DE138578C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The invention relates to a subscriber group for any number Participants of certain automatic telephone switch, whose facilities are so met are, because for the establishment of "the desired telephone connections only the Activity of the caller is used. Simultaneously with the manufacture The first handle made during the connection becomes the one leading to the caller Line connected to earth, so that interference from third parties is excluded. Based The invention is to be explained in more detail in the accompanying drawings.

First there will be a telephone network with a small number of subscribers, e.g. B. of 24 participants A, B, C .... Z, provided (Fig. 1). At the switching office there is a cylinder α made of insulating material, which has a number of flaps ν on its outer surface that corresponds exactly to the number of subscribers.

Around these flaps and where they come into contact with them, metal rails ■ / are arranged one above the other, the number of which also corresponds exactly to the number of participants. Each rail ■ / carries a slide c which, sliding on the rail, moves around the cylinder α and can be brought into conductive connection with the individual flaps by a contact arm. The line of each participant, e.g. B. that of subscriber A, depending on the two isolated arms / and g lever I of the switch assigned to it, located at the switching office, is brought to the contact piece r or to the contact piece j, through the mediation of the wire k or of the wire q can be brought into conductive connection either with its flap ν or with its rail i. A current stois sent through the line leading to the switch causes the lever / to be switched. So there are just as many in the placement office. Changeover switch available as a participant in the telephone network. In Fig. Ι only three are shown.

The position in which the switching lever I touches the contact piece r corresponds to the rest position, while the position in which it touches the contact piece s corresponds to the working position. In the rest position, the line of each participant is in conductive connection with his flap ν located on the cylinder α.

The establishment of the connection between two participants, e.g. B. between A and Z, happens in the following way:

A sends a current in a certain direction into the line and causes its switchover lever I to switch, which changes to the position indicated by a dotted line.

As a result of this change, the flap ν of subscriber A is grounded via line E through wire k, contact piece χ, lever arm g and contact piece y on the one hand, and subscriber A with his rail i and on the other hand through wire q, contact piece s, lever arm / and wire A has consequently been conductively connected to his carriage c.

Now, by means of a suitable drive device influenced by current surges,

which is described in more detail below, the slide c is driven forward until it comes to stand opposite the flap of Z. A then sends a current in the opposite direction into the line, through which the contact arm of the slide is brought against the flap of Z , which it then flips over. The connection between A and Z is now established, and it can be seen that the current is in the direction of A, lever arm /, contact piece s, wire q, slide c, flap v .. from Z, wire o. Contact piece r, Lever arm f of Z line Z hits.

The necessary positive and negative currents are sent by means of a suitable, -Apparatus set up at each participant.

Since the flap of Z has been completely folded over by the contact arm of the slide c , it will be impossible for a third party, for example M, to connect to the called party Z , because as soon as the slide c of M opposite the flap r of participant Z comes to a standstill, the contact arm of his carriage can no longer come into contact with the said flap (see Fig. 14).

If subscriber M wants to connect with subscriber A while A is still talking to Z , a special device indicates to him that A's line is busy. As soon as his sled comes into contact with A's flap, since the latter is grounded via E as a result of the changeover of the switch lever, a current will return to the subscriber is busy. As soon as subscriber A has finished his conversation, he sends the required power surges into the line, both to bring the arm of his sled into contact with the flap of Z, and to bring his sled back into the zero position. He then sets his change-over lever / back to the rest position by sending "a current in the required direction.

A disadvantage of the arrangement just explained is that it requires the use of an equal number of carriages arranged one above the other as subscribers in the telephone network are involved. However, since the sledges in use now take up a relatively large amount of space, it is necessary to find devices that allow the use of cylinders which contain fewer sledges than there are participants. In reality, the number of sledges can be _{reduced to V 10 of} the number of subscribers, if one considers that the number of subscribers who call at the same time, as practice has shown, is generally 10 pct. the total number of subscribers in the telephone network. For 400 participants, 40 sledges would be sufficient. A device for 400 participants using 40 sledges can be seen in FIGS. 2 and 3, which show the rest respectively. Represent working position. Except for the cylinder a, which has 400 flaps and 40 slides respectively. Has 40 rails, a second cylinder b is also present, which also has 400 flaps and 40 slides, the latter being conductively connected in pairs to the slides of the cylinder α by means of the rails i. In this case, cylinder α is the one whose flaps are connected to the associated stops r of the changeover switch corresponding to the rest position and cylinder Z? the one whose flaps are all connected to the stops corresponding to the working position s of the switch /. In the following, the cylinders b are called distributors, while the cylinders α are called connectors. The slides of the distributor b are constantly in motion and, in doing so, brush the flaps with their contact arms ■; / ■; the carriages of the connector α, on the other hand, are usually stationary and only move when they are driven to establish a connection with the aid of the apparatus intended for this purpose.

If, for example, subscriber A wants to connect to subscriber B , he first sends a current to his switch located on the central office and switches the lever / to contact piece j, whereby his flap u located on distributor b can be electrically influenced and his on the connector α located flap ν is placed on earth (Fig. 3). The first of the carriage k, which is in continuous motion on the rails / the distributor b and which will touch the flap u with its arm, which is electrically influenced, then stops as a result of a special process that takes place here and is described in more detail below makes contact with the flap by means of its arm, so that the slide c of the connector α corresponding to this slide k is now connected to the line from A. Now A sends the necessary current surges into the line to drive the slide c forward until it reaches the flap v, which the subscriber B has on the connector α, whereupon the arm of the slide c with the flap ν in Contact occurs and she kills. The connection is now established and the current flows from A, as can be seen from FIG

after I ₁ after the contact piece s, wire m, flap It ₁ slide k, wire n, slide c, flap v, wire O ₁ contact piece r, lever /, line B.

In order to meet the requirements in practice, a cylinder must not have more than 40 slides and not more than 400 flaps. It is therefore necessary, if the number of participants is more than 400, for example 1200, to divide them into groups, each group of which will have a distributor and connector of at most 400 flaps and 40 sleds. Such a case is illustrated in FIGS. 4 and 5, which show the rest respectively. Represent working position. At the switching office there are also-λ-iele group switches d present as subscribers are involved in the telephone network. In the same way, there are as many connectors α and as many A splitters b at the switching office as there are groups. The group changeover switches have as many contact pieces s ¹ , s ² , s ³ as there are groups. In other words, these contact pieces give every participant the opportunity to get in touch with every participant in any group. If now, for example, assuming there are three groups dais for 1,200 participants, so must, each connector having a valve 400. The 400 flaps of the binder a belonging to the first group correspond to the 400 participants in the first group; the 400 flaps of the connector belonging to the second group correspond to the 400 participants of the second group π. sw Each connector has 400 flaps and 40 rails, which are conductively connected in pairs to the 40 rails of the corresponding distributor b. But since his given in each group each participant the opportunity must, to talk to all of a group belonging to participants, so also must every A ^ contain grantor b as many flaps, are involved as participants in the telephone network. In the case of 1200 subscribers, each distributor must therefore have 1200 flaps. This is achieved by dividing the cylinder b containing 400 flaps into three parts, which can be arranged one above the other or next to one another, and which are called elementary distributors in the following.

