DE3425533C1 - Circuit arrangement for automatically closing an interrupted remote-supply loop upstream of an interruption point - Google Patents

Abstract

Circuit arrangement for automatic closure of an interrupted remote-supply loop upstream of an interruption point, a first switch which can be controlled via the remote-supply current and a second switch connected in series with the first switch being provided in a quadrature-axis branch. In a circuit arrangement of this type, the first switch is intended to be activated as an electronic switch as reliably and with as little loss as possible. This is achieved by forming the first switch by means of field effect transistor and the second switch by means of a thyristor. The circuit arrangement can be used advantageously in devices for remote-supply of intermediate stations of a data communications system. <IMAGE>

Description

In this context, there is one constructed with semiconductor elements Shunt branch advantageous, since the series choke is then essentially only used to limit di / dt is required and can therefore be comparatively small. In addition, the comparatively allows large permissible surge current has a relatively small ohm value of resistance in the cross branch. This results in little heat generation in the event of a fault, at which the remote feed current flows through the shunt.

However, thyristors require comparatively for their control large tax flows. Since there are still voltages at the cross arm of the circuit arrangement different sizes can be, the dimensioning of the resistances in the control circuit Difficulties arise because, on the one hand, the power loss is low at high voltage and on the other hand, the control current must be sufficiently large at low voltages target.

The object of the invention is therefore to provide the circuit arrangement of the initially mentioned type in such a way that the first switch located in the shunt branch as an electronic switch can be controlled as safely and with little loss as possible. In particular the circuit arrangement should be able to handle unwanted cross-connections via the shunt arm that can arise from influencing voltages or currents, to pick up automatically.

According to the invention, the circuit arrangement for solving this Task formed in the manner indicated in the characterizing part of claim 1. The nonlinear two-terminal network in the manner of a Zener diode can, for. B. a series circuit of diodes, where the sum of the threshold voltages of the diodes is effective. One or more Zener diodes are preferably used.

The measures according to the invention result in more advantageous Way a particularly low-loss and reliably working circuit arrangement.

Advantageous refinements of the invention emerge from the subclaims.

The invention is based on the embodiment shown in the figure explained in more detail.

The figure shows a circuit arrangement for closing the remote feed loop or a so-called switching add-on for series-fed repeaters or repeaters shown in the event of a break in the route. Such a switch ensures that the fault-free part of the route can remain in operation. With the help of the circuit arrangement the remote feed loop 17 is closed so that no dangerous continuous voltages arise before the point of interruption.

If the route is intact, the circuit arrangement is capable of preventing unwanted Cross connections that can arise from influencing voltages or currents, to pick up automatically.

In the remote feed circuit 17 shown in the figure are with the help the constant current source 1 of a feed point via the remote feed circuit 17 several Remotely fed intermediate stations of a communication link. From the intermediate points the remotely fed consumers 31 ... 3n are shown in each case, which are in the remote feed current paths 17, and 172 of the remote feed loop 17 are located and in particular through feed inputs are formed by repeaters or regenerators. If necessary, can ever A single feed input can be provided as an intermediate point.

On the side of the shown amplifier point facing away from the feed point, d. H. in the further part of the remote feed loop is the measuring resistor in core 172 20 inserted. Between the consumers 3, and the measuring resistor 15 is between the two wires 171 and 172 a shunt branch Q is provided, which the feed inputs the regenerators 31 connects to each other and from the series circuit of the throttle 8, the resistor 9, the thyristor 11, the drain-source path of the field effect transistor 10 and the resistor 12 consists. The choke 8 is used for the remote feed voltage In the reverse direction polarized diode 18 bridged.

The remote feed voltage is parallel to the drain-source path reverse-biased Zener diode 15. The cathode of thyristor 11 is connected to the drain electrode of the field effect transistor 10.

The control electrode of the thyristor 11 is via the Zener diode series circuit 21 to the remote feed current path 171 and via the four-layer diode 7 to a circuit point out, on the one hand via the capacitor 6 to the source electrode of the field effect transistor 10 and on the other hand via the diode 5 to the drain electrode of the field effect transistor 10 is placed. The diode 5 is polarized in the forward direction for the remote supply voltage. The drain electrode of the field effect transistor 10 is also across the resistor 4 connected to the remote feed current path 17.

Is parallel to the gate-source path of the field effect transistor 10 the collector-emitter path of the transistor 16, which has its base on the Cross branch remote end of the measuring resistor 20 is connected so that the Base-emitter path of the transistor 16 on the series circuit of the resistor 20 and the resistor 12 is located. The collector of the npn transistor 16 is immediately at the gate of the field effect transistor, which is n-type and is across the resistor 14 to the remote feed current path 17.

Are parallel to the gate-source path of the field effect transistor 10 the Zener diode 19 and the capacitor 13.

Normal operation is initially assumed, with the Constant current source 1 facing away from the side of the shunt branch Q further line fields so that the entire remote feed current IF flows through the measuring resistor 20.

