DE1244241B - Circuit arrangement for switching on or off or reversing the polarity of an output direct current by means of short input pulses - Google Patents

Description

Circuit arrangement for switching on or off or reversing the polarity of an output direct current by means of short input pulses The invention relates to a circuit arrangement for switching on or off or reversing the polarity of an output direct current using short Input pulses, especially for keying direct current telegraphic characters in telecontrol or telegraph equipment, with a transistor oscillator biased by a voltage prevented from spontaneous oscillation and as an oscillator with inductive feedback is formed, and at least one of the rectified oscillator output voltage actuatable electronic inserted into the direct current circuit to be switched Counter.

Telecommunications technology requires arrangements that are able to, for. B. pulses emitted by magnetic cores lasting a few microseconds in double current symbols to convert, which can then control the usual WT facilities.

Circuits are already known which produce short pulses in double current symbols can convert. For example, a bistable multivibrator can be connected to Push-pull switching amplifier by short pulses from one stable position to the other others are switched. To the control circuit, i.e. the one from the short switching pulses traversed current path, to be galvanically separated from the output circuit, which often continues is required by such circuit arrangements, this flip-flop must have a pulse transformer upstream. For this purpose, an arrangement is also known in which with The output voltage of the flip-flop is amplitude- or phase-modulated by a carrier voltage and is supplied by means of a transformer to a demodulator circuit in which then the control voltages for the switching amplifier can be obtained. These circuits however, they are relatively expensive.

Furthermore, from the German Auslegeschrift 1055 590 a transistor switching arrangement became known for the optional connection of a load with different potentials. The interpretation, however, is essentially only inferred, such as a load can be connected to different potentials via switching transistors and that the switching transistors by switching pulses with respect to their volume resistance should be able to be influenced and the switching pulses modulated by rectification from a AC voltage are derived, the modulation waveform of which corresponds to the waveform of the required switching impulses. via a special design of the oscillator, which generates this alternating voltage, nothing is stated in the above-mentioned interpretation.

Furthermore, from the German Auslegeschrift 1117 168 a transistor relay circuit is known in which the alternating current generator contains a transistor operating in base circuit, which is also part of a trigger circuit consisting of two emitter-coupled transistors, responsive to a threshold voltage and which supplies the sampling voltage for the alternating current generator. This transistor relay circuit is obviously not suitable to process input pulses of only a short duration in such a way that the oscillator z. B. is initially set in the oscillating state and remains in this until it is returned to the idle state by a further short input pulse and again remains in this state until it starts to oscillate again.

The object of the invention is to provide a purely electronically operating dual-current key device to create, in particular for converting short current pulses into double current symbols is suitable and with the input circuit and output circuit in the simplest possible way are galvanically separated from each other.

To solve this problem, the circuit arrangement is according to the invention designed so that the oscillator input circuit, the oscillator output circuit and the input circuit of the switch (s) each galvanically separated from each other, Windings arranged on a common transformer core exhibit and a core with a substantially rectangular hysteresis loop as the transmitter core is used that also the input pulses to be fed to the oscillator input circuit are dimensioned according to polarity and / or pulse shape in such a way that a so-called start pulse the oscillator a sufficient amount of energy to oscillate and that a so-called stop impulse is a sufficient time to stop the oscillator Having length.

It is particularly provided that start and stop pulses are different Inputs of the oscillator circuit are fed or that start and stop pulse have different polarity and / or pulse shape and on the same input the oscillator circuit act.

A single-ended oscillator with a transformer can be used as the oscillator Feedback that works in C mode and its transistor is so biased is that the oscillator does not draw any current in the deleted state, or a push-pull oscillator which also works in C mode and therefore its transistors are biased so that the oscillator does not draw any current when it is deleted. In particular, it is provided that the input pulses are connected to the base circuit of the oscillator transistor are fed. The current consumption of the circuit arrangement is therefore very low.

The invention further provides that the input pulses on two windings an oscillator transformer act in such a way that the transformer by a start pulse Energy is supplied and the entire vibration energy is transferred to the transmitter by a stop pulse is withdrawn in that the stop pulse via a diode circuit and a differential winding of the transformer short-circuits, and that the stop pulse is dimensioned so that it through Magnetic saturation of the feedback transformer tear off the oscillation of the oscillator and by slowly demagnetizing it prevents the oscillation from starting again, which makes it easy to convert short input pulses into permanent characters is effected.

