RU2314619C2 - Zero-sequence current generator - Google Patents

Abstract

FIELD: revealing of ground closing in a network with an insulated neutral.

SUBSTANCE: the device has zero-sequence current filters connected to the circuit of each connection, zero-sequence voltage filter connected to the collecting buses, device (generator) for producing the zero-sequence current connected to the collecting buses via a switch controlled by a monitoring and control module, accomplishing a short-time closing of the mentioned switch in case the actuation threshold is exceeded, and connected to the zero-sequence voltage filter, and a delay line is introduced in the monitoring and control module. The zero-sequence current generator has a reactor with a three-legged unsaturated magnetic core and star-connected windings with a grounded common point (neutral).

EFFECT: simplified construction, enhanced speed of response and reliability, reduced overall dimensions and mass, provided optimal configuration, enhanced safety of servicing.

6 cl, 3 dwg

Description

The invention relates to the field of electrical engineering, in particular to the design of devices for the selective detection of single-phase earth faults in networks with isolated neutral and protection of the network from damage in the presence of these faults.

In such networks, the selective identification of a power line in which an earth fault has occurred is often a difficult task, especially if large transient resistances occur at the site of damage and a small number of power lines are connected to the busbar section under consideration. For example, if there are two lines of different lengths connected to the busbar section and a ground fault occurs on a long line, the current in its protection may turn out to be very small, insufficient to operate.

In this case, the line protection against earth faults does not work and does not reveal a damaged connection. As a result, the damaged line is detected by alternately disconnecting the lines connected to the busbar section under consideration on the basis of the disappearance of the zero sequence voltage. Such outages can delay the process of identifying a damaged line for a considerable time and, in addition, cause significant material damage to disconnected consumers.

A device is known for detecting a ground fault connection in networks with an isolated neutral (see RU 2157038 C1), which contains, among other things, a three-phase group of high-voltage grounding resistors that are briefly connected to busbars. These resistors are a source of active current flowing through the earth fault point. As a result, the zero sequence currents in the undamaged lines remain capacitive, and the zero sequence current contains a significant active component in the damaged line. By measuring the angle of the zero sequence current with respect to the zero sequence voltage in various connections, the damaged line is determined, after which the three-phase group of grounding resistors is turned off.

The disadvantage of this solution is the presence of powerful grounding resistors that require a special device to protect against damage, as well as a complex algorithm for the comparative processing of signals from current transformers of various connections.

Another close in the architecture of the primary circuits and the ideology of its work is a complete device for partial grounding of the neutral of the development and production of JSC Moscow Electroshield Plant.

This device contains an additional grounding transformer of the TSNZ type, connected to the section busbars through the complete switchgear of the K-104M series (information leaflet of JSC Moscow Electroshield Plant). The power of the grounding transformer is 63 kVA, the high voltage winding is assembled into a star with the neutral removed, and into the low voltage winding into a triangle. The neutral of the high voltage winding is grounded through a block of resistors with an active resistance of 100 Ohms (for a 6 kV network) or 150 Ohms (for a 10 kV network).

The non-optimal design and operating mode of the grounding transformer leads to an increase in its overall dimensions, and the need for neutral grounding through active resistance requires the use of a block of high-power resistors. In addition, an additional transformer is connected to the busbars using a switching device installed in a separate cabinet of the K-104M series, that is, in fact, two cabinets are used to solve the problem of detecting a damaged connection, which implies significant overall dimensions and the cost of the device as a whole, and also reduces its reliability due to the use of a cable insert to interface the neutral grounding cabinet and the K-104M cabinet.

A known zero-sequence current generator connected between the neutral terminal of the power supply transformer and the ground, zero-sequence current filters included in the circuit of each connection, which are connected to each other through a chain of series-connected harmonic filters with a frequency of 25 hertz, threshold organs, time delay elements, and alarm elements the inputs of the respective actuators, the outputs of which serve as the outputs of the signals to disable the corresponding connection. [Cm. Bukhtoyarov V.F., Mavritsyn A.M. "Protection against earth faults in electrical installations in quarries." - M .: Nedra, 1986. p. 68].

