SU1714700A1 - Biased three-phase transformer - Google Patents

Abstract

Yadbryötönyö belongs to the electrician, and the lynches belong to adjustable transformers. The purpose of the invention is to simplify the design. The transformer consists of a three-core magnetic circuit 1 with a controllable middle rom 2, a primary 3 and a secondary 4 windings located on opposite sides of the controlled rom, two U-shaped control magnetic conductors 5 with a bias winding on each, perpendicular of the magnetic plane 1, and any of the contours of the magnetic system has at least one joint with a gap of 6.1 or. IISw N4

Description

The invention relates to electrical engineering and can be used as voltage sources with smooth, non-contact regulation under load.

An induction device is known, which is a transformer with a secondary winding located on the extreme rods of a three-core magnetic circuit. The primary winding is located on one of the extreme rods. The regulation is achieved by means of a control magnetic conductor, cut into a cross section of the middle rod and KvfM in such a way that the plane of the control magnetic conductor is orthogonal to the axial line of this rod. The biasing of the control magnetic circuit leads to a redistribution of the main magnetic field from the primary winding in a three-core magnetic circuit and voltage regulation on the secondary winding of the device 1.

However, the three-phase transformer manufactured according to this principle is characterized by the complexity of the design due to the necessity of biasing each control frame by a separate control magnet.

Also known is a three-phase power magnetisable transformer containing spatially separated rods of the primary and secondary windings spaced along the rods of the three-core magnetic core, controlled by the chassis, connecting the free parts of adjacent rods between a pair of U-shaped cores with the control windings of the magnetizable sections on each control unit. shaped cores orthogonal to the plane of a three-core magnetic circuit 2.

However, this transformer is characterized by the complexity of the device due to the large number of control magnetic circuits and windings.

The purpose of the invention is to simplify the design.

The goal is achieved by the fact that a three-phase magnetisable transformer containing a three-core magnetic core with an average control filament, primary and secondary windings located on opposite sides of the middle frame, two U-shaped control magnetic circuits with a winding winding on each plane of which is perpendicular to the plane a three-core magnetic conductor, the ends of which abut against the controlled rom on its opposite sides, the joints between the controlling magnetic conductors and the controlled rym one on either side of the middle rod of a three-core magnetic circuit, and each circuit of the magnetic system has at least one joint with a gap.

The drawing schematically shows a three-phase magnetisable transformer. The three-phase magnetisable transformer contains a three-core magnetic circuit 1 and an average control romo 2. On both sides of the circuit 2, the primary 3 and secondary 4 windings are located on the cores of the magnetic circuit 1. Two control magnets 5 with a bias winding on each cover the opposite side of the middle core of the three-core magnetic circuit 1 and the ends abut against the controlled PMo 2 on the opposite sides. In the body of the magnetic cores 1 and 5 there are joints with gaps 6.

Three-phase magnetisable transformer operates as follows.

In idle mode, with non-submagnetised control magnetic cores 5, the primary magnetic flux generated by the primary coils 3 is closed through an average controlled rm 2. A small voltage is induced on the primary winding 4, which is connected to a part of the magnetic flux that is not closed through the middle controlled rmo 2.

In the operating mode, with increasing bias of the control magnetic cores 5, the magnetic flux decreases, which is closed through the average control romo 2. This leads to an increase in the magnetic flux through the sections of the rods of the three-core magnetic core 1, on which the secondary coils 4 are located. As a result, the voltage increases secondary winding 4.. To eliminate the occurrence of eddy currents in the circuits of the three-rod 1 and control magnetic circuits, there are joints with a gap 6.

The proposed solution allows us to simplify the design of the magnetisable transformer.

Formula and Three-Phase Three-phase magnetisable transformer containing a three-core magnetic core with a middle control tube, primary and secondary windings located on opposite sides of the middle frame, two U-shaped control magnetic cores with a bias winding on each plane that is perpendicular to one side of the three-core magnetic cores with a bias winding on each plane that is perpendicular to one side of the three-core magnetic cores with a bias winding on each plane that is perpendicular to the third magnetic core, with three bi-directional magnetic circuits on each plane with a bias magnetic winding on each plane with a three-core control magnetic cores with three magnetically wound magnetic windings on each plane with a biasing magnetic winding on each three-core magnetic cores with three secondary magnetic cores.

the wires, the ends of which abut against the driven rm, are located on opposite sides of the rim from opposite sides of the three-core magron, from the middle rod, characterized in that, for the purpose of the conduit, moreover, any contour of the magnification of the structure has At least one equalizing cores and a -5 joint with clearance.

Claims (1)

For m ul y zobre te n A three-phase magnetizable transformer containing a three-core magnetic core with an average control yoke, a primary and secondary windings located on opposite sides of the middle yoke, two U-shaped control magnetic circuits with a magnetization winding on each, whose planes are perpendicular to the plane of the three-core magnet * wire, the ends of which abut against the controlled yoke from opposite sides, characterized in that, in order to simplify the design, the joints between the control magnetic circuits and the controlled yoke ohms are located on opposite sides of the middle core of the three-core magnetic circuit, and any circuit of the magnetic system has at least one joint with a gap.