BE380134A - - Google Patents

Description

       

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  Improvements to telephone systems.



   The present invention relates to telephone systems and more particularly to automatic telephone systems and its aim is, in general, the production of new and improved arrangements in automatic telephone systems to enable automatic switches to answer. more precisely to the control pulses transmitted to them.

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   As is known, switch control pulses transmitted by means of a calling telephone line in an automatic telephone system are processed by a line relay mounted in series on the line. Due to the vastly different conditions (including differences in resistance and insulation among the different lines connected to an automatic telephone office) it is difficult to maintain the line relay setting of an automatic switch so that 'it follows faithfully and without excessive distortion, the pulses received from all the lines.

   If the line relay is made too sensitive to allow it to respond satisfactorily to pulses received by long lines, the relay tends to remain actuated for too high a percentage of the time when pulses are received from. short lines.



  It is therefore proposed to interpose a vacuum tube between the line and the automatic switch in place of the line relay employed heretofore and it has been observed that substantially the same variation in plate current can. be achieved in a vacuum tube for a wide range of changes in gate potential.

   Accordingly, in the system described herein, the grid of a vacuum tube is connected to an input conductor of an automatic switch to receive the incoming pulses, while the switch operating magnets are connected. controlled in accordance with the plate current of the vacuum tube;

   which is forced to start and stop under the control of the incoming pulses received by the vacuum tube grid,
According to a method for the practice of the invention, a vacuum tube receiving the pulses is placed at each automatic switch and the working magnets.

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 The switch element are connected directly to the vacuum tube plate circuit, while according to another embodiment of the invention, vacuum tube repeaters are interposed between the calling telephone lines and the automatic switches for intercept all incoming impulses and to repeat them at the various automatic switches by means of the line relays customary in automatic switches ,,

  'Line relays employed in automatic switches are thus made capable of functioning satisfactorily since they always operate under substantially the same conditions and are not subjected to the widely varying conditions of the lines, as is the case when' they are directly connected to the calling lines.



   Another object of the present invention is to provide a vacuum tube type pulse repeater, which can be introduced into a normal automatic telephone system as an output repeater in place of existing output repeaters employing output relays. line. This repeater is useful in multi-office systems where the line conditions are not very intense so that the line relays respond satisfactorily when connected directly to the line but do not respond so strongly. satisfactory when operated by electromagnetic pulse repeaters for office-to-office calls, often involving long trunk lines.



   Other features of the invention relate to the satisfactory solution of the problems arising in connection with the application of vacuum tubes to particular circuits. These problems include turning on and off the filament circuits of the vacuum tubes, obtaining the po-

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 normal correct grid tentials for the vacuum tubes and the creation of suitable circuits to allow normal monitoring to be carried out,
In the drawings comprising FIGS. 1 to 4, it has been shown by means of the usual circuit diagrams what is required of the apparatus of a telephone system including the characteristics of the present invention in order to enable the invention to be understood.



   Figures 1 and 2 taken together show the switching apparatus and the control apparatus used to establish communication from a calling station A1 from one office to a station called B1 located in another office.



   Among this apparatus, the line switch LS1 can be a normal rotary line switch such as is usually used in automatic telephone systems.



   The office selector OS1 is assumed to be a vertical and rotary selector having fixed contacts arranged in usual horizontal rows or stages; the thousands and hundreds selectors ThSl and HSl may be mechanically and electrically similar to the OSL desktop selector and the connector C1 may be of the same type of vertical and rotary mechanism.

   In order to reduce the resistance of the circuit by which the conversation current is supplied to the calling line during the call between offices and to avoid the use of a third conductor in the connection between offices and to provide safe pulses between offices, the repeater Rl is interposed between the office selector OSl and the outgoing trunk line comprising the conductors 141-142 terminating at the office located at a distance and ending with the selector of thousands of input ThSl
Figure 3 shows the apparatus in a multi-office system similar to the system of Figures 1 and 2 except that the vacuum tube pulse repeater R2 is included.

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 teroalé in the trunk line between the line switch LS2 and the office selector OS2,

   all the switchgear being of normal construction and fitted with the usual line relays such as line relay 331 of the office selector OS2. The selectors OS2. ThS2 and HS2 may be similar to the selectors shown and described in another patent, connector 02 may be similar to connector 0 shown in that patent and the LS1 and LS2 line switches shown here may be similar to the LS line switch shown in the same patent.



   The vacuum tube pulse repeater shown in figure 4 repeats pulses directly from the incoming line to the outgoing line without the interposition of a repeater relay and can be used before a first selector switch. as in Figure 3, or it can be used as an output repeater, as in the case of the repeater R1, Figure 1. Like the repeater R2 in Figure 3, the repeater R3 in Figure 4 is arranged fa - gon to repeat pulses to normal switches employing line relays.



   Referring now in particular to Figures 1 and 2, a detailed description will be given of the operation of the apparatus shown) in these figures. For this purpose, it will be assumed that the subscriber of station A1 of the first office wishes to converse with the subscriber of station B1 in the second office. To this end, the subscriber of set A1 removes his recap- ist from the hook and forms the digits of the subscriber's number of set B1 on the dial.



