RU39738U1 - THREE-PHASE TRANSFORMER FOR SUPPLYING TWO LOADS - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, to trans-format engineering and can be used in transformers designed for railway transport. A useful model solves the problem of creating a three-phase transformer for powering two loads, devoid of the above disadvantages, eliminating the negative sequence currents in a three-phase network when connecting two single-phase loads. To solve the problem in a three-phase transformer to power two loads containing a three-core A magnetic core containing two extreme rods and one middle, on each of the rods of a three-core magnetic core, at least two concentrates, windings are placed, while on one of the concentrates there is a phase of the network winding intended for connection to a three-phase supply network, on another concentrator - the winding phase is located, designed to connect to one of the loads, it is proposed, according to this utility model, to place two additional windings on two concentrates on the middle core, one of which with connect with the network winding located on the other floor of this rod, forming one phase with it, and the other additional winding is the phase of the winding, designed to connect to one of the loads; in this case, the winding intended to connect the corresponding load is located on the middle and one of the extreme rods at the level of one of the floors, while the first of the windings, designed to connect to one load, is connected to a direct non-phase star, and the second of the windings, designed to connection

Description

The utility model relates to electrical engineering, in particular, to transformer construction and can find application in transformers designed for railway transport.

Known three-phase transformer for supplying two loads, containing a three-core magnetic circuit, on all three rods of which are placed the windings on three concentrates so that one winding is designed to connect to a three-phase network, located on the middle concentrator, and each of the other two windings located on both side of it, is the phase of the winding, designed to connect the corresponding load, and, thus, each of the windings, designed to connect to the corresponding load, three phase [L.1].

The implementation of a three-phase transformer described in [L.1] for supplying two loads provides symmetric three-phase voltage systems supplying loads, which are also connected in a three-phase group.

However, quite often, single-phase loads supply voltage from a three-phase system. In particular, power supply of alternating current railway transport is carried out in such a way that one phase of a three-phase secondary transformer winding system connected in a triangle feeds one load, and the second phase - another load,

This system has a drawback: the appearance of reverse sequence currents in a three-phase network supplying a transformer.

A useful model solves the problem of creating a three-phase transformer for supplying two loads, devoid of the above disadvantages, which eliminates the negative sequence currents in a three-phase network when two single-phase loads are connected.

It is known that the above drawback does not have a system in which the stress vectors supplying two different loads are shifted relative to each other by 90 electrical degrees (Scott effect) [L.2].

To solve this problem, in a three-phase transformer for supplying two loads, containing a three-core magnetic core, containing two extreme rods and one middle, on each of the three-core magnetic core rods are placed at least two concentrates, windings, while one of the concentrates contains phase of the mains winding intended for connection to a three-phase supply network, on another concentrator - the phase of the windings intended for connecting to one of the loads is located, it is proposed, according to this paragraph of a useful model, on the middle rod, place two additional windings on two concentrates, one of which is connected to the network winding located on the other floor of this rod, forming one phase with it, and the other additional winding is a phase of the winding intended for connection to one of loads; in this case, the winding intended to connect the corresponding load is located on the middle and one of the extreme rods at the level of one of the floors, while the first of the windings, designed to connect to one load, is connected to a direct non-phase star, and the second of the windings, designed to connected to another load, connected to a reverse in-phase star.

The utility model is illustrated by the example of the drawings, which are: FIG. 1 is a schematic illustration of the active part of the inventive three-phase transformer for supplying two loads; figure 2 is a vector voltage diagram, in particular, figure 2a is a vector diagram of voltages and connecting loads of a known three-phase transformer to power two loads, figure 2b is a vector diagram of voltages and connecting loads of the inventive three-phase transformer to power two loads.

A three-phase transformer for supplying two loads contains a magnetic circuit 1 with three rods: 2, 3, 4; while the rods 2 and 4 are extreme, and the rod 3 is the middle.

The windings located on each of the rods 2, 3, 4 occupy two concentrates. In particular, on one of the concentrates of each of the rods 2, 3, 4, the phases of the network winding are located: on the rod 2 - the phase of the network winding 5, on the rod 3 - the phase of the network winding 6, on the rod 4 - the phase of the network winding 7. Phases of the network winding 5, 6, 7, located on the rods 2, 3, 4, are connected in a star and are designed to connect to a three-phase supply network.

On the other concentrator of each of the rods 2, 3, 4 there is a phase of the winding intended for connection to one of the loads. In particular, on the rod 2 the phase of the winding 8 is placed, on the rod 3 - the phase of the winding 9, designed to connect to one of the loads; on the rod 4 - phase of the winding 10.

On the middle rod 3 on two concentrates (concentrically relative to each other) are two additional windings 11 and 12, located relative to the phase of the network winding 6 and the phase of the winding 9, designed to connect to one of the loads, floor-by-floor. In this case, the additional winding 11 is connected to the phase of the network winding

6, located on another floor of the same rod, and forms one phase with it.

Another additional winding 12 is a phase of the winding, designed to connect one of the loads as well as the phase 10 of the winding, located on the rod 4 ..

In this case, one of the windings, designed to be connected to one load, is made of two phases located at the same level in height (on one, lower, floor - see Fig.): Phase 8, located on the extreme terminal 2 of magnetic circuit 1 and phase 9 located on the middle rod 3 of the magnetic circuit 1, connected to a direct non-phase star. Another winding, designed to connect to a different load, is made of two phases located at a different level in height (on the other, upper, floor): phase 10, located on the outermost rod 4 of the magnetic circuit 1, and phase 12, located on the middle rod 3 of the magnetic circuit 1, connected to a reverse in-phase star.

To ensure this condition, the windings of the inventive transformer are connected to the secondary winding of a known three-phase transformer for powering two loads, a vector diagram of which is presented in Fig. 2a. For example, a reverse non-phase star is connected to the linear end b ₁ , and a direct non-phase star to the end c ₁ . Due to this, the voltage vector "c" - the secondary voltage supplying the load 1, is shifted 15 electrical degrees clockwise, and the voltage vector "a" supplying the load 2 is 15 electrical degrees counter-clockwise (see fig.2b).

Under this condition, only the components of the direct sequence are present in the primary winding of the transformer, which ensures good quality of the power supply network.

This embodiment of a three-phase transformer for powering two loads will ensure the angle of the shift of the voltage and load vectors

- 90 electrical degrees and thereby eliminate reverse sequence currents in the supply network.

Literature:

1. Transformer equipment for converting plants / Ya. L. Fishler, RN Urmanov, L. M. Pestryaeva, Energoatomizdat, 1989, fig. 3-4, s.p. 142, 197, Fig. 4-2v.

2. Electric machines / IP Kopylov, Energoatomizdat, 1986, p. 141.

Claims (1)

A three-phase transformer for supplying two loads, containing a three-core magnetic core, containing two extreme rods and one middle, on each of the three-core magnetic core rods are placed at least two concentrates, windings, while on one of the concentrates there is a phase of the network winding intended for connection to a three-phase supply network, on another concentrator there is a winding phase designed to connect to one of the loads, characterized in that on the middle rod are located on two concentrates x two additional windings, one of which is connected to the network winding located on the other floor of this rod, forming one phase with it, and the other additional winding is the phase of the winding, designed to connect to one of the loads, while the winding is designed to connect corresponding load, located on the middle and one of the extreme rods at the level of one of the floors, while the first of the windings, designed to connect to one load, is connected to a direct non-phase star, and the second Separated from the windings intended for connection to the other load is connected in the opposite unbalance star.