DE1144323B - Circuit arrangement with transistors for a teleprinter relay for single and double current operation - Google Patents

Description

Circuit arrangement with transistors for a teleprinter relay for Single and double-current operation The invention relates to a circuit arrangement with transistors for a telegraph relay for single and double current operation with an electrical bistable multivibrator that depends on the state this flip-flop causes two different control states of a gate.

Such arrangements are known and more recently are transistors for the manufacture of such electronic gates and the circuits that control them been used. If, for example, a changeover contact is created by such a circuit is to be realized, a bistable, flip-flop circuit can only need two Transistors in connection nü t two switching transistors are used in which the collector of one switching transistor. connected to the emitter of the other is; this arrangement forms the electrical equivalent for the actuated center spring a conventional changeover contact; the emitter of the first-mentioned transistor corresponds to the closing spring of the changeover contact and the collector of the other The transistor corresponds to the opening spring which is in contact with the central spring of the changeover contact. By applying control potentials to the bases of the two Switching transistors through the control circuit is one of the two switching transistors into the conductive state, the other at the same time into the blocking state and conversely, whereby the circuit arrangement is able to function as a changeover contact to be fulfilled with electronic switching means.

Such a circuit arrangement cannot, however, be satisfactory in all cases because the costs of switching transistors dimensioned for somewhat higher potential differences increase rapidly with the voltage values. The voltages to be switched in some types of application are, however, comparatively high in view of the values used in conventional transistors. So are z. B. to consider potentials of + 60 and -60 V used in teleprinter systems if a conventional polarized telegraph relay with a changeover contact is to be replaced by an electronic circuit. If one of the two switching transistors replacing a changeover contact is conductive, then the other transistor, which is in the blocking state, must be able to withstand a counter voltage of 120 V; such transistors suitable for this purpose are rare and expensive.

It is the object of the invention to provide an electrical circuit arrangement to create whose active electrical switching elements, such as transistors, are not necessary have properties linked to the stresses occurring at the contact.

According to the invention, the bistable multivibrator is characterized in that that it contains an AC amplifier, the output of which to an AC-DC converter is connected, whose output signals control the gate on the one hand, and on the other control another gate, which in turn feeds the alternating energy to the input circuit of the AC amplifier.

It is also an object of the invention to implement this circuit arrangement only two transistors in a particularly simple way to manufacture. In further training According to the invention, the AC amplifier consists of a transistor in which Output circuit a transformer connected to the AC-DC converter for the reduction of the output voltage is arranged and its input circuit is connected to a further gate forming second transistor whose an electrode with the output of the converter and a signal source for conversion of the conductive state of the second transistor is connected.

According to a further embodiment of the invention, the output of the converter is located via a coupling rectifier, that represents this gate a fixed equal potential.

The arrangement described represents an electronic equivalent of one Single contact; accordingly, a current can thus be caused to flow through a ü Load resistor connected to the output of the AC-DC converter flows or that this current flow is interrupted. As long as there is no Output signal appears because the gate transistor is the inflow of alternating energy the paddock is blocked, rectifier is blocked, and no current flows through the load resistor. If a rectified, voltage of sufficient magnitude occurs, then the coupling rectifier conductive, and a current of a certain strength flows through the load resistor. Just The above-mentioned high voltage is applied to the coupling rectifier, the transistors however, can be operated with a suitably selected lower voltage, dir, corresponds to the transistor type in question.

However, the arrangement described does not fulfill the function of a electronic changeover contact, as is the case with an equivalent for a polarized one Telegraph relay is necessary.

Another object of the invention is to use the basic circuit described above is an electronic equivalent for a changeover contact to accomplish.

According to a further embodiment of the invention, two such arrangements are fed by the same alternating energy source and connected to one another in such a way that when a gate of one arrangement is in the conductive state, the corresponding gate in the other arrangement is blocked and vice versa the outputs of the two AC / DC converters are connected to mutually opposite diagonals of a balanced bridge circuit in which one of the four bridge branches is formed from the load resistor connected to the pair of gates.

