NO854791L - SYSTEM FOR COMPENSATION OF CAPACITY AND ACTIVE EARTH CURRENTS. - Google Patents

Abstract

The invention solves the problem of designing a. system that enables lowering of earth short-circuit currents and shock currents for humans. by a single-phase shock below the self-tripping limit in AC mains with a. isolated neutral point. The working winding of an induction unit (1) is. connected between an artificial mesh neutral point (2). and ground, and auxiliary windings are connected to the input and output of an impedance converter amplifier (3). The first output of a control unit (4) is connected to the impedance converter's amplifier (3), and the second output is connected. to the induction unit (1), and the input of the control unit (4) is connected to the output of a. control measuring unit (5) connected between the mains. and soil. In addition, a third output at con-. in case of a fault in a phase, the control measuring unit (5) causes a signal supply to the control unit (4) which generates a signal for regulating the induction unit (1) and the impedance converter amplifier (3). A change in the inductance in the induction unit (1) resonates with the resultant inductance of the mains, whereby the capacitance component in the current of the fault phase is compensated. A change in the positive feedback coefficient of the impedance converter amplifier (3) which, through the auxiliary winding in the induction unit (1) acts on its working winding, compensates the active component of the current in the fault phase.

Description

The present invention relates to a system for compensating capacitive and active earth currents by lowering the impedance of a phase which is due to a fault in an electrical three-phase alternating current network which has an isolated neutral point. The invention finds application in compensating single-phase short-circuit currents and single-phase current at a fault due to impedance having a constant or non-linearly varying value.

Those skilled in the art are aware from Polish patent no. 92,151 of a system for compensating capacitive earth currents, consisting of an artificial short-circuit block which is connected in series with the current coil of a directive relay, and the voltage coil of said relay is connected in parallel with a choke which has a adjustable air gap. The throttle is connected in series with an earthed blocking capacitor and the contacts on the directive relay are connected in a drive unit circuit which is mechanically connected to the throttle. The artificial short circuit block is switched on and off by means of the executing relay in the programming timer unit at time intervals programmed by the system user. The system's operating principle is based on a cyclic change of the choke's inductance to the value where the capacitive earth currents are compensated.

The significant disadvantage of the above-mentioned system is the necessity of grounding one of the network's working lines while compensating for capacitive earth currents, which creates the possibility of an electric shock hazard.

Those skilled in the art know from Polish Patent No. 103,180 a system for compensating capacitive earth currents, comprising a measuring block whose output is connected to the input of a control block. The system is equipped with a magnetic amplifier whose working winding is connected in parallel with the input of the measuring block and is connected between earth and the neutral point of the network, and the control winding in the magnetic amplifier is connected to the output of the executive element in the regulation block. The use of the amplifier eliminates the necessity of grounding the network's working line while compensating the capacitive ground currents, which reduces the possibility of the electric shock risk. Compensation of capacitive earth currents occurs automatically in a continuous manner, whereby the system reacts to capacitance changes causing changes in the network's usage conditions, thereby ensuring the optimal operating parameters for this.

The significant disadvantage of the above described system is

that only the capacitive component of the earth currents is compensated, and furthermore that the system is only designed for power grids with an available neutral point.

The purpose of the present invention is to design a system which enables the lowering of earth-short-circuit currents and shock currents for people in case of single-phase shock during self-triggering in alternating current electrical networks with an isolated neutral point.

The invention satisfies the aim in such a way

that an impedance converter which is an amplifier is introduced into an induction unit, and auxiliary windings connected with the working winding in the unit, and the set thus provided is connected between an artificial neutral point in the network and earth. Next, regulation of inductance and the feedback for the amplifier in the impedance converter is carried out, the inductance in the unit being brought into resonance with the capacitance of the grid, whereby capacitive and active components in the current for the fault phase are compensated. The regulation is carried out using a voltage-current analysis of the fault phase and is compared with the limit parameters that are fed to the control measuring unit.

The system according to the invention is characterized by the fact that the working winding in the induction unit is connected between an artificial neutral point in the grid and earth, and auxiliary windings are connected to the input and output of the amplifier in the impedance converter. The first output of the control unit is connected to the amplifier in the impedance converter, and the second output is connected to the input of the induction unit which regulates its inductance, the input of the control unit being connected to the output of the control-measuring unit which is connected between the grid and ground.

According to another solution, when the network has unsymmetrical impedances in relation to earth, it is an essential feature of the invention that the third output of the control unit is also connected to a network impedance symmetry generator which is connected between the network and earth.

