A method for managing an electric utility power grid including a utility power line route may include generating an infrastructure model including utility assets and image information; receiving power line imaging data collected on the route and including utility asset imaging data; receiving geospatial topological model information; and generating a navigable simulated virtual environment model including an integrated visualization of infrastructure model image information with geospatial topological model image information and power line imaging data. A trained classification algorithm categorizes the condition of utility assets on the route from virtual views.

A method for managing an electric utility power grid including a utility power line route may include generating an infrastructure model including utility assets and image information; receiving power line imaging data collected on the route and including utility asset imaging data; receiving geospatial topological model information; and generating a navigable simulated virtual environment model including an integrated visualization of infrastructure model image information with geospatial topological model image information and power line imaging data. A trained classification algorithm categorizes the condition of utility assets on the route from virtual views.

A distributed power supply system includes a plurality of power supply groups having at least one wind turbine generator; and a rectifier which is provided corresponding to each of the power supply groups, and configured to rectify AC power to DC power, so that the DC power rectified by the rectifier is collected to transmit electric power. A control device for the distributed power supply system comprises a grouping section configured to group the power supply groups into at least two groups; a phase command generation section configured to generate phase commands different from one another for each group to output to the power supply groups belonging to the respective groups, and generate the same phase command to output to the wind turbine generators belonging to the same group; and a transmission section configured to transmit the same phase command to the wind turbine generators.

A distributed power supply system includes a plurality of power supply groups having at least one wind turbine generator; and a rectifier which is provided corresponding to each of the power supply groups, and configured to rectify AC power to DC power, so that the DC power rectified by the rectifier is collected to transmit electric power. A control device for the distributed power supply system comprises a grouping section configured to group the power supply groups into at least two groups; a phase command generation section configured to generate phase commands different from one another for each group to output to the power supply groups belonging to the respective groups, and generate the same phase command to output to the wind turbine generators belonging to the same group; and a transmission section configured to transmit the same phase command to the wind turbine generators.

A power supply for a power line includes a synchronization module having a receiver configured for receiving a clock signal from a satellite-based positioning system and an oscillator configured for generating a periodic signal synchronized to the received clock signal. The power supply includes an inverter module having an inverter configured for supplying an AC voltage to the power line, receiving the periodic signal from the synchronization module, and controlling the inverter using the received periodic signal as a synchronization reference signal for the supplied AC voltage. The power supply further includes a power exchange control module configured for: monitoring an active power flow P from the inverter module to the power line, determining whether the active power flow P satisfies a reverse-flow condition, and when the reverse-flow condition is determined, adapting at least one of a phase and an output voltage of the supplied AC voltage.

The present invention discloses an energy storage system. The energy storage system includes M cell strings, N energy storage converters, first ends of the N energy storage converters are coupled to at least one of the M cell strings, and second ends of the N energy storage converters are configured to connect to a power grid. A first end of a first energy storage converter is coupled to Q cell strings in the M cell strings, and the first energy storage converter includes a DC/AC conversion unit and at least one DC/DC conversion unit. A first DC/DC conversion unit is coupled to at least one of the Q cell strings by using the first end of the first energy storage converter, the first DC/DC conversion unit is coupled to the DC/AC conversion unit, and the DC/AC conversion unit is coupled to the power grid by using a second end of the first energy storage converter. The first DC/DC conversion unit is configured to perform adaptation between a voltage of the DC/AC conversion unit and a voltage of a cell string. Therefore, a cell capacity is fully used, and a waste of the cell capacity is reduced.

The present invention discloses an energy storage system. The energy storage system includes M cell strings, N energy storage converters, first ends of the N energy storage converters are coupled to at least one of the M cell strings, and second ends of the N energy storage converters are configured to connect to a power grid. A first end of a first energy storage converter is coupled to Q cell strings in the M cell strings, and the first energy storage converter includes a DC/AC conversion unit and at least one DC/DC conversion unit. A first DC/DC conversion unit is coupled to at least one of the Q cell strings by using the first end of the first energy storage converter, the first DC/DC conversion unit is coupled to the DC/AC conversion unit, and the DC/AC conversion unit is coupled to the power grid by using a second end of the first energy storage converter. The first DC/DC conversion unit is configured to perform adaptation between a voltage of the DC/AC conversion unit and a voltage of a cell string. Therefore, a cell capacity is fully used, and a waste of the cell capacity is reduced.

A transmitting assembly (114, 214, 334) configured to transmit electric power in a universal wireless charging device (102, 200, 302) is presented. The transmitting assembly (114, 214, 334) includes a first coil (116, 216, 316) embedded in a printed circuit board (220) and configured to transmit a first AC voltage signal having a first frequency. Also, the transmitting assembly (114, 214, 334) includes a second coil (118, 218, 318) disposed on the printed circuit board (220) and configured to transmit a second AC voltage signal having a second frequency, wherein the second frequency is different from the first frequency, and wherein the first AC voltage signal having the first frequency and the second AC voltage signal having the second frequency are used to wirelessly charge a plurality of receiver devices (104, 106) having different frequency standards.

A transmitting assembly (114, 214, 334) configured to transmit electric power in a universal wireless charging device (102, 200, 302) is presented. The transmitting assembly (114, 214, 334) includes a first coil (116, 216, 316) embedded in a printed circuit board (220) and configured to transmit a first AC voltage signal having a first frequency. Also, the transmitting assembly (114, 214, 334) includes a second coil (118, 218, 318) disposed on the printed circuit board (220) and configured to transmit a second AC voltage signal having a second frequency, wherein the second frequency is different from the first frequency, and wherein the first AC voltage signal having the first frequency and the second AC voltage signal having the second frequency are used to wirelessly charge a plurality of receiver devices (104, 106) having different frequency standards.

A power control system includes: a first AC/DC converter; a second AC/DC converter; a first switch connected between a first transmission line of a first power system having a first system frequency and the first AC/DC converter; a second switch connected between the first transmission line and the second AC/DC converter; a third switch connected between a second transmission line of a second power system having a second system frequency and the first AC/DC converter; a fourth switch connected between the second transmission line and the second AC/DC converter; a fifth switch connected between the first AC/DC converter and the second AC/DC converter; and a control device. When the first and second AC/DC converters are caused to operate as AC/DC converters in a BTB (Back to Back) method, the control device controls at least the fifth switch to be in a closed state.