BE434985A - - Google Patents

Description

       

   <Desc / Clms Page number 1>
 



  Improvements to telephone and other systems.



   The present invention relates to signaling systems and relates more particularly to switching apparatus for use in automatic telephone systems.



   In an automatic telephone system, switching apparatus comprising a large number of connectors are required to perform the various line switching functions required in establishing the desired communications between the various lines of a system. Connectors enclosing several types of switching units or mechanisms capable of fulfilling the functions indicated above are known in the art. A /

 <Desc / Clms Page number 2>

 an improved form of switching unit which is well suited for use in the indicated application, and which has significant advantages in terms of construction characteristics and mode of operation, is developed and claimed in our patent application. N 337.598 relating thereto.



  This switching unit or mechanism is designed to be associated with a bank of conductors formed by non-insulated conductors and comprises several elementary connectors, each of them acting selectively and comprising two line selection devices which are combined to be actuated. together in order to perform the simultaneous selection of two lines of the conductor bench. Furthermore, the switching unit is constructed and arranged in such a way that it can be incorporated either in a finder or in a selector at will. The shape of the switching unit is extremely compact and small while being economical to manufacture and install.



   It is an object of the present invention to provide a signaling system and more particularly an automatic telephony system comprising several connectors enclosing switching units of the type described above and enclosing members perfected for controlling these switching units. , which mainly consist of rotary connectors of a standard type and relays combined in such a way that a minimum number of actuators is required for a system of given dimensions.



   Another object of the invention is to provide, in a system of the type described, a perfect connector.

 <Desc / Clms Page number 3>

 Line selection unit comprising a switching unit of the type described above and including improved members for controlling the operation of the switching unit.



   Another object of the invention is to provide, in an automatic telephone system, a device for selecting lines and receiving pulses comprising a switching unit of the type described above and including improved members for controlling the automatic operation. of the switching unit in order to select a free line from a small group of lines.



   Another object of the invention is also to provide, in an automatic telephony system, a pulse receiver line selection connector and improved pulse members capable of transmitting several series of pulses to the line selection connector. line in order to control its operation.



   In general, the objects indicated above are achieved according to the present invention by providing, in a telephone system, switching apparatus comprising a bank of conductors consisting of uninsulated conductors and several finder-connector circuits, each of these. link circuits comprising a finder part and a connector part, and each of the connectors, forming part of the whole unit, comprising a switching unit or mechanism of the type described above giving access to each of the lines driver's bench.

   The lines of the conductor bank are divided into several divisions, each of the divisions comprising two groups, each group

 <Desc / Clms Page number 4>

 comprising several sub-groups, at least one sub-group comprising a small group of lines, and each sub-group comprising several lines. The small group of lines of the conductor bank is intended to be connected via their own line circuits to P.B.X.lines. connected as private lines to a public office; while the other lines of the conductor bank are designed to be connected by line circuits which are specific to them to subscriber lines leading to subscriber stations.

   More specifically, each of the researchers constitutes a preselector of pulse receiving lines containing a switching mechanism giving access to each of the lines of the conductor bank, and to which is associated a device comprising a circuit for the transmission of operation at the connector, a mechanism for step-by-step advancement, members comprising an electromagnet to actuate the mechanism for advancing several steps, these steps being divided into several active or inactive groups, successive groups of steps active being separated from each other by a group of inactive steps, a circuit for the excitation of the electromagnet,

   and members for controlling the drive circuit so that the electromagnet operates the stepping mechanism at a relatively slow speed for active steps and at a relatively fast speed for inactive steps. This device also comprises members for transmitting by means of the circuit indicated in the first place several series of operating pulses to the connector corresponding to the number of groups of active steps that the mechanism

 <Desc / Clms Page number 5>

 of advancement must perform, the number of pulses in each series corresponding to the number of steps that the advancement mechanism must perform in the corresponding group of active steps, so that the switching mechanism operates the selection of the corresponding row of the sub - corresponding group in the group of lines of the driver's bench.



   According to another characteristic of the invention, each of the connector assemblies constitutes a line selection connector comprising a junction line, a switching mechanism of the type described above giving access to each of the lines of the bank of conductors, members including an electromagnet responding to pulses for actuating the switching mechanism, a first and a second circuit for the excitation of the electromagnet, and members for the transmission of several series of pulses per first through the electromagnet excitation circuit so that the switching mechanism operates the selection of a line from the small group of lines of a subgroup of a group of lines of the conductor bank.

   In addition, this line selection connector includes members containing a control relay for testing whether the chdisie line of the small group of lines is free or occupied, this control relay being attracted in the event that the chosen line of the small group of lines is lines is occupied, members responding to the attraction of this control relay to transmit a single pulse through the second electromagnet excitation circuit so that the switching mechanism operates the selection from another row of the small group of rows

 <Desc / Clms Page number 6>

 devices responding to the action of the electromagnet to cause the release of the control relay, this control relay remaining released in the event that the other line chosen in the small group of lines is free,

   and the devices responding to the test of the other line chosen from the small group of lines when it is free in order to connect the junction line there. This line selection connector also includes members responding to the test of the other line chosen from the small group of lines when it is busy in order to send the current of the busy tone to the trunk line.



   According to another characteristic of the invention, each line selection connector comprises a switching mechanism of the type described above, containing several elementary connectors individually associated with the line divisions of the conductor bank, members enclosing members. a first control part for selecting one of the elementary connectors to be actuated, in order to choose the two groups in the division:

   of associated lines, members comprising a second control part so that one of the elementary connectors chosen operates the selection of any set of two corresponding sub-groups in the two groups of selected lines and the members containing a third control part so that the elementary connector chosen operates simultaneously the selection of two corresponding lines in the two sub-groups of lines chosen.

   In addition, each row selection connector contains a first member responding to the impulses in order to make the first effective successively; second and third

 <Desc / Clms Page number 7>

 control parts, a second member responding to the pulses in order to selectively actuate one of the effective control parts, a circuit for controlling the members responding to the pulses, and a control member of this circuit, this control member being so constructed and arranged that during operation a single control pulse is transmitted through the circuit to the first pulse responsive member and a series of control pulses is then transmitted through the circuit to the second organ responding to impulses.



   According to another characteristic of the invention, each line selection connector comprises a unit or switching mechanism of the type described above containing several elementary connectors and a first, a second and a third control part to cause the indicated operation of the device. elementary connector chosen, each of the control parts having a normal rest position and several working positions and members for causing the control parts in a predetermined order to move from their normal position to their working position.

