DE2911169A1 - Multiple network earth compensating system - has earthing coils connected by voltage monitoring circuits and selector to central control unit - Google Patents

Abstract

The earth connection compensating system for more than one mains supply, has the variable inductance earthing coils of the high voltage transformers of, e. g. two supplies, connected to the coils of respective controllers. These are in turn connected to a main control unit located at a central control print. This has further input/output connections for switching units connected to opposite sides of the two sets of earth ing coils. Each earthing coil is also connected to a voltage monitoring circuit to give the instantaneous value of the switching voltage. Their outputs are connected by a selector stage to the input of the main control unit, and there is a return path for each monitor from the main control unit. The unit then compensates the two supplies until a balanced condition is reached.

Description

Ground fault compensation regulation for

multiple networks The invention relates to a ground fault compensation system according to the generic term of claim 1.

Malfunctions in the electrical power supply have in the Most of the cases originate in a so-called earth fault. As a means of Prevention of the effects of earth faults in medium and high voltage networks earth fault compensation has proven itself »for decades. One understands it the connection of one or more network star points with earth via low-loss Earth fault coils, the inductances of which are matched to the network capacitance with respect to earth are. The criterion that the Resonant frequency of the - from the inductances of the coil or coils with the network earth capacitance - resonant circuit is the same as the mains frequency (resonance method).

The neutral point earth voltage is useful for recognizing the resonance tuning - also called displacement stress - as a coordination criterion at. When the network is free from earth faults, this displacement voltage is dependent on the inductance or the setting of the earth fault coil and achieved in the earth fault free State of the network in the case of resonance, i.e. with precise coordination of the earth fault coil on the conductor-earth capacities of the network, a maximum; the displacement voltage changes thus depending on the setting of the earth fault coil according to a resonance curve.

For automatic setting of the earth fault coil or coils on the correct inductance value, resonance regulators are used in a known manner. The actual value for this controller is the displacement voltage from the voltage converter the earth fault coil or from a separate set of voltage transformers in the network to the controller is fed. Since the networks are often not precisely tuned to the response, an arrangement is provided in the controller, which after detection of the maximum one Detuning of the earth fault coil executes over- or under-compensation.

Equipping the networks with resonance regulators is known such that there is always only one resonance regulator in each galvanically connected network is provided, which may also have several earth fault coils that are the same in this network or are connected to different star points.

With today's endeavors to manage several networks centrally, namely from so-called control centers, district control rooms or the like, is the known one Equipping the networks with one resonance controller each is relatively expensive.

The invention is based on the task of reducing this effort. This problem is solved according to the characterizing features of the claim 1.

With the help of the inventive ground fault compensation control for several networks, it is possible to have several networks with relatively little effort to regulate. Only a single, central controller is necessary, whereby the voltage monitoring circuits, which are each assigned to a network, no special effort compared to represent a controller and with the current state of communication In network automation, the transmission of the necessary information and setting values means no-special problems, i.e. the flow of information from the already existing ones Plant can be carried out.

Based on an embodiment shown in the drawing the invention is explained in more detail.

The drawing shows this on one side of the high voltage transformer Trl connected network Ni and also on one side of the high-voltage transformer Tr2 connected network N2. There is an earth fault coil at the neutral point of the transformer Trl Spl (further coils can be connected in parallel); accordingly lies at the star point of the transformer Tr2 a ground fault coil Sp2. From the voltage transformer of the earth fault coil Spl or from a separate set of voltage transformers in network N1 is the displacement voltage UEM1 accepted. The displacement voltage UEM2 is taken accordingly in network N2. Both earth fault coils have setting arrangements for changing their inductance values.

Two networks N1 and N2 are shown in the drawing. It understands that the number of networks is not limited in principle, i.e. it can more than two networks can also be provided.

Usually, the networks N1 and N2 by the coils Spl and Sp2 regulated by one controller each.

According to the invention, a is for all networks in question Gemeißsamer controller R provided, which in the example shown in the center Z, i.e. is located in a central control room or the like. From the principle However, this is not necessary, the controller can be located anywhere, e.g. also in the control room of a network, at a separate, special common location or similar.

The controller R has an input-side switchover arrangement at the controller input RE UE and an output-side switching arrangement UA at the controller output RA. Of the On the input-side switching arrangement, the two offset voltages UEM1 and UEM2 supplied. The output-side switching arrangement is both with the adjusting device the earth fault coil Spl as well as that of the earth fault coil Sp2.

The switching arrangements are constructed and indicated by the dashed line, interconnected so that either the displacement voltage UEM1 at the controller input RE and the ground fault coil Splam controller output RA or the Displacement voltage UEM2 at the controller input RE and the earth fault coil Sp2 at the controller output RA or the controller is switched off.

A voltage monitoring circuit is provided for each network. Thus, the network N1 is the voltage monitoring circuit Flush and the network 2 is the voltage monitoring circuit SpÜ2 assigned. The circuit SpU1 receives the displacement voltage as an input voltage UEM1 "whereas the circuit Sp02, the displacement voltage UEM2 of the network N2 as Input variable receives. These voltage monitoring circuits slha'So'ahfljbaut. that they check the instantaneous value of the displacement voltage to determine whether it lies in a specified voltage range (with this range monitoring the phase position with respect to a reference variable can also be supplied as an undrelation can) and they emit a signal at their output when this range is left for a certain time, which is indicative of the fact that the assigned Network is no longer tuned, i.e. has to be retuned by controller R. The output signals of the voltage monitoring circuits are a selection stage AW supplied to the controller R and the switching arrangements at the input and output connected is. In this selection circuit, the output signals of the voltage monitoring circuits, if they should occur simultaneously, stored, and one after the other to the controller or fed to the switching arrangements. The output signals of the voltage monitoring circuits thus represent, as it were, controller request signals.

