BE427716A - - Google Patents

Description

       

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  "PREFECTIONATIONS TO TELEPHONE SYSTEMS"
The present invention relates to telephone systems and relates more particularly to certain arrangements having the object of improving the intelligibility of conversations transmitted in automatic telephone systems.



   In these systems, the calls are transmitted through switch wipers and relay contacts which in all systems are exposed to more or less vibrate: When the contacts transmit noticeable currents, such as currents microphone supply or holding currents, for supervision purposes or

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 release, the mechanical vibrations give rise, in the subscribers' receivers, to unpleasant crackling noises, because the vibrations vary the resistance of the contacts and, consequently, the intensity of the currents which pass through them.

   It has been shown, by tests and experiments, that the variations in resistance depend on the intensity of the current, so that with large currents there are considerable variations in resistance, while these variations are small for weak currents.



   In addition, the sections of lines in which no intense currents, such as supervision or microphones supply currents, pass through the wipers of the switches and the contacts of the relays, but only currents. weak in conversation, the unpleasant phenomenon of "fading" appears. Fading occurs due to contact resistance; it sometimes becomes considerable and frequently it almost reaches the total cut.



  The physical cause of this phenomenon has not been fully explained in a satisfactory manner. However, it is assumed that the smaller vibration effect decreases the specific contact pressure, for example at switch wipers, to a value such that the perfectly polished surface at the contact points constitutes an insulating layer. In addition, the accumulation of dust, oil and humidity on contact promotes the phenomenon. It is known that the insulating layer which is thus produced is broken by the application of a so-called breakdown potential of the order of 1-60 volts.



  In known arrangements, in order to apply a potential to the contacts, the devices such as the capacitors which oppose the passage of a direct current, are shunted by high resistances.



   Although the high resistances are now

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 used on a large scale, it has not yet been possible to suppress either of these effects, namely crackling noises and fading. The invention follows from the remark that the known means for neutralizing the disorders have not been used to a sufficient extent in all points or there is a potential liable to present the aforementioned dangers.

   In accordance with the invention, the currents likely by their variations to harm the intelligibility of the conversations are not all transmitted.
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 ".lU ;;} g,; i :,,:) $ ': l:": .. $, t: .... :: ". J ... .. $ ,,' \." " '{:. ::.; \ ..,', .. '.,: \' t, '.', '"' - no contacts sensitive to mechanical vibrations, or by auxiliary lines, while all ex- subjected to mechanical vibrations are subjected to a potential high enough to break the insulating layer produced at the contacts by the phenomenon of fading.



   The diagrams of the accompanying drawings represent, by way of example only, forms of application of the invention.



   Figure 1 shows a circuit arrangement which indicates how the microphone or battery power is provided for two subscriber stations in conversation. The application of the battery supply no longer takes place, as in the known arrangements, from the first group selector, for the calling subscriber, and from the final selector, for the called subscriber; the subscriber stations are here supplied by supply bridges associated individually with the subscriber lines, while the wipers of the preselectors and final selectors are isolated by means of capacitors. The power supply bridge relays are designated by R in the diagrams.

   As can be seen in the drawings, the current at the breakdown potential passes separately through a wire of the connection line of one of the poles of the supply battery of one of the subscribers to the opposite pole.

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 corresponding to the supply battery of the other subscriber, the capacitors being shunted by high resistances.



  The signaling and supervision circuits which are necessary for the transmission of the pulses and of the supervision or release signals, are not shown in the diagram.



   The circuits must, of course, be so arranged that, while the conversation connections are made, only the conversation currents and the currents at breakdown potential pass through the rubbers of the switches and the contacts of the relays which are in contact with them. circuit. Figures 2-10 show the solutions to this problem and show the improved arrangement used for the battery supply of the subscriber stations.



   Figures 2 and 3 show an arrangement in which the transmission of the pulses and of the supervising or clearing signal of the calling subscriber is controlled by a special auxiliary wire passing between the first preselector and the first group selector. In opposition to this arrangement, the supervision signal is transmitted by the called subscriber by the test leads. The figure shows the first VW1 preselector, a first group selector GW1 and a combined LW1 selector for local and long distance service.



   The operating mode of this arrangement is as follows: When the calling subscriber Tnl picks up his receiver, the supply relay Rvl is energized by the subscriber loop: Earth, winding 11 of the Rvl relay, the conductor b, the closed loop of subscriber Tnl, conductor a, winding I of relay Rvl, battery and earth. On contact 1rv1, the following circuit is completed by the preselector rotation electro: earth, switch Ru, Dvl rotation electro, 3pvl contacts, and

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 lrvl, preselector e wiper in zero position, battery and earth. The preselector begins to rotate. After it has left the zero position, the circuit of the rotation eletro is maintained by the wiper and the continuous contact segment.

   When the switch has found a free line, the following test circuit is closed: earth, battery, preselector e wiper, contact segment, lrvl contact, Pv1 relay coils II and I, preselector c wiper, Cgl relay coil of the first group selector, the winding of the Zgl relay, contact open after the first step, called off-normal contact, 24kgl and earth. In the preselector, the Pvl test relay is energized and, by opening the 3pvl contact, the switch stops. The high resistance winding II of Pv1 is shorted to the 2pvl contact and the line is guarded against a new outlet. Contacts 5pvl and 6pvl switch the two conversation threads to the first group selector.



   In the first group selector GW1 the connection relay Cgl and the relay 2g1 are energized in series, and the relay Zgl, at the contact Z9zgl, completes a circuit to transmit the transmission signal to the calling subscriber. This circuit passes through: earth, transformer AZ, contact 30wgl open after the first step of rotation, called off-normal, contact 29zg1, winding II of the Agl relay and, from there, return to the calling subscriber. The Cgl relay closes a hold circuit for itself at contact 25cg1 so that it is kept energized after the first step of the switch rising. Furthermore, the relay Cg1 closes its contact 20cg1 and thus prepares the pulse circuit for the pulse receiving relay Agl.



