A resource management system includes first and second opening/closing control mechanisms and a grid manager. The first and second control mechanisms each include: a controller to transmit a signal between a resource supply source and a load, a monitor to monitor a state of a resource from the source, a storage to store a policy defining the signal corresponding to the state of the resource from the source; and a path controller to generate the signal based on a monitoring result of the monitor and the policy. The grid manager includes: a third monitor to monitor the state of the resource from the first source; and a third path controller to generate at least one of the first and second signals by controlling at least one of the first path and second path controllers based on a monitoring result of the third monitor.

An energy supply device comprises an analysis unit for determining a signaling information which indicates a state of operation of the energy supply device, and a communication interface for outputting said signaling information. The analysis unit is designed to detect an operating variable of the energy supply device; to set a characterization parameter; and to characterize the detected operating variable of the energy supply device as a function of the characterization parameter in order to obtain the signaling information.

A transformer monitor, communication and data collection device features a signal processor configured to receive signaling containing information about collected data, including some combination of electrical signaling data related to electrical signaling being processed by a transformer located and arranged in a grid network and to which the apparatus is mounted, metered data related to associated electrical signaling being provided from the transformer to a building or structure in the grid network, and other wireless network data related to other wireless network communication devices/nodes/end points deployed in the grid network; and determine corresponding signaling containing information about collected data for transmitting back to a central location or other connection device for further processing, based upon the signaling received.

The present disclosure is directed at methods, systems, and techniques for managing batteries for use in a downhole drilling application. The system includes a power bus, pairs of battery terminals for connecting to batteries, switching circuitry that connects and disconnects the batteries to the power bus, data collection circuitry that obtains battery parameters obtained during system operation, and a controller that controls the switching circuitry and receives the battery parameters. A control line connects the controller to the switching circuitry and a data line connects the controller to the data collection circuitry, with the control and data lines being distinct such that control and data signals are not multiplexed with each other.

A device for monitoring the function of an engine is powered by heat from the engine or other sources other than a conventional, external direct electrical power supply, which may create sparks and/or be unavailable. The device monitors one or more of heat, vibration, or other parameters and can detect certain problems with engine function. The device is particularly suited for remote engine monitoring, and can store and/or display data concerning monitored engine characteristics, and/or directly or indirectly send such data to a location removed from the engine.

A method, apparatus, system and computer program is provided for controlling an electric power system, including implementation of voltage measurement using paired t statistical analysis applied to calculating a shift in average usage per customer from one time period to another time period for a given electrical use population where the pairing process is optimized using a novel technique to improve the accuracy of the statistical measurement.

A Wireless battery area network permits the wirelessly monitoring and controlling of individual batteries within large-scale battery applications. The system automatically configures its wireless nodes in the network and provides for the linking of a plurality of batteries (10) to a master battery management unit (M-BMU) (100) by establishing a wireless battery area network within a battery pack that include slave units (S-BMU) (210). The entire system may also be controlled by a top level battery management unit (T-BMU) (510). The system and method allows for the monitoring of voltage, current, temperature, or impedance of individual batteries and for the balancing or bypassing of a battery.

Smart power socket comprising an MCU, a power supply circuit connected to the MCU, a wireless module circuit, and a drive switch control circuit, where the power supply circuit is connected to a low voltage power line, the wireless module circuit is connected to an external control device by means of wireless communication, and the drive switch control circuit is controlled by the MCU to implement controlling of on and off states of the smart power socket. Further, a smart home system comprising a remote control terminal and the smart power socket, where the smart power socket constitutes a LAN and is connected to Internet by means of a smart home gateway, and the remote control terminal is connected to the smart power socket by means of Internet to implement remote controlling of a household appliance plugged into the smart power socket.

Disclosed embodiments relate to a power metering system, a method and a system for monitoring power consumed by loads by using the power metering system. In some embodiments, the system for monitoring power consumed by loads includes an external power supply source, a renewable energy sources, a distribution board, one or more power metering systems, and a monitoring server.

An arrangement for measuring electrical energy consumption includes an input circuit operable to generate a first signal representative of a line voltage waveform and a second signal representative of a line current waveform. The arrangement further includes a processing circuit operable to generate energy consumption data based on the first signal and the second signal. The processing circuit is further operable to generate a first pulse waveform having a plurality of output pulses based on the energy consumption data, each output pulse corresponding to a quantity of energy consumed. The arrangement further includes a wireless transmitter coupled to the processing circuit, the wireless transmitter configured to transmit an RF signal each time the first pulse waveform changes state.