DE179669C - - Google Patents

Description

IMPERIAL

PATENT OFFICE

PATENT LETTERING

179669 -. CLASS 21 α. GROUP

Dr. LUIGI CEREBOTANI in MUNICH.

Type printing telepraph. Patented in the German Empire on December 2nd, 1905.

The invention belongs to that class of type printing telegraph in which, after the type of character wheel in question has been set and printed, the character wheel automatically into the rest position under the action of a spring tensioned during adjustment jumps back.

The peculiarity of the present invention consists in a transmitting device which so

ίο is related to the recipient that the the following processes occur:

a) Depressing the relevant key of a suitably arranged keyboard does not result in the simple triggering of a clockwork, but closes it Line current so that the latter a frequent interruption by means of a deal with the Axis of the encoder rotating pointer (contactor) in connection with a similar process in the pointer of the Receiver at the end station switched on in the same line learns, whereby the type wheel moved step by step at both end stations.

. b) The type wheel is stopped by pressing the prayer button at relevant set type in that this closes a circuit which the reversal of the stream of lines causes the latter as a result of the reversal the imprint of the set type conveys, whereupon the type wheel jumps back into the rest position automatically is going.

By using a simple polarized overturning magnet only needs a power surge (or two) to be transmitted over the trunk line; also can this simple current impulse excited at the transmitting device even without a wire the same Have an effect on the recipient concerned.

Fig. Ι represents the side view of the overall arrangement (Sender and receiver together).

Fig. 2 is the front view and

FIG. 3 shows the rear view of FIG. 1.

Fig. 4 shows more details about the nature of the small keyboard.

5 is a schematic representation of the overall arrangement and those involved in this Local circuits and also illustrates the components of an auxiliary apparatus, through which the direction of the line current is automatically reversed. .

FIG. 6 shows a variant of FIG. 5.

FIG. 7 illustrates the use of the arrangement according to FIG. 6 without the intermediary of a Pipeline.

Figs. 8 and 9 are structural views of the present type teleprinter.

The receiving arrangement used contains a number of previously known parts. These include in particular: an escapement wheel H (FIGS. 1, 2 and 3), which is set in rotation by two alternately responding electromagnets in, η under the action of a clockwork W and also sets a suitably mounted axle 13 in rotation; Furthermore, a disk K rigidly connected to the axis 13, the edge of which is provided with cutouts; a sleeve h that loose

sits on the axis 13; a character wheel T, which is stuck on the sleeve h; a washer S, also rigidly connected to this sleeve, which has a pin on the edge through which the latter, thus the sleeve and the type wheel T, is coupled to the wheel K ; a spiral spring tensioned against said sleeve Ji , whereby the latter, thus also parts T and 6 ″, can be moved towards the disk K ; a magnet DE, through whose response the set type is printed, and finally one on the type wheel T. attached spiral spring, which is tensioned during the adjustment, by means of which the moving type wheel is returned to its rest position.

These known parts are now followed by the following: A non-rotatably mounted disc A made of non-conductive material carries a number of metallic covers bb all around, close to the edge, of which two are each at the same angle as the types on the type wheel, and which of a pointer Z fixed on the sleeve during the rotation of the sleeve BEZW. of the type wheel T can be driven on. (According to Fig. 9, the pointer Z is attached to the type wheel T itself.) In addition, behind the escapement wheel H, also non-rotatably fixed, a conductive disk U, which, however, only comes into contact with the metallic mass of the apparatus when a with the axis 13 firmly connected pointer g touches the metallic surface of the same disk. As FIG. 3 shows, this surface is provided with points cc made of non-conductive materials. The number and arrangement of the latter coincide with that of the teeth of the escape wheel H.

