Systems and methods for traction

The invention claimed is: 1 . A method of operating a vehicle, comprising: flowing compressed gas selectively through distinct orifice sizes in response to a determined operating condition of the vehicle, and thereby to create a stream of gas that impacts a surface of a route adjacent to a wheel of the vehicle, wherein flowing the compressed gas comprises flowing the compressed gas from a compressed gas storage tank through a delivery system coupling the storage tank to a nozzle, wherein the delivery system comprises a parallel path diverging downstream of the compressed gas storage tank and converging upstream of the nozzle, the parallel path including a first path and a second path. 2 . The method of claim 1 , further comprising delivering the stream of gas to a location that is upstream relative to a direction of travel of the vehicle wheel of the vehicle via the nozzle. 3 . The method of claim 2 , further comprising selecting a mode of operation from a first mode in which the stream of gas is delivered through a first orifice disposed in the first path and not a second orifice disposed in the second path during a first condition and a second mode in which the stream of gas is delivered through the second orifice and not the first orifice during a second condition that differs from the first condition. 4 . The method of claim 3 , wherein the first condition comprises first compressed air storage pressure and the first orifice comprises a first orifice size, and the second condition comprises a second compressed air storage pressure and the second orifice comprises a second orifice size, wherein the first compressed air storage pressure is greater than the second compressed air storage pressure, and wherein the first orifice size is greater than the second orifice size. 5 . The method of claim 3 , wherein the first condition comprises a first compressed air storage leakage amount and the first orifice comprises a first orifice size, and wherein the second condition comprises a second compressed air leakage amount and the second orifice comprises a second orifice size, wherein the first compressed air storage leakage amount is smaller than the second compressed air storage leakage amount, and wherein the first orifice size is greater than the second orifice size. 6 . The method of claim 5 , further comprising estimating the compressed air leakage amount based at least in part on a model of compressed gas storage and usage in the vehicle and feedback based on a storage pressure. 7 . The method of claim 3 , further comprising actuating a first solenoid disposed in the first path to open and a second solenoid disposed in the second path to close during the first condition, and actuating the first solenoid to close and the second solenoid to open during the second, different, condition. 8 . The method of claim 1 , further comprising preventing or reducing the flow of compressed gas through either orifice during a second operating condition of the vehicle. 9 . The method of claim 1 , further comprising determining a surface moisture value for the surface as a component of the operating condition. 10 . The method of claim 1 , further comprising determining a storage pressure value as a component of the operating condition. 11 . The method of claim 1 , further comprising flowing at least a portion of the compressed gas from a storage vessel to brakes of the vehicle. 12 . A method of operating a vehicle, comprising: monitoring vehicle tractive effort to identify a reduced tractive effort that is below a threshold value; determining an operating condition of the vehicle; and responding to an identified reduced tractive effort by requesting Surface Cleaning in which compressed air is directed through a delivery system coupling a compressed air storage tank to a nozzle, the delivery system comprising a parallel path diverging downstream of the compressed air storage tank and converging upstream of the nozzle wherein the parallel path comprises a first path and a second path, wherein the compressed air is selectively directed through one or both of a first orifice disposed in the first path and a second orifice disposed in the second path toward a location on a route surface that is upstream of a vehicle wheel based at least in part on the determined operating condition of the vehicle. 13 . The method of claim 12 , further comprising selectively delivering compressed air through the first orifice and not the second orifice to the nozzle during a first condition, and delivering through the second orifice and not the first orifice during a second condition that differs than the first condition. 14 . The method of claim 13 , wherein the first condition comprises a first compressed air storage pressure and the first orifice comprises a first orifice size, and the second condition comprises a second compressed air storage pressure and the second orifice comprises a second orifice size, wherein the first compressed air storage pressure is greater than the second compressed air storage pressure, and wherein the first orifice size is greater than the second orifice size. 15 . The method of claim 13 , wherein the first condition comprises a first compressed air leakage amount and the first orifice comprises a first orifice size, and the second condition comprises a second compressed air leakage amount and the second orifice comprises a second orifice size, wherein the first compressed air leakage amount is less than the second compressed air leakage amount, and wherein the first orifice size is greater than the second orifice size. 16 . The method of claim 15 , further comprising estimating the compressed air leakage amount based at least in part on a model of compressed gas storage and usage in the vehicle and feedback based on a storage pressure. 17 . A system, comprising: a compressed gas storage tank; and a delivery system coupling the storage tank to a nozzle, the delivery system including a parallel path diverging downstream of the compressed gas storage tank and converging upstream of the nozzle, the parallel path including a first path with a first orifice and first solenoid, and a second path including a second orifice and second solenoid. 18 . The system of claim 17 , further comprising a controller having one or more processors with instructions stored therein configured to cause the first solenoid to open and the second solenoid to close during a first condition, and the first solenoid to close and the second solenoid to open during a second condition. 19 . The system of claim 18 , further comprising a vehicle configured to support the storage tank, the delivery system and the controller, and the nozzle is configured to direct a stream of gas that is supplied from the storage tank to a surface proximate to a wheel of the vehicle, and thereby to change a friction coefficient of the surface relative to the wheel responsive to the wheel contacting the surface. 20 . The system of claim 19 , wherein the vehicle is a rail vehicle, the wheel is a steel wheel, and the surface is a portion of a steel rail upstream of the wheel in the direction of travel of the vehicle.