A device and method controls the different energy sources for supplying a vehicle with main and auxiliary air, for which compressed air is produced for pressurizing a main air tank and an auxiliary air tank using at least one compressor. That compressor is driven via a respective associated electric motor, wherein the main air is supplied via an external primary energy source and the auxiliary air is supplied at least partially via an internal secondary energy source which is weaker in contrast. There is a shift between the two different energy sources depending on the operating status of the vehicle, wherein the auxiliary air supply is switched off by decoupling the electric motor from the secondary energy source.

A system and method for providing power to independent movers traveling along a track in a motion control system without requiring a fixed connection between the mover and a power source external to the mover. In one embodiment, a sliding transformer transfers power between the track and each mover. In another embodiment, an optical transmitter transfers power between the track and an optical receiver mounted on each mover. In yet another embodiment, a generator includes a drive wheel engaging the track as each mover travels along the track. A power converter on the mover receives the power generated on and/or transmitted to the mover to control an actuator or a sensor mounted on the mover or to activate drive coils mounted on the mover to interact with magnets mounted along the track and, thereby, control motion of each mover.

A frangible shunt link assembly includes a frangible link configured to conductively couple a current collector coupled with a vehicle and one or more components of the vehicle. The frangible link is configured to break responsive to the current collector being at least partially separated from the vehicle to interrupt a conductive connection between the current collector and the one or more components of the vehicle.

Provided is a first coil device that faces a second coil device in a facing direction, and wirelessly transmits or receives power, the first coil device including a first coil portion, and a first auxiliary magnetic member provided adjacent to the first coil portion in a first direction orthogonal to the facing direction. The first auxiliary magnetic member is configured to be closer to the second coil device with increasing distance in the first direction from the first coil portion.

Provided is a first coil device that faces a second coil device in a facing direction, and wirelessly transmits or receives power, the first coil device including a first coil portion, and a first auxiliary magnetic member provided adjacent to the first coil portion in a first direction orthogonal to the facing direction. The first auxiliary magnetic member is configured to be closer to the second coil device with increasing distance in the first direction from the first coil portion.

The vehicle is provided with a connecting member configured to connect an onboard device, a suspension member and a body frame. The connecting member includes a first fixture fixed to the suspension member, a second fixture located closer to the power storage device than the first fixture and fixed to the body frame, and a third fixture located between the first fixture and the second fixture and fixed to the onboard device. A section of the connecting member located between the first fixture and the second fixture is configured to bend downward when an external force is applied to the connecting member.

A contactless power receiving device includes: a power reception coil unit including a power reception coil configured to contactlessly receive magnetic flux sent from a power supply coil; iron bolts fixing the power reception coil unit to a vehicle body; and a magnetic shield plate configured to suppress diffusion of the magnetic flux received by the power reception coil unit to surroundings. The magnetic shield plate is arranged below all of the iron bolts.

Provided is a collected current monitoring device enabling an analysis of collected current in each current collector while allowing a reduced equipment cost. The collected current monitoring device of the present disclosure is installed in a railroad vehicle including current collectors, main transformers, and main converters. The collected current monitoring device includes: a supply current sensor configured to measure a current supplied to a freely-selected one of the main transformers, at least one current-sensor-between-current-collectors disposed in each communication path connecting two adjacent ones of the current collectors and configured to measure a current flowing in the communication path, and a processor configured to calculate a current flowing in each of the current collectors based on the current measured by the supply current sensor and the current measured by the at least one current-sensor-between-current-collectors, and on a distribution ratio of the currents supplied to the main transformers.

The article transport vehicle travels with its wheel rolling on the travel surface provided on the upper surface of the travel rail. The travel rail has a peripheral wall that includes a surface on which the travel surface is formed, and an internal space that is enclosed by the peripheral wall, and extends along the travel path. The travel surface has a through hole that passes through the peripheral wall, and brings the internal space into communication with an external space. The travel rail is provided with a suction device that is in communication with the internal space, and is configured to suck air in the internal space. The internal space is closed except for the through hole, and a connection portion for the suction device.

The article transport vehicle travels with its wheel rolling on the travel surface provided on the upper surface of the travel rail. The travel rail has a peripheral wall that includes a surface on which the travel surface is formed, and an internal space that is enclosed by the peripheral wall, and extends along the travel path. The travel surface has a through hole that passes through the peripheral wall, and brings the internal space into communication with an external space. The travel rail is provided with a suction device that is in communication with the internal space, and is configured to suck air in the internal space. The internal space is closed except for the through hole, and a connection portion for the suction device.