   In addition, each row selection connector contains a reset mechanism for causing the control parts in another pre-determined order to move from their working position to their normal rest position, an electromagnet to actuate this recovery mechanism, a first and a second circuit for energizing the electromagnet, members for establishing one of the circuits, members responding

 <Desc / Clms Page number 8>

 to a predetermined operation of the restoration mechanism to establish the other of these circuits, members responding to the movement of at least one of the control parts returned to its normal position in order to interrupt one of the circuits,

   and units responding to another predetermined operation of the restoration mechanism to interrupt the other of these circuits.



   The invention will be better understood by reference to the following specification relating to the accompanying drawings, in which FIG. 1 is an end elevation view of the front and rear frames of a switching device. constructed and arranged according to the present invention; Fig 2 is a front side elevational view of the frame / shown in Fig, 1; fig. 3 is an enlarged side elevational view, partially in section, of a particular construction detail of the front frame, taken in the direction of arrows 3 of FIG, 1; Fig. 4 is an enlarged sectional view of a particular construction detail of the front frame, taken along line 4-4 of fig. 2;

   fig. 5 is a fragmentary and enlarged elevational view of the conductor bank and two switching units carried by the front and rear frames shown in FIG. 1; figs. 6, 7 and 8 taken together form a fragmentary plan view of one of the automatic switching units of the switching device; lafig. 9 is a plan view of one of the elementary connectors included in the automatic switching unit shown, showing the elementary connector in a working position; fig. 10 is an end elevational view, partially in section, of the actuated elementary connector, taken along line 10-10.

 <Desc / Clms Page number 9>

 of fig. 9;

   Fig. 11 is a fragmentary side elevational view of the recovery mechanism forming part of the switching unit shown, taken in the direction of arrows 11-11 of fig. 6 ;, FIG. 12 is a sectional view of an element of the operating mechanism forming part of the switching unit shown, taken along line 12-12 of FIG. 6; fig. 13 is a fragmentary and enlarged end elevational view of an exhaust mechanism forming part of the switch unit shown, taken in the direction of arrows 13-13 of FIG. 7;

   Fig. 14 is an end elevational view of the exhaust control mechanism forming part of the switch unit shown, taken in the direction of arrows 14-14 of Fig. 7; fig. 15 is a sectional view of the exhaust control mechanism, taken along line 15-15 of FIG, 14; Fig. 16 is a sectional view of an indicator forming part of the switching unit shown, taken along line 16-16 of fig. 6;

   and figs. 17, 18 and 19 taken together represent the details of a complete automatic telephony system in which there are incorporated switching devices as shown in FIGS. l to 16 inclusive,
A detailed description of the mechanical characteristics of the switching unit is given in our patent application N 337.598 relating thereto, but with the aim of clearly understanding the operations of the circuits shown in Figs. 17, 18 and 19, a brief description will be given of the mechanical characteristics, further details being given.

 <Desc / Clms Page number 10>

 in our patent application mentioned above.



   Each switching unit comprises five elementary connectors each of them having access by means of two sets of brushes with two hundred lines, the total capacity of the unit being consequently of 1000 lines.



   Referring to figs. 6, 7 and 8, two of the elementary connectors 40 and 41 are shown therein, these connectors having the two sets of brushes 45, 46, 47 and 48, 49, 50.



   The connectors on which the brushes engage are shown at 24 in figs. 1 and 2 and constitute bare wire conductors accessible to all the elementary connectors mounted on the frames 20 and 21. The conductors are arranged in 100 levels, each of the levels having 10 conductors, the 100 levels being divided into five groups of 20 levels each, each elementary connector having access to a group.



   Referring more particularly to the elementary connector 41 shown in FIGS? 8, 9 and 10, the mechanism comprises a carriage 42 mounted for longitudinal movement along the guide plate 54 and a guide rod 52 both fixed to the base plate 28. The carriage 42 carries a mounted slide 43. to have a lateral movement with respect to the carriage thanks to tongues 57 which act on guide arms 58 of the carriage and thanks to a screw 56 which engages in a groove (not shown) of the carriage. The slide 43 carries a contact brush control part or carrier device / 44 on which the two groups of brushes are mounted.

   The selection of a particular elementary connector and the positioning of the chosen connector are carried out by means of the three bars 59,60 and 61, The bar 59 of the hundreds,

 <Desc / Clms Page number 11>

 carries as many fingers such as 64a, 65a as there are elementary connectors, the fingers being combined to engage successively with the latches such as 66 and 67 in order to block the particular elementary connector with respect to the tens bar 60 .



  The movement of the tens bar 60 carries the elementary connector chosen such that the brushes are opposite the desired level. The lateral movement of the brushes is controlled by the longitudinal movement of the bar of the units 61, the longitudinal movement being converted into lateral movement by a crank 80 pivoting around point 88 of the base plate 28. The crank is tensioned at the action of the spring 94 such that its arm 92 constantly engages against the plate 98 carried by the bar of the units 61.

   The other arm 93 of the crank is provided with a roller 96 which rolls in a groove 97 made in the sub-slide part 79. The sub-slide 79 is mounted to have a lateral movement thanks to guide rods 81a and 81b and a guide rail 82, the latter engages on a projection 85 of the sub-slide. The guide rods 8a and 81b and the guide rail 82 are all mounted on the base plate 28. The connection between the sub-slide and the slide 43 is effected by the engagement of the grooved tongue 87. extending downward and belonging to the slide 43 with the flange 86 of the sub slide 79.



   During the movement of the bar of units 61 to the left and therefore of the same movement of the plate 98 the crank 80 due to the spring

 <Desc / Clms Page number 12>

 94 will begin to rotate clockwise. This movement is imparted to the sub-slide 79 by the roll-and-groove connection between the arm 93 and the sub-slide 79 and this in turn causes the brush carrier 44 to move in a lateral direction of the slide. makes the engagement between the tongue 87 and the flange 86.



  The various elements are so combined that the extent of movement of the brush carrier is proportional to the extent of movement of the bar of units 61.



   It is understood that although the carriage 42 and hence the brush carrier 44 move longitudinally through the tens bars 60 and the sub-slide 79 attached to the base plate 28, that the flange 86 is sufficiently long as to ensure engagement between the brush carrier and the sub-slide regardless of the extent of movement of the brush carrier. In addition, the plate 98 is long enough to ensure its continuous engagement with the arm 92 of the crank.



   The movement of the three bars 59, 60 and 61 is controlled by two electromagnets M1 and M2 while the release of the elementary connector is effected by the electromagnet M3. The armature 146 of the electromagnet M1 is provided with a striking edge 153 which is combined so that, when the electromagnet M1 is in operation, it hits one of the tabs 164, 165 and 166 (figs. 7 and 13). following the cleat that has been brought into the position to be struck. The cleats are successively brought into the striking position by the electromagnet M2. Therefore when the switching unit is gripped the electromagnet M2 is energized and

 <Desc / Clms Page number 13>

 de-energized once so that the ratchet wheel 155 rotates by one step thanks to a pawl 185 mounted on the armature 179 of the electromagnet M2.

