit of the link select magnet 9 in virtue of operations which have been taking place in the link as a result of the operation of relay ST therein and which will shortly be described.
  • relay MS In the event that, due to some trouble condition, relay E of the call allotter fails to operate, relay MS cannot operate and ground will not be applied to conductor I I over its No. 3 contacts. Under these circumstances it is desirable to complete the connection if possible and so emergency means are provided for applying ground to conductor I! in the event that relay MS fails to operate. It will be remembered that upon the operation of relay LI a circuit was completed for relay N, and that prior to the operation of relay MS/relay N caused the operation of relay M. Now, when relay lVl" operates, it opens the circuit of relay N but relay M remains looked over its No. 2 contacts to ground on conductor Ill, and it will be observed that, with relay N normal and relay M operated, ground on conductor I0 is applied to conductor I 1 via the No. 1 front contacts of relay M and No. 1 contacts of relay N.
  • relay ST a circuit is completed for select magnet 9, which circuit traces from battery through the winding of said magnet, conductor H, No. 2 contacts of relay B, N o. 4 contacts of relay ST, conductor I I, to the aforetraced ground thereon.
  • Select magnet operates and preselects the group of cross,- points on its horizontal level, including crosspoint I through which the calling loop is extended into the link as shown hereinafter.
  • Relay COZil upon operating, closes an obvious circuit for hold magnet HOZiI of the Vertical 29 to which line A is conwhich links I and 2- are unava' nected and, in so doing, operates crosspoint I.
  • This crosspoint remains operated after the circuit of select magnet 9 has been opened, is standard crossbar switch operation and need not be amplified any further.
  • hold magnet H028 which may be traced operates, it releases line relay L20 in turn releasing relay LI and those relays controlled thereby.
  • Relay L20 further disconnects ground from start conductor I which caused the operation of relay ST.
  • crosspoint I since crosspoint I is closed, this relay will not release, having a locking circuit through a crosspoint contact, which may be traced over the No. 2 contacts of said relay, No. 1 contacts of relay T2, conductor SI, No. 3 contacts of crosspoint I, to ground.
  • Relay A u on operating, completes a circuit for relay B, which circuit extends from ground on conductor SI, front con: tacts of relay A, No. 4 normally made contacts of relay B, winding of relay B to battery, causing said relay to operate and lock over its No. 4 front contacts to ground on conductor Si.
  • Rela B at its No. 2 contacts, opens conductor ll thereby causing the release of the select magnet s. Since however, the hold magnet H023 is operated, crosspoint I remains operated.
  • Relay ]3 further completes a circuit from ground over itsNo. 3
  • relay CHI in the power charge circuit Hill to operate circuits thereby that will increase the charging rate to the link power supply while the link is being used and, over its No. 5 and N0. 6 contacts, connects ground to holding conductors 20 and 2! for holding andopcrating certain other relays as described hereinafter.
  • No, 1 contacts it opens the looking circuit of relay CHI in the ailotter circuit which, upon releasing, advances the common start conductor I over the Nlo. 3 contacts of relay CH2, No. 2 contacts of relay CHE. No. 1 contacts of relay CH2 to conductor 1' which further ex ⁇ tends to relay ST of link 2.
  • relay CH3 will be normal along with relays CHI and CH2.
  • the initiation of a call under these circumstances will cause ground on the start conductor I to be applied to conductor 22 via the No. 4 contacts of relay CH2, No. 1 contacts of relay CH3, No. 2 contacts of relay CHI, No.'2 contacts of relay CH2, to conductor 22.
  • This conductor extends (through bracket line I3) to the power, tone and alarm circuit lit] and closes a circuit therein which causes a distinct link busy tone to be applied to the conductors 23 and 2% connecting with the primary winding of busy tone transformer LBT.
  • relay CH2 operates and locks to ground over its No. 3 contacts to reestablish the path of start conductor I'to the winding of relay ST in readiness for seizure on the next call. If link 2 becomes available, relay CH2 operates over a circuit traceable from battery through its winding, thence as traced to conductor 3' to ground on the No. 3 normally made contacts of relay CH3.
  • relay ST of link I ground on the No. 3 contacts of said relay completes a circuit for relay LSI of its private link connector and this circuit is traced from ground on said contacts, conductor 58, winding of relay LSI. serially through the No. 2 normally made continuity contacts of relays LS2 and LS3 (the former being individual to link 2 and the latter individual to link 3) to battery.
  • Relay LSI operates. connects operatingbattery to its winding through its own No. 2 front contacts and, over its No. 1 front contacts, completes an obvious circuit for cut-in relay LCI which operates as a result thereof.
  • the object of operating relays LSI and LCI is to connect the common alternating current pulse receiver and translator shown in Figs. 8 and 9 to the link taken into use, and when this circuit is s connected.
  • the si nal for which is the operation o relay LSI said receiver must be made unava lable to other l nks. This is done by removin the ope a in round for relays LC2 and 03 at the No. 1 back contacts of relay LSI so that, if either relay LS2 or LS3 should have its operatin circuit establ shed by relay ST of its respective link.
  • the circuit of relay LC2 or LC3 is cut off at the No. 1 back contacts of relay LS5.
  • the other hand On the other hand.
  • the alternating current receiver of Fig. 9 is adapted to receive alternating current impulses from a calling station equipped with an alternating current generating device such as, for example, the device LG at station B. At the time a call is initiated, however, the seized link has no knowledge of which type of station is making the call.
  • Relay GR operates and disconnects ground from conductors II and 12 which, as will be shown, are connected to the calling loop through the operation of relay ON.
  • a circuit is also completed for relay ON which is traced from ground on the N0. 5 contacts of relay LCI, conductor 69, winding of relay ON to battery.
  • Relay ON operates and, over its No. 1 contacts, closes through a low frequency tone circuit derived from the tone oscillator It through adjustable resistance pad 62 and transformer 6
  • the path is traced as follows: From the lower terminal of the secondary winding of transformer 6
  • the tone frequencies produced by the oscillator 'Iil are thus induced over the secondary circuit above trace
  • the low frequencies are induced in the closed circuit comprising the transformer 68, a transformer in said low-pass filter and a transformer in high-pass filter fi l.
  • suitable filter networks which are designed to pass only frequencies Within the signal frequency band of the frequencies that are produced by the. station generator LG when operated.
  • the tone frequencies produced by oscillator it will not pass into the volume limiter or into the enabler 89. They will, however, be induced into the secondary winding of transformer 53 if said secondary winding is closed into an electrical system, which it is because conductors II and I2 are but extensions of the line conductors T and R into the link and alternating current receiver connected thereto.
  • the subscriber upon receiving a tone, operates the dial ID to transmit the called line designation.
  • the capacity of the ofiice is twenty lines and that the number of designations of said line extends from twenty to thirty-nine, inclusive, it being further assumed that station A has a designation of 29 and that station B has a designation of 39.
  • the calling subscriber therefore, dials a wanted designation by dialing two digits, the first of which may be a 2 or a 3 and the second of which may be any digit from to 9. Since the connection is to be established between the calling line A and called line B, the subscriber at A will first manipulate his dial to transmit three pulses for the tens digit and, thereafter, nine pulses for the units digit.
  • relay A releases on the first pulse, it completes a circuit for relay Pl which extends from ground on conductor Sl, the back contacts of relay A, No. 3 contacts of relay B, No. 2 contacts of relay E, back contacts of relay P2, No. 2 back contacts of relay P3, winding of relay Pl to battery.
  • relay Pl a branch circuit further extends to the winding of slowrelease relay C.
  • relay SW which extends from battery through its upper winding and No. 2 normally made contacts, No. 5 back contacts of relay T2, No. 2 front contacts of relay Pi, conductor 23, No. 5 contacts of relay RT, conductor M, No. 1 front contacts of relay C to ground on conductor 25.
  • Relay SW operates and locks over its No. 2 front contacts to ground on the No. 1 front contacts ofrelay C.
  • relay A When relay A operates at the termination of the first pulse, the short circuit around the lower winding of relay P2 is removed and said relay operates in series with relay Pi over a circuit path which traces from ground on the No. 2 contacts of relay C, lower winding of relay P2, No. 1 contacts of relay Pl, No. 2 contacts of relayPZi, winding of relay P1 to battery.
  • relays Pl, P2 and SW are operated, the latter being looked, as said before, to ground on conductor 2! through the No. 1 contacts of relay 0 which, being slow releasing, remains in an operated position between pulses.
  • relay A releases again and completes a circuit path for relay P3 which extends from ground on its back contacts, No. 3 contacts of relay B, No. 2contacts of relay E, front contacts and upper winding of relay P2, winding of relay P3 to battery.
  • Relay P3 operates and releases relay Pi after which a, circuit is completed for relay T2 which extends from battery through the upper winding of relay T2 and its No. 3 normally made contacts, No. 4 front contacts of relay SW, No. 2 back contacts of relay Pl, conductor 23, and thence as previously traced to ground on the No. 1 front contacts of relay C.
  • Relay T2 operates, locks through both of its windings in series through its No. 3 front contacts, No. 5 contacts of relay HS, conductor 29 to groundon the No. 5 contacts of relay B and opens the locking circuit of relay ST which releases but its release results in no other function at this time.
  • relay A reoperates and relays P2 and P3 release.
  • the pulsing relays Pi, P2 and P3 are normal, relay C is in an operated position due to its slow-releasing characteristics, while relays SW and T2 are locked.
  • relay T3 which extends from-battery through its upper winding and No. 2 normally made continuity contacts, No. 1 contacts of relay DC, No. 5 front contacts of relay SW, N0. 5 front contacts of relay T2, N0. 2 front contacts of relay PI and thence as already traced to ground on the No. 1 front contacts of relay C.
  • Relay T3 operates and, through its No. 2 front contacts, locks serially on both windings, to previously traced ground on the No. 5 contacts of relay B.
  • relay A reoperates and relay P2 operates in series with relay Pl as previously described.
  • relay A Prior to the dialing of the second or units digit. relay A is operated while relays PI, P2 and P3 are normal. Upon the first interruption of the line loop for the series of pulses of the second or units digit, relay A'will release followed by the operation of relays PI and C as previously described, while a circuit is now completed for relay CI which extends from battery, resistance RS, the winding of said relay, No. 4 normally made'continuity contacts thereof, conductor 25, No. 1 back contacts of relay RT, conductor 26, No. 4 contacts of relay T2, N0. 1 contacts of relay SW to ground on the No. 1 front contacts of re lay C.
  • Relay Ci operates in this circuit and looks over its No. 4 front contacts, No. contacts of relay HS to ground on conductor 20.