As a result, the contact part of the pointer g comes into contact with conductive and now with non-conductive substances during the rotation of the escape wheel H. On the front of the device is a series of non-conductive keys t, t. . . arranged, as many as there are guys on the type wheel. By pressing one or the other key, two metal connections go before sie, namely 1. the connection of a hinge-like attached bar y (see. Fig. 1 and 4) with a metal piece a, and 2. the connection of one of the contact springs d with a metal rod b. In the structural illustration of FIG. 9, a variant of the last-mentioned parts can be seen, which is suitable for the case of using three rows of keys. The sleeve h also bears a small disc q, which in a known manner (cf.

also patent 145234) shows a cut-out in the lowest position (Fig. 2) in the rest position of T , through which the nose of a small organ X can pass (see Fig. 9). By addressing DE, which only takes place in the working position of T and thus of q for the purpose of imprinting a type, the nose of X, which by pushing from right to left to-. there and jumps up again, in a known manner on .the other side of q, as' the dotted position (Fig. 9) of X illustrates. But if the tear-off spring ff of the DE anchor comes into play again, this nose of X presses against the wall of the disk q, whereby this nose, as its shape shows, obviously cannot yield. The consequence of this is that the sleeve Ji together with all parts connected to it is displaced (Fig. 1 and 9), and since the disk 6 "has now decoupled from K , the whole system follows the spiral spring in T and jumps into the In this position, however, the nose of X comes into the cutout of the disk q (Fig. 2), so that the spiral spring of the sleeve h comes into its own and the coupling of S ¹ and K can take place again.

With regard to the wire connections on the parts mentioned, the following should be emphasized for the time being: Each metallic document bb on the disk A is connected to a contact spring d . The pieces b, a; y \ xaav serve for further connections resp. to create 'various circuits as explained below. One, n, of the electromagnets 111 , 11 is traversed by a local current OB . The line current, on the other hand, flows through both electromagnets 111, n in a known manner. The effect of this arrangement is analogous to that described in patent 113551 by the same inventor. The electromagnet DE is subject to the action of a polarized relay R switched on circuit of the battery DB.

A special task in the processes to be described below (see FIG. 5), which represents the entire device of the present type teleprinter at both end stations, is carried out by the arrangement denoted by D in FIG. The same consists mainly of a simple electromagnet D with a breakaway spring and an armature lever, the metallic ends 14 and 15 of which are isolated from one another. The ends 14, 15 come into contact either with the contact pieces e and / or with the contact pieces k and i , depending on whether the electromagnet responds or not. The contact pieces e and i are connected to terminal i, the contact pieces k and / to terminal 2.

closed. The metallic end pieces 14 and 15 connect, one to the terminal 3 and the other to the terminal 4. The two ends of the winding of the electromagnet D are connected to the terminals 5 and 6. These six terminals are also in connection partly with two batteries LB, UB and partly with the above-mentioned new parts of the actual type telegraph, namely 1 and 2 with the poles of the line battery LB, 3 with the terminal α (see. Fig. Ι and 4), 4 to earth, 5 to one pole of the battery UB and 6 by means of the contact piece b, as will be explained below, with the pointer Z.

From this it can first be seen that the metallic connection of the poles 17 and 18 takes place either via 3 and 4 or via 4 and 3, depending on whether D responds or not, further that the response of D can only take place if the Pointer Z touches a metal document bb , which is in connection with that contact spring d, which comes into contact with b by pressing the relevant key t , whereby the following circuit is formed: 20, 5, electromagnet D, 6, b, d, document bb, pointer Z, 19.

In order to explain the meaning of the reversal of the above-mentioned metallic continuation of the poles 17, 18 by the response of D , it should be noted here that terminal 4 leads to earth and terminal 3 leads to the line "of the line, furthermore that the type wheel itself only moves in one direction under the action of the current, and finally that the imprint of the set type occurs when the line current from the battery LB is reversed, which, as indicated, by the response of the electromagnet of D, which response with the setting of the type in question coincides.

Fig. 5 shows all other wire connections and the overall device which forms the essence of the present invention. The terminal 3 is, as already mentioned, connected to the contact piece α , the metal strip y to the metal disk U. The pointer g is also metallically connected to the terminal 8, from which a wire for winding the four coils of the electromagnets m, η and leads to terminal 7. From here the long-distance line goes out, in which latter the polarized relay R is switched on at both end stations.

