MD1651Z - Transformer device for interconnection of power systems - Google Patents

Abstract

The invention relates to electrical engineering, and can be used, for example, for interconnection of three-phase alternating current power systems.The transformer device for interconnection of power systems, according to the invention, consists of a main three-phase transformer, with windings (1-18) connected in a ring circuit with twelve taps distributed over the windings (1-18) of the ring circuit, three of which are connected to the first power system (A1, B1, C1), and to each tap are connected the inputs of three electronic switches, numbered in a circle, which are connected to each tap, which are connected in three separate identical blocks of switches (20-22), to the outputs of each block of switches (20-22) are connected, respectively, the windings ( 23-25) of an additional three-phase transformer. In each block (20-22), the outputs of the odd-numbered switches are electrically connected together and connected to the first terminal of the winding (23-25) of each phase of the additional three-phase transformer, and the outputs of the even-numbered switches are also electrically connected together and connected to the second terminal of the winding (23-25) of each phase of the additional three-phase transformer. Each winding (23-25) of the additional three-phase transformer comprises seven taps, to each of which being connected the input of one output electronic switch (26-31), which form three separate identical groups. In each group, the outputs of these switches are electrically connected together and connected to the phases of the second power system (A2, B2, C2).

Description

The invention relates to electrical engineering, and can be used, for example, for interconnecting three-phase alternating current energy systems.

A transformer-type device is known for interconnecting three-phase alternating current energy systems, which consists of a three-phase transformer with windings connected in a hexagon, which are equipped with regulating sockets, in addition, the sockets, located symmetrically with respect to the vertices of the hexagon, are connected to the phases of the interconnected energy systems [1].

The disadvantage of this device is its complexity and, consequently, low reliability, since the power quality decreases with each switching for a step change of the phase angle. Therefore, to meet the requirements for power quality, this step must be kept to a minimum value. In this regard, a large number of taps distributed over the windings is required and, consequently, a large number of switching keys. When adjusting the circular angle and an angular step size of 5°, the number of taps distributed over the hexagon windings will be 360°/5° = 72 and to ensure the angle adjustment from each power system, a minimum of 2*72*3 = 432 keys will be required for all three phases.

The closest technical solution is a transformer-type device for interconnecting two energy systems, which contains two three-phase regulating windings with on-load switching means, connected in a polygon, as well as an additional three-phase winding [2].

The disadvantages of this device are its complexity and, consequently, low reliability, since in order to meet the requirements for power quality, this step must be kept to a minimum value. Therefore, when adjusting the circular angle and with an angular step size of 5°, the number of taps distributed over the hexagon windings in this device will also be equal to 360°/5° = 72. Thus, to connect all three phases of both systems connected to the given device, twice as many keys are required, i.e. 72*3 = 216 keys.

The problem that the invention solves consists in increasing reliability by reducing the number of taps distributed on the windings of the main transformer and the number of switching keys.

The transformer-type device for interconnecting energy systems, according to the invention, eliminates the above-mentioned disadvantages in that it consists of a main three-phase transformer with windings connected in a ring circuit with twelve sockets distributed on the windings of the ring circuit, three of which are connected to the phases of the first energy system, and to each socket are connected the inputs of three electronic keys, numbered in a circle, which are connected in three separate identical key blocks, to the outputs of each key block are connected, respectively, the windings of an additional three-phase transformer. In each block, the outputs of the odd-numbered keys are electrically connected together and coupled to the first terminal of the winding of each phase of the additional three-phase transformer, and the outputs of the even-numbered keys are also electrically connected together and coupled to the second terminal of the winding of each phase of the additional three-phase transformer. Each winding of the additional three-phase transformer contains seven taps, to each of which the input of an electronic output key is connected, which forms three separate identical groups. In each group, the outputs of these keys are electrically connected together and coupled to the phases of the second power system.