   When the receiver is removed at station A1, the line switch LSl operates through the conductors of

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 line 2 and 3 to extend a call to a first free selector or office selector. Assuming that the OS1 office selector is the first that is free, a connection is made to it by trotter 101-103 of the LSI line switch by means of conductors 104 -106. When this occurs, relay 107, the lower winding of which is connected between earth and conductor 106, in series with resistor 116, operates by means of the calling line and conductor.
104 which is provided with a negative potential from the office battery through resistor 123.



   In operation, relay 107 places an earth potential on the release junction conductor 105 at its upper armature so as to hold the selectors guarded against other line switches and to close the usual restraint circuit ( not shown) for the LSI line switch. At its bottom frame, release relay 107 closes an ignition circuit for the filament of tube 121 through resistor 122 and through the inner bottom frame of relay 110 from the normal office battery, Aux. : normally closed contacts controlled by the lower frame of relay 107, a point is open in the circuit of the release magnet 115 to prevent premature operation of the release magnet.

   As a result of the tube filament 121 being turned on when a circuit is closed for it by relay 107 by means of resistor 122, current tends to flow from the tube filament to the tube plate and through. relay 108 and vertical magnet 113, because of the positive potential applied to the tube plate by the special plate battery associated with vertical magnet 113. This current flow is maintained at a value minimum or completely prevented

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 (following the resistance of the line at station A) because of the negative potential coming from the office battery, which is applied to the grid element of the tube 121 by the calling line.

   The relatively high resistance 116 is interposed in the circuit between the lower winding of relays 107 and earth so as to maintain the tube grid at a relatively high negative potential.
It should be noted that when the winding circuit is closed for the filament of the tube 121, a parallel circuit is closed by contacts of the vertical magnet 113 for the upper winding of the relay 107, which turns on. strongly the relay so as to ensure that it remains actuated during the transmission of a series of pulses. With this arrangement, the line current should be only sufficient to operate the relay sufficiently to close the filament circuit, after which the circuit through the upper winding kicks in to operate the relay for the remaining distance.

   The top winding of relay 107 is bypassed by resistor 117 so as to allow a local current to flow after the top winding circuit has been opened making the relay slow to release. ,
At this point, it can be indicated that the desktop battery usually has a potential of 46 to 50 volts while the filament or vacuum tube 121 can demand a potential of three to seven volts depending on the tube used.



  Consequently, the average potential of the filament of tube 121 is a few volts from the earth potential,
When the calling device of station A1 is operated in accordance with the first digit of the desired number ,, @

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 the line circuit is opened a corresponding number of times. Whenever the line circuit is opened and upon removing the negative potential applied to the line of conductor 104 as mentioned above, the grid element of tube 121 becomes potential positive with respect to the filament as a result of the earth connection via the lower winding of relay 107 and resistance
116.

   This allows full operating current to flow from the special plate battery through vertical magnet 113 and relay 108 whenever the line circuit is momentarily open,
Whenever the line is closed again to the calling device from station A1 after a momentary interruption, current flows again on the line and the grid potential of tube 121 changes from positive to negative, which stops the passage of current in the cooked air of the plate by the magnet 113 and the relay 108.

   When this happens, the vertical magnet 113 drops out and again closes the circuit of the upper coil of the relay 107.
By the operation of the vertical magnet, the II8wI20 wipers are gradually raised until they come to rest in front of the desired stage of contacts.



   Another result of each operation of vertical link 113 is that the circuit of the top winding of relay 107 is opened at the contacts shown to the left of the vertical magnet so as to allow relay 107 to drop. and release the communication in the event that the line circuit is not closed again. During the time when the circuit of the upper winding of relay 107 is momentarily open, the relay is kept actuated by the current flowing through the winding.

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 upper, in series with resistance 117.



   The series relay 108 is provided with a conductive sleeve, as indicated by the vertical interior lines, and the relay is kept actuated between successive pulses towards the vertical magnet by the circulating current flowing through this sleeve. inverter.



   When relay 108 first operates, it prepares a circuit for forward relay 109, which circuit is closed to out-of-normal contacts 112 as soon as the switch shaft has been lifted from its normal position. by the vertical magnet 113. The relay 109 operates and closes a locking circuit for itself at its upper armature, and at its lower armature it prepares an operating circuit by the rotating magnet 114.



   When relay 108 drops out at the end of vertical switch movement, it opens the initial circuit of the currently latched forward relay 109 and completes the circuit of rotating magnet 114 from release junction conductor 105 set. To the earth .



  Magnet 114 works to advance the rubbers
118-120 until it engages with the first series of contacts in the floor opposite which they were lifted. Towards the end of its travel, magnet 114 opens the circuit of forward relay 109 to the contacts shown to the right of the valve, after which relay 109 drops out and opens a new point in its latch circuit to its switch. upper armature, at the same time opening the circuit of the rotating magnet, its lower armature. The rotating magnet drops out accordingly and reconnects relay 109

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The rest of the operation depends on whether the trunk line connected to the first fixed contact is occupied or free.

   If this line is free, it is taken into service by the operation of relay 110, but if it is busy, relay 110 is shunted by the earth potential on the release junction conductor of this line, encountered by the trotter. test 119, and relay 109 again operates through test wiper 119 and out of normal contacts 112 and again closes a latch circuit for itself at its upper arm, and it closes the circuit of the rotating magnet to its lower armature. In this way, the rotating magnet is actuated again to advance the rubbers to the next set of fixed contacts.



