DE3823938A1 - Insulation around a stabilised superconductor and method of production thereof - Google Patents

Abstract

A stabilised superconductor with approximately rectangular cross-section is surrounded by an electrical insulation. The insulation is provided with holes, in which unimpaired access of a coolant to the surface area of the superconductor is made possible. This insulation is to be easy to prepare and is to allow good cooling of the conductor with sufficiently high mechanical strength. For this purpose, the holes (10a to 10c) are subsequently made, in the region of at least one of the side faces (6a, 6b, 7a, 7b) of the superconductor (3 to 5), in the insulation (9) which initially completely surrounds the superconductor (3 to 5). A laser beam may advantageously be provided for making the holes. <IMAGE>

Description

The invention relates to electrical insulation certain mechanical strength around a stabilized Superconductors with at least a largely rectangular cross section, which is provided with recesses in which an unobstructed Access of a coolant to the surface of the superconductor is possible. The invention further relates to a method for Creation of such isolation. Correspondingly isolated Superconductors are e.g. from the publication "IEEE Trans actions on Magnetics ", vol. MAG-19, No. 3, May 1983, pages 189 known until 194.

As is known, superconducting windings can be used to make magnets fields with magnetic flux densities e.g. over 1 Tesla (T) generate particularly advantageous. In such superconducting wick In many cases, the conductor material is its critical current density (current carrying capacity) in particular highly exploited and / or mechanically particularly strong speaks. It then turns out, however, that the windings are too a so-called "training" tend. Under this phenomenon is to understand that the ladder is already small Current values change to the normal conductive state. they must therefore be cooled down again to the operating temperature and only reach the design value of their excitation current some or many cooling and excitation cycles (see e.g. "IEEE Transactions on Magnetics", Vol. MAG-17, No. Jan 1 1981, pages 863 to 872). As the main cause of such Training are viewed small local energy dissipations, e.g. due to ladder movements or crack propagation in the  Structural or insulation material are triggered.

Typical examples of highly utilized, heavily used Windings, the rotating field windings are more superconducting Generators and the elongated or curved ones, often non-planar partial windings of beam guidance magnets for high energy physics. Above all, this is used stranded, sometimes massive superconductors, which in general my rectangular or almost rectangular cross-sections point (see e.g. DE-OS 26 54 924 or DE-PS 16 14 582).

So that corresponding windings with such superconductors can be operated as training-free as possible, the electrical insulation of the conductors used must be designed and designed so that they allow a high mechanical pressure or pretension to fix the conductor in the winding network even with a small space requirement. Forces occurring here are typically in the range from 10 to 30 N / mm ² . In addition, effective cooling with reliable insulation must be ensured during operation. For this reason, the insulation should at least in places allow coolant to enter the conductor surface directly and allow winding voltages between adjacent conductors in the range of a few 100 V and voltages to ground, typically of several kV.

So far, such wick has been used for rectangular superconductors lungs essentially implemented the following insulation concepts light:

• a) Lacquer-insulated solid conductors were, for example, by a Wet winding technology or a vacuum pressure impregnation placed. This is a good mechanical fixation the leader reached; however, the isolation is only medium moderate. The cooling of the conductors is also severely hampered.
• b) The superconductors are filled with foil or fabric tapes  banded, possibly using fixing resin becomes. However, the same difficulties arise here as in concept a).
• c) There is also a full conversion with foil tapes see around which is also a layer of fabric tape Distance is wrapped. In this way arise around the Conductor around channels for a coolant passage. Yet are only a moderate fixation, moderate isolation and to achieve moderate cooling.
• d) The superconductor is used only with strong, on Ab stood wrapped foil tapes banded so that the lei The surface is partially wetted directly by the coolant that can. The cooling is accordingly good; however can fixation and insulation problems occur here.
• e) A bare superconducting flat conductor is used during winding a winding insulation in the form of prefabricated strips or molded parts included. A flank part isolation takes place in combination with a groove clothing or with included strips. Hereby are good mechanical pressability and also sufficient the cooling effect achieved; however, the isolation is moderate. In addition, the manufacturing effort is particularly at ge cranked windings very high.