   This has the effect of passing the finger 180a of the arm 160 over a protrusion of the cam disc 187 and thereby the crank lever 160 begins to rotate around the pivot 163 counterclockwise to return the tab 164 mounted on the rim in its striking position. The electromagnet M1 is then energized and de-energized a number of times so that the latch 164 is struck the same number of times. Movement of the cleat is communicated to the exhaust control part so that the exhaust system 132 can rotate one step counterclockwise with each operation of the cleat.

   This rotation of the exhaust device 132 allows the hundreds bar 59 to move longitudinally one step to the left against the action of a spring, the hundreds bar being constantly biased towards. the left by the spring 130 acting on the lever 123 which is connected to the hundreds bar by the connection of the pivot and groove 128.



   It is understood that similar mechanisms are provided for tens bars 60 and units 61 / include fingers 161c and 162c of arms 161 and 162, cam discs 158 and 159, cranks 16l and 162, cleats 165 and 166, the exhaust control parts 156 and 137, the exhaust devices 133 and 134, and the levers 124 and 125.



   Various groups of contacts are provided for controlling electrical circuits at different stages.

 <Desc / Clms Page number 14>

 operation as will be described in detail hereinafter.



  These contact groups include the self-interrupting contacts 280 associated with the electromagnet M2 and the self-interrupting contacts 233 associated with the electromagnet M1.



  Additionally, the springs 260 and 270 are actuated at various stages during the rotation of the ratchet wheel 155.



  In addition, the group of contacts 245 is actuated from the first step towards a working position of the hundreds bar 59 while the spring 241 engages that with the following springs 239 or 240 / the hundreds bar respectively executes an even number or an odd number of steps.



   The return to its normal position of the switching unit is effected by the electromagnet M3 which is energized for a period long enough to allow its rotating armature 201 to cause the rotation via the gear of the recovery cam 210 and make it perform a trick
210 full. The recovery cam / carries a roller 220 intended to engage with the levers 123 and 124 while the gear 219 carries a roller 221 intended to engage with the lever 123.

   It is understood that as soon as the armature turns the engagement of the rollers 220 and 221 with the levers 123, 124 and 125 causes the return to its normal position of the hundreds bar 59 of the tens bar 60 and of the units bar 61, The arrangement of rollers 220 and 221 and the gears between pinion 219 and recovery cam 210 are such that roll 221 is combined to engage with lever 125 before roll 220 does. - pledge with levers 123 and 124 so that the unit bar returns to its normal position before

 <Desc / Clms Page number 15>

 cross hundreds and before those tens.

   A single turn of the recovery cam 210 is provided by the springs 223 and 224 which are closed when the recovery cam is in the working position for which the electromagnet M3 is kept actuated. When the recovery cam has made a complete revolution, the springs are open and the electromagnet is de-energized,
It is assumed that the above brief description will have given a sufficiently clear description of the mechanical characteristics of the switching mechanism to render the following description of the circuits of FIGS. 17, 18 and 19 perfectly understandable, re-
Figs, 17, 18 and 19 / show the circuits of a researcher-connector link circuit used for establishing communications from a subscriber such as A to a subscriber such as B (fig.

   19), in fig, 17 is also shown a distributor 495 as well as a control connector 465 the latter serving to control the operation of the switching unit according to the markings which appear at the bench contact of this unit through the reinforcements of the line relay of the calling subscriber.



   Operation of finder 301 and distributor 302.



   Referring now more particularly to the operation of the organs shown in FIGS. 17, 18 and 19, when a subscriber A makes a call a circuit is established for relay 350 from a ground at 341 through the loop of subscriber 342, the stepped contacts of armature 351, the lower winding of 350, the conductor 333 and 391 to the distributor battery and the common equipment 302 associated with the group of hundreds

 <Desc / Clms Page number 16>

 of lines containing the calling subscriber 304. The relay 350 attracts and blocks by its upper winding and 351; and by 354, 355 and 356 it respectively applies a marking earth to the conductors 330, 331 and 332.



  Suppose the calling line 304 matches the third line of the third level or subgroup in the even group or second hundred belonging to the first division of conductor bank 24, then control conductor 332 will be multiplied to circuits of lines associated with each subscriber line of the group of the second hundred; conductor 330 will be multiplied to the line circuits associated with each subscriber line of the third subgroup; the encoder 331 will be multiple with the row circuits associated with the third row of each subgroup.

   When ground potential is applied to conductor 332, relay 390 is drawn to remove by 391 the negative potential of conductor 333, which is multiplied at the line circuits associated with each of the subscriber lines of the second hundred group. This prevents a call made by one of the stations associated with the other lines of the group of the second hundred from interfering with a call made by station A.



   Attracting, relay 390 also establishes by 392 an obvious circuit for energizing in series the relay 400 and the operating electromagnet 474 of the rotary connector 485, but due to the high resistance of this circuit, the relay 400 alone is attracted.



  Suppose that the seeker-connector link circuit 501 shown is the link circuit designated by distributor 302 to be used by calling line 304, relay 400, attracting mark by application /

 <Desc / Clms Page number 17>

 from the ground potential to the conductor 334 by 401, the finder 301 as occupied with the bank contacts of the other distributors, the conductor 334 being multiplied to the corresponding contacts of the bank contacts of the rotary connectors of the other distributors. In addition, relay 400 also establishes through 402 the following circuit for energizing relay 380 in finder 301: earth at 392, winding 400, 402, brush 488 and bench contact, winding 380 to the battery.



   In addition, the relay 400 by attracting by 408 also establishes the following circuit for the excitation of the operating electromagnet M2a: earth, brushes 477, 408, brush 492 and bank contact, winding of the electro- M2a operating electromagnet towards the battery.



  By energizing the operating electromagnet M2a, the latter puts the exhaust control mechanism of the switching unit included in the finder scope 301, in the conditions for it to move from its normal position. to its first working position, as previously described.



   Finally, relay 400 establishes via 406 the following circuit for the excitation of the operating electromagnet 11479: earth. in 406,411, and the winding of M479 towards the battery, The electromagnet of operation establishes M479 by attracting / by its armature 481 a circuit to energize the relay 410 by an earth at armature 481 and by the intermediate 422, 499, winding 410 to the battery. The relay 410 attracts to interrupt by 411 a point of the driving circuit of the operating electromagnet M479, thus causing the release of this electromagnet, in order to bring the brushes 466 and 477 of the rotary connector

 <Desc / Clms Page number 18>

 465 on contact 3.

