The present disclosure relates to an arrangement of superconducting joints, for example in a superconducting magnet for an MRI system. The disclosure also relates to arrangements for storage of excess wire in such superconducting joints.
A negative electrical connection 21a is usually provided to the magnet 10 through the body of the cryostat. A positive electrical connection 21 is usually provided by a conductor passing through the vent tube 20.
Superconducting magnet 10 comprises a number of coils of superconducting wire, electrically interconnected. These connections, and others required to complete the electrical interconnection of the coils and other electrical equipment, are carefully constructed to ensure a minimum joint resistance and effective cooling. The present disclosure relates to methods and joints useful in such an application.
The methods and joints of the present disclosure provide advantages at least in the fields of efficient cooling of superconducting joints and storage of excess wire. Excess wire is typically desired within the structure of a superconducting joint, to enable the joint to be unmade and remade, if necessary, during the lifetime of the superconducting magnet.
Conventional arrangements for effectively cooling a superconducting joint involve an electrically insulating but thermally conducting interface between a cooling means and the joint. Such conventional arrangements, however, typically have the disadvantages of requiring costly and complex parts which need to be precisely assembled. Added costs and complexity arise from the need to provide electrical insulation and to perform voltage breakdown testing. Examples of such arrangements are disclosed in U.S. Pat. No. 8,253,024, US20130090245, US20140024534, US20160086693, and CN101414742B.
JP S60 182673 A and JP S60 175383 A describe arrangements and methods for making and cooling superconductor joints.
In other known solutions, a cooling pipe containing a cryogen such as gas or liquid helium, neon or nitrogen is provided between the joint and the cryogen vessel or some other cooled component. An electrically insulating but thermally conducting element must be provided to ensure electrical insulation between the cooling pipe and the joint. Such arrangements have disadvantages in requiring costly and complex pipes and vessels with cryogen gas or liquid. Such components must be leak tight and approved for use as pressure vessels. The need to provide electrical insulation between pipes and joints introduces further complexity. An example of such an arrangement is discussed in U.S. Pat. No. 8,315,680.
An aspect of the disclosure relates to the storage of excess superconducting wire near the joint. It is conventional to coil excess superconducting wire and immobilise it using the same superconducting alloy as used for embedding the joint. Conventionally, excess superconducting wire is coiled inside a metal cup which is filled with liquid superconducting alloy and allowed to cool down to solidify. This creates a large, cylindrical volume of superconducting alloy. However, use of such large volumes of superconducting alloy may create joints which are prone to flux jumps. A large mass of superconducting alloy will require a long cool-down time, and a cup must be provided to contain the alloy. A relatively high-temperature step must be undertaken to melt the alloy and immerse the joint in it. It is also difficult, and may be messy, to extract the excess superconducting wire from the joint cup when a rejoining step is required.
The present disclosure accordingly provides a superconducting joint arrangement with wire storage arrangement to store excess length of the joined superconducting wires in the vicinity of the joint. The arrangements of the present disclosure provide effective cooling of the joint even in the absence of a cooling cryogen bath.
The present disclosure accordingly provides superconducting joints and methods for producing superconducting joints as defined in the appended claims.
The above, and further, objects, characteristics and advantages of the present disclosure will become more apparent from the following description of certain embodiments, given by way of examples only, in conjunction with the appended drawings, wherein:
The present disclosure accordingly provides a superconducting joint for superconducting magnets, wherein an elongate joint is made between superconducting filaments of superconducting wires of one or more superconducting coils, excess wire being provided electrically between the elongate joint and the one or more superconducting coils, wherein the elongate joint is in thermal contact with at least one of the superconducting wires at a location electrically between the one or more superconducting coils and the excess wire.
a.
The joint 1 is made up from two superconducting wires 2, themselves forming part of the coils of superconducting wire 3, and typically one wire each from respective coils of superconducting wire 3. As shown in
As is well-known in the art, and illustrated in
The filaments of the wires to be joined are twisted or plaited together to form elongate superconducting joint 1. The plaited or twisted filaments may then be tinned, for example with indium, to assist surface wetting of the superconducting filaments by superconducting alloy. The elongate superconducting joint 1 may then be coated in a solder, preferably a superconducting solder such as lead-bismuth. The elongate superconducting joint 1 is then placed in thermal contact with at least one of superconducting wires 2, in this example by being wrapped around the superconducting wires 2, electrically between an extremity 23 of the corresponding at least one sheath 22 and the superconducting coil 3. As shown in
This arrangement, according to the present disclosure, provides a relatively short heat transfer path from elongate superconducting joint 1 to cooled coils 3. In the absence of the arrangement of the present disclosure, heat would have to pass from the elongate joint 1 along the length of excess wire 30 to reach the cooled coils. The present disclosure provides a much reduced thermal path between the elongate superconducting join and the cooled coils, increasing the effectiveness of the cooling of the elongate superconducting joint and reducing the likelihood of a quench being initiated in the elongated superconducting joint.