Since there are now 40 carriages, z. B. come onto the first elementary distributor of a divider & 15 slides, onto the second also 15 slides and onto the third 10 slides; a total of 40. These 40 slides are constantly in motion and brush the flaps with their contact arms. The carriages of the connector α, on the other hand, have to be driven forward at the required moment. Since every participant must be able to get in touch with every group, the contact pieces of every group switch must also be distributed to all groups. In the considered case, the contact pieces of the switch of A are distributed so, s DAF ¹ with the flap of A on the first manifold, s ² with ovarian flap of A on the second A ^r issuer and s "with the flap of A on the third distributor is conductively connected.

In the same AA else ^r is from the switch of M ^s% with the flap of M to the first manifold, s ² with the flap of M on the second manifold, ^s j with the flap of M on the third distributor in fluid communication. In the rest position, the flaps of the connector α are in conductive connection with the corresponding subscriber sets. It is Z. B. the device of the participant Z, who belongs to the third group, is conductively connected in the rest position with his flap Z located on the connector α of the third group, namely by wire 7, contact piece r, switching lever I ₁ line from Z (Fig. 4).

The connection between two participants is established as follows AVise:

It is assumed that the participant A of the first group wants to connect with the participant Z of the third group. A first sends three streams to its group switch in order to be able to connect to the third group through it. As a result, this is rotated by three contact pieces, ie the contact s ^s corresponding to the third group comes into the position suitable for making the connection. A then sends a current in the opposite direction, through which the lever / folds over and comes into contact with the contact piece s ³ (FIG. 5). At the same time, the flap of A on connector a of the first group has been connected to earth via wire 2, lever arm g, contact piece χ via E. A is now in conductive connection with his flap A on distributor b of the third group through line 5, ie the flap of A is connected to A's subscriber set. The first of the carriage k, which is constantly moving around the distributor b of the "third group" and which now comes to brush against the flap A , will stop opposite it and at the same time make permanent contact by turning it over by means of its contact arm, causing other carriages to touch it are prevented from grazing them. Now A. sends as many currents in the required direction into the line as are necessary,

so that the carriage c, which is conductively connected to the carriage k , comes to stand in front of the flap of Z on the connector of the third group. Another Stromstoff, which comes from A , brings the carriage arm into contact with the flap Z, which is then turned over.

The connection between A and Z is now established, namely the current (Fig. 5) runs from A to the lever I, to the contact piece s ^s , through wire 5 to the flap A of the distributor b of the third group, from here over the carriage k and wire 6 to the carriage c, then over the flap from Z on the A ^r binder α of the third group, after wire 7, after the contact piece r, after lever / and finally after the line from Z.

For example, if subscriber M wants to contact the called subscriber Z while subscriber A is talking to subscriber Z , the arm of the carriage arriving in front of the folded flap of Z would not come into contact with this flap, since it is folded down step and therefore cannot be brought into the position required to establish the connection.

You would have to do a similar thing with one

Telephone network of 16,000 subscribers

400

= 40 groups, ie 40 connectors α and 40 distributors b . Each of the 40 connectors would have 400 flaps and each of the manifolds would have 40 elementary manifolds, each of which would have to have 400 flaps, so that, as required, each manifold would have a total of 16,000 flaps. Since there are 40 sledges on a distributor, in this case each elementary distributor would have a slide for its operation. If, however, the number of subscribers involved in the telephone network exceeds 16,000, it is necessary to connect an auxiliary distributor between each connector a and each distributor b. This is evident from the following consideration.

If you take z. B. suppose that 20,000 participants

11-1 20000

are available, = 50 group

, 400

pen, ie 50 connectors α with 400 flaps each and 50 connectors b with 50 X 400 flaps each are required, ie 50 distributors, each of which has 50 elementary distributors. Since every elementary distributor must now have at least one slide to operate its 400 flaps, each distributor should have 50 slides, which must be conductively connected in pairs to the 40 slides of the corresponding connectors. However, it is easy to see that this cannot be achieved without further ado. An auxiliary distributor must therefore be connected between each distributor and each connector, which makes it possible to bring the 50 slides of the distributor into conductive connection with the 40 slides of the connector. An arrangement suitable for this can be seen in FIG. 6, e are the auxiliary distributors connected between the connectors α and the distributors b. These have as many flaps as there are on a distributor b carriage, and as many carriages as there are on the connector ο carriage. The slides of each distributor are conductively connected to the flaps of the auxiliary distributor corresponding to them by means of the rails that carry them, and the slides of an auxiliary distributor, which continuously brush its flaps with their contact arms, are in turn in pairs with the slides of the corresponding connector. In the considered case of 20 000 participants therefore Hülfsverteiler 50 e were available, each of which flaps 50 and 40 slide would have. In this way the number of participants could be increased to any height.

With this facility, the connection "is established between two participants in the following way:

Assuming that participant A belonging to the first group wants to connect to participant Z belonging to the third group, A first sends three current impulses to his group switch, which accordingly rotates around three contacts. Then sends A a Stromstofs opposite direction in the line ", whereby the lever / folded and s is brought into contact with the contact piece ^3. This is the same time g in the same manner as in Fig. 5 through the mediation of the lever arm and the contact χ the flap of a on the connector α applied to the earth. the subscriber a is now with the flap, which he divider b on the Yer of the third group has, conductively connected to the flap of a ie in this manifold may now by one of the Subscriber station can be electrically influenced by continuous current sent into the line. As already mentioned, the slides k of the distributors are constantly in motion. The first of the carriages located on the distributor of the third group, which now touches the electrically influenced flap A , stops in front of the latter and comes into contact with it by means of its arm. The arm turns over the flap of A , so that other sledges can no longer come into contact with it. At the moment when the arm of the carriage k the flap of A

touches, the flap located on the auxiliary distributor e of the third group and corresponding to the slide k fixed on the flap A is conductively connected to the latter. The constant current still sent by A into the line now affects the one that is conductively connected to the slide k! Flap of the auxiliary distributor e of the third group. The first of the slides continuously moving on this auxiliary distributor, which touches this electrically influenced flap with his arm, immediately closes a circuit via the slide c corresponding to him on the connector α of the third group and at the same time remains in front of this flap, which he is with around his arm, stand. A galvanometer or similar device is provided at subscriber station A, which indicates the moment at which the transmission of the continuous current is to be interrupted. This moment occurs when the carriage of the auxiliary distributor has closed the circuit via the carriage c of the connector α.

Now A sends as many current impulses into the line as is necessary to bring the slide c in front of the flap of the called subscriber Z belonging to the third group, whereupon the arm of the slide c with the flap of Z, the this is turned over, is brought into contact. The connection between A and Z is now established. Now, the telephone _equipment% is to be discussed in greater detail.

