WO2013159981A1

WO2013159981A1 - Earth-fault system

Info

Publication number: WO2013159981A1
Application number: PCT/EP2013/054926
Authority: WO
Inventors: Junliang WU
Original assignee: Maschinenfabrik Reinhausen Gmbh
Priority date: 2012-04-27
Filing date: 2013-03-12
Publication date: 2013-10-31
Also published as: CN203690912U; DE102012103735A1; DE202012012810U1

Abstract

The invention discloses an earth-fault system, in which an earth fault can be established by means of a control device on the basis of measurement data. The control device then determines a value of an inductance of an earth-fault coil of the earth-fault system, said value being the most suitable for earth-fault compensation, and sends a corresponding control signal to a semiconductor stepped switch of the earth-fault system, said switch connecting or disconnecting winding sections of the earth-fault coil by virtue of semiconductor switching elements in line with the control signal, in order to set the predefined value of the inductance of the earth-fault coil.

Description

Ground fault system

The invention relates to a ground fault system for an electricity grid. In particular, the invention relates to such a ground fault system, with which a ground fault can be detected and compensated by automatic selection and adjustment of a suitable inductance of a ground fault coil.

Electricity networks can lead to unwanted conductive connections between an electrical conductor of the electricity grid and the earth potential. In such a case one speaks of a ground fault. Among the negative consequences of such a ground fault known to those skilled in the art include disturbance of the power supply, in the case of three-phase networks voltage overshoots (in relation to ground) of the phases which are not in electrical contact with the ground potential, and the formation of

Electric arc. In order to limit the effects of such negative consequences, ground-fault coils, also known as Petersen coils, are used in a known manner. The basic principle of their effect is to compensate for the capacitive reactive currents occurring during an earth fault by means of inductive reactive currents; The capacitive reactive currents arise here due to the capacity of the conductors of the electricity network to the environment. For this purpose, the inductance of the ground fault coil must be matched to the capacity of the affected network or network section, i. while in practice an overvoltage at the neutral point by a

Overcompensation during normal operation is avoided, the tuning influences the effect of the compensation in case of an earth fault. The relevant capacity of the

However, the affected network or network section depends on the location of the network

Ground fault within the network. It is now possible, for example, to specify a value of the inductance for a ground-fault coil which is sufficiently suitable for achieving a sufficient compensation for each value from the capacitance range which can occur in the event of a ground fault in the relevant network. Alternatively, the inductance of the ground-fault coil can be changed via a tap-changer with servomotor, and thus adapted to the capacity present in a specific case of a ground fault. On the one hand, this requires one

Tap changer with servomotor, which are susceptible to wear devices, on the other take the mechanical switching operations in the tap changer for a certain amount of time, in particular, the inductance of the ground fault coil can only be changed gradually, and it must sometimes with the respective

Stepper switch possible values of the inductance of the ground fault coil be tried until the desired ground fault compensation is achieved. The object of the invention is therefore to provide a ground fault system with which an occurring ground fault in an electricity grid can be compensated quickly and specifically. The system should also be designed wear, so in particular work reliably over long periods of operation. This object is achieved by a ground fault system according to claim 1.

The earth fault system according to the invention comprises at least one ground fault coil, a control device and a semiconductor tap changer for the ground fault coil. It is also possible for the control device to determine a value of an inductance of the at least one ground fault coil that is most suitable for compensating the ground fault. The possible values of

Inductance of the at least one ground fault coil depend on the Erdschlussspule itself, but also on the semiconductor tap changer, with the values of the

Inductance of Erdschlussspule are selectable. The semiconductor tap changer is controllable by the control device. When a ground fault occurs, the

Control device under the possible with the semiconductor tap changer

Inductance values of the ground fault coil the most suitable value for compensation of the ground fault, and sends a control signal to the semiconductor tap changer to cause the setting of this selected inductance value.

In this way, it is no longer necessary to try different inductance values or a desired inductance value in several

Switching operations of a tap changer stepwise to set, but the appropriate inductance value is set directly. Since the semiconductor tap changer without

mechanical parts, its wear resistance is reduced compared to a mechanical tap changer. Since the switching times of an electronic switch as it is the semiconductor tap changer, are much shorter than the

Switching times of a mechanical tap changer, and a direct as opposed to a gradual adjustment of the required inductance is possible, is the Setting the required inductance in less time than with a

mechanical tap-changer possible.

