RU2655670C2 - Method of automatic compensation of the current of a single phase fault to earth in a network with an arc-suppressing reactor in the neutral - Google Patents

Abstract

FIELD: electrical equipment.

SUBSTANCE: use: in the field of electrical engineering and power engineering. According to the method, an artificial potential is created on the neutral by injecting the source current into the network zero circuit, measuring the parameters of the zero sequence circuit and adjusting the arc suppression reactor, and from the moment of occurrence of fault to earth, the residual current at the fault to earth location is determined, compared with the threshold level, source is controlled and its current is regulated to the full compensation of the single-phase fault to earth current. Residual current is determined by summing individual current components that occur at the fault to earth location. First component of the residual current is determined by calculating the product of the conductivity of a network zero circuit contour, measured in the period preceding the moment of occurrence of a fault to earth, the voltage of the damaged phase, measured with respect to the neutral of the network. Second component of the residual current is determined by calculating the product of the conductivity of the network zero contour circuit, before the moment of fault to earth occurrence, to the voltage of the neutral relative to the earth measured during the same period. When the resultant residual current exceeds a given threshold level, the source current is set proportional to the resulting residual current, and if the resultant residual current does not exceed a given threshold level, then the source current is set to zero.

EFFECT: technical result is higher efficiency of compensation of single-phase fault to earth currents, and, as a consequence, improving electric power supply reliability of consumers.

5 cl, 1 dwg

Description

The invention relates to the field of electrical engineering and electric power industry and can be used to automatically compensate for the current of a single-phase earth fault in distribution networks with isolated neutral.

A known method of compensating the current of a single-phase earth fault in a network with an arc suppression reactor (GDR) in neutral, which provides resonant tuning of the inductive conductivity of the GDR in the normal mode of operation of the network. In this case, the resonance is found either by the maximum of the natural or artificial voltage of the neutral bias, or by using the phase characteristics of the network, highlighting the reference voltage and reducing the angle between the selected voltages to zero [1].

However, the first version of tuning the resonance resonance resonance resonance has insufficient sensitivity and low speed when stepwise reaching the resonance point. And with the second option - using phase characteristics, even with their significant complication by the introduction of modulation of the reference signal, it is difficult to ensure accuracy and independence from the natural neutral offset and quality factor of the network zero sequence loop.

The closest solution in technical essence is the compensation method, which consists in the fact that in normal operation of the network they create an artificial potential on neutral by introducing the current of the non-industrial frequency source into the zero-sequence circuit (KNI) of the network, measure its parameters and configure the GDR, aligning with the current inductive conductivity of the GDR with the previously measured capacitive conductivity of the KNP network [2].

The method is characterized by a sufficiently high accuracy of the resonant tuning of the KNI network. It is also effective in the case of static compensation devices, where the delayed inductive current is regulated by switching the capacitance of the capacitor bank connected in parallel to the main or auxiliary winding of the GDR [3], or by converting the capacitive current of the capacitor bank using a pulse-width converter [4].

The main disadvantage of the prototype is its low efficiency in electric networks with weakened insulation, characterized by a high level of active phase leakage current, and in networks with a significant asymmetry of the phase conductivities relative to the ground, where the proportion of current due to the inequality of phase conductivities relative to the ground is significant. In such networks, the resonant tuning factor is not a determining criterion for current compensation at the point of earth fault.

Another disadvantage is that the device implementing the prototype method is operable only in conditions of stable earth faults. In case of arc breakdowns at the time of arc extinction, an arbitrary opening of the auto-tuning circuit occurs and loss of controllability of the compensation system occurs. For this reason, this technical solution is unable to neutralize intermittent arc faults, which, as a rule, are accompanied by the most dangerous negative consequences.

These disadvantages limit the scope of this method.

The aim of the proposed invention is to expand the functions and increase the efficiency of compensation of currents of a single-phase earth fault and, as a result, increase the reliability of power supply to consumers.

This goal is achieved by the claimed method of automatic compensation of the current of a single-phase earth fault in a network with an arcing reactor in neutral, which consists in creating an artificial potential on the neutral by introducing a source current into the circuit of the zero sequence of the network, measuring the parameters of the zero sequence circuit and adjusting the suppression reactor , and from the moment of the occurrence of an earth fault, the residual current at the place of the earth fault is determined, compared with a threshold level, they are identified by the source and its current is regulated until the current of the single-phase earth fault is completely compensated.

The residual current is determined by summing the individual components of the current occurring at the point of earth fault.

The first component of the residual current is determined by calculating the product of the conductivity of the circuit of the zero sequence of the network, measured in the period preceding the time of an earth fault, by the voltage of the damaged phase, measured relative to the neutral of the network.

The second component of the residual current is determined by calculating the product of the conductivity of the circuit of the zero sequence of the network, measured in the period preceding the time of the earth fault, and the neutral voltage measured in the same period with respect to the earth.