The slides are driven by compressed air: the Contact arm of each carriage - effected by means of compressed air.

Each distributor or connector consists of a cylinder 37 made of insulating material (FIGS. 7 to 14), on the circumference of which the vertical flaps v, it sit. These are also made of insulating material and can be rotated about pins 38 which are inserted into bolts 39. The latter pass through bushings 40 which are fastened to the upper and lower parts of the cylinder 37. A spiral spring 41 (FIG. 7) tends to constantly push the bolts 39 outwards.

Each flap carries two metal strips 42 (Fig. 9), either with the slide arms or with the contact pieces attached to the cylinder frame ο (Fig. 7), to which the lines of the participants connect, to which the lines of the participants are connected can. Leaf springs 47 try to press the flaps against the contact pieces 0.

The cylinder 37 (FIG. 14) has a series of grooves in which the partition walls 44 fit. The latter have extensions 45 which pass through the cylinder wall. the Partitions are pressed against the bases of their guide grooves by means of springs 46. The partitions mentioned are provided with resilient pawls 48, which enter openings in the partitions when the flaps are folded down.

The rails i, j of the connectors and distributors, which serve as sliding tracks for the carriages c, k , are carried by the frame 43 (FIG. 7). Each of these rails carries two circularly arranged sleeves 49, 50 of square cross-section (FIG. 13). These bushings are used to hold the rubber tubes χ and zv, which are connected to the price air line and can be inflated by the pressure of the air.

The tubes iv are used to move the slide, the tubes .r on the other hand to move the contact arm of the slide. How this is accomplished is evident from the diagram of Fig. 15, which corresponds to the scheme of Fig. 5, projecting, b is a λ / 'issuer, α, a connector, c, k are the carriages which i of the rails, j are worn. Since the slides of the distributor b must rotate constantly, it is necessary that air is always sent into the pipes iv of the distributor. This is done by means of a kind of turbine r, the wheel of which is rotated about an axis 30 by the air coming from a collecting container t in such a way that the gear 29 seated on the axis 30 rotates with it, whereby a valve spindle engaging the teeth of this wheel is lifted and is lowered. An A ^ valve 12 is attached to this spindle, which lifts itself off its seat 11 with each stroke and allows air to flow into the various pipes w of the distributor. The slides of distributor b are driven forward around a flap for each stream of electricity. The arrangement of the carriages is described in more detail below. Since the carriage of the connector α is only moved when it is necessary, a special device must of course be provided for each line w of the connector, by means of which the calling subscriber is given the opportunity to inject as many air puffs into the one in question Line w to be sent when the carriage c has to be advanced around flaps. This is done by means of the slide drive devices h (FIG. 15), by means of which the contact arms of the slide of the distributor b are also placed at the same time. As can be seen from the drawing, this carriage drive device h consists of a disk which has a notch in which the end 25 of a spindle is usually

rests, which carries a valve that sits in the valve housing 5. On the axis of the disk 18 there is a locking mechanism, the arm 22 of which is attracted by a polarized positive electromagnet p in the rest state. A spindle is attached to the end 17 of the arm 22, the lower end of which has a valve 12 which lifts off its seat 11 when the arm 22 is repelled by the magnet p. If, accordingly, a positive current is sent into the polarized electromagnet p , the disk 18 rotates, the valve spindle 25 emerges from its incision and lifts its valve, so that air from the line 1 can get into the tube x. At the same time, however, the lifting of the arm 22 from the magnet p opens the valve 12 and air enters the line iv of the connector α , whereby the carriage c in question advances by a flap. If further currents are sent into the electromagnet ρ, the valve 12 opens with each Stromstofs and air gets into the line zv or each time. into the rubber tube w of the connector a, whereby the respective carriage advances by one flap with each air stois. In contrast, the valve of the spindle 25 will remain open until the disk has rotated completely and the end 25 can re-enter its incision.

The slide connector g, which is designed in a manner similar to the slide drive device h , is used for laying the contact arm of the slide of the connector α. On the axis of its disc 18, which has a notch, there is also a locking mechanism, the arm of which is attracted by a polarized negative electromagnet q in the state of rest. The end 17 of this arm is connected to the spindle of a valve 12, which here only serves to bring the armature of the magnet g back into the rest position under the influence of the air pressing on the same when the current has ceased to act. When the first negative current is sent through the electromagnet q , its armature is repelled. The disc 18 rotates and the end 24 of the spindle of the valve 7 emerges from its incision, lifting the valve of the housing 7 from its seat. This causes air to enter the line χ of the connector α and the arm of the affected slide is folded over. In addition to these slide drive devices h and slide connectors g , the group changeover switches d should also be mentioned, which are connected to a group locking device /. Each group switch also consists of a disk 18, on the axis of which sits a locking mechanism, the arm of which serves as an anchor for the polarized positive electromagnet m .

The end 17 of the armature carries a spindle provided with a valve 12. The air in line 1 presses against this valve, so that the armature is returned to the rest position when the current no longer passes through the winding of m . The disc itself is provided on its circumference with as many double contact pieces as there are groups in the telephone network. The disk is rotated around a tooth of the ratchet wheel with every positive current passing through m. The group lock / serves to bring about contact with the double contact pieces of the group switch by means of the two-armed lever /. This establishes the conductive connection with the flap that belongs to the calling subscriber on the corresponding distribution list in the group you are looking for. The group lock consists of a disc, the axis of rotation of which carries a locking mechanism. The arm of this barrage serves as an anchor for the polarized negative electromagnet η and is repelled by it when a negative current flows through its. Winding is sent. The valve 11 hanging at the end 17 of this armature is under the influence of the pressure of the air in the line 1, 1, so that through its mediation the armature is returned to the rest position when no more current flows through the winding of η.

At this point it should be particularly emphasized that the disks of the slide drive devices h and the slide connector g not only purely mechanically for regulating the air inlet and outlet valves, as well as for moving the connecting arm of the slide, but also, just like the disks of the group changeover switch d and the group locking device f, are used for power distribution. The discs of these organs are seen to ver-called purposes with concentric, isolated from each other, stepped copper rings, the strip over small metal plate to which anschliefsen the connection wires. By rotating the disks, the stepped metal rings can now be brought into contact with the metal plates to which the wires connect and with which one must conductively connect.

Each carriage consists of a two-part base plate sliding on the sleeves 49, 50 56, 57 (Figures 9, 11 and 12). Both parts are connected to one another by springs 58. The base plate 56 carries a lever 59 (FIG. 10) which rotates around a vertical axis 60 is rotatably mounted and about in its middle. Wearing shoe 54. Lever 59 is mediated Connecting rod 61 connected to a wedge 62 equipped with a counter tension spring which a lever 63 rests around a horizontal

zontal shaft 64 is rotatably mounted (Fig; 9 and 12). The latter is carried by the plate 57, and the short arm of the lever 63 carries a pawl 65 which is in engagement with a ratchet wheel 66 wedged onto said shaft 64. On the same shaft, a toothed wheel 67 is wedged, which passes through the base plates and engages in a circular toothed rack 68 which is firmly connected to the rail i (FIG. 8).