   This alternating operation of advance relay 109 and magnet 114 continues until a free set of fixed contacts is reached. When a free series of fixed contacts is reached, contacts 128, 130 for example, the switching spoke 110 is no longer short-circuited by the application of earth potential to its lower terminal, after which it operates. in a circuit from the grounded release junction conductor 105, through the out of normal contacts 112, in series with the relay 109; Relay 109 is not actuated at this time due to the relatively high resistance of relay 110.



  In operation, the relay 110 opens a new point in the test circuit and prepares the hold circuit for the selector at its internal upper frame; it opens the filament ignition circuit and the retaining circuit for the upper winding of relay 107 at its internal lower armature, and at its upper and lower armatures it disconnects the incoming conductors 104 and 106 from the

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 resistance 123 and the lower winding of relay 107 and extends them by means of fixed contacts 128 and 130 to the repeater Rl.



   In repeater R1, line relay 131 energizes by means of the calling line in series with resistor 139 and closes a circuit for release relay 132. Release relay 132 operates and applies. an earth potential at its upper armature to the associated release junction conductor, extending to the fixed contact 129, which completes the restraint circuit for the selector OS1 and the line switch LS1 via the upper internal frame of the switching relay 110.



   This restraining circuit is completed, as will be understood, before the slow-action release relay 107 of the desktop selector OS1 has had time to drop again due to the circuit opening of its lower winding. the lower armature of the relay 110 and by following the opening of the circuit of its upper winding to the lower internal armature of the relay 110.

   In practice, the inner bottom armature of relay 110 is set to cut first in order to extinguish the filament of vacuum tube 121 and to prevent the flow of plate current under the effect. of the disconnection of the winding infer from relay 107 to the lower armature of relay 110 and the resulting change in grid potential of tube 121 from positive potential to negative potential.



   The moment the filament is turned off and the circuit of the upper winding of relay 107 is opened, the upper winding of relay 107 is shunted by resistor 117 as previously explained, and it is also bypassed at this time by the low resistance circuit
 EMI11.1
 , mL-

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 enclosing the resistor 122 and the filament of the lamp 121,
The current. 'Produced by self-induction at. from the coil.

   The upper ment of relay 107 flows into these two branch circuits, making the relay slow enough to release to hold conductor 105 to ground until the release relay 132 of repeater R1 operates as. as explained above.,
When the relay 107 drops out, it removes the earth potential at its upper armature from the conductor 105, leaving this conductor connected to the earth by the wiper 119 and the internal upper armature of the release relay 132 of the repeater Rl At its lower armature, relay 107 opens a new point in the filament circuit and in the circuit of its upper winding, at the same time preparing a circuit for the releasing magnet 115 by the out-of-normal von- tacts 111 ,

   circuit which is kept open at this time at the lower internal armature of the switch relay 110.



   In the repeater R1, the release relay 132, in addition to earthing the release junction conductor to its internal upper armature, as indicated above, closes a bridge between the conductors. of outgoing junctions 141-142 to its upper armature by contacts of relays 133 and 134 and by marginal monitoring relay 135. The current then flows in this bridge circuit and through conductors 141 and 142 in series with the circuit Thousand selector line ThS1, Figure 2, Thousands selector which is the same as the OS1 desktop selector in Fig. 1. except for its position in the switch train.

   The passage of the cost is limited by the resistor in the selector Ths1, similar to the resistor 116 in the selector OSL Consequently, the marginal monitoring relay 135 is not

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 not actuated at this time. ThS1 Thousand Selector is prepared for operation as described for OS1 Selector.



   In repeater R1, release relay 132 also closes a circuit to its bottom armature through resistor 137 to ignite the filament of tube 136. The flow of plate current through relay 133 from the associated special battery to this (which may be the same battery as that associated with the vertical magnet 113 of switch OS1) is prevented by applying negative potential to the grid of tube 136 from the normal desktop battery , through the top coil of the line relay 131 and through the calling line to the vacuum tube grid.

   The high resistor 139 is interposed in circuit with the lower winding of the line relay for the same purpose as described in connection with the resistor 116 of the selector OS1, and the upper winding of the line relay 131 is bypassed. by resistor 143 in order to reduce the inductance of the circuit through which the negative potential is supplied to the grid of tube 121,
When the next digit is formed at the dial, the line circuit is opened a corresponding number of times.



  Each time the line circuit is opened, the gate potential of tube 136 changes from negative to positive, after which a current pulse flows through repeater relay 133 connected in the plate circuit of the tube. vacuum tube. Each time the time relay 133 operates, it opens the bridge between conductors 141 and 142 at its lower armature, repeating the pulse at the thousand ThSl selector, figure 20 As a result, the thousands ThSl selector, figure 2, operates under the effect of the second number formed on the dial by lifting its rub-

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 tors in front of the desired floor of fixed contacts and rotating them looking for a free junction line.

   We can assume that the junction line extending to the hundreds selector HS1 is the one taken in service,
As a further result of each operation of relay 133, a circuit is closed for relay 134. Relay 134 is slow to release due to resistor 120 being bridged around its winding. As a result, relay 134 operates under the effect of the first pulse of the series and remains actuated throughout the series of pulses. When operating, relay 134 disconnects conductor 141 from the upper conversational conductor of the repeater and from the upper part of the bridge through relay 135 and connects it to the lower terminal of relay 135 and to the lower conversational conductor. .