   When the brush 477 reaches the contact 3 it opens the circuit indicated above for the excitation of the operating electro-aipant M2a. This electromagnet therefore releases to cause the movement of the exhaust mechanism of the exhaust unit of the switching unit forming part of the finder scope 301, from its normal position to its first working position in order to thus making the hundreds bar of the switching unit effective.



   When the operating electromagnet M479 releases by its armature 481, it interrupts the circuit of relay 410. By releasing, relay 410 re-establishes by 411 the operating circuit of electromagnet M479, thus causing the re-establishment by this electro - magnet of the relay 410 circuit.

   When the relay 410 re-attracts it opens the excitation circuit of the electromagnet M479 which releases and makes the brushes 466 and 477 of the rotary connector 465 perform another counterclockwise step, L 'electromagnet M479 and relay 410 continue to react to each other so that the electromagnet M479 moves brushes 466 and 477 step by step counterclockwise and at a speed relatively high until the point where brush 466 is brought into contact with grounded contact 4, at which time an energizing circuit of relay 420 is established, through grounded contact 4, brush 466, winding from 420 and resistor 430 to the battery.

   The relay 420 by attracting establishes by 425 an obvious blocking circuit for itself and by 422 and its rest contact it opens the initial circuit of the relay 410 and by 422 t

 <Desc / Clms Page number 19>

 its contact of work it closes an obvious circuit for the relay 415 slow to the attraction. In addition, the relay 420 establishes by 421 another circuit for the electromagnet M2a by an earth at 405, 421, brush 492 and bench contact, winding of M2a towards the battery. The electromagnet M2a attracts to cause the exhaust control mechanism of the switching unit forming part of the finder scope 301 to move to its second working position.



   The relay 415 by attracting closes by 416 a circuit for the relay 410 which by attracting opens by 411 the excitation circuit of the electromagnet M479, which releases and advances the brushes 466 and 477 again one step in counterclockwise. By releasing the electromagnet M479 by its armature 481 interrupts the circuit of relay 415, thus causing the release of this relay to interrupt at 416 the circuit of relay 410, which causes the release of this relay, and restores by 411 the circuit of the electromagnet M479, causing a new attraction of this electromagnet and thus re-establishing by its armature 481 the circuit of the relay 415.

   This cycle of operations continues until the brush 466 engages on the contact 6 when the relay 420 is short-circuited by a ground given by the armature 392 through the armature 425, the halai 466 on the contact 6, resistor 430 to the battery. Relay 420 releases and opens its blocking circuit in 425. By releasing, relay 420 also interrupts by 422 and its working contact a point of the circuit of relay 415 and establishes by 422 and its contact of

 <Desc / Clms Page number 20>

 rest a point of the relay 410 circuit. In addition, relay 420 interrupts by 421 the circuit of the electromagnet M2a which releases and advances the exhaust control mechanism to its second working position, to make the bar effective. tens of the switching unit.



   During the above attraction the relay and de-energized 415 is energized / twice in a row. Each time the relay 415 is energized it establishes by 417 a circuit for the excitation of the electromagnet M1a, from the earth at 417, 407, the brush 490 and the bank contact, the winding of M1a towards the battery.



  Consequently two pulses are transmitted to the electromagnet M1a while the exhaust control mechanism of the switching unit occupies its first working position in order to cause the displacement of two steps of the bar hundreds of steps. the switching unit.



   When the hundreds bar of the switching unit leaves its normal position the contact group 245a, corresponding to the contact group 245 shown in fig. 6, is actuated and by contact 247a, finder 301 is marked as occupied at the bank contacts of the rotary connectors of the distributors. At the end of the first series of pulses transmitted by the electromagnet Mia, the hundreds bar occupies an even working position so that the contact springs 241a and nt 239a of the contact group 237a engage / to prepare an obvious circuit for energizing the switching relay 360.



  After relay 420 releases, relay 410

 <Desc / Clms Page number 21>

 and the M479 solenoid interact with each other again so that the M479 solenoid causes the brushes 466 and 477 to advance step by step and counterclockwise at a speed relatively high, up to the point where brush 466 engages contact 471 when relay 420 is again energized by a ground at 354. Relay 420 while attracting performs the same circuit operations as before, e- M2a electromagnet serving to bring the exhaust control mechanism into its third working position.



   After relay 420 attracts, relays 410 and 415 and the M470 solenoid interact, as previously described, for the M479 solenoid to advance brushes 466 and 477 step by step. counterclockwise at a relatively low speed, until brush 466 engages contact 472 to which lead 484 terminates when relay 420 is shorted again. Relay 420 releases, causing the same results as before, relay 415 de-energizing, relay 410 energizing, and electromagnet M2a releasing to bring the switching unit exhaust control mechanism into position. its third working position and make the unit bar of the switching unit effective.



   Every time. as the relqis 415 is energized and de-energized, the electromagnet Mla is energized and de-energized once as previously described to cause. the step by step movement of the tens bar. Since

 <Desc / Clms Page number 22>

 there are three steps between contacts 471 and 472, the tens bar of the switching unit will move three steps.



   After relay 420 releases, relay 410 and M479 solenoid again interact to cause brushes 466 and 477 to move counterclockwise step by step. at a relatively high speed, until the brush 466 engages with the contact 473 at which the conductor 332 ends when a circuit is again closed by the relay 420 thanks to a ground at 356. The relay 420 attracts as before to cause the release of the relay 410 and the pulling of the relay 415. In addition, the relay 420 closes a circuit for the electromagnet M2a which attracts to bring the exhaust control mechanism of the switching unit to move to his fourth working position.



   After relay 420 attracts relay 410, relay 415 and electromagnet M479 react to each other as previously described to cause brushes 466 and 477 to move counterclockwise stepwise. clockwise and at a relatively low speed, until brush 466 engages contact 468 at which conductor 484 terminates when relay 420 is again shorted and releases to release the relay 415, energize relay 410 and de-energize the M2a electromagnet which thereby brings the switching unit exhaust control mechanism into its fourth working position to make the unit bar of the switching unit effective. switching as previously described.

 <Desc / Clms Page number 23>

 



   Each time the relay 415 is energized and de-energized, the electromagnet Mla is energized and de-energized once as previously described to cause the unit bar to move step by step. Since there are three steps between contacts 473 and 468 the switch unit unit bar will move three steps.



   At this moment the brushes of the odd group of brushes engage on the third line of the third level of the first group in the first division of lines, while the brushes of the odd group of brushes engage on the third line of the third level of the second group in the first division of lines.



   When the exhaust control mechanism of the switching unit forming part of the finder scope 301 is brought into its fourth working position, as previously described, the group of contacts 260a, corresponding to the group of contacts 260 shown in FIG. . 7 is actuated so that the contact springs 261a and 262a engage in order to establish a circuit for the relay 360. The relay 360 attracts to connect through 361 and 363 the brushes 48a, 50a and 49a to the conductors 326, 327 and 328. At this moment it should be noted that the brushes of the odd and even brush groups of the first elementary connector are multiplied with the brushes of the odd and even brush groups of the other elementary connectors of the switching unit forming part of the researcher 301.



