DE187148C - - Google Patents

Description

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IMPERIAL

PATENT OFFICE.

The invention is' a new one Circuit on the apparatus according to the main patent 179669, in which to obtain A second line is used to ensure absolute security of the transmission of cables. In the main patent 179669 a type printing telegraph is described, which to that Class of telegraph belongs to which, after the type of a character wheel is set and has been reprinted, the character wheel under the action of a setting tensioned spring springs back automatically into the rest position. The peculiarity of this known type printer is that the axis of the type wheel at its ends each with a contact pointer (contactor) is provided in such a way that, while the one is rigidly connected to the axle, the other free themselves together with the type wheel from the axle and can also get back to the starting position with the type wheel. These pointers are arranged so that the same while the axis is rotating, one consisting of a non-conductive material and cannot be rotated mounted disc, which has as many metallic coatings as there are types. However, these metallic deposits are not the same on both discs appropriate. In the case of the disk, which of the pointer rigidly connected to the axis is driven on, all surfaces on the back of the disc are metallically connected. In contrast, the individual linings of the second-mentioned disc are each one with one key strangely arranged keyboard connected. The first-mentioned pointer (contact transmitter) mediates the line stream in such a way that when in an end station the key of the relevant The keyboard is depressed, thereby drawing electricity from a battery The same station closes, which over the pointer, a metallic coating (because in the The rest position of the devices connected to the line is always this pointer with a metallic one Coating is connected), via which the triggering of the clockwork is effected here Electromagnets, the line line, the electromagnets at the second terminus, again here the metallic coating, the pointer and immediately goes back. This Electricity goes, as indicated, at both end stations through the triggering of a clockwork causing electromagnet. The consequence of this is that the pointer concerned immediately for one. Move forward, but the current is interrupted again, there the hands are no longer in contact with the metallic coating.

But the pointers cannot stand there stay, because now the counteracting force comes into play with the clockwork, which the pointers at both end stations are back in contact with the metallic coating brings, etc. This pointer also rotates, as indicated, at both end stations the type wheel. This jerky turning of the type wheel lasts I. as long as the button remains depressed, 2. until the on

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Type J has set itself to be printed at both end stations. Here comes the The surface of the second disc at the given station is shown to advantage. The stream of lines holds probably on, but because the one with the The pointer connected to the type wheel has reached the coating, which is in metallic contact with the pressed button, a local stream has closed, which

ίο 'causes the reversal of the same line current. But since the electromagnets mentioned are only used in one direction of the line current address and in the opposite direction (the one just set by the Type) are ineffective, the type wheel cannot move any further. In addition to those mentioned above, the line also triggers the movement causing electromagnets

ao 'a polarized relay which only responds to the current direction which, as just mentioned, occurs when the desired type is set. The response of this relay causes the closure of a local circuit in which an electromagnet is switched on, through whose response the imprint of the set type takes place in a known manner. From this it follows that at the moment when the type appears at both end stations, the printing of the same also takes place. If the button were kept depressed, the reverse current would stop and the relay and the imprint magnet would respond continuously at both end stations. If, however, the key in question is released, there is no longer any line current and the armature lever of the impression electromagnet jumps back into the rest position. However, the force that produces this rest position simultaneously decouples the type wheel from the axis of the clockwork in a known manner at both end stations, whereupon, likewise in a known manner, the same wheel snaps back into the initial position and is immediately recoupled. As you can see, with this switching arrangement, the line current is propagated on the way of the first-mentioned pointer and the relevant metal coatings. Although hardly likely to be a fear that the Fortrückung the pointer on one last stop to such faster ^one than the other end station full prefer that the pointer of the first station rather leaves the metal coating is excited as the electromagnet of the other station so it cannot be ruled out that this irregularity may occur as a result of some disturbance and the like.

With the circuit according to the present invention, on the other hand, it is absolutely impossible that as a result of some disturbance, one pointer at a station is moving faster than the pointers at the other stations, or that the pointers at all of the giving station is moving when the pointers at the other stations are do not move at the same time and at the same pace.

