Disclosed are various embodiments for an improved generator/motor and a method of generating current, the method comprising providing a circular rotation path, generating a concentrated magnetic field around a portion of the circular rotation path; rotating a coil along the circular path and through the concentrated magnetic field; generating current within the coil as a result of the rotating, and extracting the current from the coil.

Disclosed are various embodiments for an improved generator/motor and a method of generating current, the method comprising providing a circular rotation path, generating a concentrated magnetic field around a portion of the circular rotation path; rotating a coil along the circular path and through the concentrated magnetic field; generating current within the coil as a result of the rotating, and extracting the current from the coil.

A rotor includes a magnet yoke and a number of permanent magnets. The magnet yoke defines a number of accommodating slots therein, and each of the permanent magnets is received in one of the accommodating slots. An elastic member protrudes from the magnet yoke towards each of the accommodating slots, the permanent magnets are inserted in the corresponding accommodating slots, and the elastic members are bent and abut against the permanent magnets. A motor and a power tool include the rotor are also disclosed.

A rotor includes a magnet yoke and a number of permanent magnets. The magnet yoke defines a number of accommodating slots therein, and each of the permanent magnets is received in one of the accommodating slots. An elastic member protrudes from the magnet yoke towards each of the accommodating slots, the permanent magnets are inserted in the corresponding accommodating slots, and the elastic members are bent and abut against the permanent magnets. A motor and a power tool include the rotor are also disclosed.

A permanent magnet motor and a home appliance including the permanent magnet motor are provided. The permanent magnet motor includes a stator and a rotor rotatable relative to the stator. The rotor includes a rotary shaft, a rotor core fixed to the rotary shaft, a commutator fixed to the rotary shaft and adjacent the rotor core, and a rotor winding wound around poles of the rotor core and electrically connected with the commutator. The stator includes a cylindrical housing, a permanent magnet mounted to an inner surface of the housing, and brushes in sliding contact with the commutator. A ratio of an outer diameter of the rotor core to an outer diameter of the housing is 60% to 85%, and a wire diameter of the rotor winding is 0.12 mm to 0.23 mm. The present invention can provide higher output power without increasing sizes of the motor.

A permanent magnet motor and a home appliance including the permanent magnet motor are provided. The permanent magnet motor includes a stator and a rotor rotatable relative to the stator. The rotor includes a rotary shaft, a rotor core fixed to the rotary shaft, a commutator fixed to the rotary shaft and adjacent the rotor core, and a rotor winding wound around poles of the rotor core and electrically connected with the commutator. The stator includes a cylindrical housing, a permanent magnet mounted to an inner surface of the housing, and brushes in sliding contact with the commutator. A ratio of an outer diameter of the rotor core to an outer diameter of the housing is 60% to 85%, and a wire diameter of the rotor winding is 0.12 mm to 0.23 mm. The present invention can provide higher output power without increasing sizes of the motor.

A DC motor includes a core, two bifurcated branching portions, an inner coil, and an outer coil. The core includes teeth. Each tooth includes a distal end and a basal end. The branching portions are located at the distal end. The inner coil is wound around the basal end. The outer coil is wound around each of the branching portions of the tooth and a branching portion of an adjacent one of the teeth. The inner coil and the outer coil each have a number of turns that is adjusted so that an inductance of the inner coil conforms to an inductance of the outer coil.

An improved hybrid magnetic engine/generator apparatus and method includes a shaft. A pair of oppositely positioned ferrous metal arms is connected to the shaft where the ferrous metal arms include a first end and a second end. Wire is wrapped in non-overlapping fashion around the ferrous metal arms and the wire includes a positive power connection and a negative power connection. A power source is connected with positive power connection and the negative power connection. A stacking magnet is located at the second end of the ferrous metal arms and an opposing magnet is located opposite from and in proximity to the first end of both of the oppositely positioned ferrous metal arms. A device for selectively connecting with the power source is provided such that the wire is intermittently charged such that polarity at the first end of the ferrous metal arms is intermittently changed.

The invention relates to a commutator motor (10), particularly as part of a windscreen-wiper motor (100), having at least four magnet elements (11 to 14) which are arranged on a reference-circle diameter around an axis of rotation of an armature shaft (2) with polarity that alternates in the circumferential direction, and having an armature (15) with armature slots (N1 to N18) and armature teeth (Z1 to Z18), wherein winding wires (20) having a multiplicity of windings (27, 28) in each case for constructing coils (C1 to C9) are arranged in the armature slots (N1 to N18), wherein a start (21) and an end (22) of a winding wire (20) is electrically conductively connected to a commutator hook (H1 to H18) in each case, wherein a winding wire (20) has two winding-wire sections (25, 26), which are arranged in the region of different magnet elements (11 to 14) in such a manner that a first winding-wire section (25) with a first number of windings (27) in a first winding direction is assigned to a first magnet element (11 to 14) and is located in two armature slots (N1 to N18), and that a second winding-wire section (26) with a second number of windings (28) in a second winding direction, opposite to the first winding direction, is assigned to a second magnet element (11 to 14) and is located in two armature slots (N1 to N18), and wherein the two magnet elements (11 to 14) have different polarities.

The invention relates to a commutator motor (10), particularly as part of a windscreen-wiper motor (100), having at least four magnet elements (11 to 14) which are arranged on a reference-circle diameter around an axis of rotation of an armature shaft (2) with polarity that alternates in the circumferential direction, and having an armature (15) with armature slots (N1 to N18) and armature teeth (Z1 to Z18), wherein winding wires (20) having a multiplicity of windings (27, 28) in each case for constructing coils (C1 to C9) are arranged in the armature slots (N1 to N18), wherein a start (21) and an end (22) of a winding wire (20) is electrically conductively connected to a commutator hook (H1 to H18) in each case, wherein a winding wire (20) has two winding-wire sections (25, 26), which are arranged in the region of different magnet elements (11 to 14) in such a manner that a first winding-wire section (25) with a first number of windings (27) in a first winding direction is assigned to a first magnet element (11 to 14) and is located in two armature slots (N1 to N18), and that a second winding-wire section (26) with a second number of windings (28) in a second winding direction, opposite to the first winding direction, is assigned to a second magnet element (11 to 14) and is located in two armature slots (N1 to N18), and wherein the two magnet elements (11 to 14) have different polarities.