When a ground fault occurs in the network using a zero-sequence current generator, a superimposed zero-sequence current of 25 hertz frequency is introduced into the neutral of the power transformer, this harmonic component in the zero-sequence current of each line is measured and compared with the response current equal to the unbalance current times the coefficient detuning, and the damaged line is considered one in which the measured value of the harmonic component of 25 hertz in the zero sequence current exceeds the current abati protection.

The disadvantages of the described device is the need to include a special high-voltage current source with a frequency of 25 hertz in the neutral of the transformer, which in networks with a voltage of 6 ... 10 kilovolts can not be output, as well as the fact that this protection method does not exclude the appearance of an alternating arc at the ground fault , which can significantly complicate the work of protection and cause its incorrect actions.

From a structural point of view, the zero-sequence current generator is made in the architecture of the complete switchgear "ETALON" (RF patent No. 2217851) and is its logical continuation.

An object of the invention is the creation of an effective zero-sequence current generator, as well as the expansion of the arsenal of zero-sequence current generators.

The technical result of the invention is to simplify the design, increase speed and reliability, reduce overall dimensions and weight, ensure an optimal layout, increase the safety of maintenance.

The essence of the invention lies in the fact that the device for detecting an earth fault connection in an isolated neutral network contains zero sequence current filters included in the circuit of each connection, a zero sequence voltage filter connected to the busbars, a device (generator) to create a zero current sequences connected to the busbars via a normally open three-phase switch controlled by a monitoring and control module connected to a zero voltage filter sequence, which performs a short-circuit of the specified switch in case of exceeding the threshold of the control device, and a delay line is introduced into the control unit (control module) and the zero-sequence current device (generator) is implemented as a three-core three-phase unsaturated reactor with windings connected to a star with grounded neutral.

Preferably, relay protection devices responsive to the zero sequence active power level are connected to said zero-sequence current and voltage filters.

In this case, the zero-sequence current generator in a three-phase network with an isolated neutral contains a reactor with a three-rod unsaturated magnetic circuit and with windings connected to a star with a grounded common point (neutral), as well as a normally open high-voltage module equipped with a drive connected to the control and control module, and made in the form of a series-connected selector and a vacuum switching module with three vacuum circuit breakers, and the selector is made with three movable contacts and, with three insulated fixed contacts, with three grounded leads and with three leads connected to the buses, and the switching module is made with three leads connected to the movable contacts of the selector and with three leads connected to the reactor windings, while the monitoring and control module made with the possibility of identifying a single-phase circuit to ground by the voltage of the zero sequence.

The device is equipped with a single case in the form of a cabinet with a busbar compartment and with a low-voltage compartment, a high-voltage compartment and a reactor compartment arranged sequentially from top to bottom, while the busbar compartment located behind the high-voltage compartment contains support insulation elements, busbars and busbar connectors, in the low-voltage compartment contains a monitoring and control module, as well as additionally installed alarm and indication bodies; the high-voltage compartment contains a switching module and a blocked These selector and in the reactor compartment - the reactor and the connecting conductors, each compartment is provided with overpressure relief valve, and a high-voltage compartment is formed with a window from a high-strength transparent polycarbonate and is provided with mechanical mimic existing allocated the chance of observing it through a window.

Figure 1 shows a diagram of the main circuits of the zero sequence current generator of the claimed device, figure 2 is the layout of the compartments of the zero sequence current generator (side view), figure 3 is a right side view of figure 1.

The device consists of compartment 1 of the high-voltage module, compartment 2 of the busbars, compartment 3 of the reactor, which are the power compartments of the generator, as well as the low-voltage compartment 4.

In the compartment 1 of the high-voltage module, there is a high-voltage module 5, including a switching device (module), a selector 6 and a mechanical actuator 7 of the selector, as well as the upper part of the bushing insulators 8 and the upper leads of the central conductors 9. The high-voltage module 5 includes a switching module and a three-position selector 6 ( figure 1).

In the transformer compartment, the lower part of the bushing insulators 10, the lower terminals of the central current conductors 11, the connecting conductors 12, and the three-phase (three-rod unsaturated) reactor 13 are located. The latter is mounted on horizontal rails installed on the base of the compartment 3 of the reactor 13.

In the compartment 2 busbars posted support insulation of the highways 14 and busbar connectors in isolation.

All power compartments 1-3 are equipped with overpressure relief valves located in the unattended area and providing the required localization strength of the device structure.

