DE73520C - Embodiments of the writing telegraph protected by patent 69964 - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The present embodiments of Gray's writing telegraph relate to FIG In the first row the device in the transmitter, which the current pulsations affecting the receiver has to send in the line. It is important that this device makes the electrical connections with absolute certainty, capable of rapid movement and not subject to destruction by friction between its parts is. These conditions are achieved through the use of an oscillating circuit make contact and -Oeffhers fulfilled, which is magnetically influenced by alternating closing and opening one or two magnetic circuits, which in turn are affected by the movements depending on the sending spring or .4 spring.

Another change is the simplification of the device that controls the receiving Has to drive and reverse the spring or G-spring.

A third purpose is to simplify and improve the device for adjusting the Paper strip, the advance of which is inevitably designed.

Finally, other changes concern details of construction and furnishings.

Fig. Ι of the drawing represents the transmission device 2 shows the same in a vertical section according to 2-2 of FIG. 1.

FIGS. 3 and 4 show a modification of the transmitter in the same way, FIG. 4 is the vertical section along 4-4 of FIG.

Figures 5, 6, 7, 8 and 9 show further modifications. Fig. 5 is side view, Fig. 6 end view, Fig. 7 jy sectional view of Fig. 6, Fig. 8 Grundrifs, partly sectional view along 8-8 of Fig. 5, Fig. 9 section along 9-9 of FIG. 5.

Figures 10, 11, 12 and 13 also represent modifications 13 is a section along 13-13 of FIG. 12,

14 top view of the table carrying the receiver,

Fig. 15 is a vertical section according to 15-15 of 14 shows the devices for moving the paper and for lifting the G -spring,

Fig. 16 is a vertical section according to 16-16 of 14 with exposure of the prime mover, the paper rolls and the devices for shifting of the paper, for reversing and switching off the engine,

Fig. 17 horizontal section according to 17-17 of the Fig. 16,

Figs. 18 and 19 show on a larger scale Drawn views of a frictionally acting and between sections of the power shaft arranged device which determines the force betfag to be supplied to the G-spring and regulates. Fig. 18 is a section along 18-18 of Fig. 19,

FIG. 20 is a view taken approximately along 20-20 of FIG. 17, with FIG Engine, its switch-off electromagnet and parts connected to it,

FIG. 21 is an end view of the half of the reversing which appears on the left-hand side of FIG. 16,

FIG. 22 associated side view in section, seen from the left with respect to FIG. 16,

23 top view of the escapement monitoring the movements of the G-spring with associated Electromagnets,

24 and 25 represent a side or Larger scale top view of the paper displacement represent.

26 and 26 a show the circuit arrangements of the transmitter BEZW. Recipient.

27 and 28 are individual representations respectively. of the main and paper switch and Fig. 29 a section according to 29-29 through both figures,

30 and 31 front and Side view of a modification of the electromagnetic contained in the reversing device Coupling.

32 and 33 are like illustrations of a modified form of this coupling.

In FIGS. 1 and 2, A denotes the sending or A -spring (pen, pencil, burin, handle set up for writing or drawing), which is connected by a flexible cord 1 to the roller 2 of the freely rotatable and return spring 5 Spindle 3 is coupled. A wheel 6 attached to the latter is fitted with teeth made of magnetizable material, that is, soft iron, which move between the pole pieces 10, 11 of two magnets 8, 9 arranged perpendicular to the plane of the wheel. The pole pieces are placed so close to one another that the teeth can just pass between them; compared to the latter, they are so tapered that their surface facing the wheel is equal to the width of the teeth. The end of a magnetizable armature 12, made of soft iron, extends between the two magnets and sits on a switching lever 21, which is located at the other end between the fixed Stromschlufsstücke 14, 15 of the circuit b and oscillates approximately around its center. The position of the pole pieces 10, 11 relative to one another can be regulated by means of the adjusting screws 16.

The .Α-nib is as in Grey's vision Writing telegraph, coupled to two such rollers as 2, each of which with a device, is connected as described.

If the .Α-spring is set in motion, it moves towards or away from the roller 2 in accordance with the letter to be formed and gives it and the wheel 6 rotary movement in one or the opposite direction. If a tooth 7 now comes between the pole pieces 11 of the magnet 9, the magnetic circuit of the latter is closed by this tooth. The two magnets are now arranged in relation to each other in such a way that at the above moment there is no tooth 7 between the pole pieces 10 of the magnet 8, i.e. the magnetic circuit of this latter magnet is open, the same thus attracts the lever 21 and places it against the socket piece 14. As the wheel continues to rotate, a tooth 7 then occurs between the pole pieces 10, while the preceding tooth moves out between the pole pieces 11. Now the magnetic circuit of the magnet 8 is closed by the tooth which has stepped between its pole pieces, while that of the magnet 9 is opened. As a result, magnet 8 releases the armature, but magnet 9 attracts it and thereby rotates lever 21 away from the end piece -14 and against the end piece 15. As the wheel 6 continues to rotate, the adjustments of the lever 21 are repeated and the result is the same caused many current pulsations in circuit b.

