DE1148315B - Stimulator for protective relay arrangements, especially distance protection relays - Google Patents

Description

Suggested for protection relay arrangements, especially distance protection relays In the case of short circuits in three-phase networks, it is often difficult to find the faulty Correctly select phase or phases; especially in networks with low resistance Star point grounding occurs the unpleasant phenomenon that not even the fault affected phases lead to residual currents and through these residual currents, for example Distance relay may not be on the short-circuit loop itself, but on be switched to another circuit and thus measure incorrectly. This wrong measurement can very easily lead to incorrect staggering and consequent false triggering of the Protection, which in most cases is uncomfortable for network operation. It we are therefore looking for solutions that always have a result in perfect measurement. Such an error measurement can in particular also with Use of single-system distance protection occurs. This then has the consequence that with the usual excitations the relay is excited as with a three-pole short circuit will; this is the reason for possible incorrect measurements in the case of asymmetrical errors.

Another known arrangement is based on the fact that In the case of a single-phase earth fault, fault currents flow in the healthy phases, which have the same size and direction. By determining the healthy phases the sick phase is determined.

For this purpose, three overcurrent relays are activated by a summation current relay in the event of a fault brought to effect. These overcurrent relays are switched so that each the differential current of two phase conductors responds, so that, for. B. in the event of a ground fault in phase T only the relay does not respond, which is due to the current difference of the phase conductors R and S is affected.

In order to avoid faults other than single-pole earth faults with this one Establishment of a sufficiently reliable selection of the phase conductors concerned, are extensive circuit measures with additional interlocked Provide relay arrangements.

Use the known stimulus elements to select the sick phase usually overcurrent or underimpedance relays that only have the ratios of their own Monitor phase. It is known that as an additional selection criterion a so-called To use a current balance, the phase with the response of several excitation relays selects the largest stream. Such a power balance alone cannot act as a stimulus serve, but it can only be the right one after another suggestion Select phase if it is an asymmetrical short circuit. the Current balance alone is especially useful for excitation in the event of a three-pole short circuit unsuitable because in this case it cannot work because all three phases are the same carry great currents. But also for small ones that are below the nominal current The current balance cannot be used with fault currents because it takes into account the possible Load imbalance of normal operation their setting should not be very sensitive allowed.

To ensure that the relay protection arrangements are properly excited in all cases to achieve with simple means in a safe manner, are according to the invention Current and voltage of each phase as a corresponding electrical benchmark of possibly different value, and the two related benchmarks of the same phase are switched against each other and in each case one pole of the resulting guide variable only one each in one current direction responsive relay supplied, while the other poles of all resulting benchmarks are summarized and combined with those connected in parallel opposite terminals of the relay windings connected via a resistor are. The invention is based on the idea that the current balance by additional To use the introduction of the voltages for an additional comparison of the impedances and thus to create a kind of current-dependent impedance balance. On the other hand, can in this way the arrangement in the case of a three-pole short circuit just like an underimpedance excitation use. In other words, there is the basic idea of the invention therein, in each individual phase depending on the predominance of the current or the voltage is a positive or negative value-variable electrical benchmark to generate and the benchmarks via polarized relay arrangements with each other to compare in such a way that not only the relays remain blocked, in which the The influence of the voltage predominates (as is the case with normal impedance excitation is), but also that the phase with the strongest triggering benchmark is the The start relay of the other phases is blocked. In particular, a direct voltage drop can be used as a benchmark to serve.

Two embodiments of the subject matter of the invention are shown in FIG Drawing shown, namely shows.

1 shows a circuit using moving coil relays and FIG. 2 a circuit with non-polarized relays in connection with current direction dependent actuated semiconductor switches.

The currents and voltages of the individual phases of a network, not shown, are simulated by current and voltage converters, also not shown, by currents I and voltages U , which indicate the respective phase affiliation with corresponding indices R, S, T. These currents and voltages are fed to converters WI and WU, which in turn are connected to the AC poles of rectifier bridges G. The individual rectifier bridges are marked with the indices RI or RU, S1, etc., so that the phase affiliation can also be recognized. For each phase, two rectifier bridges fed by current or voltage are connected in opposite series with their DC poles and each feed separate resistors R for the voltage drops, which by specifying the indices RI, RU etc., as already mentioned, the phase affiliation and current or voltage. Specify voltage dependency.

The positive pole of the rectifier bridge GRD is directly connected to the one Terminal of a moving coil relay RER connected. The same applies to the others Phases, as can be seen from FIG. 1. The positive pole of the second voltage-affected Rectifier bridge Gj @ U is with the similar DC poles of the other Rectifier bridges connected and via a common resistor RB to the parallel connected other parallel connections of the moving coil relays RE.

A modification of the embodiment of the subject matter of the invention shown in FIG. 1 can be seen in FIG. 2, in which non-polarized relays RE 'with corresponding indices are used in connection with transistors, TR of the PNP type. One of the connections of the relays are connected in parallel and connected to the negative pole of a supply current source SP. The positive pole of this supply current source is led to the parallel-connected emitters of the said transistors, the collectors of which are each connected to the other terminal only of the associated relay. The bases of the transistors are directly connected to the negative DC pole of the current-controlled rectifier bridge GR, etc. The same DC pole of the second rectifier bridge QRU, which is influenced by the voltage, is connected, together with the same poles of the other voltage-dependent rectifier bridges, to the parallel-connected emitters of the transistors via the resistor RB. The voltage drops are in turn generated in the resistors R (with corresponding indices), and the two positive DC terminals of the two cooperating bridge circuits are connected to one another as in the exemplary embodiment according to FIG. The specified polarity relates, as I said, to the use of pnp transistors. When using npn transistors, the polarity of the bridge circuit would have to be reversed. The combination of the non-polarized relay with the transistor in turn results in an arrangement that corresponds to a polarized relay in the mode of operation.