   When the calling subscriber dials his number, the subscriber circuit loop is alternately

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 open and closed. Each time the loop is interrupted, the Rvl feeder bridge relay of the calling subscriber drops out temporarily. When relay Rvl drops, the following pulse circuit is closed: earth, resistance Wil, contacts 9pvl and 8rvl, wiper d of the first preselector, wire d, contact 20cgl, winding I and II of relay Vgl, winding I of Agl relay, battery and earth. The Agl relay transmits the pulses to the ascension electro (not shown) of the first group selector and the switch is brought to the stage corresponding to the number of pulses of the train.

   At the first pulse, the relay Vgl is excited in series with the relay Agl and is maintained during the pulse since it acts as a slow relay due to the short-circuit through its winding I to the contact 21 vgl. At the end of the pulse train, the Agl and Vgl relays drop out and the Vgl relay closes an automatic interrupting and closing circuit for the rotation elec- tro (not shown). The switch searches for a free line at the level where it is is found, thanks to the interaction between the contact 28dgl, which acts when the electro of rotation operates, and the relay Agl which opens the circuit of said electro.

   When the switch has found a free line, the following test circuit is closed: earth, contact 41cgl, windings II and I of the Pg1 relay, trotter c of the first group selector, winding I of the Owl relay, off-normal contact 63kwl, battery and earth. The test relay in the group selector causes the switch to stop, the high resistance winding II of the Pgl relay is shorted to the 40pgl horn and the selected line is held against another outlet. The two conversation wires are switched by closing the 37pgl and 38pgl contacts.



  In the final selector Lwl, the control relay

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 Owl connection energizes and closes a holding circuit for itself at contact 62cw1 by which it maintains itself after off-nonnal contact 63cw1 has opened, after the first step of the switch ascending. The control pulses of the final selector, which are emitted by the calling subscriber, are transmitted from the first group selector to the relay receiving the impulse from the final selector, by the following circuit: earth, contacts 34agl, 37pgl, wiper a of the first group selector, contact 66pwl, winding I of relay Aw1, contact 67bwl, battery and earth.



  The Awl relay is subjected to the pulses and transmits them to the ascending electro of the final selector, in the usual manner.



  The switch is brought to the stage corresponding to the pulses and, at the end of this train of pulses, the pulse circuit is directed towards the electro of rotation of the final selector, in the known manner, to using the two slow relays VW1 and UW1. The final selector is then caused to turn step by step on the selected floor until it reaches the line of the requested subscriber. After stopping the switch, the relays Vwl and Uwl, which are delayed, drop successively.

   The following test circuit is thus closed: earth, contacts 83owl, 82uwl and 80vw1, windings II and I of relay Pw1, winding II of relay Cw1, wiper c of the final selector, contact 4rvl, wiper c of the preselector in the normal position, windings I and II of the Pvl relay, trotter e of the preselector in the normal position, battery and earth. In this circuit, the two test relays Pw1 of the final selector and Pvl of the preselector are energized. The Pwl relay, in the final selector, opens the stepping rotation movement circuit (not shown) and, by closing the 79pwl contact, the high resistance winding of the test relay is short-circuited and the line occupied is kept.

   The Pw1 relay then closes the following circuit for

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 the Awl relay: earth, 65pwl contact, winding I of the Awl relay, 67bwl contact, battery and earth. The Awl and Pvl relays complete a circuit, for the Vw1 relay, which is not shown and which, at this stage of the connections, acts as a bell relay. The relay Pw1 also cuts the circuit for winding I of relay Cw1, at coiii, August 60pwl. However, relay Cw1 maintains its winding II, which is in series with test relay Pwl, in the test circuit.

   The Bwl relay is energized by the 61pwl contact through the test conductor of the first group selector: earth, 40pgl contact, winding I of the Pgl relay, wiper c of the first group selector, winding I of the Bwl relay, contact 61pwl, 62cwl , resistance W18 battery and earth. The relay Bw1 closes its 64bwl contact and thus locks on the test circuit independently of the Pwl and Cwi relays. In addition, the Bwi relay is used to open the circuit of the rotation electro and the switches, through the conversation conductors, at the contacts 75bwi and 76bwi.



   The ringing current to the called subscriber passes through the following path: earth, ringing RM, contacts 74vwl and 75bw1,: wiper a of the final selector, the. closed loop at subscriber station Tn2, final selector switch b, contacts 76bw1 and 72vwl and earth. When the called subscriber answers, his feeder bridge relay 1Rv1 is energized by the closed loop. Relay 1Rv1 opens the test circuit in the preselector of the called party, via opening contact 4rvl. As a result, the test relay Pwl falls back into the final selector LW1. The Cwl relay, in series with this test relay, also drops out.

   The test relay, in the preselector of the called party, is then maintained, on the other hand, by the following local circuit: earth, resistance

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 wil,, contacts 9pvl and 7rvl, preselector wiper c in normal position, Pvl relay windings I and II, preselector e wiper in normal position, battery and earth.



   In the final selector, the Awl relay releases after releasing the Pwl relay. Releasing the relays Pw1 and Cw1 also interrupts the circuit for the bell connection relay Vwl. After releasing relay Pwl, an earth is put to conductor a through: earth, contact 68bwl, winding I of relay Awl, contact 66pwl, and conductor a, as a signal indicating that the called subscriber has answered. After relay Cw1 has been released, a counting potential is applied to the conductor. b by: battery, winding II of the Awl relay, 69bwl and 70owl contacts and the conductor b.



   The two subscribers can then talk to each other and, when at the end of the conversation, the called subscriber hangs up his receiver, his supply bridge relay is released.



  Releasing relay Rvl switches the test lead to the final selector via contacts 4rvl.



  By this circuit on the one hand, the test relay Pvl is maintained in the preselector of the called subscriber, and, on the other hand, the test relay Pwl, in the final selector, is energized in this circuit by: earth, battery, pre-selector switch e, Pvl relay windings I and II, preselector switch c contact, 4rvl contact, final selector switch c, 77cwl contact, Pwl relay winding I, 78bwl contact and earth. It is not possible, for relay Cw1, to be energized by its winding II in series with the test relay, because this winding is finally short-circuited by contact 77cwl when the relay is released.

   The Pwl relay in the final selector removes the earth from conductor a by opening contact 66pwl.

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  By this means, in a long distance transmission, the called subscriber's supervision or release signal is indicated to the long distance operator table.



