DE4795C - Telegraph chime to wake up a particular station on the line. Dr - Google Patents

Description

1878.

Class 21.

Dr. C. WITTWER in REGENSBURG.

Telegraph chime to wake a certain person on the line

Station.

, Patented in the German Empire on July 24, 1878.

Between two vertical brass stands A and B, Fig. 1, there are two vertical axes α α and a _t Ci ₁ . With the axis α α two disks c and c ' are firmly connected, of which c has a tooth-like protrusion, while c' has two such teeth behind each other. Outside B, the axis aa ends with a disk d firmly attached to it; initially at A there is a disk e , which is also firmly connected to the axis α α. A steel pin g is attached to e , FIGS. 1 and 5. The disk e with its pin g is shown in a different position but with the same letters in FIG. Against c and c ¹ , e is placed in such a way that, when the teeth of c and c ' are up, g is directed downwards.

At the axis A ₁ α, Fig. 1, the arrangement of α α is repeated, only with the difference that both disks C ₁ and c _t 'have only a single tooth.

Between the axes α α and α _γ Ct _{1 there} are two other axes hh and h 'h', the insertion of which can easily be seen from FIG. Although one axis is the continuation of the other, both move independently of each other. Firmly connected to these axes are the four wheels i 'i "i'" i "" each with twenty teeth, which match the teeth of the disks cc ¹ C ₁ C ₁ '. In addition, the two disks k and k 'are attached to the axes hh and h' h '. These discs can be rotated around the axes with friction and consist of a disc of gutta-percha and one of brass. The brass disk is somewhat smaller than the other, and only has such a bulge in a very small section that it reaches the periphery of the gutta-percha point there. This is shown in FIG. A sliding spring f prevents the axis hh from turning by itself. An electrode of the local battery is screwed into each of the heads K.

The plate C is parallel to B, FIG. 1. On the side of C facing away from B there are four wheels, which are also shown in FIG. The two smaller wheels in FIG. 3 correspond to / and I ₁ in FIG. 1. FIGS. 2, 3, 4, 5, 6 and 7 are drawn in such a way that when they are rotated by 90 ° and in connection with FIG the parts shown on the left are turned away from the viewer.

The lower small wheel, Fig. 3, moves in the _{position indicated by Z 1} , Fig. 1, on the lower side towards the viewer, while this is on the upper side. Of the two larger wheels in FIG. 3, one is connected to a matching axis of the clockwork on the Morse's watch apparatus; but the type of connection is to be ignored as being essential here.

On the same axis with the wheel /, Figs. 1 and 2, on the opposite side of C is the gear 0, Fig. 2. Owing to the action of the spring /, 0 can rotate itself, albeit with resistance when d, ι. Figure and is established. 2 if d can move rotates 0 the same with, so as DAF also the axis α α the disks and located on their turn. the same also applies to I ₁ Oy and ( Z ₁ and the axis 1% α _% . The springs / and pi are set so that their resistance stops the clockwork when α α and Ci ₁ α _t are locked at the same time, but that this works if only one of the two axes is stopped.

Fig. 5 introduces the relay. P means one pole of the electromagnet, the other is behind it. S and Si are magnetized steel plates, one of which faces one pole, the other the other, facing the observer, while the opposite pole in each case lies opposite the second (not visible in the drawing) pole of the electromagnet. In the middle of the steel magnets there are brass rods which can be rotated around j and S ₁ and thus form two-armed levers, one arm of which is closed by the steel magnet S and the other by the hook t .

The disc e, Fig. 5, corresponds to the one marked with the same letter in Fig. 1. Just as for e , the construction for ^ _{1 is} , and there is only the difference that the hook Z _{1 is} the pin belonging to ^ ₁ ^ ₁ catches when it is directed upwards. Around

Not to confuse the drawing, t _x and g have been omitted.

