A method operates an electric energy storage that is provided for an electric consumption unit, wherein the electric consumption unit is additionally coupled to an electric power grid. The method is characterized in that the control device performs the following steps of a) providing different operation logics for controlling the power flow as a function of the state of charge and of a total unit load, b) observing a status signal that is signaling the present and/or the next supply condition of the grid, c) selecting one of the operation logics as an active operation logic depending on a current value of the status signal, and d) operating the power converter according to the active operation logic.

A control device (101) for controlling a power converter (109) is configured to form a frequency droop value based on electric power supplied by the power converter to an alternating current system, decrease a frequency control value by the frequency droop value, form a power control value based on a target value of the electric power, increase the frequency control value by the power control value, and supply the frequency control value to the power converter to control alternating voltage frequency of the power converter. The electric power is driven to a value at which a combined effect of the frequency droop value and the power control value makes the alternating voltage frequency of the power converter to be the same as operating frequency of the alternating current system. Thus, the electric power can be controlled by changing the power control value.

A power conversion system includes: a storage battery; a first power conversion device configured to implement grid-connection operation with an electric power grid, converting electric power of the storage battery, outputting converted power to a connection point between load equipment and the electric power grid to supply electric power to the load equipment; and a controller transmitting a load adjusting signal to a load control part in the load equipment for reducing electric power supply to the load equipment if a state of the storage battery matches a remaining power shortage condition which is set in advance, during stand-alone operation in which the electric power grid is disconnected from the first power conversion device.

A device for detecting a secondary battery of an uninterruptible power system contains: a main battery module and at least one sub battery module. The main battery module includes a first power storage unit, a first detection unit, a first processing unit, a communication unit, and a first data transmission unit. The first power storage unit includes multiple first battery assemblies connected in series, and a respective first battery assembly has at least one secondary battery. The first detection unit includes multiple first detectors. The first data transmission unit includes a first one-way transmit port and a first two-way transmit port. The sub battery module includes a second power storage unit, a second detection unit, a second processing unit, and a second data transmission unit. The second power storage unit includes multiple second battery assemblies connected in series. The second detection unit includes multiple second detectors.

A system and method for data collection and aggregation using a distributed network of communications enabled sensors connected to another primary network to achieve a secondary out-of-band monitoring perspective, for example, in power grids. The data collection system includes an aggregation and processing server configured to collect data from a variety of sensors adjacent to the monitored network each sensor includes secondary power such that it can continue data transmission even during power grid outages. The data collection system includes a method for secure real-time data ingest, machine learning enabled analysis, risk assessment, and anomaly detection on a broad geographic scale irrespective of isolated network boundaries.

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 system to manage power consumption from a grid includes a building switchgear; an energy storage system (ESS) coupled to the building switchgear to selectively provide power in response to a customer power demand to prevent a customer grid power consumption from spiking and peaking at grid imbalance highest cost on peak times; an energy management system (EMS) to operate the ESS from behind-the-meter; and a data distribution service (DDS) coupled to the EMS forming a DDS-EMS network to provide a global data space servicing EMS edge publishers and subscribers.

A temporary power distribution device for receiving and distributing electrical power from an external power supply on a temporary basis. The temporary power distribution devices can include a plurality of electrical outlets and/or electrical communication outlets and may include additional safety features for the loss of power and/or the notification of an emergency condition. The temporary power distribution device may be portable and is meant to be portable even during use.

In one aspect, a method to determine a capacity of a microgrid includes applying a current test load to the microgrid and measuring a current through an energy storage device, the current indicating a charging status of the energy storage device based on a current load being applied to the microgrid through activated power outlets being served by the microgrid and the current test load, the energy storage device being integrated with the microgrid. The method also includes, responsive to a determination that the measured current based on the current load being applied to the microgrid and the current test load indicates that the energy storage device is discharging, determining the capacity of the microgrid, wherein the capacity is the current load being applied to the microgrid through activated power outlets and a test load applied to the microgrid immediately preceding the current test load.

A distributed energy management system includes a photovoltaic (PV) source, and a plurality of controllable loads in communication with the PV source. The plurality of controllable loads include a first controllable load including a first interactive plug associated with a first connected state timer and a first disconnected state timer, and a second controllable load including a second interactive plug associated with a second connected state timer and a second disconnected state timer. The PV source is configured to determine a maximum PV power, determine a difference between the maximum PV power and a current PV power, responsive to determining that the difference is less than or equal to a threshold power, set the reference AC voltage as a first voltage, and responsive to determining that the difference is greater than the threshold power, set the reference AC voltage as a second voltage greater than the first voltage.