EP0013399A1 - Cooling device for superconducting magnet coil - Google Patents

Abstract

The invention relates to an arrangement for forced cooling of a magnetic coil winding with coolant connection points for feeding and discharging a coolant into or out of the winding, the superconducting conductors of which have fixed operating points determined by current density I, field strength H and temperature T, which are from the nearest jump point of the superconducting one Materials are at different distances. In the case of these known cooling arrangements, however, a spread of a normally conductive zone starting from a critical conductor region is still supported by the coolant, since the coolant has always been fed into the winding at this critical conductor region. The invention therefore provides that the coolant connection point (24) with the closest distance to the conductor area (14) of the winding (2), the operating point of which is closest to a jump point, has a discharge of the coolant (A) from the winding (2) is provided. The super masters can be designed in particular as a waveguide. Such cooling arrangements can be provided in particular for large superconducting magnets with, for example, a D-shaped configuration.

Description

The invention relates to an arrangement for cooling a magnetic coil winding, which by means of a forced flow of a coolant which is fed into the winding at at least one coolant connection point and which has coolant derived again from at least one further coolant connection point, contains conductors made of superconducting material which are subdivided into conductor areas , whose operating points determined by the current density I, field strength H and temperature T differ from the closest jump point of the superconducting material, determined by the critical current density I _c , critical field strength H and critical temperature T, of the superconducting material from the superconducting to the normal conducting state are far away.

Magnetic windings with superconductors can advantageously be used to generate strong magnetic fields with a large spatial extent. The conductor materials used for this are e.g. Niobium-zirconium or niobium-titanium alloys as well as niobium-tin compounds are possible. Conductors made of these superconductor materials are generally stabilized with normally conductive material, for example embedded in a matrix made of this material. This measure is intended to prevent destruction of the superconductors in the event of an uncontrolled transition of its parts consisting of the superconductor material from the superconducting to the normally conducting state.

So-called "forced" cooling is often provided for cooling superconducting large magnets (cf. CERN Report 68-17, Nuclear Physics Division, Geneva, May 13, 1968). With this cooling technology, a coolant, for example liquid helium, is constantly pumped through discrete cooling channels which are formed in the winding. Corresponding cavities can in particular be provided as cooling channels in the superconducting conductors themselves. Such conductors are therefore generally referred to as waveguides. With this cooling technology, a helium bath cryostat required for cooling the winding of the magnetic coil can be dispensed with and replaced by a simple vacuum chamber which encloses the winding and is only used for thermal insulation of the winding from the outside. Furthermore, in the case of a magnetic winding with hollow conductors or corresponding cooling channels guided between adjacent conductors, the amount of liquid coolant required for cooling the winding can be considerably reduced compared to a magnet of approximately the same size with coolant bath cooling will. This is particularly advantageous in the case of a transition of the winding from the superconducting to the normally conducting state, because then only relatively little liquid coolant can evaporate. In addition, in contrast to most windings with bath cooling, magnetic windings with waveguides can be oriented anywhere in the room. Changes in position during operation are then also possible.

The operating values for the conductors of such a magnetic coil winding differ during undisturbed operation within the winding. This means that the winding has conductor areas whose operating values are more critical with respect to the superconducting properties of the conductor material than the values of neighboring conductor areas. The operating point of such a critical conductor area, which is determined by the operating values, is thus closer to the closest jump point, determined by the critical values of the superconducting material of the conductor, from the superconducting to the normally conducting state than the working points of other conductor areas. This jump point is mainly determined by the critical current density I _c , the critical field strength H or the critical magnetic induction B and the critical temperature T of the conductor material and lies on a three-dimensional surface in the IHT space, which the combinations of IHT, in which the superconducting state is present, separates from those with only normal conduction (Proc. IEE, IEE Reviews, Vol. 119, No. 8R, Aug. 1972, page 1007). For example, there is a conductor area in a zone of particularly high magnetic field strength that is greater than the field strength in neighboring conductor areas, the operating values of this conductor area are closer to the jump point to be assigned than in the adjacent conductor areas if the temperature and current density ratios in the conductor areas compared with one another are at least approximately the same.

An unintentional transition of a superconducting magnetic winding into the normally conductive state, which is also referred to as "quench", often starts from such a critical conductor area of the winding which is exposed to particularly extreme conditions, for example particularly high magnetic field strength or particularly high heat. In order to prevent the normally conductive zone from spreading relatively quickly over the entire coil due to heat conduction in the case of such a quench, and consequently a correspondingly large amount of energy to be extracted from the magnet, efforts are generally made to cool the magnet particularly well to get critical areas. So far, this has been attempted to ensure that the coolant was introduced into the magnet at least in the vicinity of these critical areas, since it is then still the coldest and can therefore dissipate most of the heat. However, if the winding on this critical conductor area becomes normally conductive, e.g. due to the particularly high field strength there, the increased temperature resulting from the flowing electrical current is not only passed on to neighboring conductor areas due to heat conduction along and across the conductor, but also by the heated one Coolant is transported into these conductor areas.

The invention is thus based on the knowledge that the known arrangements for forced cooling of superconducting magnet windings still support a spread of the normally conductive zone through the coolant. The object of the present invention is therefore to create an arrangement for cooling a superconducting magnet winding in which this risk does not exist.

This object is achieved according to the invention for a cooling arrangement of the type mentioned at the outset in that the coolant is discharged from the coolant connection point with the comparatively short distance to the conductor area of the winding, the working point of which is comparatively closest to a jump point of the superconducting material in the IHT space the winding is provided.