   If, now, the calling subscriber also hangs up his receiver, his 4vl supply bridge relay is released in the same way. After the Rvl relay has been released, the following circuit is completed, for the Agl relay, in the first group selector Gwl: earth, resistance Wil, contacts 9pvl and 8rvl, wiper d of the preselector vwl, contact 20ogl, windings I and II of the Vgl relay, coil I of the Agl relay, battery and earth. The Agl relay energizes for an extended period in this circuit.



  At contact 22agl, the connection relay Cg1 is short-circuited for an equivalent period and ceases to be energized.



  Before that is so however, the appeal is counted. A long earth pulse is transmitted to the final selector LW1 by the conductor a, when contact 34agl closes, when the relay Ag1 energizes, which determines various switchings in the final selector so that , in the case of local traffic, the earth potential is again applied to the conductor a.

   Due to this potential, winding III of relay Pgl of the first group selector is energized so that relay Pgl is not released although its winding I has been short-circuited by relay Cgl, to contact 39cg1. The connection to the following switch is maintained by: earth, contacts 40pgl and 39cgl and the connection to the previous preselector by the earth contact 26pgl and resistors Wi2 and Wi3.



  After the Cg1 relay has been released, the Zgl counting relay is energized by: earth, winding II of 2gl, contacts 36cgl and 38pgl, group selector switch b, contacts 70 cw1 and 69bwl, winding II of relay Aw1, battery and earth. The Zgl relay of the first group selector

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 gets excited and, by closing its contact 27zgl, short-circuits the resistor Wi2 and, thereby, increases the current through the conductor c, whereby the counter ZV1, in the preselector of the calling subscriber, is energized . The Zgl relay short-circuits the winding III of the Pgl relay, to the 33zgl contact, so that the Pgl relay is released.

   As a result, both the calling subscriber's pre-selector connection circuit and the final selector test circuit are broken. In the VW1 preselector, the Pvl relay is released. The selector rotates step by step until it has reached the normal position by means of its e wiper, the contact segment and the 3pv1 contact.



   By switching off the test lead from the first group selector, the Bwl relay in the final selector is released. Relay Bwl first opens the test circuit to the called party preselector at contact 78bwl. Furthermore, it disconnects the counting potential of the conductor b at the same time as, by opening the contacts 75bwl and 76bwl, it disconnects the two conversation lines; finally it completes a circuit (not shown) for the final selector rotation electro which is thus returned to the normal or rest position.

   When the called party preselector test circuit is open, the Pwl test relay in the final selector also releases as does the Pvl test relay in the called party preselector.



   In order to be complete, it will now be mentioned that the final selector LW1 is also designed for the interurban service. Has the establishment of long distance calls which, to. in the normal way, are produced by a trunk group selector which is multiplied to the first group selector GW1, it is possible, in case the desired subscriber is engaged in a local call, to establish a connection with the line engaged by means of relay BW1. This connection

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 is carried out by the application of a potential to the conductor b, to the trunk table, whereby the following circuit is completed: source of potential applied to the conductor b at the position of trunk operator, contact 71cw1, winding II of the Bwl relay and earth.

   Chat connection is completed to contacts 75bw1 and 76bwl. Permanent energization of relay Bwl, after the connection pulse on busy line is terminated, is prevented because, after closing contact 64bwl, winding I of this relay is arranged in a branch circuit in parallel with the Owl connection relay via a resistor Wi8 and 62cwl and 50pw1 contacts (the Pwl relay is not yet energized) and in which circuit, the winding I of the Bwl relay does not receive sufficient current to keep its frame attracted. In addition, the winding I of the relay Bwl is arranged in counter-winding with respect to the winding II.



   The circuit, for the current at the breakdown potential of the insulating film of the contacts, passes separately through the two conversation wires, i.e. from earth in the final selector, through contact 68bwl, winding 1 of relay Awl, contact 66pwl and the conductor has, in both directions, at the potential of the two supply batteries.



  The breakdown potential current, for conductor b, passes through: earth, battery, winding II of relay Aw1, contacts 69bwl and 70cwl in both directions to the earth pole of the supply batteries of the two subscribers. The capacitors arranged on the conversation wires are shunted by high resistances in the usual manner.



   Figures 4 and 5 show another embodiment of the invention. The first preselector is designated as Vw2 and the first group selector is designated as GW2. The final selector used is the selector

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 final LW1 shown in figure 3. In this form of implementation, as opposed to the. 'previous,' any separate auxiliary conductor, between the first preselector in the first group selector, is deleted. The transmission of the pulses as well as that of the supervisory signal of the calling subscriber takes place, in this case, from the preselector to the group selector, by means of an alternating current, such as a current of ringtone for example.

   The signals are received in the first group selector by an AC relay connected in parallel on the conversation conductors and protected against DC currents by capacitors. The two subscribers are supplied, as in all embodiments of the invention, by supply bridges individually associated with the subscriber lines.



  By virtue of this arrangement, the sections of the connection circuit containing the relay and switch contacts which are exposed to vibrations are withdrawn from intense currents such as supply currents or supervisory currents.



   The operating mode of this arrangement is as follows: When the calling subscriber picks up his receiver, his supply bridge relay Rv2 is energized by the closed subscriber loop. The preselector rotation electro is energized by the 12rv2 contact and acts to find a free line when the Pv2 test relay is energized by the test wiper o of the preselector and the connection relay # Cg2 of the first group selector , which is also placed in the test circuit, is energized by: earth, battery, wiper d of the VW2 selector, the contact segment, the 12rv2 contact, windings II and I of the Pv2 relay, the wiper c of the VW2 preselector , the winding of relay Cg2, the winding of relay Zg2, off-normal contact 25kg2 and earth.

   The Pv2 relay, in the preselector, brings the

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 preselector at rest and switches the conversation conductors through the group selector.



   Relay Cg2, in group selector GW2, establishes, through the conductor of a, at contact 20c2 and at contact 26cg2, a holding circuit for itself which is independent of the off-normal contact. Finally, by closing contact 40cg2 and opening contact 38cg2, the final selector test circuit is prepared.



