DE1244242B - Circuit arrangement with feedback generator for converting pulse combinations arriving in series into rectangular currents or sinus currents and re-rectification - Google Patents

Description

Circuit arrangement with a feedback generator for converting incoming pulse combinations in series in square or sinusoidal currents and Again, g, light direction For electronic relay replicas, line couplers, electronic reception distributors, electronic signal transmitters, series-parallel unisetters etc. the task is set to an arbitrarily long existing direct current state transferring an incoming line to outgoing lines without between the two and to establish a galvanic connection to the required auxiliary power source.

To solve this problem, the pulse combinations that are generated by "Double current" or "single current" can be expressed in alternating current signals converted and passed on by transmitters with I-Elfe (galvanic separation). These alternating current signals can be converted back into direct current signals by rectification implemented. For this purpose, circuits have become known that consist of a Local AC voltage source have parallel-fed branch lines which switched through according to the signal applied by electronic switches or C, Cres are locked. These known circuits operate in the manner of modulator circuits.

It is also involved in the generation and keying of carrier frequencies known, a tube generator with several resonant circuits for carrier frequency generation to use in the grid circle and the selection of the carrier frequencies by influencing to accomplish the feedback. These known circuits have the disadvantage that the generated frequencies must not be adjacent, otherwise they are mutually exclusive would disturb. In addition, this circuit is not suitable for being part of a relay simulation to be.

An electronic relay for contactless closing and interruption of a secondary circuit is already known. The control voltage, which, depending on the polarity, switches on either one generator or the other, is used as the operating voltage for the generators. This makes the circuit arrangement extremely sensitive and requires large control signals. There is no galvanic separation between the input circuit and the generators. As a result of this type of circuit, the output signals are very weak, so that amplification by switching transistors is necessary. The circuit also provides the option of providing the generators with their own power supply, but then there is no galvanic separation between the power supply for the generators and the output circuit. The known circuit arrangement requires a considerable amount of components, in particular transistors and transformers.

The object of the invention is to provide a circuit that has a Any long existing direct current state of an incoming line to a outgoing line transmits. It should be both between the two lines as also a galvanic one between one of the lines and the required auxiliary power source Separation exist.

The invention relates to a circuit arrangement with feedback Generator that oscillates or not depending on the state of the incoming line oscillates, the pulse combinations, such as telegraphic characters or the like, in keyed Square-wave currents of any frequency or sinusoidal currents, preferably higher frequencies converts them back into direct current signals in an output circuit and possibly summarized and for galvanic separation of the incoming and outgoing Line as well as the required auxiliary power source from the incoming and outgoing Line serves.

The solution takes place according to the invention in that a transformer feedback generator is provided, the at least two transformers with separate has magnetic coupling paths, which transmitters determine the oscillation frequency, each transformer having additional windings for the purpose of being dependent on the presence and / or direction of the input current through a winding of the transmitter the vibrations of the generator determined by this transmitter in such a way be suppressed that this winding is shorted, and that only at the transformer, which is not short-circuited in terms of alternating current, over a further Wickluno, an alternating voltage is taken, which after its rectificationunor determines the state of the outgoing line.

The invention represents a particularly simple and economical one Solution to the problem. Although two states are transmitted during operation, only a single auxiliary oscillator is required. The oscillator has two in series switched oscillating circuit windings, which are located on two separate transmitters, the oscillating circuit winding that is not effective in each case is replaced by another on the transformer attached winding, depending on the condition of the incoming line, short-circuited will. By inserting a third transformer, it is possible to a third state such as B. failure of the control channel or short circuit, on one third line available at the exit. One embodiment of the invention Circuit arrangement has the effect of an electronic fuse when short circuits and interruptions occur on the incoming line. The lockdown will too maintained when the Störuno is removed again. The recommissioning must be effected either manually or by a separate signal.

With the option of damping or pre-magnetizing the generator The sensitivity of the circuit arrangement according to the invention is determined by its own winding significantly increased.