Such a set of characteristics provides the possibility of two-stage regulation, the transformer-type device for interconnecting energy systems consists of two three-phase transformers, main and additional, in the first stage m-taps are required distributed on the windings of the main transformer and, consequently, 3m-electronic keys for three phases, and in the second stage n-taps are required distributed on the windings of each phase of the additional transformer and, consequently, 3n-keys for each phase, i.e. only 3m+3n keys. In the claimed device, the number of keys is 3m+3n, so for the angular step size of 5°, at m=12, we have 360°/12=30°, so 30°/5°+1=7 keys are required for each phase, i.e. n=7, from which it follows 3m+3n=3*12+3*7=36+21=57. Reducing the number of sockets and the corresponding number of keys, while maintaining the accuracy of phase adjustment, leads to increased reliability, i.e., it is a solution to the task of the invention.

The invention is explained by the drawings in Fig. 1-3, which represent:

- Fig. 1, diagram of the claimed device;

- Fig. 2, diagram of a key block;

- Fig. 3, connection diagram of the main transformer windings in the form of a hexagon.

References in figures 1 and 3:

1 - first part of the phase A1 winding; 2 - second part of the phase A1 winding; 3 - third part of the phase A1 winding; 4 - fourth part of the phase A1 winding; 5 - fifth part of the phase A1 winding; 6 - sixth part of the phase A1 winding; 7 - first part of the phase B1 winding; 8 - second part of the phase B1 winding; 9 - third part of the phase B1 winding; 10 - the fourth part of the winding of phase B1, 11 - the fifth part of the winding of phase B1, 12 - the sixth part of the winding of phase B1, 13 - the first part of the winding of phase C1, 14 - the second part of the winding of phase C1, 15 - the third part of the winding of phase C1, 16 - the fourth part of the winding of phase C1, 17 - the fifth part of the winding of phase C1, 18 - the sixth part of the winding of phase C1, 19 - electrical wiring, 20 - the first key block, 21 - the second key block, 22 - the third key block, 23 - the winding of phase A2 of the additional transformer, 24 - the winding of phase B2 of the additional transformer, 25 - the winding of phase C2 of the additional transformer, 26 - the first key of the first group of electronic output keys, 27 - n-key of the first group of electronic output keys, 28 - the first key of the second group of electronic output keys, 29 - n-key of the second group of electronic output keys, 30 - the first key of the third group of electronic output keys, 31 - n-key of the third group of electronic output keys.

References in Figure 2:

32 - first key; 33 - second key; 34 - third key; 35 - fourth key; 36 - fifth key; 37 - sixth key; 38 - seventh key; 39 - eighth key; 40 - ninth key; 41 - tenth key; 42 - eleventh key; 43 - twelfth key.

The device shown in Fig. 1-3 consists of the following parts and connections.

The three-phase main transformer includes: six parts of the phase winding Al: the first - 1, the second - 2, the third - 3, which are electrically connected to each other in series, the fourth - 4, the fifth - 5 and the sixth - 6, which are electrically connected to each other in series; six parts of the phase winding Bl: the first - 7, the second - 8, the third - 9, which are electrically connected to each other in series, the fourth -10, the fifth - 11, the sixth - 12, which are electrically connected to each other in series; and six parts of the phase winding C1: the first - 13, the second - 14, the third - 15, which are electrically connected to each other in series, the fourth - 16, the fifth - 17 and the sixth - 18, which are electrically connected to each other in series. The windings of each of the phases of the main transformer, located on three columns, are indicated by the same hatching. All these windings 1-18 are connected in a ring, to which m-taps are made (Fig. 1, 3 shows the variant for m=12). The phases of the first power system are connected as follows: phase A1 - to the connection point of the first 1 and the second 2 parts of the winding of phase Al; phase B1 - to the connection point of the first 7 and the second 8 parts of the winding of phase Bl; phase C1 - to the connection point of the first 13 and the second 14 parts of the winding of phase C1. Through the electrical wiring 19, the taps of the windings 1-18 of the main three-phase transformer are connected to three identical blocks of electronic keys: the first - 20, the second - 21 and the third - 22.

