A power distribution management apparatus (10) includes acquiring the amount of demand obtained by forecasting the amount of power to be used by load equipment of a customer, and the amount of power generation obtained by forecasting the amount of power to be generated by power generation equipment of the customer, and setting a plurality of voltage values as a plurality of candidates for a transmission voltage from a substation of a power distribution system, and calculating a voltage at a connection point of the load equipment of the customer and equipment of the power distribution system at each of the plurality of candidates by utilizing a difference between the demand amount and the power generation amount of each customer, and determining the transmission voltage of the substation from the plurality of candidates based on a result of the calculating.

A remote monitoring system and method for electricity demand of a fused magnesium furnace group. The system has a data acquisition device, a local PC, a cloud server and a remote PC. The data acquisition device has a voltage transformer, a current transformer, an active power transducer, a first slave computer, a plurality of multi-purpose electronic measuring instruments and a second slave computer. The method includes acquiring smelting current and smelting power of each fused magnesium furnace and electricity demand of the furnace group, controlling the switch off/on of each fused magnesium furnace according to the smelting current and the smelting power of each fused magnesium furnace and the electricity demand of the furnace group, sending basic monitoring data to the local PC, and achieving data exchange between the local PC and the remote PC through the Zookeeper technology.

An integrated circuit (IC) includes subcircuits, power switches coupled to pass load current to a respective one of the subcircuits when activated by a respective switch control signal, and sensing circuits. Each of the sensing circuits is coupled to a respective one of the subcircuits, wherein the sensing circuits are configured to generate sense currents that are proportional to the respective load currents. The IC also includes a conversion circuit configured to receive at least one of the sense currents and to convert the at least one of the sense currents to an equivalent multi-bit digital signal, a timestamp circuit configured to generate a timestamp value that is correlated with the multi-bit digital signal, and a controller configured to provide signals to operate the power switches and the sensing circuits.

The disclosure relates to a measuring device for measuring a physical variable. The measuring device has a converter, which is designed to convert an input variable present at a measurement input, into a measurement signal and to provide the same as an output variable. The measuring device comprises a processing unit, which is configured to process the output variable of the converter, and a signal generator, which is designed to generate a test signal on the basis of a specification which test signal corresponds to an output variable of the converter to an input variable of the converter corresponding to the specification. The processing unit can be connected via a switching element either to an output of the converter or to an output of the signal generator. The disclosure further relates to a method for testing a measuring device.

A system (10) for power and/or energy consumption metering on an AC powerline network (1) supplying a plurality of channels (C.sub.1, C.sub.2, . . . , C.sub.n) with a respective electrical load (L.sub.1, L.sub.2, . . . , L.sub.n), comprising: A central unit (11) connected to the AC powerline network (1), comprising a single central voltmeter (110) supplied by a power supply unit (112); A plurality of clamped-on units (12), distributed over each channel (C.sub.1, C.sub.2, . . . , C.sub.n) to be measured, each clamped-on unit (12) being clipped around existing cables, and comprising a current transformer (120) in order to measure current values The plurality of clamped-on units (12) are connected to the central unit (11) for data transmission and synchronization, and for power supply by the power supply unit (112).

An integrated circuit (IC) includes subcircuits, power switches coupled to pass load current to a respective one of the subcircuits when activated by a respective switch control signal, and sensing circuits. Each of the sensing circuits is coupled to a respective one of the subcircuits, wherein the sensing circuits are configured to generate sense currents that are proportional to the respective load currents. The IC also includes a conversion circuit configured to receive at least one of the sense currents and to convert the at least one of the sense currents to an equivalent multi-bit digital signal, a timestamp circuit configured to generate a timestamp value that is correlated with the multi-bit digital signal, and a controller configured to provide signals to operate the power switches and the sensing circuits.

Briefly, embodiments are directed to a system, method, and article for identifying power system event signatures. Input measurement data may be received from one or more data sources relating to a power grid system. The input measurement data may comprise normal system operation measurement data and power system event measurement data. A processor may perform operations during an online application phase. During the online application phase, a feature matrix may be generated for the power system event measurement data and the at least one trained auto-associative model. The feature matrix for the power system event measurement data may be processed to determine power system event residuals. Also during the online application phase, the power system event signatures may be identified based on residual statistics for normal system operation measurement data residuals and on the power system event residuals.

An electronic device for monitoring an electrical quantity out of a voltage and arc intensity relative to an alternating current flowing in an electrical conductor, includes a measurement module configured to measure at least one value of the electrical quantity, a wireless transceiver, and a transmission module linked to the wireless transceiver. The monitoring device furthermore includes a computation module configured to compute at least one parameter for monitoring the electrical quantity as a function of at least one measured value of the electrical quantity, each monitoring parameter being chosen from an angular phase of the electrical quantity and a modulus of the electrical quantity, the transmission module being configured to transmit, to another electronic device, a data message containing at least one computed monitoring parameter.

A system (10) for power and/or energy consumption metering on an AC powerline network (1) supplying a plurality of channels (C.sub.1, C.sub.2, . . . , C.sub.n) with a respective electrical load (L.sub.1, L.sub.2, . . . , L.sub.n), comprising: A central unit (11) connected to the AC powerline network (1), comprising a single central voltmeter (110) supplied by a power supply unit (112); A plurality of clamped-on units (12), distributed over each channel (C.sub.1, C.sub.2, . . . , C.sub.n) to be measured, each clamped-on unit (12) being clipped around existing cables, and comprising a current transformer (120) in order to measure current values

The plurality of clamped-on units (12) are connected to the central unit (11) for data transmission and synchronization, and for power supply by the power supply unit (112).

The present disclosure relates to a system for automatically identifying product information, including a lamp information collection module, a controller, and a user terminal. The controller has a built-in comparison table setting different power information intervals for different lamp categories, and sends to-be-collected power information to the lamp information collection module. The lamp information collection module is used to collect corresponding power information according to the received to-be-collected power information and send the collected power information to the controller. The controller is further used to determine a category of a lamp according to the collected power information corresponding to the lamp and the power information interval comparison table, and send information of the lamp to the user terminal. The user terminal includes a human-machine interface and is used to display the information of the lamp on the human-machine interface.