DE1102890B - Protection device for high voltage lines - Google Patents

Description

Protection device for high-voltage lines The invention relates particularly on a protective device for high-voltage lines. Such a one Establishment is needed to protect power lines and power systems from damage to protect against faults and short circuits. In a known protection method for this purpose, the phase position of the line current at both ends of the high-voltage line compared to each other. If the line is fault-free or if it is outside the relevant line Line section fault is the phase position of the currents at both ends of the line same, d. that is, the polarity of the current is at the same point in time at both ends the same as the line. A fault or short circuit on the line has the consequence that the phase position of the line currents deviates from one another by up to 180 °, d. i.e. that the Polarity of the current at certain times at both ends, different on the line is. A criterion for disconnection is derived from the phase difference serves the direction. This protection procedure assumes that the phase position of the currents unadulterated transmitted from one end of the line to the opposite end will. For this purpose, there is a high-quality transmission channel for each transmission direction required, since a variable variable must always be accurately transmitted.

So that not small phase differences that z. B. at great distances phase rotations along the line can lead to a shutdown lead the line, facilities are required that only occur when there are phase differences cause the line to be switched off with a certain minimum size.

The circuit arrangement for the protection of high-voltage lines through Comparison of the current phases at the line ends and disconnection of the line in the event of phase differences certain minimum size according to the invention avoids the disadvantages of the known such arrangements. In particular, the sensitivity to interference as well as the required Reduced bandwidth for transmission and disconnection of the line in all Malfunctions caused quickly. This is achieved according to the invention in that Switching means are provided at both ends of the line, which consist of one with the line current AC voltage with a fixed phase relationship at the respective end of the line, square-wave pulses derive a certain pulse duration and to the other end of the line if necessary transmit in the form of amplitude- and / or frequency-modulated vibrations, where evaluation switching means are provided that the received, possibly demodulated pulses sampling pulses superimpose very short pulse duration from the with the line current at this AC voltage with a fixed phase relationship can be derived from the end of the line, in the case of phase equality at both line ends in the middle of the received pulses lie, and only then actuate the release switch and the disconnection of the line cause if they are not coincident with the transmitted pulses. Disruptions on the transmission path can only have an effect if they are during the duration of the sampling pulses occur. Since the duration of these sampling pulses is very short, results maximum security.

The pulses are advantageous compared to one direction of transmission the pulses of the other transmission direction phase-shifted and only one transmission channel used for both directions of transmission. This will provide the required bandwidth reduced by half.

In the case of multiphase systems, mixing can be advantageous. the individual Current phases form a single equivalent voltage that is only used in the event of faults on the Line z. B. is used via an overcurrent excitation for phase evaluation. In this case, pulses are only sent over the transmission channel when Transmit disturbances. During the rest of the time, the transmission channel for the Transmission of other messages are exploited.

Details of the invention are explained with reference to the drawing.

Fig. 1 shows an advantageous embodiment according to the invention for monitoring a three-phase system. At input E, an alternating voltage obtained by mixing the individual current phases is only supplied in the event of disturbances on the line. The course of this voltage is shown in FIG. 2, line 1. It is fed to an amplitude limiter B, which is set to a certain value, e.g. B. 0.5 volts, and the voltage shown in Fig. 2, line 2, emits to the flip-flop K at its output. At its output, this emits the square-wave pulses shown in FIG. 2, line 3, with a duty cycle of 1: 1. On the one hand, these pulses are fed to the monostable multivibrator K111, which is triggered by each negative edge for a certain time. The output voltage of the monostable multivibrator K 3I1 is shown in FIG. 2, line 4. The pulse duration of the pulses emitted by the monostable multivibrator K @ IT 1 is adjustable, e.g. B. by changing the time constant, and corresponds to the permissible phase differences between the currents at both ends of the line. In the case of the pulses shown in FIG. 2, line 4, a permissible phase difference of ± 45 'was assumed, which corresponds to a pulse duration of 5 ms at a frequency of 50 Hz. The pulses according to FIG. 2, line 4, control the tactile modulator 11, which thereby becomes permeable during the pulse duration for the vibrations supplied by the generator G, which are transmitted via the transmission channel UK to the other end of the line. There they reach the input of the monostable multivibrator K 113 via the reception filter F, the amplifier 1 ', the rectifier circuit Gr and the low-pass filter TP.

For the other transmission direction, an alternating voltage obtained by niching the individual current phases at this end of the line is fed to input E ', which is phase-shifted by 180 ° with respect to the corresponding alternating voltage at the other end of the line and which is also only effective in the event of disturbances on the line. By shifting it by 180 °, the pulses in both transmission directions are interleaved and only one transmission channel is required for transmission. The course of this alternating voltage is shown in FIG. 2, line 6. It is limited in the limiter B ' (Fig. 2, line 7), converted into square-wave pulses in the flip-flop K' (Fig. 2, line 8) and controls the monostable flip-flop K-11 1 ', which has certain pulses at its output adjustable pulse duration emits (Fig. 2, line 9). The oscillations of the generator G 'are amplitude-modulated by these pulses in the modulator circuit ilF and transmitted via the transmission channel UK to the other end of the line, where they are transmitted via the receiving filter F', the amplifier h ', the rectifier circuit Gr' and the low-pass filter TP 'of the monostable multivibrator KM3 'are supplied.

