Vehicle braking control system

What is claimed is: 1. A braking control system comprising: a plurality of braking control modules communicatively connected to one another and configured to control different respective axles of a vehicle system that includes one or more vehicles, a first braking control module of the braking control modules configured to: generate a torque request signal including a first requested braking torque (CFr) value for controlling a first braking device operatively connected to a first axle of the axles, the first braking device comprising one or both of a friction brake or an electrodynamic regenerative brake, the first braking device configured to apply a braking torque having a first effective braking torque (CFe) value to the first axle to decelerate the vehicle system, the braking torque being based on the first CFr value; communicate to other braking control modules of the braking control modules at least one of (i) the first CFr value and the first CFe value or (ii) a first local braking torque difference (ΔCFl) value representing a difference between the first CFr value and the first CFe value; receive, from the other braking control modules, at least one of (iii) a first set of one or more CFr values associated with other axles of the vehicle system and a second set of one or more CFe values associated with the other axles of the vehicle system, or (iv) a third set of one or more ΔCFl values representing differences between the first set and the second set; determine a total braking torque difference (ΔCFt) value as one of (v) a difference between (a) a CFr aggregate of the first CFr value and the first set of one or more CFr values and (b) a CFe aggregate of the first CFe value and the second set of one or more CFe values, or (vi) a sum of the first ΔCFl value and the third set of one or more ΔCFl values; and control the first braking device to modify the braking torque applied to the first axle based on the ΔCFt value. 2. The braking control system of claim 1 , wherein the first braking control module is configured to determine the ΔCFt value as the difference between the CFr aggregate and the CFe aggregate. 3. The braking control system of claim 1 , wherein the first braking control module is configured to determine the ΔCFt value as the sum of the first ΔCFl value and the third set of one or more ΔCFl values. 4. The braking control system of claim 1 , wherein, in response to determining that the first axle is in a sliding condition relative to a route on which the vehicle system travels, the first braking control module is configured to activate an adhesion recovery device to dispense a friction-enhancing material on the route for adhesion recovery. 5. The braking control system of claim 1 , wherein, in response to determining that the first axle is in a sliding condition relative to a route on which the vehicle system travels, the first braking control module is configured to activate a magnetic brake shoe to perform a cleaning action on the route. 6. The braking control system of claim 1 , wherein responsive to the ΔCFt value having a first sign, of either positive or negative, representing that the CFr aggregate is greater than the CFe aggregate, the first braking control module is configured to control the first braking device to increase the braking torque applied to the first axle in excess of the first CFe value. 7. The braking control system of claim 6 , wherein the first braking control module is configured to control the first braking device to increase the braking torque applied to the first axle until the first braking control module determines (i) that the ΔCFt value is zero or has a second sign opposite the first sign, or (ii) that the first axle is in a sliding condition relative to a route on which the vehicle system travels, whichever occurs first. 8. The braking control system of claim 7 , wherein, in response to determining that the first axle is in the sliding condition relative to the route, the first braking control module is configured to control the first braking device to reduce the braking torque applied to the first axle until the first braking control module determines that the first axle is no longer in the sliding condition. 9. The braking control system of claim 1 , wherein the first braking control module is configured to generate the first CFr value based on a received deceleration request signal and a received weight signal, the received weight signal associated with the first axle. 10. The braking control system of claim 1 , wherein the braking control modules are communicatively connected to one another via a communication network, the first braking control module configured to communicate the at least one of (i) the first CFr value and the first CFe value or (ii) the first ΔCFl value to other braking control modules via the communication network, the first braking control module configured to receive the at least one of (iii) the first set of the one or more CFr values and the second set of the one or more CFe values or (iv) the third set of the one or more ΔCFl values from the other braking control modules via the communication network. 11. The braking control system of claim 1 , wherein the vehicle system includes multiple vehicles and the vehicles are railway vehicles. 12. The braking control system of claim 1 , wherein the first braking control module is configured to: associate the ΔCFt value with a first time; periodically update the ΔCFt value at a predetermined time interval; and control the first braking device to modify the braking torque applied to the first axle subsequent to the first time based on the ΔCFt value as updated. 13. The braking control system of claim 1 , wherein the first braking control module is configured to receive a maximum available adhesion achievement (MAAA) signal that has either a first value or a second value, the first value indicating that one or more wheels connected to the first axle are in a sliding condition attributable to exceeding an available adhesion between the one or more wheels and a route on which the vehicle system travels, the second value indicating that the one or more wheels connected to the first axle are using less than the available adhesion and are not in the sliding condition. 14. The braking control system of claim 1 , further comprising a wheel slide protection (WSP) module configured to receive the torque request signal from the first braking control module, the WSP module configured to send a reduced CFr value, that is less than the first CFr value, to the first braking device in response to determining that one or more wheels connected to the first axle are in a sliding condition relative to a route on which the vehicle system travels. 15. A method comprising: generating a torque request signal including a first requested braking torque (CFr) value for controlling a first braking device operatively connected to a first axle of a vehicle system that includes one or more vehicles, the torque request signal generated by a first braking control module of a plurality of braking control modules configured to control different respective axles of the vehicle system, the first braking device comprising one or both of a friction brake or an electrodynamic regenerative brake; determining a first effective braking torque (CFe) value of a braking torque applied to the first axle by the first braking device to decelerate the vehicle system; communicating to other braking control modules of the braking control modules at least one of (i) the first CFr value and the first CFe value or (ii) a first local braking torque d