The main three-phase transformer comprises windings 1-18, connected in the ring circuit with 12 taps distributed on windings 1-18 of the ring circuit, three of which are connected to the phases of the first energy system A1, B1, C1, and to each tap are connected the inputs of three electronic keys 32-43, numbered circularly, which are connected in three separate identical key blocks 20-22. To the outputs of each key block 20-22 are connected, respectively, the windings 23-25 of the additional three-phase transformer. In each block 20-22, the outputs of the odd-numbered switches 32, 34, 36, 38, 40, 42 are electrically connected together and coupled to the first terminal of the winding 23-25 of each phase of the additional three-phase transformer, and the outputs of the even-numbered switches 33, 35, 37, 39, 41, 43 are also electrically connected together and coupled to the second terminal of the winding 23-25 of each phase of the additional three-phase transformer. Each winding 23-25 of the additional three-phase transformer contains seven sockets, to each of which the input of an electronic output switch 26-31 is connected, which forms three separate identical groups, and, in each group, the outputs of these switches are electrically connected together and coupled to the phases of the second energy system A2, B2, C2.

All the keys of this device are electronic and controllable. The outputs of the first block 20 of electronic keys are connected to the winding 23 of the phase A2 of the additional transformer. The outputs of the second block 21 of electronic keys - to the winding 24 of the phase B2 of the additional transformer. The outputs of the third block 22 of electronic keys - to the winding 25 of the phase C2 of the additional transformer. In fig. 1 the windings of different phases of the additional transformer are shown with different hatching. Each of these windings has seven sockets, and a key from the group of output keys is connected to each socket, as follows:

- to winding 23 of phase A2, the keys are connected: starting with the first key 26 of the first group of output keys, up to the seventh key 27 of the first group of output keys;

- on winding 24 of phase B2: starting with the first key 28 of the second group of output keys, up to the seventh key 29 of the second group of output keys;

- on winding 25 of phase C2: starting with the first key 30 of the third group of output keys, up to the seventh key 31 of the third group of output keys.

The outputs of these switches in each group are electrically connected together and coupled to the corresponding phases of the second power system A2, B2 and C2.

At the connection points between the parts of windings 1-18, the keys 32-43 of all three blocks 20-22 of electronic keys are connected to the sockets of windings 1-18 of the main transformer in the same way and in the following way (fig. 2):

- The input of the first switch 32 is connected to the connection point of the first 1 and the second 2 parts of the phase winding A1;

- The input of the second key 33 is connected to the connection point of the second 2 and third 3 parts of the phase winding A1;

- The input of the third key 34 is connected to the connection point of the fourth 16 and fifth 17 parts of the C1 phase winding;

- The input of the fourth key 35 is connected to the connection point of the fifth 17 and sixth 18 parts of the C1 phase winding;

- The input of the fifth key 36 is connected to the connection point of the first 7 and the second 8 parts of the phase winding B1;

- The input of the sixth key 37 is connected to the connection point of the second 8 and third 9 parts of the phase winding B1;

- The input of the seventh key 38 is connected to the connection point of the fourth 4 and fifth 5 parts of the phase winding A1;

- The input of the eighth key 39 is connected to the connection point of the fifth 5 and sixth 6 parts of the phase winding A1;

- The input of the ninth key 40 is connected to the connection point of the first 13 and the second 14 parts of the C1 phase winding;

- The input of the tenth key 41 is connected to the connection point of the second 14 and third 15 parts of the C1 phase winding;

- The input of the eleventh key 42 is connected to the connection point of the fourth 10 and fifth 11 parts of the phase winding B1;

- The input of the twelfth key 43 is connected to the connection point of the fifth 11 and sixth 12 parts of the phase winding B1;

This device works as follows.

The phase voltage of the first power system, A1, B1 and C1, applied to the three-phase main transformer, and the currents caused by them flow through all its windings 1-18 as follows:

six parts 1-6 of the A1 phase winding (first - 1, second - 2, third - 3, fourth - 4, fifth - 5 and sixth - 6);

six parts 7-12 of the B1 phase winding (first - 7, second - 8, third - 9, fourth - 10, fifth - 11 and sixth - 12);

and six parts 13-18 of the C1 phase winding (first - 13, second - 14, third - 15, fourth - 16, fifth - 17 and sixth - 18).

