Provided is a magnetic levitation power system. The magnetic levitation power system includes: a magnetic power system disposed on a wheel hub and a driver shaft, where the magnetic power system generates a power capable of enabling a movement of the wheel hub through an interaction of magnetic fields between the wheel hub and the driver shaft; a first magnetic levitation system disposed on the wheel hub and the driver shaft, where the first magnetic levitation system is capable of enabling the wheel hub and the driver shaft to be in a levitation state within a circumferential extent of 360 degrees with the wheel hub being opposite to the driver shaft through the interaction of the magnetic fields between the wheel hub and the driver shaft; and a second magnetic levitation system disposed on the wheel hub and the driver shaft, where the second magnetic levitation system is capable of enabling the wheel hub and the driver shaft to be in a levitation state in a direction of a central axis of the wheel hub through the interaction of the magnetic fields between the wheel hub and the driver shaft. The present invention solves the problems of high hardware costs, low energy utilization rate, environmentally harmful characteristics, etc. of the existing automobile power system.

The invention provides in some aspects a transport system comprising a guideway with a plurality of propulsion coils disposed along a region in which one or more vehicles are to be propelled. One or more vehicles are disposed on the guideway, each including a magnetic flux source. The guideway has one or more running surfaces that support the vehicles and along which they roll or slide. Each vehicle can have a septum portion of narrowed cross-section that is coupled to one or more body portions of the vehicle. The guideway includes a diverge region that has a flipper and an extension of the running surface at a vertex of the diverge. The flipper initiates switching of vehicle direction at a diverge by exerting a laterally directed force thereon. The extension continues switching of vehicle direction at the diverge by contacting the septum. Still other aspects of the invention provide a transport system, e.g., as described above, that includes a merge region with a flipper and a broadened region of the running surface. The flipper applies a lateral force to the vehicle to alter an angle thereof as the vehicle enters the merge region, and the broadened region continues the merge by contacting the septum of the vehicle, thereby, providing further guidance or channeling for the merge. The flipper, which can be equipped for full or partial deployment, is partially deployed in order to effect alteration of the vehicle angle as the vehicle enters the merge.

The invention provides in some aspects a transport system comprising a guideway with a plurality of propulsion coils disposed along a region in which one or more vehicles are to be propelled. One or more vehicles are disposed on the guideway, each including a magnetic flux source. The guideway has one or more running surfaces that support the vehicles and along which they roll or slide. Each vehicle can have a septum portion of narrowed cross-section that is coupled to one or more body portions of the vehicle. The guideway includes a diverge region that has a flipper and an extension of the running surface at a vertex of the diverge. The flipper initiates switching of vehicle direction at a diverge by exerting a laterally directed force thereon. The extension continues switching of vehicle direction at the diverge by contacting the septum. Still other aspects of the invention provide a transport system, e.g., as described above, that includes a merge region with a flipper and a broadened region of the running surface. The flipper applies a lateral force to the vehicle to alter an angle thereof as the vehicle enters the merge region, and the broadened region continues the merge by contacting the septum of the vehicle, thereby, providing further guidance or channeling for the merge. The flipper, which can be equipped for full or partial deployment, is partially deployed in order to effect alteration of the vehicle angle as the vehicle enters the merge.

A vehicle includes a body configured to contain at least one passenger and/or cargo, and an engine, a drivetrain, and a plurality of wheels in mechanical communication with the body and configured to propel the body along road surfaces. The vehicle further includes at least one coupler or magnetic levitation interface in mechanical communication with the body. The at least one coupler or magnetic levitation interface is configured to controllably and repeatedly engage with and be propelled along a portion of a magnetic rail system or magnetic track and to controllably and repeatedly disengage from the portion of the magnetic rail system or magnetic track.

A vehicle includes a body configured to contain at least one passenger and/or cargo, and an engine, a drivetrain, and a plurality of wheels in mechanical communication with the body and configured to propel the body along road surfaces. The vehicle further includes at least one coupler or magnetic levitation interface in mechanical communication with the body. The at least one coupler or magnetic levitation interface is configured to controllably and repeatedly engage with and be propelled along a portion of a magnetic rail system or magnetic track and to controllably and repeatedly disengage from the portion of the magnetic rail system or magnetic track.

A transport system including at least one guideway, at least one levitation generator, at least one lifting member, at least one drive generator, and at least one drive member is presented. The at least one guideway, at least one levitation generator, at least one lifting member, at least one drive generator, and at least one drive member can each be implemented with other systems. The at least one drive generator is configured to: generate a driving magnetic flux; move with a corresponding at least one drive member; and be driven relative to the at least one drive member by the driving magnetic flux. The at least one levitation generator can be configured to: generate a levitating magnetic flux; move within a corresponding at least one lifting member; and elevate above a rest position relative to the at least one lifting member in response to the levitating magnetic flux.

A transport system including at least one guideway, at least one levitation generator, at least one lifting member, at least one drive generator, and at least one drive member is presented. The at least one guideway, at least one levitation generator, at least one lifting member, at least one drive generator, and at least one drive member can each be implemented with other systems. The at least one drive generator is configured to: generate a driving magnetic flux; move with a corresponding at least one drive member; and be driven relative to the at least one drive member by the driving magnetic flux. The at least one levitation generator can be configured to: generate a levitating magnetic flux; move within a corresponding at least one lifting member; and elevate above a rest position relative to the at least one lifting member in response to the levitating magnetic flux.

This invention powers road transportation vehicles with an electromagnetic roadway by means of magnetic propulsion. The vehicle contains an on-board magnet, and the roadway contains an array of electromagnets and an electrical power source. The vehicle is propelled in motion by the interaction between the vehicles on-board magnet and the activated electromagnets in the roadway. The electromagnets in the roadway are normally idle, and only activate when a vehicle signals that it is in range. Sequential electromagnetic activation can be viewed as electromagnetic pulses along the path of the vehicle in motion. The energy to activate the electromagnets can come from a rechargeable power source that can be charged via solar, making it very energy conscious.

This invention powers road transportation vehicles with an electromagnetic roadway by means of magnetic propulsion. The vehicle contains an on-board magnet, and the roadway contains an array of electromagnets and an electrical power source. The vehicle is propelled in motion by the interaction between the vehicles on-board magnet and the activated electromagnets in the roadway. The electromagnets in the roadway are normally idle, and only activate when a vehicle signals that it is in range. Sequential electromagnetic activation can be viewed as electromagnetic pulses along the path of the vehicle in motion. The energy to activate the electromagnets can come from a rechargeable power source that can be charged via solar, making it very energy conscious.

A wireless power transfer system for a vehicle traveling along a surface is provided. The wireless power transfer system includes a receiver coil mounted to the vehicle; a plurality of transmitter units connected in series and positioned on the surface; and a controller in communication with voltage sensors of each transmitter unit. The transmitter units include inactive and active transmitter units, and the inactive transmitter units include a leading transmitter unit and a trailing transmitter unit adjacent to the active transmitter units. The controller is configured to receive voltages of the leading and trailing transmitter units, compare the voltages with data in the database, and determine a position of the receiver relative to the transmitter units in order to activate and deactivate transmitter units as needed to dynamically modify the subset of active transmitter units to provide an efficient and smooth power supply to the receiver.