   By this arrangement the inductive relay 135 is switched off from the pulse circuit in order to give a more rapid establishment of current following each interruption in the line circuit.



   When the subscriber calling from station A1 dials the hundreds digit of the desired number, repeater R1 operates as described above to repeat the digit pulses to the ESI selector. The HS1 selector operates in the manner described for the OsL and ThS1 selectors to choose a free trunk line and it will be assumed that this trunk line is the one comprising conductors 231-233 and extending to connector C1. When this junction line is taken in service, the line relay 201 of / it operates and closes a release relay pulley circuit 203.

   Relay

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 release places the earth potential on the release junction conductor 232 at its upper armature; opens a point in the circuit of the release magnet
217 and places an earth potential on conductor 234 at its upper internal armature, and at its lower armature it closes an ignition circuit for the vacuum tube filament 211 through resistor 212. The passage of oor - plate flow in the vacuum tube 211 is prevented by the application of negative potential to the grid of the tube by the upper coil of relay 201 (shunted by resistor 223), the junction line coming from the repeater R1 and driver 233.



   When the calling subscriber dials the tens digit in the desired number, this digit is repeated by the repeater R1 in figure 1 to the C1 motor by means of the connection established using the ThSl selectors. and HS1. When the line circuit is first interrupted by repeater R1 and the gate potential of tube 211 is accordingly made positive for the first time, vertical magnet 218 operates from the special battery thereof. through series relay 204, springs out of normal 213 and 215, and through the vacuum tube plate circuit, to earth through the lower armature of relay 203.

   Slow-acting relay 204 operates in series with vertical magnet 218 and keeps the vertical magnet circuit intact after the out-of-normal springs have moved, as they do on the first vertical advance of the switch. Each vertical pulse following the first is fed to the vertical magnet by the springs 215 and 214 and by the lower armature of the actuated relay 204.

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   By the operation of the vertical magnet 218, the wipers 220222 are gradually raised until they are in front of the desired level of fixed contacts,
At the end of vertical movement, relay 204 drops down and transfers the vacuum tube plate from the vertical magnet to the rotating magnet.



   When the units digit of the number is formed on the dial, current pulses are supplied through the vacuum tube plate 211 to the rotating magnet 219 and the slow acting relay 207 in parallel. By the operation of the rotating magnet 219, the wipers 220-222 are gradually rotated until they come into engagement with the fixed contacts of the line of station B1. Relay 207 operates in parallel with rotating magnet 219 on the first pulse and since it is slow to operate, it remains actuated for the entire digit.

   At its upper armature, relay 207 disconnects test slider 221 from the test winding of switching relay 208 and connects it to occupancy relay 206, and at its lower armature it bypasses the lower contacts. of the occupancy relay 206 so as to prevent the filament of the tube 211 from going out in the event that the occupancy relay 206 is operated during the rotary motion as a result of the wiper 221 encountering a test contact busy.



   The operation which takes place at the end of the rotary motion depends on whether the called line is busy or free. If the called line is busy, there is an earth potential on the test contact thereof which is encountered by the wiper 221, and the occupancy relay 206 operates when the wiper lands on the contact.

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  With occupancy relay 206 activated, a latch circuit is closed for relay 206 when relay 207 drops. This interlock circuit goes from earth to earthed conductor 234, through the contacts of relays 206 and 207. With relay 206 actuated and relay 207 returned to normal; the filament of the tube 211 is extinguished, which prevents further operation of the rotating magnet 2I9. At its lower armature, the relay connects the busy sound conductor 251 with the lower conversation conductor by means of the associated capacitor, which causes the transmission of a busy sound through the connection established to the calling line. . On hearing this busy sound, the called subscriber must replace his receiver and release the established call.



   If we now assume that the line of set B1 is free when called, the busy relay 206 is not actuated. When the wipers 220-221 come to rest on the contacts of the called line and when the relay 207 drops out, it completes a circuit to its upper armature to energize the switching relay 208 by means of its winding of 'test. This circuit runs from earth to the grounded conductor 234 through the upper armature of the occupancy relay 206 and through the upper coil of the relay 208 through the wiper 221 by means of contacts of the relay 207. The relay circuit 208 is completed to the battery by means of the line switch interrupt relay (not shown) of the called line.

   On operation, relay 208 closes a latch circuit for its lower winding from release junction conductor 232 to its lower internal contacts; it applies the earth potential directly to the

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 test wiper 221 to its upper internal frame;

   it switches off the filament of the vacuum tube 211 at its lower middle armature, and at its upper and lower armatures it connects the wipers 220 "222. When this occurs, the ringing current coming from the ringing conductor 250 is started by the called line and returns by means of the slider 220 and the upper conversation conductor to the battery by means of the upper winding of the ring interrupt relay 205,
When the called subscriber answers his ringing by removing the receiver and substituting a DC bridge for the ringing bridge, which includes a capacitor, the ringing interrupt relay 205 operates and closes a latch circuit. for its lower winding than its lower internal reinforcement,

   and at its upper, and lower armatures it opens the ringing circuit and connects the calling lines, and telephonically called, When this occurs, the rear bridge relay 202 on the connector operates by means of the called line; disconnects the shunt resistor 223, at its upper armature, and at its lower armature it bypasses resistor 209 so as to. increase the conversation current flow in the calling line in the case where the calling line is in the same office as the called line, in which case no repeater is used. In this case, the shunt resistor 209 increases the flow of current in the connection established between the repeater B1 and the connector C1 enough to cause the operation of the marginal monitoring relay 135.

