A self guarded frog copper weld fixture has a rail form and a pair of transverse locator arms. The rail form is configured to abut with a damaged rail frog and define a proper repaired geometry for the rail frog. A pair of locator arms transversely and vertically locate and secure the rail form against one of the rails of a damaged rail frog, by applying an opposing force against a second one of the damaged rail frog rails. Any wear will present as small gaps between the rail form and rail frog. The transverse locator arms are pivotal with respect to the rail form, and so may be rotated from transverse to the rail form to align longitudinally for compact transport or storage, and may also be reversed to allow either one of the longitudinal vertical side edges of the rail form to be abutted to the rail frog.

A work train lays a rail of a railway track. The work train has a heating device with a heating zone, gas burners, and a radiant body interposed between the gas burners and the heating zone. The radiant body has openings that open into the heating zone. The work train is moved in a laying direction, so that at each moment a portion of the rail to be fixed passes through the heating zone. Heat is supplied to the rail to be fixed through the heating zone by feeding the gas burner so that no flame emerges from the openings in the heating zone and that at least 75% of the heat supplied to the rail is transmitted by radiation from the radiant body. Then the rail is fixed after the heat has been applied to a tie of the railway track behind the heating zone in the laying direction.

A work train lays a rail of a railway track. The work train has a heating device with a heating zone, gas burners, and a radiant body interposed between the gas burners and the heating zone. The radiant body has openings that open into the heating zone. The work train is moved in a laying direction, so that at each moment a portion of the rail to be fixed passes through the heating zone. Heat is supplied to the rail to be fixed through the heating zone by feeding the gas burner so that no flame emerges from the openings in the heating zone and that at least 75% of the heat supplied to the rail is transmitted by radiation from the radiant body. Then the rail is fixed after the heat has been applied to a tie of the railway track behind the heating zone in the laying direction.

A translatable, ultra-high pressure liquid jet system includes a translatable frame configured to maintain mechanical contact with a rail. The liquid jet system includes a liquid jet processing head affixed to the frame and configured to maintain a distance from the rail and provide a liquid jet that contacts the rail. The liquid jet system also includes an ultra-high pressure liquid pump in fluid communication with the liquid jet processing head. The ultra-high pressure liquid pump is configured to supply pressurized liquid to the liquid jet processing head.

In order to fix a rail of a rail track using a rail machine, the rail machine is moved in a working direction so that at all times a portion of the rail which is not attached to a cross-member of the rail track passes through a thermal conditioning zone of a thermal conditioning device of the rail machine, a temperature of a surface region of the portion of the rail passing through the thermal conditioning zone is modified using the thermal conditioning device by generating a non-homogeneous temperature distribution in the portion of the rail, and the portion of the rail is fixed to a cross-member of the rail track, after modification of the temperature of the surface region of the portion of the rail, without waiting for the temperature distribution in the portion of the rail to be homogenized.

In order to fix a rail of a rail track using a rail machine, the rail machine is moved in a working direction so that at all times a portion of the rail which is not attached to a cross-member of the rail track passes through a thermal conditioning zone of a thermal conditioning device of the rail machine, a temperature of a surface region of the portion of the rail passing through the thermal conditioning zone is modified using the thermal conditioning device by generating a non-homogeneous temperature distribution in the portion of the rail, and the portion of the rail is fixed to a cross-member of the rail track, after modification of the temperature of the surface region of the portion of the rail, without waiting for the temperature distribution in the portion of the rail to be homogenized.

A processing machine for processing a rail track has a power supply unit for providing power and a processing unit which is able to be operated by the power provided by the power supply unit. The power supply unit and the processing unit are configured so as to be separate from one another. On account thereof, the processing unit is able to be operated in a spatially separated manner from the power supply unit, on account of which a user-friendly, flexible and safe processing of the rail track is enabled.

A processing machine for processing a rail track has a power supply unit for providing power and a processing unit which is able to be operated by the power provided by the power supply unit. The power supply unit and the processing unit are configured so as to be separate from one another. On account thereof, the processing unit is able to be operated in a spatially separated manner from the power supply unit, on account of which a user-friendly, flexible and safe processing of the rail track is enabled.

A beam delivery system including a shield which includes at least one beam passage for transmission of at least one laser beam; an optics assembly configured to at least partly focus the at least one laser beam on the at least one beam passage; and means for providing a fluid flow through the at least one beam passage. Also provided is a train and a transport system, as well as a beam delivery method that includes: transmitting at least one laser beam through a respective at least one beam passage of a shield; at least partly focusing the at least one laser beam on the at least one beam passage; and providing a fluid flow through the at least one beam passage.

A maintenance vehicle for an attraction system includes a maintenance component configured to output a material onto a path of a pathway system of the attraction system, a guide engager configured to capture a projection of the pathway system, the projection being separate from the path, and a set of wheels configured to move the maintenance vehicle along the pathway system while the guide engager maintains capture of the projection to move the maintenance component along the path.