RU2850714C1 - Three-phase symmetrical device - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to devices for balancing loads in three-phase four-wire electrical installations and can be used to reduce the zero and reverse sequence voltage imbalance factor, as well as to reduce zero sequence power losses in electrical networks. The three-phase balancing device contains input terminals for connection to the phase and neutral conductors of a three-phase four-wire electrical installation, output terminals for connection to the corresponding load conductors, and a neutral conductor. The device additionally contains at least one voltage-boosting transformer for phase-by-phase voltage regulation, the input of which is electrically connected to at least one of the phase and neutral input terminals, and the output to the corresponding output terminals.

EFFECT: increased efficiency of the device due to the symmetrisation of phase and line voltages on the load, reactive power compensation, limitation of starting currents, and reduction of zero-sequence power losses.

6 cl

Description

The invention relates to the field of electrical engineering, in particular to devices for balancing loads in three-phase four-wire electrical installations, and can be used to reduce the voltage asymmetry coefficient for zero and negative sequence, as well as zero sequence power losses in electrical networks.

A three-phase symmetrizing device (hereinafter referred to as the device) is known, containing a three-phase symmetrizing transformer, the windings of which are connected in a zigzag pattern in opposition, wherein the three first outer terminals of these windings are connected to three input terminals of the device, connected to the phases of the electrical network, and the three second outer terminals are connected to each other, the device contains an additional three-phase transformer with primary windings connected in a star and connected to the phases and the neutral wire of a four-wire electrical network, and its three secondary windings are connected in an open triangle and their free ends are connected between the common connection point of the three second outer terminals of the windings of the symmetrizing transformer and the neutral wire of the four-wire electrical network [1].

The disadvantage is complexity, high zero sequence resistance, does not eliminate the negative sequence asymmetry.

A three-phase balancing device is known, comprising input and output terminals of the power supply network, wherein a three-phase transformer is connected to the output terminals, the primary windings of which are connected in a zigzag pattern in opposite directions; a first three-phase circuit breaker with an independent tripping device is connected between the input and output terminals of the power supply network; a second three-phase circuit breaker is connected in series with the primary windings of the three-phase transformer. The neutral terminal of the primary windings of the three-phase transformer, connected in a zigzag pattern in opposite directions, serves as the neutral terminal for connecting the phase loads [2].

The disadvantage is the split neutral, due to which the balancing device only affects the connected consumer and does not eliminate the asymmetry in the reverse sequence.

A three-phase balun is known with input terminals connected to the phases and neutral wire of a four-wire electrical network, containing a three-phase balun transformer, the windings of which are connected to the phases of the network and neutral wire, characterized in that the primary windings of the transformer are connected in a star and with their free ends are connected to the phases of the network, and with their common connection point - to the neutral wire of the network, while the secondary windings are connected in a triangle [3].

Disadvantage - device overload when exceeding the permissible asymmetry power, high asymmetry resistance, generation of reactive power, does not eliminate asymmetry in the reverse sequence.

A three-phase balun is known with input terminals connected to the phases and the neutral wire of a four-wire power supply network, containing a three-phase balun transformer, the windings of which are connected in a zigzag pattern in opposition, wherein the first three outer terminals of these windings are connected to three input terminals of the device connected to the phases of the power supply network, and two of the three second outer terminals are connected to each other, characterized in that all three second outer terminals of the transformer windings are connected to each other and to the input terminal of the device connected to the neutral wire of the power supply network [4].

Disadvantage - overload of the device when the permissible power asymmetry is exceeded, generation of reactive power does not eliminate the asymmetry of the reverse sequence.

The closest to the proposed one is a three-phase balun for operation from a four-wire power supply network, containing input terminals for connecting the power supply network A1, B1, C1, N1 and a three-phase circuit breaker connected in series with the primary windings of a three-rod transformer, two or three primary windings of which are connected in a “zigzag”, the common zero point of these windings is the zero terminal N2 for connecting single-phase loads, characterized in that a choke filter for zero-sequence currents is introduced between the zero terminal N1 of the power supply network and the zero terminal N2, while the input terminals A1, B1, C1 are also the output terminals for connecting the load [5].