With regard to the line battery, it is a prerequisite that one or the opposite current can be used at any time when the current is introduced at the individual stations, and when the main station is closed. The current which is used to transmit the dispatches and which, when the quiescent current is used, continuously runs through the line, will be called the current in the following. The - current attracts the armature S _1, Fig 5, the + current to the armature S.. If the line current is now interrupted and the + current is introduced for a moment, S is attracted; the hook t moves away from the pin g and this makes one turn in the direction of the arrow. After completion of the rotation, g is caught again by the hook t , which has meanwhile returned to its original position. This return is provided by a spring located at S , omitted in the figure, which pulls S from the electromagnet. If g rotates, the disks c and c ', Fig. I, also make one revolution, the wheels V and i " rotate, the former by one, the latter by two teeth, and the gutta-percha discs also move by the value of one or two Teeth forwards If the + current is closed for the second and third time and immediately interrupted again, the total rotation is at k + 3, at k ' + 6. If one then closes the - current for a moment, g _{t is released} and k and k ' each go back by one tooth value. This results in the end shifts + 2 at k and -f 3 at k'.

The disks k and k ' are, as indicated above, rotatable about their axes with friction, and are given such a position that the protrusions of both brass disks touch the slide springs. As soon as the position + 2 and + 5 is entered, the current of the local battery closes (in the arc of which an alarm clock is switched on), because the current from one button K, Fig. 4, through the slide spring, the brass plate, the device to the other brass plate and through the second slide spring on button K ₁ .

If, instead of closing the + stream three times, this had been done four times, the displacements of k and k 'would be + 4 and + 8. If this is followed by the ■ - current, the result is + 3 and + 7 · are at a second Station the disks kk 'are set so that the local current is closed during this shift, so it rings here. It does not ring, however, if the + stream has only been closed three times because the protrusions of the plates kk 'are not in contact with the slide springs. If you let the - stream re-enter from position + 3 and + 7, the ringing will stop at station II, because the disks kk ¹ are now in positions + 2 and + 6. In position - + 2 and + 6 is now, however, at station I the outstanding in k on the slider spring ;. but it cannot ring because the current is interrupted at k '. If the ringing is to occur, the slide spring must be in contact with the brass tooth on both k and k '. It can therefore not ring if the stream is closed again and the position -f- 1 and + 5 occurs.

If, starting from the zero position, one closes the + current five times one after the other, then the shifts of k and k ^{1 are} consecutively + ι and + 2, + 2 and +4, +3 and -f 6, + 4 and -f- 8, + 5 and + 10. The combinations + 2 and + 5, then + 3 and + 7 do not occur here; so it cannot ring at the two stations. However, one fell asleep. the - current once, the position is + 4 and + 9, and if at a third station the disks k and k are set accordingly, the bell rings here. Continued introduction of the - current gives + 3 and + 7, -1-2 and + 6, + 1 and + 5, etc. The apparatus therefore returns to its starting position without it having rung anywhere other than the third station.

The + stream is closed once more for each additional station.

It is essential that the slices kk 'are set in such a way that the local stream is closed when, after the appropriate number of + streams, the ■ - ■ stream has entered, otherwise the previous stations will ring when a subsequent one is called target.

Zero position. If the ringing is to occur safely, the disks kk 'must always start from ο when a call is to be made. So each time the current has to act until this zero position is restored. This takes place automatically. If a station is called, all ^ -discs move along the whole line if it rings at just one station. After the call comes the speaking. This happens exclusively with the - current, and with quiescent current lines it is also this that runs through the line. Even if a telegram is so short, enough locks occur to bring the disks k k 'back to the zero position. It is only necessary to ensure that kk ^{1 are} not moved beyond the zero position to the · - side. This can be avoided in two ways.

A tooth is broken out on gear wheel i "', Fig. 1, before the regulation of kk' . If, when the current is repeated, the tooth gap opposite gear C ₁ stops, all movement of / '" and k ceases. So this is the zero position, and it is to this that / 'is regulated.

On the axis h ¹ h ¹ , i.e. at i "", this breaking out of a tooth cannot be used, because with continued telegraphy or with quiescent current lines even at those stations after which telegraphing is not carried out, the clocks would run down in a short time.

