A wireless power feed system with high transfer efficiency of electric power is disclosed. The wireless power feed system includes a power feeding device and a power receiving device, wherein the power feeding device includes a first electromagnetic coupling coil that is connected to an AC power source via a directional coupler; a first resonant coil; a switch connected to the opposite ends of the first resonant coil; a control circuit which conducts switching on/off of the switch based on a parameter of an amplitude of a reflective wave detected by the directional coupler; and an analog-digital converter provided between the first electromagnetic coupling coil and the control circuit; and the power receiving device includes a second resonant coil; and a second electromagnetic coupling coil, and wherein the first electromagnetic coupling coil is provided between the first resonant coil and the second resonant coil.

A wireless power feed system with high transfer efficiency of electric power is disclosed. The wireless power feed system includes a power feeding device and a power receiving device, wherein the power feeding device includes a first electromagnetic coupling coil that is connected to an AC power source via a directional coupler; a first resonant coil; a switch connected to the opposite ends of the first resonant coil; a control circuit which conducts switching on/off of the switch based on a parameter of an amplitude of a reflective wave detected by the directional coupler; and an analog-digital converter provided between the first electromagnetic coupling coil and the control circuit; and the power receiving device includes a second resonant coil; and a second electromagnetic coupling coil, and wherein the first electromagnetic coupling coil is provided between the first resonant coil and the second resonant coil.

The wireless power transmission is a system for providing wireless charging and/or primary power to electronic/electrical devices via microwave energy. The microwave energy is focused to a location by a power transmitter having one or more adaptively-phased microwave array emitters. Rectennas within the device to be charged receive and rectify the microwave energy and use it for battery charging and/or for primary power.

An electrical architecture including at least one linear photovoltaic installation formed by several groups of photovoltaic panels and by a DC network, connected to an AC transmission network and/or an AC distribution network with arbitration of the power injected from the DC network to the AC network. The system substantially entails putting in place an architecture with at least one linear PV installation with a DC network and interconnecting this subassembly at at least two separate points of interconnection with a preferably existing AC power grid. Each point of interconnection to a node of the AC network is a voltage source converter VSC which can inject 0 to 100% of the maximum power P of the linear PV installations.

An architecture with at least one PV linear installation with a DC network and in interconnecting this subassembly, at at least two distinct interconnection points, with a preferably existing AC electricity network. Each interconnection point to a node of the AC network is a voltage source converter VSC that is able to inject from 0 to 100% of the maximum power P of the PV linear installations.

Disclosed are a wireless power transmitting apparatus and a wireless charging system. The wireless power transmitting apparatus includes: a detecting unit which detects transmitting current of a wireless power transmitting coil; and a charge monitoring unit which is able to determine that wireless charging has been completed when the detected transmitting current is shown to be below a charging threshold value over a set amount of time.

Provided is an apparatus for determining an abnormal status of a wireless power transmission coil, the apparatus including an input-current sensor configured to detect an input current and provided at an input side of a power transmission coil, an output-current sensor configured to detect an output current and provided at an output side of the transmission coil, and a controller configured to compare each of the input current and the output current with a predetermined threshold value corresponding thereto to determine whether a disconnection or a short circuit occurs in the transmission coil.

A power system architecture includes a prime mover, a plurality of single phase permanent magnet generators mechanically coupled to the prime mover, a DC power bus including a plurality of DC power storage components, each of the DC energy storage components being electrically connected to at least one of the single phase permanent magnet generators, a plurality of state of charge calculators, each of the state of charge calculators being connected to one of the DC energy storage component and being communicatively coupled to a generator control unit, and wherein the generator control unit is configured to independently control each of the single phase permanent magnet generators.

A power system architecture includes a prime mover, a plurality of single phase permanent magnet generators mechanically coupled to the prime mover, a DC power bus including a plurality of DC power storage components, each of the DC energy storage components being electrically connected to at least one of the single phase permanent magnet generators, a plurality of state of charge calculators, each of the state of charge calculators being connected to one of the DC energy storage component and being communicatively coupled to a generator control unit, and wherein the generator control unit is configured to independently control each of the single phase permanent magnet generators.

A wireless power transmission system, according to some implementations, includes: an antenna configured to transmit radio frequency signals for both data transmission and power transmission; and a wireless device coupled with the antenna, the wireless device configured to cause the antenna to transmit the radio frequency signals for the data transmission and the power transmission; wherein the wireless device includes a communication module configured to perform data transmission operations with respect to power transmission operations according to a temporal schedule; and wherein the temporal schedule specifies occurrence of the data transmission operations and the power transmission operations at different intervals.