RU2657474C1 - Reactor-transformer var compensator (options) - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to the electric power industry. Three-phase reactor-transformer with two secondary windings connected by a triangle and a star and connected to two thyristor groups is placed in a metal tank. One phase of the two secondary windings is combined and output through a common insulator or connected to a grounded housing.

EFFECT: three-phase reactor-transformer is proposed.

4 cl, 2 dwg

Description

The invention relates to the field of electric power.

The well-known adjustable / 1 / reactor-transformer compensator contains three phases of capacitors, some of which are designed to be connected to the network, while others are connected to symmetrical controlled valves, they only carry out discrete regulation of reactive power, which is its drawback.

The closest prototype to both versions of the invention is / 2 / a thyristor reactor-transformer compensator containing a three-phase transformer located in a common tank with two groups of secondary windings, two phases of which are led out through insulators and connected to the vertices of two triangles made up of triacs. The disadvantage of such a compensator is the relative complexity due to the large number of output insulators.

The technical problem solved in the proposal is to simplify.

The technical problem is solved in the first embodiment due to the fact that the third phases of the secondary windings are combined and brought out through a common insulator, to the output of which the third vertices of the triacs of triacs are connected.

The technical problem is solved in the second embodiment due to the fact that the third phases of the secondary windings are combined and connected to the tank body, to the output of which the third vertices of the triacs are connected.

The solution to the problem is facilitated by the fact that the third vertices of the triangles of the triacs are grounded. Another difference is that the difference in the connection groups of the windings is 5 or 7.

In FIG. Figures 1 and 2 show compensator circuits. In a metal tank 1, there is a reactor-transformer with high voltage windings 2 (35-500 kV), the leads of which outward pass through insulators 3, 4, 5, and low voltage (6-35 kV) windings 6, 7, two phases of which are connected through insulators 8, 9 and 10, 11. The third phases of the windings 6, 7 are combined. The tops of two triangles made up by triacs (or counter-parallel two thyristors) 12-14 and 15-17 are connected to the conclusions of windings 6, 7. In FIG. 1, the combined output of the third phases is output through the insulator 18, and in FIG. 2, this terminal is fixed to the tank body 1 by means of a bolted connection 19. The compensator is designed for controlled consumption of excess reactive power from the network. For this purpose, currents flowing through triacs 12-17 are regulated in a known manner. The design of the reactor transformer is simplified by reducing the number of insulators by 16% (Fig. 1), 33% (Fig. 2). In order to increase reliability, the combined phase can be grounded (paragraph 3 of the formula). The windings 6, 7 form a different connection group (usually 11 and 12), which gives the so-called 12-pulse effect on the network with a minimum of higher harmonics. When using this proposal, it is advisable to choose the connection groups so that the voltage vectors in the combined phases differ by 150 degrees electric. In this case, the current in the output of the combined phase will be significantly lower than the current in the other two phases and will reduce the wire cross section and losses. The specified shift of the vectors is provided in the case when the difference between the groups of the connection of the windings 6 and 7 is 5 or 7.

Information sources

1. Ivakin V.N. etc. Power transmission and DC inserts and static thyristor compensators. M .: Energoatomizdat, 1993, p. 188, fig. 4.34, b.

2. RF patent for utility model No. 123598, cl. H02J 3/18.

Claims (4)

1. The reactor-transformer thyristor compensator containing a three-phase transformer located in a common tank with two groups of secondary windings, two phases of which are brought out and connected to the vertices of two triangles composed of triacs or counter-parallel thyristors, characterized in that the third phases of the secondary windings are combined, brought out and connected to the third vertices of triangles of triacs or counter-parallel thyristors. 2. Reactor-transformer thyristor compensator containing a three-phase transformer located in a common tank with two groups of secondary windings, two phases of which are led out through insulators and connected to the vertices of two triangles composed of triacs or counter-parallel thyristors, characterized in that the third phases secondary windings are combined and connected to a grounded tank body, to the output of which are also connected the third vertices of triangles of triacs or counter-parallel thyristors. 3. The reactor-transformer thyristor compensator according to claim 1, characterized in that the third vertices of the triangles of the triacs are grounded. 4. The reactor-transformer thyristor compensator according to claim 1 or 2, characterized in that the difference in the connection groups of the windings is 5 or 7.

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