DE1801936C3 - Switching arrangement - Google Patents

Description

The invention relates to a circuit arrangement for uninterrupted switching of a feed line from a constant direct current supply source to an immediate reserve for remote-fed communication systems, especially for remote-fed repeater stations for carrier frequency technology.

Switching from a working to a reserve voltage source is relatively easy to carry out with remote supply with constant DC voltage, because the reserve voltage source of the work queue is switched on in parallel and then switched off can be. During the switchover time, the supply current is supplied from both sources.

The situation is different with remote supply with constant direct current. There is no such simple way of switching here must be used, as it must be ensured that during the time of the parallel connection of both

ίο Neither constant direct current sources nor the current in the Feed line nor the voltage on it exceed the prescribed values inadmissibly and at the same time the parallel switching time is also limited to the shortest possible time.

The invention now sets itself the task of a circuit arrangement for uninterrupted switchover a feed line from a constant direct current feed source to an immediate reserve for remote feed Communication systems, in particular for remote-fed repeater stations from Carrier frequency technology specify a solution as simple as possible and solves the problem in that Both constant DC power supply sources each via a controllable silicon diode with remote-fed, power supply Consumers lying in series are connected, of which a silicon diode is conductive switched and the other is blocking that the outputs of the constant direct current supply sources through each one capacitor and one zener diode each are bridged, the zener diodes when the silicon diodes are blocked take up the constant direct current and thereby the voltage on the capacitor to a value above the working voltage value limit lying value that also to switch to the other constant DC power supply source the previously blocked silicon diode by a control pulse applied to its control electrode is switched on, whereby by the discharge of the energy stored in the capacitor the voltage at the consumer increases briefly and the silicon diode, which was previously conductive, through this subsequent biasing is switched blocking in the blocking direction.

The invention will now be described in detail at Ha * d of the figures to be discribed. It shows

F i g. 1 the circuit arrangement according to the invention; F i g. 2 to 4 explain the switching process.
In Fig. 1, the device to be fed with constant direct current is indicated by its load resistance 1 effective for the supply source.

Each of these two supply sources is connected to the supply line via a controllable silicon diode (SCR = silicon controlled rectifier) 4, 5, which works as an electronic switch. Each of these diodes 4, 5 can be switched through when a pulse generator 6, 7 applies a pulse to its control electrode. A control circuit 8 initiates the switchover of the feed line from one feed source to the other, and this can be done manually or automatically. A Zener diode 9 or 10 and a capacitor U or 12 are connected across the output terminals of each supply source 2 or 3.
The mode of operation of this switching device will now be explained using a numerical example. It is assumed for this purpose that the constant supply direct current is / = 50 mA and, under normal conditions, this results in a working voltage Vl of

18 Ol

570 volts are present at the feed points. The Zcners voltage V or over the output terminals of the constant current supply sources 2 and .i arranged Zener diodes 9 and 10 is, somewhat above the working supply voltage Vz., Enva to 600 V selected. B, triggered by the switching contact 13, the constant current source 2 is switched off from the supply line, flows through the Zener diode 9 de- 50 niA constant direct current of the source 2, and the capacitor 11 is charged to 600V. If the constant current source 2 is to be switched to the feed line, a pulse is applied by the pulse generator 6 to the control electrode of the controllable silicon diode 4, which becomes conductive as a result. The constant supply current now flows via the supply line to the consumers, and a voltage of 570 V is established at the supply point. As a result, the Zener diode 9 blocks again. The switching of the feed line from the feed source 2 to the feed source 3 is initiated by actuating the switch 14. The capacitor 12 is charged to 600V. Since the controllable silicon diode is not yet conductive, it has a voltage of 600 - 570 = 30 V.

This state is shown in FIG. 2 shown. When the diode 5 is quickly controlled by a pulse from the pulse generator, the capacitor 12 begins to discharge via the diode 5 and the load resistor 1. The voltage across the load resistor will briefly rise to 599 V. As a result, a voltage of 599-571 = 28 V occurs at the controllable silicon diode 4, which makes it non-conductive. This state is shown in FIG. 3. When the capacitor 12 continues to discharge, the voltage across the load resistor 1 drops to 570 V, the Zener diode 10 of the supply source 3 being blocked. At the same time that the controlled silicon diode 4 is blocked, the capacitor 11 is charged to 600 V and the Zener diode 9 is then ignited. This state is shown in Fig. 4. From this description of the effect it can be seen that each constant direct current source 2 or 3 has to supply a current higher than the specified current for a certain short period of time. For this time, the previous reserve power source must, so to speak, have a constant voltage behavior. This is achieved in that each output has a capacitor 11 or 12 in parallel. The capacitance of this capacitor must be selected to be sufficiently large so that the blocking potential is maintained at the silicon diode to be opened for at least 20 \ is , since this time is required as a recovery time for such diodes.

As has already been mentioned, the pulse generators 6 and 7 are via the control circuit 8 of Hand or automatically stimulated. In the latter case, the control circuit 8 is in the supply current sources 2 and 3 included monitoring devices. If the one from the one Speisesiromquelle If the current supplied deviates from the setpoint value beyond a permitted tolerance value, the switchover takes place to another supply current source.

1 sheet of drawings

Claims (4)

18 Ol 936 claims: 1. Circuit arrangement for uninterrupted switching of a feed line from a constant direct current feed source an immediate reserve for remote-fed communication systems, especially for remote-fed repeater stations the carrier frequency technology, characterized in that both Consiant direct current supply sources (2,3) each via a controllable silicon diode (4, 5) with the remotely fed, power supply Consumers (1) lying in series are connected, one of which is a silicon diode (4 or 5) is switched on and the other (5 or 4) is blocking, that the outputs of the constant direct current supply source (2, 3) each with a capacitor (11 or 12) and a Zener diode (9 or 10) are bridged, the Zener diodes (10 or 9) supplying the constant direct current when the silicon diodes (5 or 4) are blocked record and thereby limit the voltage on the capacitor (12 or 11) to a value above the working voltage value zen that also to switch to the other constant direct current supply source (3 or 2) previously Blocked silicon diode (5 or 4) by a control pulse applied to its control electrode is switched on, the discharge of the stored in the capacitor (12 or 11) Energy briefly increases the voltage at the consumer and the previously conductive silicon diode (4 resp. 5) is made blocking by the resulting pre-tensioning in the blocking direction. 2. Circuit arrangement according to claim 1, characterized in that the capacitance value of the Capacitors (H, 12) is chosen so that the time of their discharge when switched through the controllable silicon diodes (4 or 5) resulting in an increase in supply voltage at the consumer (1) and thus the application of a reverse voltage to the silicon diode (5 or 4) that has been switched through up to now is greater than the recovery time of the silicon diode to be blocked (5 or 4). 3. Circuit arrangement according to claim 1, characterized in that the control pulses for the control electrodes of the controllable silicon diodes (4, 5) are supplied by a pulse generator (6 or 7) will. 4. Circuit arrangement according to claim 3, characterized in that the pulse generators of Manually or depending on the monitoring devices in the constant DC power supply sources can be started in the event of failure or deviation of the feed current from a specified nominal range.