A power conversion controller for electric train in one aspect of the present disclosure includes an active current command value generator, an overhead line voltage detector, an initial value calculator, an adjustment value calculator, an upper limit value setter, and an output limiter. The output limiter outputs a reactive current command adjustment value calculated by the adjustment value calculator as a reactive current command value when the reactive current command adjustment value is equal to or lower than an upper limit value set by the upper limit value setter, and outputs the upper limit value as the reactive current command value when the reactive current command adjustment value exceeds the upper limit value.

A power conversion controller for electric train in one aspect of the present disclosure includes an active current command value generator, an overhead line voltage detector, an initial value calculator, an adjustment value calculator, an upper limit value setter, and an output limiter. The output limiter outputs a reactive current command adjustment value calculated by the adjustment value calculator as a reactive current command value when the reactive current command adjustment value is equal to or lower than an upper limit value set by the upper limit value setter, and outputs the upper limit value as the reactive current command value when the reactive current command adjustment value exceeds the upper limit value.

A car control device according to an embodiment includes a converter and an inverter, a first contactor disposed between the transformer and the converter, a second contactor and a resistor connected in series with each other and in parallel with the first contactor, a first voltage detector and a second voltage detector disposed between the converter and the inverter, and a control unit. After the second contactor is closed and before the first contactor is closed, the control unit calculates a voltage difference between a first voltage value detected by the first voltage detector and a second voltage value detected by the second voltage detector, compares the calculated voltage difference with a predefined threshold value, and determines that at least one of the first voltage detector and the second voltage detector malfunctions when the voltage difference is greater than the threshold value.

A car control device according to an embodiment includes a converter and an inverter, a first contactor disposed between the transformer and the converter, a second contactor and a resistor connected in series with each other and in parallel with the first contactor, a first voltage detector and a second voltage detector disposed between the converter and the inverter, and a control unit. After the second contactor is closed and before the first contactor is closed, the control unit calculates a voltage difference between a first voltage value detected by the first voltage detector and a second voltage value detected by the second voltage detector, compares the calculated voltage difference with a predefined threshold value, and determines that at least one of the first voltage detector and the second voltage detector malfunctions when the voltage difference is greater than the threshold value.

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.

The invention relates to a device and a method for adjusting an inductance of at least one electric conductor. The device includes an adjustment arrangement with a first magnetically conductive element and at least a second magnetically conductive element. The adjustment arrangement includes at least a first spacer element arranged in between the first magnetically conductive element and the second magnetically conductive element.

In this power converter for a railroad vehicle, a cooling portion includes a first cooling portion arranged to block up an opening while ensuring watertightness and to come into contact with a semiconductor element through the opening, and a second cooling portion provided to be opposed to an outer surface of a power converter body not provided with the opening and adjacent to a side provided with the first cooling portion.

In this power converter for a railroad vehicle, a cooling portion includes a first cooling portion arranged to block up an opening while ensuring watertightness and to come into contact with a semiconductor element through the opening, and a second cooling portion provided to be opposed to an outer surface of a power converter body not provided with the opening and adjacent to a side provided with the first cooling portion.

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.

A high voltage device for a vehicle, which at least during driving operation is supplied with electric energy from a power system providing a high voltage, having at least one high voltage component which by a main power switching unit is electrically connectable to the power system and a grounding switching device having at least one switching device. In order to increase personal safety during work on the high voltage device in a constructively simple manner, it is proposed that the high voltage component has at least one receiving region in which the switching device is accommodatedat least in a grounding position that grounds at least one active section of the high voltage component.