The continuously closed current from the battery OB (via 9, 10) flows exclusively, as indicated above, to the coils of the electromagnet . The relay R serves to close the current from the battery DB (via 11, I2), in which Circuits of the electromagnet DE is switched on. The contact piece υ leads to earth. The terminal 20 of the battery UB is, as already mentioned, connected to 5, the second terminal 19 of the same with the pointer Z. The terminal 6 is connected to the terminal on the rod b. The metallic documents bb on the non-conductive, stationary disk A are each connected to a contact spring d (see FIG. 2).

The whole arrangement is always ready for both sending and receiving without any switchover. If you want to send, nothing more is necessary than the relevant key on the keyboard, e.g. B. at the end location I, to depress. Once this has happened, both the bar ν and the relevant contact spring d rotate at the same time until the rod α on the one hand touches the rod b on the other hand.

As a result, j / is separated from ν and the relevant document bb is connected to disk A with rod b . ' But as a result of the contact of y with ο, one or the other pole of the battery LB, depending on whether D responds or not, is connected to the metal disk U via 3, a, y, as explained. Since in the rest position the pointer g (both at point I and at point IT) is connected to the metallic part of U , the metallic connection of the mentioned pole of LB_ goes from pointer g to terminal 8, by m, n, to terminal 7 and into line L to the second terminus. But since here (position II) the apparatus is at rest respectively. If no key is depressed, a circuit of the battery LB continues here as well, namely via 7.111, n, 8, g, U, y, ν and earth. But since the other pole of the battery LB at point I is already connected to earth via 4, the first effect of pressing a button at point I is the end of a circuit of the battery LB, in which the electromagnets m at both end stations I and II , η are switched on. Since the direction of this current is opposite to that of the current from the battery OB , the magnetic arrangement in, η an and. the anchor that was attracted by η is now attracted by m (see Fig. 3). As a result of this movement, the pointer g (both at point I and at point II) has rotated half a step further and has come into contact with a non-conductive point cc , whereby the current from the battery LB is apparently interrupted. Now, however, the magnetic force on the part of η again comes into effect at both point I and point II, so that the armature rests against the electromagnet η again, the escape wheel rotates half a step further and the pointer g again at both end stations

comes into contact with the metal of U , whereby m gains the upper hand again and the pointer g moves further, etc. So as long as the relevant key t at end location I is pressed and y is in contact with a , the direction of the current remains from the Battery Li? unchanged and there is an automatic interruption of the line current at both end locations by the swinging of the armature w and by the ίο rotation of the pointer g , the number of interruptions being equal to that of the passages cc . The speed of these interruptions is dependent only on m, the assembly of the effectiveness of this coming to bear magnetic force, n. The latter may, taking into account the performance of a participating clockwork W are regulated so that the speed can be very large, and that the pointer g can move extremely quickly from one spot on the disk U to another, as far away as you want, at both endpoints.

In the process outlined, it should also be noted that the interruptions in the current from the battery LB are related to the operation of the apparatus at both end stations in such a way that neither the current connection nor the interruption of the same can occur if the pointers g are not move evenly. Both the presence of the

__ of the current than the interruption of the same

namely dependent on both the position of the pointer g at point I and on the position of the pointer g at point II, so that this forms a kind of mutual regulation and the possible slowing down of one pointer g results in the gradual waiting of the other pointer g Has.

