DE1102215B - Circuit arrangement and method for determining the fault location in electrical transmission paths - Google Patents

Description

Circuit arrangement and method for determining the location of the fault electrical transmission paths The invention relates to a circuit arrangement and a method for determining the location of the fault in electrical transmission paths with at least two parallel ones arranged one after the other in the direction of transmission Consumers, in particular for remote-fed amplifiers for electrical communications technology, wherein switching means are arranged in the remote feed circuit, which in the event of a fault Cause switching operations.

In such circuit arrangements are according to the invention in each case an on-delay relay at the consumer parallel to the incoming line and normally closed contacts of the same are provided in series with the outgoing line, so that if a short circuit occurs after the power supply is switched on again the time until the short-circuit disconnection again is a measure of the distance of the short-circuit location from the dining office. It can also be used in place of each same on-delayed relay relay with graduated response sensitivity be switched on and when a short circuit occurs when switching on again the supply voltage can be increased from 0 volts, so that the size of that voltage at which a new short circuit occurs, a measure of the distance from the short circuit location from the dining office. These measures have the advantage that you can find the location of a possibly occurring in the transmission path with little effort Determine short-circuit from the feeding office directly or as desired known fault location methods can be used again, which only then work if they are connected to the remote supply voltage.

In a further embodiment of the invention, the arrangement can also be so be taken that the response of the individual relays via one or more Auxiliary lines can be controlled from the manned office. In the event that there is a response time delay If a thermal contact is used, it is advisable to switch it on after the switch-on process has ended switch off again. To avoid excess voltage during the switch-on process with a constant supply voltage To avoid consumers, one can also provide replacement consumers who cut off when the next section is switched on.

The invention is illustrated schematically on the basis of FIG. 1 Remote feed line for AC remote feed and on the basis of the in Fig. 2 and 3 illustrated embodiments of the invention explained in more detail.

In modern long-haul systems, as can be seen from FIG. . . 6 remotely fed via the power supply switches 33 ... 56. In the case of alternating current supply, all amplifiers 7 ... 9 are used as consumers for the remote supply. practically parallel. If a short circuit occurs in the supply circuit (e.g. an interturn fault in the transformers 10 ... 12 or a connection between tube inner conductor 13... 24 and outer conductor 25... 32), a monitoring device in the feeding office switches off the remote supply voltage. As a result, all intermediate stations in the supply circuit with their monitoring devices are de-energized. Unambiguous fault location across multiple amplifiers is only possible with the usual monitoring equipment if the power supply does not fail. If a short circuit is detected within a remote feed line in the feeding office, the fault location can only be determined in the case of such remote feeding devices by successively connecting the outgoing lines to the intermediate offices, e.g. B. 14, 20 or 16, 22 or 18, 24, are separated. The fault location can then be deduced from the functionality of the individual sections. This measure described requires that a suitable person visits all intermediate offices one after the other and carries out the necessary work. Since up to now remote-fed intermediate offices are mostly built above ground, are easily accessible and can also be easily reached by traffic, this complex type of error localization is accepted. In simple systems with remote-fed intermediate amplifiers with transistors, however, the aim is to accommodate the intermediate offices underground, e.g. B. in a tightly screwed pipe. The amplifiers in these intermediate offices are therefore only accessible after a considerable amount of work.

In the exemplary embodiment according to the invention shown in FIG. 2, the load resistances R, 1 ... R "" are when the contacts a1 are closed . Is due to E. parallel to the current source in parallel with the Consumer resistors R '1... R ".", A relay depending Al.. An with response delay. When the relay Al ... An are de-energized, the contacts a1... When the voltage E is applied to the consumer resistor R "1 and the relay A1, current only flows in the first field. The relay A1 responds after a certain time and puts the second field parallel to E, etc. If a short-circuit disturbed field is coupled in the further course of the process, the monitoring at E switches off again. If the response delay of the individual relays is known, the error location can be deduced from the measured time difference between switching on and switching off. Instead of the response delay, the response sensitivity of the individual relays can also be graded.

In Figure 3, a remotely fed intermediate office is a further embodiment with circuit arrangement for temporary restarting in the event of a short circuit in a the following section. The names are partly from that Intermediate office 7 shown in Fig. 1 taken over. Parallel to the incoming remote supply voltage The inner conductor 13/19 is in series with the normally closed contact on 'of the relay A and the pre-resistor R2 the heating winding Th of the thermal contact th. Also in parallel for the remote supply voltage is in series with the series resistor R1, the rectifier Glrl and the thermal contact tla the winding of the relay A. The capacitor C in parallel for winding relay A is used to smooth the rectified alternating current. When the remote feed voltage is applied, the thermal contact brings th to the corresponding Delay the relay A, which maintains itself via its contact aIII and at the same time with contact aIv switches off the heating winding Th that is no longer required. The contacts aI and all separate the substitute consumer resistance when relay A responds R3. from the supply circuit and connect the next amplifier field to the remote supply voltage. The switched on substitute consumer resistance, which differs in the individual offices can be dimensioned, prevents an undesirable increase in the remote feed voltage during the switch-on process.

Claims (5)

PATENT CLAIMS: 1. Circuit arrangement and method for determination the location of the fault in electrical transmission paths with at least two in the direction of transmission parallel consumers arranged one after the other, especially for remote-fed consumers Amplifier of the electrical communication technology, whereby in the remote feed circuit Switching means are arranged, which cause switching operations in the event of a fault, thereby characterized that in each case at the consumer parallel to the incoming line On-delayed relay and normally closed contacts of the same in series with the outgoing one Line so that if a short circuit occurs after switching on again of the supply current source the time until the short-circuit switch-off again is a measure for the distance of the short circuit location from the feeding office. 2. Circuit arrangement and method according to claim 1, characterized in that instead of each same on-delayed relay relay with graduated response sensitivity are switched on and when a short circuit occurs when switching on again the supply voltage is increased from 0 volts, so that the size of that voltage at which a new short circuit occurs, a measure of the distance from the short circuit location from the dining office. 3. Circuit arrangement and method according to claim 1 or 2, characterized in that the response of the individual relays via a or several auxiliary lines can be controlled from the manned office. 4. Circuit arrangement and method according to one of claims 1 to 4, characterized in that a Thermal contact used for response time delay after the end of the switch-on process is switched off again. 5. Circuit arrangement and method according to one of the preceding Claims, characterized in that replacement consumers are provided when Switching on the next section must be disconnected.