RU62736U1 - DOUBLE REACTOR - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, to transformer construction, and can find application in reactor designs having two layered cylindrical coils forming parallel branches. A useful model solves the problem of creating a dual reactor, characterized by wide functionality to provide the required coupling coefficient between parallel branches of the coils. To solve the problem in a dual reactor containing two cylindrical coils with series-connected turns made of n parallel wires, where n≥2, cylindrical coils form two branches alternating in height of the reactor, it is proposed, according to this utility model, to make each branch of two parts, with each part of one branch arranged alternately in the radial direction with a part of the other branch.

Description

The utility model relates to electrical engineering, in particular, to transformer construction, and can find application in reactor designs having two layered cylindrical coils forming parallel branches.

Known dual reactor containing two cylindrical coils with series-connected turns made of n parallel wires, where n≥2, cylindrical coils form two branches, alternating in height of the reactor [L. one].

Described in [L. 1] a dual reactor is characterized by limited functionality to ensure the choice of mutual inductance within the required limits, and, therefore, does not allow to provide the required coupling coefficient between parallel branches of the coils, which ultimately leads to increased mass-dimensional characteristics of the entire reactor.

A useful model solves the problem of creating a dual reactor, characterized by wide functionality to provide the required coupling coefficient between parallel branches of the coils.

To solve the problem in a dual reactor containing two cylindrical coils with series-connected turns made of n parallel wires, where n≥2, cylindrical coils form two branches alternating in height of the reactor, it is proposed, according to this utility model, to make each branch of two parts, with each part of one branch arranged alternately in the radial direction with a part of the other branch.

The utility model is illustrated by the drawing, which shows a schematic front view of the inventive dual reactor.

A dual reactor contains two cylindrical coils with series-connected turns forming two branches 1 and 2, alternating along the height of the reactor and arranged vertically floor-by-floor at two levels 3 and 4.

Each of branches 1 and 2 is a layered cylindrical coil with successively connected turns divided into two parts: branch 1 is divided into parts 5 and 6, and branch 2 is divided into parts 7 and 8.

Parts of the coils occupy different positions in the radial direction. Part 5 belonging to branch 1 occupies an internal position (I) at the upper level 3, and part 6 belonging to the same branch 1 occupies an external position (II) at a lower level 4. Part 7 belonging to branch 2 occupies an external position ( II) at the upper level 3, and part 8, belonging to the same branch 2, occupies the internal position (I) at the lower level 4, i.e. each part of branch 1 is arranged alternately in the radial direction with a part of branch 2.

The distances between the parts of the coils in the radial direction (between their positions: I and II, respectively) are indicated in figure 1 as "X", between floors 3 and 4 - "Y", the height of each floor is "Y ₁ ".

The coupling coefficient between two branches is determined by the following relationship:

K _c = M / L _branches , where

M mutual inductance between branches 1 and 2;

L _branches - self-inductance of each branch 1 and 2.

The location of the parts of coils 5 and 6 belonging to one branch 1 at different levels 3 and 4 in height, and the parts of coils 7 and 8 belonging to another branch 2, also at different levels 3 and 4 in height, and the location

them in such a way that the parts of the coils belonging to the same branch occupy different positions in the radial direction, provides a significant length of their proximity relative to each other: at a distance of 2 Y ₁ and Y.

By varying these dimensions, namely, X, Y, and Y ₁ , it is possible to vary the mutual inductance over a wide range and provide the required value of the coupling coefficient, while obtaining the optimal dimensions, and, consequently, the mass-dimensional characteristics of the entire reactor as a whole.

Literature:

1. V.G. Sternin, A.K. Karpensky / Dry current-limiting reactors, Energia Publishing House, Moscow - Leningrad, pp. 37-38.

Claims (1)

A dual reactor containing two cylindrical coils with series-connected turns made of n parallel wires, where n≥2, cylindrical coils form two branches, alternating along the height of the reactor, characterized in that each branch is made of two parts, each part of one branches located alternating in the radial direction with part of another branch.