On the plate 57 (Fig. 9 and 12), a toothed sector 69 is also mounted, which is around a vertical axis 70 rotatable and connected to the shoe 55 by a side arm is. The toothing of the sector 69 has a toothed extension 52. Opposite to A lever 71 is arranged in this sector and is mounted rotatably about a vertical axis 72 and is subjected to the action of a spring 73 which tends to move the other against the toothing of the sector To press the end of the Flebels, which carries a gear 74, which is seated on the arm 75. gear 74 and arm 75 are movable about a common vertical axis, which carried by the end of the lever 71.

Arm 75 consists of insulating material in which two metal plates which conduct electricity are enclosed and which end in contact springs 76. The latter are brought into contact with the metal strips 42 of the flaps ν, μ. The conductive parts (FIG. 13) which are connected to these contact springs are connected to the flexible wires JJ (FIGS. 9, 13 and 14) which lead to the contact screws 78. The latter are provided with brushes (Fig. 8) which pass through the plate 57 and rub constantly on the metal rings 79 which are attached to the rear of the sleeve 51 surrounding the tube 10 and lead to the copper rings of the disks of the apparatuses g and h of which we have already spoken.

Finally, a rod 80 (Fig. 9) is arranged opposite the arm 75, which in a sleeve carried by plate 56 can slide. This rod 80 carries a lateral Arm, which aims at the rear extension of the movement of the carriage Pawl 65 to act and raise the same when it is time to operate the drive mechanism of the slide to move out.

The slide works as follows:

Each stream of air sent into the tube w moves the shoe 54 (Fig. 10) laterally, which moves the wedge 62 from left to right, whereby the free end of the lever 63 is raised. As a result, this lever rotates around its axis and, with the aid of its pawl 65 (FIGS. 9 and 12), switches the ratchet 66 forward by one or more teeth. The toothed wheel 67 connected to said ratchet wheel rotates through the same angle and moves a corresponding distance along the toothed rack 68 (FIG. 8). The wheel 6j takes the plate 57 with it, on which its shaft is mounted, and tensions the springs 58 which connect the plates 56 and 57. The former is held in place as a result of the friction against the edge of the opening 53 and against the shoe 54 caused by the inflated tube.

As soon as the air pressure as a result of the magnetic armature returning to the rest position, which opens a tap through which the air flows out, slows down, hears this friction on and the springs .58 have sufficient strength to the plate 56 to the plate 57 to be used. On the other hand, the wedge 62 (Fig. 10 and 12) under the action of it The spring moves backwards, the lever 63 falls back and the pawl 65 moves backwards on her ratchet.

This worm-like movement of the slide takes place with each new air stream which is sent into the tube w .

The compressed air entering the other pipe χ moves the shoe 55 (FIGS. 9 and 12) sideways, which moves the sector 69 from right to left. This shift in the sector produces the following effects on arm 75:

a) In the first part of the movement, the gear wheel 74 rolls on the toothing of the sector up to the extension 52. The lever Ji, which is kept pressed against the sector 69 by means of the spring 73, remains immobile, so that the axis of rotation of the gear wheel 74 and the Arm 75 with respect to axis 72 also remain immobile. The end piece of the arm 75, however, describes an arc of a circle, and the axis of the gear wheel 74 is thereby brought into a stretched position with Ji , whereby the flap uv located in its area is folded over and thus comes into contact with the stops 0 (Fig. 7) against which the flaps rest in the resting state.

b) In the last part of the movement of the sector, the gear wheel 74 moves upwards along the teeth of the extension 52. At the same time as the arm 75 continues its rotary movement about the axis of the gear wheel 74, the arm Ji rotates also about the fixed axis 72. This movement brings the arm 75 into the extension of the lever Ji (FIG. 14), the end piece of the arm 75 being displaced to the right in such a way that it is pressed perpendicularly against the flap uv of the springs 76, which at the end of this arm

sit with the metal strips 42 of the flap uv is made in this way. This pressure has in the same way had the effect of causing the flap to step behind the latch 48 of the partition 44 (FIG. 14, the latch entered the partition in order to let the flap pass, whereupon it stepped over the latter). The flap is thus held in place by the pressure of the arm 75. In this position it closes the electrical circuit at the end of the arm 75. Finally, the lifting of the gear 74 by the extension 52 (Fig. 8) still had the effect of pushing the bolt 80 backwards, the side arm of which the extension of the pawl 65 has lowered, in such a way that the latter is triggered by the ratchet wheel 66. The slide is stopped in this way.

The movements of the arm 75, which have just been explained, are repeated in the opposite sense as soon as the air pressure in the pipe χ ceases to act. The arm 75 leaves its flap, which under the action of its spring 47 (which acts more powerfully than the spring 46 of the partition 44) moves the partition 44 out of its guide groove on the cylinder 37 until the said flap releases the latch 48 (FIG. 14). . The partition then recedes into its guide groove under the action of the spring 46 and the flap rests against the stops 0 (FIGS. 7 and 11). At the same time, the pawl 65 comes back into engagement with its ratchet wheel, and the carriage is again enabled to move forward under the action of any air stream which is sent into the tube w.

The aim now is to move on to the more detailed mode of operation of the arrangement described. The current diagrams in FIGS. 16, 17, are used for this purpose. 18, 19, 20, 21, 22, 23 and 24, in which with d the group switch, with / the group lock, with b the distributor, with α the connector, with h the carriage drive device, with g the carriage connector. These figures correspond to the arrangement illustrated in FIGS. The schemes of FIGS. 25, 26, 27 and 28, on the other hand, correspond to the arrangement of FIG. 6, in which auxiliary distributors e are provided.

