DE877021C - Arrangement to prevent false triggering of line protection devices in the event of power swings - Google Patents

Description

Arrangement to prevent false tripping of line protection devices with swings It is known that line protection devices are switched incorrectly to prevent oscillations by reducing the tripping time of the line protection device, as soon as it is determined on the basis of some criterion that there is an oscillation, increased accordingly. Since there are generally oscillations following. a short circuit occur, because in the event of a short circuit, the generators work on this short circuit point and can come out of synchronicity, so that after switching off a short circuit Oscillations can occur, there is an increase in the tripping time in the event of a short circuit prepared, which comes into effect when a new stimulation occurs. Example si @ travel you have if the direction relay points outwards or if the impedance relay a certain time has elapsed so that it indicates that the error is outside the distance, or immediately at the first stimulation, increasing the release time prepared, which only became effective when a new excitation occurred. Of this The additional time by which the release time increased immediately began to run out became. After this time has elapsed, if the start relay is still in contact has closed, the actual Schutzreiaiseinriehtung, z. B. the impedance relay, put into action. This additional time must now be measured in such a way that in the case of pendulums Incorrect switching is avoided. The subject of the invention is also a direction to avoid incorrect switching of line contactor devices for pendulums, in which the tripping time is increased during the pendulum process. According to the invention, however, this time only begins to run down, if preferably after Determination that an oscillation is to be expected or that there is one that Selective Sehützeinrichtung itself has found that without considering this Additional time an immediate switch trip would take place. The extra time that is switched on, so only begins to expire when the line protection device, through the simulated fault is influenced in such a way that it gives a trip command. However, this cannot be carried out, but at this moment the begins Additional time to expire, and only when this has expired can the trigger command, if the protective device still gives it, be forwarded to the switch. By the measure according to the invention is achieved by choosing the additional time to be smaller can than the usual arrangements, which has the advantage "that if during the swings a real error occurs, the time in which the error is switched off does not become too big. The reason for reducing the additional time at the Arrangement according to the invention is that @ that until the moment of detection the relay device that an immediate shutdown should take place a more or less large part of the peadel period has passed. So she needs only to be so big that from this moment on; if .the relay device the Wants to give trigger command, this is delayed until the faked one Error comes out of the protection area of the protective device.

This can best be explained using an example. Be it assumed that it is a directional comparison protection; with the one Coupling line between two power plants is equipped. Now occurs, for example a fault in a branch of the coupling line -up, one of the two direction relays indicates at one end of a path inwards, the other outwards. If the bug is switched off, the generators can, as mentioned, start to oscillate, and the direction relays reverse one after the other. The only area for false alarms is dangerous, in which the Feiler feigns within the considered route will, i.e. in which the directional relays both point inwards. Well, if the direction relay points outwards, a blocking relay is activated, which prevents tripping, according to the invention this will expire if: the Direction relay shows naked inside. The expiration time of the blocking relay only needs something to be greater than the time that elapsed from the beginning of the pretense of the error Line section, @d. H. naked from the moment the direction relay was turned passes inside until the faked error disappears from the line. at With the previous arrangements, however, the additional time had to be so great that it was greater was as the time that passed from the suggestion to the moment when the Error out of the way.

The possible reduction in additional time when setting up after the However, the invention requires that an actual error occurring in the case of oscillations can be switched off in a shorter time.

It is advantageous to use the locking relay once it has been activated; alsö assumes the position in which the protective device is completely or only with its short tripping time is locked in this position when the excitation falls off.

What applies to directional misalignment protection also applies to others Protective devices, for example for resistance protection. Here is at pendulums A trip command by the relay device is only given when the simulated one The error was in the protection area of the arrangement for a correspondingly long time, and that in this The additional time running at the moment, which increases the tripping time, is measured in such a way that that it is greater than the time in which the error looks so far away again has that the trip command is revoked.