The control and monitoring module 15 is mounted in the low-voltage compartment, as well as terminal blocks, which provide the module 15 with the relay protection and automation devices of other section connections and with the operational power supply system.

On the facade side, compartment 1 of the high-voltage module 5 is fenced off with a removable front panel having a rectangular cutout. The cutout is closed by a sheet of high-strength transparent polycarbonate, which allows you to observe the elements and the current mechanical mimic. The latter displays the status of the main contacts of module 5 and the position of the moving contacts of the selector 6. The “Disconnected and locked” handle 16 is displayed on the front panel of the compartment 1, the purpose of which is to prevent erroneous actions by the operator when working with the selector 6 and module 5.

The device and the zero-sequence current generator operates as follows.

When a single-phase earth fault occurs, a neutral sequence current appears in the neutral, and its components in the phase conductors. The monitoring and control module (is, for example, a software device) identifies the presence of damage by the voltage of the zero sequence in the neutral (by the voltage sensor of the zero sequence), but does not allow you to set and disable the damaged phase. After a programmable time delay necessary to enable self-extinguishing of a single-phase earth fault arc, the control and control module switches on the high-voltage module. In this case, the contacts of the vacuum circuit breakers of the switching module are closed, and the selector contacts are set by its mechanical drive to the position of connection of the switching module with the busbars. If a single-phase earth fault occurs, the monitoring and control module identifies this damage by the zero sequence voltage, the filter of which is installed in a separate (transformer) switchgear cabinet of the ETALON series, connected to this section of busbars. After a certain time delay, it is necessary to allow self-extinguishing arc of a single-phase earth fault, the monitoring and control module turns on the switching module, and the busbar voltage is connected to a three-phase react yell. In this phase trehsterzhnevoy saturable reactor enters the unbalanced mode, and is formed in its neutral current ln, which depends on the phase voltage network fault resistance and the inductive reactance of the reactor coils dispersion.

The design parameters of the reactor are selected so that the current Jn is no more than 40A, which on the one hand does not lead to the development of an accident at the site of damage, and on the other, it is sufficient for reliable operation of zero-sequence current protection. To operate the latter, zero sequence filters are installed on each connection connected to the busbar section.

. Величина тока нулевой последовательности, формируемого в поврежденной фазе, не приводит к развитию аварии и достаточна для срабатывания токовых защит этой фазы. Спустя некоторое время, достаточное для идентификации однофазного замыкания на землю на поврежденном фидере, модуль контроля и управления отключает коммутационный модуль и отсоединяет реактор от сборных шин секции.The busbar voltage is connected to a three-phase unsaturated reactor (for example, a three-core core). Thus, the latter falls into an asymmetric mode and the specified current Jn of up to 40 A is formed in its neutral, depending on the phase voltage of the network and the resistance at the fault location. The generator (in addition to the flowing current) forms a short-term zero-sequence current into the damaged connection (damaged phase), which is part of the current Jn. Its value is determined by the design parameters of the reactor and is proportional to the sum of the resistance of the zero sequence of the three-phase reactor and the resistance at the site of damage. Zero-sequence magnetic flux is not induced in the three-core magnetic core, therefore, the resistance of the zero sequence of the reactor is minimal, since it is determined only by the inductive resistance of the dissipation of its windings, and the voltage across the windings does not exceed the line voltage divided by

. The value of the zero sequence current generated in the damaged phase does not lead to the development of an accident and is sufficient to trip the current protections of this phase. After some time, sufficient to identify a single-phase earth fault on the damaged feeder, the monitoring and control module disconnects the switching module and disconnects the reactor from the section busbars.

After triggering the protections, after the time required to identify a single-phase earth fault on the damaged feeder by triggering the protections, the monitoring and control module turns off the high-voltage module. In this case, the contacts of the vacuum circuit breakers of the switching module are opened, and the selector contacts are set by its mechanical drive to the neutral position until they are switched back on after the damage has been repaired.

Re-inclusion of the high-voltage module is blocked until the damage is eliminated and the zero-sequence voltage disappears in the network, which occurs after the operation of the mentioned protections of the damaged phase.

The three-position selector can be in one of the following fixed positions:

“Enabled” - the switching module is electrically connected to the busbars.

"Isolated" - the switching module is isolated.

“Grounded” - the reactor windings can be grounded if the main contacts of the switching module are closed.