First of all, consider the case where, in an arrangement without auxiliary distributor, subscriber A contacts subscriber Z (FIGS. 16 to 24). In the idle state (FIGS. 16 and 18), the flap ν of A located on the connector α is conductively connected to the subscriber set A , in the manner shown in FIGS. 16 and 18: set A, line U-, wire 40 , Group switch d, wire 41, first metal strip of flap ν from A on connector a, contact piece 0, wire 42, group switch d, wire 43, group lock f, wire 44, polarized negative electromagnet n, wire 45, group lock f, wire 46 , polarized positive electromagnet m, wire 47, group lock f, wire 48, group switch d, wire 49, contact piece o ^x , second metal strip of the flap ν of A, wire 50, group switch d, wire 51, line L ² , apparatus A. The Subscriber A sends the number of positive current surges required ("current surges for setting to the" th group) into the electromagnet m of his group switch d and causes its disk 18 to rotate (Fig. 1.5). The flap ν of A on connector a is connected to earth at the same time as the disk of apparatus d is rotated by the first electricity (FIG. 5). The circuit resulting after setting the group switch d to the desired group can be seen in Fig. 19: Line U, wire 40, group switch d, wire 43, group lock f, wire 44, polarized negative electromagnet n, wire 45, group lock /, wire 46 , polarized positive electromagnet m, wire 47, group locking device f, wire 48, group switch d, wire 51, line ZA The flap z / of A remains connected to earth. A then sends a negative current through the winding of the negative electromagnet η of the group lock /. Here, the disk 18 of the group locking device f (FIG. 15) is rotated and the positive electromagnet m of the group changeover switch d is switched off. By rotating the disk of the group lock, the roller 26 of the lever I is lifted out of its notch, so that the lever I swings and the contact pieces at the end opposite the roller 26 come into contact with the contact pieces on the disk of the group switch d corresponding to the group being searched for brings. The circuit achieved by this process can be seen in FIG. 20: Line U, wire 40, group changeover switch d, wire 43, group lock /, wire 44, negative electromagnet n, wire 45, group lock /, wire 52, contact piece I ^{1 of} the group changeover d, wire 54, first metal strip of the flap of A located on distributor b (Fig. 17), second metal strip of this flap, wire 55, contact piece /, wire 53, group locking device f, wire 48, group changeover switch d, wire 51, line ZA and this circuit is established, a permanent positive current is sent into the line, which electrically influences the metal strips of the flap of A on the manifold, so that the first of the carriages continuously moving on the manifold b carrying this flap,

which touches this flap, closes a circuit in which the positive electromagnet p of the carriage drive device is located. This circuit is that of the assembled Figs. 20 and 21:

Line U, wire 40, group switch d, wire 43, group lock f, wire 44, negative electromagnet n, wire 45, group lock /, wire 52, contact piece P, wire 54, first metal strip of the flap of A on the distributor (Fig. 17 ), Carriage k, wire 56 (Fig. 21), carriage connector g, wire 57, carriage drive device h, wire 58, positive electromagnet p, wire 59, carriage drive device h, wire 60, carriage connector g, wire 61, carriage k (Fig. 17 ), second metal strip of the flap of A on the distributor, wire 55 (Fig. 20), contact piece I, wire "53, group lock f, wire 48, group switch d, wire 51, line ZA At the moment itself, where the slide arm the electrical beeinflufste flap touches u, ie at the moment when the solenoid p in the circuit switched to and beeinfiufst the same time, three operations take place. Due to the rotation of the disc, the carriage drive device h (Fig. 15) is lifted, the valve stem 25 and air gets into the pipe χ of the distributor, so that the slide arm, through the mediation of the flap 53 and the toothed sector 69 (Fig. 9 and 12), fully stretched and thereby the flap of A is folded down. Here, the locking hook 65 is triggered by the pre-pounded rod 80 and the carriage comes to a standstill. At the same time, the carriage drive device h the valve! 2 is opened and air enters the tube through the Abstofsen of the armature 22 (Fig. 15) w of the connector A; so that the corresponding to this connector, the detected on the distributor slide carriage about a flap advances. Finally, by rotating the disk of the device h, the negative electromagnet q of the slide connector g is switched into the circuit. The circuit is then that of the assembled Fig. 20 and 22. Line U, wire 40, group switch d, wire 43, group lock f, wire 44, negative electromagnet n, wire 45, group lock f, wire 52, contact piece P, wire 54, first metal strip of the flap of A on the distributor, which corresponds to the group in which the subscriber Z is, with whom he wants to speak, carriage k (Fig. 17), wire 56, group connector g (Fig. 22). Wire 57, carriage drive device h, wire 58, positive electromagnet p, wire 59, wire 62, negative electromagnet q, wire 64, carriage drive device h, wire 60, group connector g, wire 61, carriage k (Fig. 17) on manifold b, second Metal strip of the flap of A on this distributor, wire 55 (Fig. 20), contact piece / of the group switch d, wire 53, group lock f, wire 48, group switch d, wire 51, line L ² . Now the participant A η sends positive currents into the electromagnet p of the slide drive device h in order to propel the connected slide of the connector α by η flaps, i.e. as many currents as are necessary to open the slide c in front of the flap of Z. to bring the connector α. This is followed by a negative current, which influences the negative electromagnet q of the slide connector g , as a result of which, as a result of the moving disc, the roller of the valve spindle 24 (Fig. 15) comes out of its cut and air enters the tube χ of the connector. This air flow moves the flap 55 of the carriage c (FIG. 9) and the arm 75 is stretched by making contact with the flap of Z, which it folds down. The rotation of the disk of the apparatus g also switches off the positive electromagnet p of the drive device h (FIG. 23). This negative current sent last goes through the negative electromagnet 11 of the group lock /; the circuits already made by the latter are therefore not changed in any way. The connection between the two subscribers A and Z is now established and the circuit shown in FIGS. 17 and 24 is obtained: subscriber set A, line U-, wire 40, group switch d, wire 43, group lock /, wire 44, negative electromagnet n, wire 45, group lock f, wire 52, contact piece P-, wire 54, flap u, first metal strip, slide k, wire 56, slide connector g, wire 65, negative electromagnet q, wire 66, apparatus g, wire 67, slide c, first metal strip of flap ν from Z, wire 70, group switch d from Z, wire 71, line U from Z, subscriber set from Z, line L ² from Z, wire 73, group switch d from Z, wire 72, second metal strip of Flap ν from Z, slide c, wire 68, slide connector g, wire 61, slide k, second metal strip of flap u from A, wire 55, contact piece / of group switch d from A, wire 53, group lock /, wire 48, group switch d , Wire 51, line L ² , apparatus from A. Now the calling subscriber A sends negative current surges into the line and wakes up the subscriber Z. These currents act on the negative electromagnets of the locking device / and the slide connector g , but without the electrical connections.

to change. The number of times available to wake up the called party standing currents is limited.

After the connection between two participants has been established and the conversation has ended, all parts must be brought back to the rest position. For this purpose, the negative electromagnet of the slide connector g is acted on until the disc of the latter and with it the slide arm touching the flap of participant Z are returned to the rest position. Simultaneously with the disk of the slide connector g rotates also the disk of the group locking device f, through whose negative electromagnet η the negative currents sent to the negative electromagnet -q of the slide connector g also pass. A change in the circuit is not caused by turning the disk of the group locking device /. When the disk of the slide connector has returned to the rest position, the disk of the group locking device must be rotated by one tooth of its ratchet wheel so that it returns to its initial position, since the currents still to be sent to the slide drive device h flow through it . The ratchet wheel of the disc of the group locking device / has two teeth more than the ratchet wheel of the latter, therefore and in view of the fact that it makes a partial turn more than the disc of the slide connector g when establishing the connection between two participants.