  • relay CX which extends from battery, resistance CR, through the winding of said relay, No. 3 normally made continuity contacts of said relay, No. 5 contacts of relay CI, to ground on the No. 5 contacts of relay B.
  • Relay CX operates and locks to operating ground over its No. 3 front contacts and, at its No. 1 contacts, opens the circuit of relay LS! causing it to release and, in turn, release relay LCI which disconnects the translator and alternating current receiver from the link, thus causing them to be available for service with other links.
  • a circuit is also closed for relay I which extends from battery through its upper winding and No. 5 normally made continuity contacts, No. 1 contacts of relay III, No. 3 back contacts of relay II, No. 4 back contacts of relay V, No. 3 back contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, No. 5 front contacts of relay T2, N0. 2 front contacts of relay PI and thence as traced to ground on the No. 1 front contacts of relay C.
  • Relay I operates and looks with both of its windings in series through its No. 5 operated contacts, serially through the No. 4 continuity contacts of relay II, No. 5 continuity contacts of relay III, No. 4 continuity contacts of relay IV, No. 6 continuity contacts of relay V, conductor 28, No. 5 contacts of relay HS to ground on conductor 28.
  • relay A reoperates and relay P2 is operated serially with relay Pl.
  • relay A releases and, in consequence, relay P3 operates in series with relay P2 while relay Pl releases as previously described.
  • a circuit is now completed for relay II extending from battery through its upper winding, No. 4 contacts of relay I, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay PI -to ground as previously traced to the No. 2 front contacts of relay C.
  • Relay II operates and then locks serially through both of its windings and No. 4 front contacts to a previously traced ground through the continuity contacts of relays III, IV and V. On the break of its own No. 4 continuity contacts, relay II releases relay I which thereby restores to normal.
  • relay A At the termination of the second Pulse, relay A reoperates and relays P2 and P3 release as previously described.
  • relay Pl reoperates and a circuit is completed for relay III which extends from battery through its upper winding, No. 3 front contacts of relay II, No. 4 contacts of relay V, No. 3 contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, N0. 5 front contacts of relay T2, N0. 2 front contacts of relay Pl conductor 23 to ground as previously traced.
  • Relay III operates on its upper winding, locks serially with its lower winding and No. 5 front contacts to a previously traced ground through the N0. 4 and No. 5 continuity contacts of relays IV and V, respectively, while, upon the break of its own No. 5 continuity contacts, it releases relay II which thereby restores to normal.
  • relay Pl On the fourth pulse, relay Pl will be in a nonoperated position and, therefore, a circuit will be closed for relay IV which extends from battery through its upper winding, No. 4 contacts of relay III, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay Pl to ground as previously traced.
  • Relay IV operates on its upper winding and then locks serially with pan its lower winding and No. 4 front contacts, through the No. 5 continuity contacts of relay V to ground as previously traced.
  • relay III Upon the break of its No. 4 continuity contacts, relay III releases and restores to normal.
  • relay Pl On the fifth pulse, relay Pl will be operated and a circuit will be closed for relay V which extends from battery through its upper winding, No. 3 front contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, No. 5 front contacts of relay T2, N0. 2 front contacts of relay Pl to ground.
  • Relay V operates on its upper winding and locks serially with its lower winding through the No. 3 contacts of relay I, its own No. 5 front contacts to ground as previously traced to the No. 1 front contacts of relay C. When it breaks its own No. 5 continuity contacts it releases relay IV which thereby restores to normal.
  • relay Pl On the sixth pulse, relay Pl will be in a nonoperated position whereupon a circuit will be completed for relay VI which extends from battery through its upper Winding and No. 5 continuity contacts, No. 1 contacts of relay V, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay Pl to ground.
  • Relay VI operates on its upper winding and locks serially through its lower winding and No. 5 front contacts to ground as previously traced on conductor 28.
  • Relay V however, will remain locked since its own locking circuit is independent of the operated condition of relay VI.
  • relay Pl On the seventh pulse, relay Pl will be in an operated position whereupon the previously traced circuit for relay I will be established and relay I will operate in said circuit, locking thereafter serially through its lower winding and No. 5 contacts and through the previously identified contacts of relays II, III and IV, the No. 7 contacts of relay VI to ground on conductor 28. Relay V is released upon the operation of relay I.
  • relay PI On the eighth pulse, relay PI will be unoperated and a previously traced circuit for relay II will be established, which relay, upon operating, locks serially through its lower winding and No. 4 front contacts, serially through the previously designated continuity contacts of relays III, IV and V to ground on conductor 28.
  • the locking circuit of relay I is opened at the No. 4 continuity contacts of relay II and relay I thereby restores to normal.
  • Relay VI remains locked to ground on conductor 28.
  • relay PI On the ninth pulse, relay PI will be operated and a previously traced circuit for relay III is established causing said relay to operate on its upper winding and then look serially through its lower winding and No. 5 contacts, No. 4 continuity contacts of relay IV, No. 5 contacts of relay V to ground on conductor 28.
  • relay II restores. Relay VI remains locked to ground on conductor 28.
  • relay Pl On the last or zero pulse (which will not be dialed by the subscriber since it has been assumed that the units digit will be the digit 9) relay Pl will be normal and a previously traced circuit will be established for relay IV which will operate thereover on its upper winding and then look serially through its lower winding and No. 4 continuity contacts, No. 5 continuity contacts of relay V, to ground on conductor 28. Relay VI is still locked to ground on conductor 28.
  • relay C At the end of the last pulse of the second digit with relay A reoperated, relay C will release and a circuit is then closed for relay DC which extends from battery through its lower winding and No. continuitycontacts, No. 2 contacts of relay C l, No. 1 back contacts of relay C to ground on conductor 2!.
  • Relay DC operates on its lower winding and locks in series with its upper winding and No. 5 front contacts to ground as previously traced on conductor 28.
  • Relay DC upon operating, completes a path for relay SW extending from battery through its upper and lower windings, No. 2 front contacts of relay DC to ground on conductor 28.
  • Relay DC also connects battery through the lower Winding of relay BY to a conductor which extends to an armature of the hold magnet of the vertical associated with the called line which, in this case, is hold magnet Ihis path is traced as follows: Battery through the lower winding of relay BY, No. 4 ccntinuitycontacts of said relay, No. 1 front contacts of relay Cl, No. 4 contacts of relay DC, No. 1 front contacts of relay T3, conductor 35, No. 4 front contacts of relay VI, conductor 3
  • the object of this circuit is to test for the idle or busy condition of the line. Should the line be busy, hold magnet H039 will be operated, whereupon it will apply ground to conductor 33through its lower front contacts and cause thereby the operation of relay BY which then looks through its No. 4 front contacts serially through its upper winding, No. 5 contacts of relay HS to ground on conductor 2t).
  • Relay BY applies ground through its No. 1 contacts to conductor 34 extending to the power, tone and alarm circuit Ilil whereby circuits are closed therein to apply 'a busy tone source to conductor 35. This conductor extends over the No. 2 contacts of relay BY, to one side of condenser Ctthrough which the tone current passes overthe N0.
  • relay LKI of the link in the call allotter, which circuit extends from battery through the winding of said relay, conductor 36, No. 3 contacts of relay BY, No. 3 contacts of relay SW, No. 3 contacts of relay Cl, conductor 31 to ground on the No, 11 con- Relay LKI operates, completes a circuit for relay Bl in the call allotter, which circuit extends from battery through the winding of relay Bl, conductor 38, No. 5 contacts of relay LKI, conductor 39, No. 2 contacts of relay Cl, No.
  • Relay LKI also completes a circuit for relay E of the call allotter which traces from battery through its winding, conductor 9, No.
  • Relay E now operates relays El, E2 and MS as previously described and, when the latter relay operates, a circuit is completed for select magnet 8 which extends from battery through the winding of said magnet, conductor to, No. 6
  • relay LKl contacts of relay LKl, conductor M, No. 1 contacts ofrelay Bl, conductor H, No. 3 contacts of relay MS, conductor H3, to ground on the No. 3 contacts of relay LKl.
  • Select magnet 8 operates and pre-selects the horizontal cross-. points controlled by it and completes a circuit from ground through the contacts of said magnet, conductor l8, windings of S and SI relays in parallel to battery, causing said relays to operate.
  • the operation of relay S connects ground through its No. 2 contacts, conductor 42, the No. 4 contacts of relay LKI, conductor 43 to the common terminal of resistance RS and the Winding of relay Cl causing the release of the latter.
  • relay RTR When the call is answered, relay RTR will operate and lock over its upper winding and No. 2 contacts to ground on the No. 4 front contacts of relay SP, and further completes a circuit for relay HS which extends from battery through its winding, conductor 5
  • Relay HS operates and, by opening its No. 5 contacts, disconnects the ground which holds relays SW, T2, T3, DC and the register relays III and VI.
  • relay T2 releases relay SP which, in turn, releases relay RTR, the former relay connecting the supervisory relay E to the called line.
  • the circuit of relay E is as follows: Battery through its lower winding, conductor 53, No. 7 back contacts of relay LCI, conductor 5 No. 3 back contacts of relay SP, conductor 18 thence as previously traced over the called loop back to conductor No. 2 back contacts of relay SP, conductor 55, No. 8 back contacts of relay LCI, conductor 56, upper winding of relay E to ground.
  • Relay E operates and connects ground on its No. 1
  • relay HS applies ground to conductor S which, through contact 4 of crosspoint 2, extends to the winding of the cut-off relay C039 of line B to hold said relay in an operated condition.
  • Relay HS also establishes a circuit from ground on conductor 26 over its No. 4 contacts, the No. 2 contacts of relay CX to battery through the No. 2 normal contacts and winding of relay CON to battery, whereupon relay CON operates and locks over its No. 2 contacts and the No. back contacts of relay CI to ground on conductor 20.
  • relay A of the link releases and disconnects ground on conductor S! from conductor 5! but relay HS holds, as said before, to ground on conductor 52.
  • Relay A also disconnects ground from conductor 5? which holds the cut-off relay C020 operated. thereby causing this relay to release, in turn releasing hold magnet H020 and opening crosspoint I.
  • the calling line A is now disconnected from the link.
  • the release of relay A merely removes one of the grounds which holds relay HS operated, but the latter, holding to ground on conductor 52 applied thereto by relay E which holds over the called loop, prevents the link from being disconnected from the called line.
  • relay E releases, disconnects ground from conductor 52 and thereby causes the release ,of relay HS.
  • the release of relay HS closes a circuit extending from ground on conductor 20, No. 5 back contacts of relay Cl, No. 1 contacts of relay CON, No. 6 contacts of relay HS, to the common terminal of resistance CR and the winding of relay CX, causin the latter to release.
