HUP0900619A2 - Protecting method and device for three-phase electric power networks - Google Patents

Description

PUBLICATION COPY

6945R $0900619

Protection method and equipment for three-phase electrical networks

The invention relates to a protection method and circuit for a three-phase electrical network. The invention relates to a method and circuit that enables the minimization of the neutral point voltage of medium-voltage overhead line networks, even with adequate earth fault protection.

The continuous smooth operation of electrical networks is most often disrupted by short circuits. A short circuit is a shunt fault in the network caused by the breakdown or metallic shunting of the insulation between different phase conductors of the network or between the phase conductor and the ground or grounded neutral conductor. Among the elements of electrical energy transmission, short circuits most often occur in overhead line networks. The most common causes are lightning strikes, wire breakage, shocks and insulator bridges.

The grounding of a phase in non-rigidly grounded networks is called an earth fault. In networks with an insulated star point, i.e. networks with a non-directly grounded star point, single-phase earth faults do not require immediate shutdown because the earth fault current that occurs is small. Despite the earth fault, the energy supply can be maintained for a longer or shorter period of time, and even with compensation, the majority of the so-called arcing faults, which account for the majority of earth faults, can be eliminated without disrupting the operation.

An arcing fault occurs when one of the phases contacts the ground (a point at ground potential) through an arc. Practice shows that the arc cannot be sustained at a ground fault current of less than 5 A, therefore the goal is to reduce the ground fault current to this level.

-2The star point potential of the network is determined by the symmetry of the phase-by-phase earth capacitances and terminations of each transmission line and the way the star point is handled.

A commonly known and applied technique in the field is the so-called earth fault compensation. The aim of earth fault compensation is to reduce the short-circuit fault current to a value such that the arcing fault cannot persist by establishing parallel resonance. One commonly used method of implementation is to earth the star point via an inductance (Petersen coil).

In the event of an earth fault, voltage appears on the transformer star point and the winding connected to the earth. The inductive current flowing as a result of this is closed through the short-circuited phase, the fault location and the earth and is delayed by 90° compared to the star point voltage. The direction of le determined by the capacitive earth fault network and l _L determined by the inductance are opposite. Therefore, if their magnitudes are equal, their resultant is zero, i.e. no current flows at the fault location. The inductance of the compensating winding (arcing coil) should therefore theoretically be chosen so that L = le.

The resulting inductance of the earth fault compensation device(s) and the resulting earth capacitance of the network form a parallel resonant circuit during an earth fault. Resonance compensation is the compensation state when the compensating current l _L at the earth fault location is equal to the current to be compensated l _c . However, this resonance compensated state cannot be permanently produced or maintained under operating conditions due to the harmful overvoltages that may occur. The compensated state at resonance or close to resonance is hereinafter referred to as the normal compensated state.

Since the networks compensated as above are grounded via an arc-quenching coil, their star point voltage is determined by the product of the ground capacitances and the leads. The network can operate safely if the star point voltage is as low as possible, because an increase in the star point voltage always entails an increased risk of ground faults in one or two phases.

-3The different earth capacitances of the individual phases of medium-voltage overhead line networks cause so-called zero-sequence asymmetry. This causes a voltage increase at the star point, which is a particularly big problem recently, because the automatic regulation of the arc extinguishing coils regularly passes through the resonance point and this already leads to an unacceptably high voltage increase. The desired l _L = le regulation cannot therefore be achieved, but the so-called overcompensation is implemented so that the voltage at the star point is small.

Overcompensation is the compensation state when the current to be compensated at the ground _fault location is greater than the current to be compensated.

Another solution is to connect the star point to ground with an ohmic resistor, which, however, results in significant losses and must be switched off in the event of a ground fault.

An arc extinguishing coil with adjustable inductance is described, for example, in Hungarian patent specification No. 149 536. Publication document WO 2008/116428 A2 describes a solution where, in the event of a ground fault being detected, the sensitivity of the protection circuit is increased by a resistor connected to the auxiliary coil of the arc extinguishing coil.

