DE590995C - Fast telegraph with punched tape encoder - Google Patents

Description

With high-speed telegraphy it is important to consider the disadvantages that come with -wear of the contacts connected by power interruptions should be avoided if possible. It is already has been proposed in electrical surge distributors for pressure telegraphs instead of the usual brush-making segments on the distributor surface or to arrange a series of electromagnetic pulse coils on the frame separately from a pick-up coil and the To attach the pick-up coil so that it sweeps past the row of pulse coils and current surges can be transmitted by induction, but here too the electromagnetic Pulse coils can be controlled by contact closings and openings. The invention relates to a different type of high-speed telegraphs, namely to high-speed telegraphs with punched tape dispensers. With these it was customary up to now to carry out the control through the punched tape in such a way that that scanning is accomplished through the holes so that every time the scanning lever comes over a hole, a Contact is closed. Here, of course, were the ones with the power interruptions associated disadvantages cannot be avoided. According to the invention, each contact closure and -opening avoided by the arrangement is made so that the air gap of a magnetic through the punched tape Circle and thus its reluctance is controlled, thereby in one or more with This magnetic circuit chained coils voltage fluctuations, which signals control, be generated. Here the organ that changes the air gap makes only very small ones Adjustments so that the telegraphic speed can be increased significantly.

Fig. Ι shows, partly in section, the sensing device.

Fig. 2 is a side view of Fig. 1 with omission of insignificant parts.

Fig. 3 is a plan view.

Fig. 4 shows for the purpose of explanation a useful circle through which the. Changes the magnetic resistance (reluctance) generated by the transmitter of the first figures can be used to generate voltage fluctuations.

Fig. 5 shows a modification of the arrangement according to Figs. 1 to 3. -

FIG. 6 is a circuit diagram corresponding to FIG. 5.

Figures 7 and 8 show two particularly useful circuits.

In the first embodiment, a wheel W is arranged on a shaft 6, the

Body X on the circumference contains ^ grooves in which ■ metal rings l · ', ο are inserted. These metal rings form part of a magnetic circuit of variable resistance, as will be explained in more detail later. Near the circumference of W lie the magnetic yokes a, a ' and above them the armatures H and H'. The rings b, b ' contain in their circumference a number of openings into which

ίο with the interposition of .Federn 7 and 8 pistons c and c ' protrude, the other ends of which protrude through openings in the flange of the wheel W to the outside. Around the circumference of W , a number of pull pins / are arranged at intervals equal to the distances between the pulling holes in the strip, which during operation enter the middle row of holes in the strip / and when the wheel W turns, pull this strip over the wheel. The springs 7 and 8 on the piston c and c ' normally seek to move these pistons against the armatures H and H'. The strip / prevents this movement of the pistons c after the anchors // as long as there is no hole above the piston. In this latter case, the piston is pressed by the spring through a hole against the armature. This changes the distance between the piston and armature and thus the reluctance. A direct current source 18 is connected to windings α 'and d' which are mounted on the yokes α, whereby a magnetic field is generated in the magnetic circuit. The yokes also carry a second pair of windings e and <? ', The purpose of which is explained below. In operation, the pistons c close in their upper position ■ the magnetic circuits through the ■ yokes α, the rings & and the armature //. Every change in the reluctance causes a change in the flux density in these circles and thus induces a voltage on the windings e. As the wheel W rotates, the pins / strip / 'pull around the circumference of the wheel. The pistons c are either held in their normal position by the strip or pass out through the strip holes, so that the reluctance as a result of the change in the air gap between the piston and armature becomes a maximum or a minimum, as the case may be. If you turn the wheel further, the piston is released from the strip again. As mentioned, this alternating play with respect to the air gap changes the flux densities in the magnetic circuits, which causes voltage changes in e and e '.

As a result of the arrangement of "two rows of pistons that work offset against each other, you can give these pistons the correct biases by adjusting the positions of the two armatures // to the pistons c and use the voltage pulses generated in the windings e for communication.

To make it easier to start the strip in the transmitter, the anchors H are arranged in an insulated shoe K , which is hinged to a fixed part 10. To insert the strip, this shoe is tipped up, as indicated by dotted lines in FIG.

