A generator including at least one machine device with a drive shaft; at least one flywheel connected to the drive shaft; at least one stator and rotor, wherein the drive shaft of the machine device is operable to synchronously rotate at least one rotor. The flywheel has one or more layers of arrays, or evenly spaced around magnetic field means, adapted for magnetic interaction with energizing coils of at least one support (360) so as to induce rotation of the flywheel in a single direction to rotate the rotor. The stator has an armature with a plurality of winding field coils evenly spaced apart around its circumference projected winding teeth. Each winding field coil is adapted to serve as a collecting energizing coil or an electromagnet coil. The rotor includes an array of the magnetic field generating means evenly spaced apart around its inner circumference surface.

A system can include an axial field rotary energy device with an axis of rotation and a rotor coaxial with the axis and having a shaft, bearings, rotor disks that are coaxial and permanent magnets on each rotor disk. A printed circuit board (PCB) stator is located between the rotor disks to define an air gap on each side of the PCB stator. An enclosure has two enclosure sections with an inspection port. Bearing caps and bearings are mounted to the rotor. A variable frequency drive (VFD) assembly is coupled to the axial field rotary energy device. The VFD has a flexible conduit that extends between the VFD housing and the axial field rotary energy device. The flexible conduit can adapt to different sizes of axial field rotary energy devices.

A stator arrangement includes a stator extending in a circumferential direction and plural teeth alternating with plural slots arranged along the circumferential direction. A first wire is arranged in a first slot of the plural slots. A second wire is arranged in a second slot of the plural slots, wherein the second slot is circumferentially adjacent to the first slot. A first converter has an input terminal connected to the first wire and a second converter has an input terminal connected to the second wire.

Apparatus and methods to magnetize and demagnetize the magnetic poles of a rotor assembly for an electrical machine, such as a generator. The apparatus and methods provide for individually magnetize magnetic domains in the permanent magnetic material of the magnetic poles of a rotor assembly of the electrical machine after the electrical machine is installed in a larger assembly. The magnetization system may be used to magnetize and demagnetize the magnetic poles while the rotor assembly is connected with a prime mover, such a rotor of a wind turbine.

Disclosed herein is a washing machine having an improved structure that maintains efficiency over a certain level both in washing and dehydration. The washing machine includes a body, a tub disposed within the body, a drum rotatably disposed within the tub, and a motor coupled to a rear surface of the tub to drive the drum. The motor includes a stator including a plurality of stator cores and a plurality of magnets arranged between the stator cores, and a rotor rotatably disposed at an inner side or outer side of the stator.

A method for manufacturing a rotary electric machine rotor includes forming core block elements; inserting magnets in corresponding one of the magnet holes; forming magnet core blocks by injecting a molten resin into each of the magnet holes from above the magnet, solidifying the molten resin, and thereby forming a resin portion so as to integrate each of the core block elements and the magnets. End surfaces of the magnets are exposed on a first end surface; and the molten resin is injected at a second end surface. The method also includes forming a rotor by stacking and integrating plural magnet core blocks, the plural magnet core blocks being stacked such that first end surfaces of two magnet core blocks that are disposed at both ends in an axial direction constitute end surfaces at both ends of the rotor in the axial direction.

A single rotor type motor includes: a stator including a plurality of stator cores that are divided in a plural number and radially arranged, a bobbin made of an insulating material and wrapped on an outer surface of each of the stator cores, and coils wound on an outer surface of the bobbin; and a single rotor disposed with a certain gap from any one surface of an inner surface of the stator and an outer surface thereof, wherein a wiring unit for electrically wiring coils wound on each stator core is integrally formed with the bobbin, and the wiring unit is arranged at an opposing end to an end facing the rotor of the stator core.

A rotational electric machine achieving both of productivity and insulation property is provided. A rotational electric machine includes an iron core having a plurality of slots, and a plurality of segment conductive bodies arranged in the slots, wherein the iron core includes a coil guide arranged at, at least, one of opening portions of the slots, and the coil guide includes a slot insertion portion located between the slot and the segment conductive body and at least one separation portion located between the segment conductive bodies, and the slot insertion portion and the separation portion are arranged in the slot together with the segment conductive body.

A modular magnetic induction horizontal-swing motor includes an electromagnet module, including a base, a stator arranged on the base, and a stator coil fixedly arranged around the stator; and a horizontal swing module, including a support frame, a first horizontal swing seat, a second horizontal swing seat, a first mover and a second mover, wherein the support frame is fixedly connected to the base, the first horizontal swing seat and the second horizontal swing seat are arranged in the support frame and are able to swing horizontally, linking limit members are arranged on the first horizontal swing seat and the second horizontal swing seat, and elastic pieces are arranged on two sides of the support frame respectively and provide an elastic return force when the first horizontal swing seat and the second horizontal swing seat swing horizontally in a staggered manner.

A planar drive system (10) includes at least two stator modules (12) and a frame (14). Each of the stator modules (12) has a base body (16) with a transport surface (18) and a rear side (20) opposite the transport surface (18), and further a mounting plate (22) which is detachably mounted on the rear side (20) of the base body (16). The frame (14) includes a plurality of receptacles (24) for receiving a stator module (12), with the stator modules (12) insertable into the receptacles (24) of the frame (14) with the transport surface (18) forward and are lockable in the receptacle (24) by a locking mechanism (26). Also described is a method for the installation and removal of stator modules (12) in a planar drive system (10).