   When the calling subscriber dials the desired number, his power supply bridge relay Rv2 drops out in synchronism with the pulses, and each time he drops, an alternating current is applied to the conversation wires and the pulse receiving relay Jg2, at the first group selector, is energized by: earth, resistance Wi5, contacts 4rv2, and 9pv2, pre-selector friction b, alternating current relay Jg2, contact 20eg2, contactor c of the preselector, 8pv2 and lrv2 contacts, WQ alternating current source and earth. Relay Jg2 in group selector GW2 is energized correspondingly to these pulses and repeats them to relay Ag2 by: earth, windings I and II of relay Vg2, contacts 28ig2, winding I of relay Ag2, battery and earth.



  In this circuit, the relays Vg2 and A g2 are energized. Relay Vg2 short-circuits its winding in the usual way by its contact 27vg2 and, consequently, acts as a slow relay and is maintained during the whole pulse train. The Ag2 relay repeats the pulses to the ascent electro of the group selector. At the end of this pulse train, the Vg2 relay is released and connects the rotation electro of the group selector. The selector turns on the stage which has been selected and, as soon as it has found a free line, the test relay Pg2 is energized by: contact 40cg2, windings I and II of relay Pg2, wiper c of the selector

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 of groups, winding I of the Owl relay, the off-normal contact 63kwl, the battery and the earth.

   In the test circuit, the connection relay Cw1 of the final selector is also energized.



   Subsequent switchings are carried out in the manner already described for the previous embodiment.



   The off-hook and on-hook supervision signals are monitored through the test lead between the called party's preselector and the final selector.



   When, at the end of a call, the calling party hangs up, its feeder bridge relay Rv2 is released.



  The conversation conductors between the calling subscriber and the first group selector are cut by the opening of contacts 2rv2 and 3rv2. AC current is supplied to the line conductors of the first group selector GW2 through contacts 1rv1 and 4rv2. The alternating current relay Jg2 energizes for a prolonged period of time and short-circuits the connection relay Cg2, through its contacts 24ag2, for a corresponding time. The relay Cg2 is released. After the counting has been carried out as described in the previous example, the first group selector is released and, thereby, the first preselector is also released, in the final selector.



   FIGS. 6 and 7 show a third form of implementation of the invention with the establishment of a connection comprising a first preselector VW2, a first group selector GW3 and a local and final selector LW3 for long distance communications. This realization is similar to the previous one in that any separate auxiliary conductor, to emit the pulses and to operate the supervision of the calling subscriber, between the first pre-selector and the first group selector, is eliminated,

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 In this arrangement, the pulses and supervision of the called subscriber are also effected by the conversation conductors but not by means of alternating current and relays receiving alternating current;

   uses the charging and discharging currents of capacitors by means of which polarized relays are actuated, in branch on the line and connected in series with these capacitors. In this arrangement, all sections of the line in which the contacts are exposed to vibrations are also subtracted from the supply and supervisory currents.



   The mode of operation of this arrangement is as follows: When the calling party Tn1 picks up its receiver, the supply bridge relay Rv3 is energized by the closed subscriber loop. On contact lrv3, the Dv3 rotation electro of the preselector is actuated by: earth, bet- ter, preselector contactor d, lrv3 and 3pv3 contacts, the Dv3 rotation electro, the Ru switch and the earth.



  The preselector is set in motion and searches for a free line. As soon as this is found, the Pv3 test relay is energized by the wiper c of the preselector. The Pv3 relay turns off the switch and keeps the line safe from any other seizure. Finally, the two conversation threads are switched to the first group selector at contacts 5pv3 and 6pv3.



   In the first group selector GW3, the connection relay Cg3 is also energized at the same time as the relay Vg3 by the test circuit. Relay Vg3 connects the transmit signal to the line of the calling subscriber in a manner not shown. Relay Cg3 prepares the test circuit by closing its contact 18cg3. Relay Cg3 is maintained, via contact l5cg3, after the switch has made its first step of ascent.

   The polarized relay Jg3 is connected to the line wires by the contact 11cg3 and

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 therefore, capacitor Co3 is charged by the following circuit: earth, battery, shock coil Drv, subscriber loop contact 6pv3, wiper b of pre-reader VW3, winding I of relay Jg3 , the capacitor Co3, the contact llcg3, the wiper of the VW3 pre-reader, the contacts 5pv3 and 4rv3, the winding of the relay Rv3, and the earth. The polarized relay @ g3 is set so that it does not activate its armature under the effect of this charging pulse.

   It can be mentioned here that, beyond the polarized relay, there is a blocking circuit, in the conversation conductors, which includes two capacitors Co4, Co5 and Coti, Co7, in each conductor respectively, and a Drv2 shock coil which prevents the charge and discharge pulses from expanding.



   When the calling subscriber dials the desired number, the subscriber loop is alternately opened and closed a certain number of times. When the subscriber loop is open, the circuit for the branched relay Rv3 on the calling subscriber line is opened and, thereby, the capacitor Co3 is discharged with the discharge current flowing through the windings of the relay Jg3 in the direction of excitation of the relay. A recharging of the capacitor which could result from the release of the relay Jg3 is prevented by the opening of the conductor a, at contact 4rv3. When the subscriber loop is closed again, the Rv3 relay is energized. Contact 4rv3 closes conductor a and the capacitor is charged again. These operations are repeated alternately throughout the operation of the dial.

   When relay Jg3 activates its armature, the following circuit is closed: earth, winding II of relay Vg3, contact 19ig3, winding of relay Ag3, battery and earth. The relays Vg3 and Ag3 are energized

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 in this circuit, the relay Vg3 is maintained during the pulses because it is slow to drop. Relay Ag3 repeats the pulses to the ascent electro of the group selector. After this train of pulses, the switching circuit is transferred to the rotation electro of the group selector, via relay Vg3. The said electro of rotation acts to cause the switch to search freely for a free line.

   As soon as this line is found, the relays Pg3 and Cg3 are energized by the test circuit as follows: earth, contact 18cg3, windings II and I of the test relay Pg3, wiper c of the first group selector, winding I of the relay Cw3 in the final selector, 33cw3 contact, 30kw3 off-normal contact, battery and earth. The test relay, in the group selector, shuts down the switch in the known manner, keeps the line busy against any new seizure, and switches to the conversation lines.