The voltage changes in the windings e are then used in a known manner to operate a pressure relay or to feed the input circuits of tube relays or tube transmitters.
y ^ Such a utilization of these voltage changes is shown in I ⁷ ig. 4, The windings d and d 'that match the windings c and <?' sitting on the same cores are, as mentioned, fed by the source τ8 and result in a certain flux density in the core. The hand of the Vig. The keying process described changes the reluctance of the path and thus the flux density with the signal frequency. This results in a change in the impedance of the windings e and thus voltage changes at their terminals 3 and 4. The cathode circuits of the tubes 12 and 13 are now connected to these terminals, while the terminals ι and 2 of the windings c with each other through resistors 15 and 16 and are connected to the control electrodes of the tubes. The anodes are connected via an inductance, which is coupled in some way to the useful or antenna circuit.

Fig. 5 shows a somewhat simplified circuit. The magnetic circuits are as in the previous circuit, but the magnetic field is generated by alternating current from a source 18 connected to the windings d, d 'of the yokes α . The keying process again generates changes in the reluctance, which, however, here cause corresponding changes in the impedance of the alternating current windings d. This circuit eliminates the need for a special DC power source to generate the magnetic noise.

The impedance changes can now according to Fig. 6 are used for 'actuation of a tube relay.

I ⁷ ig. FIG. 7 shows a circuit for making use of the changes in potential with sampling frequency which occur at the inductances in the magnetic circuit.

Here the tubes A and B are biased by a source, not shown, to a point in the vicinity of the lock, so that a rectification of the

Currents that reflect the tactile potentials occur in the anode circuit of these tubes. If the impedance or inductance of V in one of the magnetic circuits is equal to the impedance or inductance of IJ in the other circuit, the alternating current supplied from 18 to the circuit containing resistors 15 and 16 'and the inductances mentioned above will be equalized, and both tubes A and B have the same excitation and draw the same amount of current from the anode power source, not shown. If the impedance of IJ is smaller than that of IJ, the voltage drop of the alternating current in resistor 15 causes an imbalance in (k'r excitation of the tubes A and J>. The tube receives a larger current, with the result that A direct current flows from the anode of B to the anode of A. This results in a corresponding drop in polarity at the resistor R ^A. This pulse or potential drop causes an increase in the voltage which is fed to the tube from the pre-voltage battery 20 via the resistor 21, and a decrease in the bias applied to the control electrode of the tube d of the polarized relay via the resistor 22. The tube (/ receives current, the, voltage at its anode 23 decreases, and it becomes as the grid 24 of C over a resistor 25 is connected to the anode 23 of D , the tube C is biased until it locks, and the voltage on the anode 26 of C. This voltage increase is increased via the resistor 27 to di e 'control electrode 28 of D transfers and increases the bias voltage so that D becomes highly conductive and remains conductive until the impedance of IJ becomes less than that of IJ, whereupon the opposite clearance occurs. So one of the tubes can carry the symbol current pulses and the other pause current pulses.

In the circuit according to FIG. 8, the inductances V, LJ of the scanning device 19 according to FIG. 5 are connected to a useful circuit 1 which contains the AC voltage source 18 and the resistors 15 and 16 of FIG. The polarized relay 2, the amplifier 3, the modulator 4 and the frequency doubler 6 are connected to the circuit 1. The amplifier 7, which is connected to the antenna 9 by the transmission line 8, is connected to the frequency doubler 6.

Claims (2)

Patent claims: 1. Fast telegraph with punched tape encoder, characterized in that by the punched tape is the air gap of a magnetic circuit and thus its reluctance controlled, whereby voltage fluctuations in one or more coils linked to this magnetic circuit, which control signals, be generated. 2. Fast telegraph according to claim 1, characterized in that the magnetic Circle of a yoke system is closed by a rotating drum leaving an air gap, which through this air gap pulls the perforated tape through in such a way that radially adjustable magnetic from its holes Tail pieces are controlled and thereby "influenced by the intensity of the magnetic field which creates voltage fluctuations in windings on the yoke. 1 sheet of drawings BERLIN. CiF.niUlCKT IN I) KU