In preferred embodiments of the ground fault system, the ground fault coil has a plurality of taps. Accordingly, a semiconductor switching element is provided in the semiconductor tap changer for each tap of Erdschlussspule through which the respective tap is switched on or off. The connection or disconnection of a tap is controlled by the controller. By turning on or off a tap is effective in the electricity grid inductance of

Ground fault coil changed.

In embodiments of the ground fault system, it may be in the

Semiconductor switching elements act around thyristors. In other embodiments, insulated gate bipolar transistors (IGBTs) may be used

Semiconductor switching elements are used.

Furthermore, the invention and its advantages will be described in more detail with reference to the accompanying drawings. 1 shows a schematic representation of the ground fault system in a

Electricity network, and

FIG. 2 shows a schematic representation of the ground-fault coil, of the semiconductor

Tap changer and the control device. In the figures, identical or identical elements are identical

Reference numeral used.

Figure 1 shows a schematic representation of the ground fault system 1 according to the invention in an electricity network 2, of which only symbolically three of a

Transformer 6 outgoing conductors 21 are shown, it is in the

represented electricity network 2 to a three-phase network. A star point of the

Electricity network 2, here in the transformer 6, is connected via a ground-fault coil 3 to a ground potential 8. The earth leakage coil 3 is assigned to a semiconductor tap changer 5. The ground fault system 1 further comprises a control device 4 for determining a ground fault on the basis of measured data, determination of a suitable Value of the inductance of the earth leakage coil 3 to compensate for the ground fault, and the corresponding control of the semiconductor tap changer 5, as already discussed above. Furthermore, the capacity 24 of the lines 21 is indicated relative to the environment. The capacitive reactive currents occurring due to such a capacitance in the case of an earth fault are to be replaced by an inductive reactive current through the

Erdschlussspule 3 can be compensated.

Figure 2 is a schematic representation of the Erdschlussspule 3 with

Winding sections 32 and corresponding taps 31, the

Semiconductor stage switch 5 with semiconductor switching elements 51, and the control device 4. Each tap 31 is associated with a semiconductor switching element 51. By such a semiconductor switching element 51, the respective tap 31 can be switched on or off, whereby then a corresponding winding section 32 can be switched on or off. The switching on and off of a winding section 32 by means of a semiconductor switching element 51 is controlled by the control device 4. The connection or disconnection of a winding section 32 changes the effective in the electricity network 2 inductance of Erdschlussspule 3. It is not necessary in a semiconductor stage switch 5, winding sections 32 in turn, so according to their arrangement in the Erdschlussspule 3, turn on gradually, if more than one

Winding section to be switched on or off. Rather, it allows one

Semiconductor stage switch 5 the connection or disconnection of several winding sections 32 in a single step. As a result, the reaction times of the earth fault system according to the invention compared to a system according to the prior art are shortened. In the illustration, three winding sections 32 and correspondingly three taps 31 are shown. Of course, more than three winding sections 32 or only two winding sections 32 may be provided, each with corresponding taps 31. Also indicated are the transformer 6 and the ground potential 8 in order to clarify the reference to FIG.

The invention has been described with reference to preferred embodiments

described. However, it will be understood by those skilled in the art that changes and modifications may be made without departing from the scope of the invention

to leave the following claims.

Claims

claims

1 . Ground fault system (1) for an electricity network (2), comprising at least one ground-fault coil (3),

marked by

a control device (4),

by which a ground fault can be determined on the basis of measured data and a suitable inductance for compensation of the ground fault current can be determined,

and by a semiconductor tap changer (5) for the at least one

Ground fault coil (3), which is controllable by the control device (4).

2. The ground fault system (1) according to claim 1, wherein the earth leakage coil (3) has a plurality of taps (31), and the semiconductor tap changer (5) for each tap (31) of the Erdschlussspule (3) a semiconductor switching element (51 ), by which the respective tap (31) is switched on or off.

3. Ground fault system (1) according to claim 2, wherein at least one

Semiconductor switching element (51) is a thyristor or an IGBT (bipolar transistor with insulated gate electrode.

4. Ground fault system according to claim 2 or 3, wherein the operation of the tap changer without motor drive is feasible.