   The relay 135 operates, it disconnects the shunt resistor 143 and shunts the resistor 139 associated with the line relay 131, which increases the passage of the

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 current in the calling line so as to provide the trans. telephone maker calling a sufficient amount of yard. rant of conversation. The calling and called subscribers can then converse together as needed, the conversation circuit being provided by the large conductors.



   When the conversation is over, the two subscribers replace their receivers. When the receiver is returned to station B1, the rear bridge relay 202 of connector C1 drops out and reinserts resistor 209 into the line circuit; after which the marginal relay 135 of the repeater R1 drops and introduces the restanoe 139 into the circuit of the calling line.



   Note that the increase in line current caused by relays 202 and 235 can be used to operate a meter to record payment for the calling subscriber, if desired, and that the increase when the called subscriber answers and the decrease when he hooks up again can be used to give supervision in the case where the call comes from, for example, a private branch office employing an operator.



   When the receiver is replaced at station A1, the repeater relay 135 of the repeater R1 is actuated to open the line circuit extending to the connector C1, figure 2, The line relay I3I drops out and opens the circuit of the release relay slow-acting 132. A moment later, the slow-acting release relay 132 drops out and opens a new point in the bridge between conductors 141 and 142 at its upper frame;

   it switches off the filament of tube 136 at its lower armature, which allows relays 133 and 134 to drop out and at its upper internal armature it in ,, raises the earth of the associated release junction conductor

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 which allows the line switch LS1 to be released in the usual way and opens the circuit of the switching relay 110 of the office selector OS1. When the switching relay 110 drops out, it closes in its lower internal armature a circuit by the contacts of the release relay 107 and by the out of normal contacts 111 for the release magnet 115. The magnet release operates and returns the OS1 selector to normal, after which the release magnet circuit is open to out of normal 111 contacts.



   In connector 01, figure 2, line relay 201 drops off when its circuit is open to repeater R1, and it opens the circuits of release relay 203. Release relay 203 removes the earth potential of the conductor. junction 232 to its upper armature, which allows the ThS1 and HS1 selectors to release in the manner described in connection with the OS1 desktop selector. Removal of the earth potential of the release junction conductor 232 also allows relays 205 and 208 to drop. At its upper internal frame, release relay 203 closes a circuit through out-of-normal contacts 216 for release magnet 217.

   Release magnet 217 operates and returns connector C1 to its normal position, after which the release magnet circuit is opened at contacts 216.



   The entire call is now cleared and the equipment included in it can be used for establishing further calls.



   The system shown in this figure will now be described with reference to FIG. As previously indicated, instead of employing a vacuum tube in each switch, the system of Figure 3 employs a vacuum tube repeater in the line ahead of each first switch.

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 selector switch, while all switches which respond to pulses employ normal circuit arrangements. Further the repeater R2 of figure 3 differs from the repeater R1 of figure 1 in that the toast potential. The of the vacuum tube 311 is normally positive in the repeater R2 after this has been switched on and the gate potential is made negative each time the calling line is interrupted.

   In addition, the repeater R2 has been arranged to respond to normal reverse battery monitoring instead of the high resistance monitoring of Figures 1 and 2.



   For the purpose of explaining the operation of the apparatus of FIG. 3 in detail, it will be assumed that the subscriber of set A2 in an office wishes to converse with the subscriber of set B2 in a remote office. When the receiver is removed at station A2, line switch LS2 operates in the usual manner to seize a free trunk line. It will be assumed that this junction line is the one extending towards the repeater R2 and comprising the conductors 313-315. When this trunk line is taken up, line relay 301 operates by means of the calling line, in series with resistor 306, and by conductors 313 and 315. When operating, line relay 301 closes a circuit. by resistor 309 for the filament of tube 311. Tube 311 therefore lights up.

   Note that resistor 310 is also in series with the filament of tube 311. As indicated by the relative dimensions of resistor symbols 309 and 310, resistor 310 is a relatively low resistor while resistor 309. is a relatively high resistance.

   As a result, the filament of tube 311 is maintained at an average potential almost as negative as the negative terminal of the office battery. On the other hand, the grid of tube 311 is @

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 now held at a potential almost as positive as the positive terminal (ground terminal) of the office battery because of the ground connection to the grill from the grounded conductor 315 by means of line to station A2, the relatively high resistance 306 being introduced in circuit between the grid of tube 311 and the negative terminal of the battery, in series with the upper coil of relay 301.

   With the gate element thus maintained at a relatively positive potential with respect to the filament, the conditions are favorable for a current flow in the plate circuit. Note that no separate plate battery is used and plate relay 303 has its top terminal connected directly to earth. This arrangement is used because the characteristics of the vacuum tube 311 are such that the voltage of the office battery is sufficient to send an ample operating current through the relay 303. As a result, the relay 303 now operates and closes a circuit for. relay 302 to its lower armature, at the same time opening a point in the circuit of slow-acting relay 304 to its upper armature.