As already noted, the key in question also presses down a contact spring d at the same time as the strip 3 ', which is connected to strip b and thereby to terminal 6 and one end of the winding of the electromagnet D. This contact spring d is connected to a metal patch bb on the non-conductive disk A. The pointer Z also rotates with the pointer g in that the sleeve h is connected to K (see FIG. 1). This contact pointer Z therefore covers the same path on A as g on U and goes so far until it finally comes into contact with that metallic spot bb, which is in connection with the contact spring d . Here, however, a current is immediately formed from the battery UB, in which circuits the electromagnet D is switched on. As already indicated, the course of this current is as follows: pole 20, terminal 5, D, 6, b, d, bb, pointer Z back to pole 19 of the battery UB . So now D responds, and the consequence of this is i. that the current from the battery LB, as stated, is reversed, 2. that the armature of ■ vi, η at η remains attracted or. g and Z and the whole system does not move any further, and 3. that the polarized relay R switched on in the line L responds at both end stations, whereby electromagnet DE, also at both end stations, gets into the circuit of the battery DB , its anchor attracts and prints the type that was set by rotating the whole system around axis 13. If the relevant key remains depressed, the DE armature also remains attracted. But as soon as this key is released, the last-mentioned armature releases itself from the magnet DE , and the consequence of this, as already mentioned, is that the sleeve h and everything related to it, including T and Z, spring back into the rest position - and 5 and K pair up again. It should be noted here that the pointer g does not need to jump back, since it is sufficient that in the rest position it is somehow in contact with a metallic part of the disk U , which is the case when the magnet η exerts its magnetic force, which is always present alone when the current from the battery LB is not closed.

So if you want to work with this type telegraph resp. Send despatches so is nothing more is required than to press the keys of the relevant letters one after the other, that one is depressed as soon as the other is released, and that the release occurs as soon as the pressure is heard will. The type is set by pressing it down, immediately followed by it their imprint, and when you let go of the button everything is back in its resting position, everything Processes that hardly take half a second.

As far as the space between word and word is concerned, a key is appropriate which bears the name "pause", when depressed both 3; with α as well as directly Z with b in connection, which with the excitation of the current from the battery LB at the same time the reversal of the same current BEZW. causes D to tip over. With this stream, which, as I said, is already sent in reverse, the type wheel stops, as already explained, and only R responds, whereby no type is printed, but the paper is advanced in a known manner.

Since the arrangement U, g and the currents acting on in, η are regulated in this way

can ensure that the gradual movement of the pointer g resulting from the automatic interruptions and the swinging of the armature zv is always uniform and always at the same speed, the transmission of the dispatches with this type telegraph can also be carried out by means of a single current impulse for one letter in front of it go, namely, that each end station as a result

to accomplish · the setting of the type and the subsequent imprint etc. is left to itself. Fig. 6 shows how the arrangement is designed here. The type of pressure telegraph with all its transmitting and receiving organs remains the same as described, only the circuit is a little different. > The non-conductive disk A is provided with two metallic documents dd and ee in addition to the documents bb , in such a way that the first is in the rest position of the contact pointer Z and the second is all around on the entire path to be traveled by the contact pointer Z. These documents are touched by the contact pointer when they are driven over. One document dd is metallically connected to bar y and at the same time to one pole of a local battery BB ; the other document ee is metallically connected to one pole of a second battery BB '. In this wire connection ee, BB ' , a relay R is switched on, which has the task of closing the circuit in which the pressure electromagnet DE is switched on. Each contact spring d , when not depressed, is connected to earth by vv , as shown in FIG. The battery that has to send the power over the trunk line is now HB (Fig. 6). One pole of this battery HB is directly connected to earth, and the other pole is connected to the contact pieces a, b . The pointer Z is in connection with the long-distance line L, in which a simple, neutral relay RR is switched on at both end stations. This relay RR (Fig. 6) takes on the task of doing what the connection of y with α in the previous circuit had to do. If the relay RR responds, a polarized Unikippmagnet PR comes into one or the other of the two local circuits of the battery BB or BB ', depending on whether the mentioned contact pointer Z is in the rest position or in the working position. If the circuit of the battery BB is closed, the armature r tilts to the right, touches tt and closes the circuit of the battery LB, which circuit has the following course: 18 to m, n, over the said metal disk U, contact pointer g, armature r, tt, 17. The fact that and in what way the contact pointer g rotates step by step on the disk U as long as r is on tt does not need to be mentioned again, since the process here is exactly the same as described above. Both end stations are always ready for use with this circuit as well as with the one already described above, without any preparation, both for sending and receiving. The use is the same as explained above, only the processes are designed, here a little different. If a key t is depressed or. y brought into contact with α and the relevant d with b (Fig. 6), a current is first connected from the battery HB, the course of which is as follows: earth, HB, α, y, dd, 3, around RR, after L, in the second terminus around RR, via Z, dd, y, ν and earth. As a result, the simple relay RR responds at both end stations, and as a result, the polarized reversing relay PR also gets into the circuit of the battery BB at both end stations. The course of this circuit is as follows: 24 to PR, via 27, 41, 28, Z, dd, 29 and 23. The effect of this current is that the armature r, which was inclined to the left, now overturns to the right and on both end stations the current of the battery LB closes, which current remains closed even when RR is no longer excited. As mentioned, the completion of the circuit of the battery LB results in the rotation of g, thus also of Z , step by step. But already after the first step from Z to the right, the current from the battery HB was interrupted because the pointer Z came out of contact with the document dd . The relay RR is therefore switched off, its armature withdrawn from 27, and a line circuit, thus a circuit at 27, will only form again when a second current from the battery HB occurs during the rotation of Z. The latter happens shortly afterwards, specifically at the moment when the pointer Z reaches the document bb which is connected to the relevant contact spring d held down by the key. Here a stream is formed which has the following course: Earth, HB, b, d, bb, Z, around RR, over L, at the other end station around RR, over Z, bb, d, vv, earth.