In the modification of FIGS. 3 and 4, one of the two magnets is supported by a spring 5 replaced, which on the lever 21 in the opposite to the attraction of the magnet 18 Direction works. The effect is otherwise that already described, since the spring 5 only forms a replacement for the magnet.

In the modification shown in FIGS. 5 to 9, which is preferably used, only a single magnet 19 is also used, but the arrangement is such that two partially independent magnetic circuits are effective. The magnet 19 is provided at one pole with an extension 20 made of magnetizable material, that is to say soft iron, which extends up to close to the teeth 7 of the wheel 6. Most expediently, this extension is formed into a fork, in the slot of which the teeth 7 protrude. The switching lever 21 is rotatably mounted on the other pole, the free end of which forks into two tips 22, 23 approaching close to the path of the teeth 7. The lever 21 is made of magnetizable material up to the pivot pin. The magnetic circuit of the magnet 19 can thus close via the extension 20, the teeth 7, one or the other of the two tips 22, 23 and the lever 21. The latter lies with its end facing away from the wheel 6 between the stationary Stromschlufsstücke 24, 25 of the circuit b. The two tips 22, 23 protrude from one another so far that, when one is in front of a tooth 7, the other is opposite a tooth gap. The relationship to the wheel is such that when the lever 21 is in a closing position, e.g. B. on the end piece 25, the one point, for example 22, is moved close to the path of the teeth and the magnetic circuit over the opposite tooth and the extension 20 closes, while the other point 23 is relatively far removed from the path of the teeth and therefore does not close the current. If, on the other hand, lever 21 is on

opposite end piece 24, the tip 23 is close to the path of the teeth, whereas the tip 22 is withdrawn so that the end of the magnetic circuit now takes place via 23. From this it follows that, as the teeth 7 come in front of the tip 22 one after the other, the lever 21 is caused to assume the position in which the magnetic circuit is closed via 22 and, on the other hand, opened via 23, and that on the other hand, when the teeth also come one after the other in front of the tip 23, the lever 21 undergoes such a change that it opens the magnetic circuit via 22, on the other hand it closes via 23. These two positions of the lever constantly alternate with one another and consequently the line circuit b is constantly and uniformly interrupted, whereby current pulsations are constantly generated in it.

Fig. 9 shows the connections of the reversing circuit d, 26 is the lever rotated by the friction of the spindle 3, which each time a reversal takes place in the movement of the A -spring, the polarity of the current sent through d reverses, whereby the direction of movement of the G-spring experiences the corresponding reversal.

In this embodiment, too, as in the first described, one of the magnetic Current paths through an equivalent part, e.g. B. a spring, to be replaced, as in one Example in Fig. 10 is shown where the lever 21 has only one tip 23 and on the same behind a spring 27 acts on the pivot point. The force of these is so measured that if there is a tooth gap in front of the tip 23 and the magnetic circuit is open, she puts the lever against the Schlufsstück 25, on the other hand, if a tooth 7 comes before 23 on it and so 'the magnetic circuit is restored, yields and the lever as a result of attraction between 7 and 23 against the other closing piece 24. The effect is in the same way as if the lever 21 were equipped with two tips 22 and 23.

In the modification of FIG. 11, the lever 21 has also only a magnetisable tip. If the disk 6 rotates in the direction of the arrow and If a tooth 7 is in front of the tip 23, the magnetic circuit is established and the tip 23 follows the tooth until the lever 21 strikes against the connecting piece 25. As a result of Continued rotation of the tooth breaks the magnetic circuit; but in the same For a moment the next tooth 7 comes so close that it attracts the point; this swings against the tooth and thereby rotates the lever 21 of the connecting piece 25 against the opposite end piece 24.

The attraction of the tooth now takes the tip again in the direction of rotation of the Wheel 6 with, while turning the lever 21 from 24 to 25, and so on. In this embodiment, the teeth 7 are most expediently designed as tips and makes the tooth gaps twice as much with the same oscillation speed of the lever 21 larger than in Figs. 5 to 9.

In the embodiments described so far, the teeth 7 receive a rotary movement. However, you can also get a straight back and forth movement. Such a device is shown in FIG. Here, a drive 28 fixed on the spindle .3 engages in a rack 29 guided in a straight line in 30, 31, the upper edge of which carries the magnetizable teeth 7 and with these in the fork of the extension 20 of one magnetic pole. fafst. The rack itself consists in whole or in part of magnetizable material. The lever 21 is rotatably mounted on the other magnetic pole 33. When the roller 2 experiences rotation in accordance with the movements of the A spring, the rack shifts accordingly and causes the lever 21 to oscillate in the same way as the wheel 6 previously did.

The invention thus includes in all cases both the to and fro, as well as the Rotation of the magnetizable teeth 7.

The expressions "close" and "open" used in the preceding for the magnetic Circuit are not accurate. Theoretically, there is no complete opening of the magnetic in any of the embodiments described Circuit takes place, but only the most essential part of the magnetic lines of force becomes deflected from the magnetic circuit in question or shifted with respect to it, a small part of the lines of force also penetrate the open circuit path. For the device to work, the lines of force are weakened in a circuit path and the reinforcement of the lines of force in the other circuit path of an actual one Opening a closed and closing an open circuit is the same.

