DE3213793A1 - Device for protection against short-circuits in high-power on-board networks - Google Patents

Abstract

The invention relates to a high-power on-board network having generators which are combined to form groups, operate on a busbar and are connected to the loads. Arranged between the generator groups is an electronic power circuit breaker which inserts a parallel resistance or a parallel inductance into the circuit if a predetermined excess current is exceeded. In order to reduce the previously necessary large space requirement and the large weight for the current transformer and rectifier, once the sub-transient equalisation process has decayed and/or the voltage has returned, the power circuit breaker will partially or completely bridge over, in a current-controlled and time-controlled manner, an inductive impedance having a tap which has a reverse-parallel thyristor circuit, by means of turn-on and turn-off signals from a monitoring device, or will completely switch out a real resistor. After continuous switching of a short-circuit and return of the voltage, a phase measuring device will determine the phase of the voltages of the generator groups and, in the event of a phase balance, turn on the main thyristors of the power circuit breaker via the monitoring device. <IMAGE>

Description

"Device for protection against short circuits in on-board networks

great performance "The invention relates to a device for protection against short circuits in on-board networks with high performance according to the generic term of the main application.

It is a short-circuit protection device for on-board electrical systems with high performance from DE-AS 27 10 625 known, in which several generators combined into groups work on a busbar to which the consumers are connected. Between the generator groups is a current transformer with his in the collective rail Primary winding inserted, in its secondary circuit an electronic circuit breaker is arranged with a parallel ohmic resistor. When exceeding a Grenzatromes this resistance is switched into the circle some. The circuit breaker bridges the time-controlled after the sub-transient equalization process has subsided ohmic resistance consisting of several partial resistances in whole or in part. The ignition and extinguishing signals for the power switch are supplied by a monitoring device. An advantage this short-circuit protection device can be seen in that after the short-circuit disconnection, the defective generator group immediately synchronize again Can start operation with the undisturbed group. There is a major disadvantage in the larger space requirement and heavier weight for the Stromtransfcrmator and the Rectifier.

This short-circuit protection device is improved in DE-OS 30 05 950 has been proposed in that a device for synchronizing and Regulation of a constant voltage provided for such a power generation plant became. For this, the primary winding of the current transformer has a center tap provided, at which an actual voltage value for voltage regulation in an undisturbed effort tap is. A phase measuring device determines after the short-circuit progression the phase position of the phase voltages of the generator groups and leads in case of phase equality synchronization by switching off a parallel resistor. Although it can as a result, the power limit of the network can be increased significantly, the technical Effort for current transformer and rectifier is still necessary.

Finally, a method is known to throttle short-circuit currents via @@@@@ to dampen. However, because the islands are switched on all the time, the network becomes soft and leads to constant losses. Short circuit voltage and losses increase with the Degree of damping. There is also a larger voltage difference between: -ch end Generator groups present in the case of a current in the transfer line. This allows it to unequal blind load distribution.

The object of the invention is therefore for a power generation system to create a short-circuit protection device of the type described above, the a quick decoupling of the parallel ending generators in the event of a fault and a subsequent Parallel operation with minimal voltage drop across the Power switch guaranteed in normal operation.

To solve this problem, according to the invention, the Hennzeichen of the main claim mentioned features used further developments of this invention are characterized in the subclaims.

Compared to the known series throttles, the device leads to the Invention of a stiff network and low losses The voltage differences between the sub-networks are negligibly small even under load. A good reactive load distribution and damping to approximately the nominal current in the event of a malfunction is possible.

Compared to the well-known current transformer with rectifier is distinguished the subject of the registration due to lower costs, smaller space requirements and a lower voltage drop. When the overcurrent is attenuated by means of coarse synchronization is also possible with an inductance.

In the drawing, exemplary embodiments according to the invention are shown. FIG. 1 shows an electronic circuit breaker with parallel inductance between the generator groups, Figure 2 with the electronic circuit breaker a parallel ohmic resistor, Figure 3 an improved quenching circuit supply for the electronic circuit breaker, Figures 4-7 the use of electronic Circuit breakers in star point-free and in networks with a star point.

