A unitary multilateral junction for deployment in a wellbore, wherein the multilateral junction permits electrical power and communications signals to be established in both a lateral wellbore and a main wellbore utilizing capacitive coupling and a cavity resonator. The unitary junction assembly generally includes a conduit with a first upper aperture, a first lower aperture and a second lower aperture where the first lower aperture is defined at the distal end of a primary passageway extending from a conduit junction and a second lower aperture defined at the distal end of a lateral passageway extending from the conduit junction. A lower wireless energy transfer mechanism in the form of a capacitive coupler is positioned along at least one of the passageways between the distal end of the passageway and the junction. A cavity resonator is adjacent the capacitive coupler to enhance the electric field signal of the capacitive coupler.

A contactless power transmission apparatus includes a receiver that includes a resonant circuit including a receiver coil that receives electric power from a transmitter coil included in a transmitter and a resonant capacitor connected in parallel to the receiver coil. The receiver outputs, through an output coil having fewer turns than the receiver coil and a coil connected to the output coil, electric power received by the resonant circuit and rectifies the output power with a rectifier circuit. The transmitter includes a control circuit that controls a voltage and a switching frequency of alternating current power to be supplied to the transmitter coil from a power supply circuit to allow the contactless power transmission apparatus to continuously perform a constant voltage output operation.

A portable outlet system and method for providing electrical power transmitted from an electrical outlet wirelessly to the portable outlet system for supply to one or more electrical devices connected to the portable outlet system through one or more standard electrical device connectors. The portable outlet system is rechargeable and can optionally include LED lights as well as a handle to facilitate portability. The portable outlet system may include monitors, data receivers and transmitters, and power boosters or relays. The portable outlet system has actuators for power and LED lights and may include an actuator for device synchronizations.

A portable outlet system and method for providing electrical power transmitted from an electrical outlet wirelessly to the portable outlet system for supply to one or more electrical devices connected to the portable outlet system through one or more standard electrical device connectors. The portable outlet system is rechargeable and can optionally include LED lights as well as a handle to facilitate portability. The portable outlet system may include monitors, data receivers and transmitters, and power boosters or relays. The portable outlet system has actuators for power and LED lights and may include an actuator for device synchronizations.

A wireless power receiver and a wireless power reception method are disclosed. The wireless power receiver includes a charging element, a receiving coil configured to wirelessly receive power from a wireless power transmitter, a rectifier configured to convert an alternating current (AC) voltage generated from the receiving coil to a direct current (DC) voltage, and to output the DC voltage, a voltage converter configured to generate a charging current to charge the charging element, based on the DC voltage output from the rectifier, a current measurer configured to measure the charging current transferred to the charging element, and a controller configured to control a level of the charging current generated from the voltage converter based on a result of the measuring.

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 battery case has first and second coils on opposing sides of a battery and has switching circuitry that is coupled between the first and second coils. The battery case has a battery that provides supplemental battery power wirelessly to a wireless power receiving device via the second coil when the switching circuitry is in an open state. The case can also receive power wirelessly with the first coil from a wireless charging mat when the switching circuitry is in the open state. In a closed state, the switching circuitry shorts the first and second coils together so that current flowing through the first coil flows through the second coil in series and so that wireless power from the wireless charging mat that is received with the first coil is transmitted wirelessly to the wireless power receiving device using the second coil.

Embodiments of magnetic field transfer circuits and methods for wirelessly charging electrical load herein. In one example, a magnetic field transfer circuit (MFCT) includes a first coil and a second coil. The first coil is configured to receive a first magnetic flux transmitted from a transmitter and convert the received magnetic flux to a current. The second coil is configured to transmit a second magnetic flux to a receiver based on the current.

An electromagnetic induction device including a wireless power transmission unit including an induction coil configured to generate a magnetic flux in an up-down direction to heat an external device located above the indication coil by induction heating, and a communication unit including a communication coil configured to output a carrier wave, and a relay circuit configured to resonate at a frequency of the carrier wave, to wirelessly communicate with the external device.

An electromagnetic induction device including a wireless power transmission unit including an induction coil configured to generate a magnetic flux in an up-down direction to heat an external device located above the indication coil by induction heating, and a communication unit including a communication coil configured to output a carrier wave, and a relay circuit configured to resonate at a frequency of the carrier wave, to wirelessly communicate with the external device.