RU2732000C1 - Automated control system of state of power cable lines insulation and mode of unstable earth faults - Google Patents

Abstract

FIELD: electrical measuring equipment.

SUBSTANCE: invention relates to electric measuring equipment and can be used in electric installations, at electric stations and substations, electric networks and communication networks to determine insulation state and to predict insulation life. Automated system for diagnostics and control of insulation state of power cable lines introduces units of control of unstable earth faults. Unstable ground faults control units respond to occurrence of regular short-term faults in the network. Use of said units allows generating a signal on occurrence of such a mode with subsequent supply thereof to the input of the microcontroller. System comprises zero sequence current transformers by number of connections; zero-sequence current sensors; zero-sequence voltage transformer; zero-sequence voltage sensor; microcontroller; power supply unit; interface converter; personal computer; current transformers; negative sequence currents filter; Unstable ground faults control units.

EFFECT: technical result consists in determination of distance to place of local defect of insulation and resistance of this defect without disconnection of equipment to change parameters of operating mode of electrical equipment.

1 cl, 1 dwg

Description

The invention relates to electrical engineering and can be used in electrical installations, power plants and substations, electrical networks and communication networks to determine the state of insulation and predict the resource of insulation.

Known automated system for diagnostics and monitoring the insulation condition of power cable lines (RF Patent No. 112525. Automated system for diagnostics and monitoring of the insulation condition of power cable lines / Poluyanovich NK, Stulneva AV, Dubyago MN Publ. 10.01.2012 Bulletin No. 1), containing, according to the number of connections, zero-sequence current transformers, zero-sequence current sensors, a zero-sequence voltage measuring transformer, a zero-sequence voltage sensor, a microcontroller, a personal computer, characterized in that it contains an interface converter, a microcontroller power supply, the outputs of the zero sequence current transformers are connected to the inputs of the corresponding zero sequence current sensors, the corresponding outputs of the zero sequence current sensors are connected to the first inputs of the microcontroller, the output of the zero sequence voltage transformer is connected to the sensor input. zero sequence, the output of the zero sequence voltage sensor is connected to the second inputs of the microcontroller, the interface converter is connected to the first output of the microcontroller, the second output of the microcontroller is connected to the power supply, the input of the personal computer is connected to the output of the interface converter.

The operation of the device is based on measuring the level of the zero sequence current (TNP) in the controlled connection and the zero sequence voltage in the cable line. With the weakening of the phase insulation, the zero sequence current increases (amplitude and phase of the zero sequence current). The data on the state of the cable line is processed by the microcontroller, in which the obtained data are compared with the permissible amplitude of the TNP vector and, if its value is exceeded, the angle between the TNP vector and the phase-to-phase voltage vector is determined, as a result of which it is determined whether the resulting current corresponds to the insulation defect and if not, then a ground fault has occurred.

By the value of this angle with specified ranges, it is determined in which of the phases the defect occurred. The obtained data are processed in a mathematical model, and the system determines the distance to the defect and the resistance of the defect, or, if a defect is only planned, the system predicts the time after which a breakdown will occur.

This system provides fault finding, assessment of the state of power cable lines, due to the determination of the resistance of the defect and the distance to the defect, prediction of the impending damage to the cable line.

The disadvantage of this system is that it only monitors the phase isolation, which makes it possible to detect the occurrence and monitor the development of the processes of phase-to-earth faults. But in electrical networks, processes of reducing the dielectric strength of interphase insulation often occur, which ultimately leads to the occurrence of short circuits between phases and a power failure. Short-circuits between phases (two-phase and three-phase) are not accompanied by the appearance of zero-sequence currents, therefore, this device does not provide early detection of such damage and predict the life of phase-to-phase insulation.

Also, this system does not allow to determine with sufficient accuracy the location of the damage, since a decrease in the dielectric strength of the insulation can occur outside the line at a short distance from its end, and in this case it is difficult to determine the true location of the damage.

The closest to the invention in terms of use, technical essence and the achieved technical result is an automated system for diagnostics and monitoring of the insulation condition of power cable lines (RF Patent No. 2657290. Automated system for diagnostics and monitoring of the insulation condition of power cable lines / Biryulin VI, Kudelina D. V. Publ. 13.06.2018).

This system contains zero sequence current transformers; zero sequence current sensors; zero sequence voltage transformer; zero sequence voltage sensor; microcontroller; Power Supply; interface converter; Personal Computer; current transformers; negative sequence current filter.

The device allows you to determine the distance to the site of a local insulation defect and the resistance of this defect without shutting down the equipment by changing the parameters of the operating mode of electrical equipment, as well as predicting the appearance of defects in power cable lines.

The disadvantage of this system is that it only controls permanent damage to the phase and phase-to-phase insulation of cable lines. But it is known that unstable phase insulation damages can appear in the network. These damages are accompanied by a short-term decrease in the level of insulation resistance, followed by its restoration. In the course of the initial development of such a process, the amplitude of the currents of such damage can be relatively small, which will not ensure the operation of the system and the disconnection of the protected line, but such a mode is dangerous for the isolation of the electrical network due to the occurrence of overvoltages.

The technical problem of the proposed invention is to expand the functionality of the automated system for diagnostics and monitoring the state of insulation of power cable lines - monitoring the mode of unstable earth faults.