In a further embodiment of the invention it is provided that the output side two direct current sources in the manner of a bridge circuit, each via an electronic one Output switch a consumer resistor located in the branch in the way feed that when the oscillator oscillates, the first switch is open and the second Switch closed, when the oscillator is deleted, the second switch is opened and the first switch is closed and the direction of the current is changed reverses in consumer resistance; in particular that the output switches each from a switching transistor or from a series connection of several switching transistors consist, which are biased from the current sources feeding the output switches are that the transistor forming the first switch or the series circuit is off several transistors is permeable when the oscillator is cleared and the second one A transistor forming a switch or a series connection of several transistors is locked and this state is reversed when the oscillator oscillates. As special It is advantageously proposed that four transistors be used to form the output switch the load resistance in one bridge and in one cross-branch of the bridge, a DC voltage source and the transistors are arranged in the other shunt arm are biased from the DC voltage source so that when the oscillator is canceled two transistors opposite each other in the bridge blocked and two transistors are permeable and when the oscillator oscillates the transistors through each Rectified oscillator AC voltages taken from separate windings can be controlled so that the transistors, which are blocked when the oscillator is cleared, are conductive and the transistors that are conductive when the oscillator is cleared are blocked.

In order to achieve high switching rates, it is provided that in the output switch for steepening the pulse edges of the switched direct current feedback capacitors are introduced.

With the circuit arrangement, polarity reversal times of about Reach 3 microseconds, which means that the circuitry is at walking speeds up to 10,000 baud with less than 5% distortion.

Compared to the known circuit arrangements, the circuit arrangement according to the invention has the particular advantage that it has very little circuitry Requires effort, because an approximately rectangular hysteresis loop of the feedback transformer core of the inductively fed back oscillator in a particularly simple manner the idle state of the oscillator to stabilize and thus prevents the oscillator oscillates as a result of commonly occurring disturbances. An oscillation can now can only be done by a suitably measured input pulse, and the oscillation state is interrupted again by a so-called stop pulse. The oscillator picks up In addition, there is almost no power in the idle state. In addition, the circuit arrangement be kept potential-free on the input and output sides.

Further advantages and features of the invention result from a Preferred exemplary embodiment of the circuit arrangement explained in greater detail on the basis of three figures.

The principle of the circuit arrangement can be seen from FIG. 1. Only one oscillator is used, which works like a memory, ie it is made to oscillate by a short start pulse applied to a start input Z and deleted again by a short stop pulse applied to a stop input T. The oscillating voltage of the oscillator controls two electronic output switches. These are in the output circuit of the circuit arrangement, which leads from the switching point -TB via one switch SZ, the consumer resistor RL to the switching point MTB on the one hand and from the switching point MTB via the consumer resistor RL and the other switch ST to the switching point + TB on the other hand. In the idle state of the circuit arrangement, the electronic switch SZ is blocked and the electronic switch ST is conductive. These switch positions are fixed by bias voltages which are taken from the battery arranged between the switching points -TB and + TB , the center tap of which is connected to the switching point MTB. If the oscillator O is triggered by a start pulse fed to the start input Z, the oscillator alternating voltage is applied to the two diodes 1, 2. The diodes then supply the two switches SZ, ST with voltages that have a polarity opposite to the respective bias voltages to have. Therefore, the switch SZ now conducts as long as the oscillator is oscillating, and the switch ST is blocked for as long. In the load resistor RL, through which a current flows from the circuit point + TB to the circuit point MTB when the circuit arrangement is idle , the direction of the current is reversed as long as the oscillator is oscillating; it now flows from the circuit point MTB to the circuit point -TB.