  • the release of relay CX causes ground to be applied from conductor 20, No. 1 contacts of relay OK to conductor 58, thereby causing the reoperation of relay LSl and the reconnection of the translator and alternating current receiver to the link.
  • relay TiZ When the first digit is dialed, relay TiZ will operate as described, in turn operating relay SP over a circuit that traces from battery through the winding of said relay, No. 5 contacts of relay BY, No. 2 front contacts of relay T2 to ground on conductor S2 via the No. 3 contacts of crosspoint 2.
  • Relay SP in operating, reconnects the ringing circuit to the first called station and causes thereby the operation of the ringer thereat.
  • Relay HS operates as before described, releasing relay BY and all the register relays. It is to be noted that, on a conference connection of the type described, the stations connected to the terminating end, that is, station B, and the second called station, cannot release until all called stations disconnect since relay HS, which can be operated from any station, will hold to the cut-off relay of any one of the called stations.
  • relay GR in its unoperated condition, normally applies ground to the unoperated No. 2 and No. 5 contacts of relay ON which, when operated, connects these contacts to conductors l3 and 14 which further extend to the ring RI and tip Tl conductors of the calling line. to the operation of relay B while relay ON operates following reIayAS T.
  • relay ON operates following reIayAS T.
  • the calling subscriber at station B depresses a key (not shown) of the de- Vice LG which designates the first digit of the called number, thereby plucking two of its set of five reeds.
  • the reeds are set into vibration and produce two alternating currents of specific frequencies which are now transmitted over a circuit which may be traced as previously to conductors I3 and 14 at the Nos. 2 and 5 contacts, respectively, of relay ON and, thereafter, to conductors H and 12, respectively, connecting with the secondary winding of transformer 68-. These frequencies are induced into the circuit comprising the primary winding of said transformer and the high-pass filter 64.
  • the receiver circuit in Fig. 9 is a conventional disclosure of the receiver shown in Patent 2,269,022 issued to G. Hecht and A. A. Lundw strom on Jan. 6, 1942. It comprises the chan-: nel composed of transformer 68, the high-pass filter 64, the volume limiting device 65, the transformer 66, the adjustablepad 61, five detector amplifiers fA-fE with relays FA-FE respec- Relay GR operates subsequent tively in each of the anode circuits thereof and a suitable filter intermediate the pad 61 and each one of the detector amplifiers, each of said filters being designed to pass only the frequency intended for the particular channel.
  • Each detector amplifier tube is preceded by a filter which passes only the frequency to which that tube is assigned to respond. It is assumed that the device LG is capable of producing five different frequencies which, for convenience, may be designated AE inclusive and that, in accordance with the operation of the receiver as described in the above-mentioned copending application, frequency A will cause the operation of tube fA, frequency B will cause the operation of tube f3 and so on to frequency E which will cause the operation of tube fE. 1
  • each detector amplifier tube has-a relay connected to the anode terminal thereof, and a front contact of thisrelay is further connected to the winding of one of the five relays TA-TE in the translator circuit shown in Fig. 8.
  • Relay FA in the anode circuit of the first channel which responds to frequency A has its front contact connected to the winding of relay TA, while relay FIB of the second channel, responding to frequency B, is connected to the winding of relay TB and so on up to and including relay FE in the anode circuit of the fifth channel which responds to frequency E, the front contact of which relay is connected to relay TE.
  • the subscriber keys the first digit, which may be a 2 or a 3 but which, in the assumed illustration, will be a 2, frequencies B and D are generated and these frequencies are transmitted over a previously described loop including a winding of transformer 68 whence they pass through high-pass filter 54 from the output of which the energy thereof divides, part of it passing through transformer H2 to operate the enabler 80 and part of it passing through the volume limiter 65, transformer 66, resistance pad 61, the filters preceding the tubes 1B and ID to operate said tubes. Since the operation of the receiver has been amply described in the abovementioned patent to G. Hecht and A. A.
  • relay TL having operated over a circuit which may be traced from battery, the No. 2 contacts of relay TLT, upper winding of relay TL, No. 3 contacts of relay TLT, No. 3 contacts of relays TE and TD, No. 3 contacts of relays TB and TC, N0. 3 contacts of relay TA, No. 1 contacts of relays BKI, BK3 and KBD, conductor 16 and ground previously traced thereto.
  • Relay TL also has a circuit through its lower winding which traces from ground on the No. 6 contacts of relay ON, No. 4 contacts of relay TLT, lower winding of relay TL, No. 1 contacts of relay TLT to resistance battery.
  • relay TLT the current flowing through the upper winding of relay TLT is in a direction to cause the armature to engage the contact, while that through the lower winding is in a direction to do the opposite.
  • the strength of the current through the lower winding is not sufiicient by itself to overcome the eifect of the current flowing through the upper winding so that, when both windings are energized, the armature will engage its contact and provide locking ground for relays TB and TD as above described.
  • Relay T2 operates and then locks as previously described to register the first digit 2.
  • relays TD and TE would have been operated in consequence of the operation of channel relays FD and FE in which event, in addition to closing a circuit for relay T2, a circuit will also be closed for relay T3 and this circuit may be traced from ground on conductor '16, No. 1 contacts of relays KBD, BK3 and BKI, No. 3 contacts of relay TA, No. 3 contacts of relay TC, No. 3 contacts of relay TB, No. 4 contacts of relay TD, No. 6 contacts of relay TE, N0. 1 contacts of relay TD, No. 2 contacts of relay TE, conductor 86, No.
  • Relay T3 operates and then looks as previously described to register the digit 3.
  • a circuit is completed for relay RA.
  • the ground on conductor 15 may be traced to the common conductor joining the No. 6 and No. 9 contacts of relay TE. These paths are through a network of contacts which extends over the contacts of relays TATE in order to insure that exactly two of these relays are operated before grounding any of the link registers. From the common terminal of this network at the Nos. 6 and 9 contacts of relay TE, the circuit for relay RA may further be traced through either No. 1 contacts of relay TE or No.
  • Relay RA operates and, by the closure of its No. 1 front contacts, applies ground on conductor 1'6 to one terminal of the winding of the relay RAI, the other terminal being grounded over the No. l back contacts of said relay by the afore-traced ground for operating relay RA.
  • Relay RA in operating. opens the tone circuit at its No. 2 contacts thereby removing dial or key tone from the line.
  • Relay RAI in operating, closes a circuit for relay RT the path of which extends from groundon the No. 1 contacts of relay RAl, conductor 89, No. 2 contacts of relay LCI, conductor 9

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Description

Nov. 3, 1942. w. A. MALTHANER TELEPHONE ssrsma Filed Jill 25, 1941 10 Sheets-Sheet 1 v mos: POINT 4 Cm; POINT I VENT/(34L 20 8 v LINE-38 Q 9 k k a a a a mama:
a. v, v v Q5 a INVENTOR BY W. AMALTHANER Q-aLM 1942- w. A. MALTHANER 2,305,951
1 TELEPHONE SYSTEM I Filed July 26, 1941 10 Sheets- Sheet :5
INVENTOR WA MALTHA/VER A 7' TORNEY Nov. 3, 1942- w. A. MALTHANER 2,300,951
TELEPHONE SYSTEM I Filed July 26. 1941 10 Sheets-Sheet 4 INVENTOR WA .MALTHANER By 6P6. M
A T TORA/E V 1942. w. A. MALTHANEVR 2,300,951 1 v rams-moan SYSTEI Filed July 26, 1941 1O Sheets-Sheet 5 INVENTOR W. AMALTHANER A 7' TORNEV Nov. 3, 1942 w. A. MALQI'HANER ,3 951:
TELEPHONE SYS'IEII Filed July 26, 1941 10 Sh eets-Sheet 6 IN 5 N TOR 8? W14 .MALTHANER A 7' TORNE Y Nov. 3, 1942. w. A. MALTHANER TELEPHONE SYSTEM Filed July 26, 1941 10 Sheets- Sheet 7 lNl/E N TOR mAMALTHA/VER Q 6.
tokowz ou 23 6Q A T TORNEY -f 1942- w. A. MALTHANER' 2,300,951
' l TELEPHONE sYsmu 7 Filed July 26, 1941 10 Sheets-Sheet s rnmsuran cc FIG. 8
INVENTOR i WAMA'LTHANER GPQM A T TORNEV I I I I I Nov. 3, 1942. w. A. MALTHANER' 2,300,951
' TELEPHONE SYSTEM FiledJuly 26, 1941 10' Sheets-Sheet 10 ccr Illllllllll A TYTORIVEVI Patented Nov. 3, 1942 UNITED STATE iATE OFFlCE TELEPHONE SYSTEM Application July 26,1941, Serial No. 404,109
9 Claims.
This invention relates to telephone systems and particularly to small capacity telephone systems in which crossbar switches are employed. An object of the invention is to provide means whereby line stations equipped with different types of call devices may operate common apparatus with which to set up desired connections as, for instance, between a station equipped with a dial sender to transmit a series of impulses designating a called number and a station that utilizes an alternating current generating device to generate and transmit combinations of different frequencies to designate the called line number.
, Heretofore, systems have been provided for establishing connections between two subscribers lines in single crossbar units wherein all of the calling stations were equipped with dial sending devices as, for instance, the system disclosed in Patent No. 2,071,075 issued to Charles D. Koechling on February 15, 1937.
A feature of the present invention is an arrangement in a system of the above kind in which a connection may be established between two subscriberslines by means of a link which, on the one hand, is adapted to respond to dial pulses produced at an originating station equipped with a dial to set up a connection to the station indicated by the pulses and, on the other, is also adapted to respond to combinations of currents of-diilerent frequencies generated at an originating station, to set up the connection to the station indicated by such combinations of frequencies. The link is provided with suitable registers for response to either type of pulses,
the direct current register, however, being the one which, in all cases, operates the hold magnet of the called line in the crossbar switch. A translator is provided whereby, in response to the settmg of the reglster that respfinds to the albeen given a numerical designation 2!) while line ternating current pulses designating the digits of the called line, the direct current register is set for those which then controls means for operating the hold magnet of the called line.
The invention is illustrated in connection with the following drawings in which:
Figs. 1 and 2 show, diagrammatically, a crossbar switch frame of known construction having ten horizontal outlets and twenty verticals to each of which a subscribers station is connected.