According to FIG. 1, a first group of generators G1.1 and G1.2 feeds A busbar 81 via generator switches S1.1 and 51.2 One second group of generators E2.1 and G2.2 feeds via generator switches S2.1 and S2.2 a further busbar section 82. The busbar sections 81 and 82 can be connected to one another via a coupling bracket K. From the busbar sections branch consumer lines V1 and V2.

There is an electronic circuit breaker in series with the K toe switch ELS, which has the main thyristors TH1 and TH2 connected in antiparallel with in series lying DC converters f1 and f2 and chokes LH1 and LH2. Parallel to this is an inductance I with a tap in which a parallel Thyristor arrangement T1 and T2 is located. Quenching circuits are located immediately above the main thyristors arranged, which consists of the quenching thyristors TL1, TL2, the Ldschdrosseln LL1, LL2 and Quenching capacitors CLI and CL2 exist. The quenching capacitors are charged from isolating transformers ml and m2 via the resistors R1, R2 and diodes D1 and D2.

The secondary windings of the direct current converters f1 and f2 as well as the Control connections of the thyristors are connected to a monitoring device Ü. A phase measuring device EP detects the phase position of the voltages in the generator groups and sends a corresponding signal to the monitoring unit if the phases are identical U.

The mode of operation of the electronic circuit breaker is as follows: In the uninterrupted parallel running of the generator groups, the cup switch K is closed and the main thyristors TH1 and TH2 receive a continuous ignition signal. The direct current converters f1 and f2 record the direct current in the respective main branches and give in If an overcurrent occurs, a signal is sent to the monitoring device Ü. This causes thereupon the blocking of the ignition currenta of the main thyristors and gives to the respectively assigned quenching thyristor an ignition signal. This will make the main power commutated to the parallel throttle I and limited to the nominal current. By igniting the Antiparallel thyristors T1 and T2 can also only part of the inductance I can be switched into the circuit for current damping.

After the sub-transient and / or transient compensation process has subsided or after the voltage returns on the faulty generator side, the inductance I completely or partially bridged by ignition signals to the thyristors of the switch. These signals are output by the monitoring unit Ü.

Alternatively, a phase measuring device is available as a phasing and synchronizing device provided after the continuation of the short circuit and voltage recovery the phase position of the voltages in the generator groups is determined and in the event of phase equality supplies an output signal to the monitoring device Ü, the ignition signals the main thyristors TH there.

The inductive resistance switched on in the busbar is limited the current flowing to the trunk in a generator group. Due to the inductive resistance the generator groups are partially coupled, so that a phase shift takes place because the current balancing the Laatwinkel of the generator groups in opposite directions runs. The phase measuring device gives in the case of phase equality in the same phases the generator groups send a signal to the monitoring device for outputting a Ignition signal. Since the coupling of the networks takes place within a few P sec, it is not necessary to take account of switch operating times.

This arrangement also enables the generator groups to be roughly synchronized possible if, after closing the coupling switch K, the voltage is in one phase of the Generator groups wakes up and sends a corresponding signal the thyristor switch can be ignited at the monitoring device.

Instead of the inductance shown in Figure 1, nech Figure 2 an ohmic resistor R can be placed parallel to the main thyristor circuits. This resistance R is then to be dimensioned so that the moment load of the direct Generators affected by the short circuit are approximately equal to the moment load of the Generators are that feed the short circuit via the ohmic resistance. The even one Acting on the generators ensures that the load angle of the short circuit The power generators involved in the process do not diverge during the balancing processes and thus jeopardize continued synchronous operation.

As it is due to larger relative deviations of the load angles from each other coarser equalization processes can also occur between the generator groups, is a switch-off signal during these processes up to the start of the generators not desired by the current limit indicator. After bridging the ohmic resistance R or inductance 1 by triggering the circuit breaker are time-dependent of the Current limit value temporarily increased or the current limit value transmitter blocked. Time dependent the current limit value is released again. At this point are the generators did not step in because of any unforeseen influences the relative The position of the Laatwinkel to one another does not allow synchronous continuation the pending current fluctuations are recorded by the limit indicator, and when the Current limit value of the electronic circuit breaker money eight. The resistance R or inductance I then dampen the equalization processes until the monitoring device Ü a signal proportional to the decayed current value for the separation of the oscillating Generator group outputs.