The voltage monitoring circuits can have known arrangements being constructed. In particular, they contain a memory for the voltage, its Voltage always corresponds to the assigned displacement voltage. Threshold levels, which monitor the storage voltage in a given range over time still provided.

The voltage monitoring circuits are via a line L1 or L2 SpUl or SpÜ2 connected to the controller in such a way that the controller, if it has a network matched, he the assigned voltage monitoring circuit via the assigned line turns off. This shutdown can be done in such a way that it is both the input side as well as separating the output side by a corresponding switch; expedient However, this shutdown is made so that only the output-side line is separated, which leads to the selection stage AW, so that the assigned The displacement voltage is still present at the voltage monitoring circuit, see above that when removing the switch-off signal on the assigned line L, i.e. when Switching on the voltage monitoring circuit after the network has been regulated the regulator R, the memory of the voltage monitoring circuit immediately the regulated Value of the displacement voltage.

The voltage monitoring circuits can each be assigned on site Network be arranged; in this case an information transfer between Controller deployment location and the assigned network with regard to the signals for the shutdown the voltage monitoring circuit and the output signal of the voltage monitoring circuits, the controller request signal are created. It is therefore more useful to use the Voltage monitoring circuits in the vicinity of the controller, i.e. in the illustrated Example in the control center, because then only the displacement voltage is transmitted which has to be transferred anyway for the controller or in general is displayed in a central control center anyway. In addition, there are the accommodation options as well as the possibilities for service and monitoring in the headquarters better than on site. In addition, for example, the supply voltage of the controller in the Voltage monitoring circuit can be used for supply.

-The transfer of information between the headquarters and the individual Networking can be done using known methods of telecontrol technology or using separate cables taking place, h. the telecontrol systems that are already present in the network management can be used for this purpose can also be used.

The mode of action of the classification shown in the drawing is the following: A state is to be assumed in which both networks are disconnected ' Right are, if necessary taking into account the over- or under-compensation, i.e. the two Earth fault coils Spl and Sp2 are on the corresponding correct inductance value set. In this operating position, which may be retained for several weeks, is the controller by a corresponding position of the switching arrangements UA and UE separated from the networks or switched off. The voltage monitoring circuit assigned to each network on the other hand, it is constantly connected to the assigned displacement voltage and monitored these. It is now assumed that the network Nl is detuned, i.e. the assigned Displacement voltage UEM1 that specified in the flush voltage monitoring circuit Leaves setpoint range. The voltage monitoring circuit then indicates SpÜl their output via the selection stage Aw a signal to the controller R, which this controller switches on and actuates the switching arrangements in such a way that the controller R is on the input side with the displacement voltage UEM1 and on the output side with the earth fault coil Spl connected, i.e. fully assigned to network N1. At the same time, the Line L1 switched off the voltage monitoring circuit SpÜl. The regulator is correct now in the usual way the network N1 again to the correct value and switches If this coordination has taken place, automatically withdraw or use the line L1 the voltage monitoring circuit SpÜl in operation again.

The process takes place in the same way if the network N2 is out of tune so that this case no longer needs to be dealt with separately.

The formation of the stages shown can be based on the specified Functions that have these levels by an electronically trained professional can be carried out without further ado; numerous corresponding ones are available to those skilled in the art known circuits are available.

The selection circuit AW can also be constructed so that they Controller request signals, if they are present at the same time, not one after the other intrudes, but that it also carries out an assessment with regard to the priority; For example, it is conceivable that the network that is operationally most important comes first is voted.

Since the networks are seldom readjusted as a rule, and one at the same time When upset is even less common, the question of priority is practical not so meaningful.

Claims (5)

Claims C Ground fault compensation control for several networks according to the resonance principle, in each of which there is at least one adjustable earth fault coil for the coordination of the network is provided and of each of which the displacement voltage is derived as a tuning criterion for the control, thereby g e k e n It is clear that each network (N1, N2) has a voltage monitoring circuit (pol, SpÜ2), each of the assigned displacement voltage outputting a Controller request signal monitors whether it has a voltage range for leaves a specified time, and all networks have a common resonance controller (R) is assigned, which is due to a controller request signal on the input side the displacement voltage and can be switched on the output side to the earth fault coil of the network whose associated voltage monitoring circuit is the controller request signal generated. 2. Earth fault compensation control according to claim 1, characterized in that that the resonance regulator (R) and the voltage monitoring circuits (Sp01, SpU2) are arranged in a central network management control center (Z): 3. Ground fault compensation control according to claim 1 or claim 2, since {iurch characterized in that between the resonance regulator and the voltage monitoring circuits there is a connection (4, L2) via which the associated voltage monitoring circuit can be switched off when the resonance regulator with that of the voltage monitoring circuit in question associated network is connected. 4th Ground fault compensation control according to one of Claims 1 to 3, d a d u r c h e k.e n n z e i c h n e t that at the input and output of the resonance controller Switching arrangements (UE> UA) are provided via which the controller input or -output optionally with the displacement voltages or earth fault coils of the individual Networks can be connected or switched off. 5. Ground fault compensation control according to one of Claims 1 to 4, characterized characterized in that a selection circuit (AW) is provided on which all outputs of the voltage monitoring circuits, i.e. all controller request signals switched and which is designed in such a way that it sends the individual controller request signals one after the other switches to the resonance controller.