The invention relates to a shoe (10) on an electrical power supply track for an electric railway vehicle, the shoe (10) comprising: a power supply flange (12) movable between a retracted position and a deployed position; an actuator (11) able to move the flange between the retracted and deployed positions; and a mechanical system (13) connecting the flange to the actuator;
characterized in that the actuator (11): has a movement speed such that it is able to move the flange (12) between its retracted and deployed positions in a time period shorter than or equal to 1 second, and preferably shorter than or equal to 0.5 seconds; and has a number of operating cycles before failure greater than or equal to 2,500,000.

A conveying car comprises at least one support frame in which at least one driven conveying element is arranged, and a current collector for energizing drive means for driving the at least one conveying element and driving the conveying car; said conveying car is characterized in that same has its own power supply that is independent of the central power supply used for normal operation of the conveying car.

A conveying car comprises at least one support frame in which at least one driven conveying element is arranged, and a current collector for energizing drive means for driving the at least one conveying element and driving the conveying car; said conveying car is characterized in that same has its own power supply that is independent of the central power supply used for normal operation of the conveying car.

A current-collector arrangement for a vehicle, said arrangement includes a current collector with a contact shoe for collecting current from a conductor rail, wherein the current collector is connected to the vehicle in sprung fashion where, in order to create advantageous design conditions, the current collector and the vehicle should have arranged between them a carrier, which is connected to the vehicle via a first spring and a second spring and also a joint, and where the first spring and the second spring should each have at least one reserve spring-length region for extraordinary deflections of the current collector, and where absolute values of the extraordinary deflections exceed absolute values of ordinary deflections of the current collector such that a deflection of the current collector achieved in an extraordinary operating state is reversible and need not be restored manually.

A current-collector arrangement for a vehicle, said arrangement includes a current collector with a contact shoe for collecting current from a conductor rail, wherein the current collector is connected to the vehicle in sprung fashion where, in order to create advantageous design conditions, the current collector and the vehicle should have arranged between them a carrier, which is connected to the vehicle via a first spring and a second spring and also a joint, and where the first spring and the second spring should each have at least one reserve spring-length region for extraordinary deflections of the current collector, and where absolute values of the extraordinary deflections exceed absolute values of ordinary deflections of the current collector such that a deflection of the current collector achieved in an extraordinary operating state is reversible and need not be restored manually.

A transport system has a wheeled, steerable, self-powered, self-navigating carrier vehicle, having a substantially planar support frame, an on-board, rechargeable, battery-based power system, control circuitry, including GPS circuitry, on-board the carrier vehicle, adapted to drive and steer the carrier vehicle, and an upward-facing carrier interface adapted to the support frame, the carrier interface having first physical engagement elements, and a passenger pod adapted to carry both packages and persons, the passenger pod having a structural framework, a rechargeable, battery-based power system, and a downward-facing pod interface adapted to the structural framework, the carrier interface having second physical engagement elements. The passenger pod, placed upon the carrier vehicle, engages the downward-facing pod interface to the upward-facing carrier interface by the first and second physical engagement elements.

A transport system has a wheeled, steerable, self-powered, self-navigating carrier vehicle, having a substantially planar support frame, an on-board, rechargeable, battery-based power system, control circuitry, including GPS circuitry, on-board the carrier vehicle, adapted to drive and steer the carrier vehicle, and an upward-facing carrier interface adapted to the support frame, the carrier interface having first physical engagement elements, and a passenger pod adapted to carry both packages and persons, the passenger pod having a structural framework, a rechargeable, battery-based power system, and a downward-facing pod interface adapted to the structural framework, the carrier interface having second physical engagement elements. The passenger pod, placed upon the carrier vehicle, engages the downward-facing pod interface to the upward-facing carrier interface by the first and second physical engagement elements.

A method is provided for controlling a vehicle safety system in a vehicle provided with a current collector arranged to transmit electric power from a current conductor in the surface of a road. The current collector is controllable for vertical and transverse displacement relative to a longitudinal axis of the vehicle to contact and track the current conductor. The safety system includes at least one forward looking data collecting system for detecting obstacles on the road prior to impact with the current collector; and an electronic control unit for controlling at least power transmission and displacement of the current collector. The method involves performing the steps of detecting that an obstacle is located in the path of the current collector; transmitting data from the forward looking data collecting system to the electronic control unit; performing an object classification to determine a damage level for the dynamic charging system; determining an action to be taken by the safety system based on the determined damage level; and initiating the action in dependence of at least the determined damage level.

The invention relates to a current collector system (1) for a vehicle (F) which can be moved in a longitudinal direction along a power rail arrangement (S) having at least one current collector trolley (3) and current collector contacts (5) arranged on this, which current collector contacts can be connected to the power rails (ST) of the power rail arrangement (S) and a telescopic arm (2) which can be fixed or is fixed to a vehicle (F), which telescopic arm can be extended and/or retracted by means of an adjustment drive, characterised in that the adjustment drive has at least one rigid chain arrangement (9) which is driven by at least a first rigid chain drive (8).

The invention relates to a current collector system (1) for a vehicle (F) which can be moved in a longitudinal direction along a power rail arrangement (S) having at least one current collector trolley (3) and current collector contacts (5) arranged on this, which current collector contacts can be connected to the power rails (ST) of the power rail arrangement (S) and a telescopic arm (2) which can be fixed or is fixed to a vehicle (F), which telescopic arm can be extended and/or retracted by means of an adjustment drive, characterised in that the adjustment drive has at least one rigid chain arrangement (9) which is driven by at least a first rigid chain drive (8).