A discharge of the coolant from the winding is to be understood to mean that the coolant is removed in the vicinity of this most critical point of the winding and is not used for any further cooling of conductors in the winding. For example, the coolant can then be fed directly to a coolant supply unit. The position and number of the coolant connection points of the winding are generally specified for design-related reasons.

With this cooling arrangement it is ensured that the coolant must flow to the point which experience has shown first to change from the superconducting to the normal conducting state, and from this point at most only take a relatively small path through the winding before it is led out of it. In this way, one Forwarding of the heat transferred to the coolant at this critical point to neighboring winding parts is largely avoided. These advantages of these measures lie in the fact that a quench consequently spreads much more slowly or not at all in the winding.

In the case of a disk-shaped magnetic coil winding with, for example, a D-shaped configuration, the conductors of which in the undisturbed operating state have at least approximately the same current density I and approximately the same temperature T in all conductor areas, the coolant is advantageously diverted to a coolant connection point provided on the inside of the winding, since in generally there are the conductor areas with the highest magnetic field strength H or magnetic induction B.

Further developments of the invention are characterized in the remaining subclaims.

To further explain the invention, reference is made to the drawing, in the figure a magnetic coil winding with an arrangement for cooling according to the invention is schematically illustrated.

The coil winding 2, which is only indicated in the figure and is disc-shaped in cross section, has an approximately D-shaped shape. A large number of such coils can be combined to form a toroidal magnet system, as is provided, for example, for Tokamak fusion reactors (cf. for example "Rev. Mod.Phys.", Vol. 47, No. 1, January 1975, pages 15 to 21 ). The coil is made of a superconducting hollow conductor 3 wound, the superconducting material, for example niobium titanium or Nb ₃ Sn, is stabilized with normal conducting material. Corresponding conductors are known, for example, from German Offenlegungsschriften 26 26 914 and 26 02 735. In the figure, for the sake of clarity, the required electrical and thermal insulation devices of the coil are not shown, and only three turns 5 to 7 of a single winding layer made of the superconducting waveguide 3 are exaggeratedly large. The coil can also be constructed from several such winding layers. It is also protected against irreversible damage in the event of normal conductance. A corresponding non-executed in the figure _'measure is to decouple the field energy into an out-of winding ohmic resistor in which the energy is consumed (see FIG. "Cryogenics", June 1964, pages 153 to 165).

For cooling the coil winding 2, a forced flow of a coolant A, for example liquid helium, is provided, which for this purpose is pumped through at least one cavity 9 inside the superconducting waveguide 3.

In the operating state of such coil windings, the conductors running on the inside 11 are generally exposed to greater magnetic field strengths than the conductors on the outside 12 of the winding. Assuming that the heat input from the outside onto the coil winding 2 and the current density at each point of the coil in the waveguide 3 are approximately the same, they have on the inside of the winding 2 ordered conductors 5 operating values of their superconducting material that come closest to the jump point of the superconducting material determined from the three critical sizes mentioned. In the figure, a corresponding conductor area is delimited by a dashed line and designated by 14, it being additionally taken into account that this conductor area also includes, in particular, locations 16 and 17 of the magnetic winding, which have a particularly small radius of curvature in the case of the D-shaped shape of the winding . According to the invention, the conductors 5 of the coil 2 are most likely to quench in this region 14. According to the invention it is therefore provided that the coolant flowing through the conductor 5 is led out of the coil winding in this area 14, ie that further cooling of the winding conductors with this coolant is then no longer provided. In order to ensure a corresponding coolant flow, for producing the coil winding according to the exemplary embodiment, the conductor 3 has been wound from the inside to the outside around a central, D-shaped winding core 19 and "the coolant A is used to operate the finished coil, as indicated by an arrow 21 is fed into the winding at the outer end 22. After the coolant has flowed through the waveguide from the outside in, it is, as also indicated by an arrow 23, at an exit point 24 on the straight part of the inside of the coil 2. In this way, it can be prevented that a quench forming in area 14 of the winding is transferred to adjacent areas of the winding by the heating coolant.

In the exemplary embodiment according to the figure, it was assumed that the forced cooling of the conductors takes place through flows of a coolant through cavities in these conductors. However, a corresponding flow can equally well be provided on the outside of the conductors, for example through corresponding longitudinal channels on the conductors or in insulation parts between adjacent conductors.

Claims (4)

1. Arrangement for cooling a magnetic coil winding. which contains, by means of a forced flow of a coolant at at least one coolant junction into the winding and at least one further coolant junction derived from the coil again cooled conductors made of superconducting material, which are subdivided into conductor areas whose current density I, field strength H and Temperature T specified working points of the closest in an IHT space, determined by the critical current density I _c , critical field strength H _c and critical temperature T jump point of the superconducting material from the superconducting to the normal conducting state at different distances, characterized in that the coolant connection point (24) with the comparatively smallest distance to the conductor area (14) of the winding (2), the operating point of which is comparatively closest to a jump point of the superconducting material in the IHT space, a discharge of the coolant (A) from the W icklung (2) is provided. 2. Arrangement for cooling according to claim 1, characterized by an introduction of the coolant (A) at a coolant connection point which is closest to a conductor area whose operating point is further away from the jump point of the superconducting material than the working point of each of the other conductor areas of the winding ( 2). 3. Arrangement for cooling a disk-shaped magnetic coil winding according to claim 1 or 2, the Lei ter in the undisturbed operating state in all conductor areas have at least approximately the same current density I and the same temperature T, characterized by a discharge of the coolant (A) at a coolant connection point (24) provided on the inside (11) of the winding (2). 4. Arrangement for cooling according to one of claims 1 to 3, characterized by superconducting waveguide (3).

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