   Relay 302 operates and prepares a circuit for relay 304 at its upper internal frame; it places the earth potential on the release junction conductor 314 at its upper armature, and at its lower armature it closes an additional circuit for igniting the filament so as to keep the filament of the tubes 311 lit during im- pulses in the event that relay 301 drops out, Another result of energizing repeater relay 303 is that a circuit is closed at the bottom armature thereof for line relay 331 of the office selector CS2, by en ..

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 upper bearing of the electro-polarized relay 305 and by the impedance coil 312.

   As a result, line relay 331 operates to prepare desktop selector OS2 for operation.



   When the calling subscriber dials the first digit of the desired number, the line is interrupted at the calling device a corresponding number of times. Each time the line is interroped, the grid potential of tube 311 changes from positive to negative, after which the flow of current through the plate circuit and relay 303 ceases. Relay 303 therefore drops out each time the line circuit is opened, and each time it drops out it opens the line relay 331 circuit of the OS2 desktop selector.

   Relay 303 also opens the circuit of slow-acting release relay 302 whenever it drops out, but relay 302 remains actuated as a result of the bypass around its winding by resistor 307. relay 303 also closes a circuit for the slow acting relay 304. Relay 304 operates the first time its circuit is closed and remains energized during the series of pulses as a result of being bypassed by resistor 308. Relay 304 shifts the line relay circuit of office selector OS2 so that it excludes impedance 312 and the top winding of 305 so as to improve the pulse circuit.
At the end of the digit, relay 303 remains energized and relay 304 drops out.



   Under the effect of the pulses of the first digit, the OS2 desktop selector raised its 333-335 wipers until they are in front of the desired stage of fixed contacts, after which the wipers are rotated. the

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 in the usual way in search of a free trunk line, When a free trunk line is found, that extending to the thousands selector ThS2, for example, the switching relay 332 operates in the same way usual to enter the junction line and complete the connection to it.

   ThS2 Thousand Selector is an input selector in the remote office but no output repeater is needed at the output end of the trunk line because repeater R2 is already in communication. To repeat the pulses, it is unnecessary to extend a release junction conductor between the two offices because the office selector OS2 and the line switch selector LS2 are kept actuated by the conductor 314 by means of the potential of earth provided by the release relay 302 of repeater R2,
Under the effect of the formation, on the dial, of the remaining digits of the desired number,

   the thousands selector ThS2 the hundreds selector HS2 and the connector C 2 are actuated in the usual way to establish the connection with the line of station B2.



   When the B2 set subscriber answers, the rear bridge relay (not shown) in connector 02 is actuated to reverse the connections between the incoming line conductors and the connector line relay, thereby reversing the passage of the line. current in the incoming conductors and forces the passage of current to reverse into the rear bridge of repeater R2, enclosing the upper winding of the electro-polarized relay 305.

   When this occurs, the flow of current in the two windings of the electro-polarized relay is in agreement and the relay operates. At its upper armature, the relay 305 short-circuits the re-

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 sistor 306 so as to increase the flow of the conversation current and at its lower armature it removes the derivative ,. tion around the bottom winding of line relay 301 so as to balance the talk current.



   Subscribers can then converse as they wish and when the conversation is over, they repla. cent their receivers.



   When the receiver is hung up at station B2, the flow of current in the line conductors between repeater R2 and connector C2 is reversed to return to normal, after which the electro-polarized relay 305 returns to normal.



   When the receiver is returned to station A2, repeater relay 303 drops out and opens the outgoing line circuit at its lower frame, incidentally actuating relay 304 at its upper frame. Line relay 301 also drops out. Release relay 302 drops out after a slight interval and opens the circuit of relay 304 to its upper armature; it extinguishes the filament of the vacuum tube at its lower armature and at its upper armature it removes the earth potential of the release junction conductor 314 so as to allow the line switch LS2 and the office selector OS2 to be released.



   Under the effect of the line circuit opening at the lower armature of relay 303, switches ThS2, HS2 and C2 return to normal in the remote office,
Communication is then completely released
The repeater R2 is, as will be noted, arranged in such a way that it forces the communication to come undone and causes itself to be released from a line which may be so badly isolated that it maintains the relay. line 301 activated because the repeater relay 303, which responds to fluctuations in the grid potential at the vacuum tube, retm-

 <Desc / Clms Page number 26>

 be and opens the circuit of the release relay 302, when the receiver is replaced at the calling station, whether the line relay 301 drops or not, When the release relay
302 falls,

   the LS2 line switch releases and disengages the repeater, which allows line relay 301 to fall back and turn off the tube filament in the event that it is prevented from doing so by the flowing leakage current through the calling line.



     'We will now describe with reference to the figure
4 the repeater shown in this figure. When the repeater is taken in service, either by a line switch or by a selector, depending on the position of the repeater in the assembly, the line relay 405 operates by the conductors 401 and 403 and closes a circuit for the relay. slow-acting release 406. Relay 406 operates and at its upper armature it places the earth potential on the release junction conductor 403, At the lower armature of relay 406, a circuit is closed for the filament of the vacuum tube 411 from battery 412, It should be noted that battery 412 is individually specific to the repeater.