An exemplary embodiment of the invention will be described with reference to the drawings, of which FIG. 1 shows an electronic relay arrangement with two transistors, which is suitable for single-current operation of a telegraph line; Fig. 2 shows an electronic relay arrangement with four transistors according to the invention for double-current operation, a telegraph line.

In Fig. 1 , the active switching elements are the transistors T1 and T2, of which the former serves as a control element, the other as an alternating current amplifier.

An alternating voltage source of 10 kHz, for example, is connected to a capacitor C 1, which is on the other hand connected via a resistor R 1 to the collector of the PNP transistor Tl, the emitter of which is connected to ground Transistor T2 connected, the emitter of which is also connected to earth; The capacitor C 2, together with the resistor R 2 and the rectifier G 1 connected in parallel to it, which are connected on the one hand to the base of the transistor T2 and on the other hand to earth, form a limiter arrangement for the alternating current signals coming from the collector of the transistor TI these only become effective when they cause a potential at the base of the transistor T2 which substantially exceeds the earth potential. A potential of is situated at the base of the transistor T2 - 24 V via the resistor R 3 on.

It is initially assumed that the transistor Tl is in the blocking state and that an alternating current signal reaches the base of the transistor T2 via the capacitor C 1 and appears reinforced by this at the collector of this transistor, that is, acts on the primary winding of the transformer TR, which is connected between the collector and the potential source of -24V.

The alternating voltage appearing on the secondary winding of the transformer TR is rectified by the rectifier G2 and smoothed by the smoothing element C3, C4, R4. A potential of -60 V is applied to the secondary winding and to the common terminal of the capacitors C 3 and C 4, on the one hand, and a potential of + 60 V on the smoothing capacitor C 4 via a coupling rectifier G 3 can transmit the value of + 60 V. The load resistor R 5 is connected directly to the potential source of -60V and to the output terminal of the amplifier at the resistor R 4.

The amplifier is set up to deliver a rectified output voltage of around 130 V. This makes the coupling rectifier conductive, and as a result, the potential of +60 V is applied to the load resistor R 5. The voltage of about 120 V applied to the load resistor R 5 of about 3000 ohms drives a current of about 40 mA through the load resistor R 5.

The base of the transistor Tl is connected to the rectifier G 3 via a resistor R 6 , so that the potential of +60 V is applied to the base of the transistor T 1 in its conductive state. Further, the base of the transistor Tl is connected via a resistor R 7 to the potential of- - 24 V. When the resistance values of the resistors R 6 and R are chosen in a corresponding manner 7, then turns at the base of the transistor T 1 a above the but a ground opposing potential value, the transistor is blocked, ün substantially no current collector path flows through the emitter, the 8 through the resistor R to the source, the potential of - 24 V leads.

If the current flow through the load resistor R 5 is to be interrupted, a pulse of negative potential is given to the terminal leading to the capacitor C 5. This pulse puts the transistor TI in the conductive state. As a result, the alternating current signal is derived from the base of the transistor T 2 to earth because the transistor T 1 in its conductive state short-circuits the capacitor C 2 and the resistor R 2, the rectifier Gl and the emitter-base path of the transistor T2. The rectifier G3 is switched off by switching off the rectified on the capacitor C 4. Voltage put in the blocking state. Therefore, no more current can flow through the load resistor R5, and this state is maintained permanently because the resistor R 6 is now only at the potential of -60 V via R 4, G 2, TR, whereby the transistor T 1 is in the conductive state preserved.

If a pulse of positive potential applied to the leading to the capacitor C5 terminal, then this enables the transistor Tl again in the off state, thereby the initial state is restored in which the load resistor R is at the voltage of 120 V. 5