In Fig. 6, r represents a cross section of the axis h 'h', Fig. I, and ί a cross section of the axis α, «,. The lever arms u and υ are mounted vertically on both axes. Let the direction of u and υ indicated by solid lines be that of the zero position. If the + current starts repeatedly from this point, u jerks forwards in the direction of the arrow and finally assumes the position indicated by the dotted lines, while the lever ν , which can only be moved by the current, remains at rest. If there have been as many inflows of the -f current as are necessary to call a given station, then it is the turn of the -f current. If this happens only once, ν makes one turn around its axis in the direction of the arrow, and u goes back one step. Now comes the telegraphy, that is, an often repeated introduction of the current, and as a result of this u gradually returns to the zero position at all stations. Once this has happened, it stops the lever arm ν , and it can no longer turn. Since the rotation of the axis β, ", is no longer stopped by the hook t, but by u , one can now telegraph, a quiescent current can pass through the line. The whole apparatus remains completely immobile, and therefore the clockwork does not run down either. Only when the + current comes back when a station is called again and the lever u is moved from the zero position again, the lever υ can move again when the - current starts, until the zero position is there again if the bell does not ring. So both k and k 'must always start from the zero position. The position of ν on the axis a _t Ci ₁ is such that the lock occurs when the pin g is so that it has almost, but not quite, reached the hook ₁ , Fig. 5, which holds it open.

It can be seen from the foregoing that the apparatus is always at a single station can ring. With every call, all the devices move, but they return back to the zero position itself.

Should get mixed up with -f and - If the apparatus gets into disorder, for example during thunderstorms, everyone comes back back to the zero position if the current is passed through for some time, which is the case with closed-circuit lines happens by itself.

In the case of lines with introduced or working current, one of those described above is required Apparatus at every station. At rest.

power lines, the battery would have to be relocated entirely to the main station, from which the individual stations would be called. In practice it only happens in exceptional cases that telegraphs are to be sent from one secondary station X to the other secondary station Z within a closing arc, because the majority of dispatches use the switching of the main station. Should the exceptional case arise, X would have to give the signal to the main station that Z should be called, which does not entail any significant loss of time, because an official is always present at larger stations. If the call is made from the main station, X can telegraph to Z as before without using the main station any further.

For quiescent current lines, bells of the type described above are to be used at the secondary stations necessary, a mere alarm clock at the main station or, as is usually the case now, no apparatus at all.

Calling without changing the current direction: Should be without changing the current direction be called, which therefore requires one of the generally used quiescent current batteries, a few changes must be made to the apparatus described above.

The disks e and e _x , FIG. 1, are placed vertically one above the other and are given the shape indicated in FIG. 7. Of the levers S st and .S ₁ Si ti, Fig. 5, the former fails, the latter gets a downward and an upward hook.

Both disks e and <? ,, Fig. 7, can rotate and can be locked as in Fig. 1. The places where the disks are locked by the corresponding hooks are those where the radius suddenly increases. If the hook / is then lifted momentarily, the disk goes to the last point at which the radius increases again, and it turns out that when the hook is lifted four times, one complete revolution takes place. As long as the sector passes its hook with a larger radius, the other disc is blocked.

Fig. 7 shows the apparatus in the rest position, in which e is blocked by the upper hook, <?, by the lever uv, Fig. 6. When the current is interrupted for a moment, then moved e .sich until it has made a quarter turn, it may become the power to be closed or opened. During the first half of the movement, e, is blocked. If the chain is closed while the smaller sector of e is below, e _x begins to move, and as soon as its larger sector slides under the hook t , it blocks e independently of the current. So there is a double lock there. A disc locks the other, their grofser Sector t over is so long. It is impossible that ^one is

at the same time on both sides of the great 'Sectoren t are facing; this case can, however, occur with the small sectors. As long as this is the case, the lever j t can also move, and it blocks e when the current is closed. So this lock by st is the second. _{^ 1} can also be blocked by ί t if a large sector arrives at t with an open stream.

The telegraph is based on an alternating opening and closing of the stream. If the sum of the closing times lasts just as long as the times when the stream is open, then e and e will be blocked for the same time and be in motion for the same time. Since the effects exerted by both on k and &, Fig. 1, are equal in magnitude and opposite in direction, they cancel each other out, and the result of telegraphing is the maintenance of the zero position. It is essential that the latter should be left only temporarily and only a little while telegraphing. 7 is based on the assumption that the time of the opening is the same as that of the closing. Should the former turn out to be superior, the larger sectors in e would have to have a correspondingly larger (or in e a smaller) centri-angle than the smaller sectors. Failure to use e _t does no harm, e must be avoided.

If a station is to be called, a very simple pendulum is used, which the officer has to start. As well as this pendulum once the equilibrium position passed, the button is to be depressed, and a given number of vibrations through it keep depressed. For each station the number of oscillations necessary is one other.

