Abstract: Viable (HT) superconductor-based processing is disclosed comprising the controlled conversion of energy resulting from application of a (HT) superconductor to an electric, magnetic, electromagnetic and/or gravitational field, wherein the converted energy is released from a corresponding chill system in order to maintain a superconducting state of the (HT) superconductor under controlled extrinsic or boundary conditions. A closed vessel is instrumental to transform said energy once created into a mechanical work, a partial chill gas mass per operating time interval, i.e. &dgr;dmV/&dgr;t, and a partial conduction enthalpy. A corresponding chill system comprises optionally at least one aeropneumatic accumulator designed to operate at least one (HT) superconductor-based overpressure vessel or dewar accommodating at least one superconductor element immersed into a liquid chill agent such as liquid nitrogen of defined heat capacity per volume superconductor employed.

Abstract: The present invention relates to a cooling system for a cryostat incorporating a pulse tube refrigerator 8. The cryostat usually consists of several interior cylindrical or oval-shaped vessels for storing liquids. The cryostat for MRI/NMR applications and related fields usually comprises an outer vacuum case, a nitrogen can or a radiation shield instead, and a further radiation shield and the helium vessel housing 4 the superconducting magnet 2. The magnet usually is made of NbTi, Nb3Sn, or some HTC conductor or a combination of both. The present invention uses a pulse tube refrigerator 8, the so-called pulse tube cooler, which essentially comprises an empty tube and a further tube housing the regenerator material for the cooler, which is inserted into any opening of a cryostat. The opening is defined as e.g. the neck-tube 6 or any other location required for accessing the cryostat, e.g.

Abstract: A cryogenic inertial Micro-Electro-Mechanical System (MEMS) device is provided. The device may include a vibratory gyroscope operable to sense a rotational acceleration. The device may also include a pre-amplifier co-located in a close proximity to the vibratory gyroscope. The device may be operated at substantially low temperatures, such as cryogenic temperatures, to reduce electrical noise and improve stability of outputs of the system.

Abstract: A multi-purpose thermal insulation test apparatus is used for testing insulation materials, or other components. The test apparatus is a fluid boil-off calorimeter system for calibrated measurement of the apparent thermal conductivity (k-value) of a specimen material at a fixed vacuum level. The apparatus includes an inner vessel for receiving a fluid with a normal boiling point below ambient temperature, such as liquid nitrogen, enclosed within a vacuum chamber. A cold mass assembly, including the inner vessel and thermal guards, is suspended from the top of the vacuum chamber. Handling tools attach to the cold mass assembly for convenient manipulation of the assembly and for the installation or wrapping of insulation test materials. Liquid nitrogen is typically supplied to the inner vessel using a fill tube with funnel. A single port through the top of the vacuum chamber facilitates both filling and venting.

Abstract: An apparatus and method for disinfecting a microtome and cryostat is provided. The cryostat comprises a chamber, a pump communicating with the chamber, an ozone generator and an ozone destroyer. A microtome is located in the chamber. Oxygen molecules in ambient air are converted to ozone that is injected into the cryostat chamber, disinfecting the chamber and the microtome. After disinfection, the air and ozone present in the chamber is directed to an ozone destroying unit that eliminates any remaining ozone. This eliminates the risk of ozone exposure to nearby operators and minimizes damage to the cryostat and microtome from extended ozone contact.

Abstract: A cooling apparatus has a liquid helium container for containing liquid helium, a vacuum chamber for providing heat insulation to external air, and a cooling head disposed in the vacuum chamber and capable of cooling down to a temperature region corresponding to the melting point of the liquid helium in the liquid helium container. An inlet port is disposed in the vacuum chamber for introducing thereinto the liquid helium stored in the liquid helium container. A vacuum heat insulation piping transfers liquid helium from the liquid helium container to the inlet port. A first piping is disposed in the vacuum chamber for transferring the liquid helium from the inlet port to the cooling head. A pump pumps liquid helium from the liquid helium container to the cooling head via the vacuum heat insulation piping, the inlet port and the first piping. A second piping transfers the liquid helium from the cooling head to the pump. At least part of the second piping is disposed in the vacuum chamber.