The first vertical, assigned to station A, has a line number designation 2t, and the last vertical, assigned to station B, has a number designation 39, station A being provided with a dialing device LD and station B being provided with an alternating current or key pulsing generating device LG;
Fig. 3 in the left portion thereof, shows a link allotter circuit, while the rest of this figure, together with Fig. 4 show the call allotter circuit;
Figs. 5, 6, 7, 8 and 9 show the details of the link circuit;
Fig. 10 shows, in diagrammatic form, two other links and a power generating, tone and alarm circuit; while Fig. 11 shows the manner in which Figs. 1 to 10, inclusive, should be arranged with respect to each other to completely disclose the invention.
The invention will now be described in cletail by describing the operations necessary to set up two different types of connections; namely, a connection originating at station A for station 13, in which the number designation 39 of station B will be dialed at station A through the manipulation of dialing device LD thereat, and a connection originating at station B for station A in which the number designation 2%) of station A will be set up on device LG by the depression thereon of keys (not shown) corresponding to the digits of the designated station.
Before describing the detailed operation of the invention, however, it is desirable to call attention to the fact that the illustrative embodiment of the invention is being shown in connection with a small office having a maximum capacity of twenty lines, each station of which is equipped with either a dial ID or a generator LG for transmitting called line designations. Each line appears on one of the twenty verticals of the crossbar switch, conventionally shown in Figs. 1 and 2, and each, for simplicity, has been given a numerical designation corresponding to the vertical to which it is connected. Thus line A is connected to vertical 20 and, therefore, has
B which is connected to vertical 39 has been given a numerical designation of 39, the intermediate eighteen lines (each of which is provided either with a dial LB or a generator LG) being given numerical designations corresponding to the different verticals of the frame to which they are severally connected.
The dial LD is the ordinary impulse dial well known in automatic telephony and its manipulation interrupts the line to produce a series of pulses the number of which corresponds to the digit to which the dial is pulled over to the stop attachment prior to releasing it for its return to normal in the course of which the train or series of impulses is produced. The device LD, on the other hand, is an alternating current generator which, for example, may be of the type shown in Patent No. 2,147,710 granted to R. F. Mallina on February 21, 1939. It comprises a number of reeds which may be plucked in pairs to produce vibrations within a magnetic field and thereby cause the generation of currents having frequencies determined by their several physical constants. These currents are transmitted over the link into registers therein for use in causing the link to complete the connection to the desired line.
For the quantity of internal traffic which may arise within the twenty lines of the system only three links are provided each of which occupies two horizontal outlets of the crossbar switch, link I (the circuit of which is shown'in detail in Figs. to 9, inclusive) occupying the two uppermost outlets controlled, for selective purposes, by select magnets 8 and 9; link 2 occupying the two horizontal outlets immediately below those of link I and controlled by select magnets 6 and I, while link 3 occupies the two horizontal outlets immediately below those of link 2 and controlled by select magnets 4 and 5. The remaining four outlets of the switch may, if desired, be used as outgoing trunks or links. However, since the invention is not concerned with outgoing connections, these outlets are not shown connected either to links or trunks.
Referring, now, to Fig. 3, there are shown three relays, namely, relays CHI, CH2 and CH3, which form a link allotter circuit, the first two relays being shown in an operated position while the last is shown in an unoperated position.
These three relays control the sequential allotment of an available link to a calling line and the function of the first two relays in the position shown is to route the start conductor I to the first idle link available to the ofiice. As said before, in the present embodiment of the invention it is assumed that the trafiic between the various lines of the oifice may be properly satisfied by the use of but three links so that the relays CHI, CH2 and CH3 serve to route a calling line to one of said three links depending upon which one of them is free in the order of allotment. The operated condition of relay CHI indicates that the link to which it provides access is in an idle condition, its locking circuit (that is, the locking circuit of relay CHI) extending from battery through the winding thereof, contacts of KYI, conductor 2, No. 1 contacts of relay B of link I, conductor 3, No. 3 front contacts of relay CHI to ground. The locking circuit of relay CH2 which controls access to the second link is traced over a path which extends from battery through its winding, key KY2, conductor 2 in the bracket line 4, through the No. 1 back contacts of relay B in link No. 2 (diagrammatically indicated in Fig. conductor '3 in the bracket line 4, No. 5 contacts of relay CH2 to ground.
On the other hand, the operating circuit of relay CH3 which provides access to link No. 3, while traceable over its associated key KY3, conductor 2" within bracket line 5, through the No. 1 contact of relay B in link 3 (diagrammatically shown in Fig. 10) and conductor 3" within bracket line 5, terminates in the No. 3 normal contacts of relay CH3 and also in the No. 3 open contacts of relay CHI.
In other words, a calling line, to have accessibility to link I, relays CHI and CH2 must be operated while relay CH3 must be normal.
It will be shown that as each link is allotted in rotation, the circuits of relays CHI, CH2 and CH3 are changed to provide for the advance of start conductor I from one link to the next in the order named.
Bearing in mind the condition of relays CHI, CH2 and CH3 of the allotter circuit as described above, it may now be assumed that a call is originated at station A for station E by the removal, at the former station, of the telephone instrument from its cradle, whereupon a circuit is completed for relay L29 of said line which extends from battery over the upper normal contacts of the hold magnet HOZii associated with vertical 29, winding of relay L20, ring conductor R, over the station loop, tip conductor T, No. 1 normally made contacts of relay L28 to ground on the No. 1 contacts of cut-ofi relay C026. Relay L29 operates. Over its No. 1 contacts, the ground terminal of its circuit is switched from solid ground on the No. 1 contacts of relay CO to ground through the secondary Winding of transformer LBT to the primary of which a source of distinctive tone is connected for transmission to the calling line in the event that no link is available for completing the connection, as will be described shortly.
Over its No. 2 and No. 3 contacts, relay L20 causes a circuit to be completed for relay LI of the call allotter circuit (there being one LI relay for each line) and relay ST of link I which, since relays CHI and CH2 of the allotter are assumed to be locked and relay CH3 is assumed to be normal, is the preferred link in the order of selection. The circuit for the relays ST and LI is traced as follows: Ground through the No. 1 contacts of relay EI, winding of relay LI, conductor 6, No. 2 and No. 3 contacts of relay L20, start conductor I, No. 3 contacts of relay CH2, No. 1 contacts of relay CHI, conductor 1, winding of relay ST to battery. Both relays LI and ST operate in this circuit. Relay LI, upon operating, opens the locking circuit of all other nineteen LI relays at its No. 4 contacts and completes a circuit for relay N, which circuit may be traced from ground on the No. 1 contacts of relay LI, conductor Ill, No. 1 back contacts of relay M, No. 4 contacts of relay MS, winding of relay N to ground. Relay N operates and completes a circuit for relay M from ground on its No. 2 contacts, No. 1 back contacts of relay MS, winding of relay M to battery. Relay M operates and opens the circuit of relay N at its No. 1 back contact causing it to release while the release of relay N opens the circuit of relay M which, however, remains locked under the control of the No. 1 contacts of relay MS and its own No. 2 contacts to ground on conductor IE1. When relay MS operates as described below, relay M releases. This cycle for operating relays M and N ordinarily performs no useful function but will perform an emergency function that will be explained in its proper sequence. At the same time, relay LI completes another circuit for relay E which may be traced from ground on the No. 1 contacts of relay EI, No. 2 contacts of relay L, conductor 3, serially through the No. 1 back contacts of the individual link relays LKS, LKZ and LKI, conductor 9, winding of relay E to battery. Relay E upon operating, locks to ground on the No. 1 contacts of relay LI and at the same time closes a circuit for relays EI and E2 from ground on its contacts, No. 2 normally made contacts of relay MS to the windings of relays EI and E2 to the other respective terminals of which battery is connected. Relays EI and E2 operate but relay LI, which operated from ground on the No. 1 contacts of relay El, now holds locked on battery through relay SI of the selected link as previously traced to conductor B, winding of relay LI and its No. 2 contacts, conductor 8 as traced to conductor 9, contacts of relay E to ground on the No. 1 contacts of relay LI. Hence with the operation and looking of relay LI individual to station A, and with the operation of relays EI and E2, all other lines may not receive service if calls are initiated thereat while station A is in the process of having a link assigned since, with relays El and E2 operated, no ground is available for completing the circuit of the relays LI of the respective calling lines.
When relay EI operates, it completes a circuit for relay MS, said circuit tracing from ground on conductor It, No. 14 contacts of relay EI, winding of relay MS to battery. Relay MS operates after an interval, opens the path of relay N, supplies holding ground over its No. 2 contacts for relays El and E2 and applies ground on conductor It! to conductor II over its No. 3 contacts. Ground on conductor II is used to complete the circuit of the link select magnet 9 in virtue of operations which have been taking place in the link as a result of the operation of relay ST therein and which will shortly be described.
In the event that, due to some trouble condition, relay E of the call allotter fails to operate, relay MS cannot operate and ground will not be applied to conductor I I over its No. 3 contacts. Under these circumstances it is desirable to complete the connection if possible and so emergency means are provided for applying ground to conductor I! in the event that relay MS fails to operate. It will be remembered that upon the operation of relay LI a circuit was completed for relay N, and that prior to the operation of relay MS/relay N caused the operation of relay M. Now, when relay lVl" operates, it opens the circuit of relay N but relay M remains looked over its No. 2 contacts to ground on conductor Ill, and it will be observed that, with relay N normal and relay M operated, ground on conductor I0 is applied to conductor I 1 via the No. 1 front contacts of relay M and No. 1 contacts of relay N.
Returning, now, to the operation of relay ST, a circuit is completed for select magnet 9, which circuit traces from battery through the winding of said magnet, conductor H, No. 2 contacts of relay B, N o. 4 contacts of relay ST, conductor I I, to the aforetraced ground thereon. Select magnet operates and preselects the group of cross,- points on its horizontal level, including crosspoint I through which the calling loop is extended into the link as shown hereinafter. Magnet 9, upon operating, completes a circuit from ground, over its contacts and common conductor I3 to the windings of relays S and Si in parallel causing said relays to operate and complete a circuit for cut-oif relay C029, said circuit tracing from ground on the No. 3 contacts of said relays, No. 3 contacts of relay Ll, conductor I9, winding of relay C025 to battery. Relay COZil upon operating, closes an obvious circuit for hold magnet HOZiI of the Vertical 29 to which line A is conwhich links I and 2- are unava' nected and, in so doing, operates crosspoint I. This crosspoint remains operated after the circuit of select magnet 9 has been opened, is standard crossbar switch operation and need not be amplified any further. When hold magnet H028 which may be traced operates, it releases line relay L20 in turn releasing relay LI and those relays controlled thereby. Relay L20 further disconnects ground from start conductor I which caused the operation of relay ST. However, since crosspoint I is closed, this relay will not release, having a locking circuit through a crosspoint contact, which may be traced over the No. 2 contacts of said relay, No. 1 contacts of relay T2, conductor SI, No. 3 contacts of crosspoint I, to ground.
