A method for controlling a stand-alone modular microgrid unit, including: detecting connection between the microgrid unit and a first power source having a first capacity and a second power source having a second capacity larger than the first capacity; detecting a power demand of a load connected to the microgrid unit; in response to a total power demand from loads electrically connected to the microgrid unit falling below the first capacity, controlling the first power source to operate in a power supply mode and supplying power to the load; in response to the total power demand exceeding the first capacity, disconnecting the load from the microgrid unit, controlling the second power source to operate in a power supply mode, and in response to the second power source producing a threshold amount of power, electrically connecting the load to the microgrid unit and supplying power to the load.

An electrical power generating system for providing auxiliary or backup power to a load bus. The system may be used indoors, and generally includes a fuel cell unit comprising a first DC output, an electrical storage unit comprising a DC input coupled to the first DC output of the fuel cell, the electrical storage unit further comprising a second DC output. An inverter coupled to the second DC output receives power, the inverter comprising a first AC output. The system includes a contactor connected between the first AC output and an AC load bus. The AC load bus comprises an AC voltage, and a controller comprising inputs is adapted to sense a phase, a frequency, and a magnitude of the first AC output and the AC voltage and close the contactor when they substantially match.

A customer's solar array is connected to a utility-owned battery and inverter system. The battery and inverter system may convert DC power from the solar array or a battery bank to provide AC power to the grid. The inverter system may also convert AC power from the grid to DC power to charge the battery bank, or the battery bank may be charged by DC power from the solar array. The utility's inverter system is connected to the customer's premise on the utility's side of the meter. A transfer switch provides either grid power to the premise or AC power from the inverter via the battery bank. A solar production meter on the utility side measures power flowing from the solar array to the grid, as well as power flowing between the battery bank and the grid.

Systems and apparatuses include an automatic transfer switch including a source pole coupled with a power source, a first load pole coupled with a first load, a second load pole coupled with a second load, a first switch selectively coupling the first load pole to the source pole, and a second switch selectively coupling the second load pole to the source pole.

Methods and systems for control of a power-quality measuring or monitoring device, such as a transfer switch, are provided. An example method includes a transfer-switch controller of a transfer switch receiving an input command from a user. The method further includes, in response to receiving the input command, the transfer-switch controller entering a safe state, wherein in the safe state operational settings of the transfer switch remain unchanged. Still further, the method includes, after entering the safe state, the transfer-switch controller providing, based on operational data specific to the transfer switch, information regarding a feature of the transfer switch.

Methods and systems are described for power state management. A critical usage window may be configured at a gateway node. A change in a power state of the gateway node may be detected, at an interface, during the critical usage window. The power state of the gateway node may be adjusted via the interface for a set duration using a backup power node.

At least one aspect of the invention is directed to a power monitoring system including a generator coupled to a fuel tank, a plurality of monitors, and a processor configured to monitor one or more loads drawing power from the generator; monitor one or more parameters that affect the amount of power drawn by the one or more loads; monitor a fuel consumption rate of the generator; generate one or more load profiles for each of the one or more loads; receive a set of the one or more loads for which a predicted time is to be generated; receive values for the one or more parameters; generate a predicted load profile for the set of the one or more loads and the values of the one or more parameters; receive information indicating an amount of remaining fuel; and calculate a predicted available run time.

A micro grid system comprises a secondary energy source and a power controller. The secondary energy source is associated with a micro grid that includes a fixed or mobile facility, and the secondary energy source is configured to generate first DC power signal. The power controller is in communication with the secondary energy source and an electric grid, and configured to receive first AC power signal from the electric grid and the first DC power signal from the secondary energy source and output a second AC power signal to loads in communication with the power controller. The power controller comprises an AC to DC frequency converter configured to change frequency and/or voltage of the second AC power signal, a processor, and a memory configured to store instructions that, when executed, cause the processor to control the frequency converter to change the frequency and/or voltage of the second AC power signal.

Provided is a technique for efficiently securing power when a predetermined natural phenomenon occurs. In order to solve such a problem, there is provided a power management apparatus (1) including an event information acquisition unit (10) that acquires event information indicating the occurrence of a predetermined event relating to a natural disaster and the detail of the event, a grouping unit (20) that divides a plurality of storage batteries as managing targets into a first group and a second group on the basis of the event information acquired by the event information acquisition unit (10), and a storage battery control unit (30) that controls an charging operation of the storage battery for each group.

A power transmission system includes a plurality of electrical substations and a plurality of transmission lines arranged to connect the plurality of electrical substations to form a power transmission network; and a controller system arranged to control a power transmission within the power transmission network. The controller system includes: a detection module arranged to detect an occurrence of a fault in at least one faulty electrical substation of the plurality of electrical substations; and a restoration module arranged to at least temporally maintain an output power of the at least one faulty electrical substation; and wherein at least one of the plurality of electrical substations is operable to facilitate maintaining of the output of the at least one faulty electrical substation upon the detection of the occurrence of the fault.