DE1238995B - Circuit arrangement for rapid tripping of circuit breakers in single-ended high-voltage lines - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

HOIh

H02h

German KI .: 21c-68/50

Number: 1238 995

File number: S 93263 VIII b / 21 c

Filing date: September 21, 1964

Open date: April 20, 1967

High-voltage systems have line sections that are switched on and off by circuit breakers can be. This switching on and off is partly done by automatically given control commands, the so-called selective protection signals. Local protection relays belong to the selective S protection system - das are protective devices that respond in the event of overload or short circuit in the line network (excitation) and determine the direction and distance of a suspected short-circuit point. To this The line section that has the short circuit is to be determined and disconnected. in the In general, the circuit breakers at both ends of the high-voltage line must be tripped. In little "meshed" high-voltage networks there are line sections fed on one side or temporarily on one side before. If a short circuit occurs on this route, it is only fed on one side, and the "excitation" of the protective relay occurs through overcurrent only at one end of the line. At the Selective protection system in which the readiness to trigger is signaled from both ends of the line and is triggered if this readiness to trigger applies to both line ends, such a Short-circuit cannot be eliminated because the protective receiver of the excited station is affected by the unexcited station is blocked.

A circuit arrangement is known in which, if the counter relay does not respond, that of the direction relay sent back release characters and thus a release of the addressed Relay reached. This is called a so-called "echo circuit".

The object of the invention is to enable a permanent protection signal transmission, whereby on the one hand frequency band saved and on the other hand the existing frequency band better utilized without neglecting the security of the transmission. The rapid tripping of the circuit breaker in unilaterally fed high-voltage lines should still be within the first time stage take place.

The invention relates to a circuit arrangement for rapid tripping of circuit breakers in single-ended high-voltage lines through a selective protection device and for transmission the selective protection signals in the voice band of a carrier frequency transmission device.

The solution to the problem is that a blocking frequency above the voice band is continuously transmitted, which blocks the selective protection controlling contacts of the opposite station, and that in the circuit arrangement for rapid tripping of
Circuit breakers in single-ended
Power lines

Applicant:

Siemens Aktiengesellschaft, Berlin and Munich, Munich 2, Wittelsbacherplatz 2

Named as inventor:
Erwin Schumm, Munich

If the trigger relay (contact "on") in the transmitter of a station, the voice or data transmission is switched off and various protective frequencies are transmitted within the voice band, which correspond to the positions of switches in these excited stations, and that the corresponding contacts are actuated in the opposite station by an evaluation circuit will.

Since short times and security are important when transmitting protective signals, it is advantageous to use the Avoid waiting and switching times on the receiving side and instead use this time to increase the Exploiting security. The basic idea of the invention is to continuously cover the frequency band of the transmission channel with a protective signal transmission and during the long time in which there is no protection case, additionally in the same channel To transmit long distance calls including dial signals. There must be no mutual interference occur. Long-distance calls may only be used for the short duration of a protection case the protection signals are disturbed and interrupted on the transmission side. There have to be two of each other independent protection signals are transmitted. A selective protection device is in both switching stations arranged at the line ends of a high-voltage line, and when there is an excitation the selective protection device sends its readiness via a selective protection signal, the circuit breaker trigger.

With this measure it is possible to use unilaterally fed line sections in the first time stage, d. H. switch off within 100 ms.

A short circuit in a line section fed from one side can also be caused by a resistance-time protection to be established. Such a contradiction

709 550/200

3 4

If the standstill time is far away, it would also be considered closed - and the connections would only reach the transmission device after the second time stage, i.e. after the main switch on. 500 ms, switch off. There is also a comparison- It can now either be a voice transmission or a protection system that controls the directions of energy from both data transmission. The over-line ends are valued. This protection system is 5 transmission device in the transmission point S consists of not able to detect a short circuit, a low-frequency intermediate time converter NFIZF if the direction of the unexcited with the necessary intermediate frequency station is missing. Carrier generator ZFT as well as the implementation of the

The line intermediate frequency position affected by a short circuit in the high frequency position with section must not only be switched off extremely quickly in the high frequency carrier generator HFTs. The high-frequency output signal, which is switched on again just as quickly, comes through the ability to get high; the interruption should be as short, frequency filter HFs and the high-voltage line that the synchronization of the supply generators ER HL remains the associated receiver in the remote station hold, so that the lines are not switched on again, the protection device is to be phased over a coupling element AKG have to. The time before the start of the 15 connected to the high-voltage line HL , short circuit until shutdown should be as short as possible, which on one side should be a high-frequency block (<100 ms). The time between shutdown and HFS has. The protective device has a transmitter part S restarting must be a little longer than the start - the associated receiver part is in the ionization time of the air after the light has gone out - the opposite station - and a receiver part E arc, ie about 300 ms. 20 - the corresponding transmitter part is located in the

The invention is based on the drawings.

kutiert. In it shows frequency fork HFG connected to each other.