Since line crosspoint I is operated, the line tip and ring conductors T and R are joined to the link tip and ring conductors LT and LR, respectively, over the No. 6 and No.5 contacts of the operated crosspoint I, respectively, and this connection completes an operating path for relay .A from battery through its lower Winding, No. 2 back contacts of relay HS, conductor LT, contact 6 of crosspoint I, line conductor T, over the loop, ring conductor contact 5 of crosspcint I, conductor LR of the link, No. 3 back contact of relay HS, upper winding of relay A, to ground. Relay A, u on operating, completes a circuit for relay B, which circuit extends from ground on conductor SI, front con: tacts of relay A, No. 4 normally made contacts of relay B, winding of relay B to battery, causing said relay to operate and lock over its No. 4 front contacts to ground on conductor Si. Rela B, at its No. 2 contacts, opens conductor ll thereby causing the release of the select magnet s. Since however, the hold magnet H023 is operated, crosspoint I remains operated. Relay ]3 further completes a circuit from ground over itsNo. 3
contacts to a relay (not shown) in the power charge circuit Hill to operate circuits thereby that will increase the charging rate to the link power supply while the link is being used and, over its No. 5 and N0. 6 contacts, connects ground to holding conductors 20 and 2! for holding andopcrating certain other relays as described hereinafter. Over its No, 1 contacts it opens the looking circuit of relay CHI in the ailotter circuit which, upon releasing, advances the common start conductor I over the Nlo. 3 contacts of relay CH2, No. 2 contacts of relay CHE. No. 1 contacts of relay CH2 to conductor 1' which further ex} tends to relay ST of link 2.
It is now evident that if. at the time the call was initiated at station A, link I was busy or was otherwise unavailable, its relay CHI in the link allotter circuit would have been normal, and the start wire I, with ground applied thereto, would have been connected to conductor 7' of link 2 to cause the operation therein of relay ST in the same manner as that of relay ST in link I as already described. On the other hand. if both links I and 2 were busy or otherwise unavailable, relay CH2 as well as relay CH! would have normal since their respective locking circuits would be opened at the No.1 contacts of relay B of their respective links. However. as soon these relays are both normal. a circuit is completed for relay CH3 which extends from battery through its winding. conductor 2". No. 1 contacts of relay B of link 3, conductor 3%". to over the No. 1 normally mad contacts of relay CHI. RelayCHil operates and, with relays CH6 and CH2 normal, represents the condition in do but link 3 is available. Now if a call is l tied at a line station for instance, station A, ground on start conductor I is extended conductor l" which is connected to the winding of relay SI of link 3, the path being from ground on conductor I, No. 4 contacts of relay CH2, No. 2 contacts of relay CH3, conductor 7', to the winding of relay ST of said link causing its operation and the connection of the link to the calling line.
If all three links are unavailable, relay CH3 will be normal along with relays CHI and CH2. The initiation of a call under these circumstances will cause ground on the start conductor I to be applied to conductor 22 via the No. 4 contacts of relay CH2, No. 1 contacts of relay CH3, No. 2 contacts of relay CHI, No.'2 contacts of relay CH2, to conductor 22. This conductor extends (through bracket line I3) to the power, tone and alarm circuit lit] and closes a circuit therein which causes a distinct link busy tone to be applied to the conductors 23 and 2% connecting with the primary winding of busy tone transformer LBT. Since the secondary winding of this transformer is connected to ground and is completed into a circuit over the line loop to battery on the upper normally made contacts of the hold magnet HO- through the winding of relay L-, the subscriber at the calling station will hear the tone as an indication that, due to unavailable links, the connection cannot be established.
As soon as a link becomes available, say link I, then a circuit is completed for relay CHI which extends from battery through its winding, thence as traced to conductor 3, No. 5 contacts of relay CH2 to ground. Relay CHI operates and locks to ground over its No. 3 contacts to reestablish the path of start conductor I'to the winding of relay ST in readiness for seizure on the next call. If link 2 becomes available, relay CH2 operates over a circuit traceable from battery through its winding, thence as traced to conductor 3' to ground on the No. 3 normally made contacts of relay CH3.
Returning, now, to the operation of relay ST of link I assumed to have been taken into use, ground on the No. 3 contacts of said relay completes a circuit for relay LSI of its private link connector and this circuit is traced from ground on said contacts, conductor 58, winding of relay LSI. serially through the No. 2 normally made continuity contacts of relays LS2 and LS3 (the former being individual to link 2 and the latter individual to link 3) to battery. Relay LSI operates. connects operatingbattery to its winding through its own No. 2 front contacts and, over its No. 1 front contacts, completes an obvious circuit for cut-in relay LCI which operates as a result thereof.
The object of operating relays LSI and LCI is to connect the common alternating current pulse receiver and translator shown in Figs. 8 and 9 to the link taken into use, and when this circuit is s connected. the si nal for which is the operation o relay LSI, said receiver must be made unava lable to other l nks. This is done by removin the ope a in round for relays LC2 and 03 at the No. 1 back contacts of relay LSI so that, if either relay LS2 or LS3 should have its operatin circuit establ shed by relay ST of its respective link. the circuit of relay LC2 or LC3 is cut off at the No. 1 back contacts of relay LS5. On the other hand. if the first calling link happens to be li k. 2 or 3. then. he corresponding operation of relays LS2 or LS3 will ut off the operating circuit of relay LSI at their respective No. 2 normal- 1v made continuity contacts so that if link I is seized in the meanwhile. the failure of relay LSI to operate will prevent the operation of relay LCI and thereby prevent the simultaneous connection of the common alternating current receiver and translator to two calling links. The alternating current receiver of Fig. 9 is adapted to receive alternating current impulses from a calling station equipped with an alternating current generating device such as, for example, the device LG at station B. At the time a call is initiated, however, the seized link has no knowledge of which type of station is making the call. Hence it must be prepared, at first, to receive either direct current pulses from a dial ID or alternating current pulses from a generating device LG. Since the link itself is normally arranged with a register to receive direct current pulses, as will be shown shortly, the alternating current receiver common to all links must be connected to a calling link before the calling subscriber can be advised, by an appropriate warning tone, to transmit the called line designation. Accordingly, when relay LCI operates, a circuit is completed for relay GR which extends from ground on conductor M, No. 1 back contacts of relay C, conductor 75, No. 4 contacts of relay LC I, conductor I8, winding of relay GR to battery. Relay GR operates and disconnects ground from conductors II and 12 which, as will be shown, are connected to the calling loop through the operation of relay ON. A circuit is also completed for relay ON which is traced from ground on the N0. 5 contacts of relay LCI, conductor 69, winding of relay ON to battery. Relay ON operates and, over its No. 1 contacts, closes through a low frequency tone circuit derived from the tone oscillator It through adjustable resistance pad 62 and transformer 6|. The path is traced as follows: From the lower terminal of the secondary winding of transformer 6|, conductor I l, No. l contacts of relay ST, conductor I5, No. 6 contacts of relay LCI, conductor I5, No. 3 contacts of relay RR, No. 2 contacts of relay RA, No. 1 contacts of relay ON, conductor I2, through the low-pass filter 63 to the upper terminal of the secondary winding of transformer 6|. The tone frequencies produced by the oscillator 'Iil are thus induced over the secondary circuit above traced.
Through a transformer arrangement in the low-pass filter E3, the low frequencies are induced in the closed circuit comprising the transformer 68, a transformer in said low-pass filter and a transformer in high-pass filter fi l. Beyond the secondary winding of the transformer in the filter 64 are connected suitable filter networks which are designed to pass only frequencies Within the signal frequency band of the frequencies that are produced by the. station generator LG when operated. Hence the tone frequencies produced by oscillator it will not pass into the volume limiter or into the enabler 89. They will, however, be induced into the secondary winding of transformer 53 if said secondary winding is closed into an electrical system, which it is because conductors II and I2 are but extensions of the line conductors T and R into the link and alternating current receiver connected thereto. The path is traced as follows: From the left side of the secondary winding of transformer 63, conductor H, No. 2 contacts of relay ON, conductor 53, No. 7 front contacts of relay LCI, conductor 54, condenser C2, No. 2 back contacts of relay HS, conductor LT, No. 6 contacts of crosspoint I, conductor T, over the loop of station A, conductor R, No. 5 contacts of crosspoint I, conductor LR, No. 3 back contacts of relay HS, condenser C3, conductor 55, No. 8 front contacts of LCI, conductor I4, No. 5 contacts of relay ON, conductor 72 to the right terminal of the secondary winding of transformer 68. Inasmuch as the receiver of the telephone instrument of station A is included in the above closed circuit, the tone induced thereover is heard by the subscriber, which he understands as a signal to proceed with dialing the number of the wanted subscriber.
The subscriber, upon receiving a tone, operates the dial ID to transmit the called line designation. In the present embodiment of the invention, it is assumed, as said before, that the capacity of the ofiice is twenty lines and that the number of designations of said line extends from twenty to thirty-nine, inclusive, it being further assumed that station A has a designation of 29 and that station B has a designation of 39. The calling subscriber, therefore, dials a wanted designation by dialing two digits, the first of which may be a 2 or a 3 and the second of which may be any digit from to 9. Since the connection is to be established between the calling line A and called line B, the subscriber at A will first manipulate his dial to transmit three pulses for the tens digit and, thereafter, nine pulses for the units digit.
As is well known, the operation of the dial LD makes and breaks the calling line loop as many times as required to produce the pulses required for the digit. Hence upon dialing the digit three, three pulses are produced that will cause three successive releases of relay A. When relay A releases on the first pulse, it completes a circuit for relay Pl which extends from ground on conductor Sl, the back contacts of relay A, No. 3 contacts of relay B, No. 2 contacts of relay E, back contacts of relay P2, No. 2 back contacts of relay P3, winding of relay Pl to battery. Through the No. 1 back contacts of relay P3, a branch circuit further extends to the winding of slowrelease relay C. Both relays P! and C operate and short-circuit the lower winding of relay P2, ground to one side of this winding being supplied over the No. 2 contacts of relay C while ground on the other side of the winding is supplied over the No. 1 contacts of relay P1 to the back confacts of relay A. With the operation of relay Pl a circuit is completed for relay SW which extends from battery through its upper winding and No. 2 normally made contacts, No. 5 back contacts of relay T2, No. 2 front contacts of relay Pi, conductor 23, No. 5 contacts of relay RT, conductor M, No. 1 front contacts of relay C to ground on conductor 25. Relay SW operates and locks over its No. 2 front contacts to ground on the No. 1 front contacts ofrelay C. When relay A operates at the termination of the first pulse, the short circuit around the lower winding of relay P2 is removed and said relay operates in series with relay Pi over a circuit path which traces from ground on the No. 2 contacts of relay C, lower winding of relay P2, No. 1 contacts of relay Pl, No. 2 contacts of relayPZi, winding of relay P1 to battery. Hence after the first pulse is terminated, relays Pl, P2 and SW are operated, the latter being looked, as said before, to ground on conductor 2! through the No. 1 contacts of relay 0 which, being slow releasing, remains in an operated position between pulses.