The arrangement is therefore capable of functioning as an electronic off switch in single-current operation. The circuit arrangement according to FIG. 2 represents, so to speak, a duplication of that according to FIG. 1. A PNP transistor T2 acting as an amplifier is used in addition to a transistor T'2 of the complementary conductivity type NPN. One of the rectifier circuits, consisting of transformer TR, rectifier G 2 and capacitor C 3, an analog arrangement of the transformer TR ', rectifier G2 and capacitor C'3, is connected to the transistor T'2. The emitter of the transistor T2 is also grounded and the primary winding of the transformer TR is connected to the collector of the transistor T2 and to the potential -24 V, but the primary winding of the transformer TR 'is on the one hand at the collector of the transistor T'2, the emitter of which is also grounded is, on the other hand reach a potential of + 24 V. at the bases of the amplifier transistors acting as Tl and T'l AC signals, as in the arrangement of FIG. 1; these can come from a source of sinusoidal alternating voltage or from square-wave form. As can be seen from FIG. 2, the amplified alternating voltage reaches the bases of the transistors T2 and T'2 via the resistors R 9, R 10, R 11 or R'9, R'10, R'11 on two parallel paths . The resistors R 9 and R 10 together with the rectifier G4 form a limiter circuit; the anode of the rectifier G4 is connected to the junction of the resistors R 9 and R 1 0, and the cathode is grounded. In a similar way, a second limiting circuit is formed from the resistors R'9 and R'10 and the rectifier G'4, but its anode is grounded and its cathode is connected to the junction of the resistors R'9 and R'10; A resistor R'11, which in turn is connected to the base of transistor 72 , is connected to resistor R'10. The connection point of the resistors R'10 and R'11 is connected to earth via the collector-emitter path of the transistor 7'1; the function of the transistor is 7'1 of the transistor T 1 of FIG. 1 is equal to that. The transistor T 1 is also of the PNP type, whereas the corresponding transistor 7'1 is of the NPN type.

The output signals of the rectifier circuits including rectifiers G 2 and G'2, i. H. that is, the voltages occurring at capacitors C 3 and C'3 are applied to the diagonal branches of a balanced bridge formed from resistors R 12, R 13, R 14 and & in load resistor R 5. The resistors R 5 and R 14 are connected to earth on the one hand, while their other terminals are connected to the two assignments of the capacitor C 3 . The interconnected terminals of the resistors R 12 and R 13 are connected to the ungrounded assignment of the capacitor C'3, the other terminals of the resistors R 12 and R 13 to the assignments of the capacitor C 3. Finally, the interconnected terminals of the resistors R 12 and R 5, i.e. H. i.e. the end of the line that is not connected to earth, connected to the +60 and -60V limiting potentials via rectifiers G3 and G'3. Likewise, the interconnected bases of the amplifier transistors T1 and T'l are connected via a resistor R6 to the rectifiers G3 and G3 and to the resistor R12 connected to them and to the resistor R5 .

Assuming that the transistor T 1 is in the blocking state, only the negative half-waves of the applied alternating current signal reach the base of the transistor T2, because the positive half-waves are suppressed by the limiter circuit, because the rectifier G4 is conductive for them and therefore forms a short circuit. The negative half-waves cause the transistor T 2 to pass into the conductive state, and an intermittent current therefore flows through the primary winding of the transformer TR. Compared to the use of an alternating current signal with a sinusoidal waveform, the use of square-wave pulse trains has the advantage that the transistors T2, T'2 are switched more quickly, which reduces the effects of heat and enables the use of transistors rated for lower power values. If the voltage transformation ratio of the transformers is dimensioned accordingly, a voltage of about 130 V can be generated across the capacitor C 3.

The rectified voltage applied to the capacitor C3 causes the coupling rectifier G3 to become conductive, as a result of which the potential of -1-60 V is established on the ungrounded side of the line resistor R 5. Assuming that all four resistors R 5, R 12, R 13 and R 14 have the same resistance values, a potential of + 60-13 0 V = -70 V results at the junction of resistors R 13 and R 14 , whereas at the junction of the resistors R 12 and R 13 a potential value of - 70 + 130 V / 2 = - 5 V is established. This potential of - 5 V has the effect that the rectifier G'2 can not be conductive. On the other hand, the potential of + 60 V is applied via the rectifier G3 not only to the line resistance R 5, but also to the bases of the transistors T 1 and 7'1 via the resistor R 6 and causes the PNP transistor Tl by a low positive bias with respect to the base-emitter-circle is kept locked. This bias is generated by the NPN transistor 7'1, which is conductive under the given conditions and keeps the positive half-waves from the base of the transistor 7 "2, the positive half-waves being suppressed by the rectifier G 4.

