Technologies for performing non-intrusive fine-grained power monitoring of a datacenter are provided. Hardware component state information for servers in the datacenter is collected, along with aggregate power consumption measurements for the datacenter. The servers are grouped into multiple virtual homogenous server clusters (VHCs) based on characteristics of the servers. A power model is constructed comprising multiple power mapping functions associated with the multiple VHCs. Component state information of a particular server can then be analyzed, along with a corresponding aggregate power consumption measurement, using the constructed power model to determine an approximate power consumption of the particular server. The approximate power consumption of the server can then be displayed and/or provided to one or more power management applications.

A power management method includes step A of performing communication of a predetermined command using a predetermined protocol between a power conversion apparatus and a power management apparatus. The power conversion apparatus is connected to first and second distributed power sources. The method further includes step B of converting, by the power conversion apparatus, DC power from the first and second distributed power sources into AC power. The step A includes a step of performing, in a manner capable of identifying a connection rated output of the power conversion apparatus in a grid connection state and a self-sustained rated output of the power conversion apparatus in a self-sustained operation state, communication of a command including an information element designating at least one of the connection rated output of the power conversion apparatus and the self-sustained rated output of the power conversion apparatus, as the communication of the predetermined command.

In a direct load control system supporting frequency control of an electrical grid, at each electrical load of an aggregation of loads, a load status report is generated comprising an urgency value and a power level. At an aggregation dispatch controller, a dispatch signal is generated based on the generated load status reports and information indicative of electrical frequency. At each electrical load of the aggregation, the load is operated at the reported power level if the reported urgency value satisfies the dispatch signal and is not operated at the reported power level if the reported urgency value does not satisfy the dispatch signal.

Systems and methods are disclosed for managing power supplied over an electric power grid from at least one power supply source. A coordinator manages communications between at least one server and the at least one power supply source, wherein the server is operable to initiate power commands, wherein the communications comprise an actual amount of power supply available for the electric power grid from the at least one power supply source, and wherein the at least one power supply source is operable to provide power supply to the electric power grid based on the power commands.

An apparatus and method for aggregating and supplying energy includes a plurality of power modules for inverting a first type of electrical power, which is supplied to the power modules from multiple sources of power, to a second type of electrical power at an output of the power modules for delivery of the inverted power to a storage device for future use, or to an electrical load, or to a regional or central utility grid. A microcontroller (the power microcontroller) is carried by and incorporated within each of the power modules and each is configured for controlling the power inversion operations. A microcontroller (the control microcontroller) carried by the control module is configured for monitoring voltage levels within the at least one energy storage device and for rebalancing voltage within the energy storage device and for correcting lead and lag power factor. Means for selectively supplying power received from said multiple disparate sources of power to the destination are provided.

Techniques for monitoring statuses of electrical connections are described. In an example, an identifier of a circuit breaker is received. A determination may be made that the circuit breaker is in an on state based on the identifier of the circuit breaker being received. Further, an identifier of a load connected to the circuit breaker over a power cable is received. The identifier of the load is transmitted over the power cable. A determination may be made that the load is connected to the circuit breaker based on the identifier of the load being received. The identifier of the circuit breaker, the identifier of the load, and electrical connection statuses of the circuit breaker and the load may be provided over an interface.

In a power converter including: a first DC-DC converter, an inverter, and a control circuit, a second DC-DC converter that controls an input and an output of a power storage unit is connectable to a DC bus. The control circuit deactivates a reverse power flow suppression function for suppressing a reverse power flow from the inverter to a power system when the second DC-DC converter is not connected to the DC bus and activates the reverse power flow suppression function when the second DC-DC converter is connected to the DC bus.

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.

Computer systems and methods regarding distributed energy resource systems (DERs) re described. Configurations and employed methods may include sending a command to a DER system to place the DER system in one or more of a charge state, a discharge state, an idle state, or a reactive power state. these DER systems may include a rechargeable battery, a dc/ac converter configured to receive a DC voltage from the battery and convert the received DC voltage for receipt by an external AC circuit, and one or more controllers configured to designate operation state of the battery in at least a charge state, a discharge state, and an idle state.

An offshore oil and gas platform has a power supply system with a cascaded arrangement for a black start. The power supply system includes a first power supply apparatus for providing power at a first energy level, an uninterruptible power supply arrangement configured to receive power from the first power supply apparatus, wherein the uninterruptible power supply is for powering at least one essential and/or safety critical component, and a second power supply apparatus for providing power at a second energy level to a main power distribution system, wherein the second energy level is higher than the first energy level, wherein the second power supply apparatus includes a power source and a high-power energy storage system capable of supplying power at the second energy level, and wherein the second power supply apparatus can receive and store energy from the first power supply apparatus.