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 improved safety system used to determine the present position of road vehicles with rubber tires that are outfitted with railgear to be able to ride on railroad tracks that provides data to control signals, such as flashing lights, and crossing gates at railroad grade crossings in order to prevent accidents with vehicles or persons.

An improved safety system used to determine the present position of road vehicles with rubber tires that are outfitted with railgear to be able to ride on railroad tracks that provides data to control signals, such as flashing lights, and crossing gates at railroad grade crossings in order to prevent accidents with vehicles or persons.

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.

A rail gear system for attachment to the frame rails of a truck that readily accommodates the span of the frame rails. The system including an axle tube, a pivot tube, first and second spring sub-systems, and a pivot bar with an actuator plate mounted to the pivot bar. Frame rail mounting brackets are secured to the two frame rails of the truck. A primary actuator is employed to elevate the axle tube off of the rails and adjustment of the width of the frame rails is accomplished by movement of the bushings along both the pivot tube and pivot bar until the desired separation between the frame rail mounting brackets is achieved.

A rail gear system for attachment to the frame rails of a truck that readily accommodates the span of the frame rails. The system including an axle tube, a pivot tube, first and second spring sub-systems, and a pivot bar with an actuator plate mounted to the pivot bar. Frame rail mounting brackets are secured to the two frame rails of the truck. A primary actuator is employed to elevate the axle tube off of the rails and adjustment of the width of the frame rails is accomplished by movement of the bushings along both the pivot tube and pivot bar until the desired separation between the frame rail mounting brackets is achieved.

A system for recharging a railcar air-brake system for a road-rail vehicle, including a rail-capable material handler, adapted or modified for transporting an at least one railcar that permits an air compression system to provide a near-constant low-volume airflow to recharge the respective air-brake systems without requiring the road-rail vehicle to be driven. The system can generally comprise a hydraulic pump, an air compressor, and at least one railcar air-brake system. The system can be adapted for recharging railcar air-brake systems for a road-rail vehicle adapted for transporting at least two railcars that does not significantly diminish the utility of the road-rail vehicle.

A dual mode vehicle that operates on both guided rails and roadways includes a capsule, a carriage, a left motor, a right motor, a road drive system, a rail drive system, a pod control unit, and at least one battery. The carriage includes a spherical frame-housing, a left wheel housing, and a right wheel housing. A spherical cabin of the capsule is attitudinally mounted within the spherical frame-housing. The left motor is adjacently mounted to the left wheel housing. The right motor is adjacently mounted to the right wheel housing. The left and right motors are operatively coupled with the road drive system through the at least one battery and the pod control unit to operate a roadways transportation mode. The left and right motors are operatively coupled with the rail drive system through the at least one battery and the pod control unit to operate a railway transportation 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.