DE1463137C - Distance relay - Google Patents

Description

45

The invention relates to a distance relay with signal generators, the simulations of the vectorial Sizes of currents and voltages to a comparison system, which at predetermined, by the conditions resulting from the comparison triggers a protective function. In a known selective protection system of this type, the instantaneous values of the Voltage drops on the line loop and on the simulation in the manner of the aforementioned signal generators fed to a comparison system, which is at a sufficient time interval from the poles From these instantaneous values, a distance and a directional criterion for the position of the fault forms and from these two criteria the decision about the triggering of the associated switch meets (German interpretative pamphlet t 087 249). -

The purpose of this known arrangement is already within the first half-wave of a short circuit initiate selective shutdown.

In contrast, the invention is based on the object of creating a distance protection that is connected to any power ratios can be adapted and has a time graduation in several trigger zones, see above that any relay characteristics are obtained in different distance zones.

According to the invention, this object is achieved in a distance relay of the type mentioned at the beginning solved that at least two pairs of signal generators are provided whose output voltage vectors according to the desired relay characteristics, in a manner known per se, for. B. through recruitment the transformation ratio of in the current or Voltage path converters, change the polarity or change in the impedance of the burden of a transducer, are adjustable and that the output voltage vectors each signal generator pair are each fed to a phase angle comparator whose Outputs are connected to a third phase angle comparator, the output of which is directly connected to is connected to the circuit breaker performing the protective function.

In that the length of the vectors supplied by the signal generators' by corresponding Circuitry measures within these η generators can be changed, a convenient Adaptation to a wide variety of operating conditions can be guaranteed. The (at least) two parallel-connected In conjunction with the phase angle comparator connected downstream of them, phase angle comparators permit versatile adaptation of the conditions determined by the position and size of the voltage vectors under which a selective immediate or delayed shutdown takes place.

An instantaneous selective shutdown of a fault in a near zone is immediate caused by the output signal of the downstream phase angle comparator, the setting the signal generators and the upstream phase angle comparators is made so that the downstream phase angle comparator, which has an AND gate, simultaneously from the two Phase angle comparators output signals are supplied.

A first time delay Rann according to an advantageous one Formation of the invention thereby effected 'that a second output of one of the Signal generator pairs fed phase angle comparators via a timer stage to another Input of a signal generator of the other signal generator pair is switched.

This first time delay stage accordingly acts on one of the signal generators of another Pair one that the phase angle comparator assigned to this pair receives a second output signal and thus causes the circuit breaker to shut down without delay.

According to a further embodiment, a further time delay for a zone that is even further away can be used of the invention can be obtained in that the further output of the phase angle comparator is connected to the trigger stage via a second timer stage, the second timer stage being a has a greater time delay than the first timer stage.

An exemplary embodiment of the invention is described below with reference to the drawing. In the Drawing shows

F i g. 1 is a block diagram of the distance relay according to the invention,

F i g. 2 the circuit of one of the signal generators of the distance relay according to FIG. 1,

F i g. 3 is an impedance diagram showing various shows typical operating characteristics of the relay.

According to FIG. 1 are a current transformer 11 and a to a line 10 of the network to be protected Voltage converter 12 switched on. The current converter 11 feeds an input circuit 13 and the voltage converter 12 an input circuit 14 for the signal generators 18, 19 arranged within the relay 15,

the output terminals 30, 31, the output line 32 is connected. If Fund / voltage and current are on line 10 and if Z is the impedance value of burden 29, then the signal traveling over line 32 will represent a voltage vector (AV-BIZ ₁ ) , where A and B are constants that make up each value except that A and B cannot be zero at the same time. The values of A and B can be adjusted by the number

20, 21. The output 16 carries the tripping signals of the io of the turns of the windings of the transformers 27 Distance relay to a circuit breaker 17, which is changed in the and 29, and that the polarity of their Ver line 10 is and causes the protective shutdown. binding with the input circles 13, 14 accordingly

