RU67770U1 - CURRENT LIMITING REACTOR - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, to transformer construction, and can find application in power, in particular, current-limiting reactors.

A useful model solves the problem of creating a current-limiting reactor, in which sufficient uniformity of current distribution is ensured, its manufacture does not present great technological difficulties while minimizing the investment of active and insulating materials and improving the overall dimensions.

To solve the problem in a current-limiting reactor containing a cylindrical winding made of turns, each of which contains f parallel wires, where f is an integer, f≥4, the turns form m rows, where m is an integer, m≥4, located in the axial direction perpendicular to the axis of the winding, the wires in a row in a radial size are placed between the inner and outer diameter of the winding in n positions, where n is an integer, n≥4, from the first position on the inner diameter to the n-th position on the outer diameter, at the same time in places x transitions of wires from each previous row to the next transposition of parallel wires is performed, and, at the places of transitions of wires from each odd row, counting from the bottom, to the next even row, a general transposition of all parallel wires is made, it is proposed, according to this utility model, at least in one place where the wires move from an even row to an odd transposition, proceed as follows: divide the wires into two groups so that in each group of wires in the specified odd row there is there would be only one wire, part of the length of which is located in the nth position.

Description

The utility model relates to electrical engineering, in particular, to transformer construction, and can find application in power, in particular, current-limiting reactors.

Known current-limiting reactor containing a cylindrical winding made of turns, each of which contains f parallel wires, where f is an integer, f≥4, turns form m rows, where m is an integer, m≥4, located in the axial direction perpendicular to the axis of the winding, wires in a row in a radial size are placed between the inner and outer diameter of the winding in n positions, where n is an integer, n≥4, from the first position on the inner diameter to the n-th position on the outer diameter, while in places wire transitions from to each previous row to the next, a circular transposition of parallel wires is performed in such a way that the first wire of each previous row takes the place of the f-th wire of each subsequent row, and all other wires occupy places in the subsequent rows that differ from their corresponding places in the previous rows by one wire [L. one].

Current-limiting reactor described in [L. 1] of the design has a number of technological drawbacks: when rearranging the first parallel wire of the previous row to the last place in the row of the next row, this wire intersects the other wires, which leads to an increase in the distance between the rows to accommodate the permutations of the wires and to provide the required insulation strength between turns of rows. The noted features do not allow to achieve optimal weight and size indicators, which is caused by the need to provide increased insulation gaps between the rows, and also leads to the creation of additional technological difficulties when performing

transposition, especially on the inner diameter of the winding, where the distance between the gaskets is very limited.

Also known is a current-limiting reactor containing a cylindrical winding made of turns, each of which contains f parallel wires, where f is an integer, f≥4, turns form m rows, where m is an integer, m≥4, located in the axial perpendicular to the axis of the winding, wires in a row in a radial dimension are placed between the inner and outer diameter of the winding in n positions, where n is an integer, n≥4, from the first position on the inner diameter to the n-th position on the outer diameter, places of transitions wire in from each previous row to the next transposition of parallel wires is made; moreover, in the places of transitions of wires from each odd row to the next even row, a general transposition of all parallel wires is performed, in the places of transitions of wires from each even to the next odd row, the transposition is performed so that the wire located in an even row in (n-1 ) -th position, takes the first position in the next odd row, the wire located in the even row in the (n-2) -th position, takes the second position in the next odd row, etc., respectively, the wire located in the even row in the 2nd position In the next odd row, takes the (n-2) -th position, a wire located in the even row in the first position takes the (n-1) -th position in the next odd row [L. 2].

Current-limiting reactor described in [L. 2] design is characterized, in comparison with the current-limiting reactor described in [L. 2], higher manufacturability due to the lack of intersection of parallel wires at the transitions from the previous row to the next. However, in order to achieve a uniform distribution of current across parallel wires, such a reactor must have a number of rows of wires equal to or a multiple of twice the number of parallel wires. The fulfillment of this condition in many cases leads to the impossibility of optimal design

the reactor. At the same time, the created reactor is characterized by insufficiently good overall dimensions.

A useful model solves the problem of creating a current-limiting reactor, in which sufficient uniformity of current distribution is ensured, its manufacture does not present great technological difficulties while minimizing the investment of active and insulating materials and improving the overall dimensions.

To solve the problem in a current-limiting reactor containing a cylindrical winding made of turns, each of which contains f parallel wires, where f is an integer, f≥4, the turns form m rows, where m is an integer, m≥4, located in the axial direction perpendicular to the axis of the winding, the wires in a row in a radial size are placed between the inner and outer diameter of the winding in n positions, where n is an integer, n≥4, from the first position on the inner diameter to the n-th position on the outer diameter, at the same time in places x transitions of wires from each previous row to the next one performed a transposition of parallel wires, moreover, at the places of transitions of wires from each odd row, counting from the bottom of the row to the next even row, a general transposition of all parallel wires was made, it is proposed, according to this utility model, at least in one place where the wires go from an even row to an odd transposition, proceed as follows: divide the wires into two groups so that in each group in the specified odd row there is only one wire, part of the length of which is located in the nth position.

The utility model is illustrated by an example of the drawings: Fig. 1 schematically shows a section through a winding of a current-limiting reactor along its axis (the axis is indicated by a dash-dot line), and in Fig. 2 is a top view of a third row from below.

The current-limiting reactor contains a cylindrical winding made of twelve turns formed by six parallel wires 1, 2, 3, 4, 5, 6.