   The connection relay Cw3 in the final selector LW3 opens its contact 33cw3 and closes its contact 34cw3, so that the high resistance winding II of the relay Cw3 is connected in the connection circuit. The relay stays in this circuit independently of the off-normal contact of the final selector.



   When the calling subscriber transmits the pulses to steer the final selector, his Rv3 supply bridge relay energizes and de-energizes in synchronism with the operation of the dial switch. 'Consequently, the polarized receiving relay Jg3 alternately moves its contact in the working and resting positions. As a result, the Ag3 relay is actuated in synchronism in the first group selector. The relay Ag3 transmits the pulses to the pulse receiver relay Aw3 of the final selector via the following circuit: earth, contacts 20ag3 and

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 21pg3, wiper a of the first group selector, contact 38bw3, winding I of relay Aw3, battery and earth.



  The Aw3 relay repeats the impulses to the ascent electro of the final selector, and the switch is brought to the desired stage. The last pulse train is transmitted in a similar way to the receiver relay Aw3 of the final selector. This repeats the pulses to the rotating electro and the final selector is brought step by step to the desired subscriber line.



  If the requested subscriber is free, the following test circuit is completed during the release period of a slow relay Uw3 which is not shown: earth, contacts 5low3, 52uw3 and 53vw3, windings II and I of relay Pw3, wiper c of the final selector, wiper c of the called subscriber's preselector, in the normal position, windings I and II of the iPv3 relay, wiper d of the preselector in the normal position, battery and earth. The iPv3 relay, in the pre-selector, opens its contact corresponding to the 3pv3 contact and, therefore, prevents this switch from functioning.

   The final selector Pw3 test relay drives the switch to rest, keeps the busy line against any new taps by shorting its high resistance winding II, to 46pv3 contact, and switches the talk lines to the called line through its contacts 54pw3 and 55pw3.



   In the final selector is arranged the winding I of a polarized relay Jw3, in branch on the conversation lines and in series with a capacitor Cp3. After the conversation lines have been connected to the called line, the capacitor Cp3 receives a charge pulse through the supply bridge of the called party, as follows: earth, battery, shock coil Drv, wiper a du final selector, 54pw3 contact, Cp3 capacitor, 55pw3 contact, final selector contact b contact, Rv4 relay winding to earth. Relay Jw3 is set so as not to be energized.

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 ter in response to this impulse.

   Consequently, a circuit is closed after the energization of the relay Pw3 by a coil of relay Vw3 which then serves as a bell connection relay: earth, contacts 35iw3, 58pw3 and 59bw3, relay coil Vw3, switch Lu , battery and earth. The Vw3 relay applies a ringing current to the conversation conductors through its 57vw3 and 60vw3 contacts.



   When the called subscriber answers, the subscriber loop is closed when he picks up his receiver, and the called subscriber's supply bridge relay Rv4 is energized. When the subscriber loop is closed, the potential on the line is changed and a discharge pulse results at the capacitor Cp3. In response to this discharge pulse, the Jw3 relay attracts its armature. Relay Bw3 is then energized in final selector LW3 by: earth, contact 36iw3, winding II of relay Bw3, battery and earth.



  At the same time, slow relay MW3 is energized by: earth, contact 66iw3, the winding of relay MW3, battery and earth. Relay Bw3 is locked in the following circuit: earth, winding I of relay Bw3, contacts 42bw3 and 43pw3, battery and earth. Relay Bw3 breaks the circuit for the bell connection relay, at contact 59bw3. In addition, a counting potential is applied to the conductor of b by: earth, battery, winding I of relay Aw3, contacts 39bw3 and 40pw3, and the conductor of b. Finally, for the current at the breakdown potential, a ground is applied to the conductor of a through: earth, the high resistance Ws, contact 58pw3, winding II of relay Aw3, contact 37bw3 and the conductor of A.



   The two subscribers can then converse together.



  When the called party hangs up its receiver at the end of the call, the circuit for the called subscriber's Rv4 feeder bridge relay is cut. The cut-off pulse

 <Desc / Clms Page number 21>

 acts to reverse the polarity of capacitor Cp3 in the final selector. The load pulse is in such a direction that relay Jw3 returns its contact to rest and closes contact 35iw3.

   A counter-pulse which, due to the neutralization of the magnetic field of the Jw3 relay, could bring the annulus of the relay back to the working position, is prevented because, after the armature of the Jw3 relay has been reset - led at rest, the following circuit, for a second winding of relay Jw3, is completed by contact 60mw3: earth, contacts 35iw3 and 60nlw3 winding II of relay Jw3, off-nromal contact 31kw3, battery and earth. The second coil of the relay is arranged so that it maintains the armature of the polarized relay in the rest position. The holding circuit for winding II of relay Jw3 remains closed until relay MW3 has been released, the counter pulse being switched off at this time.

   The direct connection of the earth to the conductor has, after the called party has hung up its receiver, through contacts 35iw3, 58pw3, winding II of relay Aw3 and contact 37bw3, gives the release signal to the trunk table in the long distance calls.



   When the calling party also hangs up its receiver, its supply bridge relay Rv3 is released, which has the effect of inverting the potential on the line and producing a discharge pulse at the capacitor Co3 of the first selector of group GW3. Relay Jg3 consequently closes contact 19iw3. The Ag3 relay, in the first group selector, is energized for an extended period and short-circuits the connection relay Cg3 for a corresponding period, through its contact 13ag3. The Cg3 relay is released and, by opening its contact 15og3, it initiates the release of the VW3 preselector of the calling subscriber. By short-circuiting winding I of test relay Pg3,

 <Desc / Clms Page number 22>

 at contact 61cg3, this relay de-energizes to open the test circuit at the final selector, at contact 62pg3.

   In the final selector, the occupancy relay Cw3 is thereby released and, by opening its contact 51cw3, releases the test relay Pw3 which, when released, releases the final selector.



