An electrified railway power supply system without negative sequence in the whole process and without power supply networks at intervals, can comprise an external power supply system, an input power supply system from external to internal, and an internal power supply system. For external power supply, single-phase power supply is changed to double-phase power supply, and power of a single phase is input to the power supply system within the train via a contactor on a left arm and a right arm of a double-phase pantograph. No neutral section for passing of phase separation is provided in the whole process of operation, and a plurality of sections in the whole process are provided with no power supply network at intervals, and the motor train unit can operate normally without mechanical support for the power supply network.

An electrified railway power supply system without negative sequence in the whole process and without power supply networks at intervals, can comprise an external power supply system, an input power supply system from external to internal, and an internal power supply system. For external power supply, single-phase power supply is changed to double-phase power supply, and power of a single phase is input to the power supply system within the train via a contactor on a left arm and a right arm of a double-phase pantograph. No neutral section for passing of phase separation is provided in the whole process of operation, and a plurality of sections in the whole process are provided with no power supply network at intervals, and the motor train unit can operate normally without mechanical support for the power supply network.

According to one embodiment, a vehicle controller includes an electric power converter, a plurality of first electric power transmission members, a temperature sensor, and a first controller. The electric power converter converts input electric power and outputs the converted electric power. The plurality of first electric power transmission members transmit the input electric power and are connected in parallel to the electric power converter. The temperature sensor is connected to at least one of the plurality of first electric power transmission members. The first controller determines that at least one of the plurality of first electric power transmission members is disconnected when a temperature detected by the temperature sensor changes.

A method and a device test whether there is contact between a current collector and a contact wire of an overhead line. The current collector is located on a motor vehicle driven by an electric motor, and the contact wire extends in a direction of travel. The current collector has two contact regions oriented transversely to the direction of travel which are arranged one behind the other in the direction of travel and on each of which an end contact element is located. A pair of end contact elements located on the same side is connected to a measuring device and an electrical state variable is detected by the measuring device. Subsequently, it is determined in accordance with the detected state variable whether the pair of end contact elements is in contact with the overhead line.

A vehicle starting system according to the present invention includes: an ATC as an automatic train controller that, on the basis of a start instruction received from an OCC as a central command device on the ground, starts a TCMS as an integrated train management system mounted on a train; and the TCMS performs control to supply power to a first vehicle device, and further performs control to supply power to a second vehicle device by raising a pantograph and then closing a VCB as a vacuum circuit breaker, and converting a voltage of alternating-current power acquired from an overhead contact line via the pantograph and the VCB.

A vehicle starting system according to the present invention includes: an ATC as an automatic train controller that, on the basis of a start instruction received from an OCC as a central command device on the ground, starts a TCMS as an integrated train management system mounted on a train; and the TCMS performs control to supply power to a first vehicle device, and further performs control to supply power to a second vehicle device by raising a pantograph and then closing a VCB as a vacuum circuit breaker, and converting a voltage of alternating-current power acquired from an overhead contact line via the pantograph and the VCB.

The present invention relates to a monitoring device for monitoring catenary-pantograph interaction in a railway vehicle (100) comprising a frequency-tunable radio receiver module (2) with its associated antenna (1) for the reception of radio signals (500) emitted by pantograph-catenary interaction in the radio frequency and microwave bands; and a control module (4) for detecting electric arcs (400) in the radio signal (500) received by the radio receiver (2) within at least one of the tuned bands. Information about the detected arcs (400) can be stored in the storage module (3) and used to generate records and/or alarms sent by a communication module (6). The radio receiver module (2) can be accompanied, in an input-output module (9) to facilitate pantograph monitoring and maintenance, by a pantograph current measurement module (8) and an odometry and positioning module (7) to obtain the position and speed of the vehicle.

The present invention relates to a monitoring device for monitoring catenary-pantograph interaction in a railway vehicle (100) comprising a frequency-tunable radio receiver module (2) with its associated antenna (1) for the reception of radio signals (500) emitted by pantograph-catenary interaction in the radio frequency and microwave bands; and a control module (4) for detecting electric arcs (400) in the radio signal (500) received by the radio receiver (2) within at least one of the tuned bands. Information about the detected arcs (400) can be stored in the storage module (3) and used to generate records and/or alarms sent by a communication module (6). The radio receiver module (2) can be accompanied, in an input-output module (9) to facilitate pantograph monitoring and maintenance, by a pantograph current measurement module (8) and an odometry and positioning module (7) to obtain the position and speed of the vehicle.

A system for monitoring electrical contacts for an overhead trolley line may include a wear sensor arranged such that an electrical contact on a vehicle or work machine for contacting the overhead trolley line is continually or periodically in its line of sight. The wear sensor may be configured to capture spatial data defining the surface profile of the electrical contact. The system may also include a data processing module configured to receive the spatial data and identify a defect in the electrical contact based on the spatial data.

A system for monitoring electrical contacts for an overhead trolley line may include a wear sensor arranged such that an electrical contact on a vehicle or work machine for contacting the overhead trolley line is continually or periodically in its line of sight. The wear sensor may be configured to capture spatial data defining the surface profile of the electrical contact. The system may also include a data processing module configured to receive the spatial data and identify a defect in the electrical contact based on the spatial data.