It is not absolutely necessary that the additional time, e.g. B. with Wnderstandssdhutzeinrichtungen that are steadily or with the error distance gradually variable release time is increased by an amount, but it is sufficient z. B., if only the fast time is increased or also the time that is due to shutdown of errors at the beginning of the next route takes effect. Even with reference comparisons cutbacks will not increase the reserve time.

The drawing shows two embodiments of the invention in single-phase Depiction.

In FIG. 1, such a section of a long-distance line is designated, which can be interrupted at both ends by switches 311 which are actuated by trip coils 3L9. The relay devices at the right and left ends of the line are the same. They are therefore also provided with the same reference symbols. The trigger relay, which has a normally open and a normally open contact, is designated with @I. The directional relay has the reference number 2. It carries a movable contact and a fixed inward and a fixed outward contact. The two relay devices are connected to one another by an auxiliary line 3 # 3 and an auxiliary line 34. The positive pole of the left end of the line is connected to the negative pole of the direct current battery of the right end of the line via the auxiliary line 34. In order to prevent false tripping from occurring, a timing relay 3 (blocking relay) is provided, which has a normally closed contact in line 33. In the exemplary embodiment, it consists of a coil with a capacitor in parallel. It is excited when the trigger relay has responded and the direction relay points outwards. An auxiliary relay 4 is also provided, which is excited when the trigger relay is triggered and which has a normally closed contact and a normally open contact. The normally open contact is in the circuit of an auxiliary relay 5, which has three normally open contacts. The middle one is a self-holding contact. The left one is in series with the normally closed contact of the excitation relay in the circuit of the timing relay 3, the right one is in series with the normally closed contact of the relay 4 in the circuit of an AC timing relay 6, which has a normally closed contact in the self-holding circuit of the relay 5. In the circuit of the auxiliary relay 4. there is still a normally open contact of the timing relay 3.

If an error occurs in the line (two-sided supply is required), so speak the two excitation relays, z. B. Overcurrent relay at both ends of the line at. You put what is not shown, the voltage coil of the direction relay of tension. In the case of multi-phase systems, several starter relays are provided which, if only a single-pole directional relay is available, this one when it responds not only supply the right voltage, but also the right current. the Directional telephones close their inward contact, and thus the circuit is closed Excitation of the trip coils 32 completed. If the error lies outside, it shows a direction relay to the outside, a line break cannot occur.

It is assumed that there is an error to the left of the route section under consideration in a branch line of the coupling line connecting two power plants, which contains the section 3o has occurred. The two trigger relays respond, the left direction relay points outwards, the right one inwards. By closing the external contact, the timing relay (blocking relay) 3 is energized and opens its normally closed contact. Via the closed normally open contact of the start relay and the closed normally open contact of the timing relay 3 is the auxiliary relay q. excited and energizes relay 5 by closing its normally open contact, which softens itself holds. If the fault on the branch line is eliminated, oscillations can occur appear. The consequence of this is that the directional relays switch one after the other, because with oscillations the direction relay is simulated an error that over the line wanders away. It is assumed that the direction relay after switching off of the error maintain their position and now an oscillation begins, through which the error seems to move from left to right. The moment the faked faults occur in the route, the left direction relay will strike inside around. The timing relay 3 is de-energized and closes after a certain time Time its rest contact. This time must now be measured in such a way that, before the Normally closed contact closes, the bug eats out again at the right end. The time therefore depends on the duration of the commute and the length of the route. She is with Take into account the longest pendulum time that can still occur. As soon the faked mistake wanders out again on the right side, is confirmed by Awsschlag of the direction relay at the right end of the line, the timing relay 3 is energized and one Line interruption blocked.

Through the relay 5 and the normally closed contact of the excitation relay is reached, that also in the time segments during the pendulum process in which the excitation has dropped out, the timing relay 3 remains energized, so that even when the excitation relay responds and the direction relay applies voltage and the simulated error is on the line section at this moment, always the additional time remains connected upstream.