Relay RR now responds at both end stations, and it is terminated again at 27. But this conclusion at both end stations no longer applies to battery BB, since it has no further connection from 23 beyond dd , but to battery BB ', which is connected in the opposite direction to battery BB. The current that forms here takes the following course: 26 to PR, via 27, 41, 28, Z, voucher ee, 30, to R ', to 25. However, this circuit has the overturning of the

. Anchor r result. As a result, the action of the battery LB ceases, and the pointer G and also the pointer Z no longer move. But since in the circuit of the battery BB ' also the relay for the pressure. electromagnet DE switched on. the set type is printed at both end stations. But if the relevant key t is released, then

ίο RR and R are de-energized, and the consequence of this is, as already mentioned, that the type wheel and the pointer Z jump back into the rest position at both end stations, whereupon they are ready to experience another pre-rotation as soon as a second key is pressed, etc.

This circuit is all the more valuable because it is very well suited for so-called spark type telegraphy device remains the same here as the dd above in Fig. 1 to 6 described above. the non-conducting plate a is also provided here with two particular documents, ee. the receiving operations are discussed here in the transmission station as merely a function of a relay RR in an analogous manner as with the same relay in Fig. 6, while the same processes in the remote location (receiving station) are only related to that arrangement which is triggered as a result of the sparks or electrical waves excited in the transmitting station at the same time as RR Battery HB is closed here first by the fact that the bar y as a result of the depression de r relevant key forms a temporary but effective contact with the piece α , which contact takes place in any known manner only when moving from above down and not vice versa. In this first circuit, not only the relay RR, but also a relay RI for switching on the primary winding of the spark inductor is switched on in parallel. The developing current of the battery HB takes the following course: HB, a, y, 32, around RR, over 31, HB and also HB, a, y, 32, around the relay RI, over 31, HB. The consequence of this current connection is, in addition to that set out in the description of FIG. 6, namely the L ^T m tilting of the armature r and the switching on of the arrangement m, η in the circuit of the battery LB, the excitation of the spark inductor as a result of the response of RI. In the receiving station (remote location) the so-called fritter or the like. MM also responds, which causes the relay rm to be energized. The response of the relay j-Hi results in the same processes as when RR is triggered in the transmitting station, since the wire from the armature 34, starting with the pointer Z and the wire 33 with the wire that goes around PR and to the poles 24 and 26 goes, is connected. The resulting circuit is as follows: 23, 29, dd, Z, 38, 34, 33, 39, around PR, after 24.