The output voltage of the multivibrator K also controls a monostable Tipper KM2. Contact a is initially assumed to be open. This monostable Flip-flop K, 112 is also only through certain changes in polarity, z. B. by positive pulse edges, triggered and emits a very short cycle pulse at its output Duration with adjustable delay. These pulses are shown in FIG. 2, line 5. They are those sent by the other end of the line, shown in FIG. 2, line 9 Pulses superimposed. The delay of the pulses according to Fig. 2, line 5, is adjustable and chosen so that the sampling pulses when the currents are in phase at both ends of the line exactly in the middle of that received from the other end of the line Impulses lie. The short runtime associated with the transfer is thereby taken into account. The superimposed voltage curve that is created by combining of the voltage curves according to FIG. 2, line 9, and FIG. 2, line 5, is in Fig. 2, line 11 is shown. If the sampling pulses do not match the received Pulses are coincident, the monostable multivibrator KM3 'is triggered, its output voltage in Fig. 2, line 12, is shown. It controls the drop-out delayed relay RL '. The corresponding voltage curve is shown in FIG. 2, line 13.

At the other end of the line there is also a monostable multivibrator K, 112 ' provided, which is controlled in a completely analogous manner by the flip-flop K 'and the scanning pulses shown in Fig. 2, line 10, very short duration and adjustable Delay that is exactly in the case of phase equality at both ends of the line Middle of the received from the other end of the line, shown in Fig. 2, line 4 Impulses lie. The course of the superimposed voltage is shown in FIG. 2, line 14. This Voltage is used to control the monostable multivibrator K.1,13, its output voltage Fig. 2, line 15 shows. It controls the drop-out delayed relay RL. The corresponding The voltage curve is shown in FIG. 2, line 16.

Various malfunction cases are shown in FIG. First of all, the case is assumed that no disturbance is registered in the line network at either end of the line. As a result, no alternating voltage is fed to the inputs E and E '. At time t1, a disturbance occurs outside the protected line section which, although it leads to phase and amplitude changes in the current, is the same at both line ends, so that no phase differences arise. Although pulses are now transmitted to the other end of the line, these are coincident with the scanning pulses, so that the monostable multivibrators KM 3 and KM 3 * and the downstream relays RL and RL 'are not actuated. At time t2, an error should now occur within the line section, which is fed from both sides and results in a phase jump of 90 ° at one end of the line (FIG. 2, line 6), while only an amplitude jump occurs at the other end of the line. The phase jump exceeds the value still considered to be permissible for the phase differences of ± 45 °. As a result, the pulses transmitted to the other end of the line are no longer coincident with the scanning pulses (Fig. 2, lines 11 and 14), and the monostable multivibrators KM3 and KM3 'and the downstream relays RL and RV respond (Fig. 2, line 13) and 16). The circuit breakers at both ends of the line are now actuated via the contacts rl and rl 'and the line is switched off.

At time t 3, there should now be a fault within the line section occur that is only fed from one side (Fig. 2, line 1), which has the consequence that no more current flows at one end of the line and consequently none at input E ' AC voltage is supplied (Fig. 2, line 6). In this case too, the monostable Flip-flop KM 3 'and thus the relay RL' triggered and the line switched off caused at the end at which the feed takes place (Fig. 2, line 13).

As already mentioned, the monostable multivibrators K1472 and KM2 'contacts a and a' are connected upstream. Through these contacts, the output voltage of the flip-flop K or K 'fed to the monostable multivibrator KM 2 or KM Z' is initially short-circuited. They only open a certain time, e.g. B. 15 ms after the occurrence of the fault, so that the two flip-flops KM2 and KM2 'can only emit sampling pulses after this period. This is necessary because the supply of the alternating voltage for the phase comparison at both line ends is not guaranteed to take place simultaneously and a correctly steady state must be awaited from the transmitting side. The contacts a and a 'can also be simulated and replaced by electronic means.

Of course, the circuit arrangement shown in FIG be modified or supplemented within the scope of the invention. So it is z. B. possible the alternating voltage converted into a square wave voltage with a duty cycle of 1: 1 to be transmitted to the other end of the line. There this square wave voltage are scanned by two scanning pulses, their distance from the leading edges is normally the same and the phase differences that are still considered permissible between the currents at both ends of the line. The effort increases not compared to the illustrated embodiment, since on the receiving side although one more monostable multivibrator is required to generate the second sampling pulse which, however, is omitted on the transmission side, since the right: back pulses with the duty cycle 1: 1 not yet in square pulses with the permissible phase deviations corresponding Duration must be converted.

