A smart plug may provide a smart-plug power monitoring signal that includes information about power consumption of devices connected to the smart plug. The smart-plug power monitoring signal may be used in conjunction with power monitoring signals from the electrical mains of the building for providing information about the operation of devices in the building. For example, the power monitoring signals may be used to (i) determine the main of the house that provides power to the smart plug, (ii) identify devices receiving power from the smart plug, (iii) improve the accuracy of identifying device state changes, and (iv) train mathematical models for identifying devices and device state changes.

Included are: a performance information obtaining unit that obtains, for each of a plurality of first power customers that configure a first community, information about a power interchange performance between the first power customer and the first community; a contribution degree determination unit that determines a contribution degree of at least one of the plurality of first power customers to a surplus power amount of the first community in a certain time period, based on information about the performance obtained by the performance information obtaining unit.

Systems and methods for managing voltage event alarms in an electrical system are provided. In one aspect of this disclosure, a method for managing voltage event alarms in an electrical system includes processing electrical measurement data from, or derived from, energy-related signals captured by at least one intelligent electronic device (IED) to identify an anomalous voltage condition at a point of installation in the electrical system. The anomalous voltage condition may correspond, for example, to a measured IED voltage being above or greater than one or more upper alarm thresholds or below or less than one or more lower alarm thresholds. The method also includes determining if the electrical system is affected by the identified anomalous voltage condition. In response to determining that the electrical system is affected by the identified anomalous voltage condition, at least one of a plurality of criteria may be chosen to adjust at least one of the upper alarm thresholds and/or at least one of the lower alarm thresholds.

A power conversion device includes: a power converter connected to an electrical storage device that stores direct current power, the power converter being capable of converting the direct current power stored in the electrical storage device to alternating current power and outputting the alternating current power to a power system and to a customer load; and a control unit to control the power converter on a basis of a first active power command value and a first reactive power command value provided from an external controller, of a power consumption of the customer load, of a current root-mean-square value of a power flow current supplied to the power system, and a current upper limit that is set on a basis of a rated current of a molded case circuit breaker connected between the power converter and the power system.

An electrical device includes an electronic control unit including a radio communication interface provided with a planar internal radio antenna housed inside a first housing of the electrical device and including a first radiating element. The electrical device furthermore includes a movable coupling element connected to an external radio antenna, the coupling element being provided with a second radiating element and being able to be moved between a position connected to the housing of the electrical device and a position disconnected from the housing. In the connected position, the coupling element is positioned facing the internal radio antenna while being separated therefrom by an electrically insulating element, the second radiating element being coupled to the first radiating element so as to receive electromagnetic radiation emitted by the first radiating element.

Disclosed herein are systems and methods of calculating and mitigating time delays for electric power system samples received by remote data acquisition unit (RDAU), digitized, and transmitted to a receiving intelligent electronic device (IED). The IED may calculate time delays for various RDAUs, and establish wait windows for certain protection operations based on the samples needed for the protection operation and the calculated time delays for the various RDAUs. The IED may detect and report system or time signal anomalies based on changes to the calculated time delays from particular RDAUs.

In an embodiment, a power distribution automation applications network includes multiple intelligent nodes in communication with each other, each having a hardware and software platform, with data processing and communications functionality. The intelligent nodes are integrated or embedded with grid components. The nodes each implement a part or whole of a grid operating system that includes a set of software applications for automated and supervisory monitoring, control, protection, and optimization of an electric power system with embedded distributed energy resources and distributed information resources. The grid operating system both manages the grid and facilitates the integration of distributed energy resources and distributed information resources in an electric power system.

The disclosure provides a microgrid service entrance (MSE) and employing an MSE for controlling a microgrid. In one embodiment, the MSE includes: (1) an enclosure, (2) protective relays having bi-directional protection, (3) a communications module communicatively coupled to the protective relays, and (4) a power bus coupled to the protective relays and including a primary disconnect, wherein the protective relays, the communications module, and the power bus are located within the enclosure.

Mitigation of gratuitous conditions on an electric power delivery system is disclosed herein. Intelligent electronic devices (IEDs) may take actions on the electric power delivery system based on commands received via communications channels and based on detected electrical conditions. When a gratuitous condition (such as a cyber attack) is detected, a block command is provided to the IEDs such that the IEDs do not effect actions corresponding with commands received over a communications system. Communications may pass through a condition monitor of a communications device to detect insecurity and either block the communications or command the IED to enter interlock mode.

A method for managing voltage event alarms in an electrical system includes processing electrical measurement data from energy-related signals captured by at least one intelligent electronic device (IED) of a plurality of IEDs to identify an anomalous voltage condition at a point of installation of a respective one of the plurality of IEDs in the electrical system. In embodiments, the anomalous voltage condition corresponds to a measured IED voltage being above one or more upper alarm thresholds or below one or more lower alarm thresholds. The method also includes determining if the electrical system is affected by the identified anomalous voltage condition. In response to determining that the electrical system is not affected by the identified anomalous voltage condition, at least one of the one or more upper alarm thresholds or at least one of the one or more lower alarm thresholds may be adjusted to the measured IED voltage.