Abstract: An apparatus and method for disinfecting a microtome and cryostat is provided. The cryostat comprises a chamber, a pump communicating with the chamber, an ozone generator and an ozone destroyer. A microtome is located in the chamber. Oxygen molecules in ambient air are converted to ozone that is injected into the cryostat chamber, disinfecting the chamber and the microtome. After disinfection, the air and ozone present in the chamber is directed to an ozone destroying unit that eliminates any remaining ozone. This eliminates the risk of ozone exposure to nearby operators and minimizes damage to the cryostat and microtome from extended ozone contact.

Abstract: The invention is directed to novel cryogenic liquid transport and storage containers, which utilize external coolant tanks to supply cooling to a cryogenic liquid storage tank. The coolant tanks are mounted above the cryogenic liquid storage tank such that the length of the cryogenic liquid storage tank is capable of extending the entire length of the transport container.

Abstract: An improved and simplified system for densifying a cryogenic liquid for space vehicles is provided, which includes a heat exchanger having heat exchange tubes therein for receiving a flow of liquid from a storage tank, for example a liquid propellant in a vehicle storage tank. The heat exchanger is filled around the exchange tubes with a two-component bath, the volume of a primary component substantially exceeding the volume of a secondary component. The secondary component has a boiling temperature that is lower than the boiling temperature of the primary component, and both are lower than the boiling temperature of the cryogenic liquid. In one example, the liquid to be densified is oxygen, the primary component is liquid nitrogen, and a secondary component is liquid hydrogen. The secondary component is preferably injected into the heat exchanger in separate flows to prevent localized freezing of the first component.

Abstract: A cooling fluid system is disclosed for providing cryogenic cooling fluid to a high temperature super-conducting machine, wherein said system includes a main cooling system (52, 88) and a second cooling system, said second cooling system comprising a storage device having a first cryogenic fluid; at least one cooling coupling in fluid communication with the first cryogenic fluid from the storage device and a second cryogenic fluid flowing through the main cooling system.

Abstract: A cooling fluid system is disclosed for providing cryogenic cooling fluid to a high temperature super-conducting rotor comprising: a re-circulation compressor; a storage tank having a second cryogenic fluid; an inlet line connecting the re-circulation compressor to the storage tank and to the rotor, and forming a passage for cooling fluid to pass from the re-circulation compressor through the storage tank and to the apparatus.

Abstract: A cryogenic vessel system for containing cryogenic fluid wherein heat leak into the vessel interior is counteracted by refrigeration generated from energy provided by a pulse generator.

Abstract: Methods of extracting and removing hyperpolarized gas from a container include introducing an extraction fluid into the container to force the hyperpolarized gas out of an exit port. The hyperpolarized gas is forced out of the container separate and apart from the extraction fluid. Alternatively, if the fluid is a gas, a portion of the gas is mixed with the hyperpolarized gas to form a sterile mixed fluid product suitable for introduction to a patient. An additional method includes engaging a gas transfer source such as a syringe to a transport container and pulling a quantity of the hyperpolarized gas out of the container in a controlled manner. Another method includes introducing a quantity of liquid into a container and covering at least one predetermined internal surface or component with the liquid to mask the surfaces and keep the hyperpolarized gas away from the predetermined internal surface, thereby inhibiting any depolarizing affect from same.

Abstract: A cryogenic cooling system for use with a superconductive electric machine includes a first set of components arranged in a first circuit and adapted to force flow of a cryogen in the first circuit to and from a superconductive electric machine and being operable in a cooldown mode for cooling the cryogen and thereby the superconductive electric machine to a normal operating temperature, and a second set of components arranged in a second circuit and adapted to force flow of a cryogen in the second circuit to and from the superconductive electric machine and being operable in a normal mode for maintaining the cryogen and thereby the superconductive electric machine at the normal operating temperature.