Disadvantage: high zero-sequence resistance, generation of reactive power, does not eliminate negative sequence asymmetry.

The aim of the invention is to increase the efficiency of three-phase balancing devices by:

- reduction of zero sequence asymmetry;

- reduction of asymmetry in the reverse sequence;

- regulation and limitation of current;

- reactive power compensation;

- starting current limitations.

The stated objective is achieved due to the fact that in a known device containing input terminals connected to the phase and neutral conductors of a three-phase four-wire electrical installation and output terminals connected to the phase and neutral conductors of the load, containing a neutralizer, at least one step-up transformer is additionally introduced for phase-by-phase voltage regulation, the input of which is electrically connected to at least one of the phase and neutral input terminals, and the output to the corresponding output terminals.

Thus, the claimed device meets the invention criterion of “novelty”.

A comparison of the claimed technical solution not only with the prototype, but also with other technical solutions in this field of technology, revealed features that distinguish the claimed technical solution from the prototype, which allows us to conclude that the technical solution meets the criterion of "significant differences."

A three-phase balun with input terminals connected to the phase and neutral conductors of a three-phase four-wire electrical installation and output terminals connected to the phase and neutral conductors of the load, containing a neutralizer, additionally contains at least one step-up transformer for phase-by-phase voltage regulation, the input of which is electrically connected to at least one of the phase and neutral input terminals, and the output to the corresponding output terminals.

The device works as follows.

The neutralizer recreates the required neutral point at which the phase voltages pass through the medians of the voltage triangle, thus creating the required angles between the phase voltages, and subsequent phase-by-phase regulation allows for the alignment of the line voltages (triangle).

Thus, the neutralizer eliminates the voltage asymmetry in the zero sequence both before and after the device, and the booster transformers eliminate the voltage asymmetry in the negative sequence at the device output.

Depending on the number of regulation stages, the step-up transformer has a corresponding number of branches.

The booster transformer can be either three-phase or single-phase.

To switch the branches of booster transformers, one can use relays, starters, contactors, semiconductor switches, and to control them, electronic computing devices can be used, for example: microcontrollers, programmable logic controllers (PLC), digital signal processors (DSP) or industrial control controllers that provide automatic or remote control depending on the specified network parameters and control algorithms.

When connected in series with phase and/or neutral conductors of semiconductor keys, it becomes possible to regulate the current passing through the balun using PWM modulation or smooth opening of the gate.

This allows the current in the phases and/or in the neutral conductor to be limited to permissible values and prevents its subsequent increase, which expands the scope of application of the device and makes it suitable for operation in networks with varying power and degrees of asymmetry.

Furthermore, when a device is connected to the power grid, inrush currents are generated, which negatively impact the power grid and consumers. To prevent these negative effects, using semiconductor switches, the device can be switched on at the desired point in the sine wave, when inrush currents are minimal. Alternatively, using PWM modulation, the current can be smoothly ramped up or fixed at the desired level.

To protect the device from overcurrents, it is also possible to organize the device shutdown in case of overcurrents through semiconductor keys.

Semiconductor switches can be used to create a capacitance effect, providing compensation for the inductive component of the zero-sequence resistance of the device and thus reducing its own zero-sequence resistance and increasing efficiency.

When zero-sequence currents appear (under load asymmetry conditions), a current of equal magnitude flows through the device in each phase. However, the active and reactive components of the current differ.

Depending on the direction of the zero-sequence voltage vector, the active power component may predominate in one phase, while the reactive component, both inductive and capacitive, may predominate in others. By connecting semiconductor switches in parallel to the phase and/or neutral conductors, it becomes possible to compensate for reactive power arising both from the transformer's own inductance and from the device's operation under unbalanced conditions.

To increase the efficiency of compensation of the inductive component of the zero-sequence resistance, it is possible to use longitudinal compensation, which consists of connecting capacitors in series to the phase and/or neutral conductors.

