DE2925638A1 - Stable superconducting cable - has stationary heat-absorbing medium in spaces between conductors, contacting coolant circulation pipe - Google Patents

Abstract

The superconducting cable for strong magnets winding eliminates instabilities of cooling the individual conductors by filling clearances between the conductors with a cooling medium. In addition, pipes 10 are provided for circulation of coolant which extracts heat from the stationary cooling medium in the clearances. The stationary medium can be in the form of helium under a supercritical pressure of over 10 bars. The gas then exhibits a high thermal capacity. The inside pipe 10 is made of copper and is surrounded by superconducting wires, copper wires 12 and steel wires 13 strands. The assembly is held by vacuum sealed steel casing 19.

Description

Superconducting cable

The present invention relates to a superconducting cable with several, Cable harnesses enclosed in a tight sheath.

Superconducting cables are preferably made very strong for winding Magnets are used, which are required, for example, in plants for nuclear fusion. The cables contain wires that, in some embodiments, are stranded into wire bundles or are entangled and each of which has a plurality of filaments made of a superconducting Has material enclosed in a matrix metal. With the division of the superconductor into thin filaments, a better magnetic stability is sought. The filaments in the wire are preferably twisted and the wires are entangled, intertwined or stranded in order to reduce the shielding currents and when the magnet is excited To suppress eddy currents if possible. Despite the measures described it has not yet been possible to use simple, superconducting cables to prevent spontaneous, to avoid local instabilities, in which the superconductor also with cooling passes below the transition temperature into the normally conductive state.

A known measure for stabilizing the superconductor provides to put another conductor parallel to the superconductor and this over its entire Length to connect electrically conductive with each other. The parallel conductor is dimensioned so that it can take over the entire current of the superconductor when the latter enters the normal conducting state passes. A cooling device is also provided which ensures that the temperature of the superconductor and the parallel conductor also then does not rise above the transition temperature when the power line from the parallel conductor is taken over. It goes without saying that this type of full stabilization is technical is quite complex and that fully stabilized cables have a cross-section which practically excludes their use for magnetic windings.

For those intended for high current densities and therefore for magnetic windings Particularly suitable, directly cooled waveguides are based on full stabilization dispensed with by means of parallel conductors and tried for a very effective transient To achieve stabilization. A suitable cable is given in DE-PS 1'908'885 (Kafka).

This cable contains a plurality of superconducting wires around a Insulator are wound, which includes an inner space and a vacuum-tight Sheath, between the inner wall and the wires further free spaces are provided. The patent describes two possibilities for cooling this cable, passing a flowing coolant through that enclosed by the shell Space or the introduction of a stationary coolant with a large heat storage capacity in the space enclosed by the shell and at the same time cooling the outside the shell with a flowing coolant.

To do this, the cable can be immersed in a coolant bath, or it can pipes through which the coolant flows are arranged on the outside of the casing.

The effectiveness of cooling an encased superconductor Recently, M. O. Hoenig et al (Proc. Appl.

Superconductor Conference, Pitburgh 1978). It could it can be demonstrated that a cable filled with stationary supercritical helium even with repeated instabilities caused by the application of heat again quickly returns to the steady state.

The present invention is therefore based on the object of a superconducting Create cable that takes advantage of the designs and findings described combined and is particularly well suited for the windings of very strong magnets.

According to the invention, this object is achieved with a superconducting cable solved, the at least two arranged inside the shell coolant lines has, one of which for introducing a suitable as a heat storage stationary and the other for passing a flowing coolant suitable for dissipating heat is provided.

The new cable has good thermal conductivity between the superconducting wires and the coolant lines for the stationary and the flowing Coolant a particularly effective transient stabilization, enables because of the dense arrangement of the superconducting wires a high current density and can, because it does not have to be cooled from the outside, to magnet coils with close-together Windings are wound.