At both stations, the pointers g and Z now rotate in rapid steps, as explained. If, however, at the transmitting station, the pointer Z has come to the document bb , which is connected to the pressed contact spring d , a second one is formed here Circuit from HB, which takes the following course: ILB, 35, 36, 42, r, bd, b, d, bb, Z, 32, around RR, and also around RI, via 31 to HB.

The response of RR has here, in the imaging station just the same effect result, which has been explained in the explanation of Fig. 6, with the difference that r ,, the elimination of R BEZW with the LTmkippen of. the release "of the armature of the imprint magnet DE (cf. Fig. 5) ^takes place more than the relevant key t is released.

At the same time as RR , the relay RI (or the spark inductor) and consequently also the relay rm of the receiving station respond, which means that the same thing happens in the receiving station that was going on in the transmitting relay via the relay RR, namely the Tipping over of r and thereby the stopping of the pointer Z just at the same spot where the pointer Z had reached the transmitting station, further the imprint of the type in question by addressing R and the 'immediate jumping back of Z with the type wheel in the "rest position The current that forms from BB ' takes the following course: 25 to R, over 30, ee, Z, 38, 34, 33, 39, around PR, over 40 to 26.

It should be noted here that the so-called hammer is only knocked on the fritter MM in a known manner when the impression has been taken. This results in the importance of the immediate interruption of the circuit HBbti bb at the sending station, so that the fritter MM does not continue to work due to further excitation of the spark inductor (by responding to 7? /), Which would result in a repeated response from DE or perhaps from PR would result.

The correctness of the processes in the last FIGS. 6 and 7 depends, as already mentioned, on the assumption that the step-by-step movement of the pointers g (and Z) at both end stations as soon as PR responds

is completely the same. However, if this assumption is not found to be entirely correct, this can be remedied by using a mechanical interrupter instead of the automatic interrupter U, g at both end stations. The arrangement of the disk U and pointer g would in this case be omitted entirely and simply replaced by this mechanical breaker in the circuit 17, tt, r, um in, η and 18.

Claims (5)

