DE3211518C2 - Circuit arrangement with a relay for the automatic connection of the two remote feed current paths of an interrupted remote feed loop - Google Patents

Abstract

The invention relates to a circuit arrangement for automatically closing an interrupted remote feed loop in front of the interruption point with the aid of a relay. In such circuit arrangements, overcurrents in the remote feed circuit should not have a disadvantageous effect on the relays used and on the function of the circuit arrangement. For this purpose, the invention provides that at least one winding of the relay is supplemented to form a two-pole constant current circuit. The invention can advantageously be used in remote-fed repeaters or regenerators.

Description

The invention relates to a circuit arrangement as specified in the preamble of claim 1 with a relay for the automatic connection of the two remote feed current paths of an interrupted one Remote feed loop.

Such a circuit arrangement is already from Siemens-Zeitschrift 45 (1971), supplement »News-

Transmission technology «, page 102 known The relay windings contained in the known switch attachment are traversed by the remote supply current and are therefore against overcurrents caused by lightning strikes and the influence of heavy currents or by switching the relays. Ais such Schulz are Diodes connected in parallel to the relay windings

Such diodes can increase their voltage drop by up to five times under extreme conditions, when high lightning currents flow through them. This voltage drop can then occur in the relay coil possibly generate an overcurrent, which in certain applications, especially in sensitive polarized reed relay that can change the magnet system of the relay.

The object of the invention is to design a circuit arrangement of the type mentioned at the outset in such a way that that overflows in the remote feed circuit are not disadvantageous can affect the relays used. In addition, the overcurrents should be as low as possible Have an influence on the function and design of the circuit arrangement.

According to the invention, the circuit arrangement for solving the object is in the characterizing Part of claim 1 specified manner formed. As a constant current circuit, a Constant current diode or the like. Serve. In a further development of the invention, the circuit arrangement is as follows designed that the constant current circuit contains a transistor, the emitter of which is connected to the winding

IM) is connected, and its base is connected via a resistor the collector and, via a Zener diode, to the connection of the winding facing away from the emitter-collector path is led.

The result is that the winding current cannot be higher than the Zener diode voltage and the Specify coil resistance. Any increase in voltage on the overall structure or on the constant current circuit is increased by increasing the voltage of the collector

; Intercepted emitter path.

If a capacitor is arranged parallel to the Zener diode, there is the further advantage that this capacitor This capacitor keeps the potential at the base constant during the aforementioned dynamic processes can be made particularly small thanks to the amplifying effect of the transistor.

Further advantageous refinements of the invention emerge from patent claims 4 to 9.

The invention is explained in more detail using the exemplary embodiments shown in the figures

Show it

F i g. 1 a switching add-on in which a relay becomes a Constant current circuit is added

F i g. 2 a switching add-on in which there are two windings of a relay which is in a series branch is supplemented to a constant current circuit,

F i g. 3 a switching add-on with two windings each supplemented to form a constant current circuit Relay,

: 4 shows a circuit addition for both sides powered remote power supply circuits or an optionally arrangement ', the relay branch in one or other remote supply branch, with addition of the relay to a constant current circuit,

Fig. 5 a switching add-on for both sides fed Remote feed circuits or for the optional arrangement of a relay winding arranged in a series branch optionally in one or the other branch of the remote feed circuit, with one added to a constant current circuit Winding in a longitudinal branch and another winding in the transverse branch and

Fig. 6 a switching add-on for remote feed circuits fed on both sides or an optional arrangement of the im In the series branch winding in one or the other remote feed branch, with the addition of the winding in the series branch and a winding arranged in the shunt arm, each to a constant current circuit.

In the circuit arrangement shown in FIG. 1, intermediate amplifier points are remotely fed with constant direct current If via a remote feed loop fed on one side by means of the current source 1. Only one of the intermediate amplifier points is shown in the figure. This intermediate amplifier / slle 2 contains two amplifiers 21 and 22, of which one is looped with its feed input into one wire and the other with its feed input into the other wire of the remote feed line. B. the inner conductors of coaxial cables of a four-wire communication facility.

