RU2679595C1 - Single-phase load by the three-phase network phases uniform distribution device - Google Patents

Abstract

FIELD: power engineering.SUBSTANCE: invention can be used in the three-phase network energy into the single-phase load powering energy conversion devices. Single-phase load across the three-phase network phases uniform distribution device contains a transformer that is single-phase, has one primary and one secondary windings, the primary winding leads are the device two inputs, the secondary winding one of the leads is the device third input, secondary winding other output is one of the device outputs, which other output is the device fourth input, at that, the device four inputs are configured to be connected to the containing three phase and one neutral wire four-wire three-phase supply network.EFFECT: device simplification, increase in the manufacturability, material consumption and weight and size parameters reduction, as well as increase in the efficiency.1 cl, 2 dwg

Description

The invention relates to circuits of AC distribution networks, and can be used in devices for converting the energy of a three-phase network into energy for supplying a single-phase load.

Known balancing three-phase single-phase AC transformer containing the windings of phases A1, B1 and C1 connected in a "zigzag", and the load outputs are the junction of the ends of the semi-windings of phases B1 and C1 (see RU No. 2321133 C1, Fig. 2).

However, the known transformer does not provide an even distribution of the currents consumed from the three phases, as it distributes the currents in the proportion: 25% - 50% - 25%, which leads to not optimal or incomplete use of the power supply network, the parameters of which, as a rule, are calculated on flow of equal phase currents in strength.

A large number of windings makes the known solution complex and cumbersome.

In addition, safe and reliable operation often requires the connection of an appropriate output terminal to the neutral wire of the supply network. The well-known transformer, all windings of which are galvanically connected, excludes the possibility of such a connection of its load outputs to the neutral wire of the supply network, which, in turn, excludes the possibility of using loads with the requirement of mandatory connection of the load to the neutral and thereby narrows the scope of this solution.

The closest in technical essence - the prototype - is a device for the symmetric distribution of a single-phase load across the phases of a three-phase network, which is a three-phase isolating single or multi-winding (in the secondary circuit) consumer transformer in which each of the secondary windings has additional turns independent of the main winding, designed to compensate for the voltage drop on the line, and each of the consumers of the multi-winding isolation transformer is powered by its own or from the common ( for a single-winding three-phase transformer) of the secondary winding, in which the line of each consumer is powered from three phase transformer coils connected in series, any two of which are connected in concert, and the third is in opposite direction. (See RU 2506676 C2).

The known device contributes to the equalization of currents among themselves in all three phases when feeding single-phase loads.

A disadvantage of the known solution is the complexity and excessive material consumption due to the use of three transformer windings in the primary circuit and the corresponding number in the secondary circuit.

An excessive number of windings reduces the manufacturability of the known device since it requires the involvement of appropriate production resources, lengthening the manufacturing process.

In addition, the known solution requires the presence of excessive overall power of the transformer used (its power is equal to one and a half times the load power). However, an increase in the overall power of the transformer leads to an increase in losses in the transformer and reduces the efficiency of the device as a whole.

The technical result is to simplify the device, increase manufacturability, reduce material consumption and weight and size parameters, as well as increase efficiency.

The specified technical result is achieved by the fact that in the device for the uniform distribution of the single-phase load across the phases of the three-phase network containing the transformer, the specified transformer is single-phase and contains one primary and one secondary winding, the terminals of the primary winding are two inputs of the device, one of the terminals of the secondary winding is the third the input of the device, the other output of the secondary winding is one of the outputs of the device, the other output of which is the fourth input of the device, while D input device configured to connect to a three-phase four-wire feed network comprising a three-phase and one neutral conductor.

In addition: - the transformation ratio of the transformer is equal to one.

A device for the uniform distribution of a single-phase load across the phases of a three-phase network is illustrated using the drawings, which show examples of connection schemes of the device.

In FIG. 1 shows an example embodiment of a device in which only phase wires of a three-phase network are connected to the primary winding.

In FIG. 2 is an example embodiment of a device in which phase and neutral wires are connected to the primary winding.

The following notation is made in the drawings:

1, 2, 3,4 - inputs of the device for connecting the phases of the three-phase supply network A, B and C and neutral wire N, 5 and 6 - outputs of the device for connecting the single-phase load D1 and D2, 7 - transformer, 8 - primary winding of the transformer, 9 - secondary winding of the transformer.

A device for evenly distributing a single-phase load across the phases of a three-phase network contains a transformer with primary and secondary windings and a transformation ratio of 1. The terminals of the primary winding are two inputs of the device, the other two inputs of which are, respectively, one of the terminals of the secondary winding and one of the outputs of the device. Another output of the device is connected to another output of the secondary winding. All four inputs of the device are made with the possibility of connecting to a four-wire supply three-phase network containing three phase and one neutral wire.

The connection of the device inputs with a specific phase of a three-phase network does not matter in the general case, therefore, if the transformer is designed for a voltage of at least the linear voltage of a three-phase network, then a specific input of the device can be connected to any phase wire or a neutral wire, the only condition is the connection of all four inputs devices with four wires of a three-phase power supply network, eliminating short circuit or redundant connection.

Also, the order of winding the windings does not matter, since the input of the device can be both the beginning (Fig. 2) and the end (Fig. 1) of the secondary winding, and one of the device outputs, respectively, is the end or beginning of this secondary winding.

