DE3211498C2 - Circuit arrangement for automatically closing an interrupted remote feed loop of a remote feed device - Google Patents

Abstract

The invention relates to a circuit arrangement for automatically closing an interrupted remote feed loop upstream of the interruption point, a bias winding being provided in a shunt arm. In such a circuit arrangement, the greatest possible and constant premagnetization should be achieved. For this purpose, the invention provides a constant current source in series with the bias winding. A preferred use of the circuit arrangement relates to communication links with remotely fed repeaters or regenerators.

Description

The invention relates to a circuit arrangement for the automatic closing of an interrupted Remote feed loop in front of the point of interruption in the operationally provided remote feed loop of a Remote feed device that feeds electrical consumers by means of direct current series feed, with a relay and a break contact of the relay are arranged together with a resistor in a shunt arm, wherein in addition to a winding of the Uelais located in the operationally provided remote feed loop a bias winding arranged in the shunt arm is provided

Such a circuit arrangement is already known from DE-OS 30 03 515

If the normally closed contact in the cross-section branch is closed in such a circuit arrangement, then constant remote feed current flows through the bias winding, so that the relay biases will. The relay therefore already responds with low ampere turns in the measuring winding, which the Measures current in the further part of the remote feed loop. There is then a special for the holding excitation large changing room available. This results in an advantageous compared to others known Arrangements of the type under consideration significantly reduced voltage drop across the circuit arrangement, so that the range of the remote feed is increased Remote supply instead of a sensitive polarized relay, a non-polarized relay can be used.

If the relay drops out, so that the normally closed contact in the cross arm closes, the cable capacitance is discharged over the cross branch. If the relay is not to respond in this case, the one connected to the discharge current must Pre-magnetization of the relay remains below the response value. This can lead to the case that the bias would have to be designed to be smaller than is desirable per se. Furthermore it can prove to be disadvantageous that the premagnetization with increasing current in the operationally intended Remote feed loop decreases

The invention is based on the object of providing a circuit arrangement of the type mentioned at the beginning to train that regardless of the capacities effective in the remote feed circuit, in particular cable capacities, the largest possible premagnetization can be provided and that this premagnetization when the shunt arm is closed, it is as independent as possible of that caused by the winding in the longitudinal arm or measuring winding is flowing current.

According to the invention, the circuit arrangement is designed such that the bias winding is supplemented in the shunt branch to a constant current circuit and that parallel to the constant current circuit a circuit for voltage limiting is arranged.

The measures according to the invention have the advantage that if the remote feed loop is interrupted a particularly large pre-excitation that is constant when the shunt branch is closed is used can, so that the relay can respond to particularly small series currents.

A constant current diode or the like can serve as the constant current circuit. In a further development of the invention the constant current circuit contains a transistor with its emitter-collector path in Series to the bias winding is such that the emitter of the transistor is connected to the winding and that the base of the transistor is connected to the collector via a resistor and via a Zener diode

the terminal of the bias winding facing away from the emitter-collector path is guided.

Is parallel in a further embodiment of the invention a capacitor is arranged to the Zener diode, so is advantageously both when tightening and when the relay drops out, scraping is reliably prevented even under particularly unfavorable conditions

In a further development of the invention, the circuit contains a diode arrangement with two antiparallel branches to limit the voltage. As diodes can be used Zener diodes are used. Is the circuit arrangement formed for a certain current direction in the shunt arm, there is, based on the direction of the remote feed current in the forward direction polarized branch of the diode arrangement expediently a series circuit i <· j several diode lines or a Zener diode and the other branch from a single diode line. Is the circuit arrangement for both If the current directions are formed in the shunt arm, then the two arms of the diode arrangement expediently exist from a series connection of several dioden lines or Zener diodes. The constant current circuit can be connected via a diode-rectifier bridge be connected to the branch and the diode arrangement at the input of the diode rectifier bridge lie.

The invention is explained in more detail with reference to the exemplary embodiments shown in the figures

F i g. 1 a switching add-on for remote feed circuits fed on one side, with a constant current circuit in the shunt branch lies and

Fig. 2 a switching add-on with a constant current circuit in a shunt arm designed for both current directions.