In normal mode, the selector is in the “On” position, the main contacts of the switching module are open.

Since the magnetic core of a three-phase unsaturated reactor is made of a three-core, it does not induce a zero-sequence magnetic flux, and the resistance of the zero-sequence reactor is determined only by the inductive resistance of the dispersion of its windings.

If it is necessary to check the technical condition and maintenance of equipment located in the cabinet, the selector contacts are switched to the earthed position. On the facade side, the high-voltage module compartment is fenced off with a removable front panel having a rectangular window. The window is closed with a sheet of high-strength transparent polycarbonate, which allows you to observe the elements and the current mechanical mimic. The latter displays the state of the contacts of the switching module and the position of the moving contacts of the selector. The “Disconnected and locked” handle is displayed on the front panel of the compartment, the purpose of which is to prevent erroneous actions by the operator when working with the selector and the switching module.

Overpressure relief valves located in the unattended area of each cabinet compartment provide the required localized structural strength. The area of localization is each compartment separately.

Device Parameters:

Rated voltage, kV - 6 or 10

Rated current of busbars, A - 1600

Busbar thermal current,

effective value, kA - 31.5

Thermal resistance current flow time, s - 3

Electrodynamic resistance current of busbars, peak, kA - 80

Overall dimensions, mm

height - 2008

depth - 762

front width - 330

Weight, kg - 370

Thus, an effective device was created for detecting an earth-fault connection in a network with an isolated neutral and a zero-sequence current generator, as well as an expanded arsenal of zero-sequence current generators.

At the same time, the design is simplified, the speed and reliability are increased, the dimensions and weight are reduced, the possibility of an optimal layout is ensured, the service safety is increased.

Currently, a set of tests of the declared equipment has been carried out in the Tavrida Electric test center. Testing of the cabinet design for localization was carried out at JSC “SIC VVA”. The test results confirmed the correctness of the selected technical solutions.

Currently preparing for serial production.

Claims (6)

1. A device for detecting a ground fault connection in an isolated neutral network, containing zero sequence current filters included in each connection circuit, a zero sequence voltage filter connected to the busbars, a device (generator) for creating a zero sequence current connected to busbars through a normally open three-phase circuit breaker controlled by a monitoring and control module that performs short-circuiting of the circuit breaker in the case of increasing the voltage of the zero sequence of the response threshold and the voltage of the zero sequence connected to the filter, characterized in that a delay line is introduced into the control and control module, and the zero-sequence current device (generator) is implemented as a three-core three-phase unsaturated reactor with windings connected to a star with a grounded neutral . 2. The device according to claim 1, characterized in that the relay protection devices reacting to the active sequence level of the zero sequence are connected to said zero-sequence current and voltage filters. 3. The device according to claim 1, characterized in that the zero-sequence current generator in a three-phase network with an isolated neutral contains a reactor with a three-rod unsaturated magnetic circuit and with windings connected to a star with a grounded neutral, as well as a normally open high-voltage module equipped with a drive connected to the control and management module, and made in the form of series-connected selector and vacuum switching module with three vacuum circuit breakers, and the selector is made with three under movable contacts, with three insulated fixed contacts, with three grounded leads and with three leads connected to the buses, and the switching module is made with three leads connected to the movable contacts of the selector, and with three leads connected to the reactor windings, while the monitoring module and control is configured to identify a single-phase circuit to ground by a zero sequence voltage. 4. The device according to claim 1, characterized in that it is equipped with a single housing in the form of a cabinet with a busbar compartment and with a low-voltage compartment, a high-voltage compartment and a reactor compartment arranged sequentially from top to bottom, while in the busbar compartment located behind the high-voltage compartment, elements of supporting insulation, busbars and busbar connectors are placed, a monitoring and control module is placed in the low-voltage compartment, as well as additionally installed alarm and indication organs, a commutation is placed in the high-voltage compartment a conventional module and a selector interlocked with it, and in the reactor compartment there is a reactor and connecting conductors. 5. The device according to claim 4, characterized in that each compartment is equipped with a pressure relief valve. 6. The device according to claim 4, characterized in that the high-voltage compartment is made with a window of high-strength transparent polycarbonate and is equipped with a working mechanical mnemonic circuitry, placed with the possibility of observing it through the window.

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