Which is chosen by the current and voltage signals. The impedance value of the load 29 is fed to signal generators 18 to 21 supply output - also preselected so that the desired relay signals, which are obtained as input signals S ₁ to S ₄ phase angle 15 operating characteristics, e.g. W, X comparators 22 and 23 are fed, the one and Y according to FIG. 3. 'i

Carry out a phase comparison of the input signals. The in F i g. 3, the circle W represents the start-up

Phasenwinkelkomparator 22 generates an output ristik and an operating characteristic of a zone 3 signal for two clock stages whenever the relay. In like manner, the circuits Y phase angle set between its input signals is less ao and X is an operating characteristic of a Zone 1 or 90 °, i.e. for example whenever a zone is 2.

the phase angle comparator 22 supplied to The circle characteristic W (guide value) is there-.

output signals S ₁ and S _{2 have} the same sense of direction formed by the fact that the input signals S ₁ and S ₂ are compared during a time span within a period as mentioned above and that one which is greater than a quarter of this period, the output signal of the phase angle comparator 22 The other phase angle comparator 23, -der of the always. is generated when the phase angle signal generator 20 or 21 is fed by signals S ₃ or S ₄ between these "signals a 90 ° angle is only a coincidence detector, ie, steps. The characteristic represents a combined works like a AND gate. '· Represents the characteristic of which a part is replaced by the

The phase angle comparator 22 has one of the 3 ° guide value characteristic W is limited and a generation of an intermediate signal serving AND gate contains circular "characteristic, which is followed by a timer stage, the input signals S ₁ and the modified signal S ₁ The timer is and it is also delayed by sections AB and stages the intermediate signal limited by a pre-OC , the from the signals S ₃ , S ₄ (modified) period of time, so that it is together with 35 and S ₁ , S _3. This characteristic Y further AND gate is effective to the width of depends on the signals fed to the phase angle comparator 26, which generate an output whenever the phase angle between the intermediate signal and the output of the comparator 23 40 is greater than 90.degree .. Finally, the characteristic X is made up of another composite characteristic similar to de r characteristic Y is formed, but in this case the circle characteristics and the boundary sections DE, which are formed by S ₁ , S ₁ and

Transmitter 24 supplied signal influences the output of the 45 S ₃ , S _{4 are} derived, different sizes represent, signal generator 21. The second timer 25 generates since S _{4 is} now unmodified, and there is again a trigger signal for the circuit breaker 17 after
Expiration of a longer time delay T ₂ , namely
also in accordance with the output signal of the phase angle comparator 22. As mentioned, the 50 generated is greater than 90 °.

Phase angle comparator 22 is a phase angle comparator. The operation of the relay will now be described in detail.

Drawing of its input signals dependent intermediate signal, and this intermediate signal is together with the output of the phase angle comparator 23 a further phase angle comparator 26 is supplied. The phase angle comparator 26 is in the same way constructed like the phase angle comparator 22, and it generates a trip signal for the circuit breaker 17 whenever its input signals maintain the same sense of direction over a period of time that is greater than or equal to a quarter period. '

Fig. 2 shows the circuit of the signal generators in
individual. The primary windings of the transformers
27, 28 are connected to the circuits 13 and 14 supplying the current signals and voltage signals, respectively. The 65 used. Represented accordingly
The secondary winding of the transformer 27 is a 2 ~ 8o °

Load 29 connected in parallel. Connected in series for this purpose ''

is the secondary winding of the transformer 28. An impedance vector of size Z, with a dem

Check intermediate signal so that the through this stage introduced the time delay the actual phase angles determined by the phase angle comparator are determined, determined.