The voltage drop across resistor 20 is so great that through the base-emitter path of the bipolar transistor 16 so much current flows that the transistor 16 is fully turned on is. The gate of the field effect transistor 10, which is a MOS-FET transistor, has the voltage is zero in relation to its source electrode. The field effect transistor 10 is therefore blocked.

The capacitor 6 is across the diode 5 and the very high resistance 4 charged at most to the voltage specified by Zener diode 15.

The thyristor 11 is in the blocking state.

The voltage between terminals a 1 and a 2 of the constant current source 1 is divided between the field effect transistor 10 and the thyristor 11. The distribution of tension is specified by the resistor 4 and the Zener diode 15. The resistor 12 takes over only a very low voltage, which is neglected in the context under consideration because it has a very low resistance.

In this way, the field effect transistor 10 is one, with the help the Zener diode 15 is assigned only a low voltage. Most of the tension will be taken over by the thyristor 11.

If the remote feed loop is turned away from the constant current source 1 Side of the shunt arm Q is interrupted, the resistor 20 is de-energized, the transistor 16 blocks, the gate of the field effect transistor 10 receives a voltage from the Zener diode 19 and the very high resistance 14 is determined.

The field effect transistor 10 becomes conductive. The condensate gate 6 can be transmitted via the four-layer diode 7, via the control path of the thyristor 11 and discharged through the field effect transistor 10. The discharge current ignites the thyristor 11 and the shunt branch Q becomes conductive and takes over after the line capacitance has been discharged 21, 22 the remote supply current IF: The four-layer diode 7 can be omitted if the voltage increase at the gate of the field effect transistor 10 is happening quickly enough. With the four-layer diode 7 is also on when the field effect transistor 10 is slowly switched through reliable ignition of the thyristor 11 guaranteed.

With a slow through-connection of the field effect transistor is at the following process to be expected: The remote power supply device 1, on which a remote power supply loop 17 is connected with an interruption in the second field, is switched on. The circuit arrangement according to the figure, which is initially de-energized, should the Establish cross-connection via cross-branch Q.

The time constant, determined by the resistance 4 and the capacitor 6, be much smaller than the time constant determined by the Capacitor 13 and resistor 14 is determined. The capacitor 6 must be sufficient be charged before the gate of the field effect transistor 10 takes voltage, so sufficient energy is provided for the ignition of the thyristor 11. Because of the necessary large time constant of the RC element 14, 13 and the relative slow increase in the voltage of the remote power supply between a 1 and a 2 the field effect transistor 10 slowly switch through. Without the four-layer diode 7 would due to the slow change in the voltage at the field effect transistor 10, the discharge current of the capacitor 6 may be too small to trigger the thyristor 11. The four-layer diode However, 7 ensures a rapid change in the ignition circuit resistance and ignites hence the thyristor 11. The cross-connection via the cross-arm Q is thus established.

The choke 8 is used for di / dt limitation, the diode 18 for reverse magnetization the throttle 8.

The point of interruption on the one facing away from the constant current source 1 Side of the cross-branch Q is restored, in the resistor 2Q again Electricity flow. The transistor 16 becomes conductive and the voltage at the gate of the field effect transistor 10 becomes zero. The field effect transistor 10 blocks and takes over the voltage that at the remote supply current paths 17r and 172 of the constant current source 1 is present. This voltage is determined by the constant before the shunt arm Q is blocked Remote feed current and the resistor 9. After the blocking of the shunt branch Q rises this remote feed voltage as a result of the step-by-step commissioning of the following Switch accessories with finite speed.

The Zener voltage of the Zener diode 15 is dimensioned such that it is greater is than the remote feed voltage that is applied to the shunt branch after it has been blocked and before it is blocked of the shunt branch of a subsequent switching device is present. Through the thyristor 11 and through the Zener diode 15, no current can therefore flow in this operating state. It is also ensured that the charging current occurring during this process of the capacitor 6 is smaller than the holding current of the thyristor 11. The thyristor 11 therefore goes into the blocking state.

The blocked thyristor 11 is then able to control the proportion of over the Zener voltage of the Zener diode 15 to take up further increasing remote feed voltage.

The entire branch is blocked again.

If - based on normal operation - an increase in voltage by lightning influence between the remote feed current paths 171, 172, SO can through the Zener diodes 7 and 15 an ignition current through the grid of the thyristor 11 flow. the Line capacitances 2 and 22 discharge via the thyristor 11, the Zener diode 15 and the resistor 12. Due to the voltage drop across the resistor 12, the transistor blocks 16 and the field effect transistor 10 also becomes conductive. It relieves the Zener diode 15 and keeps itself conductive as long as the discharge current flows. With fading of the discharge current outweighs the influence of the current at the resistor 20. The Transistor 16 becomes conductive and field effect transistor 10 blocks. In a further episode the thyristor 11 regains its blocking capability in the same manner as above described. The cross connection Q blocks again. Through the Zener diodes 7 and 15 is both the field effect transistor 10 and the thyristor 11 against overvoltages, especially protected from the effects of lightning.

