Abstract: Provided are a cascaded photovoltaic grid-connected inverter, a control method and a control device for the same. The method includes: determining whether at least one of inverter units of the cascaded photovoltaic grid-connected inverter is over-modulated; injecting a reactive current to a power grid to make a grid-connected current effective value greater than or equal to ?{square root over (2)}*idcmin, in a case that at least one of the inverter units is over-modulated; determining a voltage U0 required for grid connection for the cascaded photovoltaic grid-connected inverter corresponding to a current grid-connected current effective value; and adjusting an output active voltage of each of the inverter units according to Ujd=Pj/P0*U0d, and adjusting an output reactive voltage of each of the inverter units in a case that none of the inverter units is over-modulated.

Abstract: A cascading regulation system connected to a number of serially connected power sources and uses multiple regulators having different cutoff voltages to provide an output for the local power consumption unit. Each of the regulators is connected to a subset of serially connected power sources and so configured that if the voltage generated at the lowest tap is no longer sufficient for a stable supply to the local power consumption unit, the next higher regulator takes over, and the output voltage drops in small steps reflective of that takeover of the next higher tap. When the voltage generated across a subsection grows, a lower connected tap may take over again, producing a slightly higher output voltage for the local power consumption unit. The cutover steps are chosen such that the output voltage range matches the range given as the acceptable input range for the local power consumption unit.

Abstract: In one embodiment, a method, system, and apparatus including a Power Source Equipment (PSE) device configured to provide Power-over-Ethernet (PoE) to a Powered Device (PD) that is configured to receive a request from the PD requesting a quantity of PoE power, the quantity of PoE power including an amount of power to be provided by the PSE as power for redundancy, receiving a message from the PD, the message including a unique identifier, allocating a requested quantity of PoE power, the allocating of the requested quantity of PoE power including allocating to provide the requested quantity of PoE power from one of a plurality of PSEs, and providing the requested quantity of PoE power to the PD. Related methods, systems, and apparatuses are described.

Abstract: Methods and systems for load alignment assistance are provided. An alignment current may be provided with a partial power converter through an n-phase supply line to a synchronous alternating current (AC) motor during a startup of a synchronous AC grid. The synchronous AC motor may receive polyphase AC power through the n-phase supply line from the synchronous AC grid during the startup. The partial power converter may be powered by a power source isolated from the synchronous AC grid. The alignment current may be controlled such that the alignment current causes a rotor of the synchronous AC motor to align with a rotor of a generator that powers the synchronous AC grid.

Abstract: A power receiving device and a power feeding system which are capable of performing communication and power feeding at the same time are provided. Further, a power receiving device and a power feeding system which are capable of stably performing communication during power feeding are provided. One embodiment of the present invention relates to a power receiving device which includes an antenna for communication and power feeding that receives AC power, a rectifier circuit that rectifies the received AC power including the modulation signal into DC power, a smoothing circuit that smoothes the resulting DC power, a power storage device that stores the smoothed DC power, a communication control unit that analyzes the modulation signal included in the AC power, and a transformer that is positioned between the antenna and the rectifier circuit and changes a reference potential of the AC power, and a power feeding device.

Abstract: A disconnecting device for interrupting a direct current between a direct current source and an electric apparatus, having a current-conducting mechanical switch, a power electronics unit connected thereto, and an energy store which is charged by an arcing voltage generated on the switch by an arc as the switch is being disconnected. A pulse generator that is connected to the energy store triggers at least one semiconductor switch of the power electronics unit in such a way that the power electronics unit short-circuits the switch and the arc is extinguished.

Abstract: A rechargeable battery type electric power tool is widely used for a construction work or a horticultural work. A battery of the electric power tool can also be used as a power source of an electric apparatus. Because of this construction, there is provided the electric apparatus that has a function equivalent to that of an AC power source type apparatus.

Abstract: A vehicle power supply control device includes a vehicle power supply master connected at one end of a single-system trunk line unit and including a main battery charged with power and discharging power, a plurality of area power supply masters connected with the single-system trunk line unit through branch line units and connected with load units consuming power, a first supply path supplying power from the vehicle power supply master to the area power supply masters through the single-system trunk line unit, a second supply path different from the first supply path, and an external power supplying unit provided outside the area power supply masters and supplying power to the area power supply masters through the second supply path.

Abstract: A complex regulator of a remote-controlled car or remote-controlled boat includes a power input terminal, a power output terminal, a switch regulator, and a linear regulator. The switch regulator and the linear regulator are both connected between the power input terminal and the power output terminal and regulates the input voltage after which the input voltage is conveyed to the power output terminal. The switch regulator and the linear regulator have different operational conditions. When the remote-controlled car or remote-controlled boat is operated under a heavy load condition and the input voltage is consequently reduced to a level lower than the first threshold voltage and higher than the second threshold voltage, the switch regulator stops regulating the input voltage and the linear regulator continues regulating the input voltage to maintain the operation of the controller of the remote controlled car or boat.

Abstract: When a resonant frequency of a power transmission-side resonance mechanism is expressed by fra, a switching frequency of a first switch circuit and a second switch circuit is expressed by fs, and a resonant frequency of the power transmission-side resonance mechanism and a capacitor of the first switch circuit or the second switch circuit is expressed by frb, a relation of fra<fs?frb is satisfied.