Fig. 1 is a block diagram for quick release The receiver part E is the transmitter of the

and alarm feedback from a unilaterally fed counter station via a high-frequency signal transmitted

High-voltage line, 25 the coupling element AKG and the high-frequency

F i g. 2 such a device for »triangular fork HFG . In the recipient, the carrier

Protection". The parts that are decisive for the invention are high-frequency messages from the high-frequency position HF

are held stronger than the other parts. via the intermediate frequency position ZF into the low

Because the lines to be protected have a multi-frequency LF implemented. For this purpose, double-line systems are used, ie that 3 ° corresponding bandpass filters, converters, amplifiers and two three-phase current distortions, from which the high-frequency carrier generator systems are suspended, are used for the determination, HFTe and the intermediate frequency carrier generator on which one line mast system there is an error in the lines, four ZFT are specified. The low frequency signal requires frequencies. The transmitter S in FIG. 1 comprises pilot filter is the FP to the limiter means for generating four frequencies after 35 BVR and the limiter BVa and dei frequency-stage process (F6) modulation. The detection and evaluation message sent off downstream of the four frequencies is fed through the frequency tang F, Be. The detection switch P generator F 6 is dependent on the position of the separates the received signal again into four operating switches si and sll. The two switches si and rich (/ 1/4), the evaluation circuit Be sawn s II are associated with the two three-phase systems, 40, the received signals evaluates and provides control and depending on which system up an error signals for the relays M and N. The rest frequency / 1 occurs, the switch si, sll or both contacts is used as a pilot and causes after the excluded. The two switches are z. B. from sieving through the filter FP and gain VP a direction relay or from a distance protection a gain control VHR of the carrier frequency. The one frequency / 2 is transmitted, the 45th voice signal, the frequency / 1 is transmitted when a switch si has been activated, the second frequency is the limiter amplifier BVr and the frequency sequence / 3 is transmitted when the second switch demodulator Dw, according to the Frequency reversal was actuated, and a third frequency / 4 stung in the transmitter Fl, the pulses for the connected by actuating both switches si, sll senen selector channel Kwe obtained. A transmitted transmitted. While the three frequencies / 2, / 3, / 4 50 long-distance calls are transmitted through the voice filter NFte, which are transmitted in the voice band, the fourth voice amplifier Vte and low- frequency fork NFG frequency / 1 is transmitted above the voice band and fed to a telephone channel Kt,
and serves as the blocking frequency for the contacts ml, nl . The blocking frequency prevents the switch from being thrown, and a protective signal is triggered by the contacts, η 1 during the transmission of data or long-distance calls. In addition, 5II sent out by the transmitter F 6 . By Anwird the trap frequency in addition as a pilot frequency speak to the excitation contact the vers an amplitude control of the voice transmission of voice or data messages as well, and by means of Fl-modulation with a small frequency the transmission of the rest frequency / 1 inhibited hub used for subscriber selection. The protection 60 Depending on whether si, sll or si and sil signal transmission is required, the amplitude control requires the frequency / 2, / 3 or / 4 is now transmitted. gen, and after the evaluation in the receiving part E

Normally the rest position is present, the contacts n, m or η are transmitted to the opposite station, the frequency / 1 is transmitted, which is actuated separately in and m. The contacts η 1 and mi can be generated by a transmitterFl, and trigger the associated power monitoring switch Ul - which in this case is to be thought of as a switch or a switchover to a different time switch - via the connection switch stage. They are therefore used to control m2 and η2, the breaker contact ALS - that of the selective protection.