Abstract: A containment system for samples of dangerous goods stored at cryogenic temperatures includes a bag made of a cryogenically compatible polymer film and a porous structural cartridge made of a polypropylene polymer compound for holding a plurality of sample receptacles separate from one another to comply with the standards of UN Class 6.2 certification. The porous structural cartridge has a cartridge base with a plurality of sample receptacle apertures for holding the plurality of sample receptacles. A cartridge cover mates with the cartridge base to enclose the plurality of sample receptacle apertures. Additional cartridge bases can be included as part of the porous structural cartridge. Each cartridge has sufficient absorbing capacity to absorb the entire contents of all of the sample receptacles held within its sample receptacle apertures.

Abstract: A specimen chamber for storing materials in a dewar vessel that uses liquid cryogen is made of an open-celled porous thermoplastic material that is cryogenically compatible, such as an aerated polypropylene foam. The specimen chamber allows liquid cryogen to pass through it into a plastic foam and allows liquid cryogen in a vapor phase liquid state to pass from the plastic foam into it. The thermoplastic material of the specimen chamber acts as a filter to prevent particles or fragments of plastic foam from entering into the specimen chamber and also acts as a wicking device for rapid transfer of the liquid cryogen to the plastic foam.

Abstract: An improved freezer and plant gas system that harnesses the cooling properties of the plant gas evaporator to facilitate energy and cryogen savings, as well as the automation and optimization of a plant thermal processing system. The freezer preferably includes an internally mounted evaporator sized to meet the gas requirements of the plant processes requiring inert gas. By evaporating the plant gas in the freezer, the freezer can be remotely located from the liquid cryogen source while still making liquid cryogen available when called for during a cryogenic treatment process metal or other materials. In addition, by evaporating in the freezer the freezer is able to harness the cooling properties of the evaporator to pre-cool the freezer and material prior to use of liquid in the cooling cycle. Alternatively, a liquid load basket is adapted to economically thermally treat materials in a deep cryogenic treatment.

Abstract: An apparatus for refrigerating goods in a container storing a cryogenic fluid and means for discharging the fluid into the container in order to reduce the temperature therein, characterized in that the storing means is adapted to operate at atmospheric pressures but not at pressures substantially greater than atmospheric. Such a system provides a single and inexpensive means for refrigerating goods in a transportable container, which may be divisible into smaller compartments, and may also be provided with eutectic plates to act as a thermal “buffer” whenever the container/a compartment is opened for loading/unloading.

Abstract: A method and apparatus for cooling MRI system components including components that reside inside an RF shield such as an RF coil, a receiver coil, a patient support table and a patient enclosure wall wherein the cooling system employs a liquid coolant essentially devoid of protons and to that end, essentially devoid of hydrogen atoms.

Abstract: An open flow cryostat for cooling a sample in use comprises a supply (1) for supplying a coolant, an outlet (2) for directing a flow of the coolant towards the sample, a supply line (3) for transporting coolant from the supply to the outlet and an isolation line (5) arranged to transport at least some of the coolant away from the outlet. The isolation line (5) is positioned in contact with at least a portion of the supply line (3) to thermally isolate the supply line (3) from the surroundings.

Abstract: An improved liquid cryogen dewar for storing cryobiological materials is disclosed having an inner tank with a reservoir holding a pool of liquid cryogen. A rotatable tray is contained within the inner tank, containing a platform, vertical dividers and a thermally conductive cylindrical outer sleeve, which contains a skirt extending into the pool of liquid cryogen. The sleeve transfers entering heat away from the cryobiological materials and into the liquid cryogen pool. The sleeve maintains a consistently low temperature throughout the vertically disposed shelves of the cryobiological materials contained within the inner tank.

