A storage battery capacity measurement device is provided in in-plant equipment including a storage battery system connected to an intra-equipment electric wire. The storage battery system includes plural storage batteries connected in parallel to the intra-equipment electric wire. The storage battery capacity measurement device is configured to execute a determining one storage battery among the plural storage batteries as a measurement target storage battery, and at least one storage battery other than the measurement target storage battery as a measurement support storage battery, discharging an electricity amount of the measurement target storage battery from an upper limit to a lower limit, and charging the discharged electricity amount to the measurement support storage battery, and calculating a discharge capacity of the measurement target storage battery, based on an integrated value of a current flowing through the measurement target storage battery during discharge.

A number of flywheel units are arranged in a geometric pattern. Each of the flywheel units is enclosed in a containment unit. The containment unit includes a cylindrical tube, a cover, a bottom support, resting on the ground, on which the containment unit is mounted, and a fill medium surrounding each containment unit. The containment unit may also include a horizontal plate, mounted to the base of tube, which extends outward or radially from the base of tube a pre-determined length. In this case, the fill medium rests directly on top of the portion of the plate that extends outward from tube.

This power management device: receives, at predetermined intervals for each certain time period, an integrated value that is obtained by totaling power flowing between a power system and a consumer facility within the certain time period from a smart meter that measures the amount of the power flowing between the power system and the consumer facility; receives, at shorter intervals than the predetermined intervals, the measured value of the power flowing in the consumer facility from a power sensor provided separately from the smart meter; and calculates complementary information that complements the integrated value on the basis of the measured value.

A temporary kinetic energy storage-holder and energy transfer devise, comprising of a rotating cable preferably of steel, between two fixed rotating points each a thrust bearings and a one direction rotation hub at the kinetic energy source, coupled to at one end to a kinetic energy capturing devise such as wind turbine, water wheel, animal human or any other kinetic energy generating or collector devise, and at the other end, coupled to an electricity generating devise, a generator, directly or via a geared speed modifier to control generator impute. And all this attached to a supporting structure, tower, pole, pipe column or the ground, to transform kinetic energy into electricity.

The mouse includes a circuit board having a position detecting unit for detecting the movement of the mouse, a switch for operating the mouse, and a wireless communication unit for wirelessly transmitting the data related to the movement detected at the position detecting unit and the data related to the operation of the switch to the outside. The circuit board and a power source are mounted on a bottom part. The bottom part is covered with a housing. Electronic devices including the circuit board, the power source, and other devices are accommodated in the internal space formed by the bottom part and the housing that have resistance to and strength against the change in pressure and temperature. The entire areas of the outer surfaces of the bottom part and the housing are covered with a resin cover having elasticity, heat resistance, and waterproofness. The cover seals the internal space formed by the bottom part and the housing. The electronic devices are enclosed with a heat insulating sheet.

A system of modules that hold components for operating an external energy source including solar cells and other energy sources is provided, where upon assembly of the modules an electrical cabinet with a module internal air channel for air duct cooling for the components is created. The resulting modular cabinet is only as large as required and is easily expandable. Modules are no larger than the components housed therein and the modules are easy to handle. Interior modules can be in any order reducing the chance of error during assembly and allowing modules in certain positions which may ease installation or operation. Components are thermally connected at the factory to a portion of the air duct in each module and none of the present challenges associated with thermal connection exist at the time of installation.

A plurality of storage battery modules include storage battery control devices that can mutually communicate with each other and obtain a demand for electric power in a predetermined consumer in which the plurality of storage battery modules are provided. The storage battery control devices mutually transmit and receive charging/discharging electric power of the storage batteries and control charging/discharging of the plurality of storage battery modules, respectively, on the basis of the demand for electric power in the predetermined consumer.

An energy storage module for the reversible storage of electric energy is provided that comprises several flywheel energy storage units that are electrically connected in parallel via a shared DC link. A first regulation system is connected to the DC link and that, during normal operation (NO), connects the DC link to one or more external power networks in order to absorb (En) energy from or release (Ep) energy into the external power network(s). A second regulation system includes an input side and an output side, whereby the input side is connected to at least the DC link while the output side is connected to an internal supply network for purposes of supplying one or more electrically powered operating aggregates that are needed to operate the flywheel energy storage units.

A distributed power control system is provided. The system can include a datacenter and a remote master control system. The datacenter can include (i) computing systems, (ii) a behind-the-meter power input system configured to receive power from a behind-the-meter power source and deliver power to the computing systems, and (iii) a datacenter control system configured to control the computing systems and the behind-the-meter power input system. The remote master control system can be configured to issue instructions to the datacenter that affect an amount of behind-the-meter power consumed by the datacenter. The datacenter control system can receive, from a local station control system configured to at least partially control the behind-the-meter power source, a directive for the datacenter to ramp-down power consumption, and in response to receiving the directive, cause the computing systems to perform a set of predetermined operations correlated with the directive.

A power storage system of the invention, includes: a power generator; a first storage battery; a second storage battery having smaller capacitance than that of the first storage battery; a first switcher that connects or disconnects the first storage battery to or from a power supply line and a load device; a second switcher that connects or disconnects the second storage battery to or from the power supply line and the load device; a first switching unit that compares a voltage supplied to the load device with first and second predetermined threshold voltages and controls the first switcher according to a result of the comparison; and a second switching unit that compares the voltage supplied to the load device with third and fourth predetermined threshold voltages and controls the second switcher according to a result of the comparison.