DE1813397A1 - Arrangement for holding one or more superconductive conductor strings inside a deeply cooled cable - Google Patents

Description

Cable and metal works 1 932

Gutehoffnungshütte AG _ . _f

Arrangement for holding one or more superconducting conductor strands inside a cryogenic cable

For the transmission of electrical energy, so-called cryogenic cables have become known, in which the cable strands are arranged inside a pipe filled with liquid helium or can also be corrugated to produce practically any length. A vacuum is maintained in the space between the innermost and the next following pipe, while the space between the second and third pipe is filled with liquid nitrogen to distribute the temperature gradient directed from inside to outside The space between the third and last tube, which is at room temperature, can again be evacuated hen is. λ

It is also already known that instead of a single conductor strand with conductors of large cross-section, several electrically connected in parallel Cable strands with conductors with a smaller cross-section should be selected. Lead, for example, are superconducting materials Niobium and some niobium alloys have become known. The conductors of the superconducting cable can consist of one of these materials or, since the energy transfer takes place, for example, by current displacement in a thin layer on the surface, also consist of other materials made of metal or plastic coated with a thin layer of superconducting materials * This layer can be created by electrolysis, by vapor deposition or, for example, by applying a thin metal strip.

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For holding one or more such superconducting conductor strands inside one of concentric tubes as thermal protection built-up cryogenic cable is already there thought to fix the conductor strands at certain intervals with spacers. However, the disadvantage here was that that in the spaces between every two adjacent spacers the constant distance, for example between three Phase conductor could no longer be maintained because of the twisting. The insertion of a piece of pipe from a suitable Insulating material between two spacers has also not brought the desired success, since this results in considerable ferti-Il technical difficulties arise.

To overcome these difficulties, the invention therefore takes a different approach. According to the invention, a profile strand is located in the innermost concentric tube, through the shape of which the conductor strand or strands distributed on its circumference continuously change their position relative to the cable axis over the length of the cable. Such a profile strand ensures a constant distance, for example, between the three phase conductors of a power transmission cable, with the best possible field distribution being achieved at the same time due to the continuous change in position of the conductors relative to the cable axis. Moreover, the use of such a profile strand brings considerable manufacturing advantages with it because the conductor strands are applied with- ψ means of known Verseilverfahren the miteinlaufenden profile strand.

This is especially true when in implementation of the inventive concept the extruded profile from a cross-sectionally star-shaped, longitudinally twisted carrier body made of an insulating material, for example a plastic. In this case you will namely the profile strand by means of a suitable molding tool twist and then run the prepared strand together with the superconductive strands into the Verseilnajpel permit. Finally, the plastic is relaxed, e.g. by the action of heat, so that the strand acts as a carrier for the split conductor strands most favorable shape retains.

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The profile strand advantageously has an in
Longitudinal bore on *. The reduction in the moment of resistance achieved in this way is a special one
slight twisting of the strand possible. If desired, can
the hole in the extruded profile can also be used to accommodate a separate tension element in the extruded profile, so that the tensile strength of the strand is considerably increased.

If the profile strand is made of a plastic whose coefficient of expansion differs significantly from that of the metal used for the superconducting conductor strands, it is
it is often useful to interrupt the profile strand in the longitudinal direction to compensate for the different expansion coefficients. |

Polyethylene, polyamide, for example also in the form of a foam, or also polyphenylene oxide can be selected as materials for the profile strand carrying the superconducting conductor strands
the latter being characterized by a coefficient of expansion
which is close to that of copper.

In order to fix the profile strand with the superconducting conductor strands, for example from superconducting layers such as lead, niobium and the like, attached to a suitable carrier in the innermost coaxial tube, it is particularly advantageous to use a helix over the conductor or conductors steady on the profile strand example
of a cold-resistant plastic, to apply whose strength is a measure of the distance i between the conductor and the tube wall.

The invention will be explained in more detail with reference to the embodiment shown in the figure.

To operate an electrical cable in a superconducting state consisting of smooth or corrugated tubes arranged concentrically to one another, the innermost tube 1 contains, for example, liquid helium at a temperature of about 4 K. Inside this tube, surrounded by liquid helium, the conductor strands 2 are arranged, which are constructed from a carrier 3 made of metal or a cold-resistant insulating material and the superconducting layer k . The superconducting layer 4, for example lead, or niobium
a niobium alloy, can be electrolytically or by

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be applied vapor, or by the fact that a longitudinally running Thin-walled sheet metal formed around the carrier to form a pipe, welded at the edges and in the same operation on the Carrier is pulled down.

To ensure that the distance between the three conductor strands 2 of the power transmission cable over the entire length of the cable is constant and, moreover, the twisting of the conductor strands, which is necessary for electrical reasons, is guaranteed Carrier for the conductor strands of the star-shaped profile strand 5 with its offset by 120 in the exemplary embodiment for three conductor strands Ribs provided. This shaped strand is twisted over its entire length so that the conductor strands over the length of the cable continuously change their position in relation to the cable axis. In the example shown, the extruded profile 5 consists of an insulating material, for example a cold-resistant plastic, which is relaxed after twisting, so that together with the conductor strands in one Stranding nipple (not shown) does not turn back the incoming strand and thus leads to a change in the position of the conductor strands in relation to the tube 1. To reduce the moment of resistance when twisting, the profile strand 5 points in the axial direction extending bore 6, which may be used to receive a Tensile element can be used.

Over the conductor strands 2, the insulating strand 7, e.g. a plastic thread, applied helically. This insulating strand gives the in the profile of the strand 5 stored conductor strands an additional Halt and also acts as a spacer to ensure that the position of the conductor strands in relation to the inner wall of the im Embodiment of a smooth, but also advantageously corrugated tube 1 is not changed. The constant distance between the individual strands required for electrical reasons and from the The inner wall of the pipe is thus always guaranteed. This applies to both the manufacture of the cable and the application of the other pipes serving as thermal insulation when the finished product is rolled up Cables, during laying and during operation.

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Claims (7)

18133S7 Cable and Metal Works 1 932 Gutehof fnungshütte AG, - .-> i. , nca * 5 December 1960 Pat en tanspriiche 1.) Arrangement for holding one or more superconducting conductor strands inside one of concentric tubes as Thermal insulation built-up cryogenic cable, marked by a profile strand located in the innermost concentric tube, by the shape of which the one or more on his Circumferentially distributed conductor strands over the length of the cable continuously change their position in relation to the cable axis. 2. Arrangement according to claim 1, characterized in that the profile strand consists of a star-shaped in cross section, in the longitudinal direction twisted carrier grain .i consists of an insulating material . 3 · Arrangement according to claim 2, characterized in that the Carrier body consists of a plastic that is relaxed after twisting. k. Arrangement according to claim 1, characterized in that the pro | fiLstrang is pierced in its center in the longitudinal direction. 5. Arrangement according to claim 4, characterized in that a separate tension element in the longitudinally extending bore is arranged. 6. Arrangement according to claim 1, characterized in that the profile strand is interrupted in the longitudinal direction. 7. Arrangement according to claim 1 or one of the following, characterized in that over the one or more conductor strands on the profile strand a coil, e.g. made of a cold-resistant plastic, is attached. 009625/1025 Blank page