A two-phase stepper motor with a permanent magnet (PM) rotor and a modified hybrid-type stator is provided. The modified hybrid stator can be manufactured even at the smaller motor size because it employs shoeless, straight stator poles without stator teeth and with bobbin coils that are pre-wound outside the motor and easily inserted over each of the stator poles. Each bobbin may be an elongated continuous belt of insulative material with a hollow interior that forms a sleeve that fits around its corresponding stator pole. Conductive wire wound around the sleeve forms the stator coils. Edges of the sleeve may have exterior flanges at radially inner and outer ends of the stator pole to hold windings in place and keep the sleeve from bowing outward. This stator construction allows the motor to be miniaturized so that the PM rotors can be 13 mm diameter or less.

A two-phase stepper motor with a permanent magnet (PM) rotor and a modified hybrid-type stator is provided. The modified hybrid stator can be manufactured even at the smaller motor size because it employs shoeless, straight stator poles without stator teeth and with bobbin coils that are pre-wound outside the motor and easily inserted over each of the stator poles. Each bobbin may be an elongated continuous belt of insulative material with a hollow interior that forms a sleeve that fits around its corresponding stator pole. Conductive wire wound around the sleeve forms the stator coils. Edges of the sleeve may have exterior flanges at radially inner and outer ends of the stator pole to hold windings in place and keep the sleeve from bowing outward. This stator construction allows the motor to be miniaturized so that the PM rotors can be 13 mm diameter or less.

Provided is a rotary electric machine which is configured to draw three-phase output lines from a connection side coil end by an easy process. A stator for a rotary electric machine according to the present invention includes a plurality of segment coils including connection-side winding portions and non-connection-side winding portions. The connection-side winding portions are arranged on one side of a stator core and connected to slots with the same slot pitch, and the non-connection-side winding portions are arranged on the other side of the stator core and inserted into the slots with a plurality of kinds of slot pitches. The connection-side winding portions include a first connection group and a second connection group. The first connection group is provided with a plurality of terminal portions for connecting the segments, and the second connection group connects layers different from those in the first connection group, and is provided with a plurality of terminal portions.

A rotating electric machine includes a housing, a stator core housed in the housing, a plurality of systems of winding groups, a plurality of first lead wires, and a plurality of terminal boxes. The plurality of systems of winding groups are arranged in the stator core and electrically connected to a plurality of power conversion devices, one system of winding group is defined as a plurality of windings electrically connected to one power conversion device. The plurality of first lead wires are electrically connected to the plurality of systems of winding groups and wired inside the housing. The plurality of terminal boxes are arranged at a plurality of places in an outer circumference of the housing, the plurality of first lead wires are distributed in a unit of the system and introduced into the plurality of terminal boxes.

A rotating electric machine includes a housing, a stator core housed in the housing, a plurality of systems of winding groups, a plurality of first lead wires, and a plurality of terminal boxes. The plurality of systems of winding groups are arranged in the stator core and electrically connected to a plurality of power conversion devices, one system of winding group is defined as a plurality of windings electrically connected to one power conversion device. The plurality of first lead wires are electrically connected to the plurality of systems of winding groups and wired inside the housing. The plurality of terminal boxes are arranged at a plurality of places in an outer circumference of the housing, the plurality of first lead wires are distributed in a unit of the system and introduced into the plurality of terminal boxes.

An axial flux induction machine comprises at least two stators and one rotor where the stators include an inner and outer ring of coils. The stator is comprised of two mirrored structures constructed such as to secure wire coils, amplify magnetic characteristics, and provide a structure upon which to secure a rotary shaft. The structures supporting the outer ring of coils can be in contact between the two stators and the outer ring can be spaced further from the rotary shaft than the inner ring of coils and also further from the rotary shaft than an outer edge of the rotor.

An axial flux induction machine comprises at least two stators and one rotor where the stators include an inner and outer ring of coils. The stator is comprised of two mirrored structures constructed such as to secure wire coils, amplify magnetic characteristics, and provide a structure upon which to secure a rotary shaft. The structures supporting the outer ring of coils can be in contact between the two stators and the outer ring can be spaced further from the rotary shaft than the inner ring of coils and also further from the rotary shaft than an outer edge of the rotor.

A rotating electric machine includes a machine main body, a frame member and a rectifier. The machine main body is configured to generate alternating current. The frame member holds the machine main body. The rectifier is provided axially outside the frame member and has a rectification circuit configured to rectify the alternating current generated in the machine main body into direct current. The rectifier includes first and second heat sinks that are located to axially overlap each other, first rectifying elements mounted to the first heat sink and constituting an upper arm of the rectification circuit, and second rectifying elements mounted to the second heat sink and constituting a lower arm of the rectification circuit. The second heat sink is located closer than the first heat sink to the frame member. The surface area of the second heat sink is greater than the surface area of the first heat sink.

A rotating electric machine includes a machine main body, a frame member and a rectifier. The machine main body is configured to generate alternating current. The frame member holds the machine main body. The rectifier is provided axially outside the frame member and has a rectification circuit configured to rectify the alternating current generated in the machine main body into direct current. The rectifier includes first and second heat sinks that are located to axially overlap each other, first rectifying elements mounted to the first heat sink and constituting an upper arm of the rectification circuit, and second rectifying elements mounted to the second heat sink and constituting a lower arm of the rectification circuit. The second heat sink is located closer than the first heat sink to the frame member. The surface area of the second heat sink is greater than the surface area of the first heat sink.

The object of the present invention is to provide a device that allows the intermittent operation of the cooling fan, with a mechanism controlled by the stator temperature, to reduce whipping losses and improve the operating efficiency of three-phase induction motors for industrial use, such as those that operate pumps, compressors, conveyors, fans, welding machines and die cutters, among others.