   At this moment, a loop is extended starting from the calling station A through the even group of brushes of the first elementary connector and the

 <Desc / Clms Page number 24>

 conductors 326, 327 and 328 to relay 520 of connector 500. Relay 520 attracts to establish through 521 an obvious circuit for relay 530. Relay 530 attracts to apply a ground potential at 551 to conductor 327 to thereby mark for the continuation the researcher 301 as occupied with the bank contacts of the rotary connectors of the distributors.



   Returning to the researcher, when the brush 466 arrives on the contact 468, the cam 504 is actuated to connect the contact springs 502 and 503 from where it follows that a circuit is established for the relay 498. This circuit starts from the earth at 392, by the contact springs 502 and 503 and the winding of 498 towards the battery. Relay 498 attracts to interrupt the circuit of relay 410 at 499. Therefore, the circuit of relay 410 is not reestablished when releasing relay 420 at the end of the third series of pulses, and the rotary connector 465 does not return. is not actuated further at this time.



   The potential earth applied at 531 in the connector to the conductor 327 keeps the relay 380 attracted and establishes a circuit for the excitation of the electromagnet M474 of the rotary connector 485 of the distributor 302. This last circuit leaves the conductor 327 set. to earth, by the bank contact and the brush 488, 402, the self-interrupting contacts 475 of the electromagnet M474 and the winding of M474 towards the battery.



  Relay 400 is also shorted through this circuit and released to transfer the test circuit to test brush 486 of connector 485 through 402 and its normally closed contact. When the M474 electromagnet is energized by the above circuit it attracts for

 <Desc / Clms Page number 25>

 causing brushes 486, 488, 490 and 492 of rotary connector 485 to step clockwise, thereby causing brush 486 to engage a contact of contact bank 487 at which a conductor of control associated with the following link circuit.

   If the following link circuit is free, no potential is present on the control conductor, thus causing the subsequent stoppage of the operation of the electromagnet M474. On the other hand, when the link circuit is occupied. earth is present on the control conductor thus causing the short-circuit of relay 400 and re-establishment of the excitation circuit of the electromagnet M474. Consequently, the relay 400 cannot re-attract and the electromagnet M474 continues to operate in the manner of a vibrator until the brush 486 engages on a contact associated with a free connection circuit.

   Relay 400 will be drawn back in series with the winding of the M474 electromagnet when a free link circuit is found,
The ground potential on conductor 327 also establishes a circuit for energizing relay 340 of the subscriber line circuit. Relay 340 by attracting disconnects relay 350 from the subscriber's loop through 341 and 342 and relay 350 releases, removing by 354, 355 and 356 the marking potential of conductors 330, 331 and 332.



   When the ground potential is removed from conductor 330, relay 390 releases and applies a negative through 391 to conductor 333 to mark distributor and common equipment 302 as free. By releasing the relay 390 also interrupts by 392 the circuit of the relay 498 thus causing the release of this relay. Relay 400 by releasing as described above establishes by

 <Desc / Clms Page number 26>

 409 a circuit for the excitation of the electromagnet M479, this circuit starting from the brush 477 earthed, by the multiple contacts of the associated contact bank, 409, the self-interrupting contacts 480 of the electromagnet M479 and the winding of M479 to the battery.



  When energized by the circuit shown above the M479 electromagnet functions as a vibrator to advance brushes 466 and 477 counterclockwise until they are brought back into their rest position, when the brush 477 is released from the multiple contacts of the contact bank.



  When the brushes 466 and 477 are returned to their rest position, the control cam 504 is actuated in order to open the contact springs 502 and 503. The distributor and the common equipment 302 are thereby completely released and the distributor has designated a free finder-connector link circuit for use by the next calling line of the second group of hundreds or the first group of hundreds of a group of two hundred lines.



   Operation of connector 500.



   At this time it should be noted that the switching unit forming part of the connector 500 differs slightly in construction from the switching unit forming part of the finder 301 previously described on two points of detail. First of all, the odd group of brushes carried by the control part for the contacts of at least one of the elementary connectors of the switching unit is provided with an additional brush.

   In the switching unit forming part of connector 500, this additional brush of the @

 <Desc / Clms Page number 27>

 odd group of brushes of the elementary connector shown is indicated at 512. This additional brush 512 of the odd group of brushes is used in a manner which will be explained in more detail below and which relates to the operation of the connector 500 which searches. a free line in a small group of lines PB, X.

   Secondly, the exhaust control mechanism forming part of the switching unit belonging to the connector 500 is slightly different from the exhaust control mechanism previously described, in that the first working position of this mechanism constitutes a home position such that the hundreds bar of this switching unit is made effective when the switching unit is in a home position.

   This can be easily achieved in an obvious manner by the construction and arrangement / exhaust control mechanism 154 included in the switching unit forming part of the connector 500, such that the four projections equally spaced along the periphery of each of the cams 157, 148 and 159 are spaced from each other by a distance of four paces from the ratchet wheel 155 instead of five paces.



   The connector 500 has been designed to respond to the pulses constituting the first digit emitted by the calling station A. The relay 530 prepares by 532 a pulse circuit to excite the relay 540 and the electromagnet Mlb in series, corresponding to the 'electromagnet M1 shown in FIG. 7. The pulse circuit of relay 540 and electromagnet M1b is established at the start of the first pulse as part of the first series of pulses.

 <Desc / Clms Page number 28>

 transmitted by calling station A when relay 520 releases. This circuit starts from the earth at 521, 532, the winding of 540, 592, 571 and the winding of M1b to the battery.

   The electromagnet Mlb thereby attracts and causes the displacement of the hundreds bar of the switching unit forming part of the connector 500 from its normal position to its first working position. The relay 540 is also attracted to establish by 542 an obvious circuit for the excitation of the relay 560. The relay by 566 560 by attracting establishes a circuit for the excitation of the electromagnet M2b corresponding to the electromagnet. M2 shown in fig. 7. The electromagnet M2b attracts to cause the exhaust control mechanism of the switching unit forming part of the connector 500 to move from its first working position to its second working position.



   The relay 560 by attracting establishes by 561 a bypass to the excitation circuit of the electromagnet M1b. With each pulse of the first series of pulses the electromagnet M1b is energized as described above so that at the end of the first digit the hundreds bar of the switching unit occupies a working position making the chosen elementary connector of the switching unit effective, this elementary connector having access to the line division comprising the line to which the called party's line 670 is connected. Relays 530, 540, and 560 remain energized during the pulse period due to their slow release relay characteristic.



