A positioning unit and method for forming an electrically conductive connection between a stationary charging station and a vehicle, wherein an electrical charging contact of a positioning unit is movable relative to a charging contact surface and contacted by the positioning unit having an articulated arm device and a corresponding drive device, wherein the charging contact includes a contact position for power transmission and a retracted position for power interruption, the drive device having an adjustment drive acting on the articulated arm device and a spring device wherein a contact force acting on the charging contact surface can be formed by the adjustment drive having a control device and an electric motor actuated by the control device, wherein the adjustment drive is designed such that a torque of the electric motor is detected by the control device, and the contact force controlled by the control device based on the torque.

An electric drive dump truck travels by contacting, with trolley lines, power collection units configured to be moved up and down by lifting devices and receiving electrical power from the trolley lines. A position detection device is configured to detect a position of the electric drive dump truck; a vehicle speed detection device is configured to detect a vehicle speed of the electric drive dump truck; and a storage section is configured to store a position of the trolley lines and a time (hereinafter referred to as a moving-up time) until the power collection units contact with the trolley lines since the power collection units start moving up. A control device is configured to output a signal indicating that the power collection units can be moved up based on the position and vehicle speed of the electric drive dump truck, the position of the trolley lines, and the moving-up time.

An electric drive dump truck travels by contacting, with trolley lines, power collection units configured to be moved up and down by lifting devices and receiving electrical power from the trolley lines. A position detection device is configured to detect a position of the electric drive dump truck; a vehicle speed detection device is configured to detect a vehicle speed of the electric drive dump truck; and a storage section is configured to store a position of the trolley lines and a time (hereinafter referred to as a moving-up time) until the power collection units contact with the trolley lines since the power collection units start moving up. A control device is configured to output a signal indicating that the power collection units can be moved up based on the position and vehicle speed of the electric drive dump truck, the position of the trolley lines, and the moving-up time.

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.

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 method for testing whether a current collector of a vehicle, which is preferably not rail-bound and is driven by an electric motor, is in contact with a contact wire of an overhead line which extends in a direction of travel. The current collector, which can be moved along a vertical direction, has a carrier element and a contact strip, resiliently mounted on the carrier element by a primary spring element. The contact strip, upon contacting the contact wire, is deflected relative to the carrier element counter to the vertical direction out of a resting position, wherein the deflection is detected by a sensor unit and it is determined whether the contact strip is in contact with the contact wire. There is also described a corresponding current collector.

A method for testing whether a current collector of a vehicle, which is preferably not rail-bound and is driven by an electric motor, is in contact with a contact wire of an overhead line which extends in a direction of travel. The current collector, which can be moved along a vertical direction, has a carrier element and a contact strip, resiliently mounted on the carrier element by a primary spring element. The contact strip, upon contacting the contact wire, is deflected relative to the carrier element counter to the vertical direction out of a resting position, wherein the deflection is detected by a sensor unit and it is determined whether the contact strip is in contact with the contact wire. There is also described a corresponding current collector.

An electrified road transport system includes a contact line system having a plurality of masts with support cables and contact wires suspended thereon. The contact line system has structural modifications for reducing the horizontal and/or vertical positional tolerances of the contact wires. In the context of the structural modifications, section separators are fastened directly to masts or to cantilevers of the masts, skewed overhead lines are disposed in straight section segments and/or in curves, and the support cables and/or contact wires have smaller cross-sections and/or higher longitudinal tensile forces. A method for stabilizing a contact line system of an electrified road transport system is also provided.

A method for monitoring a pantograph. The method includes acquiring an impulse response of the pantograph, extracting a natural frequency and a damping coefficient of the pantograph from the impulse response, obtaining a similarity factor of a plurality of similarity factors, and detecting a fault in the pantograph from the plurality of fault types based on the plurality of the similarity factors. Acquiring an impulse response of the pantograph includes generating the impulse response by tapping the head of the pantograph and recording the impulse response utilizing a recording equipment.

A method for monitoring a pantograph. The method includes acquiring an impulse response of the pantograph, extracting a natural frequency and a damping coefficient of the pantograph from the impulse response, obtaining a similarity factor of a plurality of similarity factors, and detecting a fault in the pantograph from the plurality of fault types based on the plurality of the similarity factors. Acquiring an impulse response of the pantograph includes generating the impulse response by tapping the head of the pantograph and recording the impulse response utilizing a recording equipment.