RU2699230C1 - Electric reactor controlled by magnetization - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the electrical equipment. Electric reactor, controlled by magnetization, comprises magnetic system with yokes and rods, main winding in form of coils, rods are made in the form of laminated packs and separated by non-magnetic clearance, control winding arranged orthogonally to coils of the main winding. Yokes are made in the form of C-shaped brackets bent in the longitudinal direction of the bonded W-shaped sheets of magnetically soft material, in the windows of which there is a magnetizing winding.EFFECT: reduced size of main winding, magnetic system, consumption of active materials, overall dimensions and reduced losses of electric power from scattering fields.1 cl, 2 dwg

Description

FIELD OF THE INVENTION

The invention relates to electrical engineering and energy, in particular to ferromagnetic devices controlled by magnetization.

State of the art

Known electrical reactors with magnetization, containing a magnetic system with yokes and rods, the main winding in the form of coils, a control winding placed orthogonally to the coils of the main winding, the charged magnetic core of the rod is made in the form of an armored core with side yokes, the core is located orthogonally relative to the axis of the coil of the main winding, and the core yokes are parallel to the axis of the main winding, the yokes are separated from the rods by non-magnetic gaps

(Description of the invention to the USSR copyright certificate No. 547852, IPC H01 F 29/14, bulletin No. 7 April 10, 1977; Description of the invention to the USSR copyright certificate No. 1020871, IPC H01 F 27/26 bulletin No. 20 1983; Description of the invention to USSR copyright certificate No. 2037224, IPC H01 F 29/14 Bulletin No. 5 of 1995).

These devices have a disadvantage - the significant size of the main winding, the magnetic system, due to the size of the control winding in the cross section of the main winding and the associated significant consumption of active materials, increased overall dimensions, as well as significant losses of electricity from the scattering fields of the main magnetic flux.

A longitudinally-transverse magnetization reactor is also known, comprising a magnetic system with yokes and rods, a main winding in the form of coils, a control winding placed orthogonally to the coils of the main winding, creating a magnetizing flux that closes within the W-shaped insert, the rod consists of W-shaped inserts separated by non-magnetic gaps. (Dorozhko L.I., Leitis L.V. Comparative analysis of various designs of controlled reactors. Article in J. "Electrical Engineering" No. 2, 1991, p. 22, Fig. 9), (prototype). This reactor also has a disadvantage - the significant size of the main winding, the magnetic system, due to the size of the control winding in the cross section of the main winding and the associated significant consumption of active materials, increased overall dimensions and significant energy losses from the scattering fields of the main magnetic flux.

Disclosure of invention

The aim of the invention is to reduce the size of the main winding, the magnetic system, the consumption of active materials, overall dimensions and energy loss from the scattering fields of the main magnetic flux. This goal is achieved by the fact that the reactor yokes are made in the form of C-shaped staples, bent in the longitudinal direction of the laced S-shaped sheets of magnetically soft material, in the windows of which there is a magnetizing winding installed orthogonally to the main windings.

Description of drawings

In FIG. 1 shows a General view of the proposed reactor. Figure 2 shows a cross section of a fragment of the yoke of the reactor.

The implementation of the invention

The proposed reactor contains coils of the working (main) winding 1, a magnetic system with rods 2 and yokes 3.. Each core of the magnetic system is a butt-jointed set of burnt bags. A non-magnetic gap is provided between the packets 4. The reactor yoke is composed of separate sheets of W-shaped sheets curved in the longitudinal direction into a C-shape. Assembled, the yoke is a C-shaped bracket. In the windows formed in the package by the yoke, a magnetization winding is installed in the form of DC coils 5, the axes of which are perpendicular to the axes of the main winding. The yoke 3 of the magnetic system of the reactor is adjacent to the rods 2, forming a closed magnetic system of the reactor.

The reactor operates as follows.

The coils of the main winding 1 are connected to an AC voltage source. The alternating current circulating in the main winding creates an alternating magnetic flux circulating through the rods and yokes. When the magnetization winding 5 is connected to an adjustable direct current source, it creates a magnetic field and changes the magnetic state with a jerk, saturating in narrowed areas from the combined effects of the alternating current and direct current fields. With increasing current in the magnetization winding, the intensity from the indicated magnetic fields in yokes increases accordingly, and their magnetic permeability decreases. With a decrease in the magnetic permeability of the latter, the magnetic resistance in the path of the alternating flux increases and, accordingly, the current in the main winding increases. Thus, by changing the current in the control winding, it is possible to change the amount of current in the main winding.

The execution of the core of the reactor in the form of C-shaped staples, curved in the longitudinal direction of the laced Sh-shaped sheets of magnetically soft material and the placement of the magnetization winding in yokes orthogonally to the main windings makes it possible to reduce the dimensions of the cross section of the reactor core, leading to a decrease in the dimensions of the main winding and overall dimensions of the reactor as a whole. Therefore, in this reactor the consumption of active materials is reduced in comparison with the known reactors.

A decrease in the size of the main winding, in turn, leads to a decrease in the scattering fields of the main magnetic flux and a decrease in the loss of electricity from the scattering fields of this magnetic flux.

Claims (1)

A magnetization controlled electric reactor containing a magnetic system with yokes and rods, a main winding in the form of coils, a control winding placed orthogonally to the coils of the main winding, the charged magnetic core of the rod are separated by a non-magnetic gap, characterized in that the reactor yokes are made in the form of C-shaped staples, bent in the longitudinal direction of the burdened Sh-shaped sheets of soft magnetic material, in the windows of which there is a magnetizing winding.

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