Compensation of the reactive power of the device can also be carried out using the transverse compensation method - by connecting capacitors between the phase conductors or between the phase and neutral conductors.

The neutralizer can be made in one of the following versions:

1. In the form of at least three single-phase transformers having at least two windings connected in a zigzag pattern taking into account polarity, wherein the first three outer terminals of these windings are connected to three input phase terminals, and the second three outer terminals are connected to each other and to the neutral input terminal of the device.

2. In the form of a three-phase transformer having at least two windings connected in a zigzag pattern taking into account polarity, wherein the first three outer terminals of these windings are connected to three input phase terminals, and the second three outer terminals are connected to each other and to the neutral input terminal of the device.

3. In the form of at least three single-phase transformers having at least two windings, the first of which are connected in a star-zero connection and connected to the input terminals of the device, and the others in a delta connection.

4. In the form of a three-phase transformer having at least two windings, one of which is connected in a star-zero connection and connected to the input terminals of the device, and the other in a delta connection.

5. In the form of at least two single-phase transformers, each of which has at least two windings, which on one side are connected to the neutral and two phase conductors of a three-phase four-wire electrical installation, and on the other side, taking into account their polarity, are connected in series, while the remaining free ends are connected to the neutral and third phase conductor of a three-phase four-wire electrical installation.

All the given options can be used as part of the declared device, maintaining the general principle of operation.

To protect a three-phase balancing device from short-circuit currents, it is possible to install a circuit breaker in the electrical circuit.

To protect against overload currents, it is possible to install a thermal relay in the electrical circuit together with a starter, contactor or circuit breaker with an independent release.

This three-phase balancing device can be used in three-phase four-wire electrical networks to reduce the voltage unbalance factor for zero and negative sequence and to reduce zero sequence power losses.

The disadvantages of a three-phase balancing device include its own load losses and no-load losses, which, taking into account the effect of reducing zero-sequence power losses in electrical networks as a whole, are insignificant.

Thus, the proposed device reduces zero- and negative-sequence voltage unbalance, as well as zero-sequence power losses in electrical networks, while also providing current limitation and regulation, reactive power compensation, and protection against inrush and fault currents. This results in improved device efficiency under load unbalance in three-phase, four-wire electrical networks.

Sources of information

1. RU 2807035 C1, IPC H02J 3/26 (2006.01).

2. RU 2314620 C2, IPC H02J 3/26 (2006.01).

3. RU 2023112767 A, IPC H02J 3/26 (2006.01).

4. RU 2023107419 A, IPC H02J 3/26 (2006.01).

5. RU 2612649 C1, IPC H02J 3/26 (2006.01).

Claims (6)

1. A three-phase balancing device with input terminals connected to the phase and neutral conductors of a three-phase four-wire electrical installation and output terminals connected to the phase and neutral conductors of the load, containing a neutralizer, characterized in that it contains at least one step-up transformer that has at least one branch for phase-by-phase voltage regulation, the input of which is electrically connected to one of the input phase terminals and the neutral input terminal, and the output with the corresponding output phase and neutral terminals, in addition, the neutralizer consists of at least two single-phase transformers, each of which has at least two windings that are connected on one side to the neutral and two phase conductors of a three-phase four-wire electrical installation, and on the other side, taking into account their polarity, are connected in series, wherein the remaining free ends are connected to the neutral and third phase conductor of the three-phase four-wire electrical installation. 2. The device according to claim 1, characterized in that it additionally contains at least one capacitor connected to the conductors of the device for longitudinal and/or transverse compensation of reactive power. 3. The device according to claim 1, characterized in that it contains at least one semiconductor switch, electrically connected to the phase and/or neutral conductors, with the possibility of including it in the corresponding electrical circuit in series or in parallel. 4. The device according to paragraph 3, characterized in that the semiconductor switch is designed with the ability to regulate the current, including the implementation of a soft start and/or current limitation. 5. The device according to paragraph 3, characterized in that the semiconductor switch is designed with the possibility of compensating for reactive power. 6. The device according to paragraph 1, characterized in that the booster transformer is single-phase or three-phase.