All these windings 1-18 are connected in a ring circuit with twelve taps, located on the circle. Through the electrical wiring 19, the twelve taps of the windings 1-18 of the main three-phase transformer are connected to three identical blocks of electronic keys: the first - 20, the second - 21 and the third - 22. Connected to the outputs of these blocks of keys 20-22, the windings 23-25 of the additional transformer: winding 23 of phase A2, winding 24 of phase B2 and winding 25 of phase C2, through the open keys of these three blocks of keys 20-22 are connected to pairs of adjacent taps from the phase windings 1-18 of the main three-phase transformer along the ring circuit of their connection.

At the output switches 26-31, the groups of seven switches of which are connected to the taps of the windings 23-25 of the additional transformer, at each moment of time only one switch is open, through which the current flows to the second power system A2, B2, C2. The output switches 26-31 are connected in the following way:

- on winding 23 of phase A2, starting with the first key 26 of the first group of output keys up to the seventh key 27 of the first group of output keys;

- on winding 24 of phase B2, starting with the first key 28 of the second group of output keys, up to the seventh key 29 of the second group of output keys;

- on winding 25 of phase C2, starting with the first key 30 of the third group of output keys, up to the seventh key 31 of the third group of output keys.

At the same frequencies, in both power systems, A1, B1, C1 and A2, B2, C2 the specific numbers of the keys to be opened are determined depending on the value of the phase shift between the voltage sinusoids of the phases with the same name of the mentioned power systems. At different frequencies, with a speed determined by the value of the frequency difference, a synchronous alternative switching of the keys 32-43 in the three key blocks occurs (in the first - 20, in the second - 21 and in the third - 22). The keys 32-43 are opened in adjacent pairs, ensuring that each winding 23-25 of the additional transformer is connected to certain adjacent taps 26-31 of the windings 23-25 of the main transformer. For example, the first keys are opened in pairs: the first key 32 and the second key 33; then the second key 33 and the third key 34; next, the third key 34 and the fourth key 35; then, the fourth key 35 and the fifth key 36; after that, the fifth key 36 and the sixth key 37; then, the sixth key 37 and the seventh key 38; further, the seventh key 38 and the eighth key 39; after that, the eighth key 39 and the ninth key 40; then the ninth key 40 and the tenth key 41; after that, the tenth key 41 and the eleventh key 42; followed by the eleventh key 42 and the twelfth key 43; and finally, the twelfth key 43 and the first key 32. In this case, if for phase A2 of the additional transformer the first key 32 and the second key 33 of the first key block 20 are opened, then for phase B2 the fifth key 36 and the sixth key 37 of the second key block 21 will be opened, and for phase C2 the ninth 40 and the tenth key 41 of the third key block 22 will be opened.

In general, this device offers the possibility of two-stage regulation, namely, the taps from the main transformer windings form the first regulation stage and the taps from the additional transformer windings form the second regulation stage, due to which the number of keys and taps from the windings is reduced.

Reducing the number of keys and the corresponding number of sockets while maintaining the accuracy of phase adjustment leads to an increase in reliability.

1. SU 625258 A1 1978.09.25

2. SU 1288764 A1 1987.02.07

Claims (1)

Transformer-type device for interconnecting energy systems, consisting of a main three-phase transformer with windings (1-18) connected in a ring circuit with twelve sockets distributed on the windings (1-18) of the ring circuit, three of which are connected to the phases of the first energy system (A1, B1, C1), and to each socket are connected the inputs of three electronic keys (32-43), numbered in a circle, which are connected in three separate identical key blocks (20-22), to the outputs of each key block (20-22) are connected, respectively, the windings (23-25) of an additional three-phase transformer; in each block (20-22), the outputs of the odd-numbered switches (32, 34, 36, 38, 40, 42) are electrically connected together and coupled to the first terminal of the winding (23-25) of each phase of the additional three-phase transformer, and the outputs of the even-numbered switches (33, 35, 37, 39, 41, 43) are also electrically connected together and coupled to the second terminal of the winding (23-25) of each phase of the additional three-phase transformer; each winding (23-25) of the additional three-phase transformer contains seven sockets, to each of which the input of an electronic output switch (26-31) is connected, which form three separate identical groups, and, in each group, the outputs of these switches are electrically connected together and coupled to the phases of the second energy system (A2, B2, C2).