This is achieved simply by: I. the line current which the clockwork electromagnets etc. flows around, not via the mentioned pointer and disk, but via the armature lever and the corresponding stop of a relay flows in its rest position, 2. the pointer in question, which is stuck on the axis is arranged so that it is not in the rest position on the metal covering, but on one Insulating material comes to rest, 3. an auxiliary line is arranged, which BEZW through the two end stations. in the event of more than two stations go through all, in which auxiliary line the just mentioned Relay is switched on in such a way that the flow of the auxiliary line stream belonging here is on the mentioned pointers and disks (or to all of them) is bound. As a result is this current is only available when all of the pointers touch the metal coatings; on the other hand, there is no current if only a single pointer is not on a metal coating sits. From this it can be seen that the main stream of lines, which, arises as soon as A key is depressed only interrupts itself when all of the pointers are on all stations have completed their step. Should one or the other Pointer (among any number of stations in a row) the step in very quickly Have done wisely, he can't go any further than up to the other hands (or the most clumsy one) have also completed their step. It it is therefore obvious that the pointers of both. End stations (or all stations) only at the same step, and that it cannot happen that as a result of any Disturbance results in an uneven gait, for if there is any movement at all, it can only happen in all Apparatus be present, and in exactly the same aisle, and if in an apparatus there is no movement, so there can be no movement in the rest of the apparatus either be.

As for the process of printing the set type, it covers the same completely with the device according to the main patent 179669. As a result of the Reversing the main line current, all pointers remain on the insulated material

sit so that no auxiliary flow can arise and consequently the main line flow does not interrupt. The following imprint, the uncoupling of the type wheel, the snap back of the same and the recoupling takes place as in the main patent.

On the accompanying drawing, FIGS. I, 2, 3, 4 and 5 bring the essential parts of the type printer according to the main patent.

Fig. 6 shows the new circuit under consideration here in the case of two together devices in use.

Figures 7 and 8 indicate the case of "more than two switched on in a line Stations there.

Fig. Ι shows the side view of the apparatus, while Fig. 2 and 3 illustrate the front and back of the same. The rod 13 is an axis (Fig. 1, 2 and 3) on which the escape wheel H, the contact pointer g and the disk K sit. The sleeve h is slidably seated on the same axis and is coupled in a known manner by means of a pin on the disk S to the disk K in such a way that with the rotation of the axis 13, the sleeve h with the parts sitting on it also rotates. The latter are: a type wheel T, a contact pointer Z and a disk q, which is used in a known manner to uncouple the sleeve h when the arrangement X is involved. As a result of the response of the electromagnet DE, which only takes place in the working position of T, thus of q for the purpose of printing a type, the nose of X, which yields from right to left and jumps up again due to an impact, gets in a known manner (cf. Patent 145234) on the other side of the disc q. But comes back the tear-off

. spring ff (Fig. 2) of the anchor of DE comes into play, the nose of X presses against the wall of the disk q, whereby this nose, as its shape shows, obviously cannot give way. The consequence of this is that the socket h and all parts connected to it

• is pushed, and since the disk S has now decoupled from the disk K , the whole system follows the spiral spring in T and jumps back into the rest position.

The axis 13 is stopped from rotating with the aid of a clockwork mechanism, but this rotation can only take place by means of the movement of the escapement H located between a pair of electromagnets τη η.

