The present subject matter is directed to an electrical power circuit connected to a power grid and method of operating same. The electrical power circuit has a power converter electrically coupled to a generator, such as a doubly-fed induction generator, having a rotor and a stator. Thus, the method includes operating rotor connections of the rotor of the generator in a wye configuration during a first rotor speed operating range. Further, the method includes monitoring a rotor speed of the rotor of the generator. Thus, the method also includes transitioning the rotor connections of the rotor from the wye configuration to a delta configuration if the rotor speed changes to a second rotor speed operating range.

An actuator including a motor with a configurable topology and a switching array operably coupled to the motor. The switching array is adapted to configure the topology of the motor. The switching array may include a first set of switches for configuring the topology of the motor to a Y-configuration or a -configuration and a second set of switches for configuring the topology of the motor to eliminate one or more stator poles of the motor. The switching array may further include a third set of switches for configuring the topology of the motor to activate a number of windings on each of a plurality of stator poles of the motor.

A switching module includes a housing that can be attached directly to an end of a stator and over line and neutral phase hairpins of the stator, electrically conductive platforms disposed in the housing and that can contact some of the hairpins, switches disposed in the housing, connected with the platforms, and that can selectively change connections of the hairpins between wye and delta configurations, and a conduit defining a coolant channel through the housing.

In a rotary electric machine, when armature coil bodies of respective phases in which first and second armature windings, are both wound around 6 kn teeth are set as Ua, Va, and Wa, armature coil bodies of respective phases in which only the first and armature winding is wound around 6 mn teeth are set as Ub, Vb, and Wb, and armature coil bodies of respective phases in which only the second armature winding is wound around 6 mn teeth are set as Uc, Vc, and Wc, Ua, Va, Wa, Ub, Vb, Wb, Uc, Vc, and Wc are respectively arranged so as to exhibit 2 n-fold rotational symmetry about an axial center of a rotor.

A rotating electric machine includes a rotor and a stator. The stator includes a stator core and a stator coil. The stator coil includes three first windings, three second windings and three switch units. The first windings are -connected to define three nodes therebetween. The second windings are arranged so as to be respectively connectable between the nodes and three phase terminals of the stator coil. The switch units respectively switch the connections between the nodes and the phase terminals between a direct connection state and an indirect connection state. In the direct connection state, the nodes are respectively directly connected with the phase terminals. In the indirect connection state, the nodes are respectively connected with the phase terminals via the second windings. The first and second windings are mounted on the stator core so that the first windings are located closer than the second windings to the rotor.

In a rotary electric machine, when armature coil bodies of respective phases in which first and second armature windings, are both wound around 6kn teeth are set as Ua, Va, and Wa, armature coil bodies of respective phases in which only the first and armature winding is wound around 6mn teeth are set as Ub, Vb, and Wb, and armature coil bodies of respective phases in which only the second armature winding is wound around 6mn teeth are set as Uc, Vc, and Wc, Ua, Va, Wa, Ub, Vb, Wb, Uc, Vc, and Wc are respectively arranged so as to exhibit 2n-fold rotational symmetry about an axial center of a rotor.

An electric motor, comprising a plurality of coils each activatable by selectively providing direct current thereto and at least one capacitor, wherein the electric motor is configured to recover energy stored in at least one of the coils into the at least one capacitor when the direct current is switched off.

Control systems and methods for starting an induction motor. The control system includes a plurality of wye switches, a plurality of delta switches, an AC power supply, and a soft-starter. The plurality of wye switches are connected between three phase stator windings of the induction motor such that closure of the plurality of wye switches causes the three phase stator windings to be connected in a wye connection. The plurality of delta switches are connected between the three phase stator windings such that closure of the plurality of delta switches causes the three phase stator windings to be connected in a delta configuration. The soft-starter is connected between three phase supply lines of the AC power supply and the three phase stator windings to control a supply of energy to the induction motor from the AC power supply.

A device comprising a housing with a stator and an internally positioned rotor mounted on a shaft attached to the housing. The rotor, equipped with multiple magnets, interacts with coil sets wound around the stator. These coil sets connect to a controller that manages the rotor's speed and torque. The device includes switches between the controller and coil sets, enabling activation or deactivation of additional wires within the coil sets to modify the motor's Kv value. The switches, which may be mechanical relays, electronic, or physical, are structured in three stages to allow precise performance control. This configuration supports versatile and efficient operation across various applications.

A motor-driving apparatus for driving a motor having a plurality of windings respectively corresponding to a plurality of phases is provided. The motor-driving apparatus includes a first inverter having a plurality of first switching devices and connected to first ends of the plurality of windings and a second inverter having a plurality of second switching devices and connected to second ends of the plurality of windings. A third switching device is configured to selectively connect and disconnect points at which a number of turns of each of the windings is divided in a preset ratio. A controller is configured to adjust an on/off state of the first to third switching devices based on required output of the motor.