After a delay time T _{1 has} elapsed, the timer 24 generates a signal which is fed to the signal generator 21, namely according to an output signal of the phase angle comparator 22. This always occurs from the time input at the phase angle comparator 26 when the phase angle between the intermediate signal and the output of the Comparator

to be viewed as. The signal generators generate output signals, each as follows from the voltage vectors depend:

5 ₁ signal generator 18, V

5 ₂ signal generator 19, - V + IZ ₃ JQ ₁ - 4> _L

5 ₃ signal generator 20, IZ ₂ ^ - 4> _L

5 ₄ Signalgenerator21, —V [«^ + / Zi \ gi_zJtL

where α, = - 10 °, S ₁ = 10 °, «fc = 80 °, β, = 45 °, and 0 _L is the phase angle between voltage and current.

The voltage of the system is used as the reference vector

Reference vector phase angle leading by 80 °. In the same way poses

represents a voltage vector of magnitude - V and a phase angle lagging the reference vector by 10 °.

If these values are present, the modified signal generated by the signal generator 21 at Receipt of a signal generated by the timer 24 is dependent on

-KV I-10 + IZ ₁ 110-β ^

where K is a constant that affects the relationship between these two terms.

If the effective impedance of the line is within the characteristics of Zone 1, the ao Intermediate signal provided by phase angle comparator 22 and the output of the phase angle comparator 23 simultaneously the same sense of direction during a period of time such that the phase angle comparator 26 supplies a trip signal to the circuit breaker without delay. ■

Whenever an output signal from Phasenwinkelkomparator 22 generates and "timers is provided 24 and 25, then each is running, the timer, and its timer function starts. Thus, a time delay of T _1, a signal is supplied to the signal generator 3:21" to change its impedance vector Z ₁ into an impedance _{vector Z 2} , so that whenever the effective impedance lies within zone 2 but not in zone 1, a trigger signal is generated after a time delay which is essentially the same .. T ₁ Subsequently generated after a longer time delay T a trigger signal ₂ by the timer 25 and supplied to the power switch 17 so that a trigger signal is always generated when the effective impedance of the line lies within the zone 3 of the relay;

The phase angle comparators can be used as symmetrical or asymmetrical phase angle comparators, and the phase angle to which responding to these comparators can be set to give the relay the desired overall operating characteristics receives. Means for modifying the waveform can also be provided, ' to modify the intermediate signal of the comparator 22 and to influence the operating characteristics of zone 1 and zone 2, but with zone 3 remains unchanged.

It is also "possible that the phase angle comparators 22 and 23 receive more than two input signals, and in the general case, where η phase angle comparators are present, n-1 intermediate signals can be fed in one or all of the n-phase angle comparators generate further relay operating characteristics. "

The patent request is only directed to the entirety of the measures contained in claim 1, at which pairs of signal generators are provided.

1 sheet of drawings

Claims (3)

Patent claims: 1. Distance relays with signal generators that simulate the vector quantities of current and Apply voltages to a comparison system, which at predetermined, resulting from the comparison Conditions triggers a protective function, characterized in that at least two pairs of signal generators (18, 19 or 20, 21) are provided, their output voltage vectors according to the desired relay characteristics, in a manner known per se, by setting the transformation ratio in the current or voltage path (13 or 14) lying transducers (27, 28), change of polarity or change of impedance of the burden (29) a converter (27), and that the output voltage vectors of each signal generator pair (18, 19 or 20, 21) are each fed to a phase ao angle comparator (22 or 23), the outputs of which are connected to a third phase angle comparator (26), the output of which directly connected to the circuit breaker (17) performing the protective function is. · .. 2. Distance relay according to claim 1, characterized in that a second output is one of the Phase angle comparators fed by the signal generator pairs (22) via a timer stage (24) to a further input of a signal generator (21) of the other signal generator pair is switched. 3. Distance relay according to claims 1 and 2, characterized in that the further output of the phase angle comparator (22) via a second timer stage (25) to the tripping stage of the circuit breaker (17) is switched on, the second timer stage (25) having a greater time delay than has the first timer stage (24) ..