In the case of the FIG. 1, intermediate amplifier points are remotely fed via a remote feed loop with constant direct current If fed on one side by means of the current source 1. Only one of the intermediate amplifiers is shown in the figure Wire and the other wire with its feed input is looped into the other wire of the remote feed line. B. ate inner conductor of coaxial cables of a four-wire communication device.

The amplifier station 2 is provided with a switching attachment 3, which is arranged in the course of the remote feed line on the side of the amplifiers 21 and 22 facing away from the power source 1. The switching attachment 3 forms a quadrupole in the form of a half member. The shunt arm of the semifinished element is a series circuit consisting of the break contact 83 of the relay, the resistor 91, the choke 92 and a parallel circuit of the constant current circuit 6 and the anti-parallel connected diode branches 5V and 52 '.

The constant current circuit 6 is a two-pole, in which in series with the bias winding 81 of the Relay, the emitter-collector path of the transistor 61 is connected. The transistor 61 is connected to the emitter side Bias winding 81 is connected and its base is connected to both the Zener diode 64 and the transistor 61 facing away from the connection of the bias winding 81 'ind on the other hand via the resistor 63 led to the collector of transistor 61. The capacitor 62 is parallel to the Zener diode 6 * Z-diode 64 is polarized in the reverse direction for the remote feed current

The winding current can then not be higher than the Zener diode voltage of the Zener diode 64 and the Specify coil resistance. Any increase in voltage on the overall structure or on the constant current circuit 6 is intercepted by increasing the voltage of the collector-emitter path of the transistor 61. In particular the capacitor 62 maintains the potential at the base of the transistor 61 during dynamic processes constant

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 Series connected diode lines is chosen so that the voltage drop across transistor 61 and on the Bias winding 81 at the nominal value of the remote feed current of the sum of the threshold voltage The diode series connection can also be replaced by a corresponding Zener diode. The individual diode 51 lies antiparallel to the diode circuit Kf.

The series branch of the auxiliary switch consists of the measuring winding 82 of the relay and the connected in parallel individual diodes 51 and 52 antiparallel to one another

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 arm and the 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 bias winding 81 flowing current causes a premagnetization of the relay 8. The through the measuring winding 82 flowing current creates an additional flow through the relay when the remote feed loop is intact The normally closed contact 83 c'-fnet, see above that the shunt branch is de-energized and the entire remote feed current via the series branch with the Wick-Iu.jg 82 flows.

With the aid of the diode branches 51 and 52, an active one becomes effective Protection of the measuring winding against interference, in particular against overcurrents caused by lightning strikes, High current influence or by switching the relays are achieved

The diodes 51, 52 can increase their voltage drop up to about five times if they are affected by high flash currents are flowed through. So that this voltage drop does not generate an overcurrent in the measuring winding, which in certain applications, in particular with sensitive positive reed relays, the magnet system could change the relay, you can - what in the figure is not shown - expediently a constant current circuit in series with the measuring winding insert.

A major advantage of the bias winding located in the shunt branch is that a maximum of only a Diouenschwelle is required as a voltage drop in the longitudinal direction of the remote feed current When the relay contact closes, the cable capacitance is discharged through the transverse resistor 91. This could Without special precautions there is a risk that the pre-excitation will be so high despite the protective diodes 51, 52 ' is that the relay responds or begins to purr. This snarling, for personal protection reasons is to be avoided, is in an advantageous manner even in unfavorable conditions by the in series to

Pre-excitation winding lying constant current circuit safely prevented.

A further advantage of the circuit arrangement according to FIG. 1 is that a predetermined relay at smaller current values are made to respond, since the pre-excitation is in the bias winding 81 is not reduced in size when the longitudinal current in the measuring winding 82 increases.

With the help of the capacitor 62 it is ensured that the pre-excitation when the relay contact opens only disappears after a delay time. This enables the relay to be picked up "without rattling". as well it is ensured that when the longitudinal current in the measuring winding 82 is reduced, the relay operates without buzzing drops, since the pre-excitation builds up after a delay time after the relay has dropped out. Even this delay time is made possible by the capacitor 62. The conduction condenser S2 can open Due to the transistor gain turn out to be correspondingly small.

