A logistic monorail transportation system. The logistic monorail transportation system comprises a logistic track beam system, a logistic vehicle system, a logistic turnout system, a logistic handling system, and a logistic signal system. The logistic track beam system is set up on the road, in the field, or in the streets in the form of single-column pier studs or frame-type pier shads. The technical solution of the present application solves the problems of short distance, high costs, and low speed of existing transportation systems, and the purpose of long-distance, low-cost, and high-speed logistic monorail transportation is achieved.

Magnetic levitation railway system for integration in a wheel railway track, comprising a magnetic levitation railway track including a linear motor and magnetic levitation rails arranged on outer sides of the wheel railway track, said magnetic levitation rail comprising a conductive guide rail having at least a horizontal portion configured for a magnetic levitation railway vehicle having a levitation device with magnets. The guide rail is configured for passive levitation of the magnetic levitation railway vehicle due to the electromotive force generated by the moving magnets of the magnetic levitation railway vehicle.

Magnetic levitation railway system for integration in a wheel railway track, comprising a magnetic levitation railway track including a linear motor and magnetic levitation rails arranged on outer sides of the wheel railway track, said magnetic levitation rail comprising a conductive guide rail having at least a horizontal portion configured for a magnetic levitation railway vehicle having a levitation device with magnets. The guide rail is configured for passive levitation of the magnetic levitation railway vehicle due to the electromotive force generated by the moving magnets of the magnetic levitation railway vehicle.

A high-speed transportation system, the system including at least one transportation path having at least one track, at least one transportation vehicle configured for travel along the at least one transportation path, a propulsion system adapted to propel the at least one transportation vehicle along the at least one transportation path; and a levitation system adapted to levitate the transportation vehicle along the at least one transportation path. The at least one transportation vehicle additionally comprises wheels for at least intermittently supporting the transportation vehicle on the at least one track.

A segmented track for a Maglev vehicle includes a structural support portion and a Maglev portion fastened to the structural support portion. Each segment of the structural support portion is formed by fusing together three cast metal components. Neighboring ones of the structural support segments are joined together end-to-end by fused metal, and neighboring ones of the reaction rail segments are joined together end-to-end by fused metal. The positioning and joining of the successive segments is done in the field using on site jigs and machines.

A segmented track for a Maglev vehicle includes a structural support portion and a Maglev portion fastened to the structural support portion. Each segment of the structural support portion is formed by fusing together three cast metal components. Neighboring ones of the structural support segments are joined together end-to-end by fused metal, and neighboring ones of the reaction rail segments are joined together end-to-end by fused metal. The positioning and joining of the successive segments is done in the field using on site jigs and machines.

A magnetic levitation train system with an asymmetrical power distribution is provided, having a train which is moved through a track that is at least partly located within an airless tube, the track having at least two stations, having each section of the track between two correlative stations the following zones: an acceleration zone located at the beginning of the section, having a plurality of consecutive winding segments electrically connected to each other and to a current supply, a deceleration zone, comprising a plurality of consecutive winding segments electrically connected to each other and to a current supply, and a cruise zone in which the train is moved on a cruise speed, located between the acceleration zone and the deceleration zone, having a plurality of winding segments electrically connected to a current supply, and comprising a plurality of empty spaces between some of the winding segments.

The present disclosure provides an electromagnetic levitation train-track system. Tracks are arranged on two sides of a roadbed or track beams, and a magnetic levitation train runs on the tracks. The system includes a traction guide electromagnet horizontally arranged on supporting arms on two sides of the magnetic levitation train, a linear motor stator horizontally arranged at a relative position on the track, the linear motor stator and the traction guide electromagnet horizontally arranged in the magnetic pole directions, a core linear motor formed by the linear motor stator and the traction guide electromagnet at a certain magnetic gap, and an E-shaped cross section levitation electromagnet and a gap sensor arranged at the bottom of the magnetic levitation train and levitated below an armature plate horizontally arranged at the bottom of the track.

The present disclosure provides an electromagnetic levitation train-track system. Tracks are arranged on two sides of a roadbed or track beams, and a magnetic levitation train runs on the tracks. The system includes a traction guide electromagnet horizontally arranged on supporting arms on two sides of the magnetic levitation train, a linear motor stator horizontally arranged at a relative position on the track, the linear motor stator and the traction guide electromagnet horizontally arranged in the magnetic pole directions, a core linear motor formed by the linear motor stator and the traction guide electromagnet at a certain magnetic gap, and an E-shaped cross section levitation electromagnet and a gap sensor arranged at the bottom of the magnetic levitation train and levitated below an armature plate horizontally arranged at the bottom of the track.

Transport apparatus having at least one levitation generator and at least one drive generator. The at least one levitation generator 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. The at least one drive generator configured to generate a driving magnetic flux, move within a corresponding at least one drive member, and laterally move relative to the at least one drive member in response to the driving magnetic flux. At least a portion of the at least one levitation generator is movable relative to the at least one drive generator.