The invention also relates to a method for cooling the new cable, in which method supercritical helium is preferred as the stationary coolant with a push of more than 10 bar and as a flowing coolant supercritical helium with a pressure of less than 10 bar is used.

The invention is illustrated below with the aid of the figures in some exemplary embodiments described. 1 shows the section through a first embodiment of the new cable, Fig. 2 is a partial section through another embodiment of the new Cable, Fig. 3 the schematic representation of a cable with the supply lines for the stationary and the flowing coolant, and FIG. 4 the schematic representation a magnet arranged in a pressure vessel, its winding with the new Cable is wrapped.

Fig. 1 shows the section through a simple embodiment of the new Cable. The cable contains an inner tube 10 made of a material that conducts heat well and preferably made of copper, which is provided as a conduit for the flowing coolant is. Around the inner pipe are superconducting wires 11, copper wires 12 and steel wires 13 stranded. The copper wires should enable partial stabilization and the Steel wires increase the strength and especially the tensile strength of the cable. The free spaces remaining between the stranded wires, e.g. spaces 15, 16, 17, which extend through the entire cable, form the line for the stationary coolants. The stranded wires are in a vacuum-tight and pressure-resistant Sleeve 19, the preferred wise made of steel, included.

The inner tube 10 is extended at the ends of the cable and to one Coolant circuit connected. The spaces 15, 16, 17 are at the ends of the Cable with a line or a storage vessel for a stationary coolant tied together.

Fig. 2 shows the partial section through another embodiment of the new cable. The cable contains a multitude of superconducting strands, such as the Strands 30, 31, each of which contains a copper tube, e.g. tubes 32, 33, around which a plurality of superconductive wires such as wires 34,35 are stranded. The strands are stranded to form strand bundles 37, 38. Every strand and every bundle of strands is with a sheathing, - e.g. sheathing 39, 40 resp.

41, which suppress eddy currents when the magnet is excited should. In the middle of the cable a steel cable 43 is arranged, which the mechanical Increased strength of the cable. The strand bundles are wrapped with a tape 44, that gives the cable bundle the necessary strength. The cable association is in a steel shell 45 is enclosed, and the shell is covered with an electrically insulating Surrounding material 47.

The spaces between the wires, the strands and the strand bundles, for example the spaces 36, 42; 50, 51 and 52 are at the ends of the cable connected to a line or a storage vessel for a stationary coolant. The pipes in the strands are carried out at the cable ends and connected to a coolant circuit connected.

Fig. 3 shows schematically the connection of a cable according to the Fig. 1 or 2 to a coolant line or to a storage vessel. The cable 55 is enclosed in a cryostat 56, for example, as at the embodiment according to FIG. 1, is designed as a vacuum jacketed vessel.

Closing caps 57, 58 are attached to the cable ends, into which the Ends of a first coolant line 60 protrude through which the free spaces in the Cable can be filled with a stationary coolant. This first coolant line consists simply of a coolant tank 61, which via a valve 62 with two precoolers 63, 64 is connected. These precoolers are high pressure coolers 66, 67 connected downstream, the output lines of which with the already mentioned, through the Closing caps in the cable protruding coolant lines are connected. Overpressure valves 68, 69 are installed in the outlet lines of the high-pressure coolers.

Further pipelines 71 are provided through each closure cap of the cable and 72, which are connected to the tubes inside the superconducting strands are. These pipelines are connected to one another via a pump 73 and a cooling device 74 connected and form a closed coolant circuit for the flowing coolant.

Fig. 4 shows schematically the section through a magnet whose Winding is wrapped with the new cable. The magnet 80 is in a pressure vessel 81 included, in the from a reservoir 82 via a valve 83 and a High-pressure cooler 84, a coolant is injected. The coolant penetrates all of them Free spaces between the wires, wire bundles and strands of the cable and fills this off. The cooling tubes dex superconducting strands are as in the scheme according to FIG Fig. 3 connected to a supply line SS and a discharge line 87, which lead to a coolant circuit belong, who is also already for di riZU? .g according to the Fig. 3 has been described. The pressure vessel 81 is built into a cryostat 88, the can be designed as a vacuum jacketed vessel or a thick layer of good thermal insulation Contains materials.