The diodes 5Γ, 52 'may be smaller than the diodes 51.52 because the lightning currents flowing through them are reduced by the resistor 91 and the choke coil 92.

The in F i g. The switching add-on shown in FIG. 2 is suitable for remote feed circuits that use two constant current sources 1 and 4 are fed on both sides. It also enables the amplifiers or regenerators to be fed Alternating from intermediate point to intermediate point to switch to 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.

The additional switch 3 'is switched on on one side with the connections A and C. on the other side with the connections B and D in the remote feed 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 measuring winding 82 of the relay and the series connection of the diodes 73 and 74 Choke 92, the normally closed contact 83 and the input of the rectifier bridge 75 ... 78.

The constant current circuit is located at the output of the rectifier bridge 3, which are like those according to FIG. 1 and includes the bias winding 81. The anti-parallel diode branches 53,54, which are used to protect the constant current circuit against overcurrents, are connected to the input of the diode bridge circuit 75 ... 78.

With regard to the alternating polarity of the current in the shunt arm, the number of diode paths in the antiparallel diode branches 53,54 are the same size in both directions. The diode branches 53,54 can also be replaced by appropriate Zener diodes. eo

If the line interruption occurs in the direction of the connections B, D , the amplifier T 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 73 to the relay contact 83, which is closed on its quiescent side, and from there back again via diode 73 and terminal C. The relay monitors the incorrect direction of 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 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 A and C.

Furthermore, it can be expedient, instead of the measuring winding 82, in parallel to the series connection of the diodes 73 and 74 to connect a constant current circuit to the relay winding 82 in series.

The circuit arrangement can advantageously also be used in feed points in order to prevent an interruption In the outgoing remote feed current paths, the Aiisgsr.g33par.nung to a harmless value to belittle.

1 sheet of drawings

Claims (7)

Patent claims: 1.Circuit arrangement for automatically closing an interrupted remote feed loop in front of the interruption point in the operationally provided remote feed loop of a remote feed device that feeds electrical loads by means of direct current series feed, a relay and a break contact (83) of the relay together with a resistor (91 ) are arranged in a shunt arm, in addition to a winding (82) of the relay located in the operationally provided remote feed loop, a bias winding (81) arranged in the shunt arm is provided, characterized in that the bias winding (81) in the shunt arm to a Constant current circuit (6) is added and that parallel to the constant current circuit (6) a Q / * haltiin € T 7iir. ^ Ηαηηΐιηα «Κ ** ση» η7ΐιησ (^ i '. 52';S'i. Τη """•• —- • - "Ο ——- - χ" ~ ------- ^ -— - ο- - σ \ - »* * ~ - 54) is arranged 2. Circuit arrangement according to claim 1, characterized in that the constant current circuit contains a transistor (61) which has its emitter-collector path in series with the bias winding (81) is such that the emitter of transistor (61) with the bias winding (81) is connected, and that the base of the transistor (61) via · a resistor (63) to the Collector and via a Zener diode (64) to the connection facing away from the emitter-collector path the bias winding (81) is performed. 3. Circuit arrangement according to claim 1 or 2, characterized in that pai.ilel to the Zener diode (64) a capacitor (62) is arranged 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the circuit a diode arrangement with two antiparallel branches (51 ', 52' ,; 53, 54) contains 5. Circuit arrangement according to claim 4, characterized in that the circuit arrangement is designed for a certain current direction in the shunt arm and that the, based on the Direction of the remote feed current in the forward direction polarized branch (52 ') of the diode arrangement a series connection of several diode lines or a Zener diode and the other branch (51 ') consists of a single diode line (FIG. 1). 6. Circuit arrangement according to claim 4, characterized in that the circuit arrangement is formed for both directions of flow in the shunt arm and that both branches (53, 54) of the Diode arrangement each consist of a series connection of several diode sections or Zener diodes (Fig. 2). 7. Circuit arrangement according to claim 6, characterized in that the constant current circuit (6) is connected to the shunt arm via a diode rectifier bridge (75 ... 78) and that the diode arrangement (53,54) at the input of the diode-rectifier bridge lies.