SU1515210A1 - Induction device - Google Patents

Abstract

The invention relates to converter equipment and can be used in power sources of electrical and electronic equipment for various purposes. The purpose of the invention is to expand the field of application by creating a high-power planar structure. The device consists of high-current secondary windings 1, 2, representing one turn of the bent insulated bus. The windings 1, 2 cover the primary winding 4 along the perimeter. The cores 6 are placed on the windings 1, 2, 4 in such a way that their end surfaces are in contact, and the outer edges lie in the same plane. The joints 7 of the cores 6 lie in different, parallel planes and are blocked by the adjacent cores 6. By eliminating the process of winding with a large cross-section wire that is not amenable to automation, the processability of the device is improved. 1 hp f-ly, 2 ill.

Description

(L

Phi ".g

315I52IO4

The joints 7 of the cores 6 lie in different large sections that are not amenable to parallel planes and are blocked by automation; they are provided with higher adjacent cores 6. Thanks to the technological effectiveness of the device and the elimination of the process of winding the wire. . f-ly, 2 ill.

The invention relates to converter equipment and can be used in the design of power sources for electrical and electronic equipment for various purposes, including power sources for low output voltages (2-5 V) and high load currents (above JOOO A), particulars for high-speed (over 100 million operations per second) computers.

The purpose of the invention is to expand the field of application by creating a high-power planar structure (with a load of 100 A and above and for voltages of 220 V and more).

FIG. 1 shows a three-winding induction device, a general view; in fig. 2 - dependence of specific xa

transformer aff.l characteristics from

Ct

the number n of the cores of magnetic circuits,

where r

4OO

- POWER of the transformer

at 400 Hz power (kV A); G - transformer weight kg.

An induction device, in particular a three-winding transformer (Fig. Y) f, consists of high-current secondary windings and 2, representing one coil of a bent insulated tire (or foil) or a semi-turn insulated straight tire (or foil), with insulation 3 between them. Winding 1 and 2 cover the perimeter of the primary winding 4 with insulation 5, wound on a mandrel or sleeve (not shown). The cores 6 are placed on the windings 1, 2 and 4 in such a way that their end surfaces are in contact, and the outer faces lie in the same plane. The junctions 7 of the cores 6 lie in different parallel planes and are covered by the adjacent cores 6. The design of the throttles is similar to that described except for the number of windings.

As can be seen from FIG. 2, the optimal number of cores, of which

from 0

five

about

five

Q with

0

five

The magnetic core is dialed, lies in the range of 6-20.

The proposed induction device can be manufactured for any load and voltage currents, including very high currents, to have (for transformers) any transformation ratios that provide virtually any output voltage for a single-phase or three-phase AC network, high reliability and durability ( especially when operating at high load currents) as well as better (by 25-50%) specific characteristics as compared with parallel transformers or throttles.

The proposed induction device has no length limitations, has a small height and a large contact surface with a cooling chassis, which makes it optimal for use in the conductive-liquid method of cooling REA.

The proposed technical solution allows improving the manufacturability of transformers and chokes, as it allows to exclude the process of winding with a large cross section, which is not amenable to automation, which, taking into account the reduction in the flow of the mother wire, allows reducing their cost.

Claims (2)

1. An induction device containing primary and secondary windings, equipped with a magnetic circuit consisting of a set of identical cores arranged axisymmetrically, characterized in that in order to expand the field of application by creating a high-power planar design, each core is split, the cores are in contact with each other. the other end surfaces, the joints of the adjacent cores are located in different planes parallel to each other. 515152 I O 2. The device according to claim 1, characterized in that the ratio of the length of the magnetic circuit to the number of cores lies in the following lah P (j NVA NG  8 10 1 p 16 18 20 72 2 26 78 (pus. 2  20, p magnetic length; number of cores.  26