Claims (9)

Claims: 1. Circuit arrangement for automatic closing an interrupted remote feed loop in front of an interruption point, for remote feed devices, which feed electrical consumers (31 ... 3n) by means of direct current series feed, wherein in a shunt arm (Q) a series connection of two controllable switches and a series circuit containing a resistor (9) is arranged, the first Switch through the one (172) of the remote feed current paths (17s, 172) flowing Current is controllable in such a way that it is at currents above a predetermined fraction from the nominal value of the remote feed current (IF) and opened for currents below a specified value Fraction of the nominal value of the remote feed current (IF) is closed and the second Switch formed by a thyristor (11) and connected to a control electrode by means of a connected control device is controllable, d a d u r c h g e -k e n n z e i c h n e t that the first controllable switch by one with the source-drain path Field effect transistor (10) lying in the shunt branch is formed, the source-drain path of which by a non-linear two-pole (15) in the manner of one for the between the remote feed current paths (171, 172) lying voltage is bridged in the reverse direction polarized Z-diode and with its drain electrode via a resistor (4) to a remote feed current path (171) is performed and that the control device provided for controlling the thyristor (11) one arranged parallel to the source-drain path of the field effect transistor (10) Series connection of a diode polarized in the forward direction for the remote feed current (5) and a capacitor (6) and that the control electrode of the thyristor (11) is connected to the junction of diode (5) and capacitor (6). 2. Circuit arrangement according to claim 1, characterized in that between the connection point of diode (5) and capacitor (6) and the control electrode of the thyristor (11) is another non-linear two-pole (7) in the manner of a four-layer diode is arranged. 3. Circuit arrangement according to claim 1 or 2, characterized in that that parallel to the control path of the field effect transistor (10), the emitter-collector path of a bipolar transistor (16) is through the in one of the remote feed current paths (172) flowing current is controllable in such a way that it is at currents above the predetermined Fraction of the nominal value of the remote feed current (IF) conductive and with currents below the specified fraction of the nominal value of the remote feed current (IF) is blocked and that the control electrode of the field effect transistor (10) has a first resistor (14) is led to the other remote feed current path (171) 4. Circuit arrangement according to claim 3, characterized in that the emitter of the bipolar transistor (16) directly to the source electrode of the field effect transistor (10) and over a resistor (12) to which a remote feed current path (172) is led. 5. Circuit arrangement according to one of claims 1 to 4, characterized characterized in that a parallel to the control path of the field effect transistor (10) for the reverse voltage between the remote feed current paths (17i, 172) polarized Zener diode (19) is arranged. 6. Circuit arrangement according to one of claims 1 to 5, characterized characterized in that a parallel to the control path of the field effect transistor (10) Condenser (13) is arranged. 7. Circuit arrangement according to one of claims 1 to 6, characterized characterized in that in the shunt arm (Q) between the source electrode of the field effect transistor (10) and a remote feed current path (172) a resistor (12) is arranged. 8. Circuit arrangement according to one of claims 1 to 7, characterized characterized in that in the shunt arm (Q) between the thyristor (11) and the one remote feed current path (171) a choke (8) is arranged through a for the remote feed current paths (171, 172) voltage is bridged in the reverse-biased diode. 9. Circuit arrangement according to claim 8, characterized in that between the thyristor (11) and the one remote feed current path (-17l) a resistor (9) is arranged for the throttle (8). The invention relates to one as in the preamble of the claim 1 specified circuit arrangement. Such a circuit arrangement is already from DE-PS 12 67 267 known. The known circuit arrangement is a so-called one Switching add-on in which a relay contact and a thyristor in series in the shunt branch are switched. The relay contact belongs to a relay that measures the current, the flows in the remote feed circuit on the side of the cross-branch that faces away from the feed source is. The control electrode of the thyristor is connected to an RC element that is parallel is arranged to the anode-cathode path of the thyristor. As a result of the delayed When the thyristor is triggered, the relay contact does not need to switch the remote feed current. As soon as the fault has been eliminated, the relay contact interrupts the cross-loop branch and thereby inevitably clears the thyristor. In this way it is achieved that the relay manages with a lower switching capacity or the one that is difficult to meet There is no requirement for high switching capacity with very low response capacity. Furthermore, a switching additive is already known from DE-OS 32 27 866, which does not require any mechanical contact in the cross branch. The branch is with The help of thyristors, d. H. realized with semiconductors. In such circuit arrangements, when switching on the Cross-branch connected to each other via a cross-resistance point of the remote feed line, which carry voltages in the order of magnitude of up to 103V against each other in normal operation can. This causes a discharge current of the cable capacitance, which z. B. to rise above 10 A and can be pending for a few 100 usecs.