   Long distance calls can also be made using the LW3 selector. These calls pass from the trunk table, in the usual manner, through a multiple trunk group selector with the first group selector. The switching operations to bring the final selector to the called subscriber line are the same as for a local call. If the called subscriber is engaged in a local call, the trunk operator can be connected to the engaged line by applying to the city table a potential to conductor b, whereby the relay Bw3 of the final selector is energized in the following circuit: source of potential applied to conductor b at the interurban operator position, contact 41pw3, winding I of relay Bw3 and earth.

   The attendant is connected to the busy subscriber, ¯ by contacts 48bw3 and 49bw3. The operator is then in a position to cut the established local connection, by applying an earth to the conductor a after having established the connection with the subscriber engaged and having thereby energized the Jw3 relay: earth on the conductor a , contact 38bw3, winding I of relay Aw3, battery and earth.



  The Aw3 relay directly connects the earth to the conversation conductors, on the one hand, through contacts 46aw3 and 47aw3 and, on the other hand, connects the earth through the 50aw3 contact and a low resistance relay T3 to the test conductor of the subscriber called. If the called subscriber is the calling subscriber in the local call in progress, the capacitor Co3 is discharged by the earth connected to the conductors a and B. Same

 <Desc / Clms Page number 23>

 time, the Rv4 power bridge relay releases. Relay Jg3 of the first group selector acts and energizes relay Ag3, for a prolonged period, by contact 19ig3. Relay Ag3 short-circuits relay Cg3 which becomes free and initiates the release of the local call in progress.

   The
 EMI23.1
 ¯ ï; ¯ -S5 ;;. $; r: ¯ ¯:.:.:,: ¯ ......;.:: ¯ ....; "" "" $ ..........- 1: .. :: - '; 1. $ ...........: '...- bearing: earth, contacts 23cg3, 24ag3, winding II of relay Jg3, battery and earth.



   If the desired subscriber for the long distance call is the called subscriber in the current local call, the Pw3 test relay of the final selector in the local connection is short-circuited by the application of an earth by the contact 50aw3 in the final selector occupied by the auxiliary operator. This relay is released and produces the disconnection of the local call.



   It should be mentioned here that the release of the local call by the trunk table can of course be introduced in other embodiments of the invention, in a manner similar to that described in the present embodiment. Thus, in the embodiment shown in Figures 2 and 3, the supply bridge relay, for the subscriber engaged in a local call, is de-energized, and the release of the first occupied group selector in the local call is produced by the driver d.



   Figures 8 and 9 show another embodiment of the invention. The first preselector is designated by VW4 and the first group selector by GW4. Only those parts of the auxiliary and local final selector indicated at LW4 which relate to the invention have been shown. The two subscribers are supplied, as in all embodiments, by supply bridges associated with the subscriber lines. The pulse and supervision signals of the calling subscriber are transmitted on the two conductors

 <Desc / Clms Page number 24>

 the line by direct current, while the called subscriber's supervision signal is transmitted through one of the two conversation conductors.

   All the sections of the line which have contacts exposed to vibrations are protected against disturbing currents by the presence of special capacitors Cvl, Cv2, Cv3 and Cv4, between the subscriber supply bridges and the switch multiplication.



   The operating mode of this arrangement is as follows: When the calling subscriber picks up his receiver, his supply bridge relay Rv4 is energized. The preselector rotation electro is energized by the lrv4 contact and the preselector is put into action to search for a free line. When this line has been found, the Pv4 test relay of the preselector and the Cg4 connection relay of the first group selector are energized by the test circuit.



  In this circuit, the relay Vg4 is energized in series with the relay Cg4 and transmits the transmission signal to the calling subscriber. In addition, the Ag4 pulse receiving relay is connected to conductor a through contacts 13cg4 and 12vg4.



   When the calling party dials their number, the Rv4 power bridge relay releases in synchronism with the operation of the dial switch.



  Consequently, the following circuit is completed for the pulse receiving relay Ag4 of the first group selector: earth, coil of relay Ag4, contacts 13cg4 and 12vg4, wiper a of the first preselector, contacts 2pv4, 5rv4 and 3pv4, wiper b of the first preselector, windings I and II of relay Vg4, battery and earth. In this circuit, the relays Av4 and Vg4 are energized. Relay Vg4 is maintained throughout the duration of the pulse train.



  The Av4 relay repeats the pulses from the ascension electro to the group selector. After this train of pulses, the

 <Desc / Clms Page number 25>

 switch turns freely and searches for a free line.



  When a free league has been found, the Pg4 test relay energizes in the first group selector as well as the Cw4 connection relay in the final selector. The Cw4 relay prepares the orientation circuit as well as the test circuit.



   Subsequent pulse trains from the calling subscriber are received by relay Ag4 and are sent as earth pulses, through contact 10ag4, to the final selector. The final selector LW4 is brought to a certain level and rotated step by step. If the final selector LW4 finds the line of the desired subscriber, the following test circuit is completed: earth, contacts 29cw4, 21uw4 and 22vw4, the windings of the test relay Pw4, wiper c of the final selector, wiper c of the VW4 preselector in the normal position, the windings of the Pv4 test relay, wiper d of the VW4 preselector in 1 a normal position, battery and earth. Both test relays energize in this circuit. The final selector test relay performs its usual functions.

   The Pv4 test relay in the pre-selector of the called subscriber applies earth to the conductor b leading to the final selector, whereby an Xw4 relay, in the final selector, is energized by: earth, friction a of the Vw4 preselector in the normal position, contacts 2pv4, 5rv4 and 3pv4, wiper b of the vw4 preselector in the normal position, trotter b of the LW4 final selector, the winding of the Xw4 relay, the battery and the earth.



  The Xw4 relay applies the earth directly to the conductor a via the 24xw4 and 25pw4 contacts which indicate, to the trunk table, the end of the selection operation.



   When the called subscriber answers, his feeder bridge relay energizes. By opening contact 5rv4, earth is disconnected from the conductor from b to the final selector.

 <Desc / Clms Page number 26>

 



  The Xw4 relay is released and, as a result, the earth is again disconnected from the a conductor, at contact 24xw4, which signals to the trunk table that the called party has answered. Earth is applied to the conductor a through the 25pw4 contact and the high resistance Ws in order to destroy any insulating layer that may have formed on the contacts.