The object of the present invention is now the isolation of the type mentioned in such a way that they can be produced in a relatively simple manner, the problems with the insulation concepts mentioned at least largely should not be given.

This object is achieved in that in the insulation completely surrounding the superconductor sluggish the recesses in the area of at least one of the be surface of the superconductor are incorporated.  

With this configuration of the isolation, in particular the following advantages: an insulating varnish or an um striped insulating film can be used only from the point of view of Reliability of the insulation, the mechanical strength the production and operation, as well as the processability at Winding and bending of the conductor can be designed. It needs advantageously no consideration given to cooling requirements will. This can lead to creepage distances from conductor to conductor significantly larger than twice the insulation thickness because the insulation is definitely the conductor edges of each Encompasses superconductor. The provided in known concepts Cooling openings in insulation tapes can consequently occur during winding do not slip on the conductor surface. Furthermore, the Conductor with its insulation advantageously a robust, prefabricated and testable unit. He can be simple Way involved and misplaced. In addition, a large range of variations in the execution of the insulation fit to the respective application.

An advantageous method for producing the fiction moderate insulation is characterized in that the Ausspa isolation in a physical process, especially with the help of a laser beam, who worked the. Such a process can easily be controlled in such a way that an undesirable damage to the surface of the superconductor does not occur.

Advantageous embodiments of the insulation according to the invention and the process for their production go from the sub claims.

To further explain the invention, reference is made below to the drawing, in which FIG. 1 schematically illustrates a superconductor structure with an insulation according to the invention. Fig. 2 shows schematically as a section the production of recesses in such insulation. In the figures, matching parts are provided with the same reference numerals.

Fig. 1 shows an oblique view of a detail of the structure of a superconducting coil 2. This winding contains a stack of individual superconductors 3 to 5 . Each super conductor has an approximately rectangular cross-sectional shape and thus two opposite flat sides 6 a and 6 b and two opposite narrow sides 7 a and 7 b . An electrical insulation 9 is arranged around each of the conductors, which is said to have sufficient mechanical strength and can consist, for example, of a wound film strip 9 a . In this Fo lienband recesses 10 a to 10 c, for example various forms, are subsequently incorporated in the region of the narrow sides 7 a and 7 b , so that zones are created for direct surface cooling of the respective conductor. The removal of the film material or the incorporation or cutting out of the savings advantageously takes place using physical methods known per se, in which, for example, ultrasound or electromagnetic radiation is used. These methods should be selected from the point of view that damage to the superconductor is avoided. The use of laser radiation of predetermined intensity therefore appears to be particularly suitable. According to the illustrated embodiment of the superconducting winding 2 , the flat sides 6 a and 6 b of the superconducting rectangular conductors 3 to 5 are available for the transmission of strong compressive forces F via the full insulation to the respective adjacent conductor. Full insulation is understood to mean insulation that completely surrounds the respective conductor without special openings or cutouts or other gaps. Pressing forces F of more than 10 N / mm ² can advantageously be transmitted in this way. The narrow sides 7 a and 7 b (conductor flanks) carry the recesses 10 a to 10 c , which allow the unimpeded access of liquid helium (LHe) as a coolant K to the respective conductor surface. This flank cooling by convection in the coolant K is indicated by arrowed lines.

Instead of the stack winding illustrated in FIG. 1, which is located, for example, in a slot of a generator rotor, the superconducting winding 2 can also have a different winding form. For example, it can be designed as a disc winding or as a layer winding.

The conductors of the superconducting winding 2 are known embodiments of superconductors which are at least partially stabilized. The superconducting material of the conductor is electrically and thermally well-conductive material such as copper or aluminum added. By means of a sufficiently intensive cooling of this normal conducting material, it can then be achieved that a point in the superconducting material which has become normally conducting can be returned to the superconducting state without interruption in operation. Corresponding superconductors for the winding 2 are in particular designed as solid (monolithic), stranded or also as entangled conductors.