   When the hundreds bar of the switching unit that is part of connector 500 moves

 <Desc / Clms Page number 29>

 from its normal position to its first working position, the contacts of the group of contacts 245b, corresponding to the group of contacts 245 shown in FIG. 6, are closed. At the end of the first series of pulses the hundreds bar of the switching unit occupies an even working position since in the present case the first series of pulses is assumed to consist of an even number of pulses. impulses. Consequently, the group of contacts 237b, corresponding to the group of contacts 237 shown in FIG. 6, 'is operated such that the contact spring 241b engages with the contact spring 239b to establish an obvious circuit for the relay 600.

   The relay 600 attracts so that the conductors 326, 327 and 328 are extended by the reinforcements 601, 604 and 607 to the brushes 45b, 47b and 46b.



   Shortly after the end of the first digit, relay 540 releases to open the circuit of relay 560 through 542, the latter releasing shortly thereafter. Releasing relay 560 interrupts by 566 the circuit of electromagnet M2b so that it releases in order to bring the exhaust control mechanism to its second working position in order to make the tens bar effective. switching unit.



   At the start of the first pulse of the second series of pulses from the calling subscriber A and when the relay 520 releases, the circuit for the series activation of the relay 540 and the electromagnet M1b is established by 521 The electromagnet Mlb attracts so that the tens bar of the switching unit forming part of the connector 500 moves from its normal position to its first working position, the

 <Desc / Clms Page number 30>

 relay 540 attracts as before followed by relay 560. As before relay 560 establishes through 566 a circuit for the electromagnet M2b which causes the exhaust control mechanism to move to the third working position.

   At each pulse of the second series of pulses the electromagnet M1b is excited in the manner described above so that the tens bar of the switching unit moves so that the elementary connector of the switching unit select the level or subgroup of in lines / conductor bank 24 to which the called party's line 670 is connected. Shortly after the end of the second digit., Relay 540 releases followed by relay 560. Releasing relay 560 interrupts by 566 the circuit of electromagnet M2b, which releases and brings the exhaust control mechanism into its third working position to make the unit / switching bar effective.



   Relay 520 responds to the third pulse and relays 540 and 560 are actuated as before. The M2b electromagnet is energized to cause the exhaust control mechanism to move to its fourth working position while the M1b electromagnet is actuated by the emitted pulses to cause stepping of the bar. units. The brushes of the elementary connector then engage on contacts of the even level and of the odd level. At this moment it should be noted that the brushes of the odd and even brush groups are multiplied by the brushes of the odd and even brushes of the other elementary connectors.



  If the requested 670 line is busy, the potential

 <Desc / Clms Page number 31>

 ground is applied to conductor 674 and relay 570 is energized by grounded conductor 674, brush 47b, 604, 562 and winding 570 to the battery. Relay 570 on attracting causes transmission of the busy tone to the calling line from the busy tone generator (not shown), conductor 625, armature 574 and thence to the talking conductor and to the circuit loop to the battery passing through the lower coil of relay 520.



   Shortly after the end of the third digit, relay 540 releases and at the end of the third series of pulses is followed by relay 560. The electromagnet M2b releases and brings the exhaust control mechanism to its fourth position. work to make / effective the units bar. By releasing relay 560, a point on the initial circuit of relay 570 is interrupted by 562, a blocking circuit being closed for relay 570 by the rest contacts of armature 562, 571 ', towards conductor 327 set to ground. Earth.



   If the called line 670 is free, the negative is present on conductor 674. Therefore relay 570 does not attract and shortly after the end of the third digit when relays 540 and 560 release, relay 590 is energized by the negative, at the winding of relay 660, the winding of 660, the conductor 674, the brush 47b, 604, 562, the lower winding of 590, 571 ', towards the conductor 327 put To the earth.

   Relay 590 attracts and blocks by its upper winding and '594 towards conductor 327; and connects the conductor 674 to the conductor grounded by 593 from where it follows that the relay 660 is drawn,

 <Desc / Clms Page number 32>

 to prevent the attraction of relay 650 when called station B answers the call.



   In addition, relay 590 through 591 and 595 closes the following inrush circuit: inrush current transformer winding earthed (not shown), conductor 626, the lower winding of 580,581, 591, 601 , broom 46b, called subscriber line circuit, broom 45b, 607,595, 585 to earth. A portion of this current returns through capacitor 597 and coupling capacitor 622 through the loop passing through calling station A to indicate to the calling subscriber that called station B is ringing.



   When station called B answers the call by picking up the receiver from its station, a low resistance circuit is established to energize 33 slow-to-pull 580 relays. Shortly thereafter, relay 580 is attracted to interrupt by 581 the call echo circuit and to interrupt by 581 and 585 the circuit to send the inrush current to the station called B.



  Relay 580 also establishes by 584 an obvious blocking circuit for itself and establishes by 581 and 585, a circuit loop between calling station A and called station B enclosing the coupling capacitors 622 and 623. When the loop is established towards the station called B, the relay 550 is attracted by the earth, the upper winding of 550, 621, 583, 595, 607, the brush 45b, 673, the bridge between the line conductors 675, and 672,672 , the brush 46b, 601, 591, 581, 620 and the lower winding of 550 to the battery. Relay 550 by pulling reverses the battery connections with respect to line conductors 328 and 326 in order to actuate a counter or a

 <Desc / Clms Page number 33>

 device; prepaid or another device associated with calling set A.

   At this time the conversation battery is connected-to the loop passing through the calling station A through the windings of the relay 520, and is connected to the loop passing through the called station B through the windings of the relay 550,
Release of finderscope 301 and connector 500.



   The release of the established communication is under the control of the calling subscriber, To release the established communication, the calling subscriber hangs up his receiver to interrupt the loop passing through this set and containing the relay 520, The relay 520 releases to interrupt by 521 the circuit of the relay 530, Shortly after the relay 530 releases and by 531 removes the earth from the conductor 587 and establishes by 558 the circuit used for the excitation of the electromagnet M3b: earth in 521 by the intermediate 532, the contact springs 252b and 251b and the M3b winding towards the battery. The electromagnet M3b, by attracting, causes the bars of the units, tens and hundreds of the switching unit to return to their normal position in the manner previously described.

   Shortly after the electromagnet M3b begins to attract, the group of contacts 222b, corresponding to the group of contacts 222 shown in FIG. 6, is actuated to cause contacts 223b and 224b to engage, to complete an obvious secondary circuit
 EMI33.1
 for the electro-aLuent M3b. When the electro4aLnant M3b returns the tens and hundreds bars to their normal position, the group of contacts 245b returns to its normal position.