To cool the new cable can easily be done both for the stationary as well as supercritical helium can be used for the flowing coolant. the The heat capacity of supercritical helium is in the temperature range of superconductivity, i.e. at around 4 to 5 K more than 100 times greater than that for stabilization mainly used metals, copper or aluminum. This great heat capacity and the enable direct contact between the superconducting wires and the coolant, the heat that may arise in the event of instabilities immediately from the superconductor to be diverted into the stationary coolant. This enables the superconductor jump back to the superconducting state immediately after a transient disturbance can. The heat absorbed by the stationary coolant is absorbed by the flowing coolant continuously discharged so that the stationary coolant has the specified temperature retains practically unchanged even over a longer period of time.

Supercritical helium is preferably used as the stationary coolant with a pressure of more than 10 bar and as a flowing coolant supercritical Helium used with a pressure of less than 10 bar. From theoretical considerations it is known that the transient heat transfer coefficient depends on the thermal conductivity, depends on the density and the specific heat. Measurements have also shown that for helium at a temperature between 5 to 10 K by increasing the pressure of 10 bar to 60 bar the heat capacity calculated from the enthalpy by around the factor summary Superconducting cables often exhibit superconductivity instabilities, in particular when external magnetic fields act on the cable. So that such instabilities quickly disappear again, is a very effective cooling of the individual superconducting Wires required in the cable. With the new cable, the empty spaces (15, 16, 17) between the wires (11, 12, 13) and optionally wire bundles as lines or storage spaces for a stationary coolant used in direct heat exchange stands with the wires. There are also pipes (10) for a flowing coolant provided that dissipates the heat absorbed by the stationary coolant as stationary Coolant with increased heat storage capacity is preferably supercritical Helium used at a pressure greater than 10 bar.

Description list 10 = inner tube 11 = superconducting wire 12 = Copper wire 13 = steel wire 15-17 = free spaces 19 = sheath 30, 31 = superconducting Strands 32, 33 = copper pipes 34, 35 = superconducting wires 36 = free space 37, 38 = Strand bundle 39-41 = sheaths made of high-resistance material 42 = free space 43 = Steel cable 44 = tape 45 = steel sleeve 47 = electrically insulating material 50-52 = Free spaces 55 = cables 56 = cryostat 57, 58 = sealing caps 60 = coolant line 61 = coolant tank 62 = valve 63, 64 = precooler 66, 67 = high pressure cooler 68, 69 2 pressure relief valves 71, 72 = pipes 73 = pump 74 = cooling device 80 = magnet 81 = pressure vessel 82 = storage vessel 83 = valve 84 = high pressure cooler 86 = supply line 87 = discharge line 88 = cryostat L. e e r e i t e

Claims (4)

Claims 1. \ Superconducting cable with several in one seal Sheath enclosed cable strands, characterized by at least two inside the casing arranged coolant lines, one of which (15, 16, 17) for introduction one suitable as a heat accumulator stationary and the other (10) for passing through a flowing coolant suitable for dissipating heat is provided. 2. Cable according to claim 1, characterized in that the cable strands (30) consist of tubes (32) around which a plurality of superconducting wires (34) are stranded are which pipes form one coolant line and the other coolant line from the free spaces (36, 42; 50, 51 resp. 52) between the wires, the harnesses and between the harnesses and the inner wall of the shell is formed. 3. A method for cooling a cable according to claim 1, characterized in that that as a coolant for the at least two coolant lines supercritical Helium is used. 4. The method according to claim 3, characterized in that as a stationary Coolant supercritical helium with a pressure of more than 10 bar and as flowing Coolant uses supercritical helium with a pressure of less than 10 bar will.