The expressions "open" and "close" are only used because they make it clearer make that the magnetic circuit undergoes a substantial change of state, d. H. one such that it provokes the adjustment of the key lever. Even if you go for the latter Purpose created a device which actually allows absolute closing and opening of the magnetic circuit, such a device would always be be essentially the same as those described in so far as the mere change in the magnetic The strength that the latter produce comes in handy

can achieve the same effects as complete opening and closing.

Under the expression "tooth" respectively. "Teeth" should not only mean what the Technician understands by this term, d. H. single of a body or one Surface protruding pieces, but also pieces or strips of any design magnetizable material, provided that they are separated by gaps or gaps are separated, so that when they pass one after the other through the magnetic circuit go through it, a sequence of magnetic current connections and openings respectively Induce shifts in the magnetic circuit. It is also not necessary that the gaps are open, they can be filled with non-magnetic or less magnetic material be.

Attention should also be drawn to the fact that a single tooth or pair of teeth have such movement that they act upon the magnetic circuit in short intervals act, can fulfill the present purpose as well as a larger number of teeth arranged one behind the other.

The application is used to juxtapose two poles of opposite signs two poles, each of which belongs to a special magnet, a substitute for one Forms horseshoe magnets, so can, without departing from the limits of this invention in Figs. 5 to 8 the single magnet by two with opposite poles next to each other arranged rod-shaped magnets are replaced, the lever 21 rotatably on one pole is placed and the teeth 7 are in magnetic contact with the other Move pole. Only this facility would require a greater expenditure of energy. The term "magnet" means any suitable source of magnetic energy.

In addition to those mentioned, various other modifications can be made in the construction of the device without leaving the scope of this invention.

Now, one embodiment of the electrical connections between transmitters and recipient, as well as the innovations relating to the latter are described.

The main line circuit b, FIGS. 26 and 26 a, goes, depending on the position of the lever 150, which is a component of the circuit breaker B and which corresponds to the switching lever 21, from the earth through one or the other of the batteries ZZ connected to the line with opposite poles ¹ and the main switches in the escapement electromagnet H of the receiving station; In the latter it sends current pulses of consecutively alternating polarity when the lever 150 swings in accordance with the movements of the yl spring towards or away from the interrupter B. Likewise, the second main line circuit c, depending on the position of the lever 150 ¹ belonging to the interrupter C, goes from the earth via one or the other of the batteries ZZ ¹ and the main switch 100 to the inhibiting electromagnet H ^{1 of} the receiving station and sends out alternating current pulses in the same opposite polarity; when the lever 150 ¹ swings in accordance with the movements of the yi spring toward or away from the interrupter C.

The reverse circuit d goes, depending on the position of the shift lever 152 influenced by B , via one or the other of the batteries ZZ ¹ and the resistor R respectively. Via the connecting pieces 153 and 154 around R , depending on the state of the A spring, the agreement switch 89 and the main switch via the polarized relay J of the receiver. The reverse circuit goes depending on the position of the shift lever ι 51 influenced by C via one or the other battery ZZ ¹ , depending on the state of the ^ 4 spring via the resistor i? ¹ resp. via the connecting pieces 155, 156 around R ¹ , the coincidence switch and the main switch via the polarized relay J ^{1 of} the receiver.

In this representation of the electrical connections it is assumed that the transmitter is in communication with the remote receiver. If the main switch 100 is set in such a way that the transmitter is connected to the receiver present at the same point, the connections through the wires or through the main switch are established. d ¹ and e ¹ made.

To send, you take the A pen in your hand and draw the letters as you would with ordinary writing. When the spring moves downwards, pulsations of consecutive opposite polarity are in each of the two main lines b and c with the aid of the breaker B respectively. C sent while from the battery Z ¹ from positive current flows through each of the two circuits d and e . If the spring is moved upwards, the breakers B and C generate similar pulsations in the long-distance lines b and c, but now negative current flows from the battery Z through the two circuits d and e. The polarity in the reversing circuit d is changed as often as the spring is reversed with respect to the breaker B , and likewise in circuit e, as often as the spring is reversed with respect to the breaker C.

The receiving spring G or G spring consists of a tool suitable for reproducing documents etc. Here is z. B. assumed a fountain pen, which is in constant communication with an ink container through a flexible hair tube. The two arms or rods 170, 171, FIG. 14, which guide the spring, are articulated to the former and are each coupled to a pulley 94 by a cord 93 in such a way that the former is wound around the latter. The G- spring gets its movement by the rotation of these rollers, and the latter is produced in accordance with the movements of the ^ L-spring by the device described below.