If the resulting residual current exceeds a predetermined threshold level, the source current is set proportional to the resulting residual current, and if the resulting residual current does not exceed a predetermined threshold level, the source current is set to zero.

A comparative analysis of the claimed solution with the prototype shows that the claimed method provides the expansion of the compensation functions of the current of the OZZ in terms of neutralizing the current, which remains uncompensated in the place of the OZZ when compensated only by the inductive current of the GDR at the network frequency. Thus, the claimed method provides the ability to reduce current and voltage drop at the site of damage, practically, to zero. As a result, the arc and the damage caused by the burning of the arc and its thermal effect at the place of damage are more effectively extinguished, as well as the risks of repeated breakdowns and overvoltages are minimized. The expansion of functions in this form gives a significant increase in the efficiency of current compensation 033, provides a higher degree of electrical safety, fire safety and reliability of power supply.

The drawing shows a functional diagram of a compensation device that implements the proposed method.

A controlled reactor 4 and an inverter 5, powered by auxiliary transformer 6 or from the secondary windings of transformer 3, are connected to an electric network containing connections 1 and 2 through a neutral-forming transformer 3. The output signals of a voltage transformer 7 and current transformers 8 and 9 are fed to the input of the first measuring body 10 in the control circuit of the reactor 4 and the input of the second measuring body 11 in the control circuit of the inverter 5. The interaction logic of these control loops is set by the program mnym by block 12.

The first measuring body 10 comprises a unit 13 in which input data in the frequency domain is processed. The active, inductive, capacitive, and total conductivities of the network zero sequence circuit are calculated. The characteristic value corresponding to the mismatch between the inductive and capacitive conductivities is determined. The mismatch signal generated by block 13 is compared in absolute value with the setting recorded in block 14, which determines the deadband of the measuring organ 10. When the switch 15 is activated, the mismatch signal is fed to the control inductance of the reactor 4.

The measuring body 11 contains a block 16, in which upon the occurrence of the SCR recorded waveforms of input signals. By processing data in the time and frequency domains, a characteristic function is calculated that is oriented with respect to the reference signal coming from one of the phase windings of the transformer 7. The signal generated by block 16 is compared in absolute value with the set value fixed in block 17, which determines the deadband of the measuring organ 11. When triggered the switch 18 formed by the block 16, the signal is supplied to control the output current of the inverter 5.

The inverter 5 is implemented on the basis of a PWM converter with an increased frequency of electric energy conversion and can be connected to the neutral through an additional winding of the reactor 4.

The device operates as follows. In normal network operation mode, the measuring body 10 measures the current parameters of the network circuit using the reference current set by block 12. Block 12 sets the cyclic mode of the inverter 5, which injects the reference current into the neutral of the network, the frequency of which can be set to a multiple of the network frequency in the ratio 1/2 or 1/3. This makes it possible to tune away from the negative impact of industrial-frequency noise on the accuracy of measurements. The absence of a signal at the output of the measuring organ 10 indicates that the inductance of the reactor 4 is near the resonance equilibrium point and the real detuning of the network loop is quite small and does not go beyond the specified deadband. In the case when switching of connections 1 and 2 occurs and the measuring body 10 detects the exit from the dead zone, the mismatch signal generated by block 13 enters the control circuit of the reactor 4, which returns to the point of resonance equilibrium by stepwise or stepless regulation of the inductance. Thus, the measuring body constantly provides resonant tuning of the reactor 4.

The occurrence of the OZZ is recorded by the measuring body 11 by the signals received at its input from the voltage transformer 7. From this moment, the actions of the measuring body 10 are interrupted, the control of the reactor 4 and the inverter 5 is blocked and the processing of data recorded by the measuring body 11 at the time of the occurrence of the OZZ . In block 16, the instantaneous values of the residual current OZZ, determined by the summation of two characteristic components, are calculated. The first component includes the active current of the network circuit and its reactive current, due to the real detuning of the network circuit at the time of the occurrence of the SCR, and the second component is the current due to the inequality of the phase conductivity relative to the ground. To calculate the first component of the current, samples of the voltage of the damaged phase, measured relative to the neutral of the network on the corresponding phase winding of the measuring transformer 7, and the total conductivity of the KNI network, measured until the moment of ground fault, are used. To calculate the second component of the current, the same total conductivity of the network circuit and the registered neutral voltage samples, measured using the "open triangle" winding of the transformer 7 in the period before the moment of ground fault, are used. Then, the signal generated in proportion to the calculated resulting current is compared in absolute value with the sensitivity threshold specified by the setting in block 17, based on the condition of minimal damage from the thermal action of the current at the site of damage and (or) inability to maintain dangerous intermittent arc processes.