The transformer according to the invention thus links the associated incoming and outgoing lines directly with one another with its coupling path, so that when the input winding is "blocked", the associated output winding is affected beyond what is required for a simple feedback and the output winding can be said to be blocked. Da-C C through, it is possible to operate two transformer next to each other that have the same structure and work so with the same oscillation frequency or work in the can. The invention is discussed with reference to the drawing. FIG. 1 shows a circuit example in which the vibration suppression is shown by means of a short-circuited transformer winding with the aid of a special control circuit, FIG . 2 a detail of FIG. 1, Fig. 3 shows a first embodiment with switching transistors for the damping circuits with a square-wave generator and with two magnetic coupling paths, FIG . 4 shows a second embodiment with a diode switch for the damping circuits, with a sine wave generator and with two magnetic coupling paths, FIG . 5 an input part for magnetic biasing of the magnetic coupling paths, FIG . 6 a further input part with transistor switch and rectification in the damping circuits, FIG . 7 shows a circuit arrangement according to FIG. 3 with additional lock, F i g. 8 shows an arrangement for operation with "single current", FIG. 9 shows another arrangement for operation with "single current", FIG. 10 shows an arrangement; for the additional transmission of the disturbed state (short circuit or interruption a) at the input of the circuit, FIG. 1 1 a further embodiment for the additional transmission of the disturbed state at the input of the circuit, FIG . 12 a further embodiment for the additional transmission of the disturbed state at the input of the circuit, FIG. 13 and 14 additional embodiments of the input side of the circuit according to FIG. 3, 4, 7 in the ID or 1.2.

F i g. 1 shows a block diagram of the vibration suppression by means of a short-circuited transformer winding with the aid of a special control circuit. The Ein-an-sklemmen a, b lead C im -, to an input circuit E, this in turn to a transformer, consisting of the windings Ll, L2, L3 and L5, which are magnetically coupled to one another; the output circuit A is connected to the transformer and forms a direct current signal from the alternating current signal of the winding L5.

To maintain these processes, the amplifier Y is provided which, together with the windings L 2 and L 3, forms part of a start-stop generator and provides the energy necessary to maintain the processes to be described. The start-stop generator works as a freely oscillating feedback generator of any circuit. The amplifier V can be a transistor amplifier in a single-ended or push-pull circuit, and the entire generator can output a sinusoidal output voltage or a square-wave output voltage. If a sinusoidal voltage is selected, it is advisable to work with the highest possible frequency and low quality (e.g. only with the self-capacitance of the coil). This on the one hand facilitates the smoothing of the output current by integrating elements (RC combination, carrier memory effect in a subsequent transistor), and on the other hand achieves a rapid on and off oscillation during the start or stop process. By choosing a square-wave output voltage, filter elements with a small time constant can achieve good smoothing of the output direct current, which enables higher transmission speeds. At the same time, this results in a lower power loss in the amplifier, which is particularly important for transistor amplifiers.

Via the input circuit E, the winding Ll is either damped so strongly, depending on the input current, that the oscillations of the generator stop, or the winding Ll is not damped at all or only so weakly that the generator oscillates and an alternating C C3 voltage can be removed.

F 1 g. 2 shows an embodiment of the input circuit E, which is constructed with diodes D 1 to D 4 and resistors R1 and R2. Without an input current, the winding L 1 is damped via the diodes D 3 or D4 and the resistor R2. If there is a positive potential at terminal a, then a voltage drops across resistor R 2, as a result of which diodes D3 and D4 are blocked and winding LI remains without attenuation. The series connection of the diode D 1 and the resistor R 1 ensures that when using double current, the single-ended resistance is the same for both current directions.

The execution form according to FIG. 3 consists of three parts like that according to F i 1 : an input switch EI which serves as a control part, a generator part G, through which the energy is provided, and an output part A, in which the signal is converted again if it is output. taken and ge., These three parts are mechanically coupled to one another by the magnetic coupling paths KI and K2. The coupling paths K 1 and K 2 are separated from one another and consist of suitable magnetic materials. The circuit arrangement according to FIG. 3 is used to convert a double current signal at the input (terminal a, b) into a signal consisting of alternating voltages either at output A 1 or at output A 2. These alternating voltages can be rectified, combined and converted into double current symbols by known rectifier circuits GbIL and Gb2.