The elongate superconducting joint 1 may be soldered to the wires 2, using the same solder which is used in the joint, thereby providing a very effective thermal link between the join and the wires 2, and a very effective mechanical support for the joint. The use of binding wire 14 provides these advantages, to some extent. In certain embodiments, binding wire and solder may be used.
The join 1 is formed over a significant length of the superconducting filaments, for example over 10-30 cm. This will ensure low joint resistance and high current handling capacity.
Preferably, the join 1 is thermally linked to wires 2 relatively close to the coils of superconducting wire 3, ensuring effective thermal coupling between the join 1 and the coils of superconducting wire 3.
In alternative embodiments, the thermal and mechanical contact between the elongate joint 1 and the at least one superconducting wire 2 may be obtained by clamping, pressing or gluing with a suitable adhesive, such as a LOCTITE (RTM) STYCAST (RTM) resin which may be obtained from Henkel Ltd.
The join may be located in a vacuum region, or within a cryogen vessel illustrated in
As explained above, superconducting coils 3 are cooled by cooling means not illustrated to a cryogenic temperature sufficiently cold to enable superconducting operation of superconducting coils 3. Joint 1, being thermally in contact with sheaths 22 of wires 2, is cooled by thermal conduction along those sheaths to the cooled superconducting coils 3.
Sheath 22 is of a thermally conductive material such as copper, aluminium, silver or a combination of some or all of those metals. Elongate joint 1 may make electrical contact as well as thermal and mechanical contact with the sheaths 22 of superconducting wires 2, as sheaths 22 and elongate joint 1 will be at a same voltage. The thermal conductivity of sheaths 22 carries heat from elongate joint 1 towards the superconducting coil 3.
Following a quench, the superconducting wire 2 and the elongate superconducting joint 1 become resistive. Typically, the metal sheath 22 is of lower resistance than the filaments 21 in this state. Current flows along path 72 following a quench. Path 72 follows one joined superconducting wire 2 but along the metallic sheath 22 in preference to the filaments 21. At elongated superconducting joint 1, current preferably transfers from metallic sheath 22 of one wire to metallic sheath 22 of the other wire, through the solder if present and out following the other joined superconducting wire 2.
As illustrated in
Assembly of the joint of the present disclosure may be facilitated by use of binding 26, for example of copper wire, to retain wires 2 together, and/or binding 14, for example of copper wire, to retain the elongate superconducting joint 1 in mechanical contact with sheaths 22 of wires 2. In an embodiment, elongate superconducting joint 1 may be formed from superconducting filaments coated in a solder such as a superconducting solder, then the elongate superconducting joint 1 may be wound around the wires 2, as illustrated in
In an alternative embodiment, a further soldering step may be applied to solder the elongate joint to the sheaths of wires 2, to provide an improved thermal conduction between elongate joint 1 and wires 2. A superconducting solder is preferably used, such as lead-bismuth or indium-tin. Such further soldering step may be performed prior to, following, or in place of, binding of the elongate joint 1 to sheaths 22 of wires 2 by binding 27.
In an embodiment, as illustrated in
According to a feature of the present disclosure, as illustrated in
Excess wire 30 is provided as a loop, comprising wires 2 electrically between elongate joint 1 and superconducting coils 3. In the illustrated embodiment, and preferably, excess wire 30 is wound into a figure-of-eight configuration, to reduce magnetic field coupling (mutual inductance) between a current loop created by excess wire 30 and current loop created by the main persistent circuit of the MRI system. This will be further explained with reference to
As is well known in the art, and with reference to the two loops 32, 34 of the figure-of-eight arrangement shown in
In the illustrated embodiment of
If constructed as above, first loop 32 and second loop 34 of loop L2 are inherently non-inductive, provided that the two wires 2 joined at the elongate superconducting joint 1 are close and parallel to one another.
In other embodiments, use of a single loop L2′ 37 as illustrated in
As a result of small mutual inductance, which may be arranged for as set out above, the net force resulting from the magnetic field of the superconducting magnet on the figure-of-eight arrangement of excess wire 30 is also minimized. This simplifies mounting arrangements and is beneficial.
Preferably, in any case, the loop containing excess wire 30 is formed as a flat, essentially planar structure. In a particular embodiment, the loop containing excess wires 30 is positioned inside OVC 14 such that a magnetic field produced by the superconducting magnet 10 is substantially parallel to the plane of the loop containing excess wires 30, to minimise magnetic coupling between the superconducting magnet 10 and the loop containing excess wires 30.
The effect of other magnetic fields may also be taken into account, such that total local magnetic field is substantially parallel to the plane of the non-inductively-wound windings. Such arrangement minimises the current induced in the non-inductively-wound windings due to external field changes as a result of energisation of the superconducting magnet and other coils associated with the superconducting magnet. For example, gradient coils produce a rapidly varying magnetic field which may have a greater potential for inducing current on the loop(s) of excess wire 30 than any likely variation in the main magnet field.