Abstract: A cryostat arrangement for keeping liquid helium comprising an outer shell (2), a helium container (6) installed therein and a neck pipe (4) extending from the helium container to the outer shell whose upper warm end is connected to the outer shell and whose lower cold end is connected to the helium container, wherein the outer shell, the helium container and the neck pipe define an evacuated space (13) containing a radiation shield (15) surrounding the helium container and being connected at a coupling to the neck pipe in a heat-conducting fashion, wherein a refrigerator is installed in the neck pipe having a cold finger (5a) which consists of at least one pipe and projects into the neck pipe, is characterized in that at least one pipe of the cold finger is surrounded by at least one separating body (3a) which divides the neck pipe into two partial volumes (8a and 9a) which are connected to one another through a lower opening (10a) and an upper opening (7a).

Abstract: A preferred embodiment of a bio-medical cryogenic system 10 is described having a unique canister support frame 100. The frame 100 is elongated when in the upright position having side walls 102 and 104, a top wall 114, a bottom wall 118, a back wall 122 and internal dividers 132 forming a narrow elongated cavity subdivided into canister compartments 136 having a front opening 130. Upright abutment lips 121 and 138 are positioned in the compartments 136 to prevent canisters 50 from being inadvertently dislodged from the compartments 136. Access slots 150 are formed in the back wall 122 and at least one of the side walls 102,104 to enable a laboratory person to insert their finger into the slot and push a canister forward while the other hand is lifting a front portion of the canister above the abutment lip 121 or 138.

Abstract: A cooling apparatus is described which includes a throttling valve and an adiabatic chamber having an input and an output, the output connected to an input of the cryostat. With such an arrangement, an improved cooling apparatus is provided with improved efficiency over known Joule-Thompson cooling apparatus.

Abstract: A heat insulation chamber according to the present invention is a heat insulation chamber which is made of heat insulating material and forms an inner chamber for accommodating an electronic part. This heat insulation chamber achieves coupling between the electronic part accommodated in the inner chamber formed within a cabinet and the outside of the cabinet by a radio transmission path or a coupling path by static coupling or inductive coupling. A thermostatic chamber and a cryostat according to the present invention comprise the aforementioned heat insulation chamber, a heat exchanger mounted in the heat insulation chamber, and a thermoregulator which maintains the temperature of the inner chamber accommodating the electronic part at an operating temperature of the electronic part through the heat exchanger.

Abstract: A cryostatic vessel 12 is radially interconnected inside a tubular thermal shield 18. A shield first endplate 20 includes a plurality of spacers 30 which are disposed in axial abutment with a corresponding first endplate 14 of the vessel during assembly. A shield second endplate 22 is disposed in axial abutment against an opposite end of the shield, and includes alignment holes 36 receiving corresponding alignment pins 32 extending from an opposite endplate 16 of the vessel. The spacers maintain a predetermined clearance between the endplates of the vessel and shield which clearance is precisely maintained upon fixedly joining both shield endplates to the shield.

Abstract: A compact device for injecting cryogenic liquid into containers is capable of use with containers of varying sizes. A vessel containing the cryogenic liquid is connected to a nozzle by a thermally-insulated, flexible hose. The nozzle is connected to an arm which is mounted to a support, such that the arm can move in different directions relative to the support. The nozzle can thus be moved with three degrees of freedom, and can be easily positioned over a container to be filled. The apparatus also includes conduits for conveying excess gas from the vessel into a process controller housing, to keep moisture out of that housing. The nozzle includes ports which receive gas formed by vaporizing cryogenic liquid from a supply. Gas flowing into these ports can be used to control the formation of droplets. When heated, such gas can also be used to prevent ice formation in the nozzle, or to remove ice that has already formed.

Abstract: Methods of collecting, thawing, and extending the useful polarized life of frozen polarized gases include heating a portion of the flow path and/or directly liquefying the frozen gas during thawing. A polarized noble gas product with an extended polarized life product is also included. Associated apparatus such as an accumulator and heating jacket for collecting, storing, and transporting polarized noble gases include a secondary flow channel which provides heat to a portion of the collection path during accumulation and during thawing.

