RU5283U1 - THREE-PHASE VOLTAGE TRANSFORMER - Google Patents

Abstract

A three-phase voltage transformer containing two magnetic cores with windings, placed in an oil-filled metal tank with a cover on which bushing is located, characterized in that one magnetic circuit contains three rods with windings, and the other magnetic circuit contains two rods with windings.

Description

Author Zierman M.Kh.N 01 B 40/04

THREE-PHASE VOLTAGE TRANSFORMER.

The utility model relates to electrical engineering and can be used in the manufacture of three-phase voltage measuring transformers with insulation control in 6-IQ-35 kV networks.

Known three-phase voltage transformer with insulation control in networks of 6-10 kV type NTMI. It is a three-phase group of single-phase transformers placed in an oil-filled metal tank with a lid on which bushing insulators are located. This transformer is unstable to ferroresonance and arc circuits to ground.

Closest to the proposed is an antiresonant three-phase voltage transformer type HAiiM. It contains two magnetic cores with windings, placed in an oil-filled metal tank with a lid, on which bushing insulators are located. One magnetic circuit contains two rods with windings, and the other one rod with windings. The transformer is resistant to ferroresonance and arc stuttering of the network to the ground, but has excess weight and excessive height. This creates difficulties when placing it in the cells of small-sized complete switchgear 6-10 kV.

The purpose of the utility model is to reduce the total mass of the transformer and its overall height.

The goal is achieved in that the three-phase voltage transformer contains two magnetic cores with windings, placed in an oil-filled metal tank with a lid, on which the bushing is located. One magnetic circuit contains three rods with windings, and the other two.

Compared with a voltage transformer such as NAMI, the utility model has increased the total number of cores of magnetic cores with windings - instead of three, it has become five. This made it possible to reduce the number of turns in each bore and reduce its outer diameter. Thanks to this, it was possible to shade the total mass of the transformer and its height, although the laboriousness of manufacturing increased slightly.

The drawing schematically shows a three-phase voltage transformer, as the corresponding utility model.

It contains two magnitude ducts I and 2 of the rod type with windings 3 and 4, placed in a metal tank 5 with insulating liquid 6. On top of the tank 5 is closed with a metal cover 7 with bushing 8. The magnetic core I contains three rods, each of which has a winding 3 The casing 2 contains two rods, on each of which a winding 4 is placed. This makes it possible to substantially reduce the outer diameters of the windings 3 and 4 and to bring the magnetic cores I and 2 closer along the height of the transformer, without violating the isolation distances between the windings. Both magnetic circuits I and 2 are mechanically bonded to each other and attached from the bottom to the cover 7. The taps of the windings 3 and 4 are brought out through the bushings 8.

The voltage transformer operates as follows. The three-phase voltage of the primary high-voltage network is fed through bushings 8 to the three high-voltage windings 3 of the magnetic circuit I. In its three rods, a three-phase direct-sequence three-phase magnetic flux is formed, which reflects a symmetrical secondary voltage. In the absence of phase-voltage imbalance of the primary network on the high-voltage windings 4 of the magnetic circuit 2, the voltage is also absent and the magnetic circuit 2 remains unexcited. There is no secondary asymmetry voltage. In the event of asymmetry in the primary network, a zero sequence voltage appears, which npii is applied to the windings 4 and excites the magnetic circuit 2, so that a zero sequence voltage also appears on the secondary windings of the transformer.

An increase in the total number of magnetic core rods and the corresponding number of windings makes it possible to reduce the number of turns in each winding and to reduce its outer diameter. This leads to a decrease in the mass and height of the transformer; it facilitates its placement in small-sized cells of switchgear and KEUN 6-10 kV.

Sources of information.

1.DEMKOV A.M. and other voltage Transformers, M. Energy, 1975, S. 23, Fig. 1-7.

2.Zicherman M.Kh. and others. Voltage transformers of increased reliability for networks of 6-10 kV. Power plants j%, 1990, p. 64-68.

Claims (1)

A three-phase voltage transformer containing two magnetic cores with windings, placed in an oil-filled metal tank with a cover on which bushing is located, characterized in that one magnetic circuit contains three rods with windings, and the other magnetic circuit contains two rods with windings.