The force necessary to move the G-spring is provided by a prime mover 95, Fig. 26a, delivered, and the attack of this force regulated by reversible inhibitions on their part get their movement through the current pulsations coming from the line. the The prime mover may be of any suitable type, but preferably an electric prime mover be. Such is also assumed here. The shaft 179 of this machine is related with a shaft 180 from which both rollers 94 are driven. This wave is rotatably mounted and provided with two force regulators acting through friction, which z. B. in the manner of mechanically acting (as opposed to by magnetic attraction acting) friction clutches are set up. * Each such force regulator is on one Side of the prime mover and directs its power into the role 94 assigned to it, by regulating the transmission of forces in such a way that only a constant fraction of the total Power of the machine is fed to the rollers. These force regulators are shown in FIGS. Both are in set up in the same way as follows: On a rigidly connected to the shaft 179, for example Hub 157 made of brass is a disk 158 made of glass or the like The fabric is clamped in such a way that it is pressed by a nut 161 from an intermediate washer 160 is pressed against a flange 159 formed on the hub. The pane of glass is expediently provided on both sides with a disc 45 made of flexible material such as rubber. The so tight with the shaft 179 Connected pane of glass forms one link of the power transmission device. The other Link consists of a friction pad 165, which is fixed to the in the axis line of the Shaft 179 arranged shaft 180 connected is. In the example shown, the cushion consists of ring-shaped pieces of felt, Chamois skin or similar fabric that works against the two sides of the pane of glass 158.

They are supported by putty or other suitable means on annular metal plates 166 and 167, which are ribbed for stiffening. The plate 167 is up with two a circle diameter opposed pins 168 occupied; these grasp through Holes of a resilient circular metal plate 169, which on the line of the holes is slightly inflected. Plate 169 bears perpendicular to the line connecting the holes two tabs 172, 173; through two holes these are small screw bolts 174, 175 inserted, each of which is supported with a head 164 against the relevant flap and. with its screw threaded end into one on plate 166 Flap is screwed. A two-armed one firmly connected to the shaft 180 Piece 162 has a slot 163 in the end of each arm; each of these slots holds over the head 164 of one of the bolts 174, 175. The pressure with which the friction pads 165 act against the disk 158 is thereafter regulated by the tension of the spring 169, and this is screwed in by the Bolts 174, 175 in the tabs of plate 166 certainly. When the cushions are clamped against the glass plate, the shaft 180 rotates with the shaft 179 until the resistance to the rotation of the shaft 180 is greater than the relationship between the cushions and the glass plate mediated by the friction, in which case the shaft 180 stops. By regulating the from the pillow against The pressure exerted on the glass pane can be that to be output from the shaft 179 to the shaft 180 Force amount can be regulated very sensitively.

The force of the shaft 180 serves to give the G-spring drive in one of two intersecting directions of movement. At the other end of the power shaft 179 there is a second power control device of the same type, which transmits power from shaft 79 to a shaft 181, which gives the G-spring the drive in the second of the two intersecting directions. The arrangement of the parts connected to shafts 180, 181 is the same, and a description of those connected to shaft 180 will suffice. The latter carries two pairs of soft iron disks 178, 182, rigidly connected to it. The shaft itself can be made of iron, steel or non-magnetic material such as brass. If it consists of magnetic material, however, its part between the above pairs of iron disks is made of non-magnetic material. Each pair of disks corresponds to one of the two electromagnets X ¹ Y \, each of which has two windings on the legs of one

horseshoe-shaped core is provided. The inner sides of the legs are close to one another the outer side of the associated pair of disks, with the shaft 180 slotted Embrace ends. The magnetic circuit of each of the two electromagnets is through the discs of the associated Couple and an anchor 34 respectively. 35, Fig. 21, 22 and 26 a, consisting of a: soft iron plate, which the discs on Touches the circumference and moves in the vertical direction, being supported by a rod 36 to be led. From the anchor plate 34 a cord 37 goes over a loose roller 39, around the roller 38 arranged on the spindle 46 of the drive roller 94 several times and is then attached to the latter. From the anchor plate 35, a cord 40 leads over the loose roller 41 and several times around the roller 38, at which it finally ends with her End is attached. Instead of these two cords 37 and 40, a single cord can also be used cord wound around the roller 38 several times can be used.

The roller 38 is firmly connected to the drive roller 94. The latter is connected to the ratchet wheel 42 by a coupling consisting of the ring of V-shaped teeth 47 and the pin 48 fixed to the spindle 46. This spindle carries the ratchet wheel 42. The associated pawls 105 sit on the armature of an electromagnet H ¹ respectively. H on the other side of the prime mover. The ^; The pawls and the teeth of the ratchet wheel are designed in such a way that the escapement can also work in the opposite direction if the direction of the force acting on it is reversed. The electromagnet H ¹ consists of a polarized relay of suitable design. In the example shown, the polarization is brought about by a permanent magnet 97, which is connected at one end to the iron piece 104 connecting the cores of the two coils, while the other end closely approximates the rear end of the armature 99 mounted in the frame. The two members 47 and 48 of the coupling are held against each other by the pressure of a spring 49, one end of which acts against the hub of the ratchet wheel and the other end against a loose sleeve 50 and the same against the underside of the roller 38 prefst . As long as the spring pressure acts against the sleeve 50 and keeps it pressed against the roller 38, the ring gear 47 is also in engagement with the pin 48, and the rollers 38, 94 are therefore coupled to the spindle 46, ie also to the Jamming wheel 42, so that it counteracts the tension exerted by the anchors 34, 35 on the roller 38. The sleeve 50 is provided with an all-round groove, and in this lies the forked extension of the. Armature 54 of an electromagnet O ¹ respectively. O on the other side of the machine. If this electromagnet is excited, it pulls the armature 54 downwards and thereby the sleeve 50 from the roller 38, which now falls back; the two coupling members 47, 48 come to engagement, the inhibition is released, and the G-spring can, as will be described later, move to the point of agreement. In order to forcibly move the roller 38 downwards, a screw 109 can be arranged on the extension of the anchor 54 so that its head hits the flange of the roller 38 when the anchor follows the attraction.