The amplifier station 2 is provided with a switch accessory 3, which in the course of the remote feed line on the Power source 1 facing away from the amplifier 21 and 22 is arranged. The additional switch 3 forms a four ; pole in the form of a half-link. The branch of the: half link is a series circuit, consisting of the 'Normally closed contact 83 of relay 8, resistor 91 and throttle 92. The series branch is connected by a parallel · . circuit, consisting of constant current circuit 6 and eo the anti-parallel connected diode branches 51 and 52. The branch 51 can also consist of a Zener diode.

The constant current circuit 6 is a two-pole, at which is in series with the relay 8, the emitter-collector path of the transistor 61. The transistor 61 is on the emitter side connected to the relay 8 and with its base both via the Z-Diod '· 64 to the transistor 61 facing away from the connection of the relay 8 and on the other hand via the resistor 63 to the collector of the transistor 61 routed parallel to the Zener diode 64 is the capacitor 62. The Zener diode 64 is for the remote supply current polarized in reverse direction.

The diode series circuit is parallel to the constant current circuit 6 52, the diodes of which are polarized in the forward direction for the remote feed current. The number of in Diode lines connected in series is selected in such a way that that the voltage drop across transistor 61 and relay 8 at the nominal value of the remote feed current of the The sum of the threshold voltages of the diodes corresponds to antiparallel to the diode series circuit 52 the single diode 51.

The terminal of the relay 8 facing away from the shunt branch is connected to a normally open contact via the resistor 65 of the relay 8 out This normally open contact forms together with the normally closed contact located in the shunt branch a toggle switch that sets the resistance when ReIr> 8 is excited 65 parallel to the constant current source and at When the relay 8 is not energized, the shunt arm 91, 92 of the auxiliary switch 3 closes

If the remote feed device is put into operation, the remote feed loop is initially via the Cross branch of the auxiliary switch 3 closed. If the remote feed loop is intact, the remote feed current is divided corresponding to the resistance of the cross arm and the loop resistance of the subsequent part of the Remote feed loop on the shunt branch and the longitudinal branch of the switch accessory 3. The one through the branch and thus current flowing through the relay 8 generates a flow which the relay 8 when intact The remote feed loop responds. The normally closed contact 83 opens, so that the shunt arm is de-energized and the entire remote feed current via the series branch flows. Since the normally open contact is in this operating state 84 is closed, the constant current circuit 6 is now bridged by the resistor 65. The resistance 65 is dimensioned so that the part of the remote feed current flowing through the relay when the normally open contact 84 is closed is certainly above the current value at which the relay drops out.

The diode branch 51 consists of a diode. This diode is polarized in reverse direction for the remote feed current. The diode branch 52 connected in anti-parallel for this purpose, however, is made up of so many in series Diodes formed so that the sum of the threshold voltages is greater than the voltage when energized Relay on whose winding 8 drops out. In this way an effective protection of the relay winding against Influence, in particular against overcurrents caused by BliUscSiläge, high-voltage current or by Switching the relays arise, achieved

These diodes can increase their voltage drop up to about five times when they are exposed to high lightning currents are flowed through. So that this voltage drop does not create an overcurrent in the relay coil, softer the magnet system for certain applications, especially for sensitive polarized reed relays the relay could change, a constant current circuit is inserted in series with the relay winding. Of the Winding current cannot be higher than the Zener diode voltage of the Zener diode 64 and the coil resistance pretend. Any increase in voltage on the overall structure or on the constant current circuit 6 is intercepted by a voltage increase in the collector-emitter path of the transistor 61. In particular the capacitor 62 maintains the potential at the base of the

Transistor 61 is constant in the aforementioned dynamic processes.

In a modification of the in FIG. 1, the resistor 65 can be omitted if the voltage drop, which the remote feed current causes on the winding 8 of the relay or on the constant current circuit 6, can be accepted in the remote feed device.

An embodiment in which there is a particularly low voltage drop across the constant current circuit 6 results and in which therefore no resistor bridging the constant current circuit is provided is shown in FIG. The one shown in FIG Circuit arrangement differs from the embodiment shown in Fig. 1 in that in the shunt arm of the switching add-on in series with the series circuit of break contact 83, resistor 91 and Choke 92 a bias winding 81 of the relay is inserted such that the closed Switch 83 in the shunt arm current flowing causes a premagnetization of the relay. The branch of the Half-link is a series circuit consisting of the bias winding 81 and the normally closed contact 83 of relay 8 and resistor 91 and choke 92.