The coupling path K1 couples the windings L1 to L15, the coupling path K2 the windings L21 to L25 magnetically with one another. The generator GI operates similarly to the blocking oscillator principle, namely, the currents of the control lines, which lead Ts3 to the base of the transistor and are filled with the Wicklun 'gen L 13, L 23 and L 14, L 24, with the currents of the collector line of the transistor Ts3, which is occupied by the windings L12 and L22, is fed back. The auxiliary voltage source - U + U supplies the energy necessary to maintain the oscillations. The way this generator GI works is described in more detail in German Ausle 1169 509. What is remarkable about this generator is that the windings L 13 and L 23, which are permanently coupled to the windings L12 and L22, and the diode D 11 form a limiting circuit which gives the generator the properties of a push-pull generator. The magnetic flux generated with the help of the windings L12 or L22 can become effective in the output windings L15 or L25 by means of the magnetic coupling path KI or K2. The input part E1 forms the control part for the aisle. A DC voltage present at the input between the decoupling terminals a and b , which can be an element of a telegraphic symbol ("double current"), switches one of the transistors Tsl or Ts2 to conductive and the other to non-conductive. If, for example, the positive pole of the control current source is at point a, the current flows through resistor R3 and the emitter-base path of transistor Ts2 to terminal b. The transistor Ts 2 is thus made conductive, a closed current path ("damping circuit") for induced currents of the winding L21 is given. This closed current path means that winding L 21 and, because of the magnetic coupling, windings L 23, L 24 and L25 are practically short-circuited so that no voltage appears at output A2 processes in the transformer ül maintain the transformer ül is not attenuated;.. at the output a 1 can be removed so zine AC voltage of a positive DC voltage at terminal a thus corresponds to an AC voltage to the output terminal pair of a 1, a positive DC voltage at the input terminal b corresponds to a AC voltage at the output terminal pair A 2. The output voltages are rectified and combined, e.g. by rectifier bridge circuits Gbl and Gb2. The prerequisite for the functioning of the described type of input circuit E 1 is the following: The transistor Tsl or Ts2, which is conductive due to the polarity of the control current, must not be switched off the winding her ges be expensive, d. That is, the half-wave of the voltage induced in the winding Lll or L21 occurring in the reverse direction to the transistor may bnv the transistor Tsl. Do not lead Ts2 out of saturation or even block it. Conversely, the transistor that is to be blocked must not be made conductive by the other half-wave of the induced voltage. The windings L 11 and L 21 must be designed so that the case just described does not occur. If there is a short circuit between the input terminals a and b or if there is no control current, the transistors Tsl and Ts2 are blocked, but "without voltage". Both outputs A 1 and A 2 therefore supply voltages. This fact must be taken into account when using.

ZD ZD The circuit according to FIG. 4 is constructed like the circuit according to FIG. 4 with regard to the basic structure of the input part E, the generator part G and the output part A. 1 or F i g. 3. The input part E is the circuit according to FIG. 1, that is to say a diode circuit E2 is used which, like the circuit according to FIG. 1 to the input currents compared to the input circuit according to FIG. 3 reacts in an inverted manner: while in the case of the input circuit EI according to FIG. 3 the current has caused a damping circuit to close, it causes the damping circuit to open in the input circuits EO and E2. The input circuits E 1 and E2 can be interchanged if the polarity of the output circuit with the terminal pairs A 1 and A 2 is reversed. The generator part G is not a »square wave generator«, but a »sine wave generator« G2 . The generator G2 can oscillate at two different, also adjacent frequencies, so the output circuit has an output frequency f 1 at A 1 and an output frequency of f 2 at A 2. Depending on the polarity of the in-anus current, a current flows via terminal a, diode D 1., resistor R 6 to terminal b or via terminal b, diode D 2, resistor R 5 to terminal a. If the current reaches a sufficient level, a voltage drops across the resistor R 6 (terminal a positive) or across the resistor R 5 (terminal b positive) such that the diodes D 5 and D 6 (terminal a positive) or the diodes D 3 and D 4 (Kler.Lime b positive) are blocked C. The C CD windings L21 or Lll belonging to the blocked diodes cannot cause any attenuation of the associated coupling path K2 or Kl. If the input terminal a carries a positive potential, then an alternating current of the frequency f2 can be taken from the output terminal pair A2; if the input terminal b has a positive potential, then an alternating current of the frequency f1 can be taken from the output terminal pair A 1 If the two windings are connected in series, the circuit directly represents a transmitter for FM-WT. If there is a short circuit between terminals a and b or if the control current is insufficient, the damping circuits D3 or D4, R5, center tapping of the winding L 11 or D 5 or D 6, R 6, center tap of winding L 21 closed, both coupling paths K 1 and K 2 for the feedback of the generator are ineffective, so that no output voltage occurs at all.

