A transport system includes: a mover on which a workpiece is mounted and which is movable in a first direction; a stator that has a plurality of coils arranged in the first direction and applies force to the mover by using the plurality of coils, the force transporting the mover in the first direction while floating the mover in a second direction crossing the first direction; a control unit that acquires a position and an attitude of the mover moving in the first direction while floating in the second direction and controls the current applied to the plurality of coils to control operation of the mover based on the acquired position and attitude; and a positioning part that limits the movement of the mover, wherein the positioning part includes a first positioning part that limits the movement of the mover in a direction of external force applied to the workpiece.

A transport system includes: a mover on which a workpiece is mounted and which is movable in a first direction; a stator that has a plurality of coils arranged in the first direction and applies force to the mover by using the plurality of coils, the force transporting the mover in the first direction while floating the mover in a second direction crossing the first direction; a control unit that acquires a position and an attitude of the mover moving in the first direction while floating in the second direction and controls the current applied to the plurality of coils to control operation of the mover based on the acquired position and attitude; and a positioning part that limits the movement of the mover, wherein the positioning part includes a first positioning part that limits the movement of the mover in a direction of external force applied to the workpiece.

A rotor for a long-stator linear motor system comprises at least three rollers for mounting the rotor on one or more guide rails of the long-stator linear motor system, the at least three rollers comprising a first roller that engages with an upper part of a first guide rail of the one or more guide rails, a second roller that engages with a lower part of the first guide rail, and a third roller that a) is rotatably mounted to at least one rotatable bolster of the rotor or b) comprises a steering rotational axis with an integrated castor.

A motion imparting leg for imparting an oscillating or reciprocating rectilinear motion to a rocking bed, comprising a base, an upper surface movable relative to the base for imparting the oscillating or reciprocating motion to the rocking bed, a servo motor for driving movement of the upper surface, a position sensor for determining the rotational position of the servo motor or the position of the upper surface, and a motor controller for controlling the servo motor based on data from the position sensing means.

A motion imparting leg for imparting an oscillating or reciprocating rectilinear motion to a rocking bed, comprising a base, an upper surface movable relative to the base for imparting the oscillating or reciprocating motion to the rocking bed, a servo motor for driving movement of the upper surface, a position sensor for determining the rotational position of the servo motor or the position of the upper surface, and a motor controller for controlling the servo motor based on data from the position sensing means.

An inductive power transfer system is used for transferring electrical power across a gap, such as an air gap or a liquid gap, such as to unmanned autonomous vehicles (UAVs). The power transfer system is a polyphase system that creates a travelling magnetic field in the air or liquid gap, implementing a resonant electro-magnetic (EM) field to allow larger gap separations and less precise alignments. The power transfer system may have a polyphase dynamoelectric machine attached to primary mechanical-inertial storage device with multiple stator and rotor ports connected to a polyphase traveling-wave inductive power transmitter apparatus. The system may be of use in transferring power to underwater vehicles in a subsea salt water environment. Such a power transfer system may part of a larger system for underwater power transfer, for instance at depths of at least 10 km, and/or at distances of 1 to 50 km.

An inductive power transfer system is used for transferring electrical power across a gap, such as an air gap or a liquid gap, such as to unmanned autonomous vehicles (UAVs). The power transfer system is a polyphase system that creates a travelling magnetic field in the air or liquid gap, implementing a resonant electro-magnetic (EM) field to allow larger gap separations and less precise alignments. The power transfer system may have a polyphase dynamoelectric machine attached to primary mechanical-inertial storage device with multiple stator and rotor ports connected to a polyphase traveling-wave inductive power transmitter apparatus. The system may be of use in transferring power to underwater vehicles in a subsea salt water environment. Such a power transfer system may part of a larger system for underwater power transfer, for instance at depths of at least 10 km, and/or at distances of 1 to 50 km.

A channel segment for a track of a mover device is provided, the channel segment comprising: opposite ends joined by a body forming a magnetic flux pathway between the opposite ends, the magnetic flux pathway being one or more of C-shaped, U-shaped and horseshoe shaped between the opposite ends, the opposite ends forming respective transverse magnetic flux pathways about perpendicular to the magnetic flux pathway; laminations of ferromagnetic material forming the body, the laminations about parallel to the magnetic flux pathway and about perpendicular to the respective transverse magnetic flux pathways; shear pins through the laminations, the shear pins positioned to reduce eddy currents one or more of in and around the shear pins; and a retention mechanism at the opposite ends, the retention mechanism configured to transversely fasten the laminations together at the opposite ends while remaining insulated from each other.

A linear electrical machine comprising a frame with a level reference plane and an array of electromagnets, connected to the frame to form a drive plane at a predetermined height relative to the reference plane. The array of electromagnets being arranged so that a series of electromagnets of the array of electromagnets define at least one drive line within the drive plane, and each of the electromagnets being coupled to an alternating current power source energizing each electromagnet. At least one reaction platen of paramagnetic, diamagnetic, or non-magnetic conductive material disposed to cooperate with the electromagnets of the array of electromagnets so that excitation of the electromagnets with alternating current generates levitation and propulsion forces against the reaction platen that controllably levitate and propel the reaction platen along at least one drive line, in a controlled attitude relative to the drive plane.

A linear electrical machine comprising a frame with a level reference plane and an array of electromagnets, connected to the frame to form a drive plane at a predetermined height relative to the reference plane. The array of electromagnets being arranged so that a series of electromagnets of the array of electromagnets define at least one drive line within the drive plane, and each of the electromagnets being coupled to an alternating current power source energizing each electromagnet. At least one reaction platen of paramagnetic, diamagnetic, or non-magnetic conductive material disposed to cooperate with the electromagnets of the array of electromagnets so that excitation of the electromagnets with alternating current generates levitation and propulsion forces against the reaction platen that controllably levitate and propel the reaction platen along at least one drive line, in a controlled attitude relative to the drive plane.