Upon return of the disc of the apparatus g in the rest position, however, the positive electromagnet of the slide-drive arrangement h again in the circuit switched and the circuit is again the assembled FIGS. 20 and 22 then sends the subscriber A positive currents in the line, which rotate the disk of the drive device h and advance the slide of the connector which, at the moment when the disk of the slide drive device returns to the rest position, arrives at the zero position. At this moment, the slide arm fixed on the flap of the distributor is returned to the rest position, and immediately after the last positive current has passed through the line, ie before the arm of the slide k of A on the distributor b has left its flap and the circuit is therefore still closed, a negative current is sent through the line, which influences the negative electromagnet of the group lock / in such a way that its disk returns to the rest position and thereby removes the connection between the contact pieces of the group changeover switch and those of the lever /. Here, the positive electromagnet m of the group switch d is switched back into the circuit and the subscriber A only needs the required. Send number of positive currents in this magnet in order to restore the circuit corresponding to the rest position (Fig. 16).

25, 26, 27 and 28 should now be used to show how the connection between two subscribers is established when the telephone network comprises a higher number of subscribers, ie when between the distributors b and the connectors α still auxiliary distributors e are switched on (Fig. 6). In such an arrangement, besides the slide driving devices h still Hülfsschlittenverbinder h 'is provided by which the manifolds are folded b, the contact arms of the carriage W. The switching of the contact arms of the carriages k of the auxiliary distributors e is done by the carriage drive device h, which is used to propel the carriages c of the connector α (FIG. 28). It should also be mentioned that in the present case on the flaps u of the auxiliary distributor e (Fig. 26) there are four metal strips n, s, t, u , to which four contact pieces n ', s', f, u' of their carriages k correspond.

Let us assume that subscriber A of the second group would like to get in touch with subscriber Z of the same group. In the idle state, the flap ν belonging to the calling subscriber A on the connector α of the second group is conductively connected to the subscriber set of A (FIG. 25). The current flow is as follows: Apparatus A, line L ¹ , wire 40, group switch d, wire 41, first metal strip of the flap ν of A on connector a, contact piece 0, wire 42, group switch d, wire 43, group lock /, line 44, negative polarized electromagnet n, wire 45, group lock /, wire 46, positive polarized electromagnet in, wire 47, group lock /, wire 48, group switch d, wire 49, contact piece o ¹ , second metal strip of flap ν of A, wire 50, group switch d, wire 51, line L ² , apparatus A. First, A sends two positive currents into the positive electromagnet m in order to set his group switch d to the second group. The first of these currents puts its flap ν on connector a to earth (Fig. 26). A then sends a negative current through the electromagnet η of its group locking device f. As a result, the disk of the group locking device f is rotated and the lever / (Fig. 15) takes control.

clock with the contact pieces of group switch d of A corresponding to the second group. At the same time, the positive electromagnet in has been switched off. Through this process a conductive connection has been established with the flap of A on the distributor of the second group (Fig. 26). The current flow is as follows: Apparatus A, line JJ, wire 40, group switch d, wire 43, group lock /, wire 44, negative electromagnet n, wire 45, group lock /, wire 52, contact piece P-, wire 54, first metal strip of the flap from A on distributor b of the second group; second metal strip of this flap, wire 55, contact piece /, wire 53, group locking device 'f, wire 48, group switch d, line L ² , apparatus. Immediately after this negative current has been sent, which has influenced the electromagnet η , a permanent positive current goes into the line from the caller's subscriber set, so that the flap of A on the distributor b of the second group is electrically influenced. The first of the carriages running on the distributor of the second group, which then reaches the flap of A , will close the stream which, as can be seen from FIG. 25, via the slide k by its arm, which brushes the flap 'will continue to take the following course: first contact piece of the slide arm, wire 60, auxiliary slide connector ti, positive electromagnet p', wire 61, auxiliary slide connector ti, wire 62, second contact piece of the slide arm. The action of the current on the electromagnet p ' will cause the disk of the auxiliary slide connector ti to rotate and an air flow will be sent into the rubber tube x, which moves the contact arm of the slide k' (FIGS. 7 and 15), and consequently the arm of this Slide the flap of A on the distributor b of the second group and at the same time causes the slide to come to a standstill. By rotating the disk of ti , however, the circuit has also become a different one, namely that shown in Fig. 26: JJ, wire 40, d, wire 43, f, wire 44, n, wire 45, /, wire 52, V, wire 54, first metal strip of flap from A on distributor b, slide k ', wire 60, auxiliary slide connector ti, wire 63, metal strip j of flap u, metal strip t of the same flap, wire ¹ JO, apparatus ti, wire 62, Slide k ', second metal strip of the flap of A on the distributor b, wire 55, contact piece / of the group switch, wire 53, /, wire 48, d, line L ² . A permanent positive current now affects the metal strips s and t of the flap u on the auxiliary distributor e. As soon as one of the carriages k comes to lie opposite this electrically influenced flap u and touches the same with its arm provided with four contacts, two circuits are closed (Fig. 26), namely, on the one hand: contact piece / of the carriage arm of k, wire 64, carriage connector g, wire 65, h, wire 66, electromagnet p, wire 67, h, wire 68, g, wire 69, contact piece t '; on the other hand as secondary circuit: wire 71, wire 72, contact piece n ', metal strip n, wire 73, apparatus ti, wire 74, electromagnet p', wire. 61, apparatus ti, wire 75, metal strip u, contact piece u ', wire 76, h, wire TJ. The electric magic p and p ' in these circuits are influenced by the positive current and cause the disks of the drive device h and the auxiliary slide connector ti to rotate. The rotation of the disc of ti has no effect on the circuit. On the other hand, as a result of the rotation of the disk of h, the arm of the slide k is folded over and this slide comes to a standstill, as well as the advance of the slide k at the same time. corresponding carriage c on the connector α of the second group, and. around a hatch. This also changes the circuit, ie the positive electromagnet p of ti is switched off and the negative electromagnet q of g is switched on. The circuit is then that of FIG. 27: contact piece /, wire 64, g, wire 65, h, wire 66, p, wire 6 ¹ J, h, wire 68, g, wire 69, contact piece t ' on the one hand and as a secondary circuit : Wire 78, wire 79, electromagnet q, wire 80, wire 81. on the other hand. A now sends as many positive currents into the line as is necessary to bring the slide c , which has already been driven forward by one flap, in front of the flap of Z on the connector α of the second group (FIG. 6). Once this has happened, a negative current follows , which influences the electromagnet q , whereby the disk of g rotates and the arm of the slide c makes contact with the flap of Z , which is then turned over (FIGS. 15 and 28). Simultaneously with this process, the solenoid p of the carriage drive device h is switched off . The connection between A and Z is now established (Fig. 28). The current flow is as follows: Apparatus Ά, line L ¹ , wire 40, group switch d, wire 43, group locking device f, wire 44, negative electromagnet n, wire 45, group locking device /, wire $ 2, contact piece P-, wire 54, first metal strip of the A flap on manifold b of the second group, carriage k ^l , wire 60, auxiliary carriage connector ti, wire 63, second metal strip of flap u on auxiliary manifold e, carriage k, wire 64, carriage connector g, wire 88, polarized negative electromagnet q , Wire 87,

Slide connector g, wire 86, slide c, first metal strip of flap ν from Z on connector α of the second group, wire 85, group switch d of participant Z, line L ¹ from Z, apparatus Z, line L ² from Z, group switch d of Z, wire 84, second metal strip of the flap ν of Z on the connector α of the second group, slide c, wire 83, slide connector g, wire 82, slide k, third metal strip of flap u of auxiliary distributor e, wire 70, auxiliary slide connector / 1 ', wire 62, carriage fe ¹ , second metal strip of the flap of A on the distributor b of the second group, wire 55, contact / of the group switch d, wire 53, group lock /, wire 48, group switch d, line L ² , apparatus A. To wake up subscriber Z , A sends negative currents into the line.