To reverse the switching state of the bistable electronic multivibrator, it is sufficient to apply a negative pulse to the interconnected bases of the transistors T 1 and T'l. This causes the transistor Tl to become conductive; the small emitter-base biasing that occurs on it is sufficient to block transistor 7'1. The state opposite to the state just described occurs, and the alternating voltage present at the input is now amplified by the transistor T'2; the positive half-waves put this transistor into the conductive state, but the negative half-waves are suppressed by the rectifier G'4.

At the non-earthed terminal of the capacitor C'3 there is a potential of - 130 V, through which the rectifier G'3 becomes conductive; characterized engages the potential of - 60 V via the rectifier G'3 and enters the LastwiderstandesR5 on at the non-grounded terminal. At the junction of the resistors R13 and R14 there is a potential of - 130 V / 2 = - 65 V because of the voltage of 130 V applied to the capacitor C'3; under these conditions the rectifier G2 is blocked. A positive pulse applied to the bases of the transistors T1 and T1 sets the circuit back to its initial state.

Since the two rectifier circuits are cleanly separated from one another without having a common connection point, this electronic telegraph relay arrangement is suitable for double-stream telegraph operation. With a load resistance R 5 ini value of 6 kiloohms, for example, the operating current is 10 mA. Apart from the advantage that can be achieved through the use of transistors for low operating voltages and the small number of switching elements, it should be noted that the the circuit forming the load is practically completely separated from the input circuit, since the only direct current carrying path from the input circuit to the output circuit via the resistor R 6 is a high resistance path.

Claims (2)

PATENT CLAIMS.- 1. Circuit arrangement with transistors for a teleprinter for single and double current operation with an electrical bistable Kippschaktuig, the two different Leitvi - rte of a gate corresponding to the respective state of the bistable flip-flop, characterized in that the bistable flip-flop causes a Alternating current amplifier (T 1, T'l) contains the output of which is connected to an alternating current-direct current converter (T2, l2, TR, TR '), the output signals of which control the gate (T 2, F2) on the one hand and another gate on the other (T] # 1'1) which in turn controls the supply of AC power to the input circuit of the AC amplifier. 2. Sch-altunganerdnung according spoke 1, characterized in that two such arrangements are fed by the same AC voltage source and that they are connected to one another in such a way that one of the two gates is in a conductive state when the other gate is blocked and vice versa , and that each of the two output circuits of the two AC / DC converters (T 2, T'2, TR, TR ') are connected to one of the two diagonal branches of a balanced bridge circuit, in which one of its four bridge branches is connected to the Load resistor (R5) is formed, which is connected to the two gates. 3. A circuit arrangement according to claim 1 or 2, characterized in that the Wechselstroraverstärker includes a first pair of transistors (T2, T2), a Transforinator (TR, TR ') is arranged to increase the output voltage in the output circuit, which with demWechselstrom-Gleichstroin -Transformer (G2, G3; G # '2, G'3) is connected, and whose input circuit is connected to a second pair of transistors (T1, 1'1), which represents a further gate, and that one electrode of this second transistor pair is connected to the output circuit of the alternating current-direct current converter and to a control signal source by means of which the conducting state of the second transistor pair (T1, T'l) can be influenced. 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that the output circuit (s) of the converter (s) is connected to a fixed DC potential (+ 60V; -60V) via coupling rectifiers (G3, U3) represent the said gate. 5. Circuit arrangement according to spoke 3 or 4, characterized in that the second-mentioned transistor pair (T 1, 1'1) is used to suppress one of the two half-waves of the incoming AC voltage in its conductive state, and that a further, uncontrolled limiter circuit ( G 4, G'4) is connected to them, which serves to suppress the other half-wave of the input AC voltage. 6. Circuit arrangement according to spoke 2 or 3, characterized in that the two first-mentioned transistors (T 2, 12) as well as the second-mentioned ones (T 1, 7'1) are of mutually opposite conductivity types. 7. Circuit arrangement according to Claim 2 and 4, characterized in that both coupling rectifiers (G3, C3) are connected to the load resistor (R5). 8. Circuit arrangement according to claim 6, characterized in that the bases of the second-mentioned transistors (T 1, T'l) are connected to one another and coupled in a suitable manner to the load resistor.