Abstract: A power system includes a turbine assembly including a turbine and a turbine shaft, a generator assembly including a generator and a generator shaft, an inertia assembly including a flywheel coupled to the generator shaft, and a clutch assembly for coupling the turbine shaft to the generator shaft. The clutch assembly is transitionable between a closed state, in which the turbine shaft is coupled to the generator shaft, and an open state, in which the turbine shaft is decoupled from the generator shaft. The power system is operable in a power generation mode when the clutch assembly is in the closed state and a synchronous condenser mode when the clutch assembly is in the open state.

Abstract: A power system includes a turbine assembly including a turbine and a turbine shaft, a generator assembly including a generator and a generator shaft, an inertia assembly including a flywheel coupled to the generator shaft, and a clutch assembly for coupling the turbine shaft to the generator shaft. The clutch assembly is transitionable between a closed state, in which the turbine shaft is coupled to the generator shaft, and an open state, in which the turbine shaft is decoupled from the generator shaft. The power system is operable in a power generation mode when the clutch assembly is in the closed state and a synchronous condenser mode when the clutch assembly is in the open state.

Abstract: Provided is a power plant that is connected to a transmission grid. The power plant includes a synchronous generator and a synchronous condenser connected in parallel. The power plant is configured to increase the rotor angle stability of the synchronous generator to ride through fault conditions and frequency deviations on the transmission grid.

Abstract: A hybrid high inertia synchronous condenser facility for delivering reactive power to an electrical grid comprises at least one synchronous condenser, a voltage transformer connecting the at least one synchronous condenser to an electrical grid, at least one bank of capacitors switchably connected to the electrical grid, at least one bank of reactors switchably connected to the electrical grid, and a controller for controlling connection of the voltage transformer, the at least one bank of shunt capacitors, and the at least one bank of shunt reactors to the electrical grid. The synchronous condenser is equipped with a flywheel.

Abstract: Systems and methods of dynamic reactive power support for a power transmission system are provided. In one embodiment, a method of dynamic reactive power support for a power transmission system includes at least one circuit breaker connecting a shunt capacitor bank containing at least one shunt capacitor with a metal oxide varistor (MOV) connected in parallel. A controller is used to detect a voltage drop at the power transmission system (e.g., substation bus). In response to detecting the voltage drop, the controller closes the circuit breaker(s) connecting the shunt capacitors to the power transmission system. The controller then monitors at least one MOV to detect a current flow. Upon detection of a current flow in the MOV, the controller disconnects one or more shunt capacitors from the power transmission system by opening one or more circuit breakers. The shunt capacitors may be disconnected simultaneously, sequentially, in groups, or otherwise.

Abstract: Systems and methods of dynamic reactive power support for a power transmission system are provided. In one embodiment, a method of dynamic reactive power support for a power transmission system includes at least one circuit breaker connecting a shunt capacitor bank containing at least one shunt capacitor with a metal oxide varistor (MOV) connected in parallel. A controller is used to detect a voltage drop at the power transmission system (e.g., substation bus). In response to detecting the voltage drop, the controller closes the circuit breaker(s) connecting the shunt capacitors to the power transmission system. The controller then monitors at least one MOV to detect a current flow. Upon detection of a current flow in the MOV, the controller disconnects one or more shunt capacitors from the power transmission system by opening one or more circuit breakers. The shunt capacitors may be disconnected simultaneously, sequentially, in groups, or otherwise.