   When contact group 245b has returned to its normal position, the

 <Desc / Clms Page number 34>

 contact springs 251b and 252b are released thereby interrupting the first circuit of the electromagnet M3b, When the electromagnet M3b turns the reset mechanism, exactly one turn, the springs 223b and 224b are released thereby interrupting the second circuit of the electromagnet M3b.



  The switching unit is therefore returned completely to its rest position.



   On releasing, the relay 530 also establishes by 532 a second circuit passing through the intermediary of the group of contacts 270b, corresponding to the group of contacts 270 shown in FIG. 7, and the group of contacts 280b, corresponding to the group of contacts 280 shown in FIG. 7 to excite the electromagnet M2b. The M2b electromagnet causes the exhaust control mechanism to move to its fifth working position. It should be noted that this position of the exhaust control mechanism corresponds to its first working position, and consequently constitutes a rest position.

   By attracting the electromagnet M2b also disengages the contact springs 281b and 282b, thereby interrupting its second excitation circuit. The electromagnet M2b releases to bring the exhaust control mechanism of the switching unit into its fifth working position.

   When the exhaust control mechanism is brought into its fifth working position, the contact springs 271b and 272b disengage to second interrupt another point of the excitation circuit of the electromagnet M2b and to stop its operation, When the hundreds bar of the switching unit has returned to its normal position, the

 <Desc / Clms Page number 35>

 contact group 237a is swept back to its normal position causing the contact spring 241b and contact spring 239b to be released, in order to interrupt the excitation circuit of relay 600. Relay 600 by releasing, disconnect brushes 45b , 47b and 46b of conductors 326, 327 and 328.



   When earth is removed by 531 from conductor 327, the blocking circuits of relays 580 and 500 are interrupted causing these relays to release. At this time the connector 500 is completely free and ready for new use.



   When the earth potenitel is removed from the conductor 327, the relay 380 releases and establishes, of the electro- by 381 a circuit for the excitation / magnet M3a which pulls to bring back the bars of the units, tens and hundreds to their normal position. Shortly after the electromagnet M5a begins to attract, the group of contacts 222a corresponding to the group of contacts 222 shown in FIG. 6, is actuated to cause the contact springs 223a and 224a to engage, and thereby establish a blocking circuit for the electromagnet M3a.



  When the hundreds and tens bars return to their normal position, the springs 252a and 25la are released, to interrupt the initial circuit of the electromagnet M3a. By the springs 247a and 248a the earth is removed from the conductor 334, in order to mark the link circuit as free at the bank contacts of the rotary connector 485.

   When the electromagnet M3a rotates the reset mechanism included in the switching unit forming part of the finder scope 301, exactly one turn, the springs 223a and 224a are opened to interrupt the blocking circuit.

 <Desc / Clms Page number 36>

 the electromagnet M3a and to stop the operation $ At this moment the switching unit forming part of the finder 301 is returned to its rest position.



   When the relay 380 releases, it also establishes through 382 a circuit passing through the intermediary of the group of contacts 270a, corresponding to the group of contacts 270 shown in FIG. 7 and the group of contacts 280a corresponding to the contact group 280 shown in FIG. 7 for the M2a electromagnet. The electromagnet M2a attracts to bring the exhaust control mechanism of the switching unit into its fifth working position, this position of the exhaust control mechanism constituting a normal position.

   By attracting the electromagnet M2a also opens the springs 28a and 282a to interrupt the circuit for the electromagnet M2a, causing this electromagnet to release in order to bring the exhaust control mechanism into its fifth. working position. The springs 26la and 262a as well as the springs 271a and 272a then open. The circuit for the electromagnet M2a is therefore interrupted and the circuit of the relay 360 is also interrupted. By releasing the relay 360 disconnects the brushes 48a, 50a and 49a from the conductors 326, 327 and 328. When the hundreds bar of the switching unit has returned to its normal position the springs 241a and 239a are opened to interrupt another point of the relay 360 circuit.

   At this time the finder 301 is completely released and ready for new use.



   When the earth is removed from the conductor 327, the excitation circuits of the relays 340 and 660 are interrupted causing the release of these relays.

 <Desc / Clms Page number 37>

 At this moment the link circuit 501 and the devices located at stations A and B are completely free and ready for a new use.



    Operation of connector 500 to operate the selection of the P.B.X.



   In establishing a communication from station A to the public office 700 via the link circuit 501 and a trunk line leading to the public office or PB.X, the operations of the distributor and the equipment 302 as well as finder 301 are the same as those described above. The initial operation of connector 500 is also the same as described above.



  In this case, three digits corresponding to the direction number to the public office are successively sent by station A, after the link circuit 501 is entered, so that the brushes 49b, 50b, 48b and 512 of the group of brushes odd respectively engage with conductors 701, 703, 702 and 704.



   The next operation of connector 500 depends 705 on the state of the P.B.X. depending on whether it is free or occupied. In the case where the P.B.X. is occupied a ground is given to the conductor 703 so that the relay 570 attracts and gives the results, as described previously, and moreover the relay 610 is actuated by: 704 grounded, brush 512, 575, the contact springs of the group 233b, 545, winding 610 to the battery. Relay 610 attracts to establish by 611 a blocking circuit for relay 560.

   The attracted relay 560 is held / by the circuit indicated above to maintain by 562 the initial operating circuit of the relay 570 and to maintain by 566 the circuit.

 <Desc / Clms Page number 38>

 fired from the M2b electromagnet. Therefore, the blocking circuit of the occupancy relay 570 is not established and the exhaust control mechanism is not brought to its fourth working position at this time.



  Attracting relay 610 establishes by 612 an electromagnet Mlb drive circuit which attracts to bring brushes 49b, 50b, 48b, 512 to the second line terminating at public office 700. By attracting electromagnet magnet M1b also interrupts the excitation circuit of relay 610 via the self-interrupting contacts 234b and 235b, and this relay releases. On releasing, the relay 610 interrupts by 611 the blocking circuit of the control relay 560 and by 612 interrupts the excitation circuit of the electromagnet Mlb. The electromagnet M1b releases to prepare by the contact springs 234b and 235b a point of the excitation circuit of the relay 610.

   If the second trunk line to the public office 700 is busy, the drive circuit of control relay 610 is re-established, causing this relay to re-pull and re-establishing the circuit of relay 560 before the latter releases, in order to re-establish by 612 the blocking circuit of the electromagnet M1b.



  Relay 610 and the M1b electromagnet continue to react to each other, as previously described, until the brushes engage a line of conductor bank 24 which is either connected to a PBX trunk line free going to public office 700 or to the last P.B.X. going to public office 700.