In order to charge the extinguishing capacitors CL in the extinguishing circuits of the electronic circuit breaker regardless of external voltage sources and still ensure a secure charging can be according to Fig. 3 Isolation transformers m3, m4 or m5, m6 are provided by both generator groups are fed and each assigned a half-wave rectifier D3, D4 or D5, D6 are.

The above-described electronic circuit breaker ELS with anti-parallel Main thyristors only need to be used in (n-l) phases in neutral networks to become. According to FIG. 4, circuit breakers are only arranged in the R and T phases while phase S remains switch-free.

If, on the other hand, there are networks with a star point Mp brought out, then According to FIG. 5, a switch ELS is to be provided in each phase R, S and T. The star point conductor Mp remains switch-free.

If, on the other hand, an electronic circuit breaker is used, its antiparallel thyristor is replaced by an antiparallel diode D, so is at such a switch in every phase and in the neutral point conductor for every network configuration to be provided.

Figures 6 and 7 show corresponding examples.

Claims (13)

PATENT CLAIMS 1. Device for protection against short circuits in on-board networks high performance, with several generators grouped together on one Work on the busbar to which the noise eliminators are connected, with the An electronic circuit breaker busbar between the generator groups is arranged, which responds when a permissible transfer current is exceeded and the current commutates to a parallel resistor or a parallel inductance p characterized in that the circuit breaker is timed after it has decayed of the sub-transient equalization process and / or an inductive one after voltage recovery Parallel resistor, which is a tap with an @ntiparallel thyristor arrangement has completely or by ignition and extinguishing signals from a monitoring device partially bridged or completely disconnects an ohmic parallel resistor, and that a phase measuring device is provided which, after short-circuit progression and voltage recovery determines the phase position of the voltages in the generator groups for phase equality via the monitoring device, the @@@@ thyristors of the Circuit breaker fires. 2. Device according to claim 1, characterized in that after subsiding of the sub-transient equalization process the circuit breaker remains deleted and only the thyristors are triggered which are connected to a part of the parallel inductive; at are connected in series. 3. Device according to claim 1, characterized in that after ignition of the circuit breaker and after bridging the parallel resistance or the parallel inductance the current limit is temporarily increased as a function of a time signal. 4. Device according to Anapruch 1, characterized in that after ignition of the circuit breaker and bridging the parallel resistance or the parallel inductance the current limit value is temporarily blocked depending on a time signal. 5. Device according to claims 1, 3 and 4, characterized in that that the monitoring device after the short-circuit continuation and ignition of the Circuit breaker detects current fluctuations when the current limit value is reached and after the time signal has expired, a clear signal for the circuit breaker is released, whereby the parallel resistor or the parallel throttle is coupled in for current damping will 6. Device according to claims 1 and 5, characterized in that the Monitoring device after the current damping is proportional to the current value Outputs a signal to switch off the oscillating generator group. 7. Device according to claim 1, characterized in that after closure a coupling switch by monitoring the phase voltages of the generator groups and ignition of the thyristor switch, synchronization takes place. 8. Device according to claim 1, characterized by such a dimensioning of the parallel ohmic resistance that the torque load of the short circuit directly feeding generators is almost the same as that of the short circuit Generators feeding the resistor. 9. Device according to claim 1, characterized in that the two Generator groups to which a circuit breaker is assigned, the Ldschkondenaator Charge in the circuit breaker's quenching circuit via isolating transformers, in their Secondary circuit a one-way rectification is provided in each case. 10. Device according to claim 1, characterized in that a circuit breaker with anti-parallel main thyristors only in (n-1) phases of a star point-free Network is arranged. 11. Device according to claim 1, characterized in that a circuit breaker with antiparallel main thyristors in networks with a star point in each phase is provided. 12. Device according to claim 1, characterized in that a circuit breaker with main thyristor and anti-parallel diode in each phase of a star point-free Network is used. 13. Device according to claim 1, characterized in that a circuit breaker with main thyristor and anti-parallel diode in networks with lead-out star point is arranged in each phase and in the neutral point conductor.