A magnetic levitation system (100) for transporting a carrier (10) in a transport direction (T) is described. The magnetic levitation system includes at least one magnetic bearing (120) having a first actuator (121) with a U-shaped electromagnet for contactlessly holding the carrier (10) in a carrier transportation space (15), and a drive unit (130) having a second actuator (131) for moving the carrier (10) in the transport direction. The second actuator (131) or a projection of the second actuator along the transport direction (T) is partially surrounded by the U-shaped electromagnet.

A magnetic levitation system (100) for transporting a carrier (10) in a transport direction (T) is described. The magnetic levitation system includes at least one magnetic bearing (120) having a first actuator (121) with a U-shaped electromagnet for contactlessly holding the carrier (10) in a carrier transportation space (15), and a drive unit (130) having a second actuator (131) for moving the carrier (10) in the transport direction. The second actuator (131) or a projection of the second actuator along the transport direction (T) is partially surrounded by the U-shaped electromagnet.

A flywheel assembly for a renewable energy generation system includes a flywheel housing defining a cavity therein, a flywheel rotatably disposed within the cavity of the flywheel housing, where the flywheel is simultaneously formed from the same component as the flywheel housing, a magnetic levitation disk defining opposed upper and lower surfaces, the upper surface supporting the flywheel and the lower surface including a first plurality of magnets disposed thereon, and a base plate having a second plurality of magnets disposed on a surface thereof that is facing the first plurality of magnets, the second plurality of magnets having a polarity that is opposite of a polarity of the first plurality of magnets such that the magnetic force of the first and second plurality of magnets urges the magnetic levitation disk away from the base plate.

A flywheel assembly for a renewable energy generation system includes a flywheel housing defining a cavity therein, a flywheel rotatably disposed within the cavity of the flywheel housing, where the flywheel is simultaneously formed from the same component as the flywheel housing, a magnetic levitation disk defining opposed upper and lower surfaces, the upper surface supporting the flywheel and the lower surface including a first plurality of magnets disposed thereon, and a base plate having a second plurality of magnets disposed on a surface thereof that is facing the first plurality of magnets, the second plurality of magnets having a polarity that is opposite of a polarity of the first plurality of magnets such that the magnetic force of the first and second plurality of magnets urges the magnetic levitation disk away from the base plate.

The present disclosure provides a support device and a display apparatus. The support device includes: a support platform; a base disposed opposite to the support platform; and a plurality of superconducting magnetic levitation structures, each of the superconducting magnetic levitation structures including a superconductor and a magnet disposed oppositely; in each of the superconducting magnetic levitation structures, one of the superconductor and the magnet is disposed on the support platform, and the other is disposed on the base. The plurality of superconducting magnetic levitation structures are arranged to operate independently of each other without interference, and a repulsive force between the superconductor and the magnet of each of the superconducting magnetic levitation structures is set to be adjustable.

The present disclosure provides a support device and a display apparatus. The support device includes: a support platform; a base disposed opposite to the support platform; and a plurality of superconducting magnetic levitation structures, each of the superconducting magnetic levitation structures including a superconductor and a magnet disposed oppositely; in each of the superconducting magnetic levitation structures, one of the superconductor and the magnet is disposed on the support platform, and the other is disposed on the base. The plurality of superconducting magnetic levitation structures are arranged to operate independently of each other without interference, and a repulsive force between the superconductor and the magnet of each of the superconducting magnetic levitation structures is set to be adjustable.

A maglev power generator has a frame, a transmitting shaft, two electricity generating sets, two axial vibration-proof sets, two maglev assemblies, and two radial vibration-proof sets. The transmitting shaft longitudinally extends within the frame. The two electricity generating sets, the two maglev assemblies, and the two radial vibration-proof sets are connected to the transmitting shaft. Each axial vibration-proof set contacts a respective end of the transmitting shaft. The transmitting shaft suspends within the frame and is able to rotate without contact with the frame. The axial vibration-proof sets, the maglev assemblies, and the radial vibration-proof sets provide the transmitting shaft with magnetic forces radially and axially to prevent the rotating transmitting shaft from deviation. Therefore, the transmitting shaft is able to rotate with minimum power loss. The axial vibration-proof sets and the radial vibration-proof sets effectively offer a good vibration-proof function to let the transmitting shaft rotate stably.

A maglev power generator has a frame, a transmitting shaft, two electricity generating sets, two axial vibration-proof sets, two maglev assemblies, and two radial vibration-proof sets. The transmitting shaft longitudinally extends within the frame. The two electricity generating sets, the two maglev assemblies, and the two radial vibration-proof sets are connected to the transmitting shaft. Each axial vibration-proof set contacts a respective end of the transmitting shaft. The transmitting shaft suspends within the frame and is able to rotate without contact with the frame. The axial vibration-proof sets, the maglev assemblies, and the radial vibration-proof sets provide the transmitting shaft with magnetic forces radially and axially to prevent the rotating transmitting shaft from deviation. Therefore, the transmitting shaft is able to rotate with minimum power loss. The axial vibration-proof sets and the radial vibration-proof sets effectively offer a good vibration-proof function to let the transmitting shaft rotate stably.

A user-worn device includes a band portion and a display portion. The band portion comprises a wire that is configured to create a first magnetic field that follows the curvature of the band portion. The display portion comprises a first electromagnet that is configured to produce a second magnetic field. The display portion orbits around the band portion in a first orbital direction when the first and second magnetic fields interact.

A user-worn device includes a band portion and a display portion. The band portion comprises a wire that is configured to create a first magnetic field that follows the curvature of the band portion. The display portion comprises a first electromagnet that is configured to produce a second magnetic field. The display portion orbits around the band portion in a first orbital direction when the first and second magnetic fields interact.