DE2115798B2 - Heavy current superconductive switching path - has superconductive strip not in direct contact with coolant - Google Patents

Abstract

The heavy current switching path contains a coil which can be switched from superconductive to normally conductive to normally conductive state by its natural magnetic field. Round the coil are provided magnetic screens of superconductive material which, in its superconductive conditions, force the coil magnetic force lines onto a longer path as in 1962704. The superconductive strip (1) of the switching path is not in direct contact with the cooland (6), but is embedded in a heat absorbing insulating material (2, 3) of high breakdown strength. The insulator thickness on the superconductor side, facing the coolant, is so rated as to reflect the required reverse cooling time period after response of the switching path.

Description

The main patent 19 62 704 relates to a switching path for heavy current from at least one superconducting, by their own magnetic field from the superconducting to the

ίο electrically normal conductive state switchable coil. The switching process begins with such a switching path when there is a current load on the sound path a certain critical magnetic field strength and a corresponding current density can be achieved. Of the

The superconductor of the sound path can be arranged in the form of a band in such a way that that which is formed in the coil Self-magnetic field runs parallel to the surface of the belt. Circuit-related measures during use such switching sections are in »Efekiroiechni-

ao see magazine ", edition A, vol. 89 (1968), p. 335 bis 339, especially p. 338, Fig. 6 and p. 339. Difficulties in operating such switching sections are mainly due to the fact that often small differences in the material properties of the supra-

* 5 conductor and in the formation of the magnetic field along the switching path superconductor, which is many kilometers long at high voltages, initially only a few places in the switching path from the superconducting to the normalconducting state.

being able to lead. First of all, those points of the switching path are normally conductive, the critical ones Magnetic field and critical current density due to the mentioned differences in the material properties and the formation of the magnetic field are lower or are reached earlier than those of other points of the switching path. These isolated, as the first to pass into the normally conducting state Areas can burn through, which can destroy the entire switching path. This is

especially critical at relatively slow speeds

Increase in current in the switching path, for example in the case of short circuits further away or smaller ones Overload of individual power supplies.

In order to ensure proper functioning of the switching path, it is proposed in the main patent magnetic shields made of superconductive material in the vicinity of the coil provide that in the superconducting state of the shields that of the coil when current flows through generated magnetic lines of force are forced on a longer path than without shields, so that the magnetic field within the coil is less than the lowest critical magnetic field strength at any one Place the coil. If a predetermined current intensity is reached in the coil, at which the Switching process is to be triggered, as a result of the associated with the current rise in the coil Increase in the magnetic field at least partially to disappear the shielding effect of the shields brought. As a result of the shortening of the magnetic lines of force, this increases Magnetic field within the coil to a value above the highest critical magnetic field strength at any point of the given

6 $ coil through which current flows.

Because the shielding effect of the superconducting shields when the critical magnetic field is exceeded the shielding disappears very quickly,

the magnetic field in the coil practically passes through due to the shortening of the magnetic lines of force Suddenly the critical area in which the critical magnetic field strengths at the individual points sprinkle the coil. As a result, the entire coil changes from the superconducting to the electrically normal conducting very quickly State transferred and a burn through of individual points of the coil and the associated Destruction of the switching path prevented.

In the main patent, various examples for the practical structure of such switching paths have been given. As a rule, the switching section conductors are applied in the form of strips of superconducting material, in particular niobium, to insulating supports in the form of plates, cylinder jackets or the like. Great care must be taken when winding the superconductor onto the carrier in order to avoid damage or tearing off. The thickness of the niobium strips is, for example, in the order of magnitude of about 1 to! Ομηι, the width to a few centimeters.

When setting up the switching sections, it is advisable to take into account the fact that one is during the switching process receives the fastest possible temperature rise in the switching path conductor. You can quickly get to the In the area of high specific resistance, the total losses in the switching path conductor up to the point of disconnection smaller due to the mechanical auxiliary switch. Plus there is only less effort for that Recooling of the cooling medium required.

These operating properties of superconducting sound paths are largely in contrast to them superconducting coils of the usual structure, since there is usually as direct a contact as possible between strives for the superconducting material and the coolant. With such direct contact However, in a superconducting switching path, the temperature in the switching path conductor during the Switching process only increase relatively slowly because the switching path conductor is intensively cooled. Serves as The coolant is liquid helium, so it can easily come to a shock-like evaporation of helium, in which a pressure surge occurs, which loads the overall construction and in particular the wall of the cryostat, in which the switching path is arranged. If helium is used as a coolant in gaseous form at temperatures which are slightly above 4.2 K at atmospheric pressure, there are indeed such shock effects avoided and a less intensive cooling achieved, yet it is difficult to obtain a sufficient electrical To achieve insulation, the winding tensions occurring when passing through shock waves safely withstands.