F i g. 5 shows a further embodiment E 3 for an input part E. If the input terminal a has a positive potential, the input current flows via the diode D7, the winding L11 to terminal b, the magnetic coupling path Kl is premagnetized and the oscillation process on it is damped. If the input cycle does not have a positive potential, the input current flows through diode D8, winding L21 to terminal a, the magnetic coupling path K2 is premagnetized, and the oscillations running through it are dampened. The effect of this input part E on the overall circuit is thus similar to that of the input part E2 according to FIG. 4th

F io, 6 shows a further input part E 4, again with transistors Tsl and Ts2 as switching elements. The transistors Tsl and Ts2 are turned on or turned off in the same way as in the circuit, ' - according to FIG. 3. The diodes D13 to D16 and the center tap of the windings L 11 and L 21 serve to supply only positive potential to the respective emitter of the transistors Ts 1 and Ts 2, respectively. The input circuit E4 thereby achieves an increased sensitivity. The midpoint rectification used here can also be replaced by a bridge rectification; both circuits can be either in the collector or emitter branch.

The circuit arrangement according to FIG. 7 is structured like that according to FIG. 3, however, has an additional part which interrupts the oscillations of the generator Gl in the event of a short circuit or interruption of the current at input E. For restarting the transistor Ts4 z. B. locked by a positive pulse on its base. The circuit is particularly suitable for applications in which short circuits and interruptions at the input rarely occur, but in which the outputs must then be safely blocked. In detail, the mode of action of the additive is as follows: In normal operation, i. H. If double current is applied to the input, only one transmitter ül or ü2 is effective for maintaining the generator oscillations, the generator oscillations are dampened with the other transmitter. This means that only one of the two windings L16 or L26 is energized; this voltage is rectified by the rectifier bridge D23 to D26 and fed to the transistor Ts4. The transistor Ts4 is thus safely blocked. The addition according to FIG. 7 thus changes the mode of operation of the circuit according to FIG. 3 not for normal operation. However, if there is no input voltage at the input and both transmitters ül and ü2 are effective, then the induced voltages of windings L 16 and L 26 cancel each other out, the negative pole of the supply voltage U- becomes effective across resistor R 5 , transistor Ts 4 is controlled. As a result, the control electrodes of the transistor Ts3 are short-circuited, so that the oscillations of the generator G stop immediately; C at the same time the transistor Ts3 is switched to the blocking state. A diode connected in series to the emitter (not shown) supports the blocking of the transistor Ts 3. The diode D 27 increases the security of the circuit against the interference voltage remaining during the compensation of the induced voltages of the windings L16 and L26 , because namely at the diode D 27 a voltage drop occurs. The capacitor C 2 suppresses interference voltages that may occur when the generator G is switched over. The diode D 27 can also be replaced by a resistor, but the effect of the diode is better because of its non-linear characteristic curve: it opposes the small interference voltages with a relatively high resistance, while its resistance for the higher useful current is relatively small. The output circuit has a series circuit of two transistors Ts9 and Ts10, the bases of which are controlled alternately via diodes D9 and D10, so never simultaneously because of the block. The output circuit simulates a changeover contact.

F i g. 8 shows a circuit arrangement for single current signals. The transistor Ts5 corresponds to the transistor Tsl of the previous circuits, while the transistor Ts 6 is separated from the input. The generator G can be a generator with a "rectangular" polarity change or a generator with a "sinusoidal" polarity change. The dash-dotted box for the generator part G can therefore, for. B. by a generator according to FIG. 3 or 4 must be filled in. The output of the transformer is provided with a rectifier bridge Gb3, the diagonal branch of which is connected to the control electrodes of the transistor Ts6. In addition, the emitter of the transistor Ts6 is connected to the supply voltage U +, while the base is connected to the blocking potential U + + via a resistor R6. The circuit works as follows: flows single current, i. That is, if terminal a is negative and terminal b is positive, transistor Ts 5 becomes conductive, the oscillation processes on transmitter ül are dampened in the manner already described, so the output (L15) of transmitter ül does not emit any voltage. The blocking potential U + + becomes effective across the resistor R 6 and blocks the transistor Ts6. The vibrations via the transformer Ü2 are not dampened, the output (L25) of the transformer Ü2 emits alternating voltage. On the other hand, if there is no input current, i. That is, if both terminals a and b are at zero volts, then the transistor Ts5 is blocked, the associated transformer ül emits current at the output which, after being rectified by the rectifier bridge Gb 3, controls the transistor Ts 6 to be conductive. This dampens the vibrations at the transformer ü2, the output of which therefore does not emit any voltage.