Each row in radial size contains two turns, each of which contains six parallel wires. So, in particular, the first row from the bottom in height is formed by two turns 7 and 8 and contains parallel wires 1, 2, 3, 4, 5, 6 in each turn, respectively. In the radial size, the wires occupy twelve positions: the wires 1, 2, 3, 4, 5, 6 of the second coil 8 occupy the positions from the 1st (on the inner diameter) to the 6th, and these same wires of the first coil 7 occupy the positions from 7 12th (last, 12th - on the outer diameter).

Similarly made following the height (counting from below) rows of turns forming a winding.

In the places of transitions of wires from each previous to each subsequent row, the transposition of wires 1 ÷ 6 is performed. Moreover, in the places of transitions of wires 1 ÷ 6 from each odd to the corresponding even row, a general transposition of all parallel wires 1 ÷ 6 is made; in this case, the wire occupying the position with the number r in the previous odd row and, accordingly, with the number of turns in the row equal to two, the position with the number (r + n / 2), for example, the fifth and 5 + 12/2 = 11th, in the next even row, it occupies the position with numbers (n / 2 + 1-r) and (n + 1-r), for example, 12/2 + 1-5 = 2nd position and, accordingly, 12 + 1-5 = 8- th position. Specifically, in the first row from the bottom in height, the wire with number 5 occupies the 5th position in the radial direction and the 11th position, in the next row in height (counting in the winding direction from the bottom up) - the 2nd and 8th positions, respectively .

Similarly, the transposition is performed in the places of transitions of wires from the third row to the fourth, from the fifth to the sixth row, i.e. from odd to corresponding even row.

When moving from row to row to maintain a constant radial size, the windings along the circumference of the wire are rearranged sequentially in different segments. In the third row from the bottom row from the second row from the second, wire 1 first passes (see Fig. 2), wire 2 passes in the next segment along the circumference of the wire, then wires 3, 4, 5, 6 proceed in a similar way. 2, 3 are located next to both the 2nd and 3rd row, so they form the first group of wires 9. Similarly, wires 4, 5, 6 are located next to both the 2nd and 3rd row , so they form the second group of wires 10.

In the group of wires 9, only wire 1 partially passes in the 3rd row along the outer diameter of the winding, thereby being in the extreme 12th position in the radial direction. The wires 2 and 3 are included in the 3rd row in the 11th position, and then the numbers of the positions in which they are only decrease. Thus, in the group of wires 9 there is only one, wire 1, part of the length of which is located in the nth (n = 12) position.

In the group of wires 10, only wire 4 partially passes in the 3rd row along the outer diameter of the winding, thereby being in the extreme - 12th position in the radial direction. The wires 5 and 6 enter the 3rd row in the 11th position in the radial direction, and then the numbers of the positions in which they are only decrease. Thus, in the group of wires 10 there is only one wire 4, part of the length of which is located in the nth (n = 12) position. Similarly, the transposition was made during the transition of wires from the 4th row to the 5th. The use of transitions of the outer wire of an even row to the outer position of the odd row or to the position closest to the outer, as production practice has shown, does not lead to the need to increase the gaps between the rows.

The location of the wires in different positions in the radial size is presented in table No. 1. In it, in particular, it is shown how many times the wires are in different positions in the radial size.

Table number 1 Wire number Radial Position Number one 2 3 four 5 6 7 8 9 10 eleven 12 one one one one one one one one one one one one one 2 one one one one one one one one one one one one 3 one one one one one one one one one one one one four one one one one one one one one one one one one 5 one one one one one one one one one one one one 6 one one one one one one one one one one one one

Thus, since the wires are in each position in the radial size once, it can be concluded that the current distribution is good, which will occur when using the claimed technical solution.

When implementing the proposed solution with six parallel wires and two turns in each row, it was possible to complete a winding with a good current distribution in six rows, while using the technical solution according to [L. 2], it was possible to carry out a winding with a minimum number of rows equal to twelve, which with many combinations of parameters would not allow the creation of a current-limiting reactor close to optimal.

The claimed solution will allow you to perform a winding with twelve rows of parallel wires, while instead of one full cycle of transpositions of parallel wires in it there will be two full cycle of transposition. Thus, even in cases where the use of a technical solution according to [L. 2] allows the reactor to be made quite optimal, the application of the proposed technical solution improves the current distribution between parallel wires, thereby reducing the current of the most loaded wire and thereby increasing the electrodynamic resistance of the current-limiting reactor.

As the calculations showed, the implementation of the proposed technical solution in many cases will reduce the cost of the current-limiting reactor by 10 ÷ 12%, and in some cases by 25 ÷ 30%.

Currently, technical documentation is being developed for the production of a series of current-limiting reactors, in which the claimed technical solution will be implemented.

Literature:

1. V.G. Sternin, A.K. Karpensky / Dry current-limiting reactors / M., "Energy", 1965, p. 74, Fig. 2-8.

2. RF patent No. 2170466 for the invention, IPC H01F 27/30, H01F 27/28, 2001

Claims (1)

A current-limiting reactor containing a cylindrical winding made of turns, each of which contains f parallel wires, where f is an integer, f≥4, the turns form m rows, where m is an integer, m≥4, located in the axial direction perpendicular the axis of the winding, wires in a row in a radial size are placed between the inner and outer diameter of the winding in n positions, where n is an integer, n≥4, from the first position on the inner diameter to the n-th position on the outer diameter, while at the junctions wires from each pre of the next row in the next transposition of parallel wires is made, moreover, in the places of transitions of wires from each odd, counting from the bottom, row to the next even row, a general transposition of all parallel wires is made, characterized in that at least at one place of the transition of wires from an even row in an odd transposition, it is made so that the wires are divided into two groups, and in each group of wires in the specified odd row there is only one wire, part of the length of which is located in the nth position.