After the connection between two participants has been established and the conversation has ended, all parts must be brought back to the rest position. For this purpose, the negative electromagnet of the slide connector g is first acted until the disc of the latter and with it the slide arm touching the flap belonging to the participant Z are brought back into the rest position. Simultaneously with the disk of the slide connector g, however, the disk of the group locking device also rotates, through whose negative electromagnet η the negative currents sent to the negative electromagnet q of the slide connector g also pass. A change in the circuit is not caused by turning the disk of the group locking device /. When the disk of the slide connector has returned to the rest position, since the currents still to be sent to the slide drive device h and the auxiliary slide connector h ' flow through it, the disk of the group locking device / must still be rotated by one tooth of its ratchet wheel so that it is in their initial position returns. The ratchet wheel of the disk of the group locking device / has two teeth more than the ratchet wheel of the latter, and in view of the fact that it makes a partial rotation more than the disk of the slide connector g when establishing the connection between two participants.

As a result of the return of the disk of the slide connector g to the rest position, the positive electromagnet of the slide drive device · h has been switched back into the circuit. Now A sends positive currents into the electromagnet p of the carriage drive device h. This rotates the disk of the drive device h and moves the carriage c to its starting position.

■ returned. The penultimate of these positive current surges causes the activation of the electromagnet of the auxiliary slide connector h ' in the circuit (FIG. 26); on the other hand, the negative electromagnet q of the slide connector g is switched off as soon as the disk has returned from h to its rest position. The return of the disk from h to the rest position also has the effect that the arm of the slide k of the auxiliary distributor e leaves its flap and the slide starts moving again. Furthermore, the last positive current, by means of which the disk of h was brought back into the rest position, brings the disk of the auxiliary slide connector h 'back into the rest position. The disk of the auxiliary slide connector h ' , however, by returning to the rest position, brings about the return of the slide arm from the distributor b to its rest position, producing the circuit of FIG. 25, ie the electromagnets p ¹ and η alone are still in the circuit. Immediately after the last positive current has been sent into the line, and before the arm of the carriage k ¹ has completely left its flap on the distributor b, so where

■ the circuit is still closed, A sends a negative current into the line, which influences the negative electromagnet of the group locking device /, which then returns to the rest position by breaking the contact between the contacts of the group switch d corresponding to the second group and the contacts of the The locking lever is interrupted by the apparatus / and the switching on of the positive electromagnet of the group switch d takes place again in the circuit.

If more than 40,000 subscribers are involved in the telephone network, group switches consisting of several slices are used. In this way, the disks cannot achieve a large diameter, since the individual contact pieces corresponding to the groups can be appropriately distributed over the various disks. Such a device is shown in FIGS. 29 to 34. The axis 217 of each group switch carries as many disks d as there is a multiple of 40,000 subscribers; for 200,000 participants z. B. each group switch five slices d. A metal disk 191, which is provided with openings 192, 193, 194, 195, 196, is arranged perpendicular to the planes in which the disks d lie (FIGS. 29, 30, 32 and 33). These openings, each of which corresponds to one of the disks d ₁₀₂ , d _19S, etc., can move one or the other into the position of a horizontal line running through the center of the disk 191 and running parallel to it.

be brought. Should z. B. the disk J _{193 are brought} to rotate, then the opening 193, which corresponds to this disk, is brought into the position of said horizontal. Each of the disks J ₁₉₂ , J ₁₀₃ etc. is provided with a locking mechanism These locking mechanisms have the pawls 197, 198, 199, 200, 201 (FIGS. 30 and 31) which are arranged on the levers 216 so as to be rotatable about the axes 218 (FIGS. 30 and 32). The levers 216 rest on a cross piece 202, which can rotate about the axis 219. The arrangement is such that of the disks J ₁₉₂ , J ₁₉₃ etc., only those can be rotated by means of their locking mechanism, the pawl of which is located opposite the opening which it on the disk 191. If, for example, the pawl 197 is opposite the _{opening 192 corresponding to the disk J 192} and which is provided on disk 191, it can move in this opening when the crosspiece 202 goes up, and the disk 192 dr marry. The opening 195 located next to the opening 192 then falls between pawls 197 and 198. A polarized positive electromagnet 229 is provided for moving the disk 191 and the crosspiece 202, the armature 204 of which has two branches 227, 228. The armature 204 can be moved in such a way that, depending on whether the disc 191 is to be rotated or the crosspiece 202 is to be lifted, the branch 227 comes to lie under the pawl 203 of the locking mechanism of the disc 191 or the branch 228 under the crosspiece 202. For this purpose, a horizontally displaceable rod 206 is provided on the armature 204, which is moved by a lever 207 rotatable about the axis 221 (FIG. 32). This lever 207 is provided at its upper end with a roller 222 which, in the rest position of the disk f, is supported against a roller 223 provided on the latter. If the disk / rotates, the lever 207, which is no longer hindered by the roller 223, moves to the right under the action of a spring, in that it moves the rod 206 in such a way that the branch 228 of the armature 204 is below the Cross piece 202 comes to rest. The locking lever 224 is attached above the disks d , the contact pieces 225 of which can be brought into contact with the various contact pieces of the disks d •. The lever 224 can, since the roller 215 is fixed with its groove in the disk /, can rotate about the axis 212 in a horizontal plane and it can also swing about the axis 213 in a vertical plane. It is guided in the slot of a segment 214 fastened on a column 225. A spiral spring 211 always brings the lever 224 back into both the vertical and the horizontal rest position when it is released. The end of the lever 224 facing the disk 191 is provided with a segment 210 on which there are several pins 226 which form a toothing and which engage in a corresponding toothing of the disk 191 consisting of pins 208. The pins 208 are / as shown in FIG. Of the disk 191 can be seen 34, only _^2/3 of the circumference are provided.