   When the filament turns on, current flows through the vacuum tube plate circuit from the desktop battery through the bottom winding of the line relay
423 of the automatic switch to which the repeater R3 is connected, through the negative junction conductor 422, the filament-plate circuit of the vacuum tube 411, the relay 407, the positive junction conductor 421 and the upper coil of the relay from line 423 to earth, At the same time, there is a circuit for connecting the upper terminal of relay 407 through the contacts of this one and through the upper winding of the electro-polarized relay * 409 to earth by the contacts of relay 410, in parallel with the upper winding of the

 <Desc / Clms Page number 27>

 relay 423.

   Relay 409 does not work in this branch circuit because relay 407 quickly energizes in the main circuit and opens the branch circuit, Line relay 423 operates in series with relay 407 and through conductors 421 and 422 and prepares the associated switch for operation in the usual manner,
When a digit is dialed after the repeater R3 is turned on, the incoming line circuit is cut a corresponding number of times. Each time the line circuit is cut, the gate potential at the 411 tube changes from the positive potential previously applied through the line at the tube gate to a negative potential applied through the upper coil of the relay. line 405 and resistor 349 to the tube grid.

   When this occurs, the flow of current in the plate circuit of the tube 411 ceases, after which the relay 407 of the repeater and the line relay 423 of the switch X drop out, the relay 407 connects the circuit again in connection. connection containing the upper winding of relay 409.



   Each time the line circuit is closed, after an interruption, relays 407 and 423 operate again, relay 407 again disconnecting the branch circuit before relay 408 has time to operate.



   At the end of the figure, the positive potential remains applied to the grid of the vacuum tube 411 and the relays 407 and 423 remain actuated.



   After the connection has been extended by the automatic switches to the called line and the a-

 <Desc / Clms Page number 28>

 called party has answered, the connection between the line relay now supplying current to the rear bridge of the repeater and the line conductors arriving at this line relay is reversed in the usual way, after which the changeover current tends to reverse in the rear bridge of the repeater. Current flow cannot be reversed through vacuum tube 411, on the contrary and relay 407 drops out and does not operate again.

   In this case the negative potential is supplied by means of the upper conductor 421 and by the contacts of the relay 407 to the upper winding of the electro-polarized relay 409, the circuit being completed towards the earth by means of the contacts of the relay 410 The electro-polarized relay 409 then operates and closes a circuit for the relays 404 and 410 in parallel.



  Relay 404 reverses the connections between line relay 406 and incoming conductors 401 and 403, simultaneously cutting resistor 349 and removing the bypass from around the lower coil of relay 405. The circuit Incoming line bake is thus balanced to give a quiet conversation circuit; the current flow is increased to give sufficient power to the transmitter of the calling line and the current flow is reversed in the calling line. It can therefore be seen that the repeater R3 provides both high resistance monitoring and reverse current monitoring. You can use either or both at the same time, if desired.



   When relay 410 operates, it closes a latch circuit for itself at its lower internal frame to grounded release junction conductor 402, simultaneously opening its original circuit; it extinguishes the filament. from the vacuum tube 411 to its internal armature

 <Desc / Clms Page number 29>

 lower middle and at its lower armature, it completes a new bridge between conductors 421 and 422 via impedance coil 413 and the lower contacts of release relay 406. When the receiver is replaced at the called station after the conversation, the Current flow in conductors 421 and 422 is reversed back to normal, after which current flow is reversed in impedance 413 and the upper winding of the electro relay. polarized 409.

   When this occurs, relay 409 returns to normal but relay 410 remains latched. Relay 404 returns to normal and reverses the flow of current through conductors 401 and 403 back to normal direction, restoring the incoming line to the conditions existing before the call was answered.



   Note that the vacuum tube 411 does not play a role in the operation of the receiver after the call is answered because the relay 410 turns off the filament of this tube and keeps it off until the connection. be released.



   When the receiver is replaced at the calling station and the flow of current ceases in conductors 401 and 403, line relay 405 drops out and opens the circuit of the release release relay $ ente 406. Relay 406 drops and opens the bridge between the conductors 421 and 422 at its lower frame to allow the communication established by means of the following automatic switches to be released, and at its upper frame it removes the. ground potential of the release junction conductor 402 to allow the repeater to be released by the automatic switch which took it in service.



   Some points relating to the operation of the

 <Desc / Clms Page number 30>

 several circuits shown in the drawing will now be explained in more detail.



   Turning first to Figure 1, it should be noted that the lower coil of relay 107 is included in the line circuit between the negative pole of the desktop battery and the grid of vacuum tube 121.



  When the break occurs at the calling station, the lower winding of relay 107 tends to prolong the flow of current by means of the well-known self-induction, which momentarily makes the grid of tube 121 more positive than the earth potential. . This has the effect of rapidly establishing the flow of current in the filament-plate circuit of the vacuum tube. On the other hand, when the line circuit is closed after an interruption, due to the inductivity of the lower winding of relay 107, the flow of current is momentarily prevented by the lower winding of the relay and the potential of the grid 121 is momentarily equal to the potential of the office battery connected to the grid via resistor 123 and of the calling line conductors.

   The effect of this is to quickly reduce the flow of current through the filament-plate circuit of the tube and thus quickly terminate the pulse.



   In the repeater R1, the same condition applies and it is favored by the resistor 143 which is, connected in shunt on the upper winding of the relay 131, which makes the line circuit practically non-inductive except for the lower winding of the relay. line 131 which is connected between the grid of the tube and the earth. A similar arrangement is used in connectors C1.