A local battery O J3 forms a circuit marked with dotted lines, in which (as with the relay according to patent 113551) the one pair of electromagnets η is switched on. The battery LB is used to deliver the line current that circles both pairs of electromagnets m η and is closed in a known manner by pressing the button t. Fig. 4 shows in more detail how, by pressing any key, the metal strip y inclines and comes into contact with the rod α, as a result of which the said current circuit is formed. In addition, the same Fig. 4, taking into account FIGS. 1 and 2, shows how, when a key is depressed, a contact spring d is connected to the rod b at the same time, a current only being formed in which the electromagnet D is switched on when the Pointer Z comes into contact with the relevant pad bb. The local battery DB only comes into play when the polarized relay R switched on in the line is triggered, which is what happens at the last indicated current shortage from the battery UB . The line current from the battery LB goes either (see Fig. 5) via 18, 2, /, 15, 4 and earth on the one hand and 17, 1, e, 14, 3, a, y, U, g, 8, η m, 7, R and earth on the other hand, or via 17, i, i, 15, 4 and earth on the one hand and 18, 2, k, 14, 3 etc. on the other hand, depending on which electromagnet D does not respond or does not respond. Only in the second case respectively. the closure of the current from the battery UB, and thus the reversal of the direction of the current from the battery LB can address the polarized relay R.> Speaking now but the relay R, so the fact of electricity precludes the battery DB in which electromagnet DE is included. The response of the latter, as indicated, results in the set type being printed as well as decoupling and recoupling. According to the main patent 179669 (Fig. 5) in the line line in which the magnet pairs m η are switched on, the interruption element U, g is affected, so that the line current from the battery LB (as already in the introduction and just set out) has to run over the parts g, cc and is thus frequently interrupted at both end stations. In the circuit according to the present invention, however (Fig. 6), the line 'JL ¹ , which has to transmit the "current for the operation of the apparatus, goes no other way than the electromagnet m η influencing the movement of the clockwork and the relay JR at the transmitting station and further around R, mn ... at the receiving stations and into the earth, only the continuation of this line depends on the non-response of an electromagnet UR , which is located at any point in the same

The electromagnet is switched on in the auxiliary line ZA. The latter starts (Fig. 6) from one pole of a battery HB and first reaches the axis of the metal pointer g of the station I. From the metal disk U respectively. from the pads cc it continues around the magnet UR to the pointer g in station II and here again w.eiter from U and directly into the earth. From this it can be seen that the metallic continuation of this line from HB to earth depends on the position of both pointers g (at both end stations). This is because a metallic continuation can only form from station to station when the pointer touches one or the other conductive spot cc; because, as already pointed out, the auxiliary line L ² passes well to the axis by an arrow g, but can only by means of one or the other covering cc (since this line b.ehufs continuing connected cc only with all the toppings, the space between the pads but is filled with insulating material) go further. If both pointers g are in connection with any associated coating cc at the same time, the current from the battery HB (one pole of which is earthed) is closed. If, however, there is no metallic connection between g and cc in one or the other end station, the current path from HB is open. But if the current from the battery HB is closed, the electromagnet UR responds, and the consequence of this is that the main line L ¹ , thus the current from any battery LB, is interrupted because, as I said, the continuation of the line L ¹ of the non-response of the electromagnet UR respectively. depends on the connection of its armature with the contact piece et.

If you notice here that the

. Pointer g in the rest position not in contact with the coatings cc (as was the case with the circuit of the main patent), but with a non-conductive material, further that the step-by-step advancement of the pointer g is caused by the alternating response of the electromagnet pairs mη , in such a way that when the electromagnet η responds alone, the pointer g is in the rest position