Abstract: A withdrawal device is provided for use with a cryogenic tank having a neck in which the neck forms an opening to the interior of the tank. The withdrawal device includes a housing having a flange adapted to overlie and abut against the neck on the cryogenic tank. An elongated extraction tube has a first portion which extends into the interior of the tank and a second portion which extends laterally outwardly from the housing exteriorly of the tank. An axially compressible resilient annular seal is mounted to the housing so that one end of the seal abuts against the flange while a seal support overlies the opposite end of the seal. Both the seal support as well as the seal are dimensioned for insertion into the neck. An elongated rod extends through the housing and has one end secured to the seal support while a second end of the rod is positioned above the housing.

Abstract: A cryostat arrangement for keeping liquid helium comprising an outer shell (2), a helium container (6) installed therein and a neck pipe (4) extending from the helium container to the outer shell whose upper warm end is connected to the outer shell and whose lower cold end is connected to the helium container, wherein the outer shell, the helium container and the neck pipe define an evacuated space (13) containing a radiation shield (15) surrounding the helium container and being connected at a coupling to the neck pipe in a heat-conducting fashion, wherein a refrigerator is installed in the neck pipe having a cold finger (5a) which consists of at least one pipe and projects into the neck pipe, is characterized in that at least one pipe of the cold finger is surrounded by at least one separating body (3a) which divides the neck pipe into two partial volumes (8a and 9a) which are connected to one another through a lower opening (10a) and an upper opening (7a).

Abstract: In the apparatus for cooling a superconductor in accordance with the present invention, a male thread portion of an inner container engages a female thread portion of an outer container so as to connect the inner and outer containers to each other. Also, the bottom wall of the inner container is provided with a thermal conductor penetrating therethrough. Further, a sapphire sheet is joined to peripheral portions of an opening of the bottom wall of the outer container facing the thermal conductor, so as to block the opening. As the distance between the bottom wall of the outer container and the bottom wall of the inner container is freely adjusted by changing the engaging position between the thread portions, the gap between a high transition temperature (high Tc) superconducting magnetic sensor and the sapphire sheet is adjusted.

Abstract: A method of using a cryostat comprises supplying a stream of cold cryogas over a specimen, and surrounding said stream in the vicinity of the specimen by a dry annular flow of the same cryogas at ambient temperature. A nozzle for the cryostat comprises a central feed tube (36) for supplying the stream of cold cryogas over a specimen (35), and an annular feed opening (34) for supplying the dry annular flow of the same cryogas at ambient temperature.

Abstract: Coolant (3) whose boiling point is higher than the temperature of cooled SQUID elements (2) as cooled objects is poured into an inner container (37) for containing SQUID elements. The SQUID elements (2) are soaked in the coolant (3). Before the inner container (37) for containing SQUID elements is used, the coolant (3) is cooled and solidified by a refrigerator (7).

Abstract: A cryostat for a superconducting transformer is provided that includes non-conducting load bearing insulation and is adapted for use with a superconducting transformer. In addition, the cryostat prevents the formation of closed loop stray currents on its outer case. The cryostat contains the winding sets and other related electrical equipment of a transformer. The cryostat generally comprises a cryogenic tank having an outer wall, a non-conducting liner, and a load bearing insulation layer disposed therebetween. The tank holds a liquid or gaseous cryogenic coolant into which the components of the transformer are immersed. A plurality of passages allow the passage of the limbs of the iron core of the transformer through the tank.

