DE1070236B - - Google Patents

Description

The invention relates to a circuit arrangement for the controlled, non-contact formation of direct current-fed devices Loop circuits. The formation of loop circuits is then necessary, for example, if a telephone system equipped with electromechanical switching elements is replaced by a Attendees. should be assigned on the input side, since in this case the formation of a loop circuit on the part of the subscriber who wishes to recognize that he is establishing a telephone connection want. If the subscriber in question is connected to a subsystem, the "Connecting line connecting the sub-system with the main system to close a DC loop, as this connection line in the main office in similar to how a direct subscriber line is treated. The formation of loop circuits was previously done by closing a contact on the line in question Position, where it is ensured that the person concerned Electrical contact from the organs controlling it, d. H. from its relay winding, is separated. These Separation 'is necessary to avoid overvoltages from the Λ / connection line malfunctions are caused in the sub-system. Such disturbances can also be avoided by additional inductive transmitters are built in, which transmit the signals given to both branches of the line Prevent interference voltages.

If it is an electronic subsystem in which the entire setting process is within the sub-system is controlled by electronic switching means, it is not easily possible if the principle of the perfect electronic implementation of the adjustment paths should not be given up should, the loop closure in the A ^ erbindungsleitung by means of an electromagnetically controlled contact. The invention therefore proposes an arrangement that allows without the aid of mechanical contacts in an exchange line to create a loop closure without the principle of galvanic separation of the connecting line is abandoned by the devices controlling the loop closure.

According to the invention, the feed current is in the loop circuit of the DC-fed line loop blocking semiconductors, together with the winding of an inductive transformer, switched, and through Changes in the current flowing through another winding of this transformer can occur in the with the semiconductors in the line loop winding which cancels the blocking effect of the semiconductors Potential can be generated.

In a preferred embodiment of the inventive circuit arrangement: ii _; ;

for controlled non-contact 'education ^

DC-fed loop en-flow circuits

Applicant: ν

Friedrich Merk; i ■> Telefonbau Aktiengesellschaft, Munich 9, Warngauer Strv 32

Leönhard Rofler, Munich,

Dipl.-Ing. Friedrich Heim, Krailling near Munich, and Dipl.-Ing. Traian Onciul, Munich,

have been named as inventors

The loop closure takes place via semiconductors, which have a glow lamp-like ¹ current voltage characteristic and the voltage pulses transmitted via the associated transformers are transferred from the high-resistance state that exerts the blocking effect to the low-resistance state that forms the loop and are kept in this state by the applied supply voltage. With this arrangement, a loop interruption desired after the loop has closed can be brought about either by temporarily switching off the supply voltage or by a temporary change in potential transmitted via the inductive transformers associated with the semiconductors. In this way, the transmission of setting pulses can be achieved, since the semiconductors in question are brought into the conducting state by a brief pulse in a certain direction and into the blocking state by a subsequent pulse in the opposite direction.

Another possibility for realizing the idea of the invention is that the semiconductors to a ver ^ the flow of a loop current hindering counter voltage are connected, the voltage changes given to the loop via the transformer for the duration of the desired

909 68T / 91

th loop closure is compensated. The potential level of the counter voltage advantageously corresponds to the supply voltage, and the inductively transmitted voltage change which enables a loop current to flow is brought about by the rectification of a square-wave voltage.
In another embodiment of the invention, the loop is guided over a full-wave rectifier arrangement which is arranged in the reverse direction with respect to the loop voltage, the blocking effect of which is canceled by an alternating potential applied to the input of the rectifier arrangement for the duration of the desired loop closure.

In the case of connecting lines between a main and a sub-system or between a switching system and a call station, it is necessary to also use alternating currents, especially low currents Frequency, for example of the ringing current, to be transmitted to the sub-system or to the intercom. In order to by the transmission of such alternating currents, which due to their potential level are capable of the Cancel the blocking effect of the semiconductors and thus, if necessary, simulate a line short, no incorrect switching occurs, it is proposed according to a further characteristic of the invention, the arrangement consisting of semiconductors and inductive transformers to the frequency of the respective alternating current matched filter and / or blocking circuits upstream and the transmitted Acquire alternating current through these circles and feed it to its evaluation. So by switching on Such circles in the connecting line do not transmit pulses over the line is disturbed, it is advantageous, during a pulse-wise formation of loop closures, e.g. B. to Transmission of setting pulses to short-circuit the inductances of these resonance circuits on the secondary side.