■ and, when the electromagnet m, responds, g comes into the working position and comes into contact with some coating cc, and finally that the current excited and sent in one station from the battery LB goes through the electromagnets m η at both end stations, so it is obvious that this current from one or the other battery LB only experiences an interruption at the contact piece ct when both g have made their step further from the non-conductive to the conductive substance at the end stations. This is because, as I said, the electromagnet UR responds and consequently interrupts the line L ¹ at ct. If this step has not been taken in one or the other station, one pointer remains in the working position until the pointer that remains behind also takes its step. If, however, both pointers are in the working position, the electromagnet UR responds and the current from one battery LB, which went above 0 0, et , is thereby interrupted at ei. As a result of this interruption (since the electromagnet m remains de-energized and η alone remains active), both hands come to their rest position when η (see FIG. 3) responds, and the current from the battery is consequently interrupted immediately because Pointer g · now no longer lie on conductive material, so that contact takes place again at c t as a result of the weakening of the armature of UR and the current from the battery LB is closed again. The latter then in turn causes both hands to move from the rest position to the working position, but in such a way that this position is not left before the awkward hand has also taken its step, since, as long as the awkward hand has not taken its step, here line 1? remains interrupted and as a result, firstly UR does not respond, also at et the connection of the line L ¹ remains, and finally the current through L ¹ stops, so that the electromagnet m still responds respectively. the pointers that have already moved away remain on the metal coverings cc. From this it follows that the step-by-step movement of both pointers g can only be mathematically the same. The functioning of the apparatus at the sending station therefore not only provides proof of a simultaneous functioning of the apparatus at the receiving station, but also proof of an entirely identical functioning. The resulting currents, z. B. from station I, where by pressing one or the other key t the bar y was brought into contact with the rod a , to station II are as follows: Battery LB, one pole of which is grounded, contact piece α, metal bar y , around magnets mn, around relay R, via line L ¹ , armature 0 0, contact piece c t, around relay R, around nm, y, v, earth, furthermore battery HB (earthed), pointerg ·, cc, L ² , around magnet UR, pointer g, coating cc, earth. . ,

It should be noted here that Fig. 6 and the following Figs. 7 and 8 should be supplemented by including everything that is shown in Fig. 5, i.e. the arrangement D, 14, 15 etc. between

see the battery LB and the ■ contact pieces a, b and the imprint electromagnet DE with its battery, depending respectively. in connection with the relay R ; 2. that in Figs. 7 and 8 in the line L \ and that in addition to the electromagnet m η and the relay R should be thought switched on.

Should the traffic not only have to take place between one terminus of a line and a second terminus of the same line, but from any of many stations connected to one and the same line (omnibus line) in such a way that the dispatches transmitted from this station to all stations on the right 7 shows how in this case the circuit, which in essence remains the one just described, has to be designed somewhat differently. The line Z- ¹ goes around all electromagnets m η and the unillustrated relay R (comp. Fig. 6) without interruption and is connected at both ends to the earth. in each station is a battery LB which is on the one hand to ground and on the other hand, by depressing any key (as in the main Patent forth ) is connected to the line L ^1. This connection is not made directly, but by way of the anchor ο ο and the contact piece c t. At each station there is namely an electromagnet UR which does not interrupt the line L ¹ by responding, as just explained, but rather the interruption of the connecting wire which leads from the battery LB in question to the line L ^1. .

The line L ² connects to this electromagnet UR in each station, which otherwise takes the same path as in FIG. 6, namely at each station via g and cc .

The use of the apparatus in the circuit of FIGS. 6 and 7 is exactly the same as in the main patent. The apparatus is ready for both giving and receiving without any switching. As W ^T as the first case (Fig. 6), so it requires regarding ■ -the practice no further explanation.

With regard to the second case (Fig. 7), use the following example: Soll, at station II a dispatch will be sent to all other stations on the line right and is to be reproduced to the left, nothing more is required than the relevant keys to press the keyboard one after the other.

• The current from the battery LB (station II) takes the following path as a result of pressing any key: Battery LB, key?, Armature 0 0, contact piece ct, connection / f A :, line to the right !. ¹ , around magnets mn, again L ¹ , around mn to earth, furthermore likewise (station II) connection kk, to the left around magnets η m, line L ¹ , η m and earth. As you can see, the continuation of the current from the battery LB (station II) is related to the non-response of the electromagnet UR . But if all pointers came from the non-conductive material to the conductive material respectively. if all magnets m have responded, then the electromagnet UR (station II) responds, and the current of the battery LB is interrupted at ct , thus all pointers g are moved further into the non-conductive positions. The co-response of the other electromagnets UR '. has nothing to say here, since the batteries LB concerned are disconnected from the line. As in the case of FIG. 6, the transmitting apparatus would either not work at all if the apparatus at the receiving station does not work, or if the former does not work, it can only work in the same step with the apparatus at the receiving station (since, as has already been mentioned many times That pointer, which was hasty and took a step first,: cannot go any further than the pointer at the other end station has also taken its step), then the transmitting apparatus (station II) either stand still if one or the other of the other stations does not work, or if the former works, just at the same pace as all the others.