F i g. 9 is a - another circuit diagram for Einfachstromtastung, however, with inversion of the signals: The circuit of the transistor Ts5 g is the same as in F i. 8. The generator G can also generate square or sinusoidal oscillations. In contrast to the embodiment according to FIG. 8 , the output of the transformer ü2 is connected to the control electrodes of the transistor Ts6 via the rectifier bridge Gb 4. The base of the transistor Ts6 is also connected via a resistor R6 to the negative pole of the operating voltage, the emitter to its positive pole.

The circuit shown works as follows: As long as there is no input current flowing, the transistor TJ5 is blocked, the oscillations at the associated transmitter 01 are undamped, and voltage can be drawn from the output of the transmitter UL. The transistor Ts6 is kept conductive by the voltage acting across the resistor R 6. As a result, a damping circuit is closed, the oscillations at the second transformer Ü2 are damped, so that no voltage occurs at the output of this excess. If the input current flows, the transistor Ts 5 becomes conductive and the oscillations at the first transformer are also damped. The collector current of the transistor Ts3, which is part of the generator G (see Fig. 3), rises, this change in current generates a voltage at the output of the transformer ü2, which is across the rectifier bridge. Gb 4 affects the switching state of the transistor Ts6. This will be blocked for a short time. The generator now oscillates with the released transformer Ü2, voltage is taken from the output of the transformer Ü2 and acts on the transistor Ts6 in the manner already described: The transistor Ts6 remains blocked. If the input current is interrupted again, the generator G initially oscillates with both transmitters Ül and Ü2. As a result, the output voltage of the transformer ü2 drops, the negative potential U- is effective across the resistor R 6 and controls the transistor Ts6 conductive. A damping circuit is thus closed, and the generator oscillates only with the aid of the transformer Ül, at whose output a voltage can be taken. The circuits of FIG. 8 and 9 pass on single streams as single streams. If a conversion from single to double current is to be carried out, only the transformer, which contains the rectifier bridge Gb 3 or Gb 4, has to have an additional output winding. An advantage of the circuit according to FIG. 9 compared to that according to FIG. 8 is that no additional voltage U ++ is required.

F i g. 10 shows a circuit which enables the so-called “third state” to be transmitted as well. The "third state" is a disturbance, i. H. a short circuit or an interruption at the input. This circuit can also be controlled optionally with double current or single current without switching, since the "third state" with double current corresponds to the start polarity with single current. The circuit differs from the previously discussed ones in that a third transformer, a compensation transformer ü3, is included in the circuit. The input part E is constructed similarly to that according to FIG. 6 for the transistors Tsll and Ts2. The damping winding L31 of the compensation transformer U3 is connected to the other input circuits by diodes D 41, D 42, D 47 and D 48 in such a way that the oscillations via the transformer U3 are always damped and thus suppressed, regardless of the direction of the input current, as long as one Input current flows. If, for example, the transistor Ts 1 is conductive, then the winding L 31 is short-circuited via the diode D 47 or D 48, the diode D 41, the transistor Tsl, and the oscillations via the transformer Ü3 are thus suppressed. If the transistor Ts2 is conductive, the short circuit of the winding L 31 occurs via the diode D 42 and the transistor Ts2. The circuit works in the following way: With "double current" the transformer ü3 is always damped, since one of the transistors Tsl or Ts2 is conductive. The output winding L35 does not emit any current, on the other hand voltages occur at the output A 1 or A 2 , depending on whether the transistor Ts2 or Tsl is turned on. The mode of operation of the circuit is that of a double-current-double-current converter when the output voltages are still rectified. In the event of an interruption or short circuit at the input or even with a single current (in short circuit or interruption keying), all three transformers are now enabled, i.e. H. the vibrations passing through them are left undamped. As a result of the similarity of the transformers and their series connection in the primary circuit (generator circuit), approximately one third of the original output voltage appears on each of the output windings L 15, L 25 and L 35. The windings L 15, L 25 and L 35 are connected so that the output voltage of the compensation transformer ü3 compensates for the other two. The circuit is also suitable for transmitting the “third state” or for serving as a single-current-single-current converter when the voltage occurring at output A 1 or A 2 is rectified.