Abstract: The disclosure concerns a portable beauty light kit, comprising a power management and control unit “PMC” and a plurality of light modules. The PMC comprises: a plurality of charging bays, and a signal transmitting circuit. Each of the individual light modules comprises: a light emitting source, a signal receiving circuit, and a housing. Each of the individual light modules is designed to nest within one of the charging bays of the PMC, wherein they receive a battery charge. Additionally, the light modules are designed to be taken from the charging bays of the PMC and removeably attached to a mirror. The signal receiving circuit of each light module is configured to receive a wireless signal communicated from the signal transmitting circuit of the PMC. The signal receiving circuit modulates a light emitting state associated with each light emitting source based on the signal communicated from the signal transmitting circuit.

Abstract: Methods and apparatus are disclosed for wirelessly transmitting power. In one aspect, an apparatus for wireless transmitting power is provided. The apparatus comprises a first coil loop defining a first area, the first coil loop conducting current at a first current value for generating a first magnetic field. The apparatus further comprises a second coil loop surrounding the first coil loop and defining a second area, the second coil loop conducting current at a second current value generating a second magnetic field, wherein a ratio of the first current value to the first area is substantially equal to a ratio of the second current value to the second area.

Abstract: An antenna for wireless power transmission. A first coil portion includes a first outer coil portion and a first inner coil portion. A second coil portion includes a second outer coil portion and a second inner coil portion. The first coil portion and the second coil portion are disposed to overlap and intersect each other at one or more points. In a state in which the first coil portion and the second coil portion are overlapped, bends of the first coil portion and the second coil portion overlap and intersect each other. All of the bends of the first outer coil portion are located above the bends of the second outer coil portion or all of the bends of the second outer coil portion are located above the bends of the first outer coil portion. Uniform charging efficiency is obtained across entire areas.

Abstract: A backup power supply system is provided in the present invention. In the backup power supply system, a power supply module is provided to transmit a work electricity to a load module. When a trigger is triggered to be switched on, a backup power module transmits a backup power to a capacitor and the load module through a switch module to make the capacitor store the backup power as a storing power. The load module is provided to receive the at least one of the backup power and the storing power to maintain a working status. The power supply module stops transmitting the work electricity to the load module when the backup power supply system is at a backup status.

Abstract: Techniques for modifying the electrical current distribution of transmit coil of a wireless power transmitting unit are described. An example power transmitting unit includes a transmit coil configured to generate a magnetic field to wirelessly power a device within an active wireless charging area. The power transmitting unit can also include a power source to transmit an alternating electrical current to an input terminal of the transmit coil and a plurality of reactive elements placed in series with the transmit coil. In some examples, the plurality of reactive elements attach to the transmit coil at least a quarter of a turn from the input terminal. The power transmitting unit can also include a controller to modify a reactance value of the reactive elements to adjust a current distribution of the transmit coil in response to detecting a characteristic of a power receiving unit.

Abstract: A solid-state automatic transfer switch includes a primary rectifier circuit and a secondary rectifier circuit, wherein at least one of the rectifier circuits includes one or more controllable semi-conductor switches. The primary rectifier circuit is electrically coupled to a primary input and an output of the solid-state automatic transfer switch. Also, the secondary rectifier circuit is electrically coupled to a secondary input of the solid-state automatic transfer switch and the output. A controller controls a control state of the controllable semi-conductor switches to allow or prevent electrical power from flowing through the primary or secondary rectifier circuits, thus selectively controlling whether power is fed from the primary input or the secondary input of the solid-state automatic transfer switch to the output of the solid-state automatic transfer switch.

Abstract: Provided is a coil position detection method for a non-contact power supply system, configured to supply power from a power transmission coil on a ground side to a power reception coil on a vehicle side, by which a position of the power reception coil is detected. Output terminals of a rectifier circuit configured to rectify AC power received by the power reception coil are connected to a drive circuit and a battery. Moreover, a relay switch is provided between the battery and one of the output terminals of the rectifier circuit. When the relay switch is on, the coil position is detected based on AC voltage detected by a first voltmeter provided upstream of the rectifier circuit and, when the relay switch is off, the coil position is detected based on DC voltage detected by a second voltmeter provided downstream of the rectifier circuit.

Abstract: Systems and techniques are provided for a power receiver circuit. A power generating mechanism may include power generating elements that may generate alternating current signals. Rectifier circuit may include rectifiers that may generate a direct current signal from an alternating current signal, and diodes. Group circuits that may connect groups of rectifier circuits in electrical circuits to combine the direct current signals from the rectifier circuits in a group into a single direct current signal. A step down converter may be connected to the group circuits. The step down converter may convert a direct current signal to a direct current signal of a target voltage level. An output switch may be connected to the step down converter. A linear regulator may be connected to the step down converter. A microcontroller may be connected to the linear regulator and the output switch and may control the output switch.

Abstract: A device for providing an activation voltage for a safety unit for a vehicle. The device includes a supply terminal for applying a first supply voltage potential, an activation terminal for outputting the activation voltage, and a control terminal for reading in a control signal. In addition, the device includes a pass-through switch that is connected between the supply terminal and the activation terminal, a first control switch, a second control switch, and a third control switch that includes a control input that is connected to the control terminal.

Abstract: A method for controlling a wireless power transmitter transmitting wireless power to a wireless power receiver is provided. The method includes generating a first differential signal for the wireless power transmitted to the wireless power receiver, measuring a second differential signal corresponding to the first differential signal applied to a resonating unit of the wireless power transmitter, and detecting at least one of an amplitude and a phase of the second differential signal according to a measurement result, and controlling at least one of the amplitude and the phase of the second differential signal according to a detect result, and controlling the wireless power transmitter based on information on the controlled second differential signal.