A system for storing input power and providing output power, such as for use with electric vehicle charging, can include an alternating current motor, a flywheel, an alternating current generator, or any combination thereof. The motor can be electrically coupled to an alternating current power source and can receive AC power from the power source. The flywheel can be coupled to a rotor external to the motor. The generator can be coupled to the flywheel and electrically coupled to a controller for supplying power to a load, such as an electric vehicle for charging one or more batteries of the vehicle.

A power system includes a base, two magnetic bearings mounted on the base, a shaft rotatably mounted on the two magnetic bearings, a flywheel mounted on the shaft, a motor connected with the flywheel, an uninterrupted power supply electrically connected with the motor, a utility power electrically connected with the uninterrupted power supply, a coupling connected with the shaft, a speed change device connected with the coupling, a generating device connected with the speed change device, a load electrically connected with the generating device, a recharge rectifier electrically connected with the uninterrupted power supply, and a reactor electrically connected with the recharge rectifier and the generating device. Thus, the enlarged torque of the flywheel provides the inertia power to enhance the generating power of the generating device.

An electro-mechanical kinetic energy storage device includes an input port, an output port, and a tertiary port separate from and magnetically coupled to the input port and the output port. The input port is configured to receive a first input electrical energy from a first electrical source for inducing mechanical energy into the electro-mechanical kinetic energy storage device. The output port is configured output a first converted electrical energy to a first load in which the outputted electrical energy is generated from the induced mechanical energy. The tertiary port is configured to receive a second input electrical energy from a second electrical source for inducing the mechanical energy, and output a second converted electrical energy to a second load, the second converted electrical energy generated from the induced mechanical energy.

A microgrid power system includes a power module configured to generate direct current (DC) power, an inverter module having a DC side and an AC side, and configured to invert DC power received from the power module on the DC side and output alternating current (AC) power on the AC side, a DC bus electrically connecting an output of the power module to an input on the DC side of the inverter module, an AC load bus configured to electrically connect an output on the AC of the inverter module to an AC load, an energy storage device electrically connected to the DC bus, and a kinetic storage device (KSD) device electrically connected to the AC load bus on the AC side of the inverter module.

An apparatus for supporting a flywheel on a floating vessel includes a support for the flywheel; and a tilt sensor for measuring an angle of slope relative to the Earth, the tilt sensor being arranged to detect a change of an angle of slope of the floating vessel relative to the Earth. The apparatus further includes a driver for manoeuvring the support relative to the floating vessel, based on the measured angle of slope from the tilt sensor, wherein the driver is operable to manoeuvre the support so as to counteract a change of an angle of slope of the flywheel relative to the Earth due to the detected change of an angle of slope of the floating vessel.

A controller for controlling an energy discharge from an energy saving device to a power grid. The system includes decision logic to implement a local response responsive to events currently occurring in a power grid and in addition remote commands sent from a remote location.

A mass displacement electricity generator, having a tower and a first mass suspended by the tower for falling and lifting. The first mass is suspended by a pulley arrangement including a first set of pulleys fixed to the tower above the first mass and a second set of pulleys fixed to the first mass. A cable extends through the first and second sets of pulleys and one end of the cable is fixed to one of the tower or to the first mass. A winch includes a barrel about which the cable winds off as the first mass falls and winds on as the first mass lifts. The winch is in driving connection with a flywheel so that as the first mass falls, the cable winds off the barrel and barrel rotation drives the flywheel to rotate. The flywheel is in driving connection with a generator so that rotation of the flywheel drives the generator for generating electrical energy.

A controller for controlling an energy discharge from an energy saving device to a power grid. The system includes decision logic to implement a local response responsive to events currently occurring in a power grid and in addition remote commands sent from a remote location.

An energy storage system operable in a charging phase and in a discharging phase is disclosed. The energy storage system includes M energy storage units and N power converters, where M is at least two and N is at least one. The energy storage system also includes a switching fabric that reconfigurably couples the energy storage units to the power converters and a controller that reconfigures the switching fabric.

A system includes multiple hybrid energy storage modules (HESMs) configured to accept constant-current DC input power from a main power source. Each HESM has a plurality of outputs configured to sequentially or simultaneously provide both constant-current and constant-voltage output power to multiple loads, the loads comprising steady state, pulsating, or intermittent loads. Each HESM comprises a combined rotating electrical machine-inertial storage module and electro-chemical storage module configured to generate second power that augments or induces first power derived from the main power source, so as to permit constant power draw or constant current draw from the main power source, wherein the output power comprises the first power and the second power.