A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. Opposite ends of a roadside barrier contain complementary tubular couplers arranged vertically. A lower end of a dielectric post positioned in one of the tubular couplers has opposing dielectric plates at an upper end. A top edge of each plate has a creepage concavity between a pair of rail recesses. Another dielectric post of similar configuration is positioned in the other of the tubular couplers. Holes within the couplers and the posts ensure alignment of respective rail recesses in which conductive rails are placed. Dielectric inserts frictionally lock the rails into the rail recesses.

A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. Opposite ends of a roadside barrier contain complementary tubular couplers arranged vertically. A lower end of a dielectric post positioned in one of the tubular couplers has opposing dielectric plates at an upper end. A top edge of each plate has a creepage concavity between a pair of rail recesses. Another dielectric post of similar configuration is positioned in the other of the tubular couplers. Holes within the couplers and the posts ensure alignment of respective rail recesses in which conductive rails are placed. Dielectric inserts frictionally lock the rails into the rail recesses.

A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. Opposite ends of a roadside barrier contain complementary tubular couplers arranged vertically, one having a first diameter supported by an arm and the other having a larger second diameter and a vertical slot. Couplers on adjacent barriers can be mated together concentrically along a central axis. The mated couplers help restrict longitudinal displacement, lateral displacement, slope change, and lateral rotation between adjacent barriers during placement. One barrier may be used as a temporary alignment structure to position barriers spaced altematingly along a haul route for the work machine.

A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. Opposite ends of a roadside barrier contain complementary tubular couplers arranged vertically, one having a first diameter supported by an arm and the other having a larger second diameter and a vertical slot. Couplers on adjacent barriers can be mated together concentrically along a central axis. The mated couplers help restrict longitudinal displacement, lateral displacement, slope change, and lateral rotation between adjacent barriers during placement. One barrier may be used as a temporary alignment structure to position barriers spaced altematingly along a haul route for the work machine.

A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. End portions of rail segments having narrower widths than body portions of the rail segments are joined within a split fishplate. Laterally opposing faces within the narrowed end portions form a longitudinal overlap, and connectors underneath the rail segments pull the split fishplate together against the end portions. In arrangements with parallel rails around a curvature, the rail segments are adjusted by sliding so that the longitudinal overlap is larger for rails on an inside of the curvature compared with rails on an outside of the curvature.

A modular structure supports elevated rail segments for delivering electrical power to a moving work machine, such as a hauler at a mining site. End portions of rail segments having narrower widths than body portions of the rail segments are joined within a split fishplate. Laterally opposing faces within the narrowed end portions form a longitudinal overlap, and connectors underneath the rail segments pull the split fishplate together against the end portions. In arrangements with parallel rails around a curvature, the rail segments are adjusted by sliding so that the longitudinal overlap is larger for rails on an inside of the curvature compared with rails on an outside of the curvature.

The rigid T-rail conductor system is configured to support a contact wire in an overhead railway electrification system. The rigid T-rail includes a first rail configured to be disposed in an overhead position of the railway electrification system. The rigid rail includes a keeper disposed on a side of the first rail, the keeper configured to be movable. When the keeper is in the first position, the keeper holds and affixes the wire on the first rail. When the keeper is in the second position, the keeper allows the wire to be installed or to be removed from the rail.

A mobile solar charging facility. The present invention relates to power supply and charging techniques for a mobile electric apparatus during movement, and in particular to such a facility having a combined technique of a solar photovoltaic battery and solar thermal power generation, and matching techniques and extended applications related to light compensation, energy storage, etc. The present invention is aimed at solving the problem of charging an electric vehicle when traveling. A highly cost-effective solar power source is used for power supply. The technical solutions of a contact rail and a collector shoe are used for mobile power supply and charging. An arc extinction circuit and an energy storage super-capacitor are provided in a line, and a safety protection measure is provided. A condenser lens and a compensation lens which can increase a power generation amount and do not need to be tracked as provided for solar power generation.

The invention relates to a line section for the operation of electrically driven rail vehicles, with a track which exhibits two parallel rails, with a contact line borne by an insulator, said contact line being arranged on one side of the track in a spatial region extending parallel to the rails, wherein the contact line is intended to supply current-collectors of the electrically driven rail vehicles with current and to support said current-collectors from underneath, and wherein the contact line and the insulator bearing the contact line are intermittently interrupted or not interrupted.

The invention is distinguished in that a support device which is non-functional for the power supply of the rail vehicle is arranged on the other side of the track in a second spatial region extending parallel to the rails, said support device being intended to support current-collectors of the electrically driven rail vehicles from underneath without supplying them with current.

The invention relates to a line section for the operation of electrically driven rail vehicles, with a track which exhibits two parallel rails, with a contact line borne by an insulator, said contact line being arranged on one side of the track in a spatial region extending parallel to the rails, wherein the contact line is intended to supply current-collectors of the electrically driven rail vehicles with current and to support said current-collectors from underneath, and wherein the contact line and the insulator bearing the contact line are intermittently interrupted or not interrupted.

The invention is distinguished in that a support device which is non-functional for the power supply of the rail vehicle is arranged on the other side of the track in a second spatial region extending parallel to the rails, said support device being intended to support current-collectors of the electrically driven rail vehicles from underneath without supplying them with current.