RU2640571C1 - Three-phase-single-phase transformer of evseev - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: three-phase single-phase transformer contains a magnetic circuit, two connected in series primary windings and a secondary winding. The magnetic core is made three-rod. Primary windings are wound on the two extreme rods of the magnetic circuit and are connected in series in a counter-manner. The secondary winding is wound on the middle rod, the width of which is equal to

times the width of the outer rods.

EFFECT: reduction of weight and dimensions, simplification of design and increase of efficiency.

4 cl, 2 dwg

Description

The invention relates to circuits of distribution AC networks and can be used to power single-phase consumers of domestic and industrial use from a three-phase network.

A device is known for symmetric distribution of a single-phase load across the phases of a three-phase network, which is a three-phase isolation single or multi-winding (in the secondary circuit) consumer transformer, characterized in that 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 a multi-winding isolation transformer is powered from its own or from a common one (for a single-winding three-phase transformer core) 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 the opposite direction (see RU 2506676 C2, class H02J 3/00).

A disadvantage of the known solution is complexity and excessive material consumption.

The closest in technical essence - the prototype is a device for the uniform distribution of a single-phase load across the phases of a three-phase network, containing primary transformer windings and connected counter-secondary transformer windings, in which the number of primary windings is only two, the primary windings are connected in series and connected to the phase inputs of the device so that the connection point of the primary windings is connected to the input of one of the three phases, and the other ends of the primary windings are connected to the corresponding etstvuyuschimi inputs of the other two phases, the number of secondary windings are also only two secondary windings connected in series and the ends of their series connection connected to the outputs of the device (See. RU 2591040 C1, cl. H02J 3/26).

A disadvantage of the known device is excessive material consumption due to the requirements of a large number of wires for winding windings, which in turn leads to an increase in the overall dimensions of the known solution.

In addition, the winding of a large number of turns reduces the manufacturability of manufacturing, entails the complexity of the design and lower efficiency.

The technical result is to reduce the material consumption and overall dimensions of the device, simplify the design, increase manufacturability and increase efficiency.

раз большую ширины крайних стержней.The specified technical result is achieved in that in a three-phase single-phase transformer containing a magnetic circuit, two primary windings connected in series, the magnetic circuit is made of three rods, the primary windings are wound on the two extreme cores of the magnetic circuit and connected in series in an opposite manner, so that the connected terminals of the primary windings are one of the phase inputs, and other outputs of the primary windings are two other corresponding phase inputs, while the secondary winding is the only one amotane on the middle rod, the width of which is a value in

times the width of the extreme rods.

Besides:

- connected are the beginning of the primary windings or the ends of the primary windings,

- the extreme rods of the magnetic circuit are made of equal cross section,

- the cores of the magnetic circuit are made of rectangular cross section.

The design of a three-phase-single-phase Evseev transformer is illustrated using the drawings, where in FIG. 1 schematically shows the location of the transformer windings relative to the magnetic circuit; FIG. 2 - connection diagram of the windings of a three-phase-single-phase transformer.

The following notation is made in the drawing.

1 and 2 - primary windings, 3 - secondary winding, 4 - clamps on the phase inputs of the device, 5 - clamps on the outputs of the device, 6 - the width of the extreme rods, 7 - the width of the middle rod.

A three-phase single-phase transformer is made on a three-core magnetic circuit and contains two 1 and 2 primary windings and one secondary 3 winding. The primary windings are wound on the two extreme rods of the magnetic circuit and are connected in series opposite, so that the beginning of the winding 1 is connected to the beginning of the winding 2, while the connection of the leads of the windings is connected to the corresponding terminal 4 and is one of the three phase inputs of phase B1 of the supply network. The end of the winding 1 is connected to the corresponding terminal 4 and is the phase input of phase A1, and the end of the winding 2 is connected to the corresponding terminal 4 and is the phase input of phase C1. Clips 4 are intended for connection to a three-phase power supply network.

The secondary winding 3 is wound on the middle core of the magnetic circuit and its conclusions are the outputs D1 and D2 of the device and are connected to the corresponding terminals 5 for connecting a single-phase consumer.

раз больше ширины крайних стержней.The magnetic core is made of a three-rod shape, while the rods have a rectangular section, characterized by the thickness of the set of plates of the magnetic core and the width of these plates, while the width and cross section of the extreme rods are equal to each other, and the width of the middle rod is made in

times the width of the extreme rods.

Three-phase single-phase transformer operates as follows.

A three-phase single-phase transformer converts the energy of a three-phase network into energy for supplying a single-phase load, symmetrically taking power from all three phases of the supply network.

The input three-phase voltage of phases A1, B1 and C1 is applied to the transformer primary windings connected in series to the opposite. The output voltage is removed from the terminals D1 and D2 of the secondary winding.

When a consumer (load) is connected to terminals D1 and D2, currents flow in the transformer windings. In this case, the currents of phases A1 and C1 are equal in magnitude, and the current of phase B1 is twice as large, since the terminals of the two primary windings of the transformer are connected to this phase. Thus, power consumption in phase B1 is 50% of total power consumption, and consumption in phases A1 and C1 is 25% of total consumption. The same power distribution in phases (25% - 50% - 25%) provides a known device, however, it requires the use of a significantly larger amount of transformer steel and a winding wire.