The insulation 9 according to the invention can be built up, for example, according to FIG. 1 with foil strips 9 a . The band widths, number of layers and degrees of overlap are largely freely selectable. Suitable film materials, which also allow the transfer of sufficiently large pressing forces with good electrical strength, are known plastics. They can be, for example, special thermally stable polyimides or special aromatic polyamides, which are known, for example, under the trade name "Kapton" or under the trade name "Nomex".

An embodiment of an electrical insulation according to the invention is indicated in Fig. 2. Here, a superconducting of the rectangular conductor 5 is taken as a basis, which is constructed from a plurality of individual conductors 12 roped together. Each individual conductor contains a multiplicity of superconducting conductor wires 13 , which are embedded in a matrix 14 made of a stabilizing material such as copper or aluminum. Around this right corner conductor 5 is first fully electrical insulation 9 'wrapped with a film strip 9 a . Subsequently, individual (discrete) cutouts 10 c are then worked into this full insulation 9 ', for example with the beam 16 of a laser. Here, the local arrangement of the individual recesses, their shape, size and number can be freely selected within wide limits, with the pressing forces and stress conditions occurring as well as the cooling requirements, of course, being taken into account. In the illustration in FIG. 2 it is assumed that savings 10 c are to be provided only on the narrow side 7 a (and correspondingly on the opposite narrow side 7 b , not shown) of the rectangular conductor 5 . If necessary, one can also form corresponding recesses on at least one of the flat sides 6 a and 6 b .

According to a specific embodiment, a supralei tender rectangular cable 5 with about 5 mm thickness D and about 15 mm width B first with a full insulation 9 'from 50 µm thick "Kapton" tapes 9 a or 80 and 250 µm thick "Nomex "Bands. With a CO ₂ laser with a nominal output of 1 kW, circular cutouts 10 c with a diameter of approximately 2.5 mm can then be cut into this full insulation without the material of the matrix 14 melting noticeably. The CO ₂ laser can have the following data for this: beam diameter 0.15 mm; Beam intensity 6.7 × 10 ⁷ W / cm ² ; Pulse duration 0.1 µsec, pulse pause 3 µsec. Carbonize the partial surfaces of the foils 9 a that are exposed to a corresponding laser beam, producing a very fine soot-like dust. However, this dust can be easily vacuumed or wiped off. The trained cut edges are clean and without melting beads.

Instead of the CO ₂ laser described, other types of laser such as excimer lasers can of course also be used.

According to the illustrated embodiment, it was assumed that the manufacture of the recesses 10 a to 10 c after the formation of the full insulation 9 'and before a superconducting winding is built. If necessary, however, it is also possible to construct the superconducting winding with superconductors whose full insulation is not yet equipped with the cutouts. In this case, the recesses are then incorporated into the full insulation of the individual conductors from the free surfaces of the winding only after the winding has been built up with the conductors, possibly even after the winding has been impregnated. Such a technology can be provided, for example, for disk coils, which are designed, for example, as flank-cooled winding modules.

Claims (6)

1. Electrical insulation of predetermined mechanical strength around a stabilized superconductor with at least largely rectangular cross-section, which is provided with recesses in which an unimpeded access of a coolant to the upper surface of the superconductor is possible, characterized in that in which the superconductor ( 3 to 5 ) initially completely surrounding insulation ( 9 '), the recesses ( 10 a to 10 c ) in the area of at least one of the side surfaces ( 6 a , 6 b , 7 a , 7 b ) of the superconductor ( 3 to 5 ) are incorporated. 2. Insulation according to claim 1, characterized by a design for pressing forces ( F ) in the normal direction on the flat sides ( 6 a , 6 b ) of the superconductor ( 3 to 5 ) of at least 10 N / mm ² . 3. Insulation according to claim 1 or 2, marked net by wrapping the superconductor ( 3 to 5 ) with at least one plastic tape ( 9 a ) or by a train of the superconductor with a plastic material. 4. Isolation according to claim 1 or 2, characterized net by casting the superconductor with a hardened plastic material. 5. A method for producing the insulation according to one of claims 1 to 4, characterized in that the recesses ( 10 a to 10 c ) are incorporated into the insulation ( 9 ') by means of a physical process. 6. The method according to claim 5, characterized in that a laser beam ( 16 ) is provided for incorporating the recesses ( 10 c ).