The disclosure features systems for wireless power transfer that include a resonator featuring a coil with at least two windings and at least one inductor having an inductance value, where the at least one inductor is connected in series to at least one of the windings, and where the inductance value is selected so that when the coil carries a current during operation of the system, the at least one inductor maintains a distribution of current flows among the at least two windings such that for each of the at least two windings, an actual current flow in the winding differs from a target current flow for the winding by 10% or less.

The present invention suppresses leakage magnetic field. A power transfer coil configured to transmit or receive power includes: an inner coil; a first outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to a magnetic flux outside the inner coil is generated outside the first outer coil, the first outer coil having one end connected to a first terminal and the other end connected to one end of the inner coil; and a second outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to the magnetic flux outside the inner coil is generated outside the second outer coil, the second outer coil having one end connected to a second terminal and the other end connected to the other end of the inner coil.

The present invention suppresses leakage magnetic field. A power transfer coil configured to transmit or receive power includes: an inner coil; a first outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to a magnetic flux outside the inner coil is generated outside the first outer coil, the first outer coil having one end connected to a first terminal and the other end connected to one end of the inner coil; and a second outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to the magnetic flux outside the inner coil is generated outside the second outer coil, the second outer coil having one end connected to a second terminal and the other end connected to the other end of the inner coil.

A method for the exchange of electrical energy between at least two moving, electrically powered vehicles, comprising the steps: providing a first and a second electrically powered vehicle, having a respective electrical energy store, the energy store of the first and the second vehicle can emit or receive electrical energy, and the first and second vehicles move or are to be moved along a first or second route; changing the first and second routes in such a way that both changed routes coincide along a route section; steering the first and second vehicle along the changed first and second route in such a way that both the vehicles move along the coinciding route section at a distance to one another that is smaller than a predefined maximum distance; and transferring electrical energy from the energy store of the first vehicle to the energy store of the second vehicle.

A method for the exchange of electrical energy between at least two moving, electrically powered vehicles, comprising the steps: providing a first and a second electrically powered vehicle, having a respective electrical energy store, the energy store of the first and the second vehicle can emit or receive electrical energy, and the first and second vehicles move or are to be moved along a first or second route; changing the first and second routes in such a way that both changed routes coincide along a route section; steering the first and second vehicle along the changed first and second route in such a way that both the vehicles move along the coinciding route section at a distance to one another that is smaller than a predefined maximum distance; and transferring electrical energy from the energy store of the first vehicle to the energy store of the second vehicle.

In certain aspects, an enclosure for a wireless power transfer pad is disclosed. The enclosure includes a cover shell configured to be positioned over a portion of the wireless power transfer pad configured to face a wireless power receiver when wirelessly transferring power, wherein at least a portion of the cover shell is made of a heat resistant material.

A method for assisting with the positioning of a motor vehicle for inductive charging of a battery of the motor vehicle comprises reading a number plate associated with the motor vehicle using the number plate information to produce a location on the vehicle of a vehicle inductive coupling point (VICP) with reference to at least one reference point on the motor vehicle, comparing a predicted current position of the VICP to a fixed inductive coupling point (ICP) located in or on a road surface upon which the motor vehicle is to be positioned, and providing feedback to one of the driver and the motor vehicle indicative of the required action required to produce alignment of the VICP with the ICP. The method may further comprise energizing the ICP to charge the battery of the motor vehicle when the VICP is predicted to be aligned with the ICP.

A non-contact power supply system supplies power in a non-contact manner between a power transmission coil of a power supply device and a power reception coil of a vehicle. The power supply device side communication unit transmits identification information of the power supply device to the vehicle. The generation unit generates a power pattern list by allocating each piece of the identification information that is received by the vehicle side communication unit to several power patterns based on a prescribed rule. The vehicle side communication unit transmits the power pattern list to the power supply device. The controller causes power to be outputted from the power transmission coil to the power reception coil according to a power pattern which corresponds to the identification information. The determination unit determines establishment of a paired communication based on a comparison the detected power pattern and a power pattern.

A vehicle emits a first signal when the vehicle moves after reception of electric power from an electric power transmission device by an electric power reception device is completed and when a preparatory condition for the vehicle to move is satisfied after reception of electric power from the electric power transmission device by the electric power reception device is completed. When a charging station receives the first signal, the charging station emits a second signal notifying that a state allows charging.

A system for charging an electric vehicle including a battery includes a charging station, a management computer, and a charging controller. The charging station includes a power transmission device that supplies electric power to the electric vehicle. The management computer stores multiple charging profiles for different battery types. The charging controller is mounted on the electric vehicle and controls charging of the battery with the electric power from the power transmission device. The charging controller stores identification information about the battery. The charging controller transmits the identification information to the management computer. The charging controller acquires the charging profile corresponding to the identification information from the management computer. The charging controller controls charging of the battery according to the charging profile.