It is important that the superconducting wire 2 is restrained in position, as far as is practicable. If the superconducting wire were free to move, any movement would take place within the magnetic field of the superconducting coil, and so a voltage would be induced in the wires, which may cause interference with the magnet magnetic field, and could even lead to quench of the magnetic field.
In the illustrated embodiment, this is achieved by use of nylon cable ties 27.
In an alternative embodiment, the excess wire 30 may be wrapped around retaining posts provided for the purpose. Other means for retaining the excess wire in position may be employed, as will be apparent to those skilled in the art.
In an example embodiment, the inventors found that a join according to the present disclosure, in use in a superconducting state, had a resistance of less than 10−12 ohm, providing a power dissipation of no more than 10−6 watts at a current of up to 1000 amperes. This low level of power dissipation, combined with high thermal conductivity between the join and the coil of superconducting wire 3 means that the temperature of the join will rise very little.
The phenomenon of flux jumping is discussed in E. W. Collings and M. D. Sumption, “Stability and AC Losses in HTSC/Ag Multifilamentary Strands” Applied Superconductivity Vol. 3, No. 11/12, pp. 551-557, 1995.
Flux jumping of magnet joints could lead to the quench of the whole magnet, and so should be avoided as far as reasonably possible.
From adiabatic theory of flux jumping it could be shown that a characteristic flux jumping dimension is proportional to: specific heat C, difference between critical temperature Tc and operating temperature T and inversely proportional to critical current density Jc of superconductor (Equation 1): When size of superconducting alloy is above aFJ flux jumps are possible.
Often the combination of C, Tc, Jc at operating temperature T of superconducting alloy 42 used in superconducting joints requires the characteristic dimension aFJ to be less than 10-20 mm. This dimensional restriction makes it very challenging to store excess length of the joined superconducting wires 30 embedded in superconducting alloy 42.
According to at least one embodiment of the present disclosure, the excess wires 30 are stored in a figure-of-eight loop. Arranging excess wire storage 30 in this way allows for reducing the dimensions of superconducting alloy 42 to below characteristic dimension aFJ. In the case of the embodiment of
Number | Date | Country | Kind |
---|---|---|---|
1808760 | May 2018 | GB | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2019/058992 | 4/9/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/228698 | 12/5/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3449818 | Chase | Jun 1969 | A |
4270264 | Weisse | Jun 1981 | A |
4558512 | Chaussy | Dec 1985 | A |
4584547 | Thornton | Apr 1986 | A |
4625193 | Purcell | Nov 1986 | A |
4692560 | Hotta | Sep 1987 | A |
4713878 | Kumpitsch et al. | Dec 1987 | A |
4845308 | Womack, Jr. | Jul 1989 | A |
4902995 | Vermilyea | Feb 1990 | A |
4924198 | Laskaris | May 1990 | A |
5215242 | Kosky | Jun 1993 | A |
5252800 | Kosky | Oct 1993 | A |
5253413 | Dorri | Oct 1993 | A |
5307037 | Woods | Apr 1994 | A |
5583319 | Lieurance | Dec 1996 | A |
8253024 | Belton et al. | Aug 2012 | B2 |
8315680 | Le Feuvre et al. | Nov 2012 | B2 |
8525023 | Tigwell | Sep 2013 | B2 |
8731629 | King | May 2014 | B2 |
20030051901 | Morita et al. | Mar 2003 | A1 |
20060153579 | Phipps | Jul 2006 | A1 |
20090280989 | Astra | Nov 2009 | A1 |
20100190649 | Doll | Jul 2010 | A1 |
20130090245 | Simpkins | Apr 2013 | A1 |
20140024534 | Lakrimi et al. | Jan 2014 | A1 |
20160086693 | Lakrimi et al. | Mar 2016 | A1 |
Number | Date | Country |
---|---|---|
101414742 | Apr 2011 | CN |
102971914 | Mar 2013 | CN |
103578681 | Feb 2014 | CN |
204010879 | Dec 2014 | CN |
104319058 | Jan 2015 | CN |
104319508 | Jan 2015 | CN |
104733151 | Jun 2015 | CN |
105825992 | Aug 2016 | CN |
S5577109 | Jun 1980 | JP |
S58159714 | Oct 1983 | JP |
S60175383 | Sep 1985 | JP |
S60182673 | Sep 1985 | JP |
0101048 | Jan 2001 | WO |
2010088254 | Aug 2010 | WO |
Entry |
---|
International Search Report dated Jul. 18, 2019 for International Application No. PCT/EP2019/058992. |
Search Report dated Nov. 20, 2018 for Application No. GB1808760.1. |
E.W. Collings and M.D. Sumption, “Stability and AC Losses in HTSC/Ag Multifilamentary Strands” Applied Superconductivity vol. 3, No. 11/12, pp. 551-557, 1995. |
Number | Date | Country | |
---|---|---|---|
20210210266 A1 | Jul 2021 | US |