If the actual error occurs during the oscillation process on the Line section, both direction relays point inwards, and after the expiry of relay 3, the route is switched off.

In order to bring the protective device back into its normal position, you can z. B. provide a timing relay from the moment of the first excitation begins to run and the self-holding circuit of the relay 5 after .a certain Time interrupts. In the exemplary embodiment, the timing relay is denoted by 6. the The excitation of the time relay excited by the AC mains voltage is still carried out via a break contact of relay 4, so that the time relay only begins to expire, when the start relay is in the rest position. The working contact of the Time relay 3 in the circuit of the Hilfarelai q. causes only once the timing relay was energized via the external contact of the direction relay., a Excitation occurs when the excitation relay has dropped out. You could also make the working contact of the timing relay. Then the timing relay would be activated after each dropout of the excitation 3 are excited.

In Fig. 2 a .anderes embodiment of the invention is shown. With i the contact of the excitation relay is again referred to, 2 is a relay device not shown, for example a resistance time-dependent, z. B. impedance time-dependent relay device. It can consist of an impedance relay, the switch-off time of which constantly depends on the distance to the fault, it can also consist of several impedance breaker relays that result in a step-by-step switch-off time in a manner known per se, or it can also be an impedance protection device that is within a certain part of the to be monitored Route with short tent, abruptly over it with a longer time and finally with a steadily increasing time turns off. As soon as this relay device, to which one or more directional relays generally belong, gives the switch-off command, the positive pole is connected to the line 35. The representation of the relay devices has not been made for the reason that it can be any relay device. With 32 the trip coil is again referred to. 7 is an auxiliary relay which is excited when the trigger relay responds and connects the trip coil to line 35. So if the trigger relay responds, the trigger coil can be excited as soon as the relay device 2 has made contact. So if the fault is nearby, for example. the triggering with short toe, if it is further away, with a longer time, etc. If, however, the fault is not switched off by relay 2 because the fault was too far away and was switched off by another relay device, and then occur this bug pendulum on; so the start relay drops out and picks up again. Now, however, the relay 7, as soon as it is excited, turns on the excitation for a relay 8 via a normally open contact, which opens a normally closed contact in the circuit of the relay 7 and maintains itself via a normally open contact. The opening of the normally closed contact has no effect as long as the excitation relay and the relay 7 have responded, since a normally open contact of the relay 7, which is parallel to the normally closed contact, is closed. If, however, the excitation relay drops out, the relay 7 also drops out and opens its normally open contact, so that the relay 7 can no longer be excited when the excitation relay closes again. The consequence of this is that the connection of the line 3: 5 with the coil 32 is interrupted and a command given by the relay device. can only set a timing relay 3 in action, which only allows the command to be passed on to the trip coil after it has expired. The additional time is also only effective here; if -the relay device gives the trip command. It is dimensioned so that such a time passes from the moment the command is given until the time relay expires that the simulated error has meanwhile moved so far away from the range of the relay unit 2 that it cancels the trip command again. The return of the device is done again by an AC time relay 6, which has a normally closed contact in the self-holding circuit of the relay 8 and is switched on by this relay. In order to enable the complete expiry of the timing relay 6 only when the oscillations are over, there is a rest contact of an auxiliary relay g in the circuit of the timing relay 6, which is excited when the excitation relay responds.

The relay device 2 can also consist of a single Richtnxngreais, If the directional comparison protection is concerned, exist. There are still for transferring the position of the direction relay and the switchover contact of the relay 7 and the contact of the timing relay 9 on the other end of the link auxiliary connections in the form of auxiliary lines or high frequency channels required by e.g. B. the trip coil is not connected directly to the negative pole, but in a similar way Form as in Fig. I via an auxiliary line with your other end of the line and: the Relay equipment there connects.

