RU2390064C1 - Superconducting multiple-core wire for dc and ac - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: superconducting multiple-core wire comprises outer insulation shell, matrix from stabilising material, with superconducting modules of circular section arranged in it and adjacent to each other, in matrix of which there are superconducting cores of circular section arranged with superconducting current-bearing elements arranged longitudinally to central axial core and adjacent to inner shell of module. At the same time diametre of module equals three diametres of superconducting core, and ratio of core cross section area to area of module cross section equals 0.77 0.78, and ratio of core cross section area to area of wire cross section equals 0.61, besides superconducing modules are arranged in the form of multilayer structure and are arranged in parallel rows. Section of wire may be arranged as square. ^ EFFECT: increased current-bearing property of wire in process of AC and DC passage with improvement of technical and economic indices due to simplification of wire manufacturing technology and improvement of its reliability. ^ 2 cl, 1 dwg

Description

The invention relates to the field of electrical engineering, in particular to the design of multicore superconducting wires for alternating and constant currents.

The known design of a flat, monolithic stranded superconducting wire obtained by the method of single-strand twisting with molding. Transposing such a wire minimizes the additional currents in the matrix of the stabilizing material of the wire (Adam B., Dickson J., Gregory E., Advanced conductor configurations for large magnets, IEEE Transactions on Magneties, 1977, v. MAG-13, No. 1 , p. 458-462).

The disadvantage of this design is the presence of an uncompensated magnetic field created by transport currents flowing in current-carrying superconducting elements, which leads to a decrease in the magnitude of these currents, an increase in AC losses, an increase in the consumption of electricity and refrigerant. The low current-carrying capacity of such a wire leads to the need to increase the number of such wires, to connect them in parallel to perform superconducting windings of electromagnetic devices or current-carrying elements of superconducting DC and AC cables, which greatly complicates and increases the cost of their manufacturing technology, leads to the degradation of transport currents in these devices due to mechanical impact on a superconductor.

Known is a superconducting multicore ribbon wire of rectangular cross section for alternating and constant currents, containing a matrix of stabilizing material, in which superconducting circular modules are installed, installed in one layer and adjacent to each other, the modules are made with superconducting veins of circular cross section, located inside the module matrix, longitudinally with the central axial core and adjacent to the inner shell of the module, the current-carrying superconducting elements are evenly distributed across th section lived in the matrix core so that each individual current-carrying superconducting element located in the magnetic field produced by current of the element, the influence of external magnetic fields produced by currents of adjacent current-carrying elements, with practically zero. Thus, each core, each module and the entire wire are in their own magnetic field, equal to the magnetic field of a separate current-carrying element. The current carrying capacity of the superconducting wire is maximum, and losses, consumption of superconducting material, refrigerant are minimal (US Pat. RF No. 2334293, BI No. 26, 2008).

However, if it is necessary to obtain large capacities in superconducting electrical equipment (for example, superconducting DC and AC cables), the throughput of such a single-layer wire will be insufficient, which will require a large number of such wires connected in parallel in bundles, bundles, etc., which complicates the manufacturing technology of superconducting electrical equipment, reduces the current density in a multi-wire combined wire made in this way, and worsens its technical performance indicators and reliability.

The objective of the present invention is to eliminate this drawback, that is, increase the current carrying capacity of the wire when passing constant and alternating currents while improving technical and economic indicators by simplifying the manufacturing technology of the wire and improving its reliability.

The specified technical result is achieved by the fact that in the superconducting stranded wire for alternating and direct currents containing an external insulating sheath, a matrix of stabilizing material with superconducting circular modules placed therein adjacent to each other, in the matrix of which superconducting circular conductors with superconducting current-carrying elements located longitudinally with the central axial core and adjacent to the inner shell of the module, while the diameter of the module is equal to three diameters of the superconducting core, the ratio of the cross-sectional area of the wires S _W to the cross-sectional area of the module S _m is:

and the ratio of the cross-sectional area of the conductors E _w to the cross-sectional area of the wire S _p is equal to:

and the matrix of the superconducting wire contains superconducting modules made in the form of a multilayer structure and placed in parallel rows. The cross section of the superconducting stranded wire may be square. The number of modules in the layer and the number of layers in the cross section of the superconducting wire is determined by the required current carrying capacity of the wire and the power of the superconducting electrical equipment (cables, transformers, current limiters, etc.) in which the proposed wire should be used.

The drawing schematically shows the proposed superconducting stranded wire of rectangular cross section with the number of parallel layers (rows) equal to, for example, three and the number of modules in the layer equal to, for example, five.