Figure 1 shows a simplified circuit illustrating a known solution for compensation, in which Uf is the phase voltage, Co is the total capacitance of the network, Ro is the total resistance of the leads, L is the instantaneous inductance of the arc extinguishing coil, and ACo is the excess zero-sequence capacitance of the network. If an earth fault occurs, then the AC ₀ capacitance is replaced by a short circuit and the earth fault current at the earth fault location will be proportional to the current flowing through the parallel resonant circuit L and Co. If the resonant circuit is tuned to around 50 Hz, then this current will be very small and thus the arc will cease; this is the process of arc extinguishing. However, the exact 50 Hz tuning cannot be maintained because the circuit is constantly powered by the AC ₀ zero-sequence capacitance and when tuned precisely, the high impedance will result in a high zero-sequence voltage U _o . To prevent this from happening, the inductance is always set to a lower value, i.e. overcompensation is used, so the circuit becomes slightly inductive. However, overcompensation significantly worsens the arc extinguishing conditions. When regulating the inductance of the arc extinguishing coil, a transition through resonance is inevitable, in which case a large

-4 star point voltage is generated, which increases the risk of short circuit. The known compensation and regulation are slow, therefore endangering the network for a long time.

Most of the overhead line networks are therefore equipped with an arc extinguishing (Petersen) coil, because in this way a significant part of the earth faults are automatically eliminated by setting them around the 50 Hz resonance. However, this tuning results in a high impedance of the parallel resonant circuit. The high impedance has a good effect on the earth fault protection, but at the same time it is a problem during operation if the zero-sequence asymmetry is high, because it increases the star point voltage, which in turn increases the number of earth faults. The problem is contradictory, because a good protection setting increases the number of earth faults, and vice versa, as the number of faults decreases, the protection efficiency deteriorates.

Therefore, the need arose for a solution in which the star point voltage could be kept close to zero while also ensuring effective compensation.

The object of the invention is therefore to provide a method and apparatus for a three-phase electrical network, which ensures effective compensation and at the same time keeps the neutral point voltage close to zero. A further object of the invention is to provide a simple, fast and safe protection method and apparatus, which is free from the disadvantages of the prior art solutions.

The object of the invention is achieved by a protection method according to claim 1 and a protection device according to claim 7. Preferred embodiments are defined in the subclaims.

Preferred embodiments of the invention are described hereinafter with reference to the drawings, in which:

Figure 1 is a simplified circuit diagram illustrating compensation, and the

Figure 2 is a schematic diagram of a protective device according to the invention.

As shown in Figure 2, the exemplary protection device for a three-phase electrical network 10 according to the invention includes an inductive device 13 connected between the neutral point 11 and the ground, capable of creating an overcompensated state.

-5. The device further comprises a sensor device 16 for detecting the occurrence of an earth fault current on the inductive device 13, a switching device 18 controlled based on the signal of the sensor device 16, and an additional inductance 19 that can be switched off by the switching device 18 in order to increase the inductance of the inductive device 13 in the event of an earth fault current and thereby create a normal compensated state. The switching device 18 is preferably designed as an electronic switch.

The inductive device 13 is preferably designed as an arc extinguishing coil 14 provided with an auxiliary coil 15. The sensing device 16 is preferably a voltage transmitter in inductive connection with the arc extinguishing coil 14, and the additional inductance 19 is an additional coil suitable for controllable connection with the auxiliary coil 15 of the arc extinguishing coil 14.

The device further comprises a control unit 17 which receives the voltage signal and, in the event of an earth fault, disconnects the additional inductance 19 from the auxiliary coil 15 by means of the switching device 18. With the additional inductance 19 disconnected, the inductance of the inductive device 13 is selected in a normal, i.e. resonant or near-resonant compensating manner, thus achieving an effective arc extinguishing effect. When the earth fault is eliminated, the additional inductance 19 is reconnected to the auxiliary coil 15 by means of the switching device 18, and thus the overcompensated state is restored with the reduced total inductance. The restored overcompensation ensures that the neutral point voltage remains close to zero. The switching is preferably carried out during a half-period in such a way that the switching is carried out at a zero crossing. This allows us to limit the switching to those times when no current flows in the auxiliary coil.