Claims (1)

- PATENT CLAIMS: i. Arrangement for the prevention of false tripping of line protective devices in the case of shuttling by increasing the tripping time during the pendulum process, characterized in that the additional time increasing the tripping time only begins to expire if, preferably after determining that a shuttling is to be expected or that such a pendulum exists, the selective protective device itself has been determined has that an immediate tripping of the circuit breaker would be brought about without taking the additional time into account. 12. The arrangement according to claim i for the directional protection, characterized in that when the direction relay deflects outwards, a blocking relay (3) is actuated, which immediately blocks the triggering option and that this blocking relay for release only begins to expire as soon as the direction relay ( 2) points inwards (Fig. I). 3. Arrangement according to claim 2, characterized in that the blocking relay is inserted into the circuit in such a way that it prevents the quick disconnection when it becomes effective, both at the end of the line where it is installed and at the other end of the line in question . q .. Arrangement according to claim i, characterized in that when pendulum phenomena occur, the trip line is interrupted and that a trip command. 5. Arrangement according to claim 4, characterized in that the readout line is interrupted only shortly after the trigger relay has responded for the first time. 6. Arrangement according to claim 5, characterized in that after: the first dropping of the starter relay (i) the trip line is interrupted, and that after a subsequent re-excitation of the selective protection relay (2) given trip command a timing relay (3) in Corridor. sets, which only allows the trigger command to be passed on to the switch after it has expired (Fig. 2). 7. Arrangement according to claim 2, characterized in that once the locking relay has been actuated, it is held in its locking position when the excitation relay drops or is brought back into it. 8. Arrangement according to claim i or one of the following, characterized in that a certain time after the beginning of the Pendelurig or a certain time after the disappearance of the Pendelurig the normal conditions, ie the: possibility of quick shutdown, are restored. G. Arrangement according to claims 2 and 7, characterized in that when the direction relay (2) deflects outwards, a blocking relay (3) is excited to switch on the additional time and that an auxiliary relay (5) is excited when the excitation relay (i) responds, which holds itself and has a normally open contact in the circuit of the blocking relay (3), which is in series with the normally closed contact of the excitation relay (i) (Fig. i). ok Arrangement according to Claim 9, characterized in that the auxiliary relay can only be excited when the blocking relay has already responded. vi. Arrangement according to claim @io, characterized in that the actuation of the auxiliary relay (5) by the excitation relay (i) takes place indirectly via a second auxiliary relay (4) which has a break contact in the circuit of a timing relay (6) preferably excited by the operating voltage, to which a working contact of the first auxiliary relay (5) is connected in series, while the Wedhselstromzeitrelais has one in the self-holding circuit of this auxiliary relay (Fig. i). i2. Arrangement according to claim 6 @, characterized in that when the trigger relay (i) responds, an auxiliary relay (7) is excited which has a normally open contact in the circuit of the trip coil (3a), but that the auxiliary relay (7) after the trigger relay has dropped out (.i) cannot be re-energized and keeps a normally closed contact closed, via which a trip command given by the relay device (z) first activates a time relay (3), which in turn only sends the trip command to the coil (3z ) passes on (Fig. @?). 13. Arrangement according to claim lic, characterized in that this auxiliary relay (7) has a normally open contact in its excitation circuit which is parallel to the normally closed contact of an auxiliary relay (8) which is excited when the first auxiliary relay (7) is excited and holds itself ( Fig. 2). 14. The arrangement according to claim 13, characterized in that in the self-holding circuit of the auxiliary relay (8) there is a normally closed contact of a timing relay (6) which opens this contact after a certain time after the oscillation has ceased (Fig. A). 1 5. Arrangement according to claim 14, characterized in that in the exciter circuit of the timing relay (6) a normally closed contact of an auxiliary relay (9), which is activated glue response of the exciter relay, and a normally open contact of the auxiliary relay (8) are in Self-holding circuit of the normally closed contact of the timing relay (6) is.