SE458164B - ARRANGEMENTS TO COMPENSATE CAPACITY AND ACTIVE GROUNDINGS - Google Patents

Description

10 15 20 25 30 35 458 164 whose working winding is connected in parallel with the input of the block and is connected between earth and the main system zero point. and the control winding of the magnetic amplifier is to the output of the executive element of the regulatory block ket. The connection of the amplifier eliminates the need of grounding the main work line during the compensation of the capacitive earth currents. which reduces the risk of electric shock.

The compensation of capacitive earth currents is progressing automatically in a continuous manner. whereby the system reacts capacitive changes caused by changes in usage conditions for the main three-phase system. which thus ensures optimal working parameters of this.

The particular disadvantage of the system described above lies in gives in that only the capacitive component of the earth currents compensated and furthermore the system is designed only for three-phase systems with an accessible zero point.

The object of the invention is to design a system. as possible- reduces short-circuited earth currents and electric currents shocks to humans during single phase shocks during self-disconnection in electrical mains with an isolated zero point.

This object is achieved by the arrangement according to the invention obtained the characteristics specified in claim 1. Yt- Further features of the invention appear from the other patents requirement. Thus, the object of the invention is thereby achieved that in an induction unit in front of an impedance converter. is an amplifier. as and auxiliary windings connected to the unit and the unit thus provided with the coupling read between an artificial zero point in the three-phase network and earth.

Thereafter, inductance control and feedback of pre- the amplifier in the impedance converter. work winding.

V8 IUHÖQII unit inauktällâ resonated with the capacitance of the network, whereby the capacitance active and active current components of the faulty phase a voltage / current analysis of the erroneous phase and is compared with the limitation parameters. which are input signals to the rules / measuring unit. pensive. Regulation is performed by 10 15 20 30 35 458 164 The solution according to the invention enables limitation of feed human hazardous single-phase currents in the network with an isolated zero- by compensating for the capacitive and active components below the limit value for automatic disconnection. as defined by recommendations from International Electro- Technical Committee (IEC). Regardless of this, it constitutes the aforesaid the solution provides complementary protection against electric shocks in net with an isolated zero point in relation to the added one the protective device.

It is also an advantage that the system is regulated to limit the surge currents ensure limitation of the earth currents at single-phase short circuits. thus limiting the spread of single-phase short circuits to two- and three-phase. Because that the risk of explosion and fire has decreased. The plea of rules / measuring unit allows regulation of the system without need of artificial groundings. which further reduces the risk for shocks. On the other hand, the application of symmetrical device for measuring the impedance function of the system according to the invention in asymmetric networks with an isolated zero point.

The invention is described in more detail below in connection with it attached the drawing. where the figure shows a block diagram of a systems that enable compensation of capacitive and active tive earth currents are achieved.- In the system shown in the figure, the working winding of an internal production unit 1 connected between an artificial measuring zero point 2 and soil. and auxiliary windings are connected to the input and the output of an impedance converter amplifier 3. The first output time on a control unit 4 is connected to the impedance converter the amplifier 3, and the second output of the control unit 4 is connected to the input of the induction unit 1 for control of its inductance. A controller / measuring unit 5 is connected between the mains and soil. and its output is connected to the input of the unit 4. In addition, the third output on the control unit is 4 connected to the input of an impedance symmetry device 6 for the network. which symmetry unit is connected between the networks and soil. 10 20 25 30 35 458 164 The rules / measuring unit 5 connected to the system is designed on such a way. that it includes a surge current control system and a ground voltage control system. The surge current control system is one replacement impedance for the human body with the voltage / current characteristics. recommended by International Electrotechnicel Committee in publication 479. Earth voltage the control system is a ground voltage comparator and an output signal analyzer comprising filters for components of symmetrical voltages and an additional amplifier. whose signals through the control unit 4 regulates the value of the earth current in the fault phase.

In the embodiment shown, the control unit 4 comprises one who chooses the minimum of the offender the phase voltage, and of elements, differentiating element, which form the signals. as impedance converter amplifier 3 and network impedance symmetry device 6. controls the induction unit l. when applying an induction unit 1 in the system according to the finding. which unit's inductance is regulated by changing the the size of the core air gap. a signal is generated in regulatory called 4, which signal starts an adjusting device. as causes the change in the size of the air gap. If on the other hand the side uses an induction unit 1. whose inductance is regulated by changing the excitation current of the transducer, is generated a signal in the control unit 4, by means of which signal the value on the current changes in the adjusting device.

In a symmetrical network, the resultant of the impedance in special phases the same value, which enables operation of the system with disconnected impedance symmetry device 6 for the network. So- Thus, the operation of the system according to the invention is in one protected symmetrical network the following. In the event of a phase failure, the the measuring / measuring unit 5 a signal to pass to the control unit 4. which generates signals for regulating the induction network 1 and the impedance converter amplifier 3. The induction unit The transmitted signal causes a change in its inductance and resonates with the resultant of the mains capacitance. 10 15 20 458 164 which compensates for the capacitive component of the current í the missing phase. On the other hand, it leads to impedance the transmitter amplifier 3 transmitted the signal a change of the positive feedback coefficient in the amplifier, as via auxiliary windings in the induction unit 1 act on its working winding. which compensates for the active component of the but in the missing phase.

In an asymmetric network, the resultant of the impedance in the social phases a different value. The working method of the system according to the invention in a protected, asymmetrical network it is following. The control / measuring unit 5 receives a signal to pass to control unit 4 regarding the state of the impedance in the the phases in relation to earth.

A control signal generated in the control unit 4 is supplied to the mains the dance symmetry device 6 provides compensation for the the result of the impedance in the measurement phases in relation to earth.

Further function of the system in the event of a phase failure progresses on the same as specified for the system for a protected symmetry risk network.

Claims (2)

10 15 458 164 Patent claims Arrangements to compensate for capacitive and active earth currents. comprising an induction unit. whose control coupling is connected to a control socket. characterized in that a working winding of an induction unit (1) is connected between an artificial neutral mains point (2) and earth. and that auxiliary windings of the induction unit are connected to an input and an output of an impedance converter amplifier (3), that a first output of a control unit (4) is connected to the impedance converter amplifier (3). that a second output on the control unit (4) is connected to an input on the induction unit (1). and that an input of the control unit (4) is connected to an output of a control / measuring unit (5). which is connected between the network and the ground. Arrangement according to Claim 1, characterized in that a third output of the control unit (4) is connected to a mains impedance symmetry device (6), the mains and earth, which is connected between