A direct current motor includes a base and a top forming a channel; a field ring level positioned between the base and the top, the field ring level having primary field shaping magnets disposed therein at an angle; a core positioned within the channel; and a brush insert disposed within the channel; the field ring level creates a magnetic field that acts like a crashing wave, wherein the magnetic field is to spin a single magnet core.

A rotor for a rotating electric machine has interference and lightening holes. The rotor includes a shaft and a rotor iron core. The shaft is press fitted in the rotor iron core. The rotor iron core includes a shaft hole, an outer area, an inner area in which the shaft is press fitted, a plurality of ribs connecting the outer area and the inner area. Each of the ribs includes a plurality of outer rib joints adjacent to the outer area, a plurality of outer rib portions adjacent to the outer area, a plurality of inner rib joints adjacent to the inner area, and a plurality of inner rib portions adjacent to the inner area. The outer rib portions are connected to the inner rib portions and the total number of the inner rib joints is larger than that of the outer rib joints.

A rotation-detecting apparatus includes the following: a rotor coil provided on a rotor; detection coils provided on stators; a control circuit that detects the relative rotational angle between the rotor and the stators by processing detection signals induced in the detection coils as a result of the rotor coil being excited by an excitation signal; and a communicating means for performing data communication with an external device. The control circuit in the rotation-detecting apparatus has functionality whereby a switch signal that turns on and off at preset rotational angles is outputted on the basis of the aforementioned detection signals. Also, the control circuit is designed such that the set rotational angles for the aforementioned switch signal can be changed by the external device via the abovementioned communicating means.

A rotor includes a unitary, single material substrate defining a rotor lamination having pockets defining legs and configured to contain permanent magnets therein to establish a magnetic pole of the rotor. The rotor includes a first region having a predefined magnetic permeability. The rotor includes a second region defined between the legs and an outer periphery of the lamination. The second region has a magnetic permeability less than the first region to reduce torque ripple of a predetermined harmonic order.

An encoder includes an encoder circuit including first and second switches, a first resistor connected in series to the first switch, and a second resistor connected in series to the second switch, the encoder circuit defined by the first switch and the first resistor and the second switch and the second resistor being connected between a power supply voltage and a ground, and a control circuit connected between the first and second resistors and the power supply voltage to turn off power supply from the power supply voltage to the first resistor when the first switch is closed and to turn off power supply from the power supply voltage to the second resistor when the second switch is closed. The control circuit is connected to a first connection point between the first resistor and the first switch and to a second connection point between the second resistor and the second switch.

An electric machine may include a rotor defining a cavity containing a magnet, an outer periphery and a top bridge therebetween. The top bridge defines at least two segments. Each of the segments has a width that is minimum closest to a Q-axis, is maximum closest to a D-axis, and monotonically increases from the minimum to the maximum such that during operation a rate of change of rotor magnetomotive force associated with each segment differs.

A rotary generator comprising: at least one magnetic annulus pair comprising a first magnetic annulus and a second magnetic annulus with a gap therebetween; a coil annulus in the gap; the first and second magnetic annuli and the coil annulus having a common axis; the first and second magnetic annuli of the at least one magnetic annulus pair each having: a sequence of principle permanent magnets spaced around the common axis with alternating north and south poles facing the gap, corresponding principle permanent magnets of the first and second magnetic annuli of a magnetic annulus pair, with unlike poles facing the gap, facing each other across the gap such that lines of magnetic flux cross the gap between the corresponding principle permanent magnets, and a sequence of intermediate permanent magnets, each of the intermediate permanent magnets being positioned between two of the principle permanent magnets, each intermediate permanent magnet having adjacent the gap a north pole facing a side of the principle permanent magnet of the two principle permanent magnets having a north pole facing the gap and each intermediate permanent magnet having adjacent the gap a south pole facing a side of the principle permanent magnet of the two principle permanent magnets with a south pole facing the gap, the coil annulus having a sequence of coils arranged around the common axis such that the lines of magnetic flux cut the turns of the coils and thus induce electric currents in the coils as the magnetic annuli are caused to rotate relative to the coil annulus, wherein the first and second magnetic annuli of the at least one magnetic annulus pair each further comprise a backing plate of ferromagnetic material, the principle permanent magnets being positioned between the backing plate and the gap and mounted to the backing plate such that adjacent principle permanent magnets are magnetically coupled to one another through the backing plate.

Disclosed are a permanent magnet motor rotor (110) and a permanent magnet synchronous motor (100). The permanent magnet motor rotor (110) comprises: a rotor core (111); tangentially magnetized main-pole permanent magnets (112), the main-pole permanent magnets (112) being disposed in a radial direction of the rotor core (111), the main-pole permanent magnets (112) being uniformly arranged in a circumferential direction of the rotor core (111), and the closest surfaces of any two adjacent main-pole permanent magnets (112) having same magnetic poles; and an auxiliary permanent magnet (113) being disposed in the radial direction of the rotor core (111), the auxiliary permanent magnet (113) being located between any two adjacent main-pole permanent magnets (112), so as to raise the operating point of the main-pole permanent magnet, thereby achieving the purpose that the demagnetization resistance capacity of the main-pole permanent magnet is improved, and the demagnetization risk is reduced.

A switched reluctance motor includes a stator and a rotor disposed within the stator, wherein at least one of the stator and the rotor is formed from a plurality of laminate sheets, wherein each of the laminate sheets extends in an axial direction and the plurality of laminate sheets are disposed in a radial direction.

An encoder includes an encoder circuit including first and second switches, a first resistor connected in series to the first switch, and a second resistor connected in series to the second switch, the encoder circuit defined by the first switch and the first resistor and the second switch and the second resistor being connected between a power supply voltage and a ground, and a control circuit connected between the first and second resistors and the power supply voltage to turn off power supply from the power supply voltage to the first resistor when the first switch is closed and to turn off power supply from the power supply voltage to the second resistor when the second switch is closed. The control circuit is connected to a first connection point between the first resistor and the first switch and to a second connection point between the second resistor and the second switch.