SU553946A3 - Superconducting cable - Google Patents

Description

one

This invention relates to the field of electrical engineering.

Superconducting cables are known, including several concentrically arranged pipes, thermal insulation and superconducting cores 1.

The disadvantage of such cables is the lack of flexibility and a rather large outer diameter.

Superconducting cables are also known, including several concentrically arranged corrugated tubes, thermal insulation and superconducting strands located with spacer elements at some distance from one another inside the central corrugated tube 2. However, these cables are not sufficiently flexible diameter.

The purpose of the invention is to increase flexibility and reduce the external diameter of the cable.

This goal is achieved by the fact that in a superconducting cable that includes several concentrically arranged corrugated tubes, thermal insulation and superconducting strands arranged using spacers at a certain distance from each other inside the central corrugated tube, strands from isolates are used as spacer elements material that are located along and between the superconducting strands and are twisted with them into a flexible rope.

In the central of the concentric tubes there is a profile element twisted from separate strands, due to the shape of which the position of one or several conductor strands distributed on its periphery relative to the cable axis continuously changes along the cable length. Such a profile element provides a constant distance, for example, between the three phase conductors of the cable, and at the same time

the best distribution of the floor due to the continuous change of the conductor position relative to the cable axis. In addition, the use of such a profile element provides significant technical advantages in terms of manufacture.

Polyethylene, polyamide, etc. can be used as material for spacers. To fix the electrical insulation

A strand with superconducting strands, for example, from superconducting layers deposited on a suitable carrier, such as lead, niobium, etc., in a central coaxial tube, it is especially expedient to wind the strand bundle with a spiral, for example, from a cold-resistant synthetic material whose thickness is a measure of the distance between the conductors and the pipe walls.

Electrically insulated strands can be made both solid and in the form of tubes, along which the cooling medium also moves. Superconducting strands can be either composite or composite, where the superconducting layer is deposited on a suitable carrier, for example, made of plastic or metal.

Conductive strands in separate layers may have the same or different sizes.

FIG. 1 shows a central tube of a superconducting cable with a bundle of superconducting and electrical insulating strands twisted into a rope; in fig. 2-5 are various embodiments of the twist of superconducting and electrically insulating strands.

Strands 2 of superconducting material, such as a niobium alloy, are located in the pipe 1 (shown in Fig. 1 is smooth but capable of being corrugated and filled with liquid helium). To ensure constant distance along the entire length of the cable between conductive strands 2 (the number in the example is three) on the central strand 3 (made in the form of a plastic thread) layer 4 strands made of the same material as strand 3 is placed. On the core thus formed, a layer is applied next with the opposite direction of winding from insulating strands 5 and superconducting strands 2.

The whole rope is wrapped, for example, in a spiral, with an insulating thread 6 so that the individual layers of the rope are connected, and at the same time a certain distance is established between the surface of the rope and the walls of the pipe 1.

Superconducting strands 2 can be made flat (Figs. 1 and 2) and in the form of tubes 7 of superconducting material (Fig. 3).

Superconducting strands of plastic or metal yarn 8 coated with a layer 9 of superconducting material can be used (Fig. 4); The superconducting strands can also be made in the form of plastic or metal tubes 10 coated with a superconducting layer 11 (Fig. 5). Regardless of which form is attached to the strands, flexibility is increased, the outer diameter of the cable is reduced, and its manufacture is simplified.

Claims (2)

1. The journal “Power Engng, 1961, 65, No. 10, p. 80-82. 2. The journal Elektrotechnik und Maschinenbau, 1965, 82, No. 6, pp. 275-280. . , / Qq /