A computing system may obtain, for each vehicle of a plurality of vehicles located within a location area, navigation data that indicates a travel route for the vehicle. Based on the navigation data for the plurality of vehicles, the computing system determines a subset of the plurality of vehicles that are within a threshold distance of each other and have respective travel routes that at least partially overlap. The computing system selects, based on a set of selection parameters, two or more vehicles among the subset of vehicles to form a platoon of vehicles that travel in a coordinated arrangement in proximity to each other during at least a portion of the respective travel routes of the selected vehicles. The computing system can direct the selected vehicles to form the platoon of vehicles.

The present disclosure discloses a road-rail dual-purpose vehicle, comprising a vehicle frame (1), and a lifting airbag mounting seat (1c) is provided between two longitudinal beams (1a) of the vehicle frame (1); a load-bearing airbag insertion hole is formed in a lower cover plate (1a1) of the longitudinal beam (1a); a load-bearing airbag mounting seat (1d) is installed in the load-bearing airbag insertion hole, and a bearing bolster (1e) is installed on an outer side of the longitudinal beam (1a). A suspension (2) comprises an axle assembly (2a); a lifting airbag (2b) is installed in a middle portion of a front end of the axle assembly (2a); both sides of the rear end of the axle assembly (2a) are provided with primary load-bearing airbags (2c); and the two primary load-bearing airbags (2c) are respectively provided with the secondary load-bearing airbags (2c); the lifting airbag (2b) is installed on the lifting airbag mounting seat (1c), and the secondary load-bearing airbag (2e) is installed in the load-bearing airbag mounting seat (1d). The single-axle bogie (3) comprises a framework (3a), and both ends of the framework (3a) are provided with axle boxes (3b); a primary damping spring assembly (3d) is provided between the axle boxes (3b) and the vehicle frame (1); and a vehicle frame connection assembly (3f) is provided on both ends of the top surface of the framework (3a) respectively; the framework (3a) is installed on the bottom surface of the bearing bolster (1e) through the vehicle frame connection assembly (3f). The road-rail dual-purpose vehicle is suitable for transportation.

A fluid-jet emitting machine, particularly a firefighting machine, comprises a fluid-jet emitting device, a transport vehicle, lifting members and a control device.

Each lifting member comprises an actuator constrained to the transport vehicle and at least one idler wheel adapted to engage a rail of a track.

The actuators are configured to move the respective wheels between a non-operative position, in which the wheels are distanced from the respective rail, and an operative position, in which the wheels are arranged in contact with the respective rail.

The control device is operatively associated with the actuators to activate the passage of the wheels from the non-operative position to the operative position so that during movement along a track and in said operative position, the wheels prove to be pressed against the respective rail, exerting a force such as to reduce only part of the pressure exerted by the movement means of the vehicle on the track.

An onsite steel rail laser processing engineering vehicle, including a laser processing power engineering vehicle and a laser processing cart, the laser processing power engineering vehicle is connected to the laser processing cart; the onsite steel rail laser processing engineering vehicle further comprises a transport mechanism disposed on the laser processing power engineering vehicle; through movement and rotation, the transport mechanism transports the laser processing cart into the laser processing power engineering vehicle or transports the laser processing cart out from the laser processing power engineering vehicle and places it on rails.

An onsite steel rail laser processing engineering vehicle, including a laser processing power engineering vehicle and a laser processing cart, the laser processing power engineering vehicle is connected to the laser processing cart; the onsite steel rail laser processing engineering vehicle further comprises a transport mechanism disposed on the laser processing power engineering vehicle; through movement and rotation, the transport mechanism transports the laser processing cart into the laser processing power engineering vehicle or transports the laser processing cart out from the laser processing power engineering vehicle and places it on rails.

Disclosed herein is a railcar-moving vehicle having a highway mode for operation on roadways, and a rail mode for operation on rails. The railcar-moving vehicle including a support system, at least one drive axle with rubber tried drive wheels, and at least one pair of steering tires and two spaced apart rail bogies suspended by the support system. The railcar-moving vehicle including a weighted sled frame slidably mounted to the support system, the sled frame translatable between the front end and the rear end of the support system for optimizing weight distribution for increasing traction by the bogies when in rail mode. The bogies retained in an elevated and stowed position during highway mode and in a lowered position when in rail mode.

Disclosed herein is a railcar-moving vehicle having a highway mode for operation on roadways, and a rail mode for operation on rails. The railcar-moving vehicle including a support system, at least one drive axle with rubber tried drive wheels, and at least one pair of steering tires and two spaced apart rail bogies suspended by the support system. The railcar-moving vehicle including a weighted sled frame slidably mounted to the support system, the sled frame translatable between the front end and the rear end of the support system for optimizing weight distribution for increasing traction by the bogies when in rail mode. The bogies retained in an elevated and stowed position during highway mode and in a lowered position when in rail mode.

Disclosed herein is a railcar-moving vehicle having a highway mode for operation on roadways, and a rail mode for operation on rails. The railcar-moving vehicle including a support system, at least one drive axle with rubber tried drive wheels, and at least one pair of steering tires and two spaced apart rail bogies suspended by the support system. The railcar-moving vehicle including a weighted sled frame slidably mounted to the support system, the sled frame translatable between the front end and the rear end of the support system for optimizing weight distribution for increasing traction by the bogies when in rail mode. The bogies retained in an elevated and stowed position during highway mode and in a lowered position when in rail mode.

In an example, the autonomous vehicle (AV) can be configured among the other vehicles and railway to communicate with a rider on a peer to peer basis to pick up the rider on demand from a location on a track, like a railway, tram or other track, rather than the rider being held hostage to a fixed railway schedule. The rider can have an application on his/her cell phone, which tracks each of the AVs, and contact them using the application on the cell phone. In an example, the AV is configured for both on-track and off track operation with different operating parameters for on-track and off track, including speed, degree of autonomy, sensors used etc.

There is described a hi-rail device comprising a cam assembly, an axle assembly and a locking pin. The cam assembly comprises a guiding slot which comprises a plurality of contiguous segments extending as a broken line, e.g., in a flattened M shape, wherein a first one and a last one of the contiguous segments extend in a downward slope with respect to a horizon. The locking pin inserted in the guiding slot and movable in translation within the guiding slot in which it is inserted. The axle assembly, in which the locking pin is inserted, has a weight applied on the locking pin which locks the locking pin in the lower end or the upper end of the guiding slot if the locking pin is in the first one or the last one of the four contiguous segments and no other force is applied thereonto.