DE604821C - Distance relay - Google Patents

Description

Distance relay

Distance relay, d. H. Relays whose tripping time increases with the distance from the fault location, can work according to the principle that the short-circuit resistance (impedance or reactance) is measured at the first moment the relay is running and on the relay for the entire duration of the relay measured value is recorded. The measured resistance is therefore for the tripping time authoritative. The work of the relay is thus independent of subsequent changes in the state in the network, such as the arc spreading to healthy phases, machine oscillations, etc., which change the resistance measured by the relay and thus the selectivity of the Question protection.

However, these relays have the following fundamental disadvantage, as follows ao hand of FIGS. 1 and 2 of the drawing is explained in more detail.

If, according to FIG. 1, the short circuit takes place at A at the end of a double line in the network, the relay 4 measures a resistance at the beginning of the short circuit which is equal to that of the line DC plus half the resistance of the line CB. This resistance is decisive for the tripping time of relay 4. The relay 2 of the diseased section measures the resistance of the entire section) CA = CB and triggers according to this resistance. The difference between the gemessenien from the ¹ two relays resistors thus does not correspond to a leg, Segregate only half a leg, thereby reducing the 'staggering endangered.

In the case of a short circuit according to FIG. 2, this disadvantage is even more pronounced. In the event of a short circuit at A in the vicinity of C, the relay 4 measures the resistance DA = DC, ie that of a section, at the beginning of the short circuit. The relay 1 measures the resistance BC, also that of a section. Both relays will thus trigger at the same time, ie relay 4 will trigger unnecessarily.

In the distance relay according to the invention, this disadvantage is avoided in that the relay only records the resistance value occurring at the beginning of the fault, if this remains the same during the fault period or decreases even further while it is set to a higher value as the resistance increases during the fault time.

In the exemplary embodiment according to FIG. 1, the relay 4 now measures after switching off, the closest relay 1 a greater resistance than at the beginning of the short circuit, namely the resistance corresponding to two whole sections DC and CB. The graduation with respect to relay 2 is therefore guaranteed. "

In the embodiment according to FIG. 2, after the relay 2 has been switched off, the relay 4 measures a resistance corresponding to the three sections DC -f- CB -j- BC via the healthy strand of the double line, so that here, too, the graduation with respect to the relay ι is guaranteed is.

The decrease in resistance that occurs with oscillations, changes in the type of disturbance, etc. is not disturbing, as the relays do not respond to it. Similarly, the apparent resistance reductions are not disruptive, in accordance with FIG. 3 at leinem short circuit in a branch A to the protected Leist end following the closure of the relay 1 occur for the relays 2 and 4. .

This principle can be used for relays with a steady as well as a step-like increase Characteristic.

Claims (1)

Claim: Distance relay that measures the resistance at the start of a fault and during the subsequent disturbance time the same holds the initial value, characterized in that the relay at the beginning The resistance value occurring during the fault only records if it remains the same during the fault time or decreases as it adjusts to a higher value when the resistance increases during the time of failure.