The device works as follows:

The calling subscriber sends positive currents into the electromagnet 229. This moves the armature 204 and causes the disk 191 to rotate. If the opening of the disk 191 corresponding to this pawl is located in front of the pawl of that disk d that is to be rotated, a negative current is sent into the electromagnet of the group locking device / and its disk rotates. Here, the roller 223 is moved and the lever 207 is released. The roller 215 of the lever 224 is still in its incision. By moving the lever 207, the rod 206 is pulled to the right and the branch 228 of the armature 204 comes to stand under the crosspiece 202. Now the calling party sends positive currents into the electromagnet 229; As a result, the armature 204 is moved and the crosspiece 202 is lifted, which moves the pawl of that disk d which is located opposite its opening provided in the disk 191. As a result, the disk d rotates on which the contact piece corresponding to the group in which the subscriber to be called is located is located. By rotating the disk 191, however, the lever 224 has also been brought over that of the disks J ₁₀₂ to J ₁₉₀ with which it is to make contact. For this purpose, the caller sends a negative current through the electromagnet of the group locker f; As a result, its disk is rotated, the roller 215 is lifted out of the incision in this disk and the lever 224 is rotated about the axis 213. Here, the contact pieces 225 come into contact with the contact pieces presented to them on the disk d, over which they are located. To return to the rest position, the contact of the lever 224 with the disk over which it is located is first removed, then the disk d, which had been rotated, is returned to its initial position. A negative current is then sent through to the electromagnet of the group locking device /, as a result of which the roller 223 moves the lever 207 back and the armature 204 is ready again for the rotation of the disk 191. Now follow

positive currents sent through the electromagnet 229. Here the Disc; 191 in their initial position and the released one Lever 229 returns to its rest position under the action of the spring 211.

From this it can be seen that those in the introduction The task set in the description is completely solved. The telephone network can have any number of subscribers and only the activity of the Calling. From all of the cases considered could it can also be seen that this is done simultaneously with that which was carried out to establish the connection first move the line leading to the caller to earth and thereby Interferences from third parties were made impossible.

Claims (6)

Patent Claims:. ■ i '. Automatic telephone switch for telephone networks divided into subscriber groups, characterized in that each group consists of a connector (a), on the circumference of which there are just as many rotatably arranged flaps (v) connected to the subscriber sets in the idle state as the respective group subscribers possesses, and a distributor (b) has as many flaps (u) as subscribers are involved in the telephone network, so that each subscriber is given the opportunity to switch through the switching of his group switch (d) located at the central office to be conductively connected to the flap (u) that he has on the distributor belonging to the group of the subscriber to be called, with simultaneous grounding of his own flap (v) located on the connector (a ), the flap of the connector (a) can be connected to each other with the flaps of the distributor (b) by means of wires, which are connected on the one hand to rails (j, i ) arranged around the distributor (b) and, on the other hand, to rails (j, i) arranged around the connector (a) , of which those of the distributor carry slides (k) which are continuously advancing and when the automatic Umlegüng of their arranged contact arms, which usually graze the flaps (u) , are stopped, while those of the connector (a ) carry slides (c) , which are driven forward only when intended; and without grazing the flaps (v) by the contact arms, .around,; if ; Arrived before the desired flap (v) , to be influenced in such a way that its contact arm (75) stretches and thereby folds the flap (v) with which it makes contact, so that the connecting line between two subscribers extends the lines, which from the subscriber sets to the connector (a) respectively. lead to the distributor (b) of the same group and from the line which is connected between the connector and distributor and through the intermediary of rails (i, j) and carriage (c, k) on the one hand to the flap (u) of the caller on the distributor (b), on the other hand, is conductively connected to the flap (v) of the called party on the connector (a). 2. Automatic telephone switch according to claim I, characterized by the inclusion of auxiliary distributors (e) between the connectors (a) and the distributors (b), of which each auxiliary distributor (e) has as many flaps as the distributor belonging to its group ( b) has sledges, and has as many slides as there are on the corresponding connector (a) , each flap of an auxiliary distributor (e ) being conductively connected to one of the rails of the distributor (b) corresponding to it, and each slide of such Auxiliary distributor is conductively connected to the carriage corresponding to it on the connector (a) of the same group, for the purpose of being able to bring the carriages present on the distributors (b) in greater number than on the connectors (a) into connection with those of the connector and This enables a telephone system to be set up with any number of participants (e.g. 100,000). 3. Automatic telephone switch according to claim I, characterized by the arrangement of group switches (d) in the switching office, which can be set to the corresponding contact of the group in which the called subscriber is, of group locking devices (f), through which by means of a Locking lever (I) the connection between the group switches (d) and the metal strips of the flaps (u) of the distributor (b) is made, as well as of slide drive devices (h) and slide connectors (g), the discs of which are polarized electromagnets' (p, q ) are moved and are set up in such a way that, through their rotation, both the air inlet and outlet valves (12) for regulating the air and those required for moving the connecting arm of the carriages (c, k) are required mechanical, as well as those used to manufacture the various electrical circuits necessary effects are produced. 4. Automatic telephone switch according to claim ι for a very high number of subscribers, characterized by a group _switch , which consists of several discs (d la2, d _1B3 us vr.j , on the circumference of which the number of contacts present in one of the number of groups is distributed and Via which, through the rotation of a parallel to the axis (217) arranged, on part of its circumference with pins (208) engaging in the toothing of the curved section (210) of the lever (224), the locking lever (191) is provided. 224) can be brought, which is rotatably arranged at (212 1 and guided in the segment (214), whereby by the rotation of the disc (191) of the notches provided in it (192, 193, 194, 195, 196) the one opposite the corresponding locking lever (197, 198, 199, 200, 201) can be brought, which is to rotate the disk (191) on which the group to be set corresponds to the mediation of the oscillating crosspiece (202) echende contact piece is located. 5. Automatic telephone switch according to claim I, characterized by a for Movement of the disc (191) and the crosspiece (202) serving polarized Electromagnet (229), its armature (204) has two branches (227 and 228), of which, depending on whether the disc (191) or the crosspiece (202) is to be moved, the former is brought under the locking lever (203), the second under the crosspiece (202) , this through the mediation of a sliding rod (206), which is influenced by a lever (207) which is held in the rest state by the roller (223) of the disc (f) , but when the latter rotates under the action of a spring about its axis ( 221) is turned to the right, only to return to the rest position when the disk of the group lock (f) has reached its original position again.
6. Automatic telephone switch according to claim 4 and 5, characterized in that the disk of the group locking device (f) in its second partial rotation, i.e. after the lever (207) has been released and, through the intermediary of the crosspiece (202), the required disks ( d la2, d _wz etc.) has been set, pushes the lever (224) out of the incision in the disk of the group _{locking device} (f) and its contact pieces (225) with the set contact pieces of the disk (d) over which it is located , brings into contact, for the purpose of establishing a conductive connection with the flap (u) which the caller has on the distributor belonging to the group of the subscriber to be called. In addition 5 sheets of drawings.