According to various aspects, exemplary embodiments are disclosed herein of wireless locomotive emergency stop systems. Also disclosed are exemplary methods of providing locomotives with wireless emergency stop systems, and exemplary methods of operating wireless locomotive emergency stop systems.

According to various aspects, exemplary embodiments are disclosed herein of wireless locomotive emergency stop systems. Also disclosed are exemplary methods of providing locomotives with wireless emergency stop systems, and exemplary methods of operating wireless locomotive emergency stop systems.

A control system is provided for improving the handling of a powered system traveling along a route. The powered system includes a first and second powered vehicle respectively positioned in two consists, which are separated by at least one non-powered vehicle. The control system includes a controller configured to determine at least one slack location along the powered system. The slack location represents a force separation in the powered system between two respective regions, which include a compression region subject to a compression force and a tension region subject to a tension force. The controller is coupled to a respective engine of a powered vehicle, and the controller adjusts an output of the engine to control a rate of change of the at least one slack location along the powered system. Additionally, a method is provided for improving the handling of a powered system traveling along a route.

A control system is provided for improving the handling of a powered system traveling along a route. The powered system includes a first and second powered vehicle respectively positioned in two consists, which are separated by at least one non-powered vehicle. The control system includes a controller configured to determine at least one slack location along the powered system. The slack location represents a force separation in the powered system between two respective regions, which include a compression region subject to a compression force and a tension region subject to a tension force. The controller is coupled to a respective engine of a powered vehicle, and the controller adjusts an output of the engine to control a rate of change of the at least one slack location along the powered system. Additionally, a method is provided for improving the handling of a powered system traveling along a route.

A transport vehicle for traveling in a low-pressure environment structure is provided. The transport vehicle may include a deployable decelerator provided on the transport vehicle and configured to deploy from the transport vehicle to decrease a distance between the transport vehicle and the low-pressure environment structure. When the decelerator is deployed the decelerator is configured to increase drag forces opposing a direction of motion of the transport vehicle and decelerate the transport vehicle.

Railway system with a railway infrastructure including a wheel railway track and wheel railway vehicles driven on the wheel railway track, the wheel railway track including rails mounted on a ballasted or unballasted ground support, for instance provided with sleepers, the wheel railway vehicles comprising a chassis and wheels coupled to the chassis, and a propulsion system, wherein the propulsion system comprises a retrofitted linear electric motor, the linear electric motor comprising a mover mounted on an underside of the chassis, or mounted on an underside of one or more bogies comprising said wheels, and a stator comprising an electromagnetic drive mounted along at least a section of the wheel railway track between the rails of the wheel railway track.

Methods and systems for operating a vehicle are provided. In one example, a method for operating a vehicle may include flowing compressed gas selectively through distinct orifice sizes depending on an operating condition of the vehicle. In another example, the vehicle may be a rail vehicle. In one example, the compressed gas may include compressed ambient air, and where the compressed gas is selectively delivered toward an upstream of a vehicle wheel riding on a rail via a nozzle. In another example, the compressed gas may be selectively delivered through a first orifice and not a second orifice to the nozzle during a first condition, and delivered through the second orifice and not the first orifice during a second condition different from the first condition.

Methods and systems for operating a vehicle are provided. In one example, a method for operating a vehicle may include flowing compressed gas selectively through distinct orifice sizes depending on an operating condition of the vehicle. In another example, the vehicle may be a rail vehicle. In one example, the compressed gas may include compressed ambient air, and where the compressed gas is selectively delivered toward an upstream of a vehicle wheel riding on a rail via a nozzle. In another example, the compressed gas may be selectively delivered through a first orifice and not a second orifice to the nozzle during a first condition, and delivered through the second orifice and not the first orifice during a second condition different from the first condition.