A method and device for producing a radially anisotropic multipolar solid magnet adapted to different waveform widths are provided. A mold core is removed from a mold for molding the magnet, and outer oriented poles, the number of which is the same as that of poles of the radially anisotropic multipolar solid cylindrical magnet, are arranged outside the mold. The width of a front end of a single outer oriented pole is determined according to the desired width of a single waveform of the radially anisotropic multipolar solid cylindrical magnet after being magnetized. The sum L of widths or arc lengths of front ends of all the outer oriented poles is less than 0.9πD, particularly less than 0.7πD, where D is the outer diameter of a mold sleeve. Magnetic particles in a mold cavity are rotated with the mold only during magnetization.

A rotary-linear actuation assembly is provided, in particular of a kind suitable to provide in independent manner at its output, either sequentially or simultaneously, a rotary movement and a linear translation movement. The assembly comprises a casing internally housing an output shaft arranged coaxial with an actuation axis (A) in a translationally and rotationally movable manner; and at least two electromagnetic actuators each comprising a respective electromagnetic stator and a respective magnetic rotor, a first of which being a linear actuator adapted to impart, at its output, a translational movement along the actuation axis (A), and a second of which being a rotary actuator adapted to impart, at its output, a rotary movement around the actuation axis (A). The electromagnetic stators of the electromagnetic actuators are arranged in a mutually coaxial and concentric manner, and each actuator independently acts on the output shaft.

An axial split-phase bearingless flywheel motor includes a stator, a stator sleeve, a rotor, a rotor sleeve, and a flywheel. The stator and the rotor are axially divided into phases A, B and C. An axially magnetized permanent magnet is provided between every adjacent phases. Twelve rotor poles are provided at equal intervals on an inner side of the rotor core in each of the phases A, B, and C. The rotor poles in the phases A, B and C are staggered in sequence along a circumference by ⅓ of a rotor pole pitch. Eight torque poles in a shape of narrow teeth and four suspension poles in a shape of wide teeth are provided on the stator core in both the phases A and C, and twelve torque poles of a uniform width are provided on the stator core in the phase B.

A rotor magnet installation structure includes: a first shaft including a shrinkage-fit portion in which an accommodation space is formed; at least one magnet inserted in the accommodation space, an installation outer diameter of the magnet being greater than an inner diameter of the accommodation space before the magnet is inserted in the accommodation space; and a second shaft comprising a connection portion inserted in the accommodation space, an outer diameter of the connection portion being greater than the inner diameter of the accommodation space before the connection portion is inserted in the accommodation space.

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 rotor assembly includes a shaft disposed along a central axis extending vertically, a tubular magnet disposed on a radially outer surface of the shaft, a lower spacer disposed axially below the magnet and fixed to the radially outer surface of the shaft, a shaft adhesive film attaching the shaft to the magnet, and a lower spacer adhesive film attaching an axially upper surface of the lower spacer to an axially lower surface of the magnet. The shaft adhesive film and the lower spacer adhesive film are an identical adhesive and are continuously formed.

A rotary-linear actuation assembly is provided, in particular of a kind suitable to provide in independent manner at its output, either sequentially or simultaneously, a rotary movement and a linear translation movement. The assembly comprises a casing internally housing an output shaft arranged coaxial with an actuation axis (A) in a translationally and rotationally movable manner; and at least two electromagnetic actuators each comprising a respective electromagnetic stator and a respective magnetic rotor, a first of which being a linear actuator adapted to impart, at its output, a translational movement along the actuation axis (A), and a second of which being a rotary actuator adapted to impart, at its output, a rotary movement around the actuation axis (A). The electromagnetic stators of the electromagnetic actuators are arranged in a mutually coaxial and concentric manner, and each actuator independently acts on the output shaft.

Provided are a rotor shaft assembly, a rotor, and a motor. The rotor shaft assembly includes a magnetic core, a first end shaft, a second end shaft, and a protective sleeve. The protective sleeve is provided, in sequence, with a first through hole, a second through hole, and a third through hole; the first end shaft is disposed through the first through hole, at least part of the magnetic core is arranged inside the second through hole, and the second end shaft is disposed through the third through hole.

Provided is a rotor that is long in the axial direction of the rotary shaft without increasing the ratio L/D between the length L and the inner diameter D of the permanent magnet. The permanent magnet of the rotor includes a plurality of sub-magnets that are divided in the axial direction A of the rotary shaft. The armor ring includes a plurality of sub-rings that are divided in the axial direction A. The connector is disposed on the inner periphery of a connecting part between the two sub-rings and that are adjacent in the axial direction A and is disposed between the two sub-magnets that are adjacent in the axial direction A. The sub-magnets each have a recess that is depressed in the axial direction A. The connector has protrusions that fit to the recesses of the magnet.

The present disclosure provides a radially oriented solid cylindrical magnet, a method and device for molding and manufacturing the same, and a rotor and motor component using the same. The radial orientation degree of the solid cylindrical magnet is greater than or equal to 90%. A mold includes no mold core. Magnetic particles in the mold are continuously rotated in a magnetic field during molding, and an oriented magnetic field is applied during molding. The manufactured solid cylindrical magnet can be directly used as a rotor of a micro-motor to replace a conventional rotor with a radially oriented magnet ring, or can be used for producing radially oriented magnet rings with an arbitrary inner diameter, so as to obtain radially oriented magnet rings having an inner diameter less than 3 mm or even less for micro-motors.