On the beginning of the second pulse, relay A releases again and completes a circuit path for relay P3 which extends from ground on its back contacts, No. 3 contacts of relay B, No. 2contacts of relay E, front contacts and upper winding of relay P2, winding of relay P3 to battery.
Relay P3 operates and releases relay Pi after which a, circuit is completed for relay T2 which extends from battery through the upper winding of relay T2 and its No. 3 normally made contacts, No. 4 front contacts of relay SW, No. 2 back contacts of relay Pl, conductor 23, and thence as previously traced to ground on the No. 1 front contacts of relay C. Relay T2 operates, locks through both of its windings in series through its No. 3 front contacts, No. 5 contacts of relay HS, conductor 29 to groundon the No. 5 contacts of relay B and opens the locking circuit of relay ST which releases but its release results in no other function at this time.
At the termination of second pulse relay A reoperates and relays P2 and P3 release. Hence at the termination of the second pulse, the pulsing relays Pi, P2 and P3 are normal, relay C is in an operated position due to its slow-releasing characteristics, while relays SW and T2 are locked.
At the beginning of the third pulse, the release of relay A again causes the operation of relay Piahd the short-circuiting of relay P2 but, in this case, a circuit is completed for relay T3 which extends from-battery through its upper winding and No. 2 normally made continuity contacts, No. 1 contacts of relay DC, No. 5 front contacts of relay SW, N0. 5 front contacts of relay T2, N0. 2 front contacts of relay PI and thence as already traced to ground on the No. 1 front contacts of relay C. Relay T3 operates and, through its No. 2 front contacts, locks serially on both windings, to previously traced ground on the No. 5 contacts of relay B. At the end of the pulse relay A reoperates and relay P2 operates in series with relay Pl as previously described. However, since this is the third and last pulse of the tens digit, there will be a relatively long interval before the transmission of the first pulse of the units digit, which interval is sufiicient to cause the release of relay C followed by the release of relay SW and the release of relays PI and P2 the latter two holding to ground over the No. 2 contacts of relay 0.
It will beobserved that the dialing of the numeral 3 as the tens digit of the called number has resulted in the operation and locking of relays T2 and T3. If the tens digit numeral had been a 2 instead of a 3, the result would have been the operation and locking of only relay T2. N0 provision has been made in the link for registering any digit other than a 2 or a 3 as a tens digit since the capacity of the omce is assumed to be limited to twenty lines, each having a numerical designation from 20 to 39. However, it is evident that if any other numerical designations were to be used, or if the capacity of the office were to be increased to include more than twenty lines, the link circuit could easily be changed by any one skilled in the art to register therein any other digit for the tens digit.
Prior to the dialing of the second or units digit. relay A is operated while relays PI, P2 and P3 are normal. Upon the first interruption of the line loop for the series of pulses of the second or units digit, relay A'will release followed by the operation of relays PI and C as previously described, while a circuit is now completed for relay CI which extends from battery, resistance RS, the winding of said relay, No. 4 normally made'continuity contacts thereof, conductor 25, No. 1 back contacts of relay RT, conductor 26, No. 4 contacts of relay T2, N0. 1 contacts of relay SW to ground on the No. 1 front contacts of re lay C. Relay Ci operates in this circuit and looks over its No. 4 front contacts, No. contacts of relay HS to ground on conductor 20. A circuit is now completed for relay CX, which extends from battery, resistance CR, through the winding of said relay, No. 3 normally made continuity contacts of said relay, No. 5 contacts of relay CI, to ground on the No. 5 contacts of relay B. Relay CX operates and locks to operating ground over its No. 3 front contacts and, at its No. 1 contacts, opens the circuit of relay LS! causing it to release and, in turn, release relay LCI which disconnects the translator and alternating current receiver from the link, thus causing them to be available for service with other links.
A circuit is also closed for relay I which extends from battery through its upper winding and No. 5 normally made continuity contacts, No. 1 contacts of relay III, No. 3 back contacts of relay II, No. 4 back contacts of relay V, No. 3 back contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, No. 5 front contacts of relay T2, N0. 2 front contacts of relay PI and thence as traced to ground on the No. 1 front contacts of relay C. Relay I operates and looks with both of its windings in series through its No. 5 operated contacts, serially through the No. 4 continuity contacts of relay II, No. 5 continuity contacts of relay III, No. 4 continuity contacts of relay IV, No. 6 continuity contacts of relay V, conductor 28, No. 5 contacts of relay HS to ground on conductor 28. Upon the termination of the pulse, relay A reoperates and relay P2 is operated serially with relay Pl.
On the second pulse, relay A releases and, in consequence, relay P3 operates in series with relay P2 while relay Pl releases as previously described. A circuit is now completed for relay II extending from battery through its upper winding, No. 4 contacts of relay I, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay PI -to ground as previously traced to the No. 2 front contacts of relay C. Relay II operates and then locks serially through both of its windings and No. 4 front contacts to a previously traced ground through the continuity contacts of relays III, IV and V. On the break of its own No. 4 continuity contacts, relay II releases relay I which thereby restores to normal.
At the termination of the second Pulse, relay A reoperates and relays P2 and P3 release as previously described.
At the beginning of the third pulse, relay Pl reoperates and a circuit is completed for relay III which extends from battery through its upper winding, No. 3 front contacts of relay II, No. 4 contacts of relay V, No. 3 contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, N0. 5 front contacts of relay T2, N0. 2 front contacts of relay Pl conductor 23 to ground as previously traced. Relay III operates on its upper winding, locks serially with its lower winding and No. 5 front contacts to a previously traced ground through the N0. 4 and No. 5 continuity contacts of relays IV and V, respectively, while, upon the break of its own No. 5 continuity contacts, it releases relay II which thereby restores to normal. On the fourth pulse, relay Pl will be in a nonoperated position and, therefore, a circuit will be closed for relay IV which extends from battery through its upper winding, No. 4 contacts of relay III, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay Pl to ground as previously traced. Relay IV operates on its upper winding and then locks serially with pan its lower winding and No. 4 front contacts, through the No. 5 continuity contacts of relay V to ground as previously traced. Upon the break of its No. 4 continuity contacts, relay III releases and restores to normal.
On the fifth pulse, relay Pl will be operated and a circuit will be closed for relay V which extends from battery through its upper winding, No. 3 front contacts of relay IV, conductor 21, No. 5 back contacts of relay SW, No. 5 front contacts of relay T2, N0. 2 front contacts of relay Pl to ground. Relay V operates on its upper winding and locks serially with its lower winding through the No. 3 contacts of relay I, its own No. 5 front contacts to ground as previously traced to the No. 1 front contacts of relay C. When it breaks its own No. 5 continuity contacts it releases relay IV which thereby restores to normal.
On the sixth pulse, relay Pl will be in a nonoperated position whereupon a circuit will be completed for relay VI which extends from battery through its upper Winding and No. 5 continuity contacts, No. 1 contacts of relay V, conductor 29, No. 4 back contacts of relay SW, No. 2 back contacts of relay Pl to ground. Relay VI operates on its upper winding and locks serially through its lower winding and No. 5 front contacts to ground as previously traced on conductor 28. Relay V, however, will remain locked since its own locking circuit is independent of the operated condition of relay VI.
On the seventh pulse, relay Pl will be in an operated position whereupon the previously traced circuit for relay I will be established and relay I will operate in said circuit, locking thereafter serially through its lower winding and No. 5 contacts and through the previously identified contacts of relays II, III and IV, the No. 7 contacts of relay VI to ground on conductor 28. Relay V is released upon the operation of relay I.
On the eighth pulse, relay PI will be unoperated and a previously traced circuit for relay II will be established, which relay, upon operating, locks serially through its lower winding and No. 4 front contacts, serially through the previously designated continuity contacts of relays III, IV and V to ground on conductor 28. Upon the operation of relay II, the locking circuit of relay I is opened at the No. 4 continuity contacts of relay II and relay I thereby restores to normal. Relay VI remains locked to ground on conductor 28.
On the ninth pulse, relay PI will be operated and a previously traced circuit for relay III is established causing said relay to operate on its upper winding and then look serially through its lower winding and No. 5 contacts, No. 4 continuity contacts of relay IV, No. 5 contacts of relay V to ground on conductor 28. Upon the operation of relay III, relay II restores. Relay VI remains locked to ground on conductor 28.
On the last or zero pulse (which will not be dialed by the subscriber since it has been assumed that the units digit will be the digit 9) relay Pl will be normal and a previously traced circuit will be established for relay IV which will operate thereover on its upper winding and then look serially through its lower winding and No. 4 continuity contacts, No. 5 continuity contacts of relay V, to ground on conductor 28. Relay VI is still locked to ground on conductor 28.
Thus the pulses of the second digit are registered in the relays I--VI of Fig. 6, the relay or relays operated depending upon the number of pulses transmitted. The relationship between the number of pulses and the relays operated is shown in the following table:
Relay Pulses operated It has been assumed that the called subscribers number is 39 and, therefore, in respect to the units digit, relays III and VI will have been operated.