The invention is based on the object of avoiding the disadvantages outlined and providing a structure of the superconductor for switching sections according to the main patent, which is used both in the manufacture of the Switching distance as well as in operation brings advantages.

This object is achieved according to the invention in that the band-shaped superconductor of Switching path is not in direct contact with the coolant, but in heat-insulating insulating material high dielectric strength is embedded, the thickness of which is at least one of the coolant facing side of the superconductor is measured according to the cooling time after a response of the Switching distance is required.

On the other side of the band-shaped superconductor, the insulating material can also have a greater thickness have, which is measured primarily with regard to the desired mechanical strength.

In an advantageous embodiment of the sound path, the band-shaped superconductor is on a Plastic film, for example made of polyethylene terephthalate, applied, for example by gluing in individual places. The superconductor is then covered with another plastic film. Both slides are connected to one another at the edges, for example by gluing or welding, so that the Superconductor is completely enclosed by insulating material. The two plastic films can advantageously be different be fat.

However, you can also coat the superconductor with a layer of insulating varnish and place it on a plastic film or cover the superconductor on all sides with a layer of insulating varnish.

If this is desired for manufacturing reasons, the band-shaped superconductor can also be constructed from several, electrically parallel-connected partial bands, which are applied next to one another on a plastic film and covered with insulating material.

The invention will be explained in more detail using a few figures and exemplary embodiments.

Fig. 1 shows schematically in section a detail an exemplary embodiment of a switching path;

2 and 3 show, in cross section, further embodiments of the switching path conductor according to the invention.

In Fig. 1 a section of a coil of a switching path is shown in section. As a switching path conductor serves a superconducting tape 1 made of niobium, which is a thickness of about 1 to 10 μίτι, preferably 3 to 5 μΐη. and can be up to several centimeters wide. This niobium tape 1 is on a tape-shaped polyethylene terephthalate film 2 glued on with a thickness of, for example, 10 to 20 μm. The niobium strip 1 is with a further tape-shaped polyethylene terephthalate film 3 covered, for example, about 6 to 10 μΐη thick can. The two foils 2 and 3 are welded to one another at their edges at 4, so that the niobium strip 1 is completely enclosed by plastic. The niobium strip 1, which is covered with foils 2 and 3, is located next to one another Windings wound onto a carrier 5. Since the superconducting niobium tape 1 by the Plastic sheath is mechanically more resistant, the winding on the carrier 5 is considerable facilitated and thus the manufacture of the switching circuit significantly simplified.

The coolant 6, for example liquid melium, washes around the surface of the thinner plastic strip 3 and is not in direct contact with the niobium strip 1. At the moment of addressing ·; the switching path therefore the cooling effect is largely absent, so that a steep temperature rise occurs in the niobium strip 1. It the heat dissipation to the coolant is also delayed, so that the otherwise occurring sudden evaporation is entirely or largely avoided.

The thickness of the plastic film surrounding the superconductor must be at least one of the coolant facing side are dimensioned so that the coolant is able to within the required Switching on again, the cooling of the superconductor to the operating temperature of around 4 K, for example to achieve. In the one shown in FIG. 1 shown embodiment

example, in which the thickness of the film 3 is dimensioned accordingly, reached after a switching operation Switching distance in fractions of a second is again that for the superconducting operating state of strip 1 required temperature.

For this purpose, an application example is given briefly in numerical terms. It is assumed that the niobium strip reaches a temperature of about 100 K within about 50 msec when the switching path responds before it is switched off by the auxiliary mechanical switch. Assuming a mean thermal conductivity of the plastic film of 6-10- * cal / cm-sec ° C, and takes into account that at a thickness of the strip 1 of about 3 μίτι a heat content of about 3 x 10 ^-2 Wsec per cm ² of Tape surface must be released to the coolant, one comes to the conclusion that with a thickness of the film 3 of about 8 μίτι within about 0.1 seconds, the niobium tape 1 can be cooled back into the range of superconductivity with high current carrying capacity. This time is completely sufficient to enable short-circuit continuation, in which reconnection times of 0.2 to 0.5 seconds are expected.