Claims (1)

Some additional devices are used to monitor the circuit arrangement according to the invention. The idle frequency / 1 is monitored on the receiving side by the monitoring circuit Ü3 in conjunction with an alarm relay A1. Until the alarm has responded, however, in the event of a possible failure of the idle frequency on the transmitting side, the speech could, under certain circumstances, activate the receiving relays M and N. On the transmitting side, the idle frequency / 1 of the transmitter F1 are therefore continuously monitored with the monitoring device Ü2 and the frequencies j2, / 3, / 4 of the transmitter F 6 with the monitoring device Ül. If one of the two monitoring devices responds, the voice amplifier Vts and the voice filter NFts as well as the transmitter F1 for the subscriber selection with the filter NFw are switched off from the line. As a result, in the event of a fault in the transmitter's protective signaling device, an alarm is also triggered with certainty on the receiving side. If the opposite station is “picked up” and ready to trigger, a corresponding signal is sent to the local station, which actuates the relays M and / or N. Either the switch m alone or the switch η alone or both can be flipped over. The received signal not only reaches the evaluation and detection circuit F, Be, but can also be sent to the transmitter via the low-frequency filter NFt and one of the switches m2 or nl, via the switch al 5 (which is to be thought of as closed) and via the activation switch 5 arrive at the station, which brings the received vibration back from the low-frequency position via the intermediate-frequency position to the high-frequency position and sends it back to the transmitting station. The associated circuit breaker is now triggered in the opposite station, after twice the signal propagation time, but still in the first time stage. The circuit described is used at both line ends of the high-voltage system, unless it is clear at which of the two stations of a power section a one-sided excitation occurs. It is now conceivable that a disturbance simulates a trigger signal, which, however, cannot trigger a high-voltage switch in the absence of excitation on both stations. This interference signal would now be sent from one station to the other and back again as a trigger signal that did not take effect. The switch al 5 is therefore provided, which interrupts the self-holding of the closed system after an appropriate time has elapsed. The switch at S can be built into both devices at the ends of the high-voltage lines. The circuit described can also be used to check the functioning of your own and the other station. For this purpose, a signal is sent from the local station to the opposite station, which is then sent back in the same way. F i g. 2 shows devices for one-sided quick release for a line triangle. Here, too, the parts that are decisive for the invention are drawn out more strongly. Each of the three switching points of a high-voltage line triangle has, in addition to a transmitter with its own frequency band, two receivers for the frequency bands occupied by the transmitters of the two opposite stations. This means that each station has a permanent, already regulated transmission channel to the two opposite stations without changing the band. F i g. 2 shows one of the three stations with its transmitter S1 and the receivers E1, E3 for receiving the transmitters of the opposite stations. The structure of the transmitter S1 and the two receivers EZ and E 3 is analogous to that in FIG. 1 arrangement shown. The receiver El contains an evaluation device Be2 and, downstream, the relays Nl and M2 and devices for receiving the selection signals, the demodulator Dw2 and the selection relay Kwel. The receiver £ 3 also contains the evaluation device with the downstream relay JV3; M3 and the corresponding devices for receiving the selection signals, the demodulator Dw 3 and the selection relay Kwe3. The transmitter 51 is controlled not only by the switches si and sU, but also by the switches m23 and «23. Diodes D 30 to D 33 are provided for mutual decoupling of the inputs. The receiver part is designed twice, namely the receiver part £ 2 is responsible for a transmitter S 2 and the receiver part E 3 for a transmitter 53. The frequency band of the local transmitter 51 is shifted to the frequency bands of the opposite station. The positions of the contacts of the relays M and N (ml, nl and m3, η3) also correspond to the positions of the send contacts si and sll of the respective opposite station. If an excited station sends a selective protection signal, this leads to certain positions of the switches m and n, and if there is also no excitation, the excitation switches α «1 and on! are in the position shown, then a signal corresponding to the received signal, i.e. in the frequency range of the transmitter 51, is sent back to the transmitting station. The transmission switch si corresponds to the switch m 23, the transmission switch ill corresponds to the switch «23. The switches m23 and «23 can be operated by the relay M2 or Nl as well as by the relays M 3 and N 3. The circuit shown in FIG. 2, like that of FIG. 1, simultaneously serves to carry out speech communication over the high-voltage line. So that this speech traffic does not interfere with the trigger signals, the speech channel is switched off by a switch rl. The switch rl is actuated by a relay Rl, which responds after actuation of each of the switches m23 or η23. The switches kl and k3 separate the unoccupied voice reception path from the subscriber after a call so that the received noise does not interfere. Patent claims: 1. Circuit arrangement for the rapid tripping of circuit breakers in unilaterally fed high-voltage lines by a selective protection device and for the transmission of the selective protection signals in the voice band of a carrier frequency transmission device between two stations located at the end of a line section, which have a transmitter and a receiver, characterized in that a blocking frequency above of the voice band is transmitted, which blocks the selective protection controlling contacts (ml, nl) of the opposite station, and that when a trigger relay (contact "on") in the transmitter of a station the voice or data transmission is triggered