At the end of the last pulse of the second digit with relay A reoperated, relay C will release and a circuit is then closed for relay DC which extends from battery through its lower winding and No. continuitycontacts, No. 2 contacts of relay C l, No. 1 back contacts of relay C to ground on conductor 2!. Relay DC operates on its lower winding and locks in series with its upper winding and No. 5 front contacts to ground as previously traced on conductor 28. Relay DC, upon operating, completes a path for relay SW extending from battery through its upper and lower windings, No. 2 front contacts of relay DC to ground on conductor 28. Relay DC also connects battery through the lower Winding of relay BY to a conductor which extends to an armature of the hold magnet of the vertical associated with the called line which, in this case, is hold magnet Ihis path is traced as follows: Battery through the lower winding of relay BY, No. 4 ccntinuitycontacts of said relay, No. 1 front contacts of relay Cl, No. 4 contacts of relay DC, No. 1 front contacts of relay T3, conductor 35, No. 4 front contacts of relay VI, conductor 3|, No. 6 contacts of relay DC, conductor 32, No. 6 contacts of relay III, conductor 33, lower armature and contact of hold magnet H539 to the winding of relay 0939. The object of this circuit is to test for the idle or busy condition of the line. Should the line be busy, hold magnet H039 will be operated, whereupon it will apply ground to conductor 33through its lower front contacts and cause thereby the operation of relay BY which then looks through its No. 4 front contacts serially through its upper winding, No. 5 contacts of relay HS to ground on conductor 2t). Relay BY applies ground through its No. 1 contacts to conductor 34 extending to the power, tone and alarm circuit Ilil whereby circuits are closed therein to apply 'a busy tone source to conductor 35. This conductor extends over the No. 2 contacts of relay BY, to one side of condenser Ctthrough which the tone current passes overthe N0. 2 back contacts of relay HS, conductor LT over the calling loop previously traced to conductor LR, No. 3 back contacts of relay HS, upper winding of relay A to ground. The busy tone thus furnished the calling subscriber indicates to him that the line is busy, whereupon he restores the telephone instrument upon the cradle and thereby opens the circuit of relay A, the release of which initiates the restoration of the apparatus as described hereinafter.
Assuming, however, that the called line is not busy, then hold magnet H039 will be normal tacts of relay El-.
and relay BY will not operate. In this case, a. circuit is closed for relay LKI of the link in the call allotter, which circuit extends from battery through the winding of said relay, conductor 36, No. 3 contacts of relay BY, No. 3 contacts of relay SW, No. 3 contacts of relay Cl, conductor 31 to ground on the No, 11 con- Relay LKI operates, completes a circuit for relay Bl in the call allotter, which circuit extends from battery through the winding of relay Bl, conductor 38, No. 5 contacts of relay LKI, conductor 39, No. 2 contacts of relay Cl, No. 1 back contacts of relay C to ground on conductor 2i, and opens the serial locking path of all relays Ll which, should any of them operate in response to the initiation of a call during the time that a link is setting up the ..terminating end of a connection, the same will be prevented from looking at the time relays El and E2 operate in the manner previously described. The failure of relay Ll to lock will then prevent ground from being applied to conductor H over'the contacts of relay MS. In this manner, a line which calls during the setting up of a connection will be prevented from interfering and, of course, will also be denied service until the previous connection has been set up. Relay LKI also completes a circuit for relay E of the call allotter which traces from battery through its winding, conductor 9, No. 1 front contacts of relay LKl, conductor 31, to round on the No. 11 contacts of relay El. Relay E now operates relays El, E2 and MS as previously described and, when the latter relay operates, a circuit is completed for select magnet 8 which extends from battery through the winding of said magnet, conductor to, No. 6
contacts of relay LKl, conductor M, No. 1 contacts ofrelay Bl, conductor H, No. 3 contacts of relay MS, conductor H3, to ground on the No. 3 contacts of relay LKl. Select magnet 8 operates and pre-selects the horizontal cross-. points controlled by it and completes a circuit from ground through the contacts of said magnet, conductor l8, windings of S and SI relays in parallel to battery, causing said relays to operate. The operation of relay S connects ground through its No. 2 contacts, conductor 42, the No. 4 contacts of relay LKI, conductor 43 to the common terminal of resistance RS and the Winding of relay Cl causing the release of the latter. Upon the release of relay Cl, ground is applied to conductor 33 which, as previously traced, is connected to the winding of relay C839 of the called line til. The path is as follows: Ground on the No. 1 back contacts of relay Cl, No. 4 contacts of relay DC, No. 1 front contacts of relay T3, conductor 39, No. 4 front contacts of relay VI, conductor 3!, No. 6 contacts of relay DC, conductor 32, No. 6 contacts of relay III, conductor 33 and thence as traced to the winding of relay C039 to battery. Relay case operates and completes an obvious circuit for hold magnet H939 which operates to close crosspo-int 2. The operation of the hold magnet H839 disconnects operating ground for relay CGBB, but this relay now holds over the No. 4 contacts of crosspoint 2, conductor S, No. 3 back contacts of relay E, No. '7 contacts of relay B, front contacts of relay A (which is being held over the calling line loop from station A) to ground on conductor Si as previously traced thereto. Operated cross points I and 2 effect the connection between the calling line A and the called line B;. Ground "on conductor S2 applied thereto by the closure of the No. 3 contacts of crosspoint 2 completes a circuit for relay SP, which circuit may be traced from ground on said conductor, No. 2 front contacts of relay T2, N0. 5 contacts of relay BY, winding of relay SP to battery. Relay SP operates and connects ringing current applied to conductor 4'1 within the bracket line 13 from the power circuit Ht, through the No. 3 contacts of relay RTR. and lower winding thereof, No. 3 front contacts of relay SP, conductor d8, No. 5 contact of crosspoint 2, ring conductor RI of the called line, over the loop of station B, tip conductor Tl of the called line, No. 6 contacts of crosspoint 2, conductor 39, No. 2 front contacts of relay SP, conductor 59 within the bracket line [3 to ground connected thereto in the power circuit Hi]. Ringing current is thus applied to the called subscribers line and an audible ringing tone is provided for the calling subscriber A over a circuit which extends from one side of ringing tone circuit (not shown) in the Power, etc., circuit H0, conductor ill within bracket line it, No. 5 contacts of relay SP, condenser C8, condenser C2, and thence as traced over the calling loop to ground through the upper winding of relay A. The calling subscriber thus hears the ringing tone. When the call is answered, relay RTR will operate and lock over its upper winding and No. 2 contacts to ground on the No. 4 front contacts of relay SP, and further completes a circuit for relay HS which extends from battery through its winding, conductor 5|, contacts I and 2 of crosspoint 2, conductor 52, No. 1 contacts of relay RTR to ground on conductor 2!. Relay HS operates and, by opening its No. 5 contacts, disconnects the ground which holds relays SW, T2, T3, DC and the register relays III and VI. The release of relay T2 releases relay SP which, in turn, releases relay RTR, the former relay connecting the supervisory relay E to the called line. The circuit of relay E is as follows: Battery through its lower winding, conductor 53, No. 7 back contacts of relay LCI, conductor 5 No. 3 back contacts of relay SP, conductor 18 thence as previously traced over the called loop back to conductor No. 2 back contacts of relay SP, conductor 55, No. 8 back contacts of relay LCI, conductor 56, upper winding of relay E to ground.
Relay E operates and connects ground on its No. 1
contacts and therefrom to conductor 52 which, over the No. 1 and 2 contacts of crosspoint 2, joins the conductor 51 which further extends to the winding of relay HS, thereby holding said relay operated. Over its No. 1 front contacts, relay HS applies ground to conductor S which, through contact 4 of crosspoint 2, extends to the winding of the cut-off relay C039 of line B to hold said relay in an operated condition. Relay HS also establishes a circuit from ground on conductor 26 over its No. 4 contacts, the No. 2 contacts of relay CX to battery through the No. 2 normal contacts and winding of relay CON to battery, whereupon relay CON operates and locks over its No. 2 contacts and the No. back contacts of relay CI to ground on conductor 20.
When the calling line A releases, relay A of the link releases and disconnects ground on conductor S! from conductor 5! but relay HS holds, as said before, to ground on conductor 52. Relay A also disconnects ground from conductor 5? which holds the cut-off relay C020 operated. thereby causing this relay to release, in turn releasing hold magnet H020 and opening crosspoint I. The calling line A is now disconnected from the link. Hence if the calling station should restore first, the release of relay A merely removes one of the grounds which holds relay HS operated, but the latter, holding to ground on conductor 52 applied thereto by relay E which holds over the called loop, prevents the link from being disconnected from the called line. The link, therefore, is held until the called line restores in order to prevent the same from seizing another link and receiving dial tone in consequence thereof. When the called station restores, relay E releases, disconnects ground from conductor 52 releasing relay HS. Relay HS, on releasing, disconnects ground from conductor 52 which releases relay C039 in turn releasing hold magnet H029 and opening crosspoint 2.
In case it is desired to add a third station to the connection for a conference, the called subscriber will replace the receiver on the switchhook. As a result of this, relay E releases, disconnects ground from conductor 52 and thereby causes the release ,of relay HS. The release of relay HS closes a circuit extending from ground on conductor 20, No. 5 back contacts of relay Cl, No. 1 contacts of relay CON, No. 6 contacts of relay HS, to the common terminal of resistance CR and the winding of relay CX, causin the latter to release. The release of relay CX causes ground to be applied from conductor 20, No. 1 contacts of relay OK to conductor 58, thereby causing the reoperation of relay LSl and the reconnection of the translator and alternating current receiver to the link. Key tone is now supplied to the calling subscriber as originally described and thereafter he will proceed to dial the number of the third party. When the first digit is dialed, relay TiZ will operate as described, in turn operating relay SP over a circuit that traces from battery through the winding of said relay, No. 5 contacts of relay BY, No. 2 front contacts of relay T2 to ground on conductor S2 via the No. 3 contacts of crosspoint 2. Relay SP, in operating, reconnects the ringing circuit to the first called station and causes thereby the operation of the ringer thereat. Now, when the second called station is connected to the link in the same manner as called station B, the bells of the two subscribers will ring, and when the second call-ed subscriber answers, the bell at station B will cease to ring and this furnishes an indication that the second called subscriber has answered. This acts as a signal to the called subscriber at B to answer also. In case the second line is busy, relay BY will operate as described when the line is tested for a busy condition and this will cause the release of relay SP since its circuit is controlled through the No. 5 contacts of relay BY in consequence of which the ringer at station B will cease to operate and the calling subscriber will receive a busy tone. The subscriber at station B will then answer since the cessation of ringing is either due to the third party answering or to the third party being busy. Relay HS operates as before described, releasing relay BY and all the register relays. It is to be noted that, on a conference connection of the type described, the stations connected to the terminating end, that is, station B, and the second called station, cannot release until all called stations disconnect since relay HS, which can be operated from any station, will hold to the cut-off relay of any one of the called stations.
Having described the establishment of a cona in consequence of which a link will be connected to the calling station B in the same manner as previously described for station A but, in this case, over crosspoint 3, and when relay ST of the link operates, relays LSI and LCI are operated to connect the alternating current translator and receiver to the link, relays ON and GR therein being operated and tone being to the calling station in the manner previously described for station A. a
It will be observed that relay GR, in its unoperated condition, normally applies ground to the unoperated No. 2 and No. 5 contacts of relay ON which, when operated, connects these contacts to conductors l3 and 14 which further extend to the ring RI and tip Tl conductors of the calling line. to the operation of relay B while relay ON operates following reIayAS T. Now inasmuch as the circuit of relay A is completed as soon as crosspoint 3 is closed and relay ON may be operated at the time, the current build-up in relay A will cause a change in the charge on condensers C2 and 03 over one path completed from one side of condenser 02, conductor 54, No. 7 contacts of relay LCI, conductor 13, Nos. 2 and 3 contacts of relay ON, to ground on the No. 2 contacts of relay GR; and another path from one side of condenser 3, conductor 55, No. 8 front contacts of relay L'Cl, conductor 14, Nos. 4 and 5 contacts of relay ON to ground on No. 1 contacts of reuntil relay GR operates, which occurs after the operation of relay B and, therefore, after the currentin relay A has reached its steady state.
