A rotary electric machine control apparatus is provided which controls energization of a rotary electric machine having a plurality of winding sets. The apparatus includes an energization control circuit that is provided for each of the winding sets and has a switching element related to switching of energization to the winding set, a driver circuit that outputs a drive signal to the switching element through a signal line connected to the switching element, and a protection element that is connected to the signal line and in parallel with the switching element. When combinations of the winding sets and electronic components including the energization control circuit provided for each of the winding sets are regarded as systems, in at least one of the systems, performance of the protection element is differentiated from that in the other system to make noise resistance different from noise resistance in the other system.

A system and method for integrated charging a vehicle includes a hybrid excitation machine, operable as a traction motor and including a rotor separated by an air gap from a stator with AC windings. An AC utility line power supply is connected to the AC windings providing an electrical current to the vehicle and inducing a magnetic flux across the air gap and in the rotor. A short circuit, an open circuit, or a DC voltage may be applied to a DC winding in the stator to reduce the magnetic flux into the rotor. A field coil in the rotor may be excited with a DC voltage using a secondary coil on the rotor in a traction mode. The secondary coil is excited by the stator windings using field-oriented control in a “self-excited machine” embodiment, and is directly excited by a separate primary coil in an “externally-excited machine” embodiment.

A method for operating an inverter-based resource includes monitoring a current magnitude in the inverter-based resource. The method also includes monitoring a voltage magnitude in the inverter-based resource. Further, the method includes comparing the current magnitude in the inverter-based resource to a primary current threshold. Moreover, the method includes comparing the voltage magnitude in the inverter-based resource to a voltage threshold. As such, the method also includes disabling switching of the switching elements of the power converter when the current magnitude increases above the primary current threshold and the voltage magnitude decreases below the voltage threshold to bypass the switching elements of the power converter until excess energy in the inverter-based resource is dissipated.

A power conversion device including: a first and second multi-phase inverters (MPI1,MPI2) to receive a DC voltage (Vdc) and convert into AC voltages (Vacs), when fc represents a frequency of a PWM signal output from each of the MPI1 and the MPI2, fr represents a lower limit frequency defined by noise regulation of the power conversion device, an absolute value of a differential voltage being a difference between: a first average voltage, which is an average value of first voltage commands of respective phases as command values for the Vacs of MPI1; and a second average voltage, which is an average value of second voltage commands of respective phases as command values for the Vacs of MPI2, is set equal to or less than k2.Math.fc/fr.Math.Vdc [V] (k2 is an odd number equal to or more than one), to reduce noise in a frequency band defined by noise regulation.

A kinetic energy recovery system with flywheel includes a flywheel doubly-fed electric machine, an electric motor, a drive circuit and a controller. The flywheel doubly-fed electric machine has a primary side coil and a secondary side coil. The electric motor has a phase coil connected in series with the primary side coil. The drive circuit has an AC/DC circuit and a DC/AC circuit, wherein the AC end of the AC/DC circuit is coupled to the primary side coil; the AC end of the DC/AC circuit is coupled to the secondary side coil. The controller is configured to manipulate a frequency and a phase of output voltage and output current of the secondary side coil, thereby controlling the frequency and phase of a voltage and a current output from the primary side coil, thereby recovering a kinetic energy of the electric motor or providing the kinetic energy to the electric motor.

A kinetic energy recovery system with flywheel includes a flywheel doubly-fed electric machine, an electric motor, a drive circuit and a controller. The flywheel doubly-fed electric machine has a primary side coil and a secondary side coil. The electric motor has a phase coil connected in series with the primary side coil. The drive circuit has an AC/DC circuit and a DC/AC circuit, wherein the AC end of the AC/DC circuit is coupled to the primary side coil; the AC end of the DC/AC circuit is coupled to the secondary side coil. The controller is configured to manipulate a frequency and a phase of output voltage and output current of the secondary side coil, thereby controlling the frequency and phase of a voltage and a current output from the primary side coil, thereby recovering a kinetic energy of the electric motor or providing the kinetic energy to the electric motor.

A rotary electric machine control apparatus is provided which controls energization of a rotary electric machine having a plurality of winding sets. The apparatus includes an energization control circuit that is provided for each of the winding sets and has a switching element related to switching of energization to the winding set, a driver circuit that outputs a drive signal to the switching element through a signal line connected to the switching element, and a protection element that is connected to the signal line and in parallel with the switching element. When combinations of the winding sets and electronic components including the energization control circuit provided for each of the winding sets are regarded as systems, in at least one of the systems, performance of the protection element is differentiated from that in the other system to make noise resistance different from noise resistance in the other system.

Systems and methods of wind power generation in electrical power systems are described. According to one aspect, a wind turbine system can include a down tower portion having a main transformer configured to transform medium voltage power to another voltage power, a tower portion having one or more medium voltage cables configured to transmit medium voltage power, and, a nacelle portion. The nacelle portion can include a generator comprising a stator and a rotor. The stator may be connected to one or more medium voltage cables via a stator power path. The nacelle portion also includes a power converter coupled to the rotor of the generator, and, a step-up transformer coupled to the power converter and the one or more medium voltage cables. The step-up transformer can be configured to step-up low voltage power to medium voltage power.

In an embodiment of the present disclosure, a heating, ventilation, air conditioning, and refrigeration (HVAC&R) system includes a refrigerant loop and a compressor disposed along the refrigerant loop. The compressor is configured to circulate refrigerant through the refrigerant loop. The HVAC&R system also includes a motor configured to drive the compressor and a variable speed drive (VSD) configured to supply power to the motor. The VSD further includes a first power pod configured to supply a first power to the motor and a second power pod configured to supply a second power to the motor.

A power conversion device including: a first and second multi-phase inverters (MPI1,MPI2) to receive a DC voltage (Vdc) and convert into AC voltages (Vacs), when fc represents a frequency of a PWM signal output from each of the MPI1 and the MPI2, fr represents a lower limit frequency defined by noise regulation of the power conversion device, an absolute value of a differential voltage being a difference between: a first average voltage, which is an average value of first voltage commands of respective phases as command values for the Vacs of MPI1; and a second average voltage, which is an average value of second voltage commands of respective phases as command values for the Vacs of MPI2, is set equal to or less than k2.Math.fc/fr.Math.Vdc [V] (k2 is an odd number equal to or more than one), to reduce noise in a frequency band defined by noise regulation.