A capacitive coupler provides high coupling capacitance through the use of an electrolyte and insulator formed as an oxide layer on at least one plate of the coupler. The coupler can be independent or provide a hydrodynamic or hydrostatic bearing as well as capacitive coupling, and the circulated dielectric can provide for cooling of associated machinery.

An embodiment relates to a motor comprising: a housing; a stator disposed in the housing; a rotor disposed in the stator; a shaft coupled to the rotor; a cover disposed on the housing; a core disposed at the cover; a plurality of brushes electrically connected to the core; and a plurality of coils wound on the core, wherein the core includes a first region, a second region connected to the first region and including a center, and a third region connected to the second region, the coil includes a first coil wound on the first region of the core and a second coil wound on the third region of the core, and the winding direction of the first coil is the same as the winding direction of the second coil with respect to the second region of the core. Therefore, the motor can inhibit or minimize the effects of externally generated electromagnetic waves by using two coils wound on a single core.

A cooling fan module includes a fan and a PMDC motor. The PMDC motor includes a stator and a rotor. The stator has 2P magnetic poles. The rotor includes a rotary shaft, a rotary core, a commutator, and a winding. The rotor core includes m×P pole teeth. The commutator includes k×m×P commutator segments. Adjacent pole teeth define therebetween winding slots for receiving the winding. The winding includes winding units each having P coils. Each of two ends of each winding unit includes a lead-out line connected to the commutator segment. Any two lead-out lines extending out of different winding slots are spaced from each other at locations outside the commutator segments.

A cooling fan module includes a fan and a PMDC motor. The PMDC motor includes a stator and a rotor. The stator has 2P magnetic poles. The rotor includes a rotary shaft, a rotary core, a commutator, and a winding. The rotor core includes m×P pole teeth. The commutator includes k×m×P commutator segments. Adjacent pole teeth define therebetween winding slots for receiving the winding. The winding includes winding units each having P coils. Each of two ends of each winding unit includes a lead-out line connected to the commutator segment. Any two lead-out lines extending out of different winding slots are spaced from each other at locations outside the commutator segments.

An electrical rotating machine, such as a generator or motor, communicates power from a stationary location to the rotating rotor of the rotating machine via opposed pairs of capacitor plates, one plate of each pair rotating with the rotor and one plate of each pair fixed not to rotate. Larger plate gaps suitable for mechanically rigid plates are possible through high-voltage and high-frequency AC signals managed by using a dielectric support design for the capacitor plates minimizing dielectric loss and/or impedance matching on the rotor.

An electrical rotating machine, such as a generator or motor, communicates power from a stationary location to the rotating rotor of the rotating machine via opposed pairs of capacitor plates, one plate of each pair rotating with the rotor and one plate of each pair fixed not to rotate. Larger plate gaps suitable for mechanically rigid plates are possible through high-voltage and high-frequency AC signals managed by using a dielectric support design for the capacitor plates minimizing dielectric loss and/or impedance matching on the rotor.

A rotor assembly for a DC motor is provided which includes a rotor having a rotor shaft, a commutator mounted to the rotor shaft, and a varistor which is connected to the commutator via an electrically-conductive solderless fixing means, such as an electrically-conductive adhesive.

A rotor assembly for a DC motor is provided which includes a rotor having a rotor shaft, a commutator mounted to the rotor shaft, and a varistor which is connected to the commutator via an electrically-conductive solderless fixing means, such as an electrically-conductive adhesive.

This disclosure describes a DC motor system that is capable of extracting electrical power to do useful work while the DC motor is in operation. The present invention relates to a DC motor configured to have a plurality of brushes which enables two of the plurality of brushes to serve as input power brushes and at least one of the plurality of brushes to serve as power extraction brush to extract electrical power from the DC motor. The extraction of electrical power is achieved by using a power extraction circuit which switches the extracted power between two different energy storage devices. The energy storage device includes and not limited to capacitors and batteries.

This disclosure describes a DC motor system that is capable of extracting electrical power to do useful work while the DC motor is in operation. The present invention relates to a DC motor configured to have a plurality of brushes which enables two of the plurality of brushes to serve as input power brushes and at least one of the plurality of brushes to serve as power extraction brush to extract electrical power from the DC motor. The extraction of electrical power is achieved by using a power extraction circuit which switches the extracted power between two different energy storage devices. The energy storage device includes and not limited to capacitors and batteries.