Upon hearing tone, the calling subscriber at station B depresses a key (not shown) of the de- Vice LG which designates the first digit of the called number, thereby plucking two of its set of five reeds. The reeds are set into vibration and produce two alternating currents of specific frequencies which are now transmitted over a circuit which may be traced as previously to conductors I3 and 14 at the Nos. 2 and 5 contacts, respectively, of relay ON and, thereafter, to conductors H and 12, respectively, connecting with the secondary winding of transformer 68-. These frequencies are induced into the circuit comprising the primary winding of said transformer and the high-pass filter 64.
The receiver circuit in Fig. 9 is a conventional disclosure of the receiver shown in Patent 2,269,022 issued to G. Hecht and A. A. Lundw strom on Jan. 6, 1942. It comprises the chan-: nel composed of transformer 68, the high-pass filter 64, the volume limiting device 65, the transformer 66, the adjustablepad 61, five detector amplifiers fA-fE with relays FA-FE respec- Relay GR operates subsequent tively in each of the anode circuits thereof and a suitable filter intermediate the pad 61 and each one of the detector amplifiers, each of said filters being designed to pass only the frequency intended for the particular channel. Between the high-pass filter 64 and the volume limiter $5 is bridged the primary of transformer H2 to the secondary of which is connected the enabler S'il. This enabler is identical in construction to that completely disclosed and described in the above-mentioned patent to G. Hecht and A. A. Lundstrom and is shown only in conventional form except for relay H. The enabler responds to a portion of,the signal pulses which pass through the high-pass filter .64 and functions to operate polarised relay 1'! after a predetere mined interval. Relay 1'! grounds conductor 18 which is connected to the cathode of each of the detector tubes fAjE thereby activating them to respond to the signal energy which passes through the volume limiter 65. Since the operation of the enabler 89 is completely described in the above-mentioned patent, reference is made to said patent for a complete description thereof, only so much of said description as is necessary to an understanding of the present invention being incorporated herein.
Each detector amplifier tube is preceded by a filter which passes only the frequency to which that tube is assigned to respond. It is assumed that the device LG is capable of producing five different frequencies which, for convenience, may be designated AE inclusive and that, in accordance with the operation of the receiver as described in the above-mentioned copending application, frequency A will cause the operation of tube fA, frequency B will cause the operation of tube f3 and so on to frequency E which will cause the operation of tube fE. 1
As already mentioned, .each detector amplifier tube has-a relay connected to the anode terminal thereof, and a front contact of thisrelay is further connected to the winding of one of the five relays TA-TE in the translator circuit shown in Fig. 8. Relay FA in the anode circuit of the first channel which responds to frequency A has its front contact connected to the winding of relay TA, while relay FIB of the second channel, responding to frequency B, is connected to the winding of relay TB and so on up to and including relay FE in the anode circuit of the fifth channel which responds to frequency E, the front contact of which relay is connected to relay TE. Hence, the operation of any combination of detector amplifiers fAfE will cause a corresponding operation of the register relays in the translator of Fig. 8.
The combination of frequencies for each of the digits which may be dialed from the calling station B, the operation of channel and translator relays operated thereby is as follows:
When, therefore, the subscriber keys the first digit, which may be a 2 or a 3 but which, in the assumed illustration, will be a 2, frequencies B and D are generated and these frequencies are transmitted over a previously described loop including a winding of transformer 68 whence they pass through high-pass filter 54 from the output of which the energy thereof divides, part of it passing through transformer H2 to operate the enabler 80 and part of it passing through the volume limiter 65, transformer 66, resistance pad 61, the filters preceding the tubes 1B and ID to operate said tubes. Since the operation of the receiver has been amply described in the abovementioned patent to G. Hecht and A. A. Lundstrom and to which reference is made for a complete description thereof, it may be stated that a definite time interval is consumed in the operation of enabler 80, in consequence of which relay 11 operates to apply ground to conductor 18. Since this conductor is connected to the cathodes of the various detectors, those detectors will respond through whose channels the filters have permitted the passage of the frequencies in the signal. Hence for the digit 2 for which the frequencies B and D are produced to cause the response of channels fB and ID, relays FE and FD will be operated and they, in turn, close obvious circuits whereby relays TB and TD are operated and, upon operating, lock over conductor Bl under the control of polarized relay TL to ground on the No. 6 contacts of relay ON; relay TL having operated over a circuit which may be traced from battery, the No. 2 contacts of relay TLT, upper winding of relay TL, No. 3 contacts of relay TLT, No. 3 contacts of relays TE and TD, No. 3 contacts of relays TB and TC, N0. 3 contacts of relay TA, No. 1 contacts of relays BKI, BK3 and KBD, conductor 16 and ground previously traced thereto. Relay TL also has a circuit through its lower winding which traces from ground on the No. 6 contacts of relay ON, No. 4 contacts of relay TLT, lower winding of relay TL, No. 1 contacts of relay TLT to resistance battery. Now the current flowing through the upper winding of relay TLT is in a direction to cause the armature to engage the contact, while that through the lower winding is in a direction to do the opposite. The strength of the current through the lower winding, however, is not sufiicient by itself to overcome the eifect of the current flowing through the upper winding so that, when both windings are energized, the armature will engage its contact and provide locking ground for relays TB and TD as above described.
It will be noted that the ground which forms a part of the circuit of the upper winding of relay TL also keeps condenser C5 short-circuited. However, the operation of any one of the register relays TATE removes this ground and a charging circuit is established for the condenser through the circuit of the upper winding of relay TL. Relay TL continues to hold for a short interval until the charging current through the condenser dies down after which. being solely responsive to the current through its lower windrelays TB and TD and during the interval that 75 the same are locked to the contacts of relay TL, a circuit is completed in the link to operate relay T2 which is the relay in the link that registers the digit 2 as previously described. This circuit is completed from ground on conductor 16, No. 1 contacts of relays KBD, BK3 and BK!, No. 3 contacts of relay TA, No. 3 contacts of relay TC, No. 4 contacts of relay TB, No. 6 contacts of relay TD, No. 9 contacts of relay TE, No. 2 contacts of relay TB, No. 11 contacts of relay TD, conductor 83, No. 3 contacts of relay LCl, conductor 84, No. 2 back contacts of relay RT, conductor 85, upper winding of relay T2 to battery. Relay T2 operates and then locks as previously described to register the first digit 2. If the first digit of the called number had been a 3 instead of a 2, then, according to the above table, relays TD and TE would have been operated in consequence of the operation of channel relays FD and FE in which event, in addition to closing a circuit for relay T2, a circuit will also be closed for relay T3 and this circuit may be traced from ground on conductor '16, No. 1 contacts of relays KBD, BK3 and BKI, No. 3 contacts of relay TA, No. 3 contacts of relay TC, No. 3 contacts of relay TB, No. 4 contacts of relay TD, No. 6 contacts of relay TE, N0. 1 contacts of relay TD, No. 2 contacts of relay TE, conductor 86, No. 1 contacts of relay LCl, conductor 81, No. 3 back contacts of relay RT, conductor 83, No. 2 normally made continuity contacts of relay T3, upper winding of said relay T3 to battery. Relay T3 operates and then looks as previously described to register the digit 3.
Simultaneously with the operation of the register relays TB and TD in response to the keying of the tens digit 2, or with the operation of relays TD and TE for the digit 3, a circuit is completed for relay RA. For either digit, the ground on conductor 15 may be traced to the common conductor joining the No. 6 and No. 9 contacts of relay TE. These paths are through a network of contacts which extends over the contacts of relays TATE in order to insure that exactly two of these relays are operated before grounding any of the link registers. From the common terminal of this network at the Nos. 6 and 9 contacts of relay TE, the circuit for relay RA may further be traced through either No. 1 contacts of relay TE or No. 1 contacts of relay TB, No. 10 contacts of relay TD, No. 5 back contacts of relay RAI, No. 1 normally made continuity contacts of relay RA, No. 1 contacts of relay RR, winding of relay RA to battery. Relay RA operates and, by the closure of its No. 1 front contacts, applies ground on conductor 1'6 to one terminal of the winding of the relay RAI, the other terminal being grounded over the No. l back contacts of said relay by the afore-traced ground for operating relay RA. Relay RA, in operating. opens the tone circuit at its No. 2 contacts thereby removing dial or key tone from the line.
7 removed from the battery side of the winding of relay RAI causing said relay to operate by the circuit completed to an afore-traced ground on the No. 1 front contacts of relay RA. Relay RAI, in operating, closes a circuit for relay RT the path of which extends from groundon the No. 1 contacts of relay RAl, conductor 89, No. 2 contacts of relay LCI, conductor 9|, winding of .relay RT to battery. Relay RT operates, locks
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2519867A (en) * 1947-05-22 1950-08-22 Automatic Elect Lab Restricted service telephone system
US2636947A (en) * 1949-12-16 1953-04-28 Bell Telephone Labor Inc Two-way trunk for pulse conversion systems
US3204040A (en) * 1961-12-29 1965-08-31 Bell Telephone Labor Inc Switching circuit
US3259697A (en) * 1962-11-28 1966-07-05 Bell Telephone Labor Inc Telephone signaling system
US3426154A (en) * 1963-04-26 1969-02-04 Siemens Ag Circuit arrangement branch exchange for a telephone installation,especially an installation with code selection and impulse selection of the subscriber stations

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2519867A (en) * 1947-05-22 1950-08-22 Automatic Elect Lab Restricted service telephone system
US2636947A (en) * 1949-12-16 1953-04-28 Bell Telephone Labor Inc Two-way trunk for pulse conversion systems
US3204040A (en) * 1961-12-29 1965-08-31 Bell Telephone Labor Inc Switching circuit
US3259697A (en) * 1962-11-28 1966-07-05 Bell Telephone Labor Inc Telephone signaling system
US3426154A (en) * 1963-04-26 1969-02-04 Siemens Ag Circuit arrangement branch exchange for a telephone installation,especially an installation with code selection and impulse selection of the subscriber stations

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