Some exemplary embodiments of the invention are shown in the drawing. It shows

1 shows an arrangement with a Shockley diode as a switching element,

2 shows the voltage characteristics of a Shockley diode,

3 shows the inductive pulses controlling the Shockley diode and the pulses applied to the line,

4 shows a switching device operating with two full-wave rectifier arrangements and a counter voltage,

5 shows a through-connection device operating with a full-wave rectifier arrangement,

Fig. 6 shows an arrangement for the removal of low frequencies Alternating currents and

7 shows a further development of the _; Fig. 6.

In all figures, only the switching elements that are absolutely necessary for understanding the invention are shown been recorded. The supply voltage of the connection line between a main arilage and a subsystem or between an office and a subscriber line is corresponding to the Established at -60 V in current practice.

In Fig. 1 by the Office with is -.. Fed 60 V connecting line VL in the sub-system via a Shockley diode D and two winding halves of the secondary winding out 5 "of a Induktivübertragers Ue According to the characteristic shown in Figure 2 of the Shockley diode D is this very hoehohmig at rest, so that it is possible via the connecting line VL no current flow take place. in order to form the line loop, it is necessary that a pulse of appropriate direction to the secondary side S is given of this transformer through the transformer Ue, which the supply voltage of

- 60 V superimposed, so that now the Shockley diode D ignites. The supply voltage of

- 60 V it is kept in the low-resistance state even after this pulse has ended.

The diode D can be extinguished either by interrupting the supply voltage;

ίο it is also possible to lower the potential at the diode D so that it is brought back into its high-impedance blocking state by means of counter-directed erase pulses which are given by the primary winding P of the transformer Ue to its secondary winding.

FIG. 3 shows how loop closings and loop interruptions follow one another through a sequence of brief ignition and extinguishing pulses on the connecting line VL , in order to thereby form setting pulses.

In the arrangement according to FIG. 4, two full-wave rectifier arrangements Gl 1 and G12 are connected in the two line branches α and b of the connection line VL , which are connected to the supply voltage at one output terminal and to a counter voltage of also -60 V at their other output terminal. This prevents a direct current from flowing over the connecting line VL .

The alternating current inputs of the two full-wave rectifier arrangements GIl and Gl 2 are connected to windings Wl and W 3 of two transformers UeI and Ue2 , whose primary windings W 2 and WA are fed to square waves. By rectifying this square wave current, an additional DC voltage of approximately 30 V is generated in each of the two rectifier arrangements GIl and Gl 2, which amplifies the DC voltage applied by the office. This enables a direct current to flow via the connecting line VL . It is also possible to arrange the windings W1 and W3 on a common core, so that in this case, instead of the windings W2 and WA, a single winding is sufficient to control the arrangement. In the embodiment according to FIG. 5, the full-wave rectifier arrangement Gl 3 is arranged in such a way that it prevents a direct current from flowing over the connecting line VL in the idle state. However, when a square wave voltage is applied to winding W 6, an opposing voltage of about 120 V is generated via windings W 5 and W 6 of transformer UeZ , which unblocks the full-wave rectifier arrangement Gl 3 and thus enables a loop current to flow via the connecting line VL.

If direct current flows through the rectifier arrangements in both the arrangement according to FIG. 4 and in that according to FIG. 5, both arrangements also have a low ac resistance. The rectifiers are forward biased, and the windings Wl and WZ or the windings W5 are practically short-circuited when the voltage source applied to the windings W 2 and WA or W 6 has a low resistance.

It is for traffic between a main and a sub-system or between an office and a call station required, a low-frequency alternating voltage as a criterion for an incoming call of about 75 V eff. to be connected to the connection line. By a tension like that

As a result, most of the known electronic switches are hindered in their function or possibly destroyed. When using a Shockley diode as a switching device, it would be ignited and extinguished, for example, in the cycle of the alternating ringing voltage, so that this would create a loop closure and simulate the reporting of the called subscriber. For this reason, FIG. 6 shows an arrangement by which such a ringing frequency is kept away from the Shockley diode and fed to an evaluation element. The arrangement provided for this consists of two parallel resonance circuits PR 1 and PR2 connected into the connecting line VL and a cross member RR designed as a series resonance circuit. The transmitted alternating ringing voltage falls largely on the parallel circuits PR 1 and PR 2 and can be fed from there to an evaluation element AR via an inductive coupling by means of the transformer Ue 4. The evaluation device AR has a high resistance so that the transmission circuit is not attenuated too much. By activating such blocking circuits, the transmission of speech frequencies is not hindered.