When converting from single to double current, the output circuit A is slightly changed. One end of the winding L 25 is loosened approximately from the node P; this means that the compensation winding L35 only has an effect on output A 1 . If the transistor Ts2 at the input is controlled to be conductive by the single current signal "stop polarity", then the transmitters ü3 and ü2 are attenuated, but not the transmitter Ül; An output signal therefore appears at output A 1. In the case of start polarity, the other characteristic state of a single current signal, there is no voltage at the input of the circuit, the damping circuits are open, the generator G can oscillate with all transmitters U1 to U3; However, since the coils L15 and L 35 are wound in the same direction, their output voltage is canceled: The output A 1 has no output voltage. On the other hand, voltage occurs at output A 2, i. that is, after rectification, the circuit thus obtained is a single-current-double-current converter.

The circuit according to FIG. 11 shows another embodiment of a converter with three transmitters. The damping circuit of the transmitter ü3 is closed by its own transistor Ts7, which is controlled to be conductive depending on the switching state of one of the two transistors Tsl or Ts2. It is switched into the circuit of the respective conductive transistor Ts 1 or Ts 2 via the diodes D 58 and D 59. The resistor R 2 thereby takes over the function of the two resistors R 2 and R 3 of the circuit according to FIG. 10. The other resistors R 5, R 6, R 7, R 8 and R 9 are used to ensure uniform blocking of the semiconductor elements by connecting the bases of the transistors to the emitters with as low an impedance as possible. The compensation transformer ü3 has two output windings L 351 and L 352 L The coil 351 is located in the output circuit A 2; both output circuits are galvanically separated from each other. The circuit according to FIG. 11 operates like that according to FIG. 10. If the input of the circuit is assigned "double current", the oscillations via the transformer ü3 are suppressed, so the output windings L351 or L352 are ineffective. The output signal can either be picked up at output A 1 or output A2, depending on whether the transistor Ts2 or Tsl is conductive. ü2 and ü3 released, i.e. the oscillations passing through them left undamped. Since the effect of the output voltages of windings L 15 and L 351 and windings L 25 and L 352 cancel each other out, no output signal appears at any of the outputs A 1 or A2 When the output voltages are rectified, the circuit of FIG. 11 can be used as a double-current to double-current converter, as a single-current to single-current converter and, if one of the windings L 351 or L352 is disconnected, as a single-current to double-current converter. The output circuits A of the circuits of FIG. 10 and C in FIG. 11 are interchangeable.

Another circuit with three transmitters UL, UL2, UL4 for transferring double current or single current is shown in FIG. The compensation transformer ü4 is switched on in the generator and in the output circuit A as well as in the circuit according to FIG. 1 1 - it can also according to FIG. 10 can be switched -, but a damping winding CP ID development is not provided for this compensation transformer ü4. The input part E corresponds e.g. B. that according to FIG. 3, however, in FIG. 12 additional diodes D 62, D 63 are provided in the damping circuits. These diodes improve the blocking of the transistors Tsl and Ts3 when the "third state" is transmitted. You can - as shown - under certain conditions also the resistors R2 and R3 of the input circuit from FIG. 3 replace. The input circuit of FIG. 12 (with or without R 2 / R 3) can again be exchanged and combined with the previously mentioned and yet to be mentioned input circuits. In the circuit according to FIG. 12, the oscillations are never dampened via the compensation transformer ü4, so its output winding always emits voltage, namely half the output voltage, if two transformers are working, a third of the output voltage. when all three transmitters work. Because of the compensation of the output voltages of the transformer in an output circuit according to FIG. 10 or 11 then results in double current that in each case at the output A 1 or A 2, whose transformer is ineffective for the oscillation process, the voltage of the compensation transformer Ü 4 can be taken, while at the other output, the voltage of the compensation transformer and the other cancel the transmitter. In the case of the “third state”, all output windings carry voltages of the same magnitude, which compensate each other so that no voltage occurs at either output A 1 or A 2. The circuit according to FIG. 12 is suitable as a converter from double current to gated alternating current at two output pairs A 1 and A 2 with evaluation of the »third state« or (with subsequent rectification) as a converter from single to single current.