It should be noted here that by means of a resistor connected between point kk and electromagnet m ri , before a message is sent, the current from the battery LB concerned can be evenly distributed to the right and left. How, after the type in question has been set at all stations, the printing of the same takes place and the initial position of the type wheel is restored, is already mentioned in the introduction. The reversal of the line current from the battery LB by means of the depressed key when setting the type in question does not only apply to the supplying apparatus, but also to all others switched on in the same line. Thus, since in all these apparatuses also, the polarized relay R (comp. Fig. 5) is in the same line L ^1, so speaks a result of said reversal of the current from battery LB in all apparatus of this relay R to which the end of a circuit from the battery DB, in which the

Imprint electromagnet DE is switched on, has the consequence. The resulting, already known processes are: the imprint of the type at all stations, the uncoupling as soon as the button on the device is released respectively. the line flow is completely interrupted, the jumping back of the type wheel at all stations into its starting position and the recoupling of the same, likewise at all stations. In the circuit according to FIG. 7, all stations are switched on one after the other in the main line, which would result in a not insignificant power consumption. Instead of a series connection, the so-called parallel connection could easily be used, namely in such a way that the line L ¹ is earthed on the one hand at each station and on the other hand continues from station to station.

Fig. 8 schematically shows this parallel device. As in Fig. 7, there is a battery LB in each station, which is grounded on the one hand and connected to the line L ¹ at kk by means of a depressed key on the way from 00, ct. From kk the current of the battery LB goes on the one hand via m η and earth and on the other hand both left and right via point kk and electromagnets m η of the next following stations and again on the right and left to point kk of the following stations, etc. The here in The processes in question are exactly the same as in FIG. 7, except that as many different circuits are formed from the battery LB as there are stations, which circuits, however, close and open, depending on whether the respective electromagnet UR does not respond or responds.

Claims (3)

, Patent Claims: i. In the type printing telegraph according to patent 179669, a circuit for achieving complete safety of traffic, characterized in that, as a modification of the circuit according to patent 179669 which works with only a single line wire, in which the contactor (g), which is fixedly seated on the axis (13), is as long as the device was at rest, in contact with conductive material (cc), and the contactor (g) interacting with the disk (U) was used to close and open the line current causing the setting of the • type, 1. the fixed pointer ^ ¹ sits on the non-conductive material of the disk (U) as long as the device is idle; that 2. An auxiliary line (L ' ² ) is used, which on the one hand emanates from a battery (HB, Fig. 6), on the other hand is grounded and only then continues in metallic form or. remains uninterrupted if the pointer (g) is in contact with a coating (cc ) on each station, and in which finally a relay (UR) is switched on, which only responds when (assuming more than two stations) all pointers (g) are on pads (cc) ; and that 3. the current causing the activation of the type wheel from: the line battery (LB) by means of the line (L ¹ ) through the 'armature (0 0) of the relay (UR) and its contact piece (ct) , whereby the closing and open the current causing the setting of the type that if the relay (UR) does not respond or. the pointers (g) are not on the conductive material of the discs (U) and a key is pressed at the contact piece (ct) the current from the battery (LB) is closed, thus all pointers (g) from the non-conductive to the conductive Move the fabric further, and when the relay (UR) responds or. when all pointers (g) have made their step, ie all pointers (g) are on pads (cc) , the current from the battery (LB) is interrupted, so that all pointers (g) move one step further and consequently again the end of the contact (ct) takes place. etc., the whole with the aim of ensuring that the pointers (g) advance in the same steps on all stations. 2. In the object according to claim ι the use of as many electromagnets (UR) as there are stations (Fig. 7 and 8), in such a way that these electromagnets (UR) not the main line (L ¹ ), which is uninterrupted by earth to earth around all progressive electromagnets (mn) ' , but have to interrupt the branch wire of the battery (LB) to the line (L ¹ ). For this purpose 2 sheets of drawings.