The task is achieved by the fact that unstable ground fault control units are introduced into the automated system for diagnostics and monitoring of the insulation state of power cable lines, which react to the appearance of regular short-term faults in the network, even if they are of lower amplitude than the allowable for zero sequence currents. The use of these blocks allows you to generate a signal about the occurrence of such a mode with its subsequent supply to the microcontroller input.

Figure 1 shows a diagram of an automated system for monitoring the state of insulation of power cable lines and the mode of unstable earth faults, on which are indicated: 1, 3, 5 - zero sequence current transformers according to the number of connections; 2, 4, 6 - zero sequence current sensors; 7 - zero sequence voltage transformer; 8 - zero sequence voltage sensor; 9 - microcontroller; 10 - power supply unit; 11 - interface converter; 12 - personal computer; 13 - current transformers; 14 - negative sequence current filter; 15 - unstable ground fault control units (BKNZZ). The outputs of the zero sequence current transformers 1, 3, 5 are connected to the inputs of the corresponding zero sequence current sensors 2, 4, 6, the corresponding outputs of the zero sequence current sensors 2, 4, 6 are connected to the inputs of the BKNZZ 15, the output of the zero sequence voltage transformer 7 is connected to the input zero sequence voltage sensor 8, the output of the zero sequence voltage sensor 8 is connected to the inputs of the BKNZZ 15, the interface converter 11 is connected to the first output of the microcontroller 9, the second output of the microcontroller 9 is connected to the power supply 10, the input of the personal computer 12 is connected to the output of the interface converter 11, the outputs zero sequence current transformers 1, 3, 5 and zero sequence voltage transformer 7 are connected to the inputs of the negative sequence current filter 14, the outputs of the negative sequence current filter 14 are connected to the BKNZZ 15 inputs, the BKNZZ 15 outputs are connected to the microcontrol inputs roller 9.

The device works as follows. Zero sequence current transformers 1, 2, 3 measure the zero sequence current level (ZF) in the monitored line, zero sequence current sensors 2, 4, 6 read information about the insulation state of the power cable line (current and phase of zero sequence current), zero voltage transformer sequence 7 transmits information to the zero sequence voltage sensor 8 about the voltage in the cable line, current transformers 13 measure the phase currents of the protected line, the negative sequence current signal is generated at the output of the negative sequence current filter 14.

BKNZZ 15, connected to the outputs of the zero sequence current sensors 2, 4, 6, are triggered when the corresponding phase of short-term surges of this current appears in the TNP, which appears during unstable ground faults.

Data on the state of the cable line is transmitted to the microcontroller 9, which is powered from the power supply 10, in the microcontroller the received data on the TNP are compared with the permissible amplitude of the TNP vector (for monitoring phase isolation) and if its value is exceeded, the angle between the TNP vector and the vector is determined phase-to-phase voltage, as a result of which it is determined whether the current generated corresponds to an insulation defect, and if so, then a ground fault has occurred. The value of this angle with the specified ranges determines in which of the phases the defect occurred. The level of the negative sequence current is monitored in the same way. If it is greater than the permissible value, then it is determined whether the resulting current corresponds to an insulation defect, and if it does, then a short circuit has occurred between the phases of the line.

The emergence of the mode of unstable ground faults is determined by the BKNZZ 15, the signals from the output of which are fed to the inputs of the microcontroller 9. The microcontroller transmits information about the occurrence of this mode to the personal computer 12.

The obtained data is processed in a mathematical model, and the system determines the distance to the defect and the resistance of the defect, or, if a defect is only planned, the system predicts the time after which a breakdown of either phase or phase-to-phase insulation will occur. The data through the interface converter 11 are transmitted to the personal computer 12, on which they are displayed in the form of the dependence of the amplitude of the vectors of the zero and negative sequence currents on time with a defect prediction window, as well as in the form of a data table (distance to the defect, defect resistance, amplitudes of zero current vectors and reverse sequence, defect type, defect phase).

The automated system for monitoring the state of insulation of power cable lines and the mode of unstable earth faults allows determining the distance to the site of a local insulation defect and the resistance of this defect without shutting down the equipment by changing the parameters of the operating mode of electrical equipment, predicting the appearance of defects in power cable lines, detecting the occurrence of unstable earth faults ...

Claims (1)

An automated system for monitoring the state of insulation of power cable lines and the mode of unstable earth faults, containing, by the number of connections, zero-sequence current transformers, zero-sequence current sensors, zero-sequence voltage measuring transformer, zero-sequence voltage sensor, microcontroller, personal computer, interface converter, power supply the microcontroller, the negative sequence current filter, the outputs of the zero sequence current transformers are connected to the inputs of the corresponding zero sequence current sensors, the output of the zero sequence voltage transformer is connected to the input of the zero sequence voltage sensor, the interface converter is connected to the first output of the microcontroller, the second output of the microcontroller is connected to the power supply, the input of the personal computer is connected to the output of the interface converter, the outputs of the current transformers are zero sequence and zero sequence voltage transformer are connected to the inputs of the negative sequence current filter, characterized in that the system includes unstable ground fault control units connected to the outputs of the zero sequence current and voltage sensors.

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