Various error cases are considered below with reference to FIG.

In the case of a three-pole symmetrical short circuit, all three mains phases carry the same currents and also have the same voltage. This means that the same current flows through the common resistor RB for each phase, and if there is a triggering potential, all three relays respond at the same time. The response only occurs when the current-dependent voltage drop exceeds the voltage-dependent drop and thus currents flow through the relay in the direction of the arrow. The arrangement here has the property of a completely normal quotient excitation. By appropriately setting the converters WI and WU in the rectifier bridges and, if necessary, the resistors R for generating the voltage drops, it can be determined at which multiple amount of the rated current the relays respond at the rated voltage, and it can also be determined at which fraction of the rated current a Response occurs when the tension should completely disappear. In the normal load range, the relays cannot respond, as is also the case with a usual ouotient excitation.

If there is a single-pole earth fault, it can be assumed as the worst case that no star point is earthed on the side of the relay installation location, while earth connections are available at other points in the network. In this worst case, the faulty phase, e.g. B. phase R, twice the current of the healthy phases S and T. Thus, the input terminal of the associated relay RE is biased more positively, in a more triggering sense than the corresponding terminals of the other two phase relays, even if the three voltages and thus the corresponding voltage drops should also be the same. A current will flow in reverse direction through the two relays of the unaffected phases S and T. The blocking effect is supported by the fact that the faulty phase usually has a lower voltage than the other phases and the triggering current is even greater. So the circuit with the lowest impedance is selected. Since, on the other hand, the impedance value is inversely proportional to the current, the comparison impedance for the healthy phase or phases is greater as a result of the lower current and the correct selection is thus always ensured.

In the case of two-phase short circuits, the impedances of these two are true faulty phases equally large among themselves, but essential less than the impedance of the healthy phase. This way it becomes the most healthy third phase very securely locked and the relay correctly bipolar stimulated.

The mode of operation of the device according to FIG. 2 results accordingly without further ado from the circuit given and therefore probably needs in detail not to be specified. It is when using the circuit of FIG just make sure that the voltages must be such that for the Triggering the relay or relays the base of the associated transistor negative against the emitter must be biased. The emitter currents of the three transistors will be out via a common resistor RB for the transistors to be blocked an additional reverse voltage due to the current of the current-permeable transistor generated. The voltage drops are only control variables here, the relays are blocked from the supply current source SP.

The invention is not limited to the two specified Circuit examples, but can be modified and added in many ways. So it is possible and in some cases useful, apart from the current and the voltage of the phases to introduce other electrical quantities into the measuring circuits. Appropriate can be used for the known generation of an angle-dependent underimpedance excitation a voltage can be introduced, which indicates the direction of the energy flow. It can also be useful to use the negative system, the positive sequence or the zero system or a suitable combination of these sizes with one another or with the direction-dependent one To apply tension.

Furthermore, the arrangement according to the invention can be particularly advantageous are used in arrangements, the transformers with star-delta connection or triangular compensation winding included. The application here is especially for this suitable, on the side facing away from the short circuit, the electrical To summarize sizes in such a way that the distance measurement is nevertheless carried out correctly, whereby if necessary, a proportional measurement error can be allowed. This is especially true for one- or two-pole earth faults in networks with low-resistance neutral point earthing.

By detecting the zero current on the side of the short circuit, e.g. B. by a switched on in the ground relay relay, can on the measuring device the gear ratio of the converter can be changed so that the aforementioned proportional Measurement error is canceled and the measurement is carried out with the correct distance.

Claims (6)

PATENT CLAIMS: 1. Stimulus for protective relay arrangements, in particular Distance protection relay, characterized in that the current and voltage of each phase in itself as a corresponding electrical benchmark of possibly different things The value is reproduced and the two associated benchmarks of the same Phase are connected against each other, that in each case one pole of the resultant resulting reference variable each with a relay that only responds in one current direction is fed and the other poles of all resulting benchmarks are summarized and with the parallel connected opposite terminals of the relay windings are connected via a resistor. 2. excitation member according to claim 1, characterized in that that, if necessary, additional electrical parameters as benchmarks, in particular as Voltage drops simulated can be used for comparison showing the direction Measure the energy flow in the network and / or the one against positive and / or zero system represent. 3. stimulating member according to claim 1 or 2, characterized in that for Generation of the benchmarks to be compared with one another in the form of voltage drops to each of the AC poles a rectifier bridge to the relevant phase current or a current corresponding to the phase voltage in question is supplied that a resistor to each of the DC poles of both cooperating rectifier bridges for the voltage drop is connected and the same DC poles both rectifier bridges are connected to each other. 4. Stimulus according to claim 3 using moving coil relays, characterized in that the positive terminals (Minus terminals) of the live rectifier bridges of all phases a common voltage rail and from there via a common resistor connected to the winding connections of the moving coil relays connected in parallel the other connection with the positive terminal (negative terminal) of the current-applied Rectifier bridge of the assigned phase is connected. 5. Stimulus according to claim 3 using unpolarized relays with semiconductor switches that are dependent on the current direction, characterized in that a direct current pole of the current-fed rectifier bridge directly to the control electrode of a semiconductor body and via a resistor is connected to the electrode, the emitters of all semiconductor bodies in parallel switched on the one hand via a resistor to the common voltage rail and on the other hand via a supply current source with the parallel connections of the relays are connected, the other terminal of which is connected to the collector of the associated semiconductor body is led. 6. Stimulus according to one or more of the preceding claims, characterized by the use of protective relays in transformers with star-delta connection or triangular compensation winding to select the correct currents and voltages Short circuit on the other side of the transformer across the transformer. Documents considered: German Patent No. 927 939.