A conversion from single current to gated alternating current at two output pairs A 1 and A 2 or with subsequent rectification to double current can be implemented in the above-discussed circuit with an input part E according to FIG. 13 or 14 and the modification already described - only one output A 1 or A 2 contains both starting winding of a Arbeitsübertragers and a compensation winding in series, the other output of A 2 or A 1 contains no compensation winding - be made. Through these circuits it is achieved that the oscillations over both Arbeitstransferger ül and ü2 when a single current step occurs in stop polarity (terminal a negative, terminal b positive) are dampened by short-circuiting the damping circuit, so that only the compensation transformer is effective and the one connected to it Output A 1 (or A 2) delivers current. If there is no voltage at the input of the circuit ( Fig. 13 or 14) (starting polarity), then the output voltages of the compensation transformer and the working transformer connected in series with it cancel each other out; instead, A 2 (or A 1) appears at the other output , which is not in series with a compensation direction, a voltage.

Claims (1)

Claims: 1. Circuit arrangement with a feedback generator that oscillates or does not oscillate depending on the state of the incoming line, converts the pulse combinations, such as telegraphic characters or the like, into square-wave currents of any frequency or sinusoidal currents, preferably higher frequencies, and converts them back into direct current signals in an output circuit # transformed and optionally sums and for galvanic separation of the incoming and outgoing lines and the necessary auxiliary power source of the incoming and outgoing line serves, d a d u rch g e -kennz eichnet that a transformer with feedback generator C, (g) is provided, which has at least two transmitters (ül, ü2) with separate magnetic coupling paths (KI, K2) , which transmitters determine the oscillation frequency, with each transmitter having additional windings (Lll, L21) for the purpose that depending on the presence and / or direction of the A 'g' angsstromes over a winding ung (Lll, L21) of the transformer (ül, ü2) di-, from this transformer certain oscillations of the generator are suppressed in such a way that this winding (L 11, L 21) is short-circuited, and that only on the transformer that does not use alternating current is short-circuited, an alternating voltage is picked up via another winding (L15, L25), which after rectification determines the state of the outgoing line. 2. Circuit arrangement according to claim 1, characterized in that the generator (G) operates on the blocking oscillator principle. 3. Circuit arrangement according to claim 2, characterized in that the generator (G) has additional feedback windings (L13, L23, L33) which are firmly coupled to the windings (L12, L22 and L32) and together with a diode (D 11) a limiter circuit - 'form which gives the single-ended generator properties of a push-pull generator. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the oscillations of the generator (G) with respect to one or more coupling paths (K1, K2, K3) are largely suppressed in that the input current depending on its presence and / or its Direction an input winding (L 11 or L 21, in F i g. 5) flows through and thereby generates a correspondingly large magnetic bias. 5. Circuit arrangement according to one of claims 1 to 3, characterized in that the oscillations of the generator (G) with respect to one or more coupling paths (K1, K2, K3) are released in that the input current depending on its direction at one of two resistors (R 5 or R 6) causes a voltage drop that blocks electronic switches (diodes D 3 to D 6) for the damping circuits. 6. Circuit arrangement according to one of claims 1 to 3, characterized in that the oscillations of the generator (G) with respect to one or more coupling paths (KI, K2, K3) are largely suppressed in that the input current depending on its presence and / or its direction an input winding (Lll or L21) switches electronically so that a closed current path as a damping circuit for the generator (G) arises or does not arise. 7. Circuit arrangement according to claim 6, characterized in that each input-side winding (Lll or L21) is bridged by a transistor (Tsl or Ts2) in the emitter circuit, which is conductively controlled by current signals. 8. Circuit arrangement according to claim 7, characterized in that each input winding (L 11 or L 21) contains a center tap and end connections which are connected to the collectors ( D 13 to D 16 or D 43 to D 46) via appropriately polarized diodes ( FIG. 6) or the emitters ( FIG. 10) of the associated transistors lead. 9. Circuit arrangement according to claim 7, characterized in that the end connections of the input-side windings (Lll, L21) are connected to the emitters and collectors of the associated transistors via corresponding bridge rectifier circuits. 10. Circuit arrangement according to claim 7, characterized in that the emitter lead of each input transistor (Tsl or Ts2) contains a correspondingly polarized diode (D 62, D 63) . 