This disclosure describes a power unmanned aerial vehicle (UAV) that may generate a current from a conductor of an overhead power line carrying an AC power signal. The power UAV has a receptor that includes a secondary coil. Current is generated by the secondary coil of the receptor from magnetic fields emanating from the overhead power lines while the power UAV is flying. The generated current may be used to fly the power UAV, recharge an energy storage device of the power UAV, or be provided to another UAV. In various implementations, while the power UAV is flying, the power UAV may receive another UAV, recharge the other UAV, and then release the UAV to resume flying. In various implementations, the power UAV may also monitor characteristics of the power delivery system.

A vehicle, particularly motor vehicle, having a plurality of wheels that form unsprung structural component parts rotatable around wheel axles and a vehicle body forming a sprung structural component part. An energy generation device is arranged in the vehicle body by which a movement of the vehicle body or of parts of the vehicle body can be converted into electrical energy supplied to a storage battery. The energy generation device is an energy absorption converter and has a cylindrical coil winding which surrounds an interior space in which an axially magnetized permanent magnet is arranged such that it can be driven so as to be coaxially movable by the movement of the vehicle body or of a part of the vehicle body.

A computationally implemented system and method that is designed to, but is not limited to: electronically receiving electric vehicle prospective use information associated with aspects indicating one or more future travel plans involving prospective use of an electric vehicle, the electric vehicle including one or more wireless electrical energy transfer receiving devices and one or more electrical energy storage devices; and electronically obtaining electrical energy transfer aspect information regarding wireless electrical energy transfer from one or more wireless electrical energy transfer imparting stations to the one or more wireless electrical energy transfer receiving devices of the electric vehicle for storage by the one or more electrical energy storage devices of the electric vehicle. In addition to the foregoing, other method aspects are described in the claims, drawings, and text forming a part of the present disclosure.

An air cut-off valve module and a control method thereof is provided. The air cut-off valve module has a structure in which valve plates and driving mechanisms thereof are formed as one module, and is mounted in a stack. Thus, components related to the air cut-off valve are constructed as a compact module. Furthermore, a bypass flow path is formed to dilute exhaust gas of the stack, thereby reducing the concentration of hydrogen.

Methods and systems are provided for controlling an aspirator shut-off valve in an engine of a hybrid vehicle. One example method includes opening the aspirator shut-off valve following a shut-down command to the engine when engine speed is between a first engine speed and a second engine speed, the first engine speed being lower than an idle speed and the second engine speed occurring before an imminent engine stop. The example method further includes not opening the aspirator shut-off valve between the first engine speed and the second engine speed if an oxygen content of an emission control device is at or near a threshold.

The disclosure relates to a wheel suspension of a device having an electrical drive of a wheel for supporting a manual movement impulse. The wheel suspension includes a connector piece movably or bendably arranged between a support element or support frame connected to the device and between an interior stator of an electrical drive, wherein the connector piece is held in a starting position due to the gravity of the device, without other influencing forces. The wheel suspension also includes at least one sensor that detects a deflection of the connector piece, and a control device designed such that the control device together with the electrical drive counteracts a deflection or bending of the connector piece.

A bicycle component control apparatus is basically provided with a power supply sensor and a controller. The power supply sensor detects a power level of a power supply being supplied from the power supply to two electrical bicycle components. The controller operates the two electrical bicycle components in response to receiving at least one signal from at least one input member. The controller operates the two electrical bicycle components at different starting times while the power level is below a prescribed power level. The controller is configured to simultaneously operate the two electrical bicycle components while the power level is above the prescribed power level.

A mining vehicle and a method for an energy supply of the mining vehicle is disclosed. The mining vehicle includes at least one mining work device, at least one AC electric motor for powering the at least one mining work device, and an auxiliary energy source. The mining vehicle further includes a power electronics device that is used for supplying reactive current and for charging or discharging the auxiliary energy source. The amount of the reactive current supplied by the power electronics device and the amount of the effective charging current for charging or discharging the auxiliary energy source are controlled such that the maximum value for the current of the supply cable and the maximum value for the current of the power electronics device are not exceeded.

A vehicle includes a motor-generator unit, an energy storage system, and a high-voltage load (such as an electric compressor and/or electric heater), all interconnected via a high-voltage bus. The motor-generator unit is configured to operate in a regenerative mode and a non-regenerative mode with respect to the high-voltage bus. A control module is configured to operate the load at a first power consumption level during the regenerative mode, and to operate the high-voltage load at a second power consumption level, less than the first power consumption level, during the non-regenerative mode.

The present disclosure relates to the field of power electronics and provides a power generating system and method for a vehicle. The present disclosure provides an alternative system for charging an energy storage device that is used to drive a vehicle and also to reduce dependency of the vehicle on the energy storage device.