In the protection method according to the invention, an overcompensated state is created by grounding the star point 11 through the inductive device 13. In the event of a ground fault, the overcompensated state is eliminated to create a normal compensated state by disconnecting the additional inductance 19 from the auxiliary coil 15, and in the event of the ground fault being eliminated, the

-6The overcompensated state is restored by reconnecting the additional inductance 19.

In the event of an earth fault, the overcompensated state is preferably eliminated within half a period, and the elimination and/or restoration of the overcompensated state is performed at a zero crossing.

The method and apparatus according to the invention preferably create an overcompensated state characterized by a residual current of 10-20 A and a normal compensated state characterized by a residual current of less than 5 A. The residual current (the fault current) is the effective value of the earth fault current occurring in the earth fault compensated network.

By quickly controlling the arc extinguishing (Petersen) coil 14, a low value of the star point voltage can be achieved in such a way that the additional shunt inductance 19 is connected to the auxiliary coil 15 of the coil, which is suitably tuned to resonance. This makes the zero-sequence impedance highly inductive and small, which keeps the voltage of the star point 11 at a low value. The extinguishing capacity of the Petersen coil is greatly reduced in the overcompensated state, therefore in the event of an earth fault, the shunt inductance is disconnected within 10 ms. Thus, with the increased extinguishing capacity, the fault is eliminated and the star point 11 reaches the low value again by switching on the additional inductance 19.

It can be seen that the method and apparatus according to the invention are excellently suited to achieving the set goals, since the effectiveness of the arc extinguishing coil is maintained while keeping the star point voltage low.

The invention is of course not limited to the preferred embodiments described in detail, but further variations, modifications and developments are also possible within the scope of protection defined by the claims.

Claims (9)

-7- · : : · .·' • · · · · ···· ·· ···· Patent claims 1. A protection method for a three-phase electrical network (10), in which an overcompensated state is created by grounding a star point (11) through an inductive device (13), characterized in that in the event of an earth fault, the overcompensated state is eliminated to create a normal compensated state, and in the event of the earth fault being eliminated, the overcompensated state is restored. 2. The method according to claim 1, characterized in that in the event of a ground fault, the overcompensated state is eliminated within half a period. 3. The method according to claim 1 or 2, characterized in that the termination and/or resetting of the overcompensated state is performed at a zero crossing. 4. The method according to any one of claims 1-3, characterized in that an overcompensated state characterized by a residual current of 10-20 A and a normal compensated state characterized by a residual current of less than 5 A are created. 5. The method according to any one of claims 1-4, characterized in that the inductive device (13) is an arc extinguishing coil (14) provided with an auxiliary coil (15), to which auxiliary coil (15) an additional inductance (19) ensuring the overcompensated state is connected, the occurrence of a ground fault on the arc extinguishing coil (14) is detected by a voltage sensor, based on the detection, the additional inductance (19) is disconnected from the auxiliary coil (15), and then, in the event of the ground fault being eliminated, the additional inductance (19) is reconnected to the auxiliary coil (15). 6. The method according to claim 5, characterized in that the additional inductance (19) is an additional coil controllably connected to the auxiliary coil (15) of the arc extinguishing coil (14). 7. Protective device for a three-phase electrical network (10), which is suitable for creating an overcompensated state connected between a star point (11) and ground -8inductive device (13), characterized in that it further comprises - a device (16) for detecting the occurrence of an earth fault current on the inductive device (13), - a switching device (18) controlled based on the signal of the detection device (16), and - an additional inductance (19) that can be switched by the switching device (18) to increase the inductance of the inductive device (13) in the event of an earth fault current and thereby create a normal compensated state. 8. The device according to claim 7, characterized in that the inductive device (13) is an arc extinguishing coil (14) provided with an auxiliary coil (15), the sensing device (16) is a voltage transmitter in inductive connection with the arc extinguishing coil (14), and the additional inductance (19) is an additional coil suitable for controllable connection with the arc extinguishing coil (14) auxiliary coil (15). 9. The device according to claim 8, characterized in that it comprises a control unit (17) receiving the voltage transmitter signal and ensuring switching during the half-cycle, at the zero crossing. (2 sheets of drawings, 2 figures)