A management method includes a step A of estimating, for each of the plurality of entities, an error pattern related to a prediction error occurring when a power consumption amount in a future period is predicted; and a step B of determining a group of entities from among the plurality of entities based on the error pattern, wherein the group is a destination of a power reduction request for reducing the power consumption amount. The step A includes a step of estimating whether the prediction error is a positive error or a negative error. The step B includes a step of determining the group such that a total prediction error of the group is minimized, by combining an entity of which the prediction error is estimated to be a positive error and an entity of which the prediction error is estimated to be a negative error.

The converter circuit includes an inverter. The converter circuit receives DC power from a DC power supply (such as a solar cell or a storage battery unit), has the DC power converted into AC power by at least the inverter, and outputs the AC power to a load or a power grid. When acquiring information that two or more types of power curtailment causes have arisen, a control circuit makes the converter circuit limit power output to a maximum degree of power curtailment out of two or more degrees of power curtailment according to specifics of the two or more types of power curtailment causes.

A controller according to an embodiment controls a hydrogen system including at least a hydrogen production system in which received power is planned in advance and a hydrogen production amount changes in accordance with the received power. The controller includes: a processor that calculates, in a preparation time period before a demand adjustment time period in which a target value of the received power is set in advance, a control command value such that input power to be inputted as the received power to the hydrogen production system matches the target value at a start of the demand adjustment time period; and a command controller that outputs the control command value calculated by the processor to the hydrogen production system.

Regarding an independent system, a prediction value of charged/discharged power of a storage battery is calculated, based on a prediction value of generated power of a renewable energy power generator, a prediction value of demanded power of a control device, and a prediction value of demanded power of a load on an assumption that a power supply limit is applied to the load. Whether or not charge or discharge of the storage battery with charged/discharged power matching the prediction value of the charged/discharged power of the storage battery is possible is determined. The power supply limit is tightened when it is determined that the charge or discharge of the storage battery is not possible. A limit data indicating a detail of the power supply limit is output when it is determined that the charge or discharge of the storage battery is possible.

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.

Systems and methods are provided for managing power usage in mining environments. The amount of power needed to operate a set of electrical machines that are to run simultaneously is determined. Power usage by the electrical machines during a time period can be predicted based on how much power is expected to be needed by each machine. If the predicted power usage exceeds a threshold power usage, power to one or more electrical machines in the mining environment is restricted so that actual power usage in the mining environment does not exceed the threshold power usage during the specified time period. The electrical machines which will have power restricted thereto can be selected based at least in part on relative priorities for the electrical machines in the set. Power can be restricted to machines as a whole (an effective shutdown), or to specific operations of the machines.

A method, apparatus, and system for dynamic management of multiple device power consumption is disclosed. One or more battery-powered devices may be connected to a power supply for charging. A first battery-powered device may determine an amount of power stored in a power supply. A first power consumption profile of the first battery-powered device and a second power consumption profile of a second battery-powered device may be determined. The first and second battery-powered devices may be electrically connected to the power supply. Based at least on the first and second power consumption profiles, the power stored in the power supply may be distributed to the first and second battery-powered devices according to a power distribution ratio such that a first projected battery depletion time of the first battery-powered device substantially coincides with a second projected battery depletion time of the second battery-powered device.

Methods and systems for managing energy consumption during a power-loss event provide a backup power unit that can notify electronic devices of a switch to backup power. The electronic devices can then automatically minimize power consumption upon receiving such notification. The notification can take the form of one or more signals indicative of a backup power operational state. The signals may be sent to the electronic devices over any suitable wired or wireless connection. Depending on the particular operational states, the electronic devices can take one or more predefined backup power handling actions, such as reducing device functionality, entering low-power mode, performing a controlled shutdown, and the like. The particular actions taken may depend on the type of devices, such that certain devices may have power consumption priority over other devices. The above arrangement provides an intelligent way to reduce overall energy consumption during a power-loss event.

Systems and techniques for tolerance-based intelligent edge network energy delivery are described herein. A flexibility metric may be calculated for a node of the edge network. The flexibility metric of the node and flexibility metrics of a set of additional nodes of the edge network may be ranked to create a set of flexibility ranked edge nodes. A notification may be received of a demand response event. A candidate node subset may be identified from the set of flexibility ranked nodes based on requirements of the demand response event and a ranked order the set of flexibility ranked nodes. A demand response command may be transmitted to the candidate node subset upon determining that the candidate node subset satisfies the requirements of the demand response event. The demand response command may cause nodes of the candidate node subset to alter energy consumption for a time period of demand response event.

An in-vehicle power control system includes a first load control unit and a power control device. In the power control device, switch units respectively switch the second conductive paths between an electrically connected state and a not-electrically connected state. A second load control unit predetermines types of switch units, and, if the second load control unit has received, from the first load control unit, a power reduction instruction in which a control method is designated by type, controls the switch units for each type thereof based on the control methods designated by type by the power reduction instruction.