This invention relates to a vehicle power coupling apparatus for a vehicle. The apparatus has a pickup coil arrangement for receiving an alternating magnetic field applied to the vehicle for generating power to operate the vehicle. The apparatus further has a shield for shielding a region including the pickup coil arrangement from an interior of the vehicle where a user of the vehicle may be present when the vehicle is in operation, and the shield includes at least one hole therein for providing access to one or more components of the vehicle for working on the one or more components. Additional aspects of the invention relate to receiving an alternating magnetic field and converting the alternating magnetic field into electrical power for recharging a vehicle and/or for providing motive power to the vehicle.

A dynamic wireless power transfer system performs, through a plurality of primary coils installed along a traveling direction of a road and a secondary coil mounted in a vehicle, power transfer to the vehicle while the vehicle is traveling. The secondary coil is an M-phase coil including M coils, M denoting an integer which is two or higher. The M coils each include a coil end extending along a front-rear direction of the vehicle and a main coil portion extending along a width direction of the vehicle, the M coils each being configured such that a magnetic resistance of a magnetic path where a magnetic flux of the coil end passes is higher than a magnetic resistance of a magnetic path where a magnetic flux of the main coil portion passes.

A driving assistance apparatus includes an information acquiring unit and a determining unit. The information acquiring unit is configured to acquire a target value of a power storage amount in an onboard battery mounted on a vehicle. The determining unit is configured to determine one or more charging implementation lanes out of charging lanes that are traveling lanes provided on a travel route of the vehicle to an expected arrival location, apart from each other along a direction of the travel route, and configured to charge the onboard battery while the vehicle is traveling. The one or more charging implementation lanes are part of the charging lanes to implement charging of the onboard battery. The determining unit is configured to determine, on the basis of the target value of the power storage amount, the one or more charging implementation lanes to minimize a number of times of the charging of the onboard battery.

An independent cart system includes an inductive link for contactless power transfer between a track and each mover as the mover travels along the track. A system for contactless data transmission between movers and a controller in the independent cart system includes a transmitter and/or receiver mounted on each mover and a complementary receiver and/or transmitter mounted on a track. The transmitter receives data to be transmitted across the inductive link and modulates a voltage present on either the primary or secondary winding to which it is coupled. The modulated voltage present on one winding induces a corresponding modulation on the voltage present on the other winding. A receiver operatively connected to the other side of the inductive link detects the modulated voltage and decodes the data from the modulated voltage received across the inductive link.

Systems and methods for charging an electric bus having a charging interface on its roof may include determining that an approaching bus is supposed to be charged at the charging station, lowering the charging head of the charging station to land on the roof of the bus, and moving the bus with the charge head on its roof to engage the charging head with the charging interface.

A vehicle power supply system is configured to supply power to a vehicle from a power supply apparatus laid on a power supply lane of a vehicle travel path, the power supply apparatus includes a plurality of power supply segments laid in a preset interval along the power supply lane, and a controller configured to control the plurality of power supply segments. The controller is configured to estimate timing of the vehicle reaching a next power supply segment that supplies power next after a present power supply segment that is supplying power, from at least a vehicle velocity derived from a change in position of the vehicle, and cause the next power supply segment to start power supply at the timing estimated.

A system and method for varying an amplitude of voltage on a DC bus by track segment in a linear drive system for an independent cart system according to application requirements is disclosed. The track includes at least a first portion and a second portion, where a DC voltage at a first amplitude is provided to the first portion of the track, and a DC voltage at a second amplitude is provided to the second portion of the track. The first amplitude of the DC voltage is selected to permit movers traveling along the track to travel at full rated speed with a full rated three applied to the mover. The second amplitude of the DC voltage is selected to permit the movers to travel at a reduced speed with full or increased three applied or to travel at full rated speed with a reduced force applied to the mover.

An apparatus comprises a first induction section comprising a first core and a first coil on the first core. A second induction section comprises a second core and a second coil on the second core. The first core comprises rail extensions, where at least two of the rail extensions extend from opposite ends of the first core. The second core comprises shoe portions located at respective ones of the rail extensions, where a gap is provided between each of the rail extensions and respective ones of the shoe portion. The second induction section is configured to move relative to the first induction section in a path along the extensions. The first induction section is configured to induce current in the second induction section, including when the second core moves relative to the first core along the extensions, to provide a contactless induction coupling between the first induction section and the second induction section.

The present disclosure relates to an automatic transportation system that moves along a rail and is powered by induction feeding, and more particularly, to a terminal block configured to facilitate installation and extension of a cable for a configuration of an induction power track and to prevent a fire accident due to overheating in advance by an overheat detection unit provided therein and an automatic transportation system using the same.

A contactless power feeding system includes: a power feeding device including a plurality of power feeding coils along a road, and configured to transmit electric power to a power receiving coil of an electric vehicle in a contactless manner; a receiver configured to receive traffic congestion information of the road; and an electronic control unit configured to: control transmission power transmitted from each of the plurality of power feeding coils to the power receiving coil, and control the power feeding device such that the transmission power of one or more power feeding coils located in a congestion occurrence section is higher than the transmission power of one or more power feeding coils located in a non-congestion occurrence section, wherein each of the congestion occurrence section and the non-congestion occurrence section are along a portion of the road including the plurality of power feeding coils.