The invention described refers to an equipment and corresponding method that enables side sliding load transfer between one vehicle/structure acting as loader, and another vehicle/structure acting as receptor. Both loaders and receptors can be vehicles or piers using a side sliding loading system that includes lifting and lateral displacement equipment. The great innovation of this system is the appearing of carriages consisting of 2 chassis, one inferior and one superior, both mobile and independent, that are coupled to form a single carriage. One of the equipment developed, automatically auto-load/unload standard containers to/from railway wagons and fixed platforms. This equipment can be loaded directly by the pier crane and move autonomously to the loading areas of railway wagons, trucks or buffer areas, where the containers are organized on leaving the port. When groups of these vehicles lined up parallel to the railway track, loaded on one side and empty on the other, they can load and unload the train quickly and simultaneously.

The invention described refers to an equipment and corresponding method that enables side sliding load transfer between one vehicle/structure acting as loader, and another vehicle/structure acting as receptor. Both loaders and receptors can be vehicles or piers using a side sliding loading system that includes lifting and lateral displacement equipment. The great innovation of this system is the appearing of carriages consisting of 2 chassis, one inferior and one superior, both mobile and independent, that are coupled to form a single carriage. One of the equipment developed, automatically auto-load/unload standard containers to/from railway wagons and fixed platforms. This equipment can be loaded directly by the pier crane and move autonomously to the loading areas of railway wagons, trucks or buffer areas, where the containers are organized on leaving the port. When groups of these vehicles lined up parallel to the railway track, loaded on one side and empty on the other, they can load and unload the train quickly and simultaneously.

Disclosed is a comprehensive inspection vehicle for a subway tunnel, including a positioning system, an acquisition system and a flatcar. The flatcar runs on a railway of the subway tunnel. The positioning system and the acquisition system are arranged on the flatcar. The positioning system includes a laser ranging module and an inertial navigation module. The comprehensive inspection vehicle further includes an independent power supply system and a central control system arranged on the flatcar. The independent power supply system supplies power for the acquisition system, the positioning system and the central control system. The central control system includes an acquisition industrial computer and a positioning industrial computer which are respectively connected to the acquisition system and the positioning system.

The present disclosure relates to a rail vehicle that includes a chassis and a rail milling assembly coupled to the chassis. The rail milling assembly includes a bracket for coupling the rail milling assembly to the chassis and a milling workhead forming a portion of the rail milling assembly. The milling workhead including a spindle and a cutter depending downwardly from the spindle. The spindle and cutter are driven by a spindle motor. The milling workhead further includes a cylinder rod disposed between the spindle motor and the spindle to thereby bias the cutter towards the rail during operation.

The present disclosure relates to a rail vehicle that includes a chassis and a rail milling assembly coupled to the chassis. The rail milling assembly includes a bracket for coupling the rail milling assembly to the chassis and a milling workhead forming a portion of the rail milling assembly. The milling workhead including a spindle and a cutter depending downwardly from the spindle. The spindle and cutter are driven by a spindle motor. The milling workhead further includes a cylinder rod disposed between the spindle motor and the spindle to thereby bias the cutter towards the rail during operation.

A securement for crawler cranes and system and method for use of the same are disclosed. In one embodiment of the system, a pair of structural securements are spaced at approximately a track-distance apart with respect to the crawler crane and coupled together by multiple transverse support members. When the crawler crane is driven onto the structural securements and fastened thereto, the tipping fulcrum of the crawler crane is shifted, thereby requiring a greater tipping force to tip and adding stability during high wind events.

A system is provided that includes a self-propelled platform that can traverse a first rail of a first vehicle and a first rail of a second vehicle, the first rail of the first vehicle and the first rail of the second vehicle separated in spaced relation. The self-propelled platform has a wheel assembly that can engage the first rail of the first vehicle and the first rail of the second vehicle. The wheel assembly may include at least one guide extending away from the self-propelled platform and having a size and shape to engage a first rail of the first vehicle or the first rail of the second vehicle while a portion of the self-propelled platform remains on the first rail of the first vehicle and the first rail of the second vehicle, to guide the wheel assembly onto the first rail of the first vehicle or the first rail of the second vehicle.

A system is provided that includes a self-propelled platform that can traverse a first rail of a first vehicle and a first rail of a second vehicle, the first rail of the first vehicle and the first rail of the second vehicle separated in spaced relation. The self-propelled platform has a wheel assembly that can engage the first rail of the first vehicle and the first rail of the second vehicle. The wheel assembly may include at least one guide extending away from the self-propelled platform and having a size and shape to engage a first rail of the first vehicle or the first rail of the second vehicle while a portion of the self-propelled platform remains on the first rail of the first vehicle and the first rail of the second vehicle, to guide the wheel assembly onto the first rail of the first vehicle or the first rail of the second vehicle.

The invention relates to a modular system for weed control for a rail vehicle. The modular system has a control module including a control unit and a control module. The control unit is configured to generate a first set of control signals for controlling valves and mixers in an herbicide and mixing module configured to mix an herbicide mixture and to generate a second set of control signals for controlling valves of a nozzle assembly. The herbicide and mixing module has a plurality of containers for receiving different herbicides. The nozzle assembly has a first set of nozzles for spraying herbicides, and the control module, the herbicide and mixing module, and the nozzle assembly can each be individually fixed to a carrier element in a reversible manner.

The invention relates to a modular system for weed control for a rail vehicle. The modular system has a control module including a control unit and a control module. The control unit is configured to generate a first set of control signals for controlling valves and mixers in an herbicide and mixing module configured to mix an herbicide mixture and to generate a second set of control signals for controlling valves of a nozzle assembly. The herbicide and mixing module has a plurality of containers for receiving different herbicides. The nozzle assembly has a first set of nozzles for spraying herbicides, and the control module, the herbicide and mixing module, and the nozzle assembly can each be individually fixed to a carrier element in a reversible manner.