A power generation system includes a power source that is configured to communicate with at least one of a downstream load or a downstream device by changing a voltage on a power bus between the power source and the at least one of the downstream load or the downstream device, while power source provides power on the power bus to the at least one of the downstream load or the downstream device.

This disclosure describes techniques that enable a supplemental voltage to be delivered to a Remote Radio Unit (RRU) to compensate for a voltage loss that occurs between a primary Direct Current (DC) power source and the RRU. A supplemental voltage controller is described that captures current environmental metadata associated with an operation of the RRU and calculates an RRU voltage at the RRU. In doing so, the supplemental voltage controller may generate a supplemental voltage control signal that supplements the RRU with a supplemental DC voltage.

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.

Methods and systems identify connection paths between a power source and a plurality of loads. A reachability signal is sent on a cable connecting a power output of the power source to a power distribution unit (PDU). The PDU receives the reachability and forwards a modified reachability signal on one or more power outputs of the PDU to one or more loads. The PDU receives a return reachability signal from the one or more loads and forwards corresponding modified return reachability signals on the cable to the power source. The power output of the power source receives a plurality of modified return reachability signals that each comprises an identity of the PDU, an identity of a respective power output of the PDU, and an identity of a respective load. A reference between these identities is stored by the power source in a database.

A method for power management that includes: determining, by a network device, a maximum current rating of a first power distribution unit (PDU) driven by a first direct current (DC) power plant including multiple backup batteries; determining multiple power ratings for multiple line modules in the network device, where the multiple line modules are connected to a first feed from the first PDU and a second feed from a second PDU; calculating, by the network device, a maximum aggregate current for the multiple line modules based on the multiple power ratings and a shutdown voltage corresponding to the multiple backup batteries; and allocating, in response to the maximum aggregate current exceeding the maximum current rating, a first current threshold to a first line module and a second current threshold to a second line module.

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.

The invention relates to a device, system and method for balancing power in an electrical power grid, to which a plurality of households are connected. The total electrical power production of those households that have a net electrical power production is calculated, as well as the total electrical power consumption of those households that have a net electrical power consumption. The ratio of the values obtained is then calculated, and compared to a predetermined value. Depending on the outcome of the comparison, a signal is created that triggers the switching of an apparatus in one of the households to an on-state or an off-state. In this way, an effective balancing of the supply with the consumption of electricity in a local low-voltage power grid has been achieved.

An emergency operating arrangement for at least one building technical device is provided, comprising a power supply unit, and an emergency supply unit, the power supply unit and the emergency supply unit being adapted to be supplied by an electrical supply and being configured to output a DC voltage, wherein the emergency supply unit is configured to detect an emergency situation and being configured to output a DC voltage higher than the DC voltage output by the power supply unit when the emergency situation is detected.

Power management device includes memory, classification portion, planning portion and indication portion. Classification portion classifies a change in monitoring power during a unit period with respect to each of buildings, stored in memory, into any one of kinds of electric power patterns. Planning portion determines pattern sets based on the kinds of electric power patterns, and determines control content for charging and discharging of electric storage apparatus with respect to each pattern set under condition of minimizing any one of amount of electric power to be received from power grid, compensation of amount of electric power to be received from power grid, and amount of carbon dioxide to be exhausted. Indication portion indicates control content corresponding to each of pattern sets determined by planning portion to electric storage apparatus of a building, which each pattern set conforms with, of the buildings.

Methods and apparatus for enhancing reserve power units are described. An example apparatus includes a power source to operate a process control component and a power conditioner to provide power during a disruption of power from the power source to prevent a false trigger of a shutdown function of the process control component.