If the remote feed device is put into operation, the remote feed loop is initially via the Transverse branch of the auxiliary switch closed. If the remote feed loop is intact, the remote feed current is divided accordingly the resistance of the shunt branch and the loop resistance of the subsequent part of the remote feed loop onto the transverse branch with winding 81 and the longitudinal branch with winding 82. The one through the winding 81 flowing current causes a premagnetization of the relay 8. The current flowing through the winding 82 Electricity creates an additional flow that the Relay 8 responds if the remote feed loop is intact. The normally closed contact 83 opens, so that the Shunt branch becomes currentless and the entire remote feed current flows through the series branch with the winding 82.

The bias winding 81 is connected by the diode series circuit 54 and that connected in antiparallel to it Single diode 53 bridged. The diode series circuit can also consist of a Zener diode. the for a remote feed current flowing in the shunt branch in the forward direction polarized diode series circuit 54 contains so many diodes that the sum of the threshold voltages is greater than the voltage due to of the remote feed current drops only at the bias winding 81.

The additional switch shown in Fig. 3 differs differs from that according to FIG. 2 in that in the shunt branch instead of the winding 81 of the relay, a constant current circuit is provided which contains a winding 81 of the relay.

According to FIG. 4, the intermediate points of a nighttime transmission device are fed with a constant direct current If by means of series feeding. In each intermediate point, which can be a regenerator or amplifier point, a consumer is provided, the input of which is traversed by the remote feed direct current h. The consumer is in each case a line amplifier 2 ', which contains an individual amplifier for each transmission direction of the communication link. The two individual amplifiers are what is not shown in the figure. fed directly or in parallel via a direct current converter, so that there is a parallel series feed for the circuit arrangement for remote feeding.

The consumers are connected in series in the remote feed circuit operated. The inputs of the consumers can alternate from intermediate point to intermediate point be switched into one and the other remote feed current path in order to ensure an even load distribution to achieve or to compensate for the influence of induced alternating currents on the route to reach. However, if necessary, you can also use one and the same remote feed wire or one and the same Remote feed current path must be inserted.

The remote feed wire pair is connected to a remote feed device 1 or 4 at both ends. As soon as there is a connection between the feed wires, the remote feed device 1 feeds up to this point. The remote power supply 4 also feeds up to the connection point, so that the entire route continues to be supplied remain.

An uninterrupted operation of the interim parties even in the event of an interruption at any point in the remote feed wire pair is achieved that In each intermediate point a switch 3 'or 3 "is provided, which in the event of an interruption of one or both feed wires closes the remote feed circuit before this interruption point so that the intermediate points continue to be supplied.

After the interruption has been eliminated, the wire connection on the switching add-on is automatically restored canceled.

The switching additive is switched on on one side with connections A "and C" and on the other side with connections B " and D" in the I-ern supply circuit.

The connections A ″ and B ″, to which the amplifier 2 ′ is connected, are connected via a series circuit made up of the diodes 71 and 72. Between the connections C " and D" there is a parallel connection of the winding 8 of the relay 8 and the series connection of the diodes 73 and 74. The series connection of the resistor 91 is located between the connection points of the two diodes 71, 72 or the diodes 73 and 74 and the choke 92 with the rest side of the double changeover contact 83 'of the relay 8. With reference to the remote supply current If flowing in the remote supply loop, the diodes 71 and 72 are polarized in the reverse direction and the diodes 73 and 74 in the forward direction.

If the line interruption occurs in the direction of the connections B ", D" , the amplifier 2 'continues to be operated from the direction of the connections A " to C" . The supply current then flows from terminal A " via the input of amplifier 2 '(diode 71 blocks). Diode 72 and resistor 91 to relay contact 83', which is closed on its quiescent side, and from there back again via diode 73 and terminal C". The relay 8 monitors the incorrect direction of the connections B " and D".

If the line interruption occurs in the direction of the connections A "and C" , the amplifiers 2 'continue to be operated from the direction of the connections B " and D". The current flow then runs from the connection D " via the diode 74, the contact 83 ', the choke 92, the resistor 91, the diode 71, the amplifier 2 to the connection B". The relay 8 now monitors the incorrect direction of the connections Λ "and C".