The solution according to the invention enables the limitation of shock for people in the form of single-phase currents in networks with an isolated neutral point by compensating the capacitive and active components below the self-triggering limit defined by the recommendations of the International Electrotechnical Committee (IEC). Due to this mentioned solution, a complementary protection against electric shocks in the network is achieved with an isolated neutral point in relation to the protective agent used.

An advantage is also that the system, which is regulated to limit the shock-forming currents, ensures the limitation of earth currents in case of single-phase short-circuits, whereby the extension of single-phase short-circuits to two- and three-phase types is limited, whereby the risk of explosion and fire is reduced .

The use of the control measuring unit allows regulation of the system without the necessity of artificial grounding, which further reduces the risk of shock. On the other hand, the use of the network impedance symmetry generator enables the operation of the system according to the invention on an unsymmetrical network with an isolated neutral point.

The invention will now be explained by means of an example,

on the basis of the system shown in the drawing, and which

shows in block diagram form the system which enables the achievement of compensations of capacitive and active earth currents.

In the system shown in the drawing, the working winding in an induction unit 1 is connected between an artificial mains neutral point 2 and ground, and auxiliary windings are connected to the input and output of the impedance converter amplifier 3. The first output of a control unit 4 is connected to the impedance converter amplifier 3, and the other output from the control unit 4 is connected to the input of the induction unit 1 for regulating its inductance. The control measuring unit 5 is connected between the grid and earth, and its output is connected to the input of the control unit 4. Moreover, the third output of the control unit 4 is connected to the input of the grid impedance symmetry generator 6 which is connected between the grid and earth.

The control measurement unit 5 used in the system is solved in such a way that it comprises a shock current control system and an earth voltage control system. The shock-current control system is a replacement impedance for the human body with the voltage-current characteristic recommended by the International Electrotechnical Committee in publication 479. The ground-voltage control system is a ground-voltage comparator and an output analyzer consisting of filters for components of symmetrical voltages and an adding amplifier, whose signals through the control unit 4 regulate the value of earth current in the fault phase.

The control unit 4 is solved in such a way that it consists of

a differentiated element that selects the minimum value of the wrong-phase voltage, and of elements that form the signals that control the induction unit 1, the amplifier of the impedance converter 3 and the impedance symmetry-former of the network 6.

If in the system according to the invention the induction unit 1 is used whose inductance is regulated by changing the size of the air gap in the core, a signal is generated in the control unit 4 which starts an adjustment device which causes the change in the said air gap size. On the other hand, using the induction unit 1 whose inductance rggule--; res by changing the magnetization current for the transducer, a signal is generated in the control unit 4, by means of which the value of said current is changed in the adjustment device.

In a symmetrical network, the resultant of the impedance for particular phases has the same value, which enables operation of the system with disconnected network impedance symmetry generator 6. Thus, the operation of the system according to the invention in

a protected symmetric net as follows. In the event of an error in one phase, the control measurement unit 5 makes a signal transmission to the control unit 4 which generates signals for regulating the induction unit 1 and the impedance converter amplifier 3. The signal sent to the induction unit causes a change in its inductance and brings it into resonance with the resultant of the network capacitance, thereby compensating the capacitive component of the current for the fault phase. On the other hand, the signal sent to the amplifier 3 of the impedance converter causes a change in the positive feedback coefficient in the amplifier which, through auxiliary windings in the induction unit 1, acts on its working winding, whereby the active component of the current in the fault phase is compensated.

In an unsymmetrical network, the resultant of the impedance for particular phases has a different value. The operation of the system according to the invention in a protected asymmetric network is as follows. The control measurement unit 5 creates a signal transmission to the control unit 4 with regard to the impedance state of the mains phases in relation to earth.

A control signal generated in the control unit 4, fed to the network's impedance symmetry generator 6, causes compensation of the impedance resultant of the network's phases in relation to earth. Further operations of the system in the event of a fault in one phase occur as in the description of the system for a protected symmetrical network.

Claims (2)

1. System for compensating capacitive and active earth currents, comprising an induction unit whose control is connected to a control block, characterized in that the working winding in the induction unit (1) is connected between an artificial mains neutral point (2) and earth, and its auxiliary windings are connected on the input and output of an impedance converter amplifier (3), the first output of a control unit (4) being connected to the impedance converter amplifier (3), the second input being connected to the input of the induction unit (1), and the input of the control unit ( 4) is connected to the output of a control-measuring unit (5) which is connected between the grid and ground. 2. System as stated in claim 1, characterized in that a third output on the control unit 4 is connected to a network impedance symmetry generator (6) which is connected between the network and earth.