An actuator that transforming electrical energy into mechanical energy (or vice-versa) that is particularly suited to portable applications requiring a high degree of efficient control, e.g. applications in which human-like movement needs to be simulated or interacted with. The actuator has a stator comprising electromagnetic sectors for generating phased electromagnetic fields around the stator and at least one cylindrical element (and preferably two such elements). The stator and the cylindrical element(s) are arranged concentrically around a central axis. The cylindrical element has permanent magnetic elements magnetized radially and arranged as one or more discontinuous helices. Phased magnetization of the stator causes the cylindrical element to rotate around the axis along a helical path, thereby exerting a longitudinal force along the axis. Preferably one cylindrical element rotates along a helical path relative to another cylindrical element that has permanent magnetic elements magnetized radially and arranged in one or more helices. Applications of the actuator include prosthetic limbs and orthoses, and for service and remotely operated robots.

A synchronous reluctance motor assisted by permanent magnets comprises a stator provided with stator windings, for generating a magnetic flux, which has a circular central seat to house a cylindrical shaped rotor suitable for being actuated in rotation about an axis of rotation, wherein the rotor comprises internal slots, for housing respective permanent magnets, and wherein the internal slots and the permanent magnets are curvilinear shaped in order to optimise the magnetic interaction between the rotor and the stator windings.

A permanent-magnet electric motor includes: a rotor; and a rotational-position detection sensor configured to detect a rotational position of the rotor. The rotor includes: a rotating shaft; an annular ferrite magnet disposed on an outer circumferential surface of the rotating shaft; and a rare-earth magnet disposed on an outer circumferential surface of the ferrite magnet, and a length from a center of the ferrite magnet in an axial direction of the ferrite magnet to an end face of the ferrite magnet on a side of the rotational-position detection sensor in the axial direction of the ferrite magnet is longer than a length from a center of the rare-earth magnet in an axial direction of the rare-earth magnet to an end face of the rare-earth magnet on a side of the rotational-position detection sensor in the axial direction of the rare-earth magnet.

A stepping motor includes a rotor magnet magnetized at N-poles and S-poles arranged alternately in a circumferential direction of a rotor and a stator yoke including salient poles disposed with intervals in the circumferential direction. Stator coils are respectively wound around the salient poles. A number of the poles of the rotor is a multiple of 6. A number of the salient poles of the stator yoke is a multiple of 8. The stator coils are composed of first-phase stator coils and second-phase stator coils. The salient poles are divided into a first group and a second group each of which includes half of the salient poles. The salient poles of the respective groups are alternately arranged in the circumferential direction. A winding direction of each of the stator coils is alternately changed for each of the salient poles in the circumferential direction for the respective groups.

This rotor assembly for a turbine engine includes: a solid permanent magnet (6) press-fitted inside a band (4) made of a non-magnetic material, a first shaft (2) having at least one bearing (12) intended for engaging with a support bearing so as to form a gas bearing and ensure rotational guidance of the first shaft (2), the band (4) forming an integral assembly with the first shaft (2) in the extension thereof, and a second shaft (8) having at least one bearing (14) intended for engaging with a support bearing so as to form a gas bearing and ensure rotational guidance of the second shaft (8) extending from the band (4) opposite the first shaft (2), coaxially with the first shaft (2) such that the first shaft (2), the band (4), and the second shaft (8) form an integral assembly.

Turbine engine with such rotor assembly.

The present invention relates to a shaft-embracing permanent magnet inter-shaft glued stator structure of a high-speed motor; the structure is a shaft-embracing permanent magnet integrated structure; the rotor structure comprises a permanent magnet (2), an output shaft (1) which is connected with one end of the permanent magnet (2) and embraces one part of the permanent magnet (2), and a rear shaft (4) which is respectively connected with the other end of the permanent magnet (2) and the output shaft (1), used for embracing the other part of the permanent magnet (2), and connected with the output shaft (1) to form a sealing mechanism of the permanent magnet (2). Compared with the prior art, the present invention has advantages of good electro-magnetic performance, high reliability, high productivity and good concentricity.

A step actuator includes a housing, a stator in the housing, a rotor including a magnet provided radially inward of the stator and a nut member inserted into the magnet and protruding through one side of the housing, a bearing rotatably supporting the nut member, a screw member coupled with the nut member to linearly move as the rotor rotates, and a mounting member supported on one side of the housing to support the screw member in such a manner that the screw member is linearly movable. The nut member includes an end portion passing through the bearing and a coupling portion extending from the end portion to couple with the bearing.

A turbo compressor is disclosed. The turbo compressor may have an assembly-type rotational shaft where a permanent magnet is inserted into a connecting sleeve, at least one first locking projection formed on either an inner periphery of the connecting sleeve or an outer periphery of the permanent magnet facing the inner periphery of the connecting sleeve, and at least one first locking groove formed on the other. Thus, the permanent magnet constituting a rotor may be easily coupled into the rotational shaft, and the permanent may be effectively prevented from slipping. Moreover, a magnet embedded in the rotational shaft may be securely fixed so that it is held in a position where it is assembled, thus providing an advantage in concentrically aligning the magnet.

A rotor of a motor capable of improving durability of the motor by increasing a bonding force between a ring magnet and a resin. The rotor includes a ring magnet having an insertion hole passing through the center thereof, a shaft inserted into the insertion hole, and a resin that is disposed between the insertion hole and the shaft and fixes the ring magnet and the shaft. The resin extends to upper and lower surfaces of the ring magnet so as to cover at least parts of the upper and lower surfaces of the ring magnet.

The present invention discloses a motor comprising: a stator part; and a rotor assembly rotatably disposed with respect to the stator part, wherein the rotor assembly comprises: a ring magnet including an insertion hole with a shaft disposed therein and a plurality of first grooves formed at one side thereof along a first imaginary circle; and a core member including a body portion disposed between the shaft and the insertion hole, and an extension portion covering the plurality of first grooves, wherein the extension portion comprises a plurality of second grooves deviated from a plurality of first imaginary straight lines which pass from a center of the first imaginary circle respectively through the plurality of first grooves.