A power generation system includes a generator operatively coupled to an engine for generating electrical power and supplying the electrical power to a grid. Further, the power generation system includes a resistive braking system operatively coupled between the generator and the grid. The resistive braking system includes a mechanical switch connected in parallel with a resistor, and a controller for, in response to a grid event, controlling power from the engine and operating the mechanical switch to redirect current between the mechanical switch and the parallel connected resistor.

Methods for controlling a converter and corresponding apparatus and system are provided. The converter is configured to be connected to a rotor of a doubly-fed induction generator for feeding electrical power into an electrical grid, the converter having a machine-side inverter, a grid-side inverter, and a DC voltage intermediate circuit including a protection element for dissipating power from the DC voltage intermediate circuit. The method includes obtaining information representative of power supplied by the generator to the electrical grid exceeding a target power value beyond a predetermined threshold; and controlling the converter, in response to obtaining the information, such that the grid-side inverter supplies power to the protection element so as to dissipate power from the DC voltage intermediate circuit.

Methods for controlling a converter and corresponding apparatus and system are provided. The converter is configured to be connected to a rotor of a doubly-fed induction generator for feeding electrical power into an electrical grid, the converter having a machine-side inverter, a grid-side inverter, and a DC voltage intermediate circuit including a protection element for dissipating power from the DC voltage intermediate circuit. The method includes obtaining information representative of power supplied by the generator to the electrical grid exceeding a target power value beyond a predetermined threshold; and controlling the converter, in response to obtaining the information, such that the grid-side inverter supplies power to the protection element so as to dissipate power from the DC voltage intermediate circuit.

Systems and methods are provided for controlling breaker operation of power systems during a close before excitation (CBE) operation. One method includes closing the breaker of a generator prior to alternator voltage excitation, using power sourced from a permanent magnetic generator (PMG) that is coupled to the alternator.

A rectifier includes a rectification MOSFET that performs rectification, a comparator formed by connecting a drain of the rectification MOSFET to a non-inverting input terminal and a source to an inverting input terminal, and a control circuit that performs an on/off control of the rectification MOSFET using an output of the comparator. The control circuit includes a shut-off MOSFET that disconnects a drain of the rectification MOSFET and a non-inverting input terminal of the comparator from each other, and a shut-off circuit that turns off the shut-off MOSFET to electrically disconnect the drain of the rectification MOSFET and the non-inverting input terminal of the comparator from each other when the drain voltage of the rectification MOSFET is equal to or higher than a predetermined first voltage.

An example aircraft electrical system includes a generator coupled with a gas turbine engine and a controller operable to distribute power of the generator. The controller includes a first control module positioned at a first location remote from the generator and a second control module positioned at a second location proximate the generator. The first control module is configured to verify at least one output of the generator, detect a fault condition of the generator, and control operation of at least one power bus in communication with the first control module. The second control module is configured to regulate the at least one output of the generator, where the at least one output includes a voltage. An example method of operating an electrical system is also disclosed.

A variable-speed constant-frequency (VSCF) power converter includes a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency. The VSCF power generator also includes an inverter control operable to regulate a VSCF output voltage at a point-of-regulation at a constant frequency, where the generator control and the inverter control independently control a main line contactor of the point-of-regulation to provide redundant fault protection for an aircraft use.

A variable-speed constant-frequency (VSCF) power converter includes a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency. The VSCF power generator also includes an inverter control operable to regulate a VSCF output voltage at a point-of-regulation at a constant frequency, where the generator control and the inverter control independently control a main line contactor of the point-of-regulation to provide redundant fault protection for an aircraft use.

In one embodiment, a generator includes a rotor configured to rotate in cooperation with a stator to generate electrical power. A sensor, which is supported by the rotor, is configured to generate a trigger signal indicative of a position of the rotor. A communication interface is configured to receive the trigger signal from the sensor of the rotor and receive data indicative of an output of the generator. A controller supported by the rotor or configured to perform a phase analysis of the trigger signal and the output of the generator and calculate a power angle for the generator based on the phase analysis.

A control device for rotating electric machine, which controls a rotating electric machine as a charging electric generator, using an inverter circuit, the control device including: an energization amount generating unit for generating a first electric generation mode in which an energization amount for a field winding and an energization amount for an armature winding of the rotating electric machine are controlled and the inverter circuit is driven to perform electric generation, and a second electric generation mode in which an energization amount for the field winding is controlled to perform electric generation; and an energization signal generating unit for, on the basis of variation-related information relevant to variation in one of electric generation torque and electric generation current of the rotating electric machine, performing switching between the first electric generation mode and the second electric generation mode, and generating energization signals for the field winding and the armature winding.