Of course, the scanning pulses could also be transmitted and the selected with regard to their pulse width according to the permissible phase deviations Pulses are superimposed. However, this is disadvantageous for reasons of disturbance.

If, as in the embodiment shown in FIG Protection of multi-phase systems by mixing the individual current phases, an alternating voltage is derived, which is only effective in the event of disturbances on the line, the transmission channel during the rest of the time it can be used to transmit other messages. In this case, the circuit is to be implemented in such a way that this message transmission The transmission of the protection signals is switched over as soon as faults on the Line occur.

The circuit arrangement according to the invention can advantageously be used anywhere are used where a comparison of spatially separated locations normally the same states with regard to their time-correct mutual Location and marking of deviations of a certain minimum size required or is desired. This is, for example, when phasing teletype transmission systems the case.

Claims (12)

PATENT CLAIMS: 1.Circuit arrangement for the comparison of states occurring at spatially separate locations, which are normally the same with regard to their mutual position at the correct time and to identify deviations of certain minimum sizes, preferably to protect high-voltage lines by comparing the current phases at the line ends and disconnecting the line in the event of phase differences Minimum size, characterized in that switching means are provided at both line ends which derive square-wave pulses of a certain pulse duration from an alternating voltage that is in a fixed phase relationship with the line current at the respective line end and transmit them to the other line end, optionally in the form of amplitude- and / or frequency-modulated oscillations, where Evaluation switching means are provided which superimpose the received, possibly demodulated pulses, scanning pulses of very short pulse duration, which are derived from the line current at this Le at the end of a fixed phase relationship, alternating voltage can be derived, if the two ends of the line are in phase, they are in the middle of the received pulses and only actuate the release switch and cause the line to be disconnected if they do not coincide with the transmitted pulses. 2. Circuit arrangement according to Claim 1, characterized in that the duration of the respective other line end transmitted impulses the phase differences between corresponds to the currents at both ends of the line and the sampling by one each sampling pulses lying in the middle of the received pulses takes place. 3. Circuit arrangement according to claim 2, characterized in that the alternating voltage standing in a fixed phase relationship with the line current at the respective line end is initially converted into a square-wave voltage with the aid of a limiter (B, B ') and a trigger stage (K, IL') controlled by this and is used to control a first monostable multivibrator (11M1, K, 171 '), which forms pulses with a specific pulse duration corresponding to the phase differences considered permissible. 4. Circuit arrangement according to claim 3, characterized in that the first monostable multivibrator (KM 1, KM l ') is triggered only by changes in polarity in a certain direction of the square-wave voltage supplied to it. 5. Circuit arrangement according to Claim 3 and 4, characterized in that the output voltage of the flip-flop (k, K ') is also fed to a second monostable flip-flop (KM2, KM2') which is only triggered by polarity changes in a certain direction and those with a such a delay returns to the stable position that the and the sampling pulses superimposed on the pulses received from the other end of the line very short pulse duration with phase equality at both ends of the line in the middle these impulses lie. 6. Circuit arrangement according to claim 5, characterized in that that the scanning pulses superimposed on the pulses received from the other end of the line a third monostable flip-flop (KM3 ', KM3) are fed and this only then for one to safely address and hold a downstream trigger element, z. B. trigger a delayed relay (RL, RL ') for a sufficient period of time, if they do not coincide with the received pulses or if there are no pulses be received. 7. Circuit arrangement according to claim 1, characterized in that that the pulses transmitted to the other end of the line have a pulse duration ratio to have pulse pause of 1: 1 and the sampling by two each in the case of phase equality sampling pulses located at both ends of the line in the middle of the received pulses takes place whose distance from the leading edges or from the trailing edges of the received Impulses the phase differences between the currents at both that are still considered permissible Line ends. B. Circuit arrangement according to Claims 1 to 7, characterized characterized in that the sampling pulses only after one of the transient processes occur or take effect for a certain period of time after the start of the fault, e.g. B. by blocking the input of the second monostable multivibrator (KM2, KM2 ') during this period (contact a, a. '). 9. Circuit arrangement according to claim 1 to 8, characterized in that the pulses of a direction of transmission opposite the Pulses in the other direction of transmission are preferably 180 ° out of phase and both are transmitted over a transmission channel. 10. Circuit arrangement according to claim 9, characterized in that the alternating voltage derived from the current phases is fed to one end of the line with respect to the other with opposite Po: ment and the first monostable multivibrator (KM 1, K M 1 ') by polarity changes in one direction (z B. positive direction) and the second monostable multivibrator (KM2, KM2 ') can be triggered by changes in polarity in the other direction (negative direction). 11. Circuit arrangement according to Claims 1 to 10, preferably for monitoring three-phase systems, characterized in that that the alternating voltage which has a fixed phase relationship with the line current is obtained by suitable mixing of the individual current phases and preferably is only used for phase comparison in the event of faults on the line. 12. Circuit arrangement according to claim 11, characterized in that the transmission channel during the Transmission pauses are used for the transmission of other messages.