The electrical connections of the electromagnets X YX ¹ F ¹ are as follows: In each of the two reversing circuits d and e there is a polarized relay respectively. JJ ¹ , the armature 53 of which swings between fixed electrical circuit pieces 43, 44 and serves to supply the current of a special battery r or r ^! in one or the other of two special circuits which set the reversing devices in motion. The piece 43 is closed by wire y ^x to one end of the winding of the electromagnet F ¹ and the other end is connected by wire η to a spring 5 1 which rests on the ground plate 52, the purpose of which will be explained later. From the piece 44 a wire χ 'leads to one end of the winding of the electromagnet X ¹ , the other end of which is connected to the wire. If the current flowing through the electromagnet J ^{1 is} such that the armature 53 is held against 43, the battery current flows through the coils of the electromagnet Y ¹ and magnetizes the disks 182, which in turn attract the armature 34 and take it by them Rotation with down; so he pulls on the cord 37 and gives the roller 38 the effort to turn in the direction of the arrow. However, this is not counteracted by the engagement of the pawls 105 in the ratchet wheel 42 only when current pulsations are sent flowing over the line c through the coils of the electromagnet H ¹ ; because every pulsation causes the pawls to oscillate and thus allows the roller 38 to turn further by half a tooth width of the ratchet wheel. Meanwhile, the rotation of the roller 38 has wound the cord 40 accordingly and thereby pulled the armature 35 upwards accordingly. The armature 34 is continuously pulled down and the roller 38 continues to rotate in the direction of the arrow until the polarity in the circuit e is reversed and consequently the position of the armature 53 of the electromagnet J ^{1 is} changed. Kick

If this change occurs, the current of the battery r ^{1 is passed} into the circuit x ^l , i.e. h, by the winding of the electromagnet X ¹ . The armature 34 is released from the disks 182, while armature 3 5 is drawn along by the disks 178; the tension on the cord 37 ceases, but tension is exerted on the cord 40, and consequently the roller 38 is driven in the direction opposite to that of the arrow.

The mode of operation of the receiver described so far is as follows: During the graph, the shaft 179 of the machine is in uninterrupted rotation and drives the shafts 180 and 181. If one or the other of the electromagnets X ¹ F ^{1 is} energized, it pulls the cord gripping its armature downwards and thereby gives the roller 94 driving the G-spring drive in one direction or the other. When the current is in the line, the roller can only follow this drive if the armature 99 carrying the pawls 105 oscillates and thereby lifts them out of the ratchet wheel 42. The pulsations of alternately opposite polarity sent by the transmitter into the line cause the polarity to change in the pole pieces of the electromagnet H ¹ , whereby the armature 99 is swung first to one and then to the opposite side and allows the jam wheel to move with each pulsation, i.e. step to continue rotating step by step, in the direction in which the pull is being exerted. If the direction of movement of the ^ 4 spring is reversed, the polarity of the current flowing through the reversing circuit is changed. The armature of the electromagnet J ¹ follows this change, and the electrical state of the electromagnets X ¹ Y ¹ is reversed into the opposite one, so that the roller 94 now tries to change its direction of rotation, including the direction of that movement which it is making the rod 170 that guides the G-spring. The movement is continued in this reversed direction until the polarity reversal occurs again in the reversing circuit.

Since the main circuit b also contains a polarized electromagnet H and the reversing circuit d an electromagnet /, and the other devices are the same as described for c and β , the same effects are produced with regard to the second guide rod 171, whose reversing electromagnet is denoted by XY and are connected to the connecting pieces 43, 44 by conductors χ or y (Fig. 26 a).

Any movement of the 4-spring from each of the breakers B respectively. C away from or towards the same causes the G-spring to move in the corresponding direction, and the movement of the G -spring is made up of short steps; any movement of the A -spring in a direction lying between the above two directions also causes the G-spring to move in the same direction, but with a movement which is made up of a number of steps at right angles to one another, the number of Steps in each direction depends on the greater or lesser steepness of the spring tension.

