In a method for renewing a track (2) and cleaning a ballast bed (3), the old track (2) is lifted off the ballast bed in sections as a track panel (15), transported forward in a working direction (4) and deposited on track panel wagons (8). The exposed ballast bed (3), forming a renewal gap (17), is cleaned by a cleaning machine (11), spoil (32) accruing in the process is transported forward underneath the track panels (15) deposited on the track panel wagons (8), and stored in hopper cars (10). New rails (29), pre-deposited underneath new sleepers (27) positioned on sleeper wagons (14), are pulled forward into the renewal gap (17) by the cleaning machine (11) and deposited on the cleaned ballast bed (3). The new sleepers (27) are laid down on the cleaned ballast bed and connected to the new rails (29) lifted off the ballast bed (3).

A railcar configured to transport a payload, the open-topped railcar including left and right sidewalls, forward and rear sidewalls, a left track, and a right track. The left and right sidewalls extend vertically from the floor and include upper edges. The forward and rear sidewalls extend vertically from the floor between the left and right sidewalls to form a payload bay. The left track is positioned near the left sidewall and spaced above the floor and below the upper edge of the left sidewall. The right track is positioned near the right sidewall and spaced above the floor and below the upper edge of the right sidewall. The left track and right track may include a number of pedestals spaced apart from each other and a number of ramps angled diagonally upward from some of the pedestals to upper edges of the forward and rear sidewalls. The left and right tracks are configured to support an independent material moving machine at least partially in the payload bay and/or between the left and right sidewalls.

A processing system for carrying out track work includes a rail vehicle having a processing device and a monitoring device for defining and monitoring a permissible working space for the rail vehicle. The processing system further includes a position measuring device for determining a position of the rail vehicle. The rail vehicle is controlled to carry out the track work by using a control device in dependence on the determined position and the defined working space. A method for carrying out track work is also provided.

A railway vehicle for moving material includes a first and a second railway wagon, each of which extend between respective first and a second end portion the first and second railway wagons engaged at the second end portion of the first railway wagon and at the first end portion of the second railway wagon, wherein the first and second railway wagons each include: a platform, a carriage, a conveyor carried by the platform and having an operating section configured to move the material along a advancement direction. The railway vehicle includes a connection device carried by at least one of the first and second railway wagons (and configured to define an intermediate section for connecting the operating sections of the conveyors of the first and second railway wagons.

The invention relates to a control and operating system for working on a track with a track maintenance machine, with at least one machine frame movable on rail-based running gears, comprising working devices , a sensor and measuring system for recording the position data of the working devices and for detecting objects of the track, in particular sleepers, rails, and, as the case may be, obstacles, and further comprising an arrangement of cameras for optical detection of the working devices and the working areas. It is provided that a control station without free visual range of a respective working device is set up at a location inside or outside the track maintenance machine and that the control station comprises a display device for virtual operation, control, and/or monitoring of the track maintenance machine. This achieves greater flexibility during working operation, an extension of the controlling and operating options, and a significant increase in safety and ergonomic design at the workstation.

The disclosure describes a sample confinement tool that includes a first end and a second end. The first end of the sample confinement tool is coupled to a driving tool. The driving tool is coupled to a heavy-duty vehicle. The sample confinement tool is operable to insert a predetermined depth below a ballast surface and collect a ballast sample within the second end of the sample confinement tool. The sample confinement tool is also operable to confine the ballast sample within the second end of the sample confinement tool by mechanically compressing the ballast sample. The sample confinement tool is further operable to release the ballast sample into a sample receptacle by mechanically decompressing the ballast sample.

A vibratory grouting drilling rig includes: a drilling rig bracket, a moving bracket, and a driving mechanism mounted on the drilling rig bracket for driving the moving bracket to move; wherein a working bracket is slidingly mounted on the moving bracket, and a sliding direction of the working bracket is identical to a moving direction of the moving bracket; a vibratory grouting rod and a drilling rod are mounted on the working bracket; multiple flexible connectors are connected between the working bracket and the drilling rig bracket, and are arranged along the moving direction of the moving bracket; the flexible connectors go around an end of the moving bracket and are connected to the drilling rig bracket. When the moving bracket moves, the flexible connectors pull the working bracket to move relative to the moving bracket, thus providing extra drilling force.

A control system and method for a machine is disclosed. The control system may comprise a machine controller configured to activate autonomous remote operation of the machine based on parameters. The parameters may include a range, a set-point and an obstruction status, wherein the range is a distance from the machine to an operator.

In one embodiment, a sample confinement tool includes a first end and a second end. The first end of the sample confinement tool is coupled to a driving tool. The driving tool is coupled to a heavy-duty vehicle. The sample confinement tool is operable to insert a predetermined depth below a ballast surface and collect a ballast sample within the second end of the sample confinement tool. The sample confinement tool is also operable to confine the ballast sample within the second end of the sample confinement tool by mechanically compressing the ballast sample. The sample confinement tool is further operable to release the ballast sample into a sample receptacle by mechanically decompressing the ballast sample.

In one embodiment, a sample confinement tool includes a first end and a second end. The first end of the sample confinement tool is coupled to a driving tool. The driving tool is coupled to a heavy-duty vehicle. The sample confinement tool is operable to insert a predetermined depth below a ballast surface and collect a ballast sample within the second end of the sample confinement tool. The sample confinement tool is also operable to confine the ballast sample within the second end of the sample confinement tool by mechanically compressing the ballast sample. The sample confinement tool is further operable to release the ballast sample into a sample receptacle by mechanically decompressing the ballast sample.