Intelligent non-autogenous metalworking systems and control logic with automated wire-to-beam alignment

What is claimed: 1. A method for operating a non-autogenous workpiece processing system, the workpiece processing system including a system controller, a pivotable processing head bearing a wire feeder operable to discharge filler wire and a beam emitter operable to melt the filler wire, and an actuator operable to selectively pivot the processing head, the method comprising: receiving, via the system controller from a position sensor, sensor signals indicative of a wire location of the filler wire discharged into a joint region by the wire feeder; determining, via the system controller based on the received sensor signals, a wire displacement between the wire location and a beam location of a beam emitted onto the joint region by the beam emitter; determining, via the system controller, if the wire displacement is greater than a threshold wire displacement value; determining, via the system controller responsive to the wire displacement being greater than the threshold wire displacement value, a corrective force calculated to reduce the wire displacement to below the threshold wire displacement value; and transmitting, via the system controller to the actuator, a command signal to pivot the processing head to thereby apply the corrective force to the filler wire as the filler wire is discharged from the wire feeder. 2. The method of claim 1 , wherein the corrective force is calculated via the system controller as a function of the wire displacement and a spring constant factor of the filler wire. 3. The method of claim 2 , wherein the corrective force is calculated as: Σ F=F JOINT −F OPTIC =k wire ·d meas where F JOINT is a reaction force applied to the filler wire by the joint region between two workpieces into which the filler wire is discharged by the wire feeder; F OPTIC is the corrective force applied to the filler wire by the pivoting of the processing head; k wire is the spring constant factor of the filler wire; and d meas is the wire displacement. 4. The method of claim 3 , wherein the reaction force is applied via the joint region to a distal end of the filler wire in a first transverse direction, and the corrective force is applied via a feeder nozzle of the wire feeder to a lateral side of the filler wire in a second transverse direction. 5. The method of claim 1 , further comprising: determining, via the system controller based on the received sensor signals, a lateral edge of the wire, the lateral edge being set as the wire location; and determining, via the system controller based on the received sensor signals, a beam center of the beam, the beam center being set as the beam location, wherein determining the wire displacement includes measuring a distance between the lateral edge of the wire and the beam center of the beam. 6. The method of claim 1 , wherein determining if the wire displacement is greater than the threshold wire displacement value includes: determining if the wire displacement is greater than a first threshold displacement value; and determining if the wire displacement is less than the first threshold displacement value and greater than a second threshold displacement value less than the first threshold displacement value. 7. The method of claim 6 , wherein determining the corrective force calculated to reduce the wire displacement to below the threshold wire displacement value includes: determining, responsive to the wire displacement being greater than the first threshold displacement value, a first corrective force; and determining, responsive to the wire displacement being greater than the second threshold displacement value and less than the first threshold displacement value, a second corrective force distinct from the first corrective force. 8. The method of claim 7 , wherein transmitting the command signal to the actuator includes: transmitting, responsive to determining the first corrective force, a first command signal to pivot the processing head a first angular distance to thereby apply the first corrective force to the filler wire; and transmitting, responsive to determining the second corrective force, a second command signal to pivot the processing head a second angular distance to thereby apply the second corrective force to the filler wire. 9. The method of claim 1 , further comprising transmitting, via the system controller to the actuator, a series of command signals to pivot the processing head in a sequence of angular distances of a predetermined welding and/or brazing operation, wherein the command signal adds to or subtracts from one or more of the angular distances of the processing head during the predetermined welding and/or brazing operation. 10. The method of claim 1 , further comprising determining a saturation limit for the actuator, wherein the determined corrective force applied by the processing head to the filler wire is limited to being less than or equal to the saturation limit. 11. The method of claim 1 , wherein the beam emitter includes a welding/brazing laser assembly and the beam includes a laser beam, the method further comprising setting, via the system controller in a resident memory device, a calibrated beam spot location of the laser beam, wherein the beam location is the calibrated beam spot location. 12. The method of claim 1 , wherein the actuator includes a servomotor drivingly attached to the processing head, and wherein the command signal transmitted via the system controller includes an angular position for an output shaft of the servomotor. 13. The method of claim 1 , wherein the position sensor includes a digital camera module mounted to the processing head and configured to capture real-time images of the filler wire discharged from the wire feeder, and wherein the sensor signals include the real-time images of the filler wire. 14. An automated non-autogenous workpiece processing system comprising: a processing head with a support frame configured to pivotably mount to a support structure, a wire feeder mounted on the support frame and operable to discharge filler wire, and a beam emitter mounted on the support frame and operable to melt the filler wire; an actuator drivingly attached to the support frame and operable to selectively pivot the processing head; and a system controller communicatively connected to the actuator and the processing head, the system controller being programmed to: receive sensor signals from a position sensor indicative of a wire location of the filler wire discharged into a joint region by the wire feeder; determine, based on the received sensor signals, a wire displacement between the wire location and a beam location of a beam emitted onto the joint region by the beam emitter; determine if the wire displacement is greater than a threshold wire displacement value; responsive to the wire displacement being greater than the threshold wire displacement value, determine a corrective force calculated to reduce the wire displacement to below the threshold wire displacement value; and transmit a command signal to the actuator to pivot the processing head such that the processing head applies the corrective force to the filler wire as the filler wire is discharged from the wire feeder. 15. The workpiece processing system of claim 14 , wherein the corrective force is calculated via the system controller as a function of the wire displacement and a spring constant factor of the filler wire. 16. The workpiece processing system of claim 15 , wherein the corrective force is calculated as: Σ F=F JOINT −F OPTIC =k wire ·d m