A motor includes a bearing housing and a stator. The stator includes a stator core, an insulator, and a conductor. The insulator is an insulating body covering at least a part of the stator core. The conductor is wound around the stator core via the insulator. The bearing housing and the stator are connected to each other by a main adhesive and an auxiliary adhesive. A curing time of the auxiliary adhesive is shorter than that of the main adhesive. Therefore, the bearing housing and the stator can be temporarily fixed by the auxiliary adhesive of which the curing time is short until the main adhesive is cured. Therefore, it is possible to suppress that the position of the stator is deviated with respect to the bearing housing until the main adhesive is cured.

An insulation seat of a slim reel-type brushless motor includes a ring-shaped bottom plate, an inner plate and an outer plate. The ring-shaped bottom plate has an opening. The inner plate is arranged around the opening. At least one upper locking element is protruded upwardly from the inner plate. At least one lower locking element is protruded downwardly from the inner plate. The upper locking element and the lower locking element are staggered. The outer plate is arranged around an outer periphery of the ring-shaped bottom plate. An accommodation space is defined by the ring-shaped bottom plate, the inner plate and the outer plate. A coil is disposed within the accommodation space. The at least one upper locking element of the inner plate is engaged with a first magnetic seat. The at least one lower locking element of the inner plate is engaged with a second magnetic seat.

High efficiency and reduction of loss at high rotation speed can be attained with a simple configuration. The M/G includes a disc-shaped rotor 12 coupled to a main shaft 10 rotatably supported by a housing 20, 22. The rotor 12 has a permanent magnet array 14 providing a Halbach array magnetic field. Armature coils 16 are arranged in a disc-shape array to oppose to the permanent magnet array 14 and fixed to the housing 20, 22 as stators. A disc-shaped magnetic field member 24 is made of a magnetic material and arranged in a recessed part 22c formed in the housing 20, 22 at a side of the armature coils 16 opposite to the permanent magnet array 14.

A rotating electric machine according to the present disclosure is a rotating electric machine including a stator and a rotor, in which the rotor includes a plurality of permanent magnets arranged in a circumferential direction of a rotation axis and a plurality of protrusions arranged in the circumferential direction, the stator includes a plurality of teeth, an armature winding wound around the plurality of teeth, and a field winding wound around the plurality of teeth, a field pole is formed in the plurality of protrusions by energization to the field winding and the plurality of permanent magnets, the plurality of permanent magnets and the plurality of teeth are alternately arranged at intervals in the circumferential direction to form the field pole, all the permanent magnets have the same polarity, wherein, |P.sub.aP.sub.f|1, |P.sub.rP.sub.f|1, and |P.sub.aP.sub.r|1, and P.sub.r is even.

A method of constructing an electrical machine by assembling a first structure (one of a rotor and stator structure) and a second structure (the other of the rotor and stator structure), along with a plurality of first elements (one of a plurality of permanent magnet elements and a plurality of winding elements) and a plurality of second elements (the other plurality of the permanent magnet elements and winding elements). The first elements are attached to a rim of the first structure, and the second elements are attached to the first elements, this attachment being caused by a magnetic attraction. The first structure is assembled with the second structure such that the second elements are positioned for a posterior attachment to a rim of the second structure, and the second elements are attached to the rim of the second structure.

The described technology relates to a motor using a complex magnetic flux, which uses a radial magnetic flux and an axial magnetic flux together, thereby generating a larger torque in the same volume. The motor can also use a radial magnetic flux, an axial magnetic flux, and an oblique magnetic flux together, thereby generating a larger torque in the same volume.

A motor 1 according to one embodiment of the present disclosure includes a rotor 10 configured to freely rotate around a rotary shaft member 13; a stator 20, 320 including a stator unit 21 of a claw-pole type, the stator unit including a winding wire 212 that is annularly wound around the rotary shaft member 13 and a stator core 211 provided so as to surround the winding wire 212, the stator core 211 having a through hole piercing the stator core 211 around the rotary shaft member 13; and a first bearing holder 24B provided at one end side of the stator 20 in an axial direction of the rotary shaft member 13 and configured to hold a first bearing 25 rotatably supporting the rotary shaft member 13, wherein the first bearing 25 and the first bearing holder 24B are arranged on an outside in the axial direction with respect to the stator core 211, and an outer diameter of the first bearing 25 or the first bearing holder 24B is larger than an inner diameter of the through hole of the rotary shaft member 13.

A motor 1 according to an embodiment of the present disclosure includes a rotor 10 configured to freely rotate around a rotation axis AX; and a stator 20 arranged inside the rotor 10 and including a stator unit 21 of a claw-pole type, the stator unit including a winding wire 212 that is annularly wound around the rotation axis AX and a stator core 211 provided so as to surround the winding wire, wherein the stator 20 includes an inner space 24A around the rotation axis AX and in communication with an outer side of the rotor 10, such that heat can be radiated to the inner space 24A.

Various embodiments are described herein for switched reluctance machine configurations. In at least one embodiment, a switched reluctance machine configured according to the teachings herein comprises an axially extending shaft, an axially extending rotor mounted to the shaft, the rotor having a plurality of salient rotor poles, an axially extending stator disposed coaxially and concentrically with the rotor, the stator having a plurality of salient stator poles protruding radially from the stator towards the rotor poles, a plurality of stator teeth and tooth-tips, and a plurality of electrical coils wound about the stator poles to define a plurality of phases of the switched reluctance machine, where a number of stator poles can be determined according to the following equation and at least one constraint condition:

[00001]$N_s=\frac{N_t\mathrm{LCM}\left(N_s,N_r\right)}{N_r{N}_{p.Math..Math.h}S}.$

Provided is a motor for a drone comprising: a rotary shaft; a stator including a hole in which the rotary shaft is disposed; a rotor disposed outside the stator; and a housing coupled to the stator, wherein the stator comprises a stator core and a coil wound around the stator core, wherein the stator core comprises an annular yoke coupled to the housing, teeth extending radially from the yoke, and a shoe disposed at one end of the teeth, wherein the teeth comprise protrusions projecting from the side surface thereof. As such, the present invention provides an advantageous effect of securing an air flow path for heat radiation to enhance a heat radiating effect while preventing water or foreign matter from flowing into the motor.