The transformer 7 is single-phase, and can be performed on magnetic circuits of a toroidal or rod structure. The transformer has a primary 8 winding and a secondary 9 winding, wound so that the transformation ratio is equal to one.

The winding process of each of the windings determines the presence of the beginning and end of the corresponding winding. In one (Fig. 1) of the device examples, the beginning of the primary winding 8 is connected to phase A of the supply network, and the end of the primary winding is connected to phase B. Secondary winding 9 is connected by its beginning to one of the outputs of the device for connecting to the load input D1, and at its end - with the third phase C. The neutral wire N in the indicated embodiment of the device is connected to another output of the device for connecting to the load input D2.

In another (Fig. 2) example of the device, one of the inputs, namely, input 4 is both the input of the device and its output, i.e. input for load. The overall power of the transformer in this example embodiment of the device is equal to half the load power. The decrease in the required overall power of the transformer is due to the lower value of the phase voltage between the phase wire and the neutral in comparison with the linear voltage between the phase wires. The indicated linear and phase voltages differing by √3 times and can have standard values of 220/127 V, respectively, or 380/220 V, respectively, or 10 / 5.8 kV, respectively, or other values.

A device for uniform distribution of a single-phase load operates as follows.

The transformer, taking into account its connection scheme, provides the conversion of the energy of a three-phase network into energy for supplying a single-phase load, evenly taking power from all three phases of the supply network. The magnitude of the currents in the phases and the current of the neutral wire are equal to each other. This provides the most favorable mode of operation of the supply network, since the supply wires are loaded evenly.

When a three-phase voltage of the mains is supplied to the inputs 1, 2, 3 and 4 of the device, in which the phase wires and the neutral can be designated as A, B, C, N, respectively, the output single-phase voltage is generated at the outputs 5 and 6 of the device. When the load Dl, D2 is connected to the outputs, current flows through the load.

For the exemplary embodiment shown in FIG. 1, the equality of the currents in phase C and the neutral wire is explained by the fact that the load current flows in this circuit, the equality of the currents in phases A and B follows from the fact that the current of the primary winding of the transformer is equal to the current of its secondary winding and, therefore, the load current. Thus, all four current values are equal in magnitude.

A device for uniform distribution of a single-phase load provides 2 / √3 times higher voltage at its outputs compared to line voltage. So, provided that the device operates from a standard electric three-phase network with a nominal voltage of 380 V, the voltage at the outputs of the device is 440 V.

A smaller number of secondary windings in comparison with the prototype simplifies the device and makes it more technologically advanced in manufacture, as well as reduces the overall overall power of the transformers. As calculations show, the overall power of the transformer in the exemplary embodiment shown in FIG. 1 is √3 / 2≈0.866 of the load power, and in the example of FIG. 2 √3 times less in comparison with the corresponding indicator of the prototype, the mass and cost of the materials of the transformer are also accordingly reduced.

Thus, a device for the uniform distribution of a single-phase load requires a lower total overall power of the transformers.

Since energy losses occur in the transformer, which reduce the overall efficiency of the device, the losses will be the smaller the smaller the overall transformer power required to convert the same amount of energy. Therefore, a decrease in the required overall power of the transformer will lead to an increase in the efficiency of the device. At the same time, the overall dimensions of the device will decrease.

In addition, due to a three times smaller number of windings, the design of the device is simplified and its manufacturing process is simplified, i.e. manufacturability is increasing.

Calculations using vector voltage diagrams show that the value of the output voltage

where: U _n - load voltage,

U _l - the linear voltage of the supply network (that is, the voltage between any two phases).

To change the voltage supplying the load, an adjustable transformer can be connected to the output of the device, while the equality of the phase currents and the current of the neutral wire will not be violated.

A device for uniform distribution of a single-phase load, made according to the scheme of FIG. 1 has a through neutral wire, so that a load requiring a connection to the neutral can be connected to the neutral wire of the supply network, in this example, this is realized by connecting the load input D2.

The device is operable when connecting the terminals of both windings without taking into account their beginning and end of the winding, which is also an advantage of the device.

To ensure the solvable task of three-phase-single-phase conversion while ensuring a uniform phase load, there is no simpler solution than the proposed one: the number of transformers used (one) is the minimum possible; the number of windings in the transformer (two - one primary, one secondary) - is also the minimum possible.

Despite the simplicity of the device, the prior art does not contain solutions characterized by a combination of formulated features.

The device transformer can be manufactured using standard transformer iron and winding wire.

Thus, a device for evenly distributing a single-phase load across the phases of a three-phase network is structurally simpler and more technologically advanced, has lower material consumption, weight and dimensions, and greater efficiency.

In addition, the reduction of the overall dimensions of the device can be ensured with the possibility of connecting the load to the neutral wire of the supply network, which expands the scope of the device.

Claims (2)

1. A device for uniform distribution of a single-phase load across the phases of a three-phase network, comprising a transformer, characterized in that said transformer is single-phase, has one primary and one secondary winding, the terminals of the primary winding are two inputs of the device, one of the terminals of the secondary winding is the third input of the device , the other terminal of the secondary winding is one of the outputs of the device, the other output of which is the fourth input of the device, while the four inputs of the device are made with ozhnostyu connection to a four-phase supply network comprising a three-phase and one neutral conductor. 2. The device according to p. 1, characterized in that the transformation ratio of the transformer is equal to one.

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