The device for lifting and placing the G-spring is similar to the known one. The reverse circuits d and e contain resistors R BEZW at the transmitting station. R ¹ and the changes in the strength of the currents flowing through those circuits, brought about by switching the latter on and off, are used to bring the lifting device in the receiver into action. The writing pad of the transmitting station rests on a held and lifted by spring force. in 113 rotatably mounted plate 118, Fig. 26. The rear extension 114 carries two closing pieces 154 and 156 .; when 118 is raised, 154 is in contact with a fixed closing piece 153; if, on the other hand, the plate is lowered by the writing pressure, the joint between 153 and 154 is released, and the second joint piece 156 is placed against a second fixed joint piece 1 5 5. As a result of this adjustment, the circuit e is short-circuited around the resistor R ¹ , the circuit d , on the other hand, is passed through the resistor R , with the result that the current strength becomes stronger in e and weaker in d. In each of the circuits d and e there is a relay P respectively at the receiving end of the line. P ¹ , Fig. 26 a. The resistors RR ¹ are regulated with respect to the tapping springs of the latter in such a way that the armatures are only attracted when the resistors are switched off. So if the A -spring is placed on the paper, the relay P releases its armature, whereas the relay P ¹ pulls its own; if, on the other hand, the spring is lifted, P draws his anchor and P 'releases his own. The raising and lowering of the G - spring is carried out by two electromagnets S and T arranged one above the other in connection with two batteries ν and y ¹ . Both electromagnets have a common armature 129 arranged between them, on which the spring holder 130 is fastened. The circuit of the electromagnet S goes through battery v, armature 133 of P ¹ , connector 134, wire s, connector spring 117, plate 52 to earth. The circuit of the electromagnet T goes through battery v \ armature 132 from P, connector 128, wire t, spring 116 and plate 52 to earth.

If the A spring is put on, the resulting weakening of the current in the circuit d causes the electromagnet P to let go of its armature, so that the electromagnet T is excited; At the same time, the increase in the current in the circuit e causes the armature 133 to be attracted by relay P ¹ and thereby the opening of the circuit of the electromagnet S. The armature 129 moves downwards and places the G-spring on the paper by taking the spring holder 130 with it. The G-spring remains in this position until the processes are reversed by lifting the A-spring.

From FIGS. 15, 16, 24, 25 and 26a it can be seen that the paper is inevitably adjusted and the feed rollers are driven directly by the main shaft 179. The latter is provided with a pair of soft iron discs 55, similar to the reversing device. The same protrude between the pole extensions of an electromagnet F. The armature 56 of the latter can slide back and forth horizontally, being guided with the rear extension 57 in the column 58 (FIGS. 15, 24 and 25). At the front end it is articulated to a lever 59 mounted on column 60, which seeks to rotate a torsion spring 61 against the electromagnet F. The other end of this spring is attached to an adjustable piece 62 to regulate its tension. The paper is removed from the roller 63 and pulled over a guide roller 64 by two pulling rollers 65, 66. The upper of the latter has its bearings in two arms 67, 68 of a shaft 69 mounted in the frame; Springs 70 pulling the outer ends of the arms press the upper roller against the lower. An extension of the pin of the roller 65 comes out through a slot 71 in the frame and here carries a gear 72 which is in engagement with a gear 73 wedged onto the axis of the lower roller 66. Two projections 75 fastened to the shaft 69 provided with the handle 74 lie against the pins 76 and yy of the arms 6γ and 68, so that the roller 65 can be lifted off by pressing the handle 74 down. In a ratchet wheel 82 fastened on the axis of the roller 66, two spring-loaded pawls 80 and 81, which are seated on the lever 79 mounted in 78, engage. The lower end of the latter fafst into the fork-shaped end of the lever 59. The shaft 179 respectively. the disks 55 rotate in the direction of the arrow. When the electromagnet F is energized, the armature 56 sticks to the discs and is carried along to the left (Fig. 24), whereby it moves the lower end of the lever 59 to the right (Figs. 17 and 25). This movement continues until the armature projection 83 opens the circuit of the electromagnet Fin 136, FIG. 26 a, and thereby prevents its further forward movement. The torsion spring drives the armature back, the circuit of F closes again, and the armature moves forward again quickly until the electromagnet F is de-energized again, and so on. The advance of the armature 56 is such that the pawl 81 rotates the roller 66 until the pawl 80 falls behind a tooth of 82. This advances the paper by the line spacing. The paper rolls are now held in place by the pawl 80 until the next anchor advance. When 56 returns to its normal position, it gives the pawl 80 a slight forward movement, thereby rotating the roller 66 forward a little and tensioning the paper. The feed rollers, drive wheels, and other parts of the device are adjusted so that each time the electromagnet F is energized, the paper is drawn forward by a distance of two lines.

The circuit of the electromagnet F goes from the earth through the battery v, armature 133 of the relay P ¹ , connection piece 135, wires hi, switch 136, the position of which depends on armature pin 83, wire Ar, winding of F, wires Imp, connection piece 137 , Armature 132 of relay P, battery v ^l to earth. Electromagnet V is therefore only excited when both relays attract their armatures. This only happens when the full current flows through the two circuits d and e . This power transmission is made possible by the so-called agreement switch of the transmitting station. It consists of an arm 89, FIG. 27, which is fastened to a stationary spindle 90. On the latter sit two triangular pieces 91 and 92, Fig. 29. For each of these, a pair of spring springs 119, 120 and 121, 122 is arranged (Fig. 26). 119 and 121 are respectively with the circuits d. e connected, the springs 120, 122 with the batteries Z respectively. Z ¹ through wires α a \ The pieces 91 and 92 are in connection with the circuits d respectively. e, which continue from them via the main switch 100. Shaft 90 is usually held against a stop by a spring. In this situation, the circuits are de over 121 respectively. 119 closed. If the sender now wishes to set the device for establishing the match in motion or to cause the paper to be shifted at the receiving point, he moves the ^ 4 spring against the arm 89 and rotates the latter until the circuits d and e via 119 respectively. 121 open and over 1 20 resp. 122 to be closed again. Now electricity flows from Z respectively. Z ^x into circuits d and e

over the wires α respectively. a '. These currents have full strength, since they are both independent of the resistances RR ^x , and therefore cause armature attraction by both relays PP ^{1 of} the receiving station, ie the closure of the circuit, the electromagnet V and thus the paper displacement.

