In one embodiment, a method includes transmitting from power sourcing equipment, low voltage pulse power to a powered device in a communications network, performing a safety test, enabling high voltage pulse power operation at the power sourcing equipment upon passing the safety test, and transmitting high voltage pulse power from the power sourcing equipment to the powered device. The powered device synchronizes with a waveform of the low voltage pulse power.

A power flow schedule of a cluster is determined by calculating sensitivity of the net power exchange bounds. Each cluster includes a different section of the power system. The cluster provides to another cluster the power flow schedule and the net power exchange bounds for determination of a second power flow schedule by another cluster based on collective net power exchange bounds, a forecast power supply of the plurality of clusters, and a forecast power demand schedule. The clusters are hierarchically arranged such that the another cluster is higher in a hierarchy than the cluster. The cluster receives from the another cluster the second power flow schedule. The first power flow schedule is adjusted locally within the cluster based on the second power schedule and the net power exchange bounds of the cluster. The power output of the cluster is controlled using the adjusted first power flow schedule.

A system and method to join distributed energy resources (DER) to achieve common objectives is provided. The present technology organizes and/or aggregates DERs by routing a (DER) program request for resources to DER contributors capable of responding to and performing the request using a routing system. The system accesses a plurality of DER profiles, each profile associated with a DER contributor capable of contributing a resource to the request, and calculates an initial value for each DER profile based on request attributes and scoring metrics associated with the profile. The system then calculates a fitness metric for each DER profile based on the initial value using a neural network having weights based on the plurality of performance indicators and selects the DER profile and contributors to whom to route the request.

Methods for damping oscillations in a high voltage power grid, including power distribution and supply systems by distributing a plurality of voltage/impedance injection modules to inject voltages/impedances onto high voltage power transmission lines of the power grid, sensing power oscillations on the high voltage transmission lines, extracting the dominant oscillatory mode or modes of sensed power oscillations on the high voltage transmission lines, and injecting voltages/impedances responsive to at least the most dominant oscillatory mode onto the respective high voltage transmission lines to counteract the respective oscillations.

There is described a connecting board for a power supply unit, comprising at least one power converter, at least one filtering unit connected to an input of the at least one power converter, a controller connected to the at least one power converter and the at least one filtering unit, and at least one output pin connected to the output of the at least one power converter. The filtering unit comprises interconnected components each having a resistive or a capacitive value, the resistive or capacitive value controlling at least one operating parameter of the power converter. The controller is configured to adjust the resistive or capacitive value for causing a given one of a plurality of voltages to be produced at an output of the power converter. The output pin is configured to receive the given voltage and to deliver the given voltage to a load.

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.

A power management server comprises a controller configured to select, from a plurality of facilities having storage battery apparatuses, two or more first facilities applying first processing configured to suppress a discharge amount of the storage battery apparatuses. The controller is configured to apply, to the two or more first facilities, a same condition as a suppression condition of the discharge amount of the storage battery apparatuses.

A fuel cell system comprises an interface configured to receive a user operation toward the fuel cell system, and a controller configured to perform a predetermined process related to a reception stop of the user operation at least during a period from a start to an end of a stop operation of the fuel cell system.

A power supply apparatus is connectable to a common communication line together with at least one other apparatus. The power supply apparatus includes a communication interface and a controller. The communication interface is configured to transmit a signal indicating the presence of the power supply apparatus to a first apparatus connected to the power supply apparatus among the at least one other apparatus and to receive a signal indicating the presence of a second apparatus from the second apparatus connected to the power supply apparatus among the at least one other apparatus. The controller is configured to determine whether the power supply apparatus is connected to an end portion of the common communication line, based on whether the communication interface has received the signal indicating the presence of the second apparatus.

A method and system for bidirectional data, power transmission, electrical/electronic fault isolation, and system recovery is shown and described. An exemplary embodiment includes a DC power source, a main power controller (MPC) with a MPC microprocessor and an MPC power switcher driver and fault switching control circuit, and a plurality of Nodes connected to the DC power source through conductors that allow both power to be supplied and bidirectional data transfer between a data receiver and the plurality of Nodes. The fault switching control circuit can provide for short detection and isolation (or other fault detection and isolation) without the direct involvement of the MPC microcontroller. The combined use of the conductors for power, data transmission, and fault detection and isolation offers significant advantages over the prior art in terms of weight reduction, system modularity, and complexity, as well as system protection and survivability.