DE956054C - Circuit arrangement for generating double current characters for telex purposes - Google Patents

Description

ISSUED JANUARY 10, 1957

S 42146 Villa / 21a ¹

for telex purposes

For the transmission of telex characters in double-stream operation, it is known to have a center-tapped Use an I2Q-V battery with one core of the transmission line at the center tap. Depending on the current step to be transmitted (separator or character current step), the other wire becomes the Transmission line to the top end of the battery (+ 6oV opposite the center tap) or to the the lower end of the battery (- 6o V opposite the center tap). The switchover takes place either through the contacts of a polarized relay or, for higher accuracy requirements, through two sets of springs, controlled by cams operated by a motor.

For electronic measuring devices, e.g. B. for text and test transmitters as well as for electronic teletyping machines, the use of relays or cam-controlled spring sets is undesirable. The present The invention is therefore based on the object of an arrangement ao working with electronic means to create double stream characters.

The essential feature of the invention is that to generate double-stream characters a bridge circuit is used which is fed with a constant voltage in one of its shunt arms »5 and its other shunt branch is bridged by a removal resistor for the double current symbol is, and that as a bridge resistance electrical

Valves are switched on so that if one of the crossed pairs of valves for the feed flow is made permeable, a flow in one and when the other of the valve pairs is flow-permeable is made, a current flows in the opposite direction through the take-off resistor.

The invention is explained in more detail below with reference to FIGS.

Fig. Ι a and ib show basic circuit diagrams of circuit arrangement according to the invention; in

Fig. 2 is a detailed circuit example of an arrangement according to the invention is shown in which each two current gates of the bridge circuit are connected in the form of a bistable trigger circuit; Fig. 3 shows a simplified circuit arrangement of Fig. 2; in

Fig. 4 shows the voltage profile that occurs at the pickup resistor.

Fig. Ia shows a bridge circuit in whose bridge branches the electrical valves Vi to V4 are switched on. A constant voltage is applied to terminals 1 and 2. In the other branch of the bridge is the resistor W, which is connected to terminals a and b . The load resistor WB is connected to the terminals α and b. If the valves Vi and V 4 are made permeable to the supply current, it flows from the terminal 1 via the valve Vi, the resistor W and the valve V4 to the terminal 2. As a result, a voltage drop occurs at the resistor W, which results in that the terminal α is positive with respect to the terminal b . A current I flows in the direction of the arrow through the load resistor WB. If terminal a is positive compared to terminal b, this corresponds to the isolating current state.

In Fig. Ib the circuit arrangement of Fig. Ia is shown again. Here, however, the valves V 2 and F 3 are made permeable to the feed flow. In this case, it flows from terminal 1 via valve F3, resistor W and valve F2 to terminal 2. A voltage drop again occurs at resistor W , which is now the opposite of that in FIG. 1a. As a result, terminal α is now negative compared to terminal b and a current I flows through the load resistor in the direction indicated by the arrow. If terminal α is negative compared to terminal b, this corresponds to the character current state.

By comparing FIGS. 1 a and 1 b , it can be seen immediately that double current symbols appear at the terminals α and b when the crossed valve pairs are alternately made permeable to the feed current. Due to the symmetry of the bridge circuit, the double current symbols are also symmetrical.

2 shows a detailed circuit arrangement of an arrangement according to the invention. A supply voltage is applied to terminals 1 and 2, which is kept constant via resistor W 5 and a stabilizer Ä5. The heated electricity gates R1 to 2? 4 used. The current gates Ri and Rz are interconnected in the form of a known bistable flip-flop circuit; the same applies to the power gates R 3 and R 4. The pick-up resistor located in a cross-branch of the bridge is denoted by W6 ; it lies between the terminals α and. b of the dual current output.

First, it is assumed that the current gates R 2 and R 3 are ignited. A current therefore flows through the current gate R2, the resistor W 6 and the current gate A3. The voltage drop occurring across the resistor Wb has the effect that the terminal α is positive with respect to the terminal b , which corresponds to the isolating current state. The circuit arrangement is so dimensioned that the resistance W6 a voltage drop of z. B. 60 V occurs. If an ignition pulse occurs on line Z, it will ignite the current gates Ri and R4 . As a result of the voltage drop across the resistor Wi , the anode of the current gate R1 is now at low potential. This low potential also occurs at the anode of the current gate Rz via the capacitor Ci, as a result of which the voltage falls below the operating voltage there, and the current gate goes out. The voltage drop occurring at the cathode resistor W4 when the current gate R 4 is ignited causes an increase in the cathode potential of this current gate. This increase in potential is coupled to the cathode of the current gate i? 3 via the capacitor C 2, so that the voltage drops below the operating voltage there too and the current gate goes out. Since the current gates Ri and R4 are now burning, a current flows through the current gate R 1, the resistor W 6 and the current gate A4. The voltage drop occurring across the resistor W & has the effect that the terminal α is now negative with respect to the terminal b , which corresponds to the character current state.

If an ignition pulse then occurs on the line T , the current gates R 2 and R 3 are ignited and the current gates J? 1 and R 4 go out. This corresponds to the switching state explained at the beginning, in which the terminal α has a positive potential compared to terminal b . The desired double current symbols appear at terminals α and b in the cycle of the ignition pulses appearing on lines T and Z.