A preferred embodiment of the circuit is shown in FIG. 2. So that the oscillator, which consists of the transistor T 1, the resistors R 1, R 2, R 3, the capacitor C1, the diode G1 and the two coils W 2 and W 3 , does not start to oscillate by itself, the oscillator transistor is T1 blocked by a voltage threshold. This voltage threshold is formed at the diode G 1 as a result of the current flowing from ground via this diode and the resistor R 2 to the node -UB . The resistor R 3 is used to limit the oscillator alternating voltage. In order to reduce the damping of the oscillator circuit C 1, W 3 by the emitter-base path of the transistor T 1, the resistor R 1 is inserted into the base lead of the transistor. The resistors R 1 and R 3 also have a current-limiting effect. The oscillator can be controlled via two separate windings W 1, W 4. Is z. B. the winding W 1 of the transformer IU, which is arranged with the windings W 2 and W 3 of the oscillator and the winding W 4 on a common core, as a result of the node 6, the start input, supplied short start pulse from If a current surge flows through about 10 microseconds, the oscillator begins to oscillate because this current surge stores so much energy in the transformer that the voltage induced in the winding W 2 can overcome the voltage threshold blocking the oscillator transistor. A stop pulse of about 10 microseconds duration applied to circuit point 7, the stop input, causes the two diodes 8 and 9 to become conductive, whereby winding W4 becomes a short-circuit winding in which the oscillation energy of the oscillator is consumed and therefore the oscillator is deleted. On the output side, the transformer ü has two further windings W 5 and W 6, likewise seated on the same core, which are used to decouple the output alternating voltage of the oscillator. The ends of these two windings are each connected downstream of diodes 10, 11 and 12, 13, each of which rectifies the oscillator AC voltage present at the winding ends. Each of these voltages reaches the base terminal of a switching transistor via corresponding filter elements, which consist on the one hand of the capacitor C2, the resistor R4, on the other hand of the capacitors C 3 and C 4 and the resistors R 6 and R7. When the oscillator is deleted, the transistor T 2 is blocked and the transistor T 3 is permeable. The reverse voltage for the transistor T2 is obtained at the diode G2. It is created by a current that flows from the node -TB via the resistor R11, the diode G2 and the resistor RL to the node MTB. The resistor R 5 serves to feed the potential of the base point of the diode G2 to the base of the transistor T2.

The current that keeps the transistor T3 in the conductive state flows from the node + TB via the emitter-base path of the transistor T3 and the resistor R9 to the node -TB. The resistors R 6 and R 7 prevent the base-emitter voltage therefore present at the transistor T3 from driving an excessive current through the diodes 12 and 13 and thus attenuating the transformer 1 ~ 1 'in an impermissible manner. Together with the capacitors C3 and C4, they simultaneously form filter elements, the chain connection of two filter elements having the advantage that, despite the relatively high value of R 9, the current holding transistor T3 in the saturated state can flow again very soon after the oscillator has been extinguished. The collector circuits of the transistors contain the resistors R 8 and R 10. These limit the collector currents during the respective switchover. They also protect the transistors when the output of the switches is shorted. As feedback capacitors, capacitors C 5 and C 6 each connect the collector of one transistor to the base of the other transistor. This ensures that the circuit arrangement can switch over in 1 to 3 microseconds. The load resistor RL is bridged with a capacitor C 7 in order to prevent it from influencing the feedback too much. If the oscillator oscillates as a result of a start pulse fed to the start input 6 , the direct voltages obtained from the transformer windings W 5 or W 6 control the previously blocked transistor T2 to the conductive state and the previously conductive transistor T3 to the blocked state. The current in the load resistor RL, which initially had the direction from the circuit point + TB via the transistor T 3 to the circuit point MTB, therefore now reverses its direction as long as the oscillator oscillates.

The transistors T 2 and T3, which are used to switch or reverse the polarity of the output direct current flowing through the load resistance, can also be replaced by a series connection of several transistors in order to e.g. B. to be able to switch higher output DC voltages.

In addition, the output switch can also be designed so that four transistors form a bridge, in one of which the load resistance is then applied RL is arranged, while a DC voltage source forms the other shunt arm. The transistors are biased from the DC voltage source so that at cleared oscillator two transistors opposite each other in the bridge blocked and two transistors are low-resistance. When the oscillator is oscillating then the conducting transistors when the oscillator is deleted is blocked. In this case you do not need a power source with center tap MTB.

Furthermore, the oscillator used in the circuit arrangement can also be designed as a push-pull oscillator. The voltage threshold that occurs in the single-ended or push-pull oscillator circuit the oscillator transistors in the cleared state is dimensioned so that the oscillator does not consume any current when it is deleted.

Can on the galvanic separation of the input control pulses traversed circles of the oscillator circuit can be dispensed with, so the oscillator can also be designed (see FIG. 3) that the feedback winding W 7 is placed in the emitter circuit of the oscillator transistor and from the base this transistor an RC element 15, 16 is connected to ground, to which a positive current-limiting voltage builds up when the oscillator oscillates. Of the Start input is blocked by the capacitor 17 against the base of the transistor. A negative pulse applied to this input leaves the base potential briefly become negative against the potential of the emitter and thus the oscillator to swing. The independent oscillation of the oscillator is prevented by that material with a rectangular hysteresis loop is used for the transformer core will.