Some of the various advantages of the described device for displacing the Paper, that it draws the necessary force from the prime mover moving the G-spring, that it ensures a certain advance of the paper, whether the switch is longer or shorter Time is kept in the position necessary for the displacement, so that the length of the advance regardless of the thickness of the paper layer on the roll and therefore uniform is that the apparatus is limited in its effect, and finally that these effects can be achieved by a very simple design.

The device for establishing the correspondence between the movements of the two springs consists of two electromagnets OO ¹ , FIGS. 16 and 22, each of which is provided with an armature 54 forked at the free end to encompass the sleeve 50 already described. Each of the two electromagnets is in a secondary loop 0 o ¹ to the electromagnet P respectively. P ¹ . So they are only excited when they attract their armature at the same time, and this occurs, as already explained, only when the sender switches the switch 89. When energized, the electromagnets OO ¹ pull the sleeves 50 downward against the resistance of springs 49 by means of armature attraction, so that the clutches 47, 48 and thus also the drive rollers 94 are released from the locking wheels 42. Each roller 94 can now freely follow the course which the currently active electromagnet X ¹ F ¹ resp. XY initiates, and the G - spring quickly follows the drive given to it by the respective electromagnet, and moves up to the limit which its movement is set in the respective direction. Since both rollers 94 are released from their jamming wheels at the same time, the G-spring moves in the direction resulting from the two drive directions. The connections of the wires α α ¹ with the batteries ZZ ¹ are such that the currents sent through the reversing circuits de cause the G-spring to move at a point which corresponds to the position of the 4-spring when it is on the switch 89 , ie near the top left corner of the writing field. At this point, it is inhibited by the pieces 84, 85, FIG. 21, arranged on the guide rods hitting against pieces 86, 87, which are arranged on the anchors 34, 35. From this arrangement it follows that, if the G-feather was ahead of the A -feather, it will be overtaken by the vl-feather at the excited extreme point of its movement at the moment of the paper displacement, and, on the other hand , if the A- feather was ahead, it will overtaken by the G-spring at the same point.

When the device is in operation, the circuit of the prime mover 95 via battery u by wires u \ spring 88 and plate 52 is also closed. The latter acts in conjunction with the closing springs lying on it as a circuit breaker in order to prevent loss of battery power when the device is inactive. Two electromagnets LL \ in the circuits d respectively. e, have an armature in common, and a lever 98 is connected to this, which carries the plate 52 on a non-conductive block and can also oscillate in the horizontal direction, ie perpendicular to the armature movement.

If the electromagnets LL ^{1 are} not energized as a result of interruption of the circuits de , then lever 98 engages in a further to the right rotated position with a pin 103 in a screw thread 108 arranged on the shaft 179. Now one or the other of them receives by Schlufs the circuits d respectively. e current, the pin 103 is pulled out of the thread by the armature attraction and a spring 106 swings lever 98 to the left with the connecting piece under all the connecting springs 51, 117, 116 and 88.

If, however, the device is set to action and no current flows through one of the reversing circuits de , then the armature 97 is released, the pin 1.03 is placed in the screw 108, thereby turning the lever 98 to the right until the springs from the plate 52 open step the non-conductive block 102, which opens the relevant circuits. The secondary spring 88 which supplies the prime mover with current is arranged in such a way that it slides off the plate 52 last. If, therefore, lines d and e are de-energized, the various circuits of the receiving station and finally also the machine circuit are only interrupted after a few revolutions of the prime mover. The final springs are set with respect to the plate 52 so that the interruption does not take place when the coincidence of the two springs is checked or. want to improve or move the paper, that is, the point of agreement is reached before the springs move on the non-conductive block 102.

At each point there is a transmitter and. a receiver set up. It's the one for Gray Telegraph known device, that by inserting the / t-spring in

a holder a changeover switch (main changeover switch) is adjusted so that it places the receiver on the line. Fig. 28 shows such a device. The adjustment of the connecting pieces 109, 110, 111, 112 connected to the spring holder interrupts the connection of the transmitter with the line wires bc de and connects them to the wires b ^l c ^l d ^l e ¹ leading to the receiver at the same point. In the modification of the reversing clutch shown in FIGS. 30 and 31, the electromagnets X ¹ Y ^1, each with the sleeve 123 carrying the winding, are pushed loosely onto the soft iron core 125 firmly connected to the shaft 180; the winding is secured against rotation by the shaft 180 by fastening it to a ring 124 held by the column 126.

The anchor 128, to which the cord going to the roller 94 is attached, lies on the circumference of the soft iron disks 127 connected to the core ends. The operation is the same as that of the embodiment described earlier. One equivalent arrangement would be to mount the coil on the core and the usual To provide means to guide the currents from the windings into the fixed conductors.