   When the called subscriber hangs up at the end of the conversation, his feeder bridge relay Rv4 is released due to the interruption of the loop. Earth is reapplied to conductor b of the final selector via contact 5rv4. The Xw4 relay energizes again and gives the release signal to the trunk table.



   When the calling subscriber also hangs up, his Rv4 feeder bridge relay is released. A loop is consequently established in the first group selector, in the manner already described, by: earth, the winding of the relay Ag4, contacts 13cg4, and llpg4, froi, tor a of the preselector VW4, contacts 2pv4, 5rv4 and 3pv4, wiper b of the first pre-selector, windings I and II of the battery relay and the earth. The relays Ag4 and Vg4, in the first group selector, are energized in this circuit. Releis Ag4 short-circuits releis Cg4 by contact 15ag4 so that relay Cg4 is released and causes the release of all the switches at the strap which has been described previously.



   Fig. 10 shows details of another embodiment of the invention, namely the circuit of a call finder serving as a preselector device.



   The battery supply is again performed by a supply bridge Rs individually associated with the subscriber line. In addition, a relay Ts is associated with each subscriber line. When the calling subscriber picks up his receiver

 <Desc / Clms Page number 27>

 tor, the supply bridge relay Rs is energized. A start-up relay is actuated, in the known manner, by an lrs contact and puts the call finder into action and, moreover, the Rs relay prepares the test circuit by closing the 3rs contact. When the call seeker has found the calling line, its test relay Ps is energized in the following circuit: earth, windings I and II of the relay Ps, wiper c of the call seeker, contacts 2ts and 3rs, winding I of the Ts relay, battery and earth.



  The Ps and Ts relays are energized in this circuit, The Ps relay stops the call finder and switches the line to the first group selector. The Ts relay is locked in the following circuit: earth, contacts 4ts and 5rs, winding II of relay Ts, battery and earth. After the relay Ts has been energized, the test circuit is broken at contact 25s. However, the call finder test relay Ps remains in the following local circuit: earth, 7ps contact, low resistance winding II of the Ps test relay, 6ps contact, Wi resistance, battery and earth. Another call seeker is thereby prevented from performing a test on the calling line, as is an end selector.



   When the calling subscriber who made a local call by call searcher As, is requested by a long distance call, earth is applied to conductor c in the final selector which is activated by the interurban operator on the subscriber line. This connection has been shown as being made by an ignition key Fa in the figure, for simplicity. If the long distance operator wishes to interrupt the local connection, the call searcher test relay Ps is short-circuited by: earth, ignition key Fa, contact 8ts, call searcher contactor c, coil II of the relay test Ps, contact 7ps and the

 <Desc / Clms Page number 28>

 Earth. The relay Ps is released and produces the release of the call seeker, and subsequently, of the subscriber requested by the long distance table.



   CLAIMS
1 - A telephone system provided with arrangements to prevent a reduction in the intelligibility of the conversations transmitted, due to an increase in the resistance of the surfaces of the contacts through which the conversation currents pass, in which the reduction in intelligibility system gibility due to the increase in resistance produced by the vibrations of the contacts is prevented by locating, in those sections of the line which do not have such con- tacts, the intense currents such as those which are used to produce the currents of powering the microphones, and wherein the decrease in intelligibility which results from the gradual increase in resistance to the contact surfaces is avoided by applying to the surfaces a potential of value such that the insulating layer formed on these surfaces is broken.

   



   2 - A telephone system in which the supply relays for the subscriber's microphones are provided individually on the subscriber lines, and are placed between the multiplication of the banks of the first switches in the office and the terminals of the subscriber lines in the office.


    

Claims (1)