If there is no signal at the output of the measuring organ 11 in the SCR conditions, this means that the resulting residual current measured indirectly is small and does not exceed the sensitivity threshold. In this case, the current in the neutral circuit of the reactor 4, previously tuned to the resonance, is sufficient to neutralize the current at the fault location to a safe level. In the absence of a signal in the control circuit of the inverter 5, its output circuit remains de-energized and maintains a high impedance, which excludes its influence on electromagnetic processes in the CNR network.

In the case when, under the conditions of OZZ, the measuring body 11 detects the exit from the dead zone, the signal generated by block 16 enters the control circuit of inverter 5 and puts it into the current injection mode into the neutral of the network, which is proportional to the measured resulting residual current and is directed counter to it. As a result, a current is generated in the neutral circuit, formed by superimposing the current of the reactor 4, aimed at compensating the capacitive component of the current of the network circuit, and the current of the inverter 5, aimed at compensating the residual current. The latter includes the active component of the current of the network circuit and its reactive component, due to the real detuning of the network circuit at the time of occurrence of the SCR, as well as a component due to the inequality of the phase conductivity relative to the ground. In this case, the current at the point of earth fault is completely neutralized and the potential of the damaged phase is aligned with the potential of the earth. These factors make it possible to minimize the risks of re-arcing and damage from thermal effects at the site of damage.

After the software interval set in block 12, the compensation mode is interrupted and the possibility of self-elimination of the OZZ is checked. If this did not happen, then the compensation mode of the current of the OZZ is restored without limiting the duration of time. If the OZZ is self-eliminated, then block 12 restores the cyclic injection mode by the inverter of the reference current and activates the operation of the measuring body 10.

Thus, the measuring bodies 10 and 11 constantly provide the adjustment of the reactor 4 and inverter 5 to fully compensate the current OZZ.

The present invention provides a solution to the following technical problems.

1. The claimed method provides compensation for the residual current at the point of earth fault, acting in concert with the compensation component of the capacitive conductivity of the KNP network at the network frequency (resonant compensation). Under these conditions, the current and voltage at the site of damage are reduced to levels at which the burning of the electric arc and arc breakdowns cease. As a result, the efficiency of compensation and, consequently, the reliability of power supply are increased. The preferred area of application is networks with weakened insulation and increased asymmetry, where the effects of resonant compensation are not sufficient to extinguish the arc at the site of damage and suppress the negative effects of single-phase earth faults.

2. Compensation of the residual current can be realized by a separate device using a controlled source, the installed power of which is obviously much less than the power of the GDR. This makes it possible to expand the scope of the method by improving the resonant compensation systems in operation by supplementing the GDR with a less energy-intensive controlled source.

Information sources

1. Chernikov A.A. Compensation of capacitive currents in networks with grounded neutral. - M .: Energy, 1974., p. 83, 84.

2. Pat. 2130677 RF. A method for automatic tuning of an extinguishing reactor and a device for its implementation / Bryantsev A.M., Dolgopolov AG - Publ. 05/20/1999. Application No. 97111743/09 of 07/01/1997.

3. Pat. 2330366 RF. Method for tuning resonant grounding of the neutral of three-phase AC electric networks / Shpiganovich A.N., Shpiganovich A.A., Zakharov K.D. and others. - Publ. 07/27/2008. Application No. 2007112075/09 of 02/02/2007.

4. Pat. 2524347 RF. The device for compensating the earth fault current in three-phase electric networks (options) / Mustafa G.M. - Publ. 11/20/2013. Application No. 2012119729/07 dated 12/18/2006.

Claims (5)

1. A method of automatically compensating a single-phase earth fault current in a network with an arcing reactor in neutral, which consists in creating an artificial potential on the neutral by introducing a source current into the zero sequence circuit of the network, measuring the parameters of the network circuit and adjusting the arcing reactor, characterized in that since the occurrence of an earth fault, determine the residual current at the earth fault, compare with a threshold level, control the source and adjust its current to full ompensatsii current single-phase ground fault. 2. The method of automatic compensation according to claim 1, characterized in that the residual current is determined by summing the current components that occur at the point of earth fault. 3. The method of automatic compensation according to paragraphs. 1 and 2, characterized in that the first component of the residual current is determined by calculating the product of the conductivity of the circuit of the zero sequence of the network, measured in the period preceding the time of the occurrence of an earth fault, by the voltage of the damaged phase, measured relative to the neutral. 4. The method of automatic compensation according to paragraphs. 1 and 2, characterized in that the second component of the residual current is determined by calculating the product of the conductivity of the circuit of the zero sequence of the network, measured in the period preceding the time of the earth fault, and the neutral voltage relative to the earth, measured in the same period. 5. The method of automatic compensation according to paragraphs. 1-4, characterized in that when the resulting residual current exceeds a predetermined threshold level, the source current is set proportional to the resulting residual current, and if the resulting residual current does not exceed a predetermined threshold level, the source current is set to zero.

Images