Abstract: Disclosed is a method of controlling alignment of a rotor of an SRM with respect to a stator, the SRM including a stator having a plurality of diametrically opposed stator salient magnetic pole pairs around each which each of a plurality of phase coils is wound, and a rotor disposed about a shaft within the stator and having a plurality of diametrically opposed rotor salient pole pairs, comprising the steps of: (a) applying a voltage pulse having an identical magnitude to each phase coil surrounding the plurality of pairs of stator salient magnetic poles in a plurality of respective motor phases of a stator of the SRM upon the initial starting of the SRM; (b) detecting current flowing into the each phase coil in the plurality of respective motor phases in accordance to the application of the voltage pulse; (c) comparing the respective magnitude values of the detected current in the respective motor phases with each other; and (d) bringing rotor salient pole pair of the rotor into alignment with a correspondin

Abstract: A double-tube type heat exchanger has a restriction hole (6), formed on an inner tube (3), through which a refrigerant introduced into an outer tube (3) is introduced into the inner tube (3) while the refrigerant expands. Therefore, a part of the refrigerant introduced into the outer tube (3) can be introduced into the inner tube (2) from the restriction hole (6) while the refrigerant expands. That is, the restriction hole (6) formed on the inner tube (2) serves as an expansion mechanism of a bypass flow. Therefore, this double-tube type heat exchanger (1) allows an injection circuit or a super-cooling circuit to be compactly and inexpensively constructed.

Abstract: Self-triggering cryogenic heat flow switches are used particularly with cooling systems that require a redundant operation. The self-triggering cryogenic heat flow switch has the simplest possible construction while providing a reliable, maintenance-free mode of operation, and ensures a self-switching connection between a heat sink and an end use device or application that is to be cooled. The heat flow switch includes an outer hollow cylinder 1 that is connected with a heat sink 9, and an inner body 2 that is arranged coaxially to the outer hollow cylinder 1 and connected to the end use device or application to be cooled. When the heat sink 9 is switched off, a concentric annular gap 4 fixed by spacers is provided between the hollow cylinder 1 and the inner body 2.

Abstract: Methods of extracting and removing hyperpolarized gas from a container include introducing an extraction fluid into the container to force the hyperpolarized gas out of an exit port. The hyperpolarized gas is forced out of the container separate and apart from the extraction fluid. Alternatively, if the fluid is a gas, a portion of the gas is mixed with the hyperpolarized gas to form a sterile mixed fluid product suitable for introduction to a patient. An additional method includes engaging a gas transfer source such as a syringe to a transport container and pulling a quantity of the hyperpolarized gas out of the container in a controlled manner. Another method includes introducing a quantity of liquid into a container and covering at least one predetermined internal surface or component with the liquid to mask the surfaces and keep the hyperpolarized gas away from the predetermined internal surface, thereby inhibiting any depolarizing affect from same.

Abstract: A method and apparatus for activating fusible links on a circuit substrate. The circuit substrate is supported in a fixture which is cooled to a below ambient temperature. Cooling of the circuit substrate decreases the absorption of energy by the substrate, permitting a smaller spot size laser beam having a lower wavelength to be employed for interrupting the fusible links. The substrate is cooled by a refrigeration coil in heat transfer with the fixture holding the substrate. Moisture formation is avoided by placing the substrate and laser source in a controlled atmosphere.

Abstract: To provide cooling apparatus for cooling a workpiece or sensor down to the region of the melting point of helium where it is not necessary to pre-cool the inside of the apparatus using liquid nitrogen etc., and where the time and trouble involved in performing the cooling can be omitted.

Abstract: A process for preparing hyperpolarized helium gas at high pressure including optical pumping at a resonant wavelength of about 1083 nanometers a helium gas formed by pure helium-3 isotope or by a mixture of helium-3 and helium-4 isotopes; and subjecting the helium gas to a magnetic field of about 0.01 to about 1 tesla during optical pumping and maintaining pressure higher than about 10 mbar and an apparatus for preparing a hyperpolarized helium gas at high pressure including a helium gas confinement cell; an excitation laser positioned to irradiate the helium gas; and means for generating a magnetic field of about 0.01 to about 1 tesla operatively connected to the confinement cell.

Abstract: A multi purpose interconnect assembly between upper and lower helium vessels in a recondensing superconducting magnet to provide isothermal connections to extend the ride-through period, and to provide for helium liquid and gas passage, electrical interconnections, and to accommodate differential thermal contraction and expansion.

