A testing platform for evacuated tube high-temperature superconducting magnetic levitation (HTS maglev) under a high-speed operation state, including an evacuated tube, a supporting platform assembly, a model train and a gantry. The supporting platform assembly is arranged in the evacuated tube, and is provided with a permanent magnet track and a stator winding. A mover and a cryogenic dewar are arranged at a bottom of the model train, and multiple superconducting bulks are arranged in the cryogenic dewar. A side wall of the model train is made of a metal material. The gantry is arranged on the supporting platform assembly, and permanent magnets are arranged on upright posts of the gantry. A testing method using the testing platform is also provided.

A set of stators of a linear induction motor are mounted on a track. A three-phase current is provided to each of the stators, such that a traveling magnetic field (TMF) is created by the stators along the length of the track. The traveling magnetic field includes a magnetic flux corresponding to a stator excitation modulated with a message signal. A rotor includes a series of conductor plates. As the traveling magnetic field passes through the conductor plates, a current is induced in the plates by induction. Such current then generates an opposing magnetic field causing the plates and the vehicle to be propelled. Each phase may first be modulated with a message signal, before being provided to the stator. The current at the rotor is then demodulated to realize the message signal. A doppler shift due to the speed of the rotor relative to the stator is corrected.

An off-shore port system includes a land-based port infrastructure area, an off-shore cargo ship docking area located in a body of water, and a transportation system having at least one tube connecting the land-based port infrastructure area and the off-shore cargo ship docking area.

An off-shore port system includes a land-based port infrastructure area, an off-shore cargo ship docking area located in a body of water, and a transportation system having at least one tube connecting the land-based port infrastructure area and the off-shore cargo ship docking area.

A vehicle for travelling along a linear route guideway, comprising a body configured to accommodate cargo, equipment or passenger(s); traction engines on the body of the vehicle configured to orient the body within relative to the linear route guideway; and a controller for actuating at least one of the traction engines as a function of a desired orientation of the vehicle relative to the linear route guideway. A controller system for a vehicle for travelling along a linear route guideway is also disclosed.

A vehicle for travelling along a linear route guideway, comprising a body configured to accommodate cargo, equipment or passenger(s); traction engines on the body of the vehicle configured to orient the body within relative to the linear route guideway; and a controller for actuating at least one of the traction engines as a function of a desired orientation of the vehicle relative to the linear route guideway. A controller system for a vehicle for travelling along a linear route guideway is also disclosed.

A transport and power system having a plurality of tubes or tunnels, a magnetic levitation and linear motor train, and a superconducting power cable. One of the tubes can be an escape, power distribution, and maintenance tunnel. These tubes can be above ground, below ground, at ground, or under water.

A transport and power system having a plurality of tubes or tunnels, a magnetic levitation and linear motor train, and a superconducting power cable. One of the tubes can be an escape, power distribution, and maintenance tunnel. These tubes can be above ground, below ground, at ground, or under water.

Magnetic levitation can be used for transportation purposes. In various embodiments, the vehicle utilizing magnetic levitation can be enclosed within a tube or a tunnel or outside of an enclosed environment. Various cross-sections of vehicles and tubes can be utilized. In various embodiments, the vehicles can be used for personal or mass transportation use. The vehicle can travel in at least two directions with a window at each end of the vehicle.

Magnetic levitation can be used for transportation purposes. In various embodiments, the vehicle utilizing magnetic levitation can be enclosed within a tube or a tunnel or outside of an enclosed environment. Various cross-sections of vehicles and tubes can be utilized. In various embodiments, the vehicles can be used for personal or mass transportation use. The vehicle can travel in at least two directions with a window at each end of the vehicle.