   If all the P.B.X. going to the public office 700 are occupied, the relay 610 and the Mlb electromagnet continue to react on each other until the brushes engage on the

 <Desc / Clms Page number 39>

 last line P.B.X. busy. The control conductors of the last P.B.X.

   going to the public office 700 are not connected together, the control conductor corresponding to the conductor 703 having an earth potential, and the control conductor corresponding to the conductor 704 being open circuit, When the brushes engage on the line of conductor bank 24 connected to the last junction line P, B, X, going to the public office 700, the relay 610 is not re-energized and shortly after it releases to establish by 563 the blocking circuit of the relay 570, The relay 570 then attracts in the manner described above to return the busy tone current to the loop passing through calling station A. Releasing relay 560 also interrupts by 506 the circuit of electromagnet M2b,

   which releases and brings the exhaust control mechanism to its fourth working position, in order to ineffective the bar of the units of the switching unit.



     , IF one of the P.B.X. is free, -the interaction of relay 610 and electromagnet Mlb is stopped when this line P, B, X, is chosen and relay 590 is pulled when relay 560 releases by: battery, re- layer 720, conductor 703, brush 50b, 604, 562, bottom winding 590, and 571 'to conductor 327 -grounded. Relay 610 therefore does not attract.



  When energized by the circuit shown above relay 590 attracts to connect conductor 703 of the P.B.X line. to the driver 327.



   When connector 703 is connected to conductor 327 - relay 720 is energized and interrupts by 721 and 722

 <Desc / Clms Page number 40>

 730 line relay excitation circuit points. Sending inrush current to the P.B.X. 705 and the attractions of relays 580 and 550 when the call is answered by public office 700, proceed as previously described. The release of the communication established between the calling station A and the public office 700 is also under the control of the subscriber calling at the station A and takes place in the manner previously described.
 EMI40.1



    

Claims (1)

CLAIMS. EMI41.1 ------- ..,. ----------- .------ 1; In a telephone system or similar signaling system, a switching unit giving access to several lines and combined to have a selection movement in order to mechanically select two groups of lines and in order to actuate contacts to select one of the two groups of lines under the control of a single series of pulses. 2. In a telephone system or analog signaling system, a switching unit having access to several lines and combined to have three movements. EMI41.2 selection elements soos the control of three series of pulses transmitted by a common circuit to a single operating electromagnet, the first of these series of pulses being used to select the group of lines which contains the desired line, $ the second of these series of pulses serving to select the sub-group which contains the desired row while the third of these series of pulses serves to select the desired row in the sub-group, a command being provided to be exerted between each series of pulses on an inverting electromagnet so that the appropriate movement takes place. 3. In a telephone system or similar signaling system, a switching unit having access to several lines and combined to have three selection movements to select the first line of a small group of lines under the control of three series of pulses transmitted by a common circuit to a single operating electromagnet, the first of these series of pulses serving to select the group of lines which contains the small group of <Desc / Clms Page number 42> lines, the second of these series used to select the sub-group of lines which contains the small group of lines and the third of these series of pulses used to select the first line of this small group of lines, a stepping circuit being established for this operating electromagnet if the first row is not available so that movement continues in the small group of rows until a row is found. 4. In a telephone or similar signaling system, a finder comprising a switching unit having access to several lines and combined to be actuated to select a calling line by several movements under the control of several series of calls. pulses generated under the control of an auxiliary connector, the contacts of which are marked according to the number of the calling line. 5. In a telephone system or similar signaling system, a finder comprising a switching unit having access to several lines and combined to be put in position to select a particular line by three selection movements, the number of steps each of the movements being determined by the markings given to the contacts of an auxiliary connector. 6. In a telephone system or analogous signaling system, a finder-finder having a common operating electromagnet for several selection operations and a reverse electromagnet in which a temporarily operating auxiliary connector is combined to control the transmission of pulses to the operating solenoid @ <Desc / Clms Page number 43> according to the calling line number and to control the operation of the inverting electromagnet between each of the series of pulses, 7. A switching unit as claimed in claim 1 in which the positioning of the unit on a particular row of the chosen group is effected by two other selection movements. 8. A researcher as claimed in claim 4 wherein the pulses are transmitted by a single circuit to a common operating electromagnet of the switching unit while the pulses for causing the change in motion are transmitted to a second electromagnet. magnet, 9. A finderscope as claimed in claim 4, 5 or 6 in which the auxiliary connector is associated with the switching unit by a distributor and is only used during the positioning of the finder, 10. A switching unit such as claimed in claim 1, 2, 5, 4, 5 or 6 in which there are several elementary connectors and the first movement of which has the effect of selecting one of these elementary connectors. 11. A switching unit as claimed in claim 10 in which each elementary connector has access to two groups of lines and this same elementary connector being chosen by two successive steps of the first movement, the selection of the appropriate group being carried out according to the number. of steps of the first movement. 12. A switching unit as claimed in claim 11 in which each elementary connector is provided with two sets of brushes each of which has access. <Desc / Clms Page number 44> to a group of lines, the determination of the group of brushes to be used being effected by the mechanical operation during the first movement of a group of contact springs. 13. A switching unit as claimed in claim 12 in which the contact springs control the operation of the brush switching relay (s). 14. A switching unit as claimed in claim 10 in which the switching unit is provided with three actuators the first actuator being moved step by step to select the elementary connector having access to the requested group of lines and to select the requested group, while the second and third control members are moved step by step so that the elementary connector chosen and to be actuated selects the desired subgroup belonging to the chosen group and the requested line in the subgroup. selected group. 15. A switching unit as claimed in claims 4, 5 or 6 in which the positioning of the switching unit is controlled by common members. 16. A switching unit as claimed in claim 15 in which the lines to which the connector has access are divided into groups and the common members are unique to each group. 17. A switching unit as claimed in claim 15 or 16 in which the switching unit is controlled in its first movement to select the required group by a permanent marking given to the appropriate contact of the auxiliary connector. <Desc / Clms Page number 45> forming part of the common organs. 18. A switching unit as claimed in claim 17 in which the switching unit is controlled in its. two other movements by variable markings given to the appropriate contacts of the auxiliary connector when the call is made. @ 19. A switching unit as claimed in claim 17 or 18 in which the number of steps taken by the switching unit is determined by the number of steps taken by the auxiliary connector when moving from a marked position to one. fixed position, 20, A switching unit as claimed in claim 19 in which the auxiliary connector steps with each step of the switching unit, 21, A switching unit as claimed in claim 19 in which the The connector advances step by step at a low speed to move from the marked position to the fixed position and at a high speed to move from the fixed position to a new marked position. 22, A switching unit as claimed in claim 3 in which if the line of the group on which the switching unit is in position is not available, the stepping circuit is established. by an additional brush associated with the switching unit, 23. In a telephone or similar signaling system, a switching unit as claimed in any one of the preceding claims, as described herein and shown on the plans. attached.