The plastic film 2 resting on the carrier 5 is to increase the mechanical strength of the with Insulating material sheathed switching gap conductor dimensioned thicker than the film adjoining the coolant 6 3. If there are gaps between the carrier 5 and the switching path conductor 1 covered with insulating material for the coolant, for example in the form of narrow ones worked into the surface of the carrier Channels, are present, the switching section conductor can also be wound onto the carrier 5 in this way be that the thinner plastic film 3 faces the carrier 5.

If the speed of the recooling does not play a decisive role, there is the possibility of the To further increase the thickness of the insulating material, so that the effects of a switching operation on the Coolant can be reduced even further. An increased thickness of the insulating material sheath can in particular then be of advantage when it comes to increasing the dielectric strength to control Impulse voltages when passing through traveling waves with a steep front arrives.

If by welding the ribbon-shaped plastic films at the edges or because of the required dielectric strength is the distance between the adjacent turns of the band-shaped switching section conductor is so large that

ίο as a result of passing through between the windings Magnetic field components the current density is increased at the band edges of the switching gap conductor, can be used to guide the magnetic field at the joints between two adjacent ones Windings strips made of magnetically conductive, electrically insulating material, for example made of ferrite or ferrite-plastic composite material, can be arranged parallel to the tape windings. In Fig. 1 are those for example, arranged sunk in the carrier 5

μ strip 7 shown.

F i g. 2 shows in cross section another embodiment of a switching gap conductor in which a superconducting Band 21 first surrounded by an insulating varnish layer 22 and then on a band-shaped plastic film 23 is glued on. In such an embodiment, for example, the thickness of the insulating lacquer layer 22 according to the recooling conditions and the thickness of the plastic film 23 according to the desired mechanical strength.

In the case of the in FIG. 3 is an embodiment of a retainer shown in cross section ribbon-shaped superconductors made up of several electrically connected in parallel. side by side tcil bands 31 to 33 composed. The partial bands 31 to 33 are glued next to one another onto a band-shaped plastic film 34. Another ribbon-shaped plastic film 35 covers the part bands and is welded to the plastic film 34 at the edges at 36 Such an embodiment is advantageous when the switching section conductor is to have a greater width than the single available superconducting tapes.

1 sheet of drawings

Claims (8)

Patent claims: 1. Switching path for heavy current from at least one superconducting, due to its own magnetic field coil which can be switched from the superconducting to the electrically normalconducting state, in which in the In the vicinity of the coil magnetic shields made of superconductive material are provided in this way are that in the superconducting state of the shields from the coil when current flows through generated magnetic lines of force are forced to travel longer than without shields, so that the magnetic field inside the coil is smaller than the lowest critical field strength any point of the coil, and that when a predetermined current strength is reached in the coil the The shielding effect of the shields at least partially disappears as a result of the increased magnetic field and as a result of the resulting shortening of the magnetic lines of force, the magnetic field within the coil to a value above the highest critical magnetic field strength at any point of the specified Current flowing through the coil increases, according to Patent 1962 704, characterized in that that the band-shaped superconductor (1) of the switching path is not in direct contact with the coolant (6), but in heat-insulating insulating material (2, 3) with high dielectric strength is embedded, the thickness of which is at least on one of the coolant (6) facing side of the Superconductor is dimensioned according to the cooling capacity after the switching path has responded is required. 2. Switching path according to claim 1, characterized in that the superconductor (1) on one Plastic film (2) is applied and covered with a plastic film (3) and both plastic »Toffolien are connected to one another at the edges (4). 3. switching path according to claim 2, characterized in that the two plastic films (2,3) are of different thicknesses. 4. switching path according to claim 3, characterized in that the superconductor (1) is a niobium strip from about 1 to ΙΟμηι thickness on a plastic film (2) applied from about 10 to 20 μm thickness and with a plastic film (3) of about 6 to 10 μm thickness is covered. 5. switching path according to claim 1, characterized in that the superconductor (21) with a Insulating lacquer layer (22) is coated and applied to a plastic film (23). 6. switching path according to claim 1, characterized in that the superconductor with all sides tiner insulating lacquer layer is surrounded. 7. switching path according to one of claims 1 to 5, characterized in that the superconductor several, electrically parallel-connected partial belts (31,32,33) is constructed, which are next to each other a plastic film (34) are applied and covered with insulating material (35). 8. switching path according to one of claims 1 to 7, characterized in that at the joints between two adjacent turns of the superconductor (1) to guide the magnetic field Strip (7) made of magnetically conductive, electrically insulating material parallel to the turns are arranged.