If the current source 4 is replaced by a short circuit, the line is fed alone by the power source 1.

Parallel to the series connection of diodes 73 and 74 is the constant current circuit 6 with the relay winding

treatment 8. When the normally closed contact 83 'is open, the double normally open contact 84' is closed, the resistor 65 being parallel to the constant current circuit 6. This bridging resistance is expediently dimensioned as in the exemplary embodiment according to FIG. 1 and can, for example, be omitted here if necessary.

The Shah addition according to Fig. 5 agrees with that according to FIG. 4 largely corresponds, but does not contain a bridging resistor 65, because the winding 82 of the relay because of the arranged in the shunt arm, for premagnetization serving winding 81 can correspond to low resistance. The one for premagnetization Serving winding 81 is via the bridge circuit consisting of diodes 75 to 78 in the shunt arm looped in. Lie parallel to the pair of connections of the diode bridge circuit in the shunt branch the two anti-parallel connected diode series circuits 53 and 54, which are also Zener diodes could be.

The switch addition according to FIG. 6 differs from that according to FIG. 5 in that the premagnetization Serving winding 81 is added to a constant current circuit.

The circuit arrangement can advantageously also be used in feed points in order to prevent an interruption in the outgoing remote supply current paths, the output voltage to a harmless value to belittle.

In addition 5 sheets of drawings

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40

45

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55 I.

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65

Claims (9)

Patent claims: 1. Circuit arrangement (additional switch 3) with a relay to automatically connect the two Remote feed current paths of an interrupted remote feed loop in front of the interruption point, for Remote feed devices in which electrical consumers are connected in series in a remote feed loop (Amplifier 21, 22) are fed from at least one constant current source (1, 4), the Circuit arrangement both at least one arrangement lying in one of the remote feed current paths with a winding of the relay (8) and with a circuit (51,52) to limit the amount of time on the winding occurring voltage as well as a series circuit arranged between the two remote feed current paths from a normally closed contact (83) of the relay (8) and a resistor (91) contains thereby characterized in that in the arrangement or in at least one of the arrangements the winding of the relay (8) to one designed as a two-pole and arranged in the relevant remote feed current path Constant current circuit (6) and the circuit (51, 52) to limit the on the winding lying voltage is arranged parallel to the constant current circuit (6) 2. Circuit arrangement according to claim 1, characterized in that the constant current circuit contains a transistor whose emitter is connected to the winding, and whose base is connected via a Resistance to the collector and via a Zener diode to the emitter-collector; corner facing away Connection of the winding is performed. 3. Circuit arrangement according to claim 2, characterized in that parallel to the Zener diode (64) a capacitor is arranged. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the Emitter-collector path facing away from the connection of the winding via a resistor (65) via a at open normally closed contact closed normally open contact of the relay with the collector of the transistor (61) is connected (Fig. 1). 5. Circuit arrangement according to one of claims 1 to 4, characterized in that in the shunt branch a further winding (81) of the relay is inserted in such a way that a premagnetization results. 6. Circuit arrangement according to claim 5, characterized in that the further winding (81) of the relay is supplemented to form a constant current circuit which is arranged in the shunt arm. 7. Circuit arrangement according to claim 4, characterized in that in each of the intermediate amplifier points the series connection of relay coil and emitter-collector section on the one hand and the Feed input on the other hand are looped into different remote feed current paths and the shunt branch in particular via a switch circuit, consisting of one each of the feed input and the Relay coil parallel series connection of at least two diodes is performed and that the Collector of the transistor via a contact that is closed when the normally closed contact is open and its resistance with the terminal of the winding which is remote from the emitter-collector path of the transistor (61) connected is. 8. Circuit arrangement according to claim 4, characterized in that in each of the intermediate amplifier points the series connection of relay coil and emitter-collector section on the one hand and the Feed input on the other hand are looped into different remote feed current paths and the shunt branch in particular via a switch circuit, consisting of one each of the feed input and the Relay coil parallel series connection of at least two diodes is performed and that in a diode rectifier circuit, which is terminated with the further winding, is inserted into the shunt arm is 9. Circuit arrangement according to claim 8, characterized in that the further winding (81) supplemented to a constant current circuit which is connected to the diode rectifier circuit is