In the above-explained operations, during ignition of the current goals R1 and R4 and the deletion of the current gates Rz and R 3 are not taken into account that if the current goals R1 and R4 ignite, a voltage drop occurs across the resistor W6, of the cathode potential of the current gate Rz decreased and the anode potential of the current gate A3 increased. These sudden changes in potential, which still occur within the deionization time of the current gates Rz and Rs , mean that the current gates Rz and R 3 do not extinguish. In this case, the current gates R1 to R 4 would all remain ignited. To avoid this, the capacitor C 3 and, under certain circumstances, the resistor Wj are connected in parallel to the resistor W6. First, it is assumed that the resistor W 7 is bridged. If the current gates R 2 and 3 are ignited, the terminal α carries a positive potential, compared to the terminal 6. The capacitor C 3 connected in parallel with the resistor W6 is then charged to this potential. Will the electricity

gates Ri and 2? 4 ignited, the capacitor C 3 discharges mainly through the resistor W6, which has the consequence that the cathode potential of the current gate R 2 decreases only slowly, while the anode potential of the current gate 7? 3 increases slowly in the same way. This ensures that after the ignition of the power gates J? 1 and R 4 the cathode potential of the current gate 2? 2 remains so high that the voltage at this current gate is undershot, and that the anode potential of the current gate 2? 3 is briefly kept so low that the burning voltage is also undercut at this current gate. The time constant with which the capacitor C 3 discharges is chosen so that after the extinguishing of the current ports R 2 and R 3, the burning voltage remains below these current ports during the deionization time.

The resistor Wy can be used to control the discharge of the capacitor C 3 in a manner known per se. 4 shows the voltage occurring across the resistor W6 , namely the solid line shows the voltage profile when the resistor Wy is selected to be zero, and the dashed line when the resistor Wy is selected to be not equal to zero. By suitably dimensioning the resistor Wy and the capacitor C 3, one has the ability to control the voltage jump occurring at the resistor W 6 in such a way that the current gates R 2 and 2? 3 can be deleted with certainty. For deleting the power gates Ri and 2? 4, what has been described above applies accordingly.

The time constant with which the capacitor C 3 discharges is calculated using the following formula:

". "- Δ Ua3 Δ Uk2

TI = Jii-O2;> ~ 7 ~ r ~; Mention = - ~ TTr "* en * <o»

Δ Uk 3 Δ Ua 2

In this formula, Ri denotes the resistance that is measured from the capacitor C 3 into the entire circuit. With Δ Ua 2 that is when the current gates Ri and R4 are ignited at the anode of the current gate 2? 2 occurring voltage jump and with Δ Uk2 the voltage jump occurring at the cathode of the current gate 2-2 denotes. For Δ Ua $ and Δ Ukj, what has been said applies accordingly.

In Fig. 3 a variant of the circuit arrangement of Fig. 2 is shown. This circuit arrangement works without the resistors Wi and W 4 and the capacitors C ι and C 2. Otherwise, the circuit corresponds exactly to that of FIG. 2, so that the same reference numerals have been used for the same switching elements in FIGS.

It is again assumed that the current gates 2? 2 and 2? 3 are conductive. An ignition pulse occurring on line Z now also ignites current gates 2? ι and 2? 4. All power gates Ri to R ^ burn for a short time. The resulting increased current has a voltage drop at the stabilizer 2? 5 result. Through the capacitor C 3, as

6a already described for FIG. 2, the cathode potential

of the power gate 2? 2 and the anode potential of the current gate 2? 3 held at such tension, that as a result of the voltage drop on the stabilizer 2? 5 the electricity gates 2? 2 and 2? 3 go out. Otherwise is the mode of operation of the arrangement of FIG. 3 is exactly the same as that already described for FIG became.

Claims (5)

PATENT CLAIMS: 1. A circuit arrangement for generating double current characters for telex purposes, characterized in that a bridge circuit is provided which is fed in its one shunt arm with a constant voltage and the other shunt arm is bridged by a removal resistor (W 6) for the double current characters, and that as Bridge resistors electrical controllable valves (Ri to 2-4) are switched on so that when one of the crossed pairs of valves (Ri and 2-4) is made permeable to the supply current, a current in one and, when the other the Valve pairs (2? 2 and 22 3) is made current-permeable, a current flows in the opposite direction through the removal resistor (W6) . 2. Circuit arrangement according to claim 1, characterized in that heated grid-controlled gas discharge tubes are used as bridging resistors and the ignition electrodes of one of the crossed Stromtorpaare (2? 2 and 2? 3) with one of the ignition pulses for separating current and the ignition electrodes of the other Stromtorpaares (221 and R4) are connected to a line that supplies the ignition pulses for symbol current. 3. Circuit arrangement according to claim 2, characterized in that one current gate (2? 1 or 2? 3) of the one and the other current gate pair (2? 2 or R4) are interconnected in the form of a bistable trigger circuit. ' 4. Circuit arrangement according to claim 3, characterized in that a capacitor (C 3) is connected in parallel to the removal resistor (W6) , which is dimensioned so that after the ignition of the current gates one of the current gate pairs (Ri and 2? 4 or 2? 2 and 2? 3) for a short time at the ^ current gates of the other pair such a voltage is maintained that they are definitely extinguished. 5. Circuit arrangement according to one of claims i, 2 and 4, characterized in that a voltage source preferably containing a voltage stabilizer (W5 and R5) is used to feed the bridge, which voltage source has such an internal resistance that due to the simultaneous burning of all current gates During the switching process of the bridge, a higher current decrease caused the supply voltage for a short time. is lowered early enough that the power gates burning before the switching process are definitely extinguished. 1 sheet of drawings © 609529/208 5.56 (609 742 1.57)