Provided is a collected current monitoring device. A transformer current acquisition unit acquires a current value I.sub.p of a current flowing through a part of a plurality of transformers. A total collected current calculation unit calculates a current value I.sub.all of a collected current supplied by a plurality of current collectors from the current value I.sub.p by using a following Equation (1): I.sub.all=I.sub.p(M.sub.all/M.sub.p). A collected current acquisition unit acquires a current value I.sub.X of a collected current supplied by the current collector(s) other than one current collector. The collected current calculation unit calculates a current value I.sub.Y of a collected current supplied by the one current collector by subtracting the current value I.sub.X from the current value I.sub.all.

An assembly includes a movable door assembly and a heating element. The movable door assembly is configured to be disposed on an exterior of a vehicle. The heating element is coupled to the movable door assembly, and is configured to receive energy from a battery disposed on the vehicle and to heat at least a portion of the movable door assembly.

A third rail paddle system includes a support assembly configured for attachment to a vehicle, a pivot connection attached to the support assembly and that defines a range of up and down movement, and a third rail paddle assembly having an arm unit and a paddle. The paddle assembly is attached to the pivot connection for the paddle to contact a third rail and move up and down relative to the third rail when the support assembly is attached to the vehicle. One of the pivot connection, the paddle assembly, or the support assembly includes a stop element that limits the range of the up and down movement and prevents the paddle assembly from moving downwards to a bottom of the range of movement.

A third rail paddle system includes a support assembly configured for attachment to a vehicle, a pivot connection attached to the support assembly and that defines a range of up and down movement, and a third rail paddle assembly having an arm unit and a paddle. The paddle assembly is attached to the pivot connection for the paddle to contact a third rail and move up and down relative to the third rail when the support assembly is attached to the vehicle. One of the pivot connection, the paddle assembly, or the support assembly includes a stop element that limits the range of the up and down movement and prevents the paddle assembly from moving downwards to a bottom of the range of movement.

Systems and methods for controlling operation of a vehicle system are provided. This vehicle system can be at least partially powered by electric current conducted to a collector device of the vehicle system from a conductive pathway extending along a route traveled by the vehicle system. A voltage level of the conductive pathway may be monitored, and a conduction impaired location of the conductive pathway may be identified based at least in part on the voltage level of the conductive pathway that is monitored. The collector device or a removal device may be controlled to remove a contaminant from the conductive pathway at the conduction impaired location, the vehicle system may be controlled to compensate for the conduction impaired location, and/or an off-board facility and/or another vehicle system may be notified of the conduction impaired location responsive to identifying the conduction impaired location.

An electric vehicle charging system includes a charging interface positioned on an external surface of the electric vehicle and one or more electrodes positioned on the charging interface. The charging system may also include a heating system positioned on the charging interface. The heating system may be configured to heat at least a portion of the charging interface. The charging system may also include a control system configured to selectively activate the heating system based at least on one or more ambient conditions.

An electric vehicle charging system includes a charging interface positioned on an external surface of the electric vehicle and one or more electrodes positioned on the charging interface. The charging system may also include a heating system positioned on the charging interface. The heating system may be configured to heat at least a portion of the charging interface. The charging system may also include a control system configured to selectively activate the heating system based at least on one or more ambient conditions.

A method for controlling the temperature of a changing cable of a fast charging station for fast charging a battery of a vehicle with en electric drive. The method includes the steps of heating the charging cable in order to form an electrical connection of the charging cable to the vehicle, sensing connection of the charging cable to the vehicle, and ending the heating of the charging cable for fast charging the battery of the vehicle. A fast charging station has a charging cable for fast charging a battery of a vehicle with an electric drive. The fast charging station is designed to carry out the above method for controlling the temperature of a charging cable

A method for controlling the temperature of a changing cable of a fast charging station for fast charging a battery of a vehicle with en electric drive. The method includes the steps of heating the charging cable in order to form an electrical connection of the charging cable to the vehicle, sensing connection of the charging cable to the vehicle, and ending the heating of the charging cable for fast charging the battery of the vehicle. A fast charging station has a charging cable for fast charging a battery of a vehicle with an electric drive. The fast charging station is designed to carry out the above method for controlling the temperature of a charging cable

One aspect of this disclosure relates to an electrified vehicle including a heater element at least partially insert-molded with a charging port. In another aspect of this disclosure, the charging port includes a polymer material having a thermal conductivity greater than about 10 watts per meter-Kelvin (W/m-K). A method is also disclosed.