It is evident that in this way the + - displacements of the k- disks must occur, and the pendulum could easily take the place of the multiple closings of the - current mentioned above. As there the disks kk ^{1 are set} to more or less often repeated closings, so this happens here with oscillations of the pendulum.

When the appropriate number of oscillations is reached, the button is released, so the current is closed again. The disk e is blocked and ^ ₁ leads kk ' back to the rest position. The time must come at the called station, but at this station alone, in which the protrusions of both disks kk ', FIG. 4, are in contact with their slide springs. During this time you can use an electromagnet to trigger the alarm clock of a clock or switch on an electric alarm clock. In the latter case the anchor closes the local battery _; and it '"- it would only be necessary to omit the usual spring which pulls the armature off the magnet. This pulling would have to be done by the official who came over, whereupon the ringing would stop.

In the invocation procedure with currents the drives of the various stations are only in progress while the call is being made, if a dispatch is not sent to the station itself. In the case of the apparatus without current reversal all clockworks run along the whole line even while telegraphing. However, they stop when the telegraphy ceases; but it can easily happen that the clock is absent of the telegraph operator expires, and then, if the station should be called afterwards, failing service. It is true that a device can easily be produced, by virtue of which the clock rings when it is up; but it is in the nature of things that this shouldn't happen too often.

To avoid this imbalance, the drive must be given a slower gear. This is done simply by providing one of the wheels / or /, Fig. 1 and 3, with a correspondingly large vestibule. In this way, the expiry time can be increased many times over. This device also offers the advantage that the springs p and p _{according to} FIG. 2 are also more spared, which is why it is also recommended for devices with a current change.

This device is on the aisle of the drive while a dispatch is being picked up without influence, because when the officer wants to receive a dispatch, he solves it through mediation one lever just as he currently does in the same Fall sets the previously blocked drive in motion.

If the rate of the clock is very slowed down during the absence of the telegraphist and as long as there is no telegraphing at all, then one needs a lot of pendulum oscillations to call, which results in an uncomfortable loss of time. To prevent this, you can bezw on the disks cc 'C ₁ and C ₁ '> Fig. I, two or more teeth. Attach pairs of teeth in equal spaces. It is only to be avoided that the disks c c ' and the disks C ₁ c \ simultaneously engage in the teeth of the / -wheels. For this purpose, the device is made so that the teeth engage in i every time a large sector, Fig. 7, is opposite the hook t , i.e. the other disk (e or e _t ) is blocked. At the indicated in FIG. 7 means could therefore attach of 90 ° c or four teeth (in c ') pairs of teeth at intervals. If one wanted to increase the number still further, this would also have to be the case with the large sectors of ee _1} Fig. 7.

Claims (1)

The difference between the pager with current alternation and the one without the latter is based, according to the above, on the modification of the disks e. (possibly also c) by increasing the number of teeth. Furthermore, in the case of the apparatus without a current change, the vestibule and the electromagnet on the alarm clock are necessary, for which one of the levers Sst, Fig. 5, fails. In essence, the calling procedure is based on the following: By opening and closing the stream of lines becomes a clockwork (which the drive of the Morse apparatus can be used as) triggered and inhibited, and this clockwork is used to move the whole apparatus. If the battery permits the use of both currents, the differences in the number of teeth of two evenly moving wheels with repeated opening and Closing the chain shifts two conductors achieved. The magnitude of the shifts depends on the number of closings, and the ladder moved in this way in turn close the local battery at the called station, which then sets an alarm clock in motion puts. The shifts are the same on all stations, but each station requires another shift, d. i. another number of closings of the line stream, if you want your alarm clock to ring. The return of the ladder to its original position is facilitated by the earlier one opposite current causes, which two other wheels of among themselves the same number moving teeth. To prevent the two conductors from going backwards over the starting position going out, a tooth will be broken out of a wheel that moves with one conductor, while one with the other Head moving wheel is locked by two levers hitting each other. Through this the device is independent of the current until the call is renewed Causes shifting of the ladder. In the case of quiescent current settings, which allow the use of only one current direction, the displacement of the two conductors by interrupting them for a longer period of time of the current, the return to the starting position, on the other hand, by closing of the stream. Every single station here asks so much if it is to be rung Time of uninterrupted opening of the stream than in the previous case the number associated with it caused by closings of the current necessary to move the conductors. Sponsorship τ claim: The chime as described and drawn above. 1 sheet of drawings.