A vehicle is provided that comprises two or more radio frequency (RF) antennas and two or more RF transceivers to communicate wirelessly sensitive information associated with a user of the vehicle (the two or more RF antennas being at different physical locations on an exterior of the vehicle). The vehicle determines which one of the two or more RF antennas is receiving a strongest signal from a common signal source, selects a first RF transceiver associated with the RF antenna with the strongest signal to send the sensitive information associated with the user to the common signal source, and sends the sensitive information associated with the user to the first RF transceiver for transmission to the common signal source.

Provided herein is an energy delivery system for transporting electrical energy from an electrical energy generation facility to an electrical energy consumption facility via rail. The energy delivery system can comprise a train comprising at least one rail car loaded with at least one battery system. The at least one battery system can comprise an energy transfer interface for wirelessly receiving energy from the energy generation facility when the train is located at the energy generation facility for charging batteries of the battery system and for wirelessly transferring energy stored by the battery system to the energy consumption facility when the train is located at the energy consumption facility.

The adjustable crossover includes first and second cross-members, each having a central disc with two opposed arms extending radially therefrom. Each disc has a series of radial teeth on one side thereof, with the radial teeth of the two discs engaging one another to lock the arms of the two discs at an angle to one another when the two discs are locked together. The distal ends of the arms include electric line connectors to facilitate attachment of electrical power lines or cables.

In a method of operating a motor vehicle driven electrically, at least temporarily, on a roadway, the motor vehicle is moved fully autonomously by a control unit in response to a command for automatic operating mode. After a charging arm of the motor vehicle has been extended, a lateral control of the motor vehicle is executed to bring the extended charging arm into electric contact with a charging line arranged at or on the roadway. As a result, electric energy provided from the charging line to the charging arm is used for charging an energy accumulator of the motor vehicle and/or operating a drive device of the motor vehicle for moving the motor vehicle. A longitudinal control of the motor vehicle is executed to thereby maintain a predefined longitudinal speed of the motor vehicle until a distance of the motor vehicle reaches a predefined minimum distance to a leading vehicle.

A control method and system of neutral section passing of multi-locomotive short broke trains. Distance traveled by a train after a primary multiple unit enters a neutral section is calculated in real time, so that a neutral section passing procedure of a secondary multiple unit is effectively controlled, thereby solving the problem that when the multi-locomotive short broke trains operate with double-raised pantographs, if the distance between the two pantographs is shorter than the length of a neutral zone of a neutral section and longer than the length of a no-electricity zone of the neutral section, when the two pantographs pass through the neutral sections, the two pantographs will span the two neutral sections and generate an interphase short circuit. The method improves safety of the EMU when it passing neutral section and ensure that the EMU can reliably pass through the neutral section with double-raised pantographs. The present invention has the advantages of being safe, reliable, easy to implement and convenient to promote and apply.

A control method and system of neutral section passing of multi-locomotive short broke trains. Distance traveled by a train after a primary multiple unit enters a neutral section is calculated in real time, so that a neutral section passing procedure of a secondary multiple unit is effectively controlled, thereby solving the problem that when the multi-locomotive short broke trains operate with double-raised pantographs, if the distance between the two pantographs is shorter than the length of a neutral zone of a neutral section and longer than the length of a no-electricity zone of the neutral section, when the two pantographs pass through the neutral sections, the two pantographs will span the two neutral sections and generate an interphase short circuit. The method improves safety of the EMU when it passing neutral section and ensure that the EMU can reliably pass through the neutral section with double-raised pantographs. The present invention has the advantages of being safe, reliable, easy to implement and convenient to promote and apply.

Provided herein is an energy delivery system for transporting electrical energy from an electrical energy generation facility to an electrical energy consumption facility via rail. The energy delivery system can comprise a train comprising at least one rail car loaded with at least one battery system. The at least one battery system can comprise a pantograph for receiving energy from the energy generation facility when the train is located at the energy generation facility for charging batteries of the battery system and for transferring energy stored by the battery system to the energy consumption facility when the train is located at the energy consumption facility.

Provided herein is an energy delivery system for transporting electrical energy from an electrical energy generation facility to an electrical energy consumption facility via rail. The energy delivery system can comprise a train comprising at least one rail car loaded with a battery system. The battery system can comprise an energy transfer interface for receiving energy from the energy generation facility when the train is located at the energy generation facility for charging batteries of the battery system and for transferring energy stored by the battery system to the energy consumption facility when the train is located at the energy consumption facility. The energy transfer interface can be configured to receive energy from a corresponding energy transfer interface mounted to a retractable arm system of the energy generation facility and to transfer energy to a corresponding energy transfer interface mounted to a retractable arm system of the energy consumption facility.

Provided herein is an energy delivery system for transporting electrical energy from an electrical energy generation facility to an electrical energy consumption facility via rail. The energy delivery system can comprise a train comprising at least one rail car loaded with at least one battery system. The battery system can comprise an energy transfer interface for receiving energy from the energy generation facility when the train is located at the energy generation facility for charging batteries of the battery system and for transferring energy stored by the battery system to the energy consumption facility when the train is located at the energy consumption facility. The energy transfer interface can be configured to receive energy from a corresponding energy transfer interface mounted to a crane system of the energy generation facility and to transfer energy to a corresponding energy transfer interface mounted to a crane system of the energy consumption facility.

Provided herein is an energy delivery system for transporting electrical energy from an electrical energy generation facility to an electrical energy consumption facility via rail. The energy delivery system can comprise a train comprising at least one rail car loaded with at least one battery system. The at least one battery system can comprise a contactor for contacting a third rail of the energy generation facility for receiving energy when the train is located at the energy generation facility for charging batteries of the battery system and for contacting a third rail of the energy consumption facility for transferring energy stored by the battery system to the energy consumption facility when the train is located at the energy consumption facility.