   In repeater R2 of figure 3, the lower winding of relay 301 is normally shunted so as to re-

 <Desc / Clms Page number 31>

 - pull the lower inductive winding of the pulse circuit, and the upper inductive winding of relay 301 is connected between the negative pole of the office battery and the grid of the vacuum tube 311 so as to add the The selfinductive action of the winding exceeds the current fluctuations caused by the line interruptions to produce more violent fluctuations in the grid potential of the vacuum tube.

   By this arrangement, the grid of tube 311 becomes more negative when the line is cut than after the line has been cut for an instant and the grid is made more positive when the line circuit is closed after being cut than. It is not closed an instant after the line circuit is closed, causing the desired abrupt changes in the passage of the plate flow. The same arrangement is employed in the repeater R3 of figure 4.



   It should be noted that in all cases, the line circuit is balanced and that the conversation current is increased when the subscriber answers, since there is no longer any need to maintain the state. control of the cadran.
 EMI31.1
 



  R 7â V 1, ïβ I C A T I 0 I; S;
I.- An automatic switch for use in telephone or analogous systems, in which current pulses to energize the working magnet are produced in the control circuit.
 EMI31.2
 plate of a -Cermionic valve with three electrodes by potential changes applied to the gate circuit.

** ATTENTION ** end of DESC field can contain start of CLMS **.


    

Claims (1)

2. - A telephone system employing automatic switches intended to be placed under <Desc / Clms Page number 32> the effect of pulses from a subscriber dial, in which the grid of a three-electrode therminoic valve is connected to the line in such a way that the opening of the dial springs changes the potential on the grid and produces an increase in current in the plate circuit sufficient to actuate the control magnet of an automatic switch. 3. - A telephone system employing automatic switches intended to be placed in position under the effect of pulse trains, in which pulses are transmitted to the gate of a thermionic valve with three electrodes, different valves being used in successive switching stages. 4.- A telephone system employing pulse repeaters, in which incoming pulses including interruptions in a loop circuit are used to produce variations in the gate potential of a three-electrode thermionic valve in the circuit. the plate circuit of which is a relay arranged so as to produce corresponding pulses in a loop circuit extending through the outgoing line. 5. - A telephone system employing pulse repeaters, in which the incoming pulses are used to produce variations in the gate potential of a three-electrode thermionic valve whose plate circuit contains a relay responding to the pulses. , located at the far end of the trunk line exiting the repeater. 6. - A telephone system employing pulse repeaters, in which the gate of a three-electrode thermionic valve is connected to one of the incoming line conductors for the repeater, while the <Desc / Clms Page number 33> Plate circuit encloses the two outgoing line conductors, in series. 7.- A telephone system or a similar signaling system, comprising signaling operations carried out under the effect of the transmission of pulses, in which each pulse initiated from the point of transmission changes the gate potential of a thermionic valve, the plate circuit of which contains a slow relay which is intended to remain energized until a longer pause than that usually occurring between successive pulses. 8.- A telephone system according to claims 2, 3, 4,5, 6 or 7, in which the grid is connected to a terminal of the office battery in a closed circuit also containing a high resistance, and the variations Required potential are produced by breaking the direct connection between the grid and the battery. 9. A telephone system according to claim 8, in which the grid is normally maintained substantially at the potential of the desktop battery while the variation is to return the grid substantially to the ground potential. 10.- A telephone system according to claim 8, in which the grid is normally maintained substantially at earth potential, while the variation consists in bringing it substantially to the potential of the office battery. 11.- A telephone system according to claims 9 or 10, in which during the conversation the high resistance through which the grid is connected to the. earth, is short-circuited to improve the conversation characteristics. 12.- A telephone system following the sells! - <Desc / Clms Page number 34> 'cations 2, 3, 4, 5, 6 or 7, in which the socket in service of the apparatus completes a circuit passing through the calling loop for a relay which then effects the ignition of the filament of the valve . 13. A telephone system according to claim 12, in which when the switch has been fully turned on, the circuit for the valve filament is open. 14. A telephone system according to claim 12, in which during the interruption of the loop to effect transmission of pulses the relay is kept energized by means of a second winding in a local circuit. 15. A telephone system according to claim 14, in which the latch circuit is intended to be opened as a result of the operation of the magnet. 16. A telephone system according to claim 3, in which a valve is permanently associated with a particular switch. 17. A telephone system according to claims 5 and 6, in which after the impulse transmission is completed, the bridge between the conversation conductors comprising the valve plate circuit is replaced by a metal bridge having appropriate characteristics for the transmission of the conversation. 18.- A telephone system according to claims 5 and 6, in which the current source is located at the far end of the trunk line and under the effect of a reversal of the connection of this source. with the line conductors, the flow of current in the plate circuit of the valve is interrupted, which allows the de-energization of a relay located in this circuit at the output end, and as a result a polarized relay is <Desc / Clms Page number 35> connects to the line circuit and functions to produce the talk conditions. 19. A telephone system according to claims 1 to 18, in which the change in potential of the grill as a result of the opening of the loop serves to prevent the flow of current through the plate circuit. 20. - A telephone system according to claims 1 to 7, in which current only flows through the valve plate circuit when the grill potential is changed as a result of the loop being interrupted. 21.- A telephone system in substance as described and shown in the accompanying drawings. 22. - An automatic switch, in substance as described and shown in the accompanying drawings.