A method and system of managing power within a data center and providing power to the load including IT equipment includes determining a required power level for a data center, and determining a level of renewable energy available from one or more renewable energy sources. The method also includes determining a level of power available within a primary storage system for the data center. In addition, the method includes selectively utilizing renewable energy from the renewable energy sources to charge the primary storage system or power server racks, a cooling system, or a lighting system.

Present embodiments relate to a power controller for charging at least two battery banks. More specifically, the present embodiments relate to a power controller which provides for at least two input sources and may charge the at least two battery banks simultaneously or independently.

Present embodiments relate to a power controller for charging at least two battery banks. More specifically, the present embodiments relate to a power controller which provides for at least two input sources and may charge the at least two battery banks simultaneously or independently.

A nanogrid device for off-grid power includes a housing and a plurality of energy-receiving components coupled to the housing. The energy-receiving components are movable relative to the housing from a first, stored position to a second, fully deployed position. The energy-receiving components are configured to form an A-frame structure in the second, fully deployed position, and the housing is configured to be disposed underneath the A-frame structure in the second, fully deployed position.

A nanogrid device for off-grid power includes a housing and a plurality of energy-receiving components coupled to the housing. The energy-receiving components are movable relative to the housing from a first, stored position to a second, fully deployed position. The energy-receiving components are configured to form an A-frame structure in the second, fully deployed position, and the housing is configured to be disposed underneath the A-frame structure in the second, fully deployed position.

A renewable-energy electrical generation and distribution system including a first container and a second container. Each of the first container and the second container includes a power source disposed within the container and deployable therefrom, and generating energy from a renewable resource. A first compartment is disposed within the container, and retains a battery in communication with the power source. A power distribution system is disposed within the container and in communication with the battery and with the power source. A communications system is disposed within the container and configured to communicate data via an ad-hoc mobile communications network formed by the first container and the second container and configured to operate independent of any communication network not part of the first container and the second container forming the ad-hoc mobile communications network.

A renewable-energy electrical generation and distribution system including a first container and a second container. Each of the first container and the second container includes a power source disposed within the container and deployable therefrom, and generating energy from a renewable resource. A first compartment is disposed within the container, and retains a battery in communication with the power source. A power distribution system is disposed within the container and in communication with the battery and with the power source. A communications system is disposed within the container and configured to communicate data via an ad-hoc mobile communications network formed by the first container and the second container and configured to operate independent of any communication network not part of the first container and the second container forming the ad-hoc mobile communications network.

A thermophotovoltaic generator incorporating a two-stage combustor for providing heat to a thermophotovoltaic cell. Combustor parts include a partial oxidation reactor, which functions catalytically to convert a hydrocarbon fuel and a first supply of an oxidant into a gaseous partial oxidation product; and further include downstream thereof, a deep oxidation reactor including a premixer plenum fluidly connected to a heat spreader comprising a porous matrix, such as a ceramic foam. Functionally, the deep oxidation reactor converts the gaseous partial oxidation product and a second supply of oxidant into complete combustion products. Heat produced by the two-stage combustor generates radiative energy from a photon emitter, which is directly converted to electricity in a photovoltaic diode cell.

A thermophotovoltaic generator incorporating a two-stage combustor for providing heat to a thermophotovoltaic cell. Combustor parts include a partial oxidation reactor, which functions catalytically to convert a hydrocarbon fuel and a first supply of an oxidant into a gaseous partial oxidation product; and further include downstream thereof, a deep oxidation reactor including a premixer plenum fluidly connected to a heat spreader comprising a porous matrix, such as a ceramic foam. Functionally, the deep oxidation reactor converts the gaseous partial oxidation product and a second supply of oxidant into complete combustion products. Heat produced by the two-stage combustor generates radiative energy from a photon emitter, which is directly converted to electricity in a photovoltaic diode cell.

An apparatus for harvesting energy, such as solar, wind, wave, thermal, and the like, including a solar panel and a duct supporting the solar panel at an operational angle. The duct comprises a bottom shroud and side shrouds, therein forming a large aperture, a small aperture, and an oblique frustum shaped cavity. The oblique frustum shaped cavity is configured to direct a flow of fluid from the large aperture to the small aperture. A flow energy generator, such as a turbine, located at the small aperture is configured to collect flow energy. Temperature differences between the solar panel and the environment may be used to harvest thermal energy with a thermoelectric generator. Fluid flow under the solar panel may decrease the panel temperature and increase the efficiency. Generators may be operated in reverse to lower the solar panel temperature and increase efficiency.