Because the behavior of a filter does not only depend on the frequency of the alternating currents flowing through it because the behavior of a filter is also determined by the terminating resistors and these change with the respective line length, it is advantageous to use the filter when a dialing pulse is given switch off, so that the correct transmission of the dialing pulses does not occur through these filters is disturbed.

The filter can be switched off without a galvanic connection to the control part in that, as shown in FIG. 7, some of the inductances of the filter are designed as transformers which can be short-circuited on the secondary side. In a manner not shown, both the inductances of the parallel circuits PR 1 and PR 2 and the inductance of the series resonant circuit RR via contacts kl and. k2 short-circuited on the secondary side. In these circles, only the control inductance is effective in the pulse transmission, and the blocking frequency of the filter is so high that the 'dialing pulses are not deformed.

The arrangement according to FIG. 7 is only to be understood as an example. Instead of short-circuiting the inductances on the secondary side, these inductances can also be influenced primarily, or any complex resistances can be inserted instead of a short-circuit on the secondary side. Since it is an electronic sub- installation, the contacts / el and k2 are expediently also designed as electronic switching means.

Claims (10)

Claims: 60 1. Circuit arrangement for the controlled, non-contact formation of DC-fed loop circuits, in particular via connecting lines running between electronic telephone substations and main telephone systems equipped with electromechanical switching means, characterized in that semiconductors which block the feed current are connected together with the winding of an Iriducfiv transformer in the loop circuit of the DC-fed line loop and that ' Changes in the current flowing through another winding of this transformer in the winding located only in the semiconductors in the line loop can be generated at the blocking effect of the semiconductors. 2. Circuit arrangement according to claim 1, characterized in that the loop closure takes place via semiconductors with a current-voltage characteristic curve corresponding to a glow lamp and the semiconductors by means of voltage pulses transmitted via the transformers assigned to them the high-resistance state exerting the blocking effect into the state forming the loop closure transferred to the low-resistance state and held in this state by the applied supply voltage will. 3. Circuit arrangement according to claim 1 and 2, characterized in that one after Loop closure Desired loop interruption by temporarily switching off the supply voltage is brought about. 4. Circuit arrangement according to claim 1 and 2, characterized in that one after Loop closure desired loop interruption by one associated with the semiconductors Inductive transmitters transmitted temporary change in potential is brought about. 5. Circuit arrangement according to claim 1, characterized in that the semiconductors are connected to a the flow of a loop current hindering the counter voltage are switched by a Voltage change given to the loop via the transformer • for the duration of the desired one Loop closure is compensated. 6. Circuit arrangement according to claim 1 and 5, characterized in that the counter voltage corresponds in its potential level to the supply voltage and the flow of a loop current Enabling inductively transmitted voltage change by rectifying a square-wave voltage is effected. 7. Circuit arrangement according to claim 1, 5 and 6, characterized in that in each branch each loop a full-wave rectifier arrangement formed from semiconductors is switched, the inputs of which are fed by an inductively transmitted square wave current. 8. Circuit arrangement according to claim 1, characterized in that the loop has a Full-wave rectification arrangement arranged in the reverse direction in relation to the loop voltage is and its blocking effect by a to the input of the rectifier arrangement for the Duration of the desired loop closure applied alternating potential is canceled. 9. Circuit arrangement according to claim 1, characterized in that for additional transmission of alternating currents, especially of low-frequency alternating currents from semiconductors and inductive transmitters existing arrangement on the frequency of the alternating current in question matched sieve ^ and / or Blocking circuits are connected upstream and the additionally transmitted alternating current is removed via these circuits and its evaluation is supplied. 10. Circuit arrangement according to claim 1 and 9, characterized in that the one in the Loop-laid parallel resonance circuit, falling alternating current of a certain frequency is inductively removed from these resonance circuits.
> ; ill. Circuit arrangement according to Claims 1, 9 and 10, characterized in that during the pulse-wise formation of loop closures, for example for the transmission of setting pulses, the inductances of the resonance circuits are short-circuited on the secondary side. References considered: British Patent No. 670,252. 1 sheet of drawings