The vibration remains in spite of the powerful feedback Received emitter counter voltage. If the oscillator is to be stopped, the must Base of the oscillator transistor via the stop input 18, in which the diode 19 is arranged a positive pulse can be applied. This blocks the transistor, whereby However, it must be noted that the time constant of the RC element 15, 16 is so large is dimensioned so that the transistor is fed to the stop input for as long as this Pulse is held in the locked state until the stored in the collector resonant circuit Energy has subsided.

Claims (12)

Claims: 1. Circuit arrangement for switching on and off or polarity reversal of an output direct current by means of short input pulses, in particular for the keying of direct current telegraphic characters in telecontrol or telegraph devices, with a transistor oscillator, which is caused by a bias on the spontaneous oscillation is prevented and designed as an oscillator with inductive feedback, and at least one of the rectified oscillator output voltage actuatable into the to be switched direct current circuit inserted electronic switch, d a -by characterized in that the oscillator input circuit, the oscillator output circuit and the input circuit of the switch (s) each galvanically separated from each other, have windings arranged on a common transformer core and as a transformer core a core with a substantially rectangular hysteresis loop is used that further the input pulses to be fed to the oscillator input circuit according to polarity and / or Pulse shape are dimensioned such that a so-called start pulse is given to the oscillator supplies sufficient amount of energy to start oscillating and that a so-called stop pulse has a sufficient length of time to stop the oscillator. 2. Circuit arrangement according to Claim 1, characterized in that start and stop pulses are fed to different inputs of the oscillator circuit. 3. Circuit arrangement according to claim 1, characterized in that start and stop impulses are different Have polarity and / or pulse shape and on the same input of the oscillator circuit act. 4. Circuit arrangement according to claim 1, characterized in that the The oscillator is designed as a single-ended oscillator operating in C mode, its The transistor is so biased that the oscillator is not in the deleted state Consumes electricity. 5. Circuit arrangement according to claim 1, characterized in that that the oscillator is designed as a push-pull oscillator operating in C mode is whose transistors are so biased that the oscillator is deleted State does not draw power. 6. Circuit arrangement according to claim 1, 4 or 5, characterized in that the input pulses to the base circuit of the oscillator transistor are fed. 7. Circuit arrangement according to claim 1, characterized in that that the input pulses act on two windings of the oscillator transformer in such a way that that the transmitter is supplied with energy by a start pulse and by a Stop impulse the transmitter the entire vibration energy is withdrawn in that the stop pulse via a diode circuit a differential winding of the transfer carrier shorts. B. Circuit arrangement according to Claim 1, characterized in that the stop pulse is dimensioned in such a way that it is caused by magnetic saturation of the feedback transformer (Ü) breaks the oscillation of the oscillator and slowly demagnetizes it a renewed fanning of the oscillation is prevented. 9. Circuit arrangement according to claim 1, characterized in that the output side has two direct current sources in the manner of a Bridge circuit via an electronic output switch in each case, one in the shunt branch feed lying consumer resistance (RL) in such a way that when oscillating Oscillator the first switch open and the second switch closed, at When the oscillator is canceled, the second switch is open and the first switch is closed is and that in each case the direction of current in the consumer resistance is reversed. 10. Circuit arrangement according to claim 1, characterized in that the output switches each consist of a switching transistor (T2, T3) or each of a series connection of several switching transistors which are biased from the current sources feeding the output switch in such a way that the transistor forming the first switch ( T3) or the series connection of several transistors is permeable when the oscillator is cleared and the transistor (T2) forming the second switch or the series connection of several transistors is blocked and this state is reversed when the oscillator oscillates. 11. Circuit arrangement according to claim 1, characterized in that four transistors are used to form the output switch the load resistance in one bridge and in one cross-branch of the bridge, a DC voltage source and the transistors are arranged in the other shunt arm are biased from the DC voltage source so that when the oscillator is canceled two transistors opposite each other in the bridge blocked and two transistors are permeable and when the oscillator oscillates the transistors through rectified oscillator alternating voltages taken from separate windings can be controlled so that the transistors, which are blocked when the oscillator is cleared, are conductive and the transistors that are conductive when the oscillator is cleared are blocked. 12. Circuit arrangement according to claim 1, characterized in that feedback capacitors (C5, C6) are inserted into the output switch for steepening the pulse edges of the switched direct current. Publications considered: German Auslegeschriften Nos. 1055 590, 1117168.