A railway direct-current system according to the present invention is provided with: a feeding line that is connected to a plurality of electric power substations arranged along a railway; and a trolley line that is connected to the feeding line via feeding branch lines at an arbitrarily defined interval, wherein a superconductive feeding cable is connected to somewhere midway in each of railroad lines extending from the substations to the trolley line via the feeding lines, so as to be parallel with the railroad line.

In a trolley-wire display device, a display reference point of point-group data is set for each point on a trolley wire having a height and a displacement measured based on a reference obtained from rails. First and second points on a track center line are used to calculate a first distance, and a third distance based on the first distance and a second distance. The first point corresponds to the display reference point. The second point corresponds to each point on the trolley wire. The first distance is a distance from the first point to each second point. The second distance is a distance from a positional start point to the first point. The third distance is a distance from the start point to each second point, and is used to create display data for displaying a height and a displacement of each point on the trolley wire.

In a trolley-wire display device, a display reference point of point-group data is set for each point on a trolley wire having a height and a displacement measured based on a reference obtained from rails. First and second points on a track center line are used to calculate a first distance, and a third distance based on the first distance and a second distance. The first point corresponds to the display reference point. The second point corresponds to each point on the trolley wire. The first distance is a distance from the first point to each second point. The second distance is a distance from a positional start point to the first point. The third distance is a distance from the start point to each second point, and is used to create display data for displaying a height and a displacement of each point on the trolley wire.

A monitor vehicle for a rail system includes a wheeled trolley, an overhead vehicle, a supporting structure, and a first sensor. The wheeled trolley is above a rail of the rail system, is operable to move over the rail, and has a bottom surface. The overhead vehicle body is suspended by the wheeled trolley and below the rail. The supporting structure connects the wheeled trolley and the overhead vehicle body. The first sensor is on the bottom surface of the wheeled trolley and is configured to detect a first parameter of the rail of the rail system.

A monitor vehicle for a rail system includes a wheeled trolley, an overhead vehicle, a supporting structure, and a first sensor. The wheeled trolley is above a rail of the rail system, is operable to move over the rail, and has a bottom surface. The overhead vehicle body is suspended by the wheeled trolley and below the rail. The supporting structure connects the wheeled trolley and the overhead vehicle body. The first sensor is on the bottom surface of the wheeled trolley and is configured to detect a first parameter of the rail of the rail system.

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.

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 power converter to be mounted to a mounting portion of a host in a suspended manner includes a plurality of component-housing chassis configured to be connected together parallel to the mounting portion, the plurality of component-housing chassis each containing parts for a power converter so that the plurality of component-housing chassis collectively constitute the power converter for the host, wherein at least one of the plurality of component-housing chassis has a support frame, the support frame protruding out so as to extend into at least an adjacent one of the component-housing chassis, wherein the at least adjacent one of the component-housing chassis has an insertion hole for inserting the support frame, and wherein the support frame is configured to be inserted into the insertion hole in the adjacent component-housing chassis and fixed to the adjacent component-housing chassis.

A power converter to be mounted to a mounting portion of a host in a suspended manner includes a plurality of component-housing chassis configured to be connected together parallel to the mounting portion, the plurality of component-housing chassis each containing parts for a power converter so that the plurality of component-housing chassis collectively constitute the power converter for the host, wherein at least one of the plurality of component-housing chassis has a support frame, the support frame protruding out so as to extend into at least an adjacent one of the component-housing chassis, wherein the at least adjacent one of the component-housing chassis has an insertion hole for inserting the support frame, and wherein the support frame is configured to be inserted into the insertion hole in the adjacent component-housing chassis and fixed to the adjacent component-housing chassis.

A power converter includes a chassis having attached thereto a holding fixture for mounting the chassis to a mounting portion in a suspended manner. The holding fixture includes a first member attached to a first surface of the chassis which faces the mounting portion, and a second member attached to the first member and a second surface of the chassis that adjoins the first surface.