In one or more embodiments, a system for operation in a generator mode comprises a cryocooler to cool a superconducting coil. The system further comprises a flux pump to provide flux to the superconducting coil. Also, the system comprises a shaft of a prime mover to receive torque to rotate a rotor. In addition, the system comprises the superconducting coil to electrically interact with a main stator coil through a rotating magnetic field. Further, the system comprises a control stator coil to receive a current from a controller and to electrically interact with a non-superconducting coil. In one or more embodiments, a magnitude, phase, and/or frequency of rotating magnetic fields of the superconducting coil and the non-superconducting coil is varied in comparison to a magnitude, phase, and/or frequency of the magnetic field produced by the superconducting coil alone to control a magnitude, phase, and/or frequency of an output voltage.

Embodiments described herein provide devices, systems, and techniques for generating a magnetic field pattern that includes a plurality of magnetic poles. In specific embodiments, a magnetic device is disclosed which generates a magnetic field pattern including two magnetic poles of the same polarity on both ends, or sides of the magnetic device, and a third magnetic pole of a different polarity from the other two magnetic poles, wherein the third magnetic pole is located inside the magnetic device and between the other two magnetic poles. Moreover, the magnetic device is configured with two openings located at the two transition boundaries/interfaces of the three-pole magnetic field. As such, the two transition boundaries become accessible to objects. In particular, when another magnet is inserted at an interface between two magnetic poles, the magnet will “register” right at the interface and hover over or be suspended at the opening of the magnetic device.

Embodiments described herein provide devices, systems, and techniques for generating a magnetic field pattern that includes a plurality of magnetic poles. In specific embodiments, a magnetic device is disclosed which generates a magnetic field pattern including two magnetic poles of the same polarity on both ends, or sides of the magnetic device, and a third magnetic pole of a different polarity from the other two magnetic poles, wherein the third magnetic pole is located inside the magnetic device and between the other two magnetic poles. Moreover, the magnetic device is configured with two openings located at the two transition boundaries/interfaces of the three-pole magnetic field. As such, the two transition boundaries become accessible to objects. In particular, when another magnet is inserted at an interface between two magnetic poles, the magnet will “register” right at the interface and hover over or be suspended at the opening of the magnetic device.

An assembly having a cylindrical structure supported by a support structure having at least one support element, the support structure being cradle shaped, such that vertical and horizontal loads are taken largely as shear forces by respective interface surfaces which are substantially parallel to the direction of the respective load, and vertical loads are taken in a direction substantially tangential to the cylindrical surface of the cylindrical structure.

An assembly having a cylindrical structure supported by a support structure having at least one support element, the support structure being cradle shaped, such that vertical and horizontal loads are taken largely as shear forces by respective interface surfaces which are substantially parallel to the direction of the respective load, and vertical loads are taken in a direction substantially tangential to the cylindrical surface of the cylindrical structure.

A system for providing a magnetic field for a sample includes a first contact surface for thermally contacting the sample and a second contact surface, which is in thermal contact with at least one magnetic element.

A dual coil solenoid valve is disclosed for a fuel gas control valve, which comprises a stationary coil assembly and a moving coil assembly, wherein both the stationary coil assembly and the moving coil assembly consist of a magnetic core and a coil. Grooves are provided on the inside of the magnetic cores and coils are arranged in the grooves of the magnetic cores. The stationary coil assembly and the moving coil assembly have an equal cross-sectional area and are arranged oppositely with their axes coinciding with each other. The coils are arranged in the grooves of the magnet cores in such a way that the leakage flux can be reduced and the electromagnetic forces can be increased.

A current lead assembly for minimizing heat load to a conduction cooled superconducting magnet during a ramp operation is provided. The current lead assembly includes a vacuum chamber having a through hole to enable a first end of a current lead contact to remain outside the vacuum chamber and a second end of the current lead contact to penetrate within the vacuum chamber. A vacuum boundary wall is located between the vacuum chamber and the current lead contact. At least one superconducting magnet is arranged inside of the vacuum chamber and includes a magnet lead. A second end of the current lead contact is coupled to the magnet lead via an internal lead. A vacuum cap is removably disposed to sealingly encompass therein the first end of the current lead contact during a first state of operation. The first end of the current lead contact is arranged to contact a power supply during a second state of operation, wherein the contact occurs exterior the vacuum chamber.

A superconducting magnet apparatus includes a plurality of superconducting magnet coil sections connected in series and housed within a cryogenically cooled, vacuum container. A power source generates a current. A first lead is electrically connected to the superconducting magnet coil sections. A second lead is enclosed entirely within the vacuum container. The second lead has a first section and a second section, and the first section is electrically connected to the power source. The second section is electrically connected to the first lead, and rigidly connected to a linear displacement device enclosed entirely within the vacuum container. The linear displacement device linearly displaces the second section relative to the first section, so that the first section contacts the second section thereby electrically connecting the first and second sections, or by creating a gap between the first section and second section thereby electrically disconnecting the first section from the second section.

Charging method for a superconductor magnet system with reduced stray field, weight and space includes: arranging the system within a charger magnet bore; with T.sub.main>T.sub.main.sup.crit and T.sub.shield>T.sub.shield.sup.crit, applying a current I.sub.charger to the charger magnet and increasing I.sub.charger to a first current I.sub.1>0; lowering a main superconductor bulk magnet temperature T.sub.main to an operation temperature T.sub.main.sup.op, with T.sub.main.sup.op<T.sub.main.sup.crit, while keeping T.sub.shield>T.sub.shield.sup.crit; lowering I.sub.charger to a second current I.sub.2<0, thereby inducing a persistent current IP.sub.main in the main magnet; lowering a shield magnet temperature T.sub.shield to an operation temperature T.sub.shield.sup.op, with T.sub.shield.sup.op<T.sub.shield.sup.crit; increasing I.sub.charger to zero, thereby inducing a persistent current IP.sub.shield in the shield magnet; removing the magnet system from the charger bore, and keeping T.sub.main≤T.sub.main.sup.op with T.sub.main.sup.op<T.sub.main.sup.crit and T.sub.shield≤T.sub.shield.sup.op with T.sub.shield.sup.op<T.sub.shield.sup.crit; where: T.sub.main.sup.crit: main magnet critical temperature and T.sub.shield.sup.crit: shield magnet critical temperature.