Abstract: An apparatus for forming an amorphous tissue specimen into a cooled block while preserving the anatomical orientation of the specimen includes a base assembly, a system of magnetic movable wall units and a cover which may be intercoupled to form an enclosed specimen cavity. The wall units each include a hinged panel at one end, so that the wall units may be adjustably intercoupled to form various planar surfaced shapes, such as a rhomboid or eccentric block form. Each wall unit also includes a reservoir for a refrigerant such as liquid nitrogen for cooling the enclosed specimen to an optimal temperature for tissue cutting. The base is equipped with orientation indicia and temperature sensors. A synthetic resin may be applied to the specimen-contacting surfaces of the form in order to facilitate release of the cooled specimen.

Abstract: A CT scanner (10) for obtaining a medical diagnostic image of a subject includes a stationary gantry (12), and a rotating gantry (16) rotatably supported on the stationary gantry (12) for rotation about the subject. A fluid bearing (18) is interposed between the stationary and rotating gantries (12) and (16), respectively. The fluid bearing (18) provides a fluid barrier (110) which separates the rotating gantry (16) from the stationary gantry (12). In a preferred embodiment, the fluid bearing (18) provides for quieter CT scanner operation at high rotational speeds. Moreover, eliminating the physical contact between the gantries minimizes wear and optimizes longevity.

Abstract: A cryogenic thermal switch operates based on the principle of differential coefficients of thermal expansion of differing materials. A small gap is either closed or opened, dependant upon the relative dimensions of two pieces of differing materials. As the temperature of the pieces is raised, the piece having the greater coefficient of thermal expansion (CTE) increases its dimensions at a greater rate, causing a gap to open up. Conversely, when the temperature of the pieces is lowered, the piece having the greater CTE shrinks proportionally faster, thereby closing the gap. The present invention makes use of a reliable flat-faced geometry for the two sides of the gap.

Abstract: The invention relates to a high-pressure freezing system in which the pressure build-up ensues from a prestressed pneumatic cylinder. This results in a particularly rapid pressure rise in the sample holder.

Abstract: A magnet, such as an open or closed magnet, has a first assembly with at least one superconductive main coil and with a first vacuum enclosure enclosing the main coil(s). A first cryocooler coldhead has a rigid first housing and is generally vertically aligned. A first flexible bellows is vertically aligned, has a first end attached to the first housing of the first cryocooler coldhead and has a second end attached to the first vacuum enclosure of the first assembly.

Abstract: Ergonomic systems which provide medical therapy, comfort and enhanced function are provided. Surfaces are provided with adjustable contour, transient force damping and temperature. The technologies are applied to footwear, seating surfaces an cryotherapy devices. The cooling and cryotherapy system employ an evaporator in close proximity to skin, and therefore employ methods to reduce risk of frostbite. Advanced control and power supply options are disclosed.

Abstract: Described herein is an improved suspension system for cryostat vessels forming a part of magnetic resonance imaging (MRI) apparatus. The MRI apparatus comprises an outer cylindrical element, an inner cylindrical element mounted within the outer element, and a suspension system for accurately mounting the inner element with respect to the outer element. The suspension system comprises a plate (40) pivotally mounted on the inner cylindrical element (10) for rotation relative thereto and a pair of continuous bands (66, 68) connecting the plate (40) to the outer element. Adjusters are positioned offset from the axis of rotation of the plate for tensioning the bands. Locking means are also provided to retain the plate in a given position relative to the outer element.

Abstract: A cryogenic storage device is disclosed having a tank with an open top and a wall which defines an interior chamber adapted to receive biological specimens. A fluid reservoir is disposed around at least a portion of the wall on an outer surface of the wall and this fluid reservoir receives a liquefied gaseous material, such as liquid nitrogen. The source of the liquid gaseous material is fluidly connected through a valve to the reservoir to maintain the level of the liquefied gaseous material between preset limits in the reservoir thus cooling the interior of the interior chamber and any biological specimens contained within the interior of the chamber.