In the modification of FIGS. 32 and 33, the soft iron disks 138 are connected to one another and rigidly to the shaft 180 by a sleeve made of soft iron 139. The member of the coupling sliding in the vertical direction consists here of the core 140 of the electromagnet itself. The coils can move with the core or they can be fixed, in which case the core shifts within the coils, as in FIGS. 32 and 33, where the coils of X ¹ and Y ^{1 are} mounted on supports 141.

Although the parts of the device which are the main parts of the present invention form, in conjunction with particular embodiments of the others drawn and parts described are shown, this invention is not related to application the parts in this connection alone, but also in every execution both in connection with parts other than those described and drawn, as well as in connection with other mechanisms by which they can take effect.

Even if an electric prime mover is preferred as the power source because it is faster from the transmitter is so limited than any other type of prime mover The subject of the invention is by no means based on this source of power, but rather it can be replaced by any other suitable type of mechanical prime mover or a Kick weight or a shaft driven by any power source.

Under the expression "letters" should any characters, maps, plans, drawings, diagrams, etc. can also be understood, likewise, the term "paper" should be anything suitable for writing, drawing, etc. Include area; because when the apparatus for reproducing drawings and the like. is to serve, there is nothing more to be done than the possibility of extensive movement for to create the j4 spring and G spring.

If you want the telegram in the usual way as a continuous line on a take up narrow strips of paper, only the device for shifting the paper is like that to arrange that the paper is drawn forward in the line direction instead of perpendicular to it will.

If desired, the G- nib can be made of an ordinary pencil and the ink container can be omitted.

The movements necessary for reproduction can also be completely communicated to the paper instead of the G -pen, or partly to this part and to the other part of the G-pen, that is, the movement of the writing surface is only to be regarded as a substitute for the movement of the G-pen .

The application of the changes described with regard to the transmitter is completely independent on the establishment of the receiver, as well as the establishment of the transmitter and the breaker without influence on the application the facilities described in relation to the recipient. The term "interrupter" is intended to mean any device be understood, which can serve to prevent current surges, regardless of whether of the same or of alternately opposite polarity, to be generated in an electrical circuit.

The inventor's claims are not limited to devices from the described and illustrated facility, but includes in the same all somehow designed Devices, which in the field of telegraphy as an equivalent substitute of the various institutions described, or of their essential parts are.

Claims (4)

Patent claims: i. An embodiment of the writing telegraph protected by patent no. 69964, in which the conversion of the movements of the A- spring into the current pulsations influencing the escapements (42) of the G-spring by magnetic influencing of the circuit (b) and respectively. (c) working changeover switch (21) is effected in such a way that a) the switch at the same time the common armature of two their poles facing magnets (8, 9), Fig. 1 and 2, respectively. . Joined with Abreifsfeder armature of a magnet (18), Figures 3 and 4, forms, and ¹ is the magnetic circuits are alternately opened and closed by a series magnetisirbarer teeth (7) projecting from the through A - driven spring spindle (3 ) are moved through between the magnetic poles; or b) the switch (21), with its magnetizable front end lying in a recess of one pole of a magnet (19), one swinging moving extension of the same, on the other hand the row of teeth mentioned under a) one side moves in the slot of an extension (20) of the other pole or close to this extension forward pole extension forms, and wherein the switch the teeth opposite either with two pole tips (22,23), Fig. 5 to 8 and 12, or instead with only one pole tip (23), FIGS. 10 and 11, and one is provided to replace the other tapping spring. 2. An embodiment of the writing telegraph protected by patent no. 69964, in which the connection of the G- spring with the power shaft is effected by the fact that the electromagnets (de) influenced ^{by the reversing circuits (X 1} Y ¹ XY) are caused by rotating soft-iron disks (178, 182 ) have an attractive effect on magnetizable plates (34, 35) which are movable tangentially to the latter and are connected by a cord and roller to the spindles of the rollers (94) driving the G-spring (FIGS. 21, 22, 30 and 31), and these plates at the same time can also form the cores of the electromagnets (Figs. 32 and 33). 3. An embodiment of the writing telegraph protected by patent no. 69964, in which the connection of the drive rollers (94) of the G- spring to the power shaft (179) through the intermediate shaft (180) is effected by friction in such a way that one on the former Fastened glass pane (158) covered with leather, etc., is clamped between two washers (166, 167) which are connected to arms (162) of the intermediate shaft by adjusting screws (174, 175), and the friction between the two parts by one between the heads These screws and the inner ring washer clamped plate spring (169) is regulated (Fig. 19). 4. An embodiment of the writing telegraph protected by patent no. 69964, in which the paper displacement is derived from the force wave driving the G spring in such a way that the latter is guided horizontally by means of soft iron disks (55) rotated between the pole pieces of the electromagnet (V) and pulls the armature (56) connected with the switching mechanism that rotates the paper feed roller against the resistance of a spring (61) until it automatically opens the circuit of the electromagnet (V) for a moment after a certain advance and is thereby withdrawn by the spring for repeated advance ( Figs. 24 and 25). In addition 4 sheets of drawings.