A superconducting stranded wire for alternating and direct currents 1 with an outer insulating sheath 2 contains round-section superconducting modules 4 made of a stabilizing material in a matrix 3 made of a stabilizing material, made in the form of a multilayer structure and arranged in parallel rows, and each of the modules 4 of the wire 1 includes superconducting conductors 5 , pressed into the matrix 6 of the module 4, while over the entire cross section of the cores 5 in the matrix 7 of the cores 5 are uniformly located superconducting current-carrying elements 8.

When connecting the electric power source to the superconducting electrical equipment based on the proposed stranded superconducting wire 1, the current will flow through the superconducting current-carrying elements 8. Moreover, each superconducting current-carrying element 8, each core 5, each module 4 and the entire superconducting multicore wire 1 will be in own localized magnetic field equal to the magnetic field of an individual superconducting current-carrying element 8. Current-carrying capacity of such a superconductor The stranded stranded wire 1, the superconducting modules 4 of which are made in the form of a multilayer structure and are arranged in parallel rows, is maximum, and losses, consumption of superconducting material, and refrigerant are minimal. The current density in the proposed wire exceeds a similar value in multi-wire combined superconducting wires.

The fill factor of the SP wire of the SP wire, equal to the ratio of the cross-sectional area of the SP wire to the cross-sectional area of the SP wire, is determined as follows:

if the number of modules arranged in a row along the length of the cross section of the wire is, for example, “a”, and in width, respectively, “b”, then the length of the cross section of the wire 1 will be - d _m · a, width - d _m · at.

d _m is the diameter of the superconducting module.

The cross-sectional area of the wire is:

Given that the diameter of the module is d _m = 3d _w , where d _w is the diameter of the core, then the cross-sectional area of wire 1 is:

The cross-sectional area of one core 5 is equal to:

The cross-sectional area of all cores 5 of one module 4 is equal to:

The cross-sectional area of all cores 5 of wire 1 is equal to:

Then the ratio of the cross-sectional area of all superconducting veins to the cross-sectional area of the wire:

This ratio is the most important parameter of high-power superconducting stranded wires for energy purposes and in combination with superconducting modules made in the form of a multilayer structure and placed in parallel rows in a matrix of a superconducting wire, it allows to obtain a highly efficient superconducting wire. The superconducting stranded wires made on this basis will have a high current-carrying capacity (the values of critical currents and current density in them will increase significantly), which will increase the power of those superconducting devices in which they will be used. At the same time, the technical and economic indicators of such wires are improving, because the consumption of superconducting material decreases, the electricity associated with the cooling of wires, etc., their reliability increases.

The proposed design of a superconducting stranded wire for alternating and constant currents will significantly increase the current-carrying, throughput, power of the wire, simplify the manufacturing technology of stranded superconducting wires and energy devices based on them, improve technical and economic performance and reliability of powerful superconducting electrical equipment. The number of modules in one row and the number of rows in such a multilayer stranded wire can be increased to almost any size without the danger of transferring such a wire from a superconducting to a normal state (emergency mode).

If necessary, the cross section of such a multilayer stranded superconducting wire can be made square. A particular advantage of the proposed multilayer superconducting wire is the simplification of the manufacturing technology of superconducting AC and DC cables from it, since at present such cables are made by winding a single-layer ribbon wire with a predetermined value of its bend onto the pipe (former), which is a complex technological process. The current density in cables manufactured in this way is reduced, since during winding of the superconducting tape an inter-brew space is formed that is not filled with current during cable operation. A superconducting, stranded, multilayer wire of rectangular or square cross section will significantly simplify the manufacture of superconducting cables, increase the current density in them, reduce the cost of their manufacturing technology, and increase reliability.

The proposed superconducting, stranded, multilayer wire of rectangular or square cross section with a localized magnetic field is intended for use in electrical and electromagnetic superconducting systems of alternating and direct current energy purposes (cables, transformers, power windings of electrical machines, etc.). It will provide a large current-carrying capacity, reducing losses of superconducting material, refrigerant, simplifying the manufacturing technology of both the wire itself and the superconducting electrical equipment in which it will be used, and will increase the technical and economic performance and reliability of these systems.

Claims (2)

1. A superconducting stranded wire for alternating and constant currents, containing an outer insulating sheath, a matrix of stabilizing material with superconducting circular modules placed in it adjacent to each other, in a matrix of which superconducting circular conductors with superconducting current-carrying elements are placed longitudinally with central axial core and adjacent to the inner shell of the module, while the diameter of the module is equal to three diameters of the superconducting core, the area ratio and the cross section of the veins S _W to the cross-sectional area of the module S _m is equal to:

and the ratio of the cross-sectional area of the wires S _W to the cross-sectional area of the wire S _p is equal to:

characterized in that in the matrix of the superconducting wire, the superconducting modules are made in the form of a multilayer structure and are arranged in parallel rows. 2. The superconducting stranded wire for alternating and direct currents according to claim 1, characterized in that the wire cross section is square.