Patent Claims: 1. Type printing telegraph of the type in which the type of a type wheel is first set by a series of current pulses in the same direction and then printed by a current pulse in the opposite direction, whereupon the type wheel jumps back into the rest position, characterized in that for the purpose of To advance the type wheel until the relevant type is set, both as a result of a multiple automatic power interruption and as the cause of the same interruption, when the relevant key is pressed, the usual escape wheel (H) moved by means of a pointer with the help of a known electromagnet arrangement (in, n) (Contactor g), which drives a disc (U) that is soon conducting, continuing the line line, and soon non-conducting disc (U) by rotating the wheel (H) , opens the line battery current (LB) and immediately closes the line battery circuit again, and so on, until the type stopped enrades (T) for the relevant set type and.,. Imprinting the same the type wheel itself. respectively a contact spring (Z ) rotating with the type wheel (T) just at the moment when the. The relevant type reaches the paper band, closes the circuit of a local battery (UB, Fig. 5), which reverses the line current and thus stops the escape wheel (H), since the polarized electromagnet arrangement fm, η) no longer responds with this current direction, as well as the simultaneous imprint of the type. 2. In the type printing telegraph characterized by claim 1, a transmitting device consisting of a non-conductive, fixed disk A, which the latter is provided with metal covers bb, which are driven over by a pointer Z fixed on the sleeve h and each connected to a contact spring d, which contact spring is depressed by the relevant key of a suitably arranged keyboard, so that as soon as the pointer Z arrives at the corresponding document bb , a current is generated from the battery UB (Fig. 5), which causes the set type to be printed, furthermore consisting of a bar y, an immovable metal disc U provided with non-conductive points cc and a pointer g fixed on the axis 13, connected to one another in such a way that the first effect of a pressed keyboard key is the end of a current, which then automatically flows through the jumping of the pointer-g from conductive to non-conductive e places the disk U interrupts, for the purpose of creating a transmitting device which is suitable for three different circuits, namely i. a circuit in which the imprint of the set type takes place after a series of current impulses for the setting of the type has been automatically transmitted from one end station to the other by means of a line, 2. a circuit in which only one current impulse for setting the type needs to be transmitted, and 3. one in which both the setting of the type and the imprint can take place without a wire. 3. In the type printing telegraph characterized by claim 1 and 2, the connection of one pole of a line battery LB with the contact pieces e, i and the other pole with k and I (Fig. 5), and one end of the armature lever 14 with the contact pieces a and the other 15 to earth, for the purpose of using a single battery in two directions and rapidly reversing the direction of the current, and finally the connection of the strip 3; with the disc U and the two ends of the winding of the electromagnet D on the one hand with one pole of the battery UB - in that the other is connected to the pointer Z - and on the other hand with the metal rod b, in such a way that a current is generated by pressing a key forms from the battery LB , which goes via the electromagnet arrangement m, η of both end stations and is interrupted and closed again several times and automatically by the jerky advancement of g via U- , and that a second current is then formed from the battery UB , ( as soon as the pointer Z has reached the document bb , which with the spring d depressed by the key (Fig. 2 and 5) is metallically connected), at which current circuit the electromagnet D responds, whereby the direction of the current from the battery LB is reversed, which stops the type wheel at both end stations and the imprint of the set type in a known manner Consequence. 4. In the type printing telegraph characterized by claim 1 and 2, the arrangement of the documents dd, ee (Fig. 6) and the use of two local batteries BB, BB ' except for a battery LB and a line battery HB, also an ordinary, in the long-distance line L. Relay RR switched on at both end stations and a polarized reversing relay PR with the following connections: one pole of battery HB grounded, the other pole connected to a, b; ν and vv grounded; dd connected to y and at the same time to one pole of the battery BB; ee connected via relay R to a pole of the BattericBB '; the pointer Z is connected to the trunk line L and through the relay RR to the armature of RR ; the second pole of said batteries BB, BB ' via the polarized relay Pi? connected to the contact piece 27; Finally, one pole of the battery LB is connected to the metal disk U via the magnetic arrangement of the type printing telegraph (ni, n) and the other pole is connected to the contact pieces tt, which is continued in metallic form by moving the armature r to the pointer g, whereby through Depressing any key t (whereby the bar y comes into contact with the metal rod α and the relevant contact spring d comes into contact with the rod b ) first of all forms a current from the battery HB via dd at both end stations, which is activated by the relay RR at both end stations and the subsequent conclusion of a current from battery BB via dd, Z, 27, PR and BB causes the armature r to tip over at both end stations (whereupon the current of the battery LB for the electromagnet arrangement · m, η comes into play), and Immediately afterwards a second current is generated from the same battery HB via b, d, bb , which through the repeated activation of the relay RR at both end stations and d en subsequent conclusion of a current from the battery BB ' (not BB) via relays R, ee, Z, 27, PR to BB' die. Tipping of r again to the left, thus causing the current from the battery LB to be interrupted and the pressure relay R to respond. 5. In the type printing telegraph characterized by claim 1 and 2 - for the purpose of using the two power surges mentioned in claim 4 via dd and bb for telegraphy without wire connection - the introduction of a relay rni, which depends on the fritter or a similar device. MM is (Fig. 7), and the response of which results in the same processes as the response of the relay RR , and the use of the battery HB not for a current via the trunk, but for one. Local circuit in which, in addition to the relay RR , the relay RI for the primary winding of the spark inductor is included, one pole of the battery HB being connected to the strip y and the other to a metal piece a that only temporarily contacts y , as well as this The latter pole of HB is connected to b on the path 35, 36, r and bd , whereby an interruption occurs as soon as the armature r tips over. For this purpose 2 sheets of drawings.