11. Circuit arrangement according to one of claims6 to 10, characterized in that each transformer (ül, ü2) has further windings (L 16 or L 26 in FIG. 7) for generating a blocking voltage, the winding directions of which are opposite to one another lead these windings (L 16 or L 26) via a rectifier circuit (D 13 to D 26) to the control electrodes of an electronic short-circuit switch (Ts4), which short-circuits the control electrodes of the active element (Ts3) of the generator (G) when both windings ( L16 or L26) conduct current t2. 12. Circuit arrangement according to claim 11, characterized in that the control electrodes of the short-circuit switch (Ts4) are bridged by a capacitor (C2). 13. Circuit arrangement according to claim 11 or 12, characterized in that the rectifier circuit (D 13 to D 26) is followed by a further diode (D 27) . 14. Circuit arrangement for single current input signals according to one of claims 5 to 10, characterized in that only a single input winding (LII), but two Überertrac, he (ül and ü2) are present that the output current of the first transformer (ül) the & influenced in the input of the second transmitter (Ü2) in the sense of damping the generator oscillations and that the output of the second transmitter (Ü2) serves as a signal output. 15. Schaltunasordnung for single current input signals according to one of claims 5 to 10, characterized in that at the moment of the changeover from freely oscillating to damped state of the oscillations in the first transmitter (ü 1) the current of the active element (Ts3) of the generator (G ) increases, as a result of which a voltage is induced in the second transformer (ü2), which is fed back in the sense of canceling the otherwise effective damping of the generator oscillations. 16 Circuit arrangement according to one of Claims 5 to 10, characterized in that a compensation transformer (ü3) with a magnetic coupling path (K3) separate from the other transmitters (working transformer ül, Ü2) is inserted into the circuit in addition to the two working transmitters (Ü1 and Ü2) and that this is Kompensationsübertragger (ü3) so connected to the input circuit (e), that the vibrations of the generator (G) with respect to this will always be damped transformer regardless of the direction in the presence of the input current. 17. Circuit arrangement according to one of claims 5 to 10, characterized in that a compensation transformer (ü4) with a separate magnetic coupling path (K4) in addition to the working transmitters (t71 and ü2) is inserted into the circuit, such that the compensation transformer is independent of the input current 4D is never attenuated. 18. Schaltun-sanordnung according to claim 16, characterized in that the compensation transformer (ü3) with its damping winding (L 31) through diodes (D 41, D 42, D 47, D 48) to the input circuit (E) is connected in such a way that a damping circuit for the input winding (L31) via one of the transistors (Tsl or Ts2) is closed when one of these transistors (Tsl or Ts2) is turned on. 19. Circuit arrangement according to spoke 16, characterized 'in' that the compensation transformer (T 3) is damped by a switched-through diodes (D 58, D 59) transistor (TJ7) when (Tsl or Ts2) is conducting, d. H. as long as an input current flows. 20. Circuit arrangement according to one of claims 16 to 19, characterized in that the output winding (L35) of the compensation transformer (ü3 or ü4); In the output circuit of both the one and the other output winding (L 15 and L 25) of the working transformer (ül and ü2), so that the voltage of the output winding (L35) of the compensation cD In the C transformer (Ü3) the voltages of the other two output windings ( L15 and L25) compensated if the generator (G) oscillates with all three transmitted (ül, Ü2 and ü3 or ü4). 21. Circuit arrangement for single-current input signals according to one of claims 16 to 19h, characterized in that the output winding (L 35) of the compensation transformer (ü3 or ü4) in the output circuit (A't or A 2) has only one output winding (L15 or L25) of the working transformer (ÜI or ü2) is so that the voltages of the output winding (L35) of the compensation transformer (03) only compensates for the voltages of one other output winding # (L15 or L25) when the generator oscillates with all three transformers. 22. Circuit arrangement according to claim l (or 17, characterized in that the compensation transformer (ü3 or ü4) has two output windings (L 351 and L352) in the sense of voltage compensation for the other output windings (L 15 and L 25) , one of which (L351) in the first (A 1) and the other (L352) in the second output circuit (A: #. 23. Circuit arrangement according to Claim 17, characterized in that, when a single-current signal element is present, both working transformers (ül and ü2) are in Sense of the damping of the generator oscillations are influenced and that the compensation transfer (Ü4) is only effective with regard to an output winding (Lli # or L25) of a working transfer (ül or ü2. Considered publications: German Auslegeschriften No. 1078 613, 1117 168, 1073 542.