раз больше, чем векторов магнитных потоков в крайних стержнях,Since the primary windings are connected counterclockwise, the magnetic flux generated by the windings on the outer rods is subtracted from one another. The directions of the voltage vectors of the phases of the three-phase network differ by an angle of 120 °, the directions of the magnetic flux vectors differ by the same angle. The module of the difference magnetic flux vector has a value of

times more than the magnetic flux vectors in the outer rods,

раз больше ширины крайних стержней, и так как толщина набора пластин для всех трех стержней одинакова, то и сечение среднего стержня магнитопровода в

раз больше, чем сечение крайних стержней.The width of the middle rod is also in

times the width of the extreme rods, and since the thickness of the set of plates for all three rods is the same, the cross section of the middle core of the magnetic circuit is

times larger than the cross section of the extreme rods.

раз больше ЭДС витка первичной обмотки.The electromotive force (EMF) of the coil coil is proportional to the magnitude of the magnetic flux of induction, whereby the EMF of the coil of the secondary winding in

times more EMF of the coil of the primary winding.

The reduction in wire consumption compared to the known solution is due to the following two reasons.

раз увеличило ЭДС одного витка вторичной обмотки также в

раз, но длина витка при этом увеличивается меньше, чем в

раз. Это обусловлено тем, что при увеличении ширины стороны прямоугольника его площадь растет быстрее, чем периметр.First, the increase in the cross-sectional area of the middle rod in

times increased the EMF of one turn of the secondary winding also in

times, but the length of the coil in this case increases less than

time. This is due to the fact that as the width of the side of the rectangle increases, its area grows faster than the perimeter.

. Так, в известном решении для получения напряжения 220B требуются 2 обмотки по 127B

, в то же время 127+127=254B, т.е. витки на 34B (254-220) являются избыточными, но на них тратится провод и они генерируют дополнительное тепло, снижая КПД.Secondly, in the transformer, the output voltage is provided by one secondary winding, and there is no vector summation of voltages, while in the known solution the output voltage is obtained by vector summing the voltages of two secondary windings, which leads to an excessive number of turns in

. So, in a well-known solution, to obtain a voltage of 220V, 2 windings of 127B each are required

, at the same time 127 + 127 = 254B, i.e. turns on 34B (254-220) are redundant, but the wire is wasted on them and they generate additional heat, reducing efficiency.

According to calculations, the required amount (mass) of the secondary winding wire in the transformer can be reduced by about 40% compared with the mass of the secondary windings of the known solution, and the total weight reduction of all windings (primary and secondary) is about 20%. Reduced wire consumption leads to increased efficiency and simplified coil design.

Despite the simplicity of the design of the transformer, the prior art does not contain solutions characterized by a combination of formulated features, in particular, there are no descriptions of such three-phase three-rod transformers with rods having not the same cross section. Moreover, the implementation of the rods is not of the same cross section, but providing for the indicated ratio between the cross sections of the central and extreme rods simultaneously with the presence of only two primary windings connected in series in the opposite direction, form an not obvious combination of features ensuring the achievement of a technical result.

A three-phase-single-phase transformer contains only three windings, i.e. the smallest possible number of them, since less than two windings cannot be connected to the three phases, and the load cannot be powered by less than one winding, which leads to simplicity of design and manufacturability.

A decrease in the number of windings provides a simplification of the design and increases the manufacturability of manufacturing a device requiring less winding, while reducing the overall dimensions of the device. A decrease in the number of turns of the windings also entails a decrease in material consumption.

Increasing the efficiency of the device is provided due to the smaller required number of wires, which leads to a decrease in losses in the windings, and also due to a decrease in the mass of the magnetic circuit, which allows to reduce losses in transformer steel.

A three-phase single-phase transformer also provides a symmetrical distribution of a single-phase load across the phases of a three-phase network.

A three-phase single-phase transformer can be manufactured using standard transformer iron and a winding wire.

Thus, the three-phase single-phase Evseev transformer has lower material consumption, weight and dimensions, has a simpler design, more technological and has higher efficiency.

Claims (4)

1. A three-phase-single-phase transformer containing a magnetic circuit and two series-connected primary windings, characterized in that the magnetic circuit is made of a three-core, the primary windings are wound on two extreme rods of the magnetic circuit and are connected in series in an opposite manner, so that the connected terminals of the primary windings are one of the phase inputs, and the other terminals of the primary windings are two other corresponding phase inputs, while the secondary winding is the only one and is wound on the middle rod, width which is √3 times the width of the extreme rods. 2. A three-phase single-phase transformer according to claim 1, characterized in that the beginning of the primary windings or the ends of the primary windings are connected. 3. Three-phase single-phase transformer according to claim 1, characterized in that the extreme cores of the magnetic circuit are made of equal cross-section. 4. A three-phase-single-phase transformer according to claim 1, characterized in that the cores of the magnetic circuit are rectangular.

Images