3 - A telephone system according to claim 1 wherein the battery supply relays are individual to each subscriber line. 4. A telephone system according to claim 1 or claim 3, wherein the guidance pulses and the supervisory signal of the calling party <Desc / Clms Page number 29> are transmitted to the first group selector by an additional driver. 5 - A telephone system according to claim 3 in which the supervisory signal of the called party is transmitted by the test leads which extend between the selector and the preselector, under the control of a group of relay . 6 - A telephone system according to claim 5 in which an auxiliary relay connected in parallel with the connection relay of the final selector is energized by the operation of the test relay, and is maintained independently of the test relay. 7 - A telephone system according to claim 6 in which the auxiliary relay, after being energized, acts to effect the switching to the conversation conduc- tors and to keep the called line. 8 - A telephone system according to claim 6 in which the final selector test relay is energized when the called line is free, and deenergized when the called subscriber answers. 9 - A telephone system according to claim 8 in which the test circuit between the final selector and the preselector of the calling party is opened by a contact of the supply bridge relay of the called subscriber, when this last responds. 10. A telephone system according to claim 9 in which the test relay associated with the pre-selector of the calling subscriber is kept energized in a local circuit after the test circuit is opened. 11 - A telephone system according to claim 1 in which, at the end of a call and the release of the supply bridge relay associated with the station <Desc / Clms Page number 30> called up, the circuit established by the test lead to the final selector is closed again and the final selector test relay is re-energized for the feedback transmission of the supervision signal. 12 - A telephone system according to claim 6 in which the auxiliary relay serves as a ringing connection relay in the case of long distance calls. 13 - A telephone system according to claim 12 in which the auxiliary relay has two windings, one of which is connected to one of the conversation conductors when the final selector has been taken and is energized by a potential applied to the conversation conductor when an interurban operator wishes to obtain access to the seized line, while the second winding, which is connected in parallel with the connection relay to the potential application, receives as a result from the shunt by the occupancy relay, insufficient current to keep the relay actuated when the potential is removed. 14. A telephone system according to claim 1 or claim 3 in which the currents at breakdown potential pass separately through the conversation conductors. 15. A telephone system according to claim 6 or claim 7, in which different potentials are connected to the conversation leads, in the final selector by the auxiliary relay, after the called subscriber's line has been terminated. found free, which establishes circuits for the current of the corresponding pole breakdown potential of the current sources at the two subscribers. 16. A telephone system according to claim 1 or claim 3 wherein the pulses-, <Desc / Clms Page number 31> digital signals transmitted by the preselector of the calling party to the group selector, in the form of alternating current pulses, are stirred by an alternating current relay in shunt on the conversation conductors and comprising capacitors connected in series with them. 17 - A telephone system according to claim 16, wherein when the calling subscriber hangs up the release of the associated feed bridge relay produces transmission to the group selector of a long pulse of alternating current , by the conversation leads, whereby the release of the connection is initiated. 18. A telephone system according to claim 1 or claim 3 in which polarized receiver relays connected through the conversation conductors in series with capacitors are associated with the switches and are controlled by load pulses or discharge during digital selection and transmission of the supervisory signal by subscribers. 19 - A telephone system according to claim 18 in which the capacitor, in the first group selector, is charged by the supply battery of the calling station after the connection has been extended to the first selector. grouping but the polarity of the load pulse is not such that it can actuate the polarized receiver relay. 20. A telephone system as claimed in claim 19, in which discharge pulses are produced by interruptions of the subscriber station loop, while load pulses are produced by the closing of this loop, these various pulses alternately bringing the polarized relay of the group selector to energization and to rest. <Desc / Clms Page number 32> 21 - A telephone system according to claim 10 in which the supply bridge relay of the calling station is de-energized by interrupts in the loop and thus synchronously interrupts one of the conversation conductors which extends between the battery. power supply and the receiver relay. 22. A telephone system according to claim 20 wherein the transmission of the supervisory signal by the calling subscriber produces the operation of the receiving relay polarized for an extended period due to the discharge pulse of the resulting capacitors. from the interruption of the loop, which releases the switch. 23. A telephone system according to claim 22 wherein the polarized receiver relay is returned to idle in a local circuit by a second winding after release of the first group selector. 24 - A telephone system according to claim 18 in which a polarized supervisory relay is associated with the final selector and mounted in branch on the conversation conductors and in series with the capacitor. 25 - A telephone system according to claim 24 in which the capacitor is charged by the power source of the called station when the subscriber loop is closed, and discharged when the loop is open. 26 - A telephone system according to claim 25 in which the supervisory relay mounted in series with the capacitor is energized by the charge pulses and de-energized by the discharge pulses. 27 - A telephone system according to claim 24 in which the relay is polarized so <Desc / Clms Page number 33> that it is not actuated by the load pulse produced when the final switch switches to the supply bridge of the called subscriber. 28 - A telephone system according to claim 27 in which, when the called party answers, the capacitor is discharged due to the closing of the subscriber loop, whereby the polarized relay is actuated to connect an auxiliary relay, in the final selector, which acts to close the chat connection. 29 - A telephone circuit according to claim 28 in which, when the release signal is given by the called station, the capacitor is charged due to the interruption of the loop at the subscriber's station, thanks to whereby the polarized relay is brought to rest and a supervision signal is returned by one of its own contacts. 30 - A telephone system according to claim 29 in which the polarized relay comprises two windings the second of which returns the polarized relay to rest, by a local circuit, when the connection is released by the calling subscriber before the supervision signal has been given by the called subscriber. 31 - A telephone system according to claim 18 in which, on the application of a disconnect potential to the long distance operator position, to disconnect a local call in progress, a discharge pulse is transmitted from the capacitor , in the group selector occupied by the called subscriber, whereby the receiving relay is actuated for an extended period and releases the local connection. 32 - A telephone system according to claim 2 or the. re-greening 3 in which the dali- <Desc / Clms Page number 34> The indication individually associated with the subscriber line and connected directly to it is separated, by capacitors, from the multiplies of the switch. 33 - A telephone system according to claim 32 in which when the calling subscriber transmits pulses and the supervisory signal, a loop is established by the talk leads between the preselector and the first group selector. 34 - A telephone system according to claim 33 in which the loop which extends between the preselector and the first group selector is closed when the calling subscriber supply bridge relay is operating. 35 - A telephone system according to claim 34 in which when the final selector performs the test of the desired subscriber line a direct current circuit is completed from the preselector of the called station by one. conversation wires, for a supervisory relay in the final selector. 36 - A telephone system according to the claim EMI34.1 i0l1;: '5 1fl:. $ which 1.? .w ..; t <. :, ::,: o ;;> ùa, - "'\ 1: t: .. nu depends on the supply bridge relay so that, when the called station answers, the circuit is opened and closed again when the called station gives the release signal. 37 - A telephone system according to claim 35 in which the direct current circuit is completed through the normal position of the preselector wiper which switches through one of the conversation wires a part of this wire and the other conversation wire, and by the preselector rubbish, which switches by the other conversation wire, through the normal position of which is connected the conversation wire which ends at the final selector. <Desc / Clms Page number 35> 38. A telephone system according to claim 1 or claim 3 and employing seeker switches in which operation of the feeder bridge relay associated with the subscriber line activates the seeker switch. when a call is started, and prepares the test circuit. 39 - A telephone system according to claim 38 in which a relay associated with the subscriber line is energized by the seeker switch test circuit to open the test circuit and completes a circuit by the test lead which originates from of the final selector. 40 - A telephone system according to claim 39 in which the relay associated with the subscriber line is maintained locally by a second winding after the interruption of the test circuit. 41 - A telephone system according to claim 39 in which the seeker switch test relay is held, after the test circuit has been interrupted, by a low resistance winding connected to the test line in a local circuit, so that the test relay can be controlled by the test lead from the final selector. 42 - A telephone system according to claim 41 in which the call finder test relay is released under the control of an auxiliary operator by a potential connected to the test lead in the final selector and produces the release of connection if the called party is engaged in a local call. 43 - A telephone system in principle as described and shown in the accompanying drawings. <Desc / Clms Page number 36> SUMMARY A telephone system provided with arrangements to prevent a reduction in the intelligibility of the conversations transmitted, due to an increase in the resistance of the contact surfaces through which the conversation currents pass, in which the reduction of intelligence gibility due to the increase in resistance produced by the vibrations of the contacts is prevented by locating, in those sections of the line which do not have such contacts, the intense currents such as those used to produce the currents. microphone power supply, and wherein the decrease in intelligibility which results from the gradual increase in resistance to the contact surfaces is avoided by applying to the surfaces a potential of value such that the insulating layer formed on these surfaces is broken.