Superconducting magnet split cryostat interconnect assembly

Refrigeration – Storage of solidified or liquified gas – With conservation of cryogen by reduction of vapor to liquid...

Reexamination Certificate

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C062S051100, C335S216000

Reexamination Certificate

active

06289681

ABSTRACT:

BACKGROUND OF INVENTION
This invention relates to a split cryostat superconducting magnet, and more particularly to the interconnect assembly between the magnets.
As is well known, a superconducting magnet can be made superconducting by placing it in an extremely cold environment, such as by enclosing it in a cryostat or pressure vessel containing liquid helium or other cryogen. The extreme cold ensures that the magnet coils can be made superconducting, such that when a power source is initially connected to the coil (for a relatively short period) current continues to flow through the coils even after power is removed due to the absence of resistance, thereby maintaining a strong magnetic field. Superconducting magnets find wide application in the field of Magnetic Resonance Imaging (hereinafter MRI).
Another problem encountered by conventional and early MRI equipments is that they utilize solenoidal magnets enclosed in cylindrical structures with a central bore opening for patient access. However, in such an arrangement, the patient is practically enclosed in the warm bore, which can induce claustrophobia in some patients. The desirability of an open architecture magnet in which the patient is not essentially totally enclosed has long been recognized. Unfortunately, an open architecture structure poses a number of technical problems and challenges.
One type of open architecture superconducting magnet utilizes a split dewar or split liquid helium vessels with the lower helium vessel and the upper helium vessel connected by a helium passageway or transfer tube. A helium recondenser may be connected to the upper helium vessel to receive the boiled helium gas from both vessels for recondensing back to liquid helium which is flowed into the upper helium vessel and by gravity through the vertical transfer tube in the interconnect support to the lower helium vessel. A loss of sufficient liquid helium in either vessel can cause highly undesirable quenching or discontinuance of superconducting operation of the magnet. Replenishing the liquid helium supply followed by restarting superconducting operation is expensive in terms of cost and down time of the MRI equipment. Such a loss of liquid helium can result, for example, from failure of a mechanical cryocooler associated with a helium recondenser. Cryocoolers are typically positioned in a sleeve which enables cryocooler repair or replacement without opening the helium vessel to the outside. However, replacement of the cryocooler must be made in the period after the problem is detected and before superconducting operation ceases. This period is known as the ride-through period during which the final period of superconducting magnet operation and helium boiloff continues before quenching of the superconducting magnet.
It is highly desirable to be able to extend the ride-through period to provide sufficient time for detection and correction of the problem such as by replacement of a cryocooler, and also to avoid the possibility of peak temperatures being generated by superconducting operation quench which could exceed the critical temperature of the superconducting wires with which the magnet coils are wound, resulting in magnet damage.
In addition to providing an increased ride-through period the magnet interconnect must provide adequate strength and rigidity in the presence of extreme thermal contraction and expansion encountered by the superconducting magnet and to provide suitable electrical and helium gas interconnections between the magnet coils in each of the helium vessels.
SUMMARY OF INVENTION
Thus, there is a particular need for an interconnect assembly to extend the ride through period of a superconducting magnet to provide additional time to correct the problem and avoid the aforementioned magnet quench problems, and to provide the necessary mechanical, thermal, electrical and helium interconnections.
In accordance with one form of the invention, an open recondensing architecture superconducting magnet includes an upper and lower separated cryogen vessel each including superconducting magnet coils and liquid cryogen, and separated by an interconnect assembly. The magnet is isothermalized by a layer of highly thermally conductive aluminum around the cryogen vessels and through the interconnect assembly providing a low thermal resistivity, high thermally conductive path between the cryogen vessels to conduct heat away from the cryogen vessel of higher temperature to the cryogen vessel of lower temperature. A flexible thermal joint is provided within the interconnect assembly. The isothermal members extend the ride-through period of magnet superconducting operation in the event of recondensing or other failure which results in an increase in temperature in the magnet.
More particularly the aluminum layer is RRR 1500 aluminum {fraction (1/16)}-¼ inch thick, the joints of which are welded for at least 50% of their length.
The high purity aluminum tube in the interconnect includes a flexible joint which in combination with a bellows on the outer stainless steel tube accommodates thermal contraction and expansion. Helium gas boiloff from the lower helium vessel is vented to the interior of the interconnect assembly for transfer to the helium gas recondenser, and a phenolic